nut/drivers/mge-hid.c

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2012-06-01 13:55:19 +00:00
/* mge-hid.c - data to monitor Eaton / MGE HID (USB and serial) devices
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*
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* Copyright (C)
* 2003 - 2015 Arnaud Quette <arnaud.quette@free.fr>
* 2015 Arnaud Quette <ArnaudQuette@Eaton.com>
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*
* Sponsored by MGE UPS SYSTEMS <http://www.mgeups.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
*
*/
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/* TODO list:
* - better processing of FW info:
* * some models (HP R5000) include firmware.aux (00.01.0021;00.01.00)
* * other (9130) need more processing (0128 => 1.28)
* ...
* - better handling of input.transfer.* (need dstate_addrange)
* - outlet management logic (Ie, for outlet.X.load.{on,off}.delay
* => use outlet.X.delay.{start,stop}
*/
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#include "main.h" /* for getval() */
#include "usbhid-ups.h"
#include "mge-hid.h"
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#define MGE_HID_VERSION "MGE HID 1.39"
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/* (prev. MGE Office Protection Systems, prev. MGE UPS SYSTEMS) */
/* Eaton */
#define MGE_VENDORID 0x0463
/* Dell */
#define DELL_VENDORID 0x047c
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/* Powerware */
#define POWERWARE_VENDORID 0x0592
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/* Hewlett Packard */
#define HP_VENDORID 0x03f0
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/* AEG */
#define AEG_VENDORID 0x2b2d
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#ifndef SHUT_MODE
#include "usb-common.h"
/* USB IDs device table */
static usb_device_id_t mge_usb_device_table[] = {
/* various models */
{ USB_DEVICE(MGE_VENDORID, 0x0001), NULL },
{ USB_DEVICE(MGE_VENDORID, 0xffff), NULL },
/* various models */
{ USB_DEVICE(DELL_VENDORID, 0xffff), NULL },
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/* PW 9140 */
{ USB_DEVICE(POWERWARE_VENDORID, 0x0004), NULL },
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/* R/T3000 */
{ USB_DEVICE(HP_VENDORID, 0x1fe5), NULL },
/* R/T3000 */
{ USB_DEVICE(HP_VENDORID, 0x1fe6), NULL },
/* various models */
{ USB_DEVICE(HP_VENDORID, 0x1fe7), NULL },
{ USB_DEVICE(HP_VENDORID, 0x1fe8), NULL },
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/* PROTECT B / NAS */
{ USB_DEVICE(AEG_VENDORID, 0xffff), NULL },
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/* Terminating entry */
{ -1, -1, NULL }
};
#endif
typedef enum {
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MGE_DEFAULT_OFFLINE = 0,
MGE_PEGASUS = 0x100,
MGE_3S = 0x110,
/* All offline models have type value < 200! */
MGE_DEFAULT = 0x200, /* for line-interactive and online models */
MGE_EVOLUTION = 0x300, /* MGE Evolution series */
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MGE_EVOLUTION_650,
MGE_EVOLUTION_850,
MGE_EVOLUTION_1150,
MGE_EVOLUTION_S_1250,
MGE_EVOLUTION_1550,
MGE_EVOLUTION_S_1750,
MGE_EVOLUTION_2000,
MGE_EVOLUTION_S_2500,
MGE_EVOLUTION_S_3000,
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MGE_PULSAR_M = 0x400, /* MGE Pulsar M series */
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MGE_PULSAR_M_2200,
MGE_PULSAR_M_3000,
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MGE_PULSAR_M_3000_XL,
EATON_5P = 0x500 /* Eaton 5P / 5PX series */
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} models_type_t;
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/* Default to line-interactive or online (ie, not offline).
* This is then overriden for offline, through mge_model_names */
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static models_type_t mge_type = MGE_DEFAULT;
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/* Countries definition, for region specific settings and features */
typedef enum {
COUNTRY_UNKNOWN = -1,
COUNTRY_EUROPE = 0,
COUNTRY_US,
/* Special European models, which also supports 200 / 208 V */
COUNTRY_EUROPE_208,
COUNTRY_WORLDWIDE,
COUNTRY_AUSTRALIA,
} country_code_t;
static int country_code = COUNTRY_UNKNOWN;
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static char mge_scratch_buf[20];
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/* ABM - Advanced Battery Monitoring
***********************************
* Synthesis table
* HID data | Charger in ABM mode | Charger in Constant mode
* UPS.BatterySystem.Charger.ABMEnable | 1 | 0
* UPS.PowerSummary.PresentStatus.ACPresent | On utility | On battery | On utility | On battery
* Charger ABM mode | Charging | Floating | Resting | Discharging | Disabled | Disabled
* UPS.BatterySystem.Charger.Mode | 1 | 3 | 4 | 2 | 6 | 6
* UPS.PowerSummary.PresentStatus.Charging | 1 | 1 | 1 | 0 | 1 | 0
* UPS.PowerSummary.PresentStatus.Discharging | 0 |  0 |  0 | 1 | 0 | 1
*
* Notes (from David G. Miller) to understand ABM status:
* When supporting ABM, when a UPS powers up or returns from battery, or
* ends the ABM rest mode, it enters charge mode.
* Some UPSs run a different charger reference voltage during charge mode
* but all the newer models should not be doing that, but basically once
* the battery voltage reaches the charger reference level (should be 2.3
* volts/cell), the charger is considered in float mode. Some UPSs will not
* annunciate float mode until the charger power starts falling from the maximum
* level indicating the battery is truly at the float voltage or in float mode.
* The %charge level is based on battery voltage and the charge mode timer
* (should be 48 hours) and some UPSs add in a value thats related to charger
* power output. So you can have UPS that enters float mode with anywhere
* from 80% or greater battery capacity.
* float mode is not important from the softwares perspective, its there to
* help determine if the charger is advancing correctly.
* So in float mode, the charger is charging the battery, so by definition you
* can assert the CHRG flag in NUT when in float mode or charge mode.
* When in rest mode the charger is not delivering anything to the battery,
* but it will when the ABM cycle(28 days) ends, or a battery discharge occurs
* and utility returns. This is when the ABM status should be resting.
* If a battery failure is detected that disables the charger, it should be
* reporting off in the ABM charger status.
* Of course when delivering load power from the battery, the ABM status is
* discharging.
*/
#define ABM_UNKNOWN -1
#define ABM_DISABLED 0
#define ABM_ENABLED 1
/* Internal flag to process battery status (CHRG/DISCHRG) and ABM */
static int advanced_battery_monitoring = ABM_UNKNOWN;
/* Used to store internally if ABM is enabled or not */
static const char *eaton_abm_enabled_fun(double value)
{
advanced_battery_monitoring = value;
upsdebugx(2, "ABM is %s", (advanced_battery_monitoring==1)?"enabled":"disabled");
/* Return NULL, not to get the value published! */
return NULL;
}
static info_lkp_t eaton_abm_enabled_info[] = {
{ 0, "dummy", eaton_abm_enabled_fun },
{ 0, NULL, NULL }
};
/* Note 1: This point will need more clarification! */
# if 0
/* Used to store internally if ABM is enabled or not (for legacy units) */
static const char *eaton_abm_enabled_legacy_fun(double value)
{
advanced_battery_monitoring = value;
upsdebugx(2, "ABM is %s (legacy data)", (advanced_battery_monitoring==1)?"enabled":"disabled");
/* Return NULL, not to get the value published! */
return NULL;
}
static info_lkp_t eaton_abm_enabled_legacy_info[] = {
{ 0, "dummy", eaton_abm_enabled_legacy_fun },
{ 0, NULL, NULL }
};
#endif /* if 0 */
/* Used to process ABM flags, for battery.charger.status */
static const char *eaton_abm_status_fun(double value)
{
/* Don't process if ABM is disabled */
if (advanced_battery_monitoring == ABM_DISABLED) {
/* Clear any previously published data, in case
* the user has switched off ABM */
dstate_delinfo("battery.charger.status");
return NULL;
}
upsdebugx(2, "ABM numeric status: %i", (int)value);
switch ((long)value)
{
case 1:
snprintf(mge_scratch_buf, sizeof(mge_scratch_buf), "%s", "charging");
break;
case 2:
snprintf(mge_scratch_buf, sizeof(mge_scratch_buf), "%s", "discharging");
break;
case 3:
snprintf(mge_scratch_buf, sizeof(mge_scratch_buf), "%s", "floating");
break;
case 4:
snprintf(mge_scratch_buf, sizeof(mge_scratch_buf), "%s", "resting");
break;
case 6: /* ABM Charger Disabled */
snprintf(mge_scratch_buf, sizeof(mge_scratch_buf), "%s", "off");
break;
case 5: /* Undefined - ABM is not activated */
default:
/* Return NULL, not to get the value published! */
return NULL;
}
upsdebugx(2, "ABM string status: %s", mge_scratch_buf);
return mge_scratch_buf;
}
static info_lkp_t eaton_abm_status_info[] = {
{ 1, "dummy", eaton_abm_status_fun },
{ 0, NULL, NULL }
};
/* Used to process ABM flags, for ups.status (CHRG/DISCHRG/RB) */
static const char *eaton_abm_chrg_dischrg_fun(double value)
{
/* Don't process if ABM is disabled */
if (advanced_battery_monitoring == ABM_DISABLED)
return NULL;
switch ((long)value)
{
case 1: /* charging status */
case 3: /* floating status */
snprintf(mge_scratch_buf, sizeof(mge_scratch_buf), "%s", "chrg");
break;
case 2:
snprintf(mge_scratch_buf, sizeof(mge_scratch_buf), "%s", "dischrg");
break;
case 6: /* ABM Charger Disabled */
case 4: /* resting, nothing to publish! (?) */
case 5: /* Undefined - ABM is not activated */
default:
/* Return NULL, not to get the value published! */
return NULL;
}
upsdebugx(2, "ABM CHRG/DISCHRG legacy string status (ups.status): %s", mge_scratch_buf);
return mge_scratch_buf;
}
static info_lkp_t eaton_abm_chrg_dischrg_info[] = {
{ 1, "dummy", eaton_abm_chrg_dischrg_fun },
{ 0, NULL, NULL }
};
/* ABM also implies that standard CHRG/DISCHRG are processed according
* to weither ABM is enabled or not...
* If ABM is disabled, we publish these legacy status
* Otherwise, we don't publish on ups.status, but only battery.charger.status */
/* FIXME: we may prefer to publish the CHRG/DISCHRG status
* on battery.charger.status?! */
static const char *eaton_abm_check_dischrg_fun(double value)
{
if (advanced_battery_monitoring == ABM_DISABLED)
{
if (value == 1) {
snprintf(mge_scratch_buf, sizeof(mge_scratch_buf), "%s", "dischrg");
}
else {
snprintf(mge_scratch_buf, sizeof(mge_scratch_buf), "%s", "!dischrg");
}
}
else {
/* Else, ABM is enabled, we should return NULL,
* not to get the value published!
* However, clear flags that would persist in case of prior
* publication in ABM-disabled mode */
snprintf(mge_scratch_buf, sizeof(mge_scratch_buf), "%s", "!dischrg");
}
return mge_scratch_buf;
}
static info_lkp_t eaton_discharging_info[] = {
{ 1, "dummy", eaton_abm_check_dischrg_fun },
{ 0, NULL, NULL }
};
static const char *eaton_abm_check_chrg_fun(double value)
{
if (advanced_battery_monitoring == ABM_DISABLED)
{
if (value == 1) {
snprintf(mge_scratch_buf, sizeof(mge_scratch_buf), "%s", "chrg");
}
else {
snprintf(mge_scratch_buf, sizeof(mge_scratch_buf), "%s", "!chrg");
}
}
else {
/* Else, ABM is enabled, we should return NULL,
* not to get the value published!
* However, clear flags that would persist in case of prior
* publication in ABM-disabled mode */
snprintf(mge_scratch_buf, sizeof(mge_scratch_buf), "%s", "!chrg");
}
return mge_scratch_buf;
}
static info_lkp_t eaton_charging_info[] = {
{ 1, "dummy", eaton_abm_check_chrg_fun },
{ 0, NULL, NULL }
};
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/* The HID path 'UPS.PowerSummary.Time' reports Unix time (ie the number of
* seconds since 1970-01-01 00:00:00. This has to be split between ups.date and
* ups.time */
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static const char *mge_date_conversion_fun(double value)
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{
time_t sec = value;
if (strftime(mge_scratch_buf, sizeof(mge_scratch_buf), "%Y/%m/%d", localtime(&sec)) == 10) {
return mge_scratch_buf;
}
upsdebugx(3, "%s: can't compute date %g", __func__, value);
return NULL;
}
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static const char *mge_time_conversion_fun(double value)
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{
time_t sec = value;
if (strftime(mge_scratch_buf, sizeof(mge_scratch_buf), "%H:%M:%S", localtime(&sec)) == 8) {
return mge_scratch_buf;
}
upsdebugx(3, "%s: can't compute time %g", __func__, value);
return NULL;
}
#ifdef HAVE_STRPTIME
/* Conversion back retrieve ups.time to build the full unix time */
static double mge_date_conversion_nuf(const char *value)
{
struct tm mge_tm;
/* build a full value (date) + time string */
snprintf(mge_scratch_buf, sizeof(mge_scratch_buf), "%s %s", value, dstate_getinfo("ups.time"));
if (strptime(mge_scratch_buf, "%Y/%m/%d %H:%M:%S", &mge_tm) != NULL) {
return mktime(&mge_tm);
}
upsdebugx(3, "%s: can't compute date %s", __func__, value);
return 0;
}
/* Conversion back retrieve ups.date to build the full unix time */
static double mge_time_conversion_nuf(const char *value)
{
struct tm mge_tm;
/* build a full date + value (time) string */
snprintf(mge_scratch_buf, sizeof(mge_scratch_buf), "%s %s", dstate_getinfo("ups.date"), value);
if (strptime(mge_scratch_buf, "%Y/%m/%d %H:%M:%S", &mge_tm) != NULL) {
return mktime(&mge_tm);
}
upsdebugx(3, "%s: can't compute time %s", __func__, value);
return 0;
}
static info_lkp_t mge_date_conversion[] = {
{ 0, NULL, mge_date_conversion_fun, mge_date_conversion_nuf }
};
static info_lkp_t mge_time_conversion[] = {
{ 0, NULL, mge_time_conversion_fun, mge_time_conversion_nuf }
};
#else
static info_lkp_t mge_date_conversion[] = {
{ 0, NULL, mge_date_conversion_fun, NULL }
};
static info_lkp_t mge_time_conversion[] = {
{ 0, NULL, mge_time_conversion_fun, NULL }
};
#endif /* HAVE_STRPTIME */
/* The HID path 'UPS.PowerSummary.ConfigVoltage' only reports
'battery.voltage.nominal' for specific UPS series. Ignore
the value for other series (default behavior). */
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static const char *mge_battery_voltage_nominal_fun(double value)
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{
switch (mge_type & 0xFF00) /* Ignore model byte */
{
case MGE_EVOLUTION:
if (mge_type == MGE_EVOLUTION_650) {
value = 12.0;
}
break;
case MGE_PULSAR_M:
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case EATON_5P:
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break;
default:
return NULL;
}
snprintf(mge_scratch_buf, sizeof(mge_scratch_buf), "%.0f", value);
return mge_scratch_buf;
}
static info_lkp_t mge_battery_voltage_nominal[] = {
{ 0, NULL, mge_battery_voltage_nominal_fun }
};
/* The HID path 'UPS.PowerSummary.Voltage' only reports
'battery.voltage' for specific UPS series. Ignore the
value for other series (default behavior). */
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static const char *mge_battery_voltage_fun(double value)
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{
switch (mge_type & 0xFF00) /* Ignore model byte */
{
case MGE_EVOLUTION:
case MGE_PULSAR_M:
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case EATON_5P:
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break;
default:
return NULL;
}
snprintf(mge_scratch_buf, sizeof(mge_scratch_buf), "%.1f", value);
return mge_scratch_buf;
}
static info_lkp_t mge_battery_voltage[] = {
{ 0, NULL, mge_battery_voltage_fun }
};
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static const char *mge_powerfactor_conversion_fun(double value)
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{
snprintf(mge_scratch_buf, sizeof(mge_scratch_buf), "%.2f", value / 100);
return mge_scratch_buf;
}
static info_lkp_t mge_powerfactor_conversion[] = {
{ 0, NULL, mge_powerfactor_conversion_fun }
};
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static const char *mge_battery_capacity_fun(double value)
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{
snprintf(mge_scratch_buf, sizeof(mge_scratch_buf), "%.2f", value / 3600);
return mge_scratch_buf;
}
static info_lkp_t mge_battery_capacity[] = {
{ 0, NULL, mge_battery_capacity_fun }
};
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info_lkp_t eaton_enable_disable_info[] = {
{ 0, "disabled", NULL },
{ 1, "enabled", NULL },
{ 0, NULL, NULL }
};
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static info_lkp_t mge_upstype_conversion[] = {
{ 1, "offline / line interactive", NULL },
{ 2, "online", NULL },
{ 3, "online - unitary/parallel", NULL },
{ 4, "online - parallel with hot standy", NULL },
{ 5, "online - hot standby redundancy", NULL },
{ 0, NULL, NULL }
};
static info_lkp_t mge_sensitivity_info[] = {
{ 0, "normal", NULL },
{ 1, "high", NULL },
{ 2, "low", NULL },
{ 0, NULL, NULL }
};
static info_lkp_t mge_emergency_stop[] = {
{ 1, "Emergency stop!", NULL },
{ 0, NULL, NULL }
};
static info_lkp_t mge_wiring_fault[] = {
{ 1, "Wiring fault!", NULL },
{ 0, NULL, NULL }
};
static info_lkp_t mge_config_failure[] = {
{ 1, "Fatal EEPROM fault!", NULL },
{ 0, NULL, NULL }
};
static info_lkp_t mge_inverter_volthi[] = {
{ 1, "Inverter AC voltage too high!", NULL },
{ 0, NULL, NULL }
};
static info_lkp_t mge_inverter_voltlo[] = {
{ 1, "Inverter AC voltage too low!", NULL },
{ 0, NULL, NULL }
};
static info_lkp_t mge_short_circuit[] = {
{ 1, "Output short circuit!", NULL },
{ 0, NULL, NULL }
};
info_lkp_t mge_onbatt_info[] = {
{ 1, "!online", NULL },
{ 0, "online", NULL },
{ 0, NULL, NULL }
};
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/* allow limiting to ups.model = Protection Station, Ellipse Eco
* and 3S (US 750 and AUS 700 only!) */
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static const char *eaton_check_pegasus_fun(double value)
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{
switch (mge_type & 0xFF00) /* Ignore model byte */
{
case MGE_PEGASUS:
break;
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case MGE_3S:
/* Only consider non European models */
if (country_code != COUNTRY_EUROPE)
break;
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default:
return NULL;
}
snprintf(mge_scratch_buf, sizeof(mge_scratch_buf), "%.0f", value);
return mge_scratch_buf;
}
static info_lkp_t pegasus_threshold_info[] = {
{ 10, "10", eaton_check_pegasus_fun },
{ 25, "25", eaton_check_pegasus_fun },
{ 60, "60", eaton_check_pegasus_fun },
{ 0, NULL, NULL }
};
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/* allow limiting standard yes/no info (here, to enable ECO mode) to
* ups.model = Protection Station, Ellipse Eco and 3S (US 750 and AUS 700 only!)
* this allows to enable special flags used in hid_info_t entries (Ie RW) */
static const char *pegasus_yes_no_info_fun(double value)
{
switch (mge_type & 0xFF00) /* Ignore model byte */
{
case MGE_PEGASUS:
break;
case MGE_3S:
/* Only consider non European models */
if (country_code != COUNTRY_EUROPE)
break;
default:
return NULL;
}
return (value == 0) ? "no" : "yes";
}
/* Conversion back of yes/no info */
static double pegasus_yes_no_info_nuf(const char *value)
{
switch (mge_type & 0xFF00) /* Ignore model byte */
{
case MGE_PEGASUS:
break;
case MGE_3S:
/* Only consider non European models */
if (country_code != COUNTRY_EUROPE)
break;
default:
return 0;
}
if (!strncmp(value, "yes", 3))
return 1;
else
return 0;
}
info_lkp_t pegasus_yes_no_info[] = {
{ 0, "no", pegasus_yes_no_info_fun, pegasus_yes_no_info_nuf },
{ 1, "yes", pegasus_yes_no_info_fun, pegasus_yes_no_info_nuf },
{ 0, NULL, NULL }
};
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/* Determine country using UPS.PowerSummary.Country.
* If not present:
* if PowerConverter.Output.Voltage >= 200 => "Europe"
* else default to "US" */
static const char *eaton_check_country_fun(double value)
{
country_code = value;
/* Return NULL, not to get the value published! */
return NULL;
}
static info_lkp_t eaton_check_country_info[] = {
{ 0, "dummy", eaton_check_country_fun },
{ 0, NULL, NULL }
};
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/* Limit nominal output voltage according to HV or LV models */
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static const char *nominal_output_voltage_fun(double value)
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{
static long nominal = -1;
if (nominal < 0) {
nominal = value;
}
switch ((long)nominal)
{
/* LV models */
case 100:
case 110:
case 120:
case 127:
switch ((long)value)
{
case 100:
case 110:
case 120:
case 127:
break;
default:
return NULL;
}
break;
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/* line-interactive and online support 200/208 and 220/230/240*/
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/* HV models */
/* 208V */
case 200:
case 208:
switch ((long)value)
{
case 200:
case 208:
break;
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/* 230V */
case 220:
case 230:
case 240:
if ((mge_type & 0xFF00) >= MGE_DEFAULT)
break;
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default:
return NULL;
}
break;
/* HV models */
/* 230V */
case 220:
case 230:
case 240:
switch ((long)value)
{
2011-09-29 18:14:46 +00:00
case 200:
case 208:
/* line-interactive and online also support 200 / 208 V
* So break on offline models */
if ((mge_type & 0xFF00) < MGE_DEFAULT)
return NULL;
/* FIXME: Some European models ("5130 RT 3000") also
* support both HV values */
if (country_code == COUNTRY_EUROPE_208)
break;
2010-03-25 23:20:59 +00:00
case 220:
case 230:
case 240:
break;
default:
return NULL;
}
break;
default:
upsdebugx(3, "%s: can't autodetect settable voltages from %g", __func__, value);
}
snprintf(mge_scratch_buf, sizeof(mge_scratch_buf), "%.0f", value);
return mge_scratch_buf;
}
static info_lkp_t nominal_output_voltage_info[] = {
2011-09-29 18:14:46 +00:00
/* line-interactive, starting with Evolution, support both HV values */
2010-03-25 23:20:59 +00:00
/* HV models */
/* 208V */
{ 200, "200", nominal_output_voltage_fun },
{ 208, "208", nominal_output_voltage_fun },
/* HV models */
/* 230V */
{ 220, "220", nominal_output_voltage_fun },
{ 230, "230", nominal_output_voltage_fun },
{ 240, "240", nominal_output_voltage_fun },
/* LV models */
{ 100, "100", nominal_output_voltage_fun },
{ 110, "110", nominal_output_voltage_fun },
{ 120, "120", nominal_output_voltage_fun },
{ 127, "127", nominal_output_voltage_fun },
{ 0, NULL, NULL }
};
/* --------------------------------------------------------------- */
/* Vendor-specific usage table */
/* --------------------------------------------------------------- */
2012-06-01 13:55:19 +00:00
/* Eaton / MGE HID usage table */
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static usage_lkp_t mge_usage_lkp[] = {
{ "Undefined", 0xffff0000 },
{ "STS", 0xffff0001 },
{ "Environment", 0xffff0002 },
{ "Statistic", 0xffff0003 },
{ "StatisticSystem", 0xffff0004 },
/* 0xffff0005-0xffff000f => Reserved */
{ "Phase", 0xffff0010 },
{ "PhaseID", 0xffff0011 },
{ "Chopper", 0xffff0012 },
{ "ChopperID", 0xffff0013 },
{ "Inverter", 0xffff0014 },
{ "InverterID", 0xffff0015 },
{ "Rectifier", 0xffff0016 },
{ "RectifierID", 0xffff0017 },
{ "LCMSystem", 0xffff0018 },
{ "LCMSystemID", 0xffff0019 },
{ "LCMAlarm", 0xffff001a },
{ "LCMAlarmID", 0xffff001b },
{ "HistorySystem", 0xffff001c },
{ "HistorySystemID", 0xffff001d },
{ "Event", 0xffff001e },
{ "EventID", 0xffff001f },
{ "CircuitBreaker", 0xffff0020 },
{ "TransferForbidden", 0xffff0021 },
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{ "OverallAlarm", 0xffff0022 }, /* renamed to Alarm in Eaton SW! */
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{ "Dephasing", 0xffff0023 },
{ "BypassBreaker", 0xffff0024 },
{ "PowerModule", 0xffff0025 },
{ "PowerRate", 0xffff0026 },
{ "PowerSource", 0xffff0027 },
{ "CurrentPowerSource", 0xffff0028 },
{ "RedundancyLevel", 0xffff0029 },
{ "RedundancyLost", 0xffff002a },
{ "NotificationStatus", 0xffff002b },
{ "ProtectionLost", 0xffff002c },
{ "ConfigurationFailure", 0xffff002d },
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{ "CompatibilityFailure", 0xffff002e },
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/* 0xffff002e-0xffff003f => Reserved */
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{ "SwitchType", 0xffff0040 }, /* renamed to Type in Eaton SW! */
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{ "ConverterType", 0xffff0041 },
{ "FrequencyConverterMode", 0xffff0042 },
{ "AutomaticRestart", 0xffff0043 },
{ "ForcedReboot", 0xffff0044 },
{ "TestPeriod", 0xffff0045 },
{ "EnergySaving", 0xffff0046 },
{ "StartOnBattery", 0xffff0047 },
{ "Schedule", 0xffff0048 },
{ "DeepDischargeProtection", 0xffff0049 },
{ "ShortCircuit", 0xffff004a },
{ "ExtendedVoltageMode", 0xffff004b },
{ "SensitivityMode", 0xffff004c },
{ "RemainingCapacityLimitSetting", 0xffff004d },
{ "ExtendedFrequencyMode", 0xffff004e },
{ "FrequencyConverterModeSetting", 0xffff004f },
{ "LowVoltageBoostTransfer", 0xffff0050 },
{ "HighVoltageBoostTransfer", 0xffff0051 },
{ "LowVoltageBuckTransfer", 0xffff0052 },
{ "HighVoltageBuckTransfer", 0xffff0053 },
{ "OverloadTransferEnable", 0xffff0054 },
{ "OutOfToleranceTransferEnable", 0xffff0055 },
{ "ForcedTransferEnable", 0xffff0056 },
{ "LowVoltageBypassTransfer", 0xffff0057 },
{ "HighVoltageBypassTransfer", 0xffff0058 },
{ "FrequencyRangeBypassTransfer", 0xffff0059 },
{ "LowVoltageEcoTransfer", 0xffff005a },
{ "HighVoltageEcoTransfer", 0xffff005b },
{ "FrequencyRangeEcoTransfer", 0xffff005c },
{ "ShutdownTimer", 0xffff005d },
{ "StartupTimer", 0xffff005e },
{ "RestartLevel", 0xffff005f },
{ "PhaseOutOfRange", 0xffff0060 },
{ "CurrentLimitation", 0xffff0061 },
{ "ThermalOverload", 0xffff0062 },
{ "SynchroSource", 0xffff0063 },
{ "FuseFault", 0xffff0064 },
{ "ExternalProtectedTransfert", 0xffff0065 },
{ "ExternalForcedTransfert", 0xffff0066 },
{ "Compensation", 0xffff0067 },
{ "EmergencyStop", 0xffff0068 },
{ "PowerFactor", 0xffff0069 },
{ "PeakFactor", 0xffff006a },
{ "ChargerType", 0xffff006b },
{ "HighPositiveDCBusVoltage", 0xffff006c },
{ "LowPositiveDCBusVoltage", 0xffff006d },
{ "HighNegativeDCBusVoltage", 0xffff006e },
{ "LowNegativeDCBusVoltage", 0xffff006f },
{ "FrequencyRangeTransfer", 0xffff0070 },
{ "WiringFaultDetection", 0xffff0071 },
{ "ControlStandby", 0xffff0072 },
{ "ShortCircuitTolerance", 0xffff0073 },
{ "VoltageTooHigh", 0xffff0074 },
{ "VoltageTooLow", 0xffff0075 },
{ "DCBusUnbalanced", 0xffff0076 },
{ "FanFailure", 0xffff0077 },
{ "WiringFault", 0xffff0078 },
{ "Floating", 0xffff0079 },
{ "OverCurrent", 0xffff007a },
{ "RemainingActivePower", 0xffff007b },
{ "Energy", 0xffff007c },
{ "Threshold", 0xffff007d },
{ "OverThreshold", 0xffff007e },
/* 0xffff007f => Reserved */
{ "Sensor", 0xffff0080 },
{ "LowHumidity", 0xffff0081 },
{ "HighHumidity", 0xffff0082 },
{ "LowTemperature", 0xffff0083 },
{ "HighTemperature", 0xffff0084 },
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{ "ECOControl", 0xffff0085 },
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{ "Efficiency", 0xffff0086 },
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{ "ABMEnable", 0xffff0087 },
{ "NegativeCurrent", 0xffff0088 },
{ "AutomaticStart", 0xffff0089 },
/* 0xffff008a-0xffff008f => Reserved */
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{ "Count", 0xffff0090 },
{ "Timer", 0xffff0091 },
{ "Interval", 0xffff0092 },
{ "TimerExpired", 0xffff0093 },
{ "Mode", 0xffff0094 },
{ "Country", 0xffff0095 },
{ "State", 0xffff0096 },
{ "Time", 0xffff0097 },
{ "Code", 0xffff0098 },
{ "DataValid", 0xffff0099 },
{ "ToggleTimer", 0xffff009a },
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{ "BypassTransferDelay", 0xffff009b },
{ "HysteresysVoltageTransfer", 0xffff009c },
{ "SlewRate", 0xffff009d },
/* 0xffff009e-0xffff009f => Reserved */
{ "PDU", 0xffff00a0 },
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{ "Breaker", 0xffff00a1 },
{ "BreakerID", 0xffff00a2 },
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{ "OverVoltage", 0xffff00a3 },
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{ "Tripped", 0xffff00a4 },
{ "OverEnergy", 0xffff00a5 },
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{ "OverHumidity", 0xffff00a6 },
{ "ConfigurationReset", 0xffff00a7 }, /* renamed from LCDControl in Eaton SW! */
{ "Level", 0xffff00a8 },
{ "PDUType", 0xffff00a9 },
{ "ReactivePower", 0xffff00aa },
{ "Pole", 0xffff00ab },
{ "PoleID", 0xffff00ac },
{ "Reset", 0xffff00ad },
{ "WatchdogReset", 0xffff00ae },
/* 0xffff00af-0xffff00df => Reserved */
2010-03-25 23:20:59 +00:00
{ "COPIBridge", 0xffff00e0 },
/* 0xffff00e1-0xffff00ef => Reserved */
{ "iModel", 0xffff00f0 },
{ "iVersion", 0xffff00f1 },
{ "iTechnicalLevel", 0xffff00f2 },
{ "iPartNumber", 0xffff00f3 },
{ "iReferenceNumber", 0xffff00f4 },
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{ "iGang", 0xffff00f5 },
/* 0xffff00f6-0xffff00ff => Reserved */
2010-03-25 23:20:59 +00:00
/* end of table */
{ NULL, 0 }
};
static usage_tables_t mge_utab[] = {
mge_usage_lkp,
hid_usage_lkp,
NULL,
};
/* --------------------------------------------------------------- */
/* Model Name formating entries */
/* --------------------------------------------------------------- */
typedef struct {
const char *iProduct;
const char *iModel;
models_type_t type; /* enumerated model type */
const char *name; /* optional (defaults to "<iProduct> <iModel>" if NULL) */
} models_name_t;
/*
* Do not remove models from this list, but instead comment them
* out if not needed. This allows us to quickly add overrides for
* specific models only, should this be needed.
*/
static models_name_t mge_model_names [] =
{
/* Ellipse models */
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{ "ELLIPSE", "300", MGE_DEFAULT_OFFLINE, "ellipse 300" },
{ "ELLIPSE", "500", MGE_DEFAULT_OFFLINE, "ellipse 500" },
{ "ELLIPSE", "650", MGE_DEFAULT_OFFLINE, "ellipse 650" },
{ "ELLIPSE", "800", MGE_DEFAULT_OFFLINE, "ellipse 800" },
{ "ELLIPSE", "1200", MGE_DEFAULT_OFFLINE, "ellipse 1200" },
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/* Ellipse Premium models */
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{ "ellipse", "PR500", MGE_DEFAULT_OFFLINE, "ellipse premium 500" },
{ "ellipse", "PR650", MGE_DEFAULT_OFFLINE, "ellipse premium 650" },
{ "ellipse", "PR800", MGE_DEFAULT_OFFLINE, "ellipse premium 800" },
{ "ellipse", "PR1200", MGE_DEFAULT_OFFLINE, "ellipse premium 1200" },
2010-03-25 23:20:59 +00:00
/* Ellipse "Pro" */
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{ "ELLIPSE", "600", MGE_DEFAULT_OFFLINE, "Ellipse 600" },
{ "ELLIPSE", "750", MGE_DEFAULT_OFFLINE, "Ellipse 750" },
{ "ELLIPSE", "1000", MGE_DEFAULT_OFFLINE, "Ellipse 1000" },
{ "ELLIPSE", "1500", MGE_DEFAULT_OFFLINE, "Ellipse 1500" },
2010-03-25 23:20:59 +00:00
2011-09-29 18:14:46 +00:00
/* Ellipse MAX */
{ "Ellipse MAX", "600", MGE_DEFAULT_OFFLINE, NULL },
{ "Ellipse MAX", "850", MGE_DEFAULT_OFFLINE, NULL },
{ "Ellipse MAX", "1100", MGE_DEFAULT_OFFLINE, NULL },
{ "Ellipse MAX", "1500", MGE_DEFAULT_OFFLINE, NULL },
2010-03-25 23:20:59 +00:00
/* Protection Center */
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{ "PROTECTIONCENTER", "420", MGE_DEFAULT_OFFLINE, "Protection Center 420" },
{ "PROTECTIONCENTER", "500", MGE_DEFAULT_OFFLINE, "Protection Center 500" },
{ "PROTECTIONCENTER", "675", MGE_DEFAULT_OFFLINE, "Protection Center 675" },
2010-03-25 23:20:59 +00:00
2011-06-01 20:31:49 +00:00
/* Protection Station, supports Eco control */
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{ "Protection Station", "500", MGE_PEGASUS, NULL },
{ "Protection Station", "650", MGE_PEGASUS, NULL },
{ "Protection Station", "800", MGE_PEGASUS, NULL },
2011-06-01 20:31:49 +00:00
/* Ellipse ECO, also supports Eco control */
{ "Ellipse ECO", "650", MGE_PEGASUS, NULL },
{ "Ellipse ECO", "800", MGE_PEGASUS, NULL },
{ "Ellipse ECO", "1200", MGE_PEGASUS, NULL },
{ "Ellipse ECO", "1600", MGE_PEGASUS, NULL },
2011-09-29 18:14:46 +00:00
/* 3S, also supports Eco control on some models (AUS 700 and US 750)*/
{ "3S", "450", MGE_DEFAULT_OFFLINE, NULL }, /* US only */
{ "3S", "550", MGE_DEFAULT_OFFLINE, NULL }, /* US 120V + EU 230V + AUS 240V */
{ "3S", "700", MGE_3S, NULL }, /* EU 230V + AUS 240V (w/ eco control) */
{ "3S", "750", MGE_3S, NULL }, /* US 120V (w/ eco control) */
2010-03-25 23:20:59 +00:00
/* Evolution models */
{ "Evolution", "500", MGE_DEFAULT, "Pulsar Evolution 500" },
{ "Evolution", "800", MGE_DEFAULT, "Pulsar Evolution 800" },
{ "Evolution", "1100", MGE_DEFAULT, "Pulsar Evolution 1100" },
{ "Evolution", "1500", MGE_DEFAULT, "Pulsar Evolution 1500" },
{ "Evolution", "2200", MGE_DEFAULT, "Pulsar Evolution 2200" },
{ "Evolution", "3000", MGE_DEFAULT, "Pulsar Evolution 3000" },
{ "Evolution", "3000XL", MGE_DEFAULT, "Pulsar Evolution 3000 XL" },
/* Newer Evolution models */
{ "Evolution", "650", MGE_EVOLUTION_650, NULL },
{ "Evolution", "850", MGE_EVOLUTION_850, NULL },
{ "Evolution", "1150", MGE_EVOLUTION_1150, NULL },
{ "Evolution", "S 1250", MGE_EVOLUTION_S_1250, NULL },
{ "Evolution", "1550", MGE_EVOLUTION_1550, NULL },
{ "Evolution", "S 1750", MGE_EVOLUTION_S_1750, NULL },
{ "Evolution", "2000", MGE_EVOLUTION_2000, NULL },
{ "Evolution", "S 2500", MGE_EVOLUTION_S_2500, NULL },
{ "Evolution", "S 3000", MGE_EVOLUTION_S_3000, NULL },
2014-04-22 18:39:47 +00:00
/* Eaton 5P */
{ "Eaton 5P", "650", EATON_5P, "5P 650" },
{ "Eaton 5P", "850", EATON_5P, "5P 850" },
{ "Eaton 5P", "1150", EATON_5P, "5P 1150" },
{ "Eaton 5P", "1550", EATON_5P, "5P 1550" },
2010-03-25 23:20:59 +00:00
/* Pulsar M models */
{ "PULSAR M", "2200", MGE_PULSAR_M_2200, NULL },
{ "PULSAR M", "3000", MGE_PULSAR_M_3000, NULL },
{ "PULSAR M", "3000 XL", MGE_PULSAR_M_3000_XL, NULL },
/* Eaton'ified names */
{ "EX", "2200", MGE_PULSAR_M_2200, NULL },
{ "EX", "3000", MGE_PULSAR_M_3000, NULL },
{ "EX", "3000 XL", MGE_PULSAR_M_3000, NULL },
/* Pulsar models (TBR) */
/* { "Pulsar", "700", MGE_DEFAULT, NULL }, */
/* { "Pulsar", "1000", MGE_DEFAULT, NULL }, */
/* { "Pulsar", "1500", MGE_DEFAULT, NULL }, */
/* { "Pulsar", "1000 RT2U", MGE_DEFAULT, NULL }, */
/* { "Pulsar", "1500 RT2U", MGE_DEFAULT, NULL }, */
/* Eaton'ified names (TBR) */
/* { "EX", "700", MGE_DEFAULT, NULL }, */
/* { "EX", "1000", MGE_DEFAULT, NULL }, */
/* { "EX", "1500", MGE_DEFAULT, NULL }, */
/* { "EX", "1000 RT2U", MGE_DEFAULT, NULL }, */
/* { "EX", "1500 RT2U", MGE_DEFAULT, NULL }, */
/* Pulsar MX models */
{ "PULSAR", "MX4000", MGE_DEFAULT, "Pulsar MX 4000 RT" },
{ "PULSAR", "MX5000", MGE_DEFAULT, "Pulsar MX 5000 RT" },
/* NOVA models */
{ "NOVA AVR", "500", MGE_DEFAULT, "Nova 500 AVR" },
{ "NOVA AVR", "600", MGE_DEFAULT, "Nova 600 AVR" },
{ "NOVA AVR", "625", MGE_DEFAULT, "Nova 625 AVR" },
{ "NOVA AVR", "1100", MGE_DEFAULT, "Nova 1100 AVR" },
{ "NOVA AVR", "1250", MGE_DEFAULT, "Nova 1250 AVR" },
/* EXtreme C (EMEA) */
{ "EXtreme", "700C", MGE_DEFAULT, "Pulsar EXtreme 700C" },
{ "EXtreme", "1000C", MGE_DEFAULT, "Pulsar EXtreme 1000C" },
{ "EXtreme", "1500C", MGE_DEFAULT, "Pulsar EXtreme 1500C" },
{ "EXtreme", "1500CCLA", MGE_DEFAULT, "Pulsar EXtreme 1500C CLA" },
{ "EXtreme", "2200C", MGE_DEFAULT, "Pulsar EXtreme 2200C" },
{ "EXtreme", "3200C", MGE_DEFAULT, "Pulsar EXtreme 3200C" },
/* EXtreme C (USA, aka "EX RT") */
{ "EX", "700RT", MGE_DEFAULT, "Pulsar EX 700 RT" },
{ "EX", "1000RT", MGE_DEFAULT, "Pulsar EX 1000 RT" },
{ "EX", "1500RT", MGE_DEFAULT, "Pulsar EX 1500 RT" },
{ "EX", "2200RT", MGE_DEFAULT, "Pulsar EX 2200 RT" },
{ "EX", "3200RT", MGE_DEFAULT, "Pulsar EX 3200 RT" },
/* Comet EX RT three phased */
{ "EX", "5RT31", MGE_DEFAULT, "EX 5 RT 3:1" },
{ "EX", "7RT31", MGE_DEFAULT, "EX 7 RT 3:1" },
{ "EX", "11RT31", MGE_DEFAULT, "EX 11 RT 3:1" },
/* Comet EX RT mono phased */
{ "EX", "5RT", MGE_DEFAULT, "EX 5 RT" },
{ "EX", "7RT", MGE_DEFAULT, "EX 7 RT" },
{ "EX", "11RT", MGE_DEFAULT, "EX 11 RT" },
/* Galaxy 3000 */
{ "GALAXY", "3000_10", MGE_DEFAULT, "Galaxy 3000 10 kVA" },
{ "GALAXY", "3000_15", MGE_DEFAULT, "Galaxy 3000 15 kVA" },
{ "GALAXY", "3000_20", MGE_DEFAULT, "Galaxy 3000 20 kVA" },
{ "GALAXY", "3000_30", MGE_DEFAULT, "Galaxy 3000 30 kVA" },
/* end of structure. */
{ NULL }
};
/* --------------------------------------------------------------- */
/* Data lookup table (HID <-> NUT) */
/* --------------------------------------------------------------- */
static hid_info_t mge_hid2nut[] =
{
2011-09-29 18:14:46 +00:00
/* Device collection */
/* Just declared to call *hid2info */
{ "device.country", ST_FLAG_STRING, 20, "UPS.PowerSummary.Country", NULL, "Europe", HU_FLAG_STATIC, eaton_check_country_info },
2010-03-25 23:20:59 +00:00
/* Battery page */
{ "battery.charge", 0, 0, "UPS.PowerSummary.RemainingCapacity", NULL, "%.0f", 0, NULL },
{ "battery.charge.low", ST_FLAG_RW | ST_FLAG_STRING, 5, "UPS.PowerSummary.RemainingCapacityLimitSetting", NULL, "%.0f", HU_FLAG_SEMI_STATIC, NULL },
{ "battery.charge.low", 0, 0, "UPS.PowerSummary.RemainingCapacityLimit", NULL, "%.0f", HU_FLAG_STATIC , NULL }, /* Read only */
{ "battery.charge.restart", ST_FLAG_RW | ST_FLAG_STRING, 3, "UPS.PowerSummary.RestartLevel", NULL, "%.0f", HU_FLAG_SEMI_STATIC, NULL },
{ "battery.capacity", 0, 0, "UPS.BatterySystem.Battery.DesignCapacity", NULL, "%s", HU_FLAG_STATIC, mge_battery_capacity }, /* conversion needed from As to Ah */
{ "battery.runtime", 0, 0, "UPS.PowerSummary.RunTimeToEmpty", NULL, "%.0f", 0, NULL },
2011-06-01 20:31:49 +00:00
{ "battery.runtime.low", ST_FLAG_RW | ST_FLAG_STRING, 10, "UPS.PowerSummary.RemainingTimeLimit", NULL, "%.0f", 0, NULL },
2010-03-25 23:20:59 +00:00
{ "battery.runtime.elapsed", 0, 0, "UPS.StatisticSystem.Input.[1].Statistic.[1].Time", NULL, "%.0f", HU_FLAG_QUICK_POLL, NULL },
2011-09-29 18:14:46 +00:00
{ "battery.runtime.low", ST_FLAG_RW | ST_FLAG_STRING, 10, "UPS.PowerSummary.RemainingTimeLimit", NULL, "%.0f", 0, NULL },
2011-01-26 09:35:08 +00:00
{ "battery.temperature", 0, 0, "UPS.BatterySystem.Battery.Temperature", NULL, "%s", 0, kelvin_celsius_conversion },
2010-03-25 23:20:59 +00:00
{ "battery.type", 0, 0, "UPS.PowerSummary.iDeviceChemistry", NULL, "%s", HU_FLAG_STATIC, stringid_conversion },
{ "battery.voltage", 0, 0, "UPS.BatterySystem.Voltage", NULL, "%.1f", 0, NULL },
{ "battery.voltage", 0, 0, "UPS.PowerSummary.Voltage", NULL, "%s", 0, mge_battery_voltage },
{ "battery.voltage.nominal", 0, 0, "UPS.BatterySystem.ConfigVoltage", NULL, "%.0f", HU_FLAG_STATIC, NULL },
{ "battery.voltage.nominal", 0, 0, "UPS.PowerSummary.ConfigVoltage", NULL, "%s", HU_FLAG_STATIC, mge_battery_voltage_nominal },
{ "battery.protection", ST_FLAG_RW | ST_FLAG_STRING, 5, "UPS.BatterySystem.Battery.DeepDischargeProtection", NULL, "%s", HU_FLAG_SEMI_STATIC, yes_no_info },
{ "battery.energysave", ST_FLAG_RW | ST_FLAG_STRING, 5, "UPS.PowerConverter.Input.[3].EnergySaving", NULL, "%s", HU_FLAG_SEMI_STATIC, yes_no_info },
2015-04-30 13:53:36 +00:00
{ "battery.energysave.load", ST_FLAG_RW | ST_FLAG_STRING, 5, "UPS.PowerConverter.Input.[3].ConfigPercentLoad", NULL, "%.0f", HU_FLAG_SEMI_STATIC, NULL },
/* Current implementation */
{ "battery.energysave.delay", ST_FLAG_RW | ST_FLAG_STRING, 5, "UPS.PowerConverter.Input.[3].EnergySaving.ShutdownTimer", NULL, "%.0f", HU_FLAG_SEMI_STATIC, NULL },
/* Newer implementation */
{ "battery.energysave.delay", ST_FLAG_RW | ST_FLAG_STRING, 5, "UPS.PowerConverter.Input.[3].ShutdownTimer", NULL, "%.0f", HU_FLAG_SEMI_STATIC, NULL },
{ "battery.energysave.realpower", ST_FLAG_RW | ST_FLAG_STRING, 5, "UPS.PowerConverter.Input.[3].ConfigActivePower", NULL, "%.0f", HU_FLAG_SEMI_STATIC, NULL },
/* ABM (Advanced Battery Monitoring) processing
* Must be processed before the BOOL status */
/* Not published, just to store in internal var. advanced_battery_monitoring */
{ "battery.charger.status", 0, 0, "UPS.BatterySystem.Charger.ABMEnable", NULL, "%.0f", HU_FLAG_QUICK_POLL, eaton_abm_enabled_info },
/* Same as the one above, but for legacy units */
/* Refer to Note 1 (This point will need more clarification!)
{ "battery.charger.status", 0, 0, "UPS.BatterySystem.Charger.PresentStatus.Used", NULL, "%.0f", HU_FLAG_QUICK_POLL, eaton_abm_enabled_legacy_info }, */
/* This data is the actual ABM status information */
{ "battery.charger.status", 0, 0, "UPS.BatterySystem.Charger.Mode", NULL, "%.0f", HU_FLAG_QUICK_POLL, eaton_abm_status_info },
2010-03-25 23:20:59 +00:00
/* UPS page */
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{ "ups.efficiency", 0, 0, "UPS.PowerConverter.Output.Efficiency", NULL, "%.0f", 0, NULL },
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{ "ups.firmware", 0, 0, "UPS.PowerSummary.iVersion", NULL, "%s", HU_FLAG_STATIC, stringid_conversion },
{ "ups.load", 0, 0, "UPS.PowerSummary.PercentLoad", NULL, "%.0f", 0, NULL },
{ "ups.load.high", ST_FLAG_RW | ST_FLAG_STRING, 5, "UPS.Flow.[4].ConfigPercentLoad", NULL, "%.0f", HU_FLAG_SEMI_STATIC, NULL },
{ "ups.delay.start", ST_FLAG_RW | ST_FLAG_STRING, 10, "UPS.PowerSummary.DelayBeforeStartup", NULL, DEFAULT_ONDELAY, HU_FLAG_ABSENT, NULL},
{ "ups.delay.shutdown", ST_FLAG_RW | ST_FLAG_STRING, 10, "UPS.PowerSummary.DelayBeforeShutdown", NULL, DEFAULT_OFFDELAY, HU_FLAG_ABSENT, NULL},
{ "ups.timer.start", 0, 0, "UPS.PowerSummary.DelayBeforeStartup", NULL, "%.0f", HU_FLAG_QUICK_POLL, NULL},
{ "ups.timer.shutdown", 0, 0, "UPS.PowerSummary.DelayBeforeShutdown", NULL, "%.0f", HU_FLAG_QUICK_POLL, NULL},
{ "ups.timer.reboot", 0, 0, "UPS.PowerSummary.DelayBeforeReboot", NULL, "%.0f", HU_FLAG_QUICK_POLL, NULL},
2011-01-26 09:35:08 +00:00
{ "ups.test.result", 0, 0, "UPS.BatterySystem.Battery.Test", NULL, "%s", 0, test_read_info },
2010-03-25 23:20:59 +00:00
{ "ups.test.interval", ST_FLAG_RW | ST_FLAG_STRING, 8, "UPS.BatterySystem.Battery.TestPeriod", NULL, "%.0f", HU_FLAG_SEMI_STATIC, NULL },
{ "ups.beeper.status", 0 ,0, "UPS.PowerSummary.AudibleAlarmControl", NULL, "%s", HU_FLAG_SEMI_STATIC, beeper_info },
2011-01-26 09:35:08 +00:00
{ "ups.temperature", 0, 0, "UPS.PowerSummary.Temperature", NULL, "%s", 0, kelvin_celsius_conversion },
2010-03-25 23:20:59 +00:00
{ "ups.power", 0, 0, "UPS.PowerConverter.Output.ApparentPower", NULL, "%.0f", 0, NULL },
{ "ups.L1.power", 0, 0, "UPS.PowerConverter.Output.Phase.[1].ApparentPower", NULL, "%.0f", 0, NULL },
{ "ups.L2.power", 0, 0, "UPS.PowerConverter.Output.Phase.[2].ApparentPower", NULL, "%.0f", 0, NULL },
{ "ups.L3.power", 0, 0, "UPS.PowerConverter.Output.Phase.[3].ApparentPower", NULL, "%.0f", 0, NULL },
{ "ups.power.nominal", 0, 0, "UPS.Flow.[4].ConfigApparentPower", NULL, "%.0f", HU_FLAG_STATIC, NULL },
{ "ups.realpower", 0, 0, "UPS.PowerConverter.Output.ActivePower", NULL, "%.0f", 0, NULL },
{ "ups.L1.realpower", 0, 0, "UPS.PowerConverter.Output.Phase.[1].ActivePower", NULL, "%.0f", 0, NULL },
{ "ups.L2.realpower", 0, 0, "UPS.PowerConverter.Output.Phase.[2].ActivePower", NULL, "%.0f", 0, NULL },
{ "ups.L3.realpower", 0, 0, "UPS.PowerConverter.Output.Phase.[3].ActivePower", NULL, "%.0f", 0, NULL },
{ "ups.realpower.nominal", 0, 0, "UPS.Flow.[4].ConfigActivePower", NULL, "%.0f", HU_FLAG_STATIC, NULL },
{ "ups.start.auto", ST_FLAG_RW | ST_FLAG_STRING, 5, "UPS.PowerConverter.Input.[1].AutomaticRestart", NULL, "%s", HU_FLAG_SEMI_STATIC, yes_no_info },
{ "ups.start.battery", ST_FLAG_RW | ST_FLAG_STRING, 5, "UPS.PowerConverter.Input.[3].StartOnBattery", NULL, "%s", HU_FLAG_SEMI_STATIC, yes_no_info },
{ "ups.start.reboot", ST_FLAG_RW | ST_FLAG_STRING, 5, "UPS.PowerConverter.Output.ForcedReboot", NULL, "%s", HU_FLAG_SEMI_STATIC, yes_no_info },
2013-11-24 15:00:12 +00:00
{ "ups.shutdown", ST_FLAG_RW | ST_FLAG_STRING, 10, "UPS.PowerSummary.PresentStatus.Switchable", NULL, "%s", HU_FLAG_SEMI_STATIC | HU_FLAG_ENUM, eaton_enable_disable_info },
2010-03-25 23:20:59 +00:00
#ifdef HAVE_STRPTIME
{ "ups.date", ST_FLAG_RW | ST_FLAG_STRING, 10, "UPS.PowerSummary.Time", NULL, "%s", 0, mge_date_conversion },
{ "ups.time", ST_FLAG_RW | ST_FLAG_STRING, 10, "UPS.PowerSummary.Time", NULL, "%s", 0, mge_time_conversion },
#else
{ "ups.date", 0, 0, "UPS.PowerSummary.Time", NULL, "%s", 0, mge_date_conversion },
{ "ups.time", 0, 0, "UPS.PowerSummary.Time", NULL, "%s", 0, mge_time_conversion },
#endif /* HAVE_STRPTIME */
{ "ups.type", 0, 0, "UPS.PowerConverter.ConverterType", NULL, "%s", HU_FLAG_STATIC, mge_upstype_conversion },
/* Special case: boolean values that are mapped to ups.status and ups.alarm */
{ "BOOL", 0, 0, "UPS.PowerSummary.PresentStatus.ACPresent", NULL, NULL, HU_FLAG_QUICK_POLL, online_info },
{ "BOOL", 0, 0, "UPS.PowerConverter.Input.[3].PresentStatus.Used", NULL, NULL, 0, mge_onbatt_info },
{ "BOOL", 0, 0, "UPS.PowerConverter.Input.[1].PresentStatus.Used", NULL, NULL, 0, online_info },
2015-04-30 13:53:36 +00:00
/* These 2 ones are used when ABM is disabled */
{ "BOOL", 0, 0, "UPS.PowerSummary.PresentStatus.Discharging", NULL, NULL, HU_FLAG_QUICK_POLL, eaton_discharging_info },
{ "BOOL", 0, 0, "UPS.PowerSummary.PresentStatus.Charging", NULL, NULL, HU_FLAG_QUICK_POLL, eaton_charging_info },
/* And this one when ABM is enabled (same as battery.charger.status) */
{ "BOOL", 0, 0, "UPS.BatterySystem.Charger.Mode", NULL, "%.0f", HU_FLAG_QUICK_POLL, eaton_abm_chrg_dischrg_info },
2010-03-25 23:20:59 +00:00
/* FIXME: on Dell, the above requires an "AND" with "UPS.BatterySystem.Charger.Mode = 1" */
{ "BOOL", 0, 0, "UPS.PowerSummary.PresentStatus.BelowRemainingCapacityLimit", NULL, NULL, HU_FLAG_QUICK_POLL, lowbatt_info },
/* Output overload, Level 1 (FIXME: add the level?) */
{ "BOOL", 0, 0, "UPS.PowerConverter.Output.Overload.[1].PresentStatus.OverThreshold", NULL, NULL, 0, overload_info },
/* Output overload, Level 2 (FIXME: add the level?) */
{ "BOOL", 0, 0, "UPS.PowerConverter.Output.Overload.[2].PresentStatus.OverThreshold", NULL, NULL, 0, overload_info },
/* Output overload, Level 3 (FIXME: add the level?) */
{ "BOOL", 0, 0, "UPS.PowerSummary.PresentStatus.Overload", NULL, NULL, 0, overload_info },
{ "BOOL", 0, 0, "UPS.PowerSummary.PresentStatus.NeedReplacement", NULL, NULL, 0, replacebatt_info },
/* FIXME: on Dell, the above requires an "AND" with "UPS.BatterySystem.Battery.Test = 3 " */
2011-09-29 18:14:46 +00:00
{ "BOOL", 0, 0, "UPS.LCMSystem.LCMAlarm.[2].PresentStatus.TimerExpired", NULL, NULL, 0, replacebatt_info },
2010-03-25 23:20:59 +00:00
{ "BOOL", 0, 0, "UPS.PowerConverter.Input.[1].PresentStatus.Buck", NULL, NULL, 0, trim_info },
{ "BOOL", 0, 0, "UPS.PowerConverter.Input.[1].PresentStatus.Boost", NULL, NULL, 0, boost_info },
{ "BOOL", 0, 0, "UPS.PowerConverter.Input.[1].PresentStatus.VoltageOutOfRange", NULL, NULL, 0, vrange_info },
{ "BOOL", 0, 0, "UPS.PowerConverter.Input.[1].PresentStatus.FrequencyOutOfRange", NULL, NULL, 0, frange_info },
{ "BOOL", 0, 0, "UPS.PowerSummary.PresentStatus.Good", NULL, NULL, 0, off_info },
{ "BOOL", 0, 0, "UPS.PowerConverter.Input.[2].PresentStatus.Used", NULL, NULL, 0, bypass_auto_info }, /* Automatic bypass */
{ "BOOL", 0, 0, "UPS.PowerConverter.Input.[4].PresentStatus.Used", NULL, NULL, 0, bypass_manual_info }, /* Manual bypass */
{ "BOOL", 0, 0, "UPS.PowerSummary.PresentStatus.FanFailure", NULL, NULL, 0, fanfail_info },
{ "BOOL", 0, 0, "UPS.BatterySystem.Battery.PresentStatus.Present", NULL, NULL, 0, nobattery_info },
{ "BOOL", 0, 0, "UPS.BatterySystem.Charger.PresentStatus.InternalFailure", NULL, NULL, 0, chargerfail_info },
{ "BOOL", 0, 0, "UPS.BatterySystem.Charger.PresentStatus.VoltageTooHigh", NULL, NULL, 0, battvolthi_info },
{ "BOOL", 0, 0, "UPS.PowerConverter.Input.[1].PresentStatus.VoltageTooHigh", NULL, NULL, 0, battvolthi_info },
/* Battery DC voltage too high! */
{ "BOOL", 0, 0, "UPS.BatterySystem.Battery.PresentStatus.VoltageTooHigh", NULL, NULL, 0, battvolthi_info },
{ "BOOL", 0, 0, "UPS.BatterySystem.Charger.PresentStatus.VoltageTooLow", NULL, NULL, 0, battvoltlo_info },
2011-06-01 20:31:49 +00:00
{ "BOOL", 0, 0, "UPS.PowerConverter.Input.[1].PresentStatus.VoltageTooLow", NULL, NULL, 0, mge_onbatt_info },
2010-03-25 23:20:59 +00:00
{ "BOOL", 0, 0, "UPS.PowerSummary.PresentStatus.InternalFailure", NULL, NULL, 0, commfault_info },
{ "BOOL", 0, 0, "UPS.PowerSummary.PresentStatus.OverTemperature", NULL, NULL, 0, overheat_info },
{ "BOOL", 0, 0, "UPS.PowerSummary.PresentStatus.ShutdownImminent", NULL, NULL, 0, shutdownimm_info },
/* Vendor specific ups.alarm */
{ "ups.alarm", 0, 0, "UPS.PowerSummary.PresentStatus.EmergencyStop", NULL, NULL, 0, mge_emergency_stop },
{ "ups.alarm", 0, 0, "UPS.PowerConverter.Input.[1].PresentStatus.WiringFault", NULL, NULL, 0, mge_wiring_fault },
{ "ups.alarm", 0, 0, "UPS.PowerSummary.PresentStatus.ConfigurationFailure", NULL, NULL, 0, mge_config_failure },
{ "ups.alarm", 0, 0, "UPS.PowerConverter.Inverter.PresentStatus.VoltageTooHigh", NULL, NULL, 0, mge_inverter_volthi },
{ "ups.alarm", 0, 0, "UPS.PowerConverter.Inverter.PresentStatus.VoltageTooLow", NULL, NULL, 0, mge_inverter_voltlo },
{ "ups.alarm", 0, 0, "UPS.PowerConverter.Output.PresentStatus.ShortCircuit", NULL, NULL, 0, mge_short_circuit },
/* Input page */
{ "input.voltage", 0, 0, "UPS.PowerConverter.Input.[1].Voltage", NULL, "%.1f", 0, NULL },
{ "input.L1-N.voltage", 0, 0, "UPS.PowerConverter.Input.[1].Phase.[1].Voltage", NULL, "%.1f", 0, NULL },
{ "input.L2-N.voltage", 0, 0, "UPS.PowerConverter.Input.[1].Phase.[2].Voltage", NULL, "%.1f", 0, NULL },
{ "input.L3-N.voltage", 0, 0, "UPS.PowerConverter.Input.[1].Phase.[3].Voltage", NULL, "%.1f", 0, NULL },
{ "input.L1-L2.voltage", 0, 0, "UPS.PowerConverter.Input.[1].Phase.[12].Voltage", NULL, "%.1f", 0, NULL },
{ "input.L2-L3.voltage", 0, 0, "UPS.PowerConverter.Input.[1].Phase.[23].Voltage", NULL, "%.1f", 0, NULL },
{ "input.L3-L1.voltage", 0, 0, "UPS.PowerConverter.Input.[1].Phase.[31].Voltage", NULL, "%.1f", 0, NULL },
{ "input.voltage.nominal", 0, 0, "UPS.Flow.[1].ConfigVoltage", NULL, "%.0f", HU_FLAG_STATIC, NULL },
{ "input.current", 0, 0, "UPS.PowerConverter.Input.[1].Current", NULL, "%.2f", 0, NULL },
{ "input.L1.current", 0, 0, "UPS.PowerConverter.Input.[1].Phase.[1].Current", NULL, "%.1f", 0, NULL },
{ "input.L2.current", 0, 0, "UPS.PowerConverter.Input.[1].Phase.[2].Current", NULL, "%.1f", 0, NULL },
{ "input.L3.current", 0, 0, "UPS.PowerConverter.Input.[1].Phase.[3].Current", NULL, "%.1f", 0, NULL },
{ "input.current.nominal", 0, 0, "UPS.Flow.[1].ConfigCurrent", NULL, "%.2f", HU_FLAG_STATIC, NULL },
{ "input.frequency", 0, 0, "UPS.PowerConverter.Input.[1].Frequency", NULL, "%.1f", 0, NULL },
{ "input.frequency.nominal", 0, 0, "UPS.Flow.[1].ConfigFrequency", NULL, "%.0f", HU_FLAG_STATIC, NULL },
/* same as "input.transfer.boost.low" */
{ "input.transfer.low", ST_FLAG_RW | ST_FLAG_STRING, 5, "UPS.PowerConverter.Output.LowVoltageTransfer", NULL, "%.0f", HU_FLAG_SEMI_STATIC, NULL },
{ "input.transfer.boost.low", ST_FLAG_RW | ST_FLAG_STRING, 5, "UPS.PowerConverter.Output.LowVoltageBoostTransfer", NULL, "%.0f", HU_FLAG_SEMI_STATIC, NULL },
{ "input.transfer.boost.high", ST_FLAG_RW | ST_FLAG_STRING, 5, "UPS.PowerConverter.Output.HighVoltageBoostTransfer", NULL, "%.0f", HU_FLAG_SEMI_STATIC, NULL },
{ "input.transfer.trim.low", ST_FLAG_RW | ST_FLAG_STRING, 5, "UPS.PowerConverter.Output.LowVoltageBuckTransfer", NULL, "%.0f", HU_FLAG_SEMI_STATIC, NULL },
/* same as "input.transfer.trim.high" */
{ "input.transfer.high", ST_FLAG_RW | ST_FLAG_STRING, 5, "UPS.PowerConverter.Output.HighVoltageTransfer", NULL, "%.0f", HU_FLAG_SEMI_STATIC, NULL },
{ "input.transfer.trim.high", ST_FLAG_RW | ST_FLAG_STRING, 5, "UPS.PowerConverter.Output.HighVoltageBuckTransfer", NULL, "%.0f", HU_FLAG_SEMI_STATIC, NULL },
{ "input.sensitivity", ST_FLAG_RW | ST_FLAG_STRING, 10, "UPS.PowerConverter.Output.SensitivityMode", NULL, "%s", HU_FLAG_SEMI_STATIC, mge_sensitivity_info },
{ "input.voltage.extended", ST_FLAG_RW | ST_FLAG_STRING, 5, "UPS.PowerConverter.Output.ExtendedVoltageMode", NULL, "%s", HU_FLAG_SEMI_STATIC, yes_no_info },
{ "input.frequency.extended", ST_FLAG_RW | ST_FLAG_STRING, 5, "UPS.PowerConverter.Output.ExtendedFrequencyMode", NULL, "%s", HU_FLAG_SEMI_STATIC, yes_no_info },
/* Bypass page */
{ "input.bypass.voltage", 0, 0, "UPS.PowerConverter.Input.[2].Voltage", NULL, "%.1f", 0, NULL },
{ "input.bypass.L1-N.voltage", 0, 0, "UPS.PowerConverter.Input.[2].Phase.[1].Voltage", NULL, "%.1f", 0, NULL },
{ "input.bypass.L2-N.voltage", 0, 0, "UPS.PowerConverter.Input.[2].Phase.[2].Voltage", NULL, "%.1f", 0, NULL },
{ "input.bypass.L3-N.voltage", 0, 0, "UPS.PowerConverter.Input.[2].Phase.[3].Voltage", NULL, "%.1f", 0, NULL },
{ "input.bypass.L1-L2.voltage", 0, 0, "UPS.PowerConverter.Input.[2].Phase.[12].Voltage", NULL, "%.1f", 0, NULL },
{ "input.bypass.L2-L3.voltage", 0, 0, "UPS.PowerConverter.Input.[2].Phase.[23].Voltage", NULL, "%.1f", 0, NULL },
{ "input.bypass.L3-L1.voltage", 0, 0, "UPS.PowerConverter.Input.[2].Phase.[31].Voltage", NULL, "%.1f", 0, NULL },
{ "input.bypass.voltage.nominal", 0, 0, "UPS.Flow.[2].ConfigVoltage", NULL, "%.0f", HU_FLAG_STATIC, NULL },
{ "input.bypass.current", 0, 0, "UPS.PowerConverter.Input.[2].Current", NULL, "%.2f", 0, NULL },
{ "input.bypass.L1.current", 0, 0, "UPS.PowerConverter.Input.[2].Phase.[1].Current", NULL, "%.1f", 0, NULL },
{ "input.bypass.L2.current", 0, 0, "UPS.PowerConverter.Input.[2].Phase.[2].Current", NULL, "%.1f", 0, NULL },
{ "input.bypass.L3.current", 0, 0, "UPS.PowerConverter.Input.[2].Phase.[3].Current", NULL, "%.1f", 0, NULL },
{ "input.bypass.current.nominal", 0, 0, "UPS.Flow.[2].ConfigCurrent", NULL, "%.2f", HU_FLAG_STATIC, NULL },
{ "input.bypass.frequency", 0, 0, "UPS.PowerConverter.Input.[2].Frequency", NULL, "%.1f", 0, NULL },
{ "input.bypass.frequency.nominal", 0, 0, "UPS.Flow.[2].ConfigFrequency", NULL, "%.0f", HU_FLAG_STATIC, NULL },
/* Output page */
{ "output.voltage", 0, 0, "UPS.PowerConverter.Output.Voltage", NULL, "%.1f", 0, NULL },
{ "output.L1-N.voltage", 0, 0, "UPS.PowerConverter.Output.Phase.[1].Voltage", NULL, "%.1f", 0, NULL },
{ "output.L2-N.voltage", 0, 0, "UPS.PowerConverter.Output.Phase.[2].Voltage", NULL, "%.1f", 0, NULL },
{ "output.L3-N.voltage", 0, 0, "UPS.PowerConverter.Output.Phase.[3].Voltage", NULL, "%.1f", 0, NULL },
{ "output.L1-L2.voltage", 0, 0, "UPS.PowerConverter.Output.Phase.[12].Voltage", NULL, "%.1f", 0, NULL },
{ "output.L2-L3.voltage", 0, 0, "UPS.PowerConverter.Output.Phase.[23].Voltage", NULL, "%.1f", 0, NULL },
{ "output.L3-L1.voltage", 0, 0, "UPS.PowerConverter.Output.Phase.[31].Voltage", NULL, "%.1f", 0, NULL },
{ "output.voltage.nominal", ST_FLAG_RW | ST_FLAG_STRING, 3, "UPS.Flow.[4].ConfigVoltage", NULL, "%.0f", HU_FLAG_SEMI_STATIC | HU_FLAG_ENUM, nominal_output_voltage_info },
{ "output.current", 0, 0, "UPS.PowerConverter.Output.Current", NULL, "%.2f", 0, NULL },
{ "output.L1.current", 0, 0, "UPS.PowerConverter.Output.Phase.[1].Current", NULL, "%.1f", 0, NULL },
{ "output.L2.current", 0, 0, "UPS.PowerConverter.Output.Phase.[2].Current", NULL, "%.1f", 0, NULL },
{ "output.L3.current", 0, 0, "UPS.PowerConverter.Output.Phase.[3].Current", NULL, "%.1f", 0, NULL },
{ "output.current.nominal", 0, 0, "UPS.Flow.[4].ConfigCurrent", NULL, "%.2f", 0, NULL },
{ "output.frequency", 0, 0, "UPS.PowerConverter.Output.Frequency", NULL, "%.1f", 0, NULL },
/* FIXME: can be RW (50/60) (or on .nominal)? */
{ "output.frequency.nominal", 0, 0, "UPS.Flow.[4].ConfigFrequency", NULL, "%.0f", HU_FLAG_STATIC, NULL },
{ "output.powerfactor", 0, 0, "UPS.PowerConverter.Output.PowerFactor", NULL, "%s", 0, mge_powerfactor_conversion },
/* Outlet page (using MGE UPS SYSTEMS - PowerShare technology) */
{ "outlet.id", 0, 0, "UPS.OutletSystem.Outlet.[1].OutletID", NULL, "%.0f", HU_FLAG_STATIC, NULL },
{ "outlet.desc", ST_FLAG_RW | ST_FLAG_STRING, 20, "UPS.OutletSystem.Outlet.[1].OutletID", NULL, "Main Outlet", HU_FLAG_ABSENT, NULL },
{ "outlet.switchable", 0, 0, "UPS.OutletSystem.Outlet.[1].PresentStatus.Switchable", NULL, "%s", HU_FLAG_STATIC, yes_no_info },
/* On Protection Station, the line below is the power consumption threshold
* on the master outlet used to automatically power off the slave outlets.
* Values: 10, 25 (default) or 60 VA. */
{ "outlet.power", ST_FLAG_RW | ST_FLAG_STRING, 6, "UPS.OutletSystem.Outlet.[1].ConfigApparentPower", NULL, "%s", HU_FLAG_SEMI_STATIC | HU_FLAG_ENUM, pegasus_threshold_info },
2011-09-29 18:14:46 +00:00
{ "outlet.power", 0, 0, "UPS.OutletSystem.Outlet.[1].ApparentPower", NULL, "%.0f", 0, NULL },
{ "outlet.realpower", 0, 0, "UPS.OutletSystem.Outlet.[1].ActivePower", NULL, "%.0f", 0, NULL },
{ "outlet.current", 0, 0, "UPS.OutletSystem.Outlet.[1].Current", NULL, "%.2f", 0, NULL },
2012-06-01 13:55:19 +00:00
{ "outlet.powerfactor", 0, 0, "UPS.OutletSystem.Outlet.[1].PowerFactor", NULL, "%.2f", 0, NULL }, /* "%s", 0, mge_powerfactor_conversion }, */
2011-09-29 18:14:46 +00:00
/* First outlet */
2010-03-25 23:20:59 +00:00
{ "outlet.1.id", 0, 0, "UPS.OutletSystem.Outlet.[2].OutletID", NULL, "%.0f", HU_FLAG_STATIC, NULL },
{ "outlet.1.desc", ST_FLAG_RW | ST_FLAG_STRING, 20, "UPS.OutletSystem.Outlet.[2].OutletID", NULL, "PowerShare Outlet 1", HU_FLAG_ABSENT, NULL },
{ "outlet.1.switchable", 0, 0, "UPS.OutletSystem.Outlet.[2].PresentStatus.Switchable", NULL, "%s", HU_FLAG_STATIC, yes_no_info },
{ "outlet.1.status", 0, 0, "UPS.OutletSystem.Outlet.[2].PresentStatus.SwitchOn/Off", NULL, "%s", 0, on_off_info },
/* For low end models, with 1 non backup'ed outlet */
{ "outlet.1.status", 0, 0, "UPS.PowerSummary.PresentStatus.ACPresent", NULL, "%s", 0, on_off_info },
2012-06-01 13:55:19 +00:00
/* FIXME: change to outlet.1.battery.charge.low, as in mge-xml.c?! */
2010-03-25 23:20:59 +00:00
{ "outlet.1.autoswitch.charge.low", ST_FLAG_RW | ST_FLAG_STRING, 3, "UPS.OutletSystem.Outlet.[2].RemainingCapacityLimit", NULL, "%.0f", HU_FLAG_SEMI_STATIC, NULL },
{ "outlet.1.delay.shutdown", ST_FLAG_RW | ST_FLAG_STRING, 5, "UPS.OutletSystem.Outlet.[2].ShutdownTimer", NULL, "%.0f", HU_FLAG_SEMI_STATIC, NULL },
{ "outlet.1.delay.start", ST_FLAG_RW | ST_FLAG_STRING, 5, "UPS.OutletSystem.Outlet.[2].StartupTimer", NULL, "%.0f", HU_FLAG_SEMI_STATIC, NULL },
2011-09-29 18:14:46 +00:00
{ "outlet.1.power", 0, 0, "UPS.OutletSystem.Outlet.[2].ApparentPower", NULL, "%.0f", 0, NULL },
{ "outlet.1.realpower", 0, 0, "UPS.OutletSystem.Outlet.[2].ActivePower", NULL, "%.0f", 0, NULL },
{ "outlet.1.current", 0, 0, "UPS.OutletSystem.Outlet.[2].Current", NULL, "%.2f", 0, NULL },
2012-06-01 13:55:19 +00:00
{ "outlet.1.powerfactor", 0, 0, "UPS.OutletSystem.Outlet.[2].PowerFactor", NULL, "%.2f", 0, NULL }, /* "%s", 0, mge_powerfactor_conversion }, */
2011-09-29 18:14:46 +00:00
/* Second outlet */
2010-03-25 23:20:59 +00:00
{ "outlet.2.id", 0, 0, "UPS.OutletSystem.Outlet.[3].OutletID", NULL, "%.0f", HU_FLAG_STATIC, NULL },
{ "outlet.2.desc", ST_FLAG_RW | ST_FLAG_STRING, 20, "UPS.OutletSystem.Outlet.[3].OutletID", NULL, "PowerShare Outlet 2", HU_FLAG_ABSENT, NULL },
2012-06-01 13:55:19 +00:00
/* needed for Pegasus to enable master/slave mode:
* FIXME: rename to something more suitable (outlet.?) */
{ "outlet.2.switchable", ST_FLAG_RW | ST_FLAG_STRING, 3, "UPS.OutletSystem.Outlet.[3].PresentStatus.Switchable", NULL, "%s", HU_FLAG_SEMI_STATIC, pegasus_yes_no_info },
/* Generic version (RO) for other models */
{ "outlet.2.switchable", 0, 0, "UPS.OutletSystem.Outlet.[3].PresentStatus.Switchable", NULL, "%s", 0, yes_no_info },
2010-03-25 23:20:59 +00:00
{ "outlet.2.status", 0, 0, "UPS.OutletSystem.Outlet.[3].PresentStatus.SwitchOn/Off", NULL, "%s", 0, on_off_info },
{ "outlet.2.autoswitch.charge.low", ST_FLAG_RW | ST_FLAG_STRING, 3, "UPS.OutletSystem.Outlet.[3].RemainingCapacityLimit", NULL, "%.0f", HU_FLAG_SEMI_STATIC, NULL },
{ "outlet.2.delay.shutdown", ST_FLAG_RW | ST_FLAG_STRING, 5, "UPS.OutletSystem.Outlet.[3].ShutdownTimer", NULL, "%.0f", HU_FLAG_SEMI_STATIC, NULL },
{ "outlet.2.delay.start", ST_FLAG_RW | ST_FLAG_STRING, 5, "UPS.OutletSystem.Outlet.[3].StartupTimer", NULL, "%.0f", HU_FLAG_SEMI_STATIC, NULL },
2011-09-29 18:14:46 +00:00
{ "outlet.2.power", 0, 0, "UPS.OutletSystem.Outlet.[3].ApparentPower", NULL, "%.0f", 0, NULL },
{ "outlet.2.realpower", 0, 0, "UPS.OutletSystem.Outlet.[3].ActivePower", NULL, "%.0f", 0, NULL },
{ "outlet.2.current", 0, 0, "UPS.OutletSystem.Outlet.[3].Current", NULL, "%.2f", 0, NULL },
2012-06-01 13:55:19 +00:00
{ "outlet.2.powerfactor", 0, 0, "UPS.OutletSystem.Outlet.[3].PowerFactor", NULL, "%.2f", 0, NULL }, /* "%s", 0, mge_powerfactor_conversion }, */
2010-03-25 23:20:59 +00:00
/* instant commands. */
/* splited into subset while waiting for extradata support
* ie: test.battery.start quick
*/
{ "test.battery.start.quick", 0, 0, "UPS.BatterySystem.Battery.Test", NULL, "1", HU_TYPE_CMD, NULL },
{ "test.battery.start.deep", 0, 0, "UPS.BatterySystem.Battery.Test", NULL, "2", HU_TYPE_CMD, NULL },
{ "test.battery.stop", 0, 0, "UPS.BatterySystem.Battery.Test", NULL, "3", HU_TYPE_CMD, NULL },
{ "load.off.delay", 0, 0, "UPS.PowerSummary.DelayBeforeShutdown", NULL, DEFAULT_OFFDELAY, HU_TYPE_CMD, NULL },
{ "load.on.delay", 0, 0, "UPS.PowerSummary.DelayBeforeStartup", NULL, DEFAULT_ONDELAY, HU_TYPE_CMD, NULL },
{ "shutdown.stop", 0, 0, "UPS.PowerSummary.DelayBeforeShutdown", NULL, "-1", HU_TYPE_CMD, NULL },
{ "shutdown.reboot", 0, 0, "UPS.PowerSummary.DelayBeforeReboot", NULL, "10", HU_TYPE_CMD, NULL},
{ "beeper.off", 0, 0, "UPS.PowerSummary.AudibleAlarmControl", NULL, "1", HU_TYPE_CMD, NULL },
{ "beeper.on", 0, 0, "UPS.PowerSummary.AudibleAlarmControl", NULL, "2", HU_TYPE_CMD, NULL },
{ "beeper.mute", 0, 0, "UPS.PowerSummary.AudibleAlarmControl", NULL, "3", HU_TYPE_CMD, NULL },
{ "beeper.disable", 0, 0, "UPS.PowerSummary.AudibleAlarmControl", NULL, "1", HU_TYPE_CMD, NULL },
{ "beeper.enable", 0, 0, "UPS.PowerSummary.AudibleAlarmControl", NULL, "2", HU_TYPE_CMD, NULL },
/* Command for the outlet collection */
{ "outlet.1.load.off", 0, 0, "UPS.OutletSystem.Outlet.[2].DelayBeforeShutdown", NULL, "0", HU_TYPE_CMD, NULL },
{ "outlet.1.load.on", 0, 0, "UPS.OutletSystem.Outlet.[2].DelayBeforeStartup", NULL, "0", HU_TYPE_CMD, NULL },
{ "outlet.2.load.off", 0, 0, "UPS.OutletSystem.Outlet.[3].DelayBeforeShutdown", NULL, "0", HU_TYPE_CMD, NULL },
{ "outlet.2.load.on", 0, 0, "UPS.OutletSystem.Outlet.[3].DelayBeforeStartup", NULL, "0", HU_TYPE_CMD, NULL },
/* end of structure. */
{ NULL }
};
/*
* All the logic for finely formatting the MGE model name and device
* type matching (used for device specific values or corrections).
* Returns pointer to (dynamically allocated) model name.
*/
static char *get_model_name(const char *iProduct, const char *iModel)
{
models_name_t *model = NULL;
upsdebugx(2, "get_model_name(%s, %s)\n", iProduct, iModel);
/* Search for device type and formatting rules */
for (model = mge_model_names; model->iProduct; model++) {
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if(model->name) {
upsdebugx(2, "comparing with: %s", model->name);
}
else {
upsdebugx(2, "comparing with: %s %s", model->iProduct,
model->iModel);
}
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if (strcmp(iProduct, model->iProduct)) {
continue;
}
if (strcmp(iModel, model->iModel)) {
continue;
}
mge_type = model->type;
break;
}
if (!model->name) {
/*
* Model not found or NULL (use default) so construct
* model name by concatenation of iProduct and iModel
*/
char buf[SMALLBUF];
snprintf(buf, sizeof(buf), "%s %s", iProduct, iModel);
return strdup(buf);
}
return strdup(model->name);
}
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static const char *mge_format_model(HIDDevice_t *hd) {
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char product[SMALLBUF];
char model[SMALLBUF];
double value;
/* Dell has already a fully formatted name in iProduct */
if (hd->VendorID == DELL_VENDORID) {
return hd->Product;
}
/* Get iProduct and iModel strings */
snprintf(product, sizeof(product), "%s", hd->Product ? hd->Product : "unknown");
HIDGetItemString(udev, "UPS.PowerSummary.iModel", model, sizeof(model), mge_utab);
/* Fallback to ConfigApparentPower */
if ((strlen(model) < 1) && (HIDGetItemValue(udev, "UPS.Flow.[4].ConfigApparentPower", &value, mge_utab) == 1 )) {
snprintf(model, sizeof(model), "%i", (int)value);
}
if (strlen(model) > 0) {
free(hd->Product);
hd->Product = get_model_name(product, model);
}
return hd->Product;
}
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static const char *mge_format_mfr(HIDDevice_t *hd) {
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return hd->Vendor ? hd->Vendor : "Eaton";
}
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static const char *mge_format_serial(HIDDevice_t *hd) {
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return hd->Serial;
}
/* this function allows the subdriver to "claim" a device: return 1 if
* the device is supported by this subdriver, else 0. */
static int mge_claim(HIDDevice_t *hd) {
#ifndef SHUT_MODE
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int status = is_usb_device_supported(mge_usb_device_table, hd);
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switch (status) {
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case POSSIBLY_SUPPORTED:
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switch (hd->VendorID)
{
case HP_VENDORID:
case DELL_VENDORID:
/* by default, reject, unless the productid option is given */
if (getval("productid")) {
return 1;
}
/*
* this vendor makes lots of USB devices that are
* not a UPS, so don't use possibly_supported here
*/
return 0;
default: /* Valid for Eaton */
/* by default, reject, unless the productid option is given */
if (getval("productid")) {
return 1;
}
possibly_supported("Eaton / MGE", hd);
return 0;
}
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case SUPPORTED:
return 1;
case NOT_SUPPORTED:
default:
return 0;
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}
#else
return 1;
#endif
}
subdriver_t mge_subdriver = {
MGE_HID_VERSION,
mge_claim,
mge_utab,
mge_hid2nut,
mge_format_model,
mge_format_mfr,
mge_format_serial,
};