rockbox/firmware/target/arm/imx31/gigabeat-s/powermgmt-imx31.c

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/***************************************************************************
* __________ __ ___.
* Open \______ \ ____ ____ | | _\_ |__ _______ ___
* Source | _// _ \_/ ___\| |/ /| __ \ / _ \ \/ /
* Jukebox | | ( <_> ) \___| < | \_\ ( <_> > < <
* Firmware |____|_ /\____/ \___ >__|_ \|___ /\____/__/\_ \
* \/ \/ \/ \/ \/
* $Id$
*
* Copyright (c) 2008 by Michael Sevakis
*
* 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 software is distributed on an "AS IS" basis, WITHOUT WARRANTY OF ANY
* KIND, either express or implied.
*
****************************************************************************/
#include <stdlib.h>
#include "config.h"
#include "system.h"
#include "thread.h"
#include "mc13783.h"
#include "adc.h"
#include "powermgmt.h"
#include "power.h"
#include "power-imx31.h"
/* TODO: Battery tests to get the right values! */
const unsigned short battery_level_dangerous[BATTERY_TYPES_COUNT] =
{
3450
};
const unsigned short battery_level_shutoff[BATTERY_TYPES_COUNT] =
{
3400
};
/* voltages (millivolt) of 0%, 10%, ... 100% when charging disabled */
const unsigned short percent_to_volt_discharge[BATTERY_TYPES_COUNT][11] =
{
/* Toshiba Gigabeat Li Ion 830mAH figured from discharge curve */
{ 3480, 3550, 3590, 3610, 3630, 3650, 3700, 3760, 3800, 3910, 3990 },
};
/* voltages (millivolt) of 0%, 10%, ... 100% when charging enabled */
const unsigned short percent_to_volt_charge[11] =
{
/* Toshiba Gigabeat Li Ion 830mAH */
3480, 3550, 3590, 3610, 3630, 3650, 3700, 3760, 3800, 3910, 3990
};
/* Returns battery voltage from ADC [millivolts] */
unsigned int battery_adc_voltage(void)
{
/* ADC reading 0-1023 = 2400mV-4700mV */
return ((adc_read(ADC_BATTERY) * 2303) >> 10) + 2400;
}
/* Returns the application supply voltage from ADC [millvolts] */
unsigned int application_supply_adc_voltage(void)
{
return ((adc_read(ADC_APPLICATION_SUPPLY) * 2303) >> 10) + 2400;
}
unsigned int chrgraw_adc_voltage(void)
{
return (adc_read(ADC_CHARGER_VOLTAGE) * 23023) >> 10;
}
/* Returns battery charge current from ADC [milliamps] */
int battery_adc_charge_current(void)
{
/* Positive reading = charger to battery
* Negative reading = battery to charger terminal
* ADC reading -512-511 = -2875mA-2875mA */
unsigned int value = adc_read(ADC_CHARGER_CURRENT);
int I;
if (value == ADC_READ_ERROR)
return INT_MIN;
I = ((((int32_t)value << 22) >> 22) * 2881) >> 9;
return ILEVEL_ADJUST_IN(I);
}
/* Estimate power dissipation in the charge path regulator in mW. */
unsigned int cccv_regulator_dissipation(void)
{
/* BATTISNS is shorted to BATT so we don't need to use the
* battery current reading. */
int chrgraw = (adc_read(ADC_CHARGER_VOLTAGE) * 230225) >> 10;
int batt = ((adc_read(ADC_BATTERY) * 23023) >> 10) + 24000;
int ichrgsn = adc_read(ADC_CHARGER_CURRENT);
ichrgsn = ((((int32_t)ichrgsn << 22) >> 22) * 2881) >> 9;
ichrgsn = abs(ichrgsn);
return (chrgraw - ichrgsn - batt)*ILEVEL_ADJUST_IN(ichrgsn) / 10000;
}
/* Returns battery temperature from ADC [deg-C] */
int battery_adc_temp(void)
{
/* E[volts] = value * 2.3V / 1023
* R[ohms] = E/I = E[volts] / 0.00002[A] (Thermistor bias current source)
*
* Steinhart-Hart thermistor equation:
* [A + B*ln(R) + D*ln^3(R)] = 1 / T[<5B>K]
*
* Coeffients that fit experimental data (one thermistor so far, one run):
* A = 0.0013002631685462800
* B = 0.0002000841932612330
* D = 0.0000000640446750919
*/
static const unsigned short ntc_table[] =
{
#if 0 /* These have degree deltas > 1 (except the final two) so leave them
* out. 70 deg C upper limit is quite sufficient. */
0, /* INF */ 1, /* 171 */ 2, /* 145 */ 3, /* 130 */
4, /* 121 */ 5, /* 114 */ 6, /* 108 */ 7, /* 104 */
8, /* 100 */ 9, /* 96 */ 10, /* 93 */ 11, /* 91 */
12, /* 88 */ 13, /* 86 */ 14, /* 84 */ 15, /* 82 */
16, /* 81 */ 17, /* 79 */ 18, /* 78 */ 19, /* 76 */
20, /* 75 */ 21, /* 74 */ 22, /* 72 */ 23, /* 71 */
#endif
24, /* 70 */ 25, /* 69 */ 26, /* 68 */ 27, /* 67 */
28, /* 66 */ 30, /* 65 */ 31, /* 64 */ 32, /* 63 */
33, /* 62 */ 35, /* 61 */ 36, /* 60 */ 38, /* 59 */
39, /* 58 */ 41, /* 57 */ 43, /* 56 */ 45, /* 55 */
47, /* 54 */ 49, /* 53 */ 51, /* 52 */ 53, /* 51 */
56, /* 50 */ 58, /* 49 */ 61, /* 48 */ 63, /* 47 */
66, /* 46 */ 69, /* 45 */ 73, /* 44 */ 76, /* 43 */
80, /* 42 */ 83, /* 41 */ 87, /* 40 */ 92, /* 39 */
96, /* 38 */ 101, /* 37 */ 106, /* 36 */ 111, /* 35 */
116, /* 34 */ 122, /* 33 */ 128, /* 32 */ 135, /* 31 */
142, /* 30 */ 149, /* 29 */ 156, /* 28 */ 164, /* 27 */
173, /* 26 */ 182, /* 25 */ 192, /* 24 */ 202, /* 23 */
212, /* 22 */ 224, /* 21 */ 236, /* 20 */ 249, /* 19 */
262, /* 18 */ 277, /* 17 */ 292, /* 16 */ 308, /* 15 */
325, /* 14 */ 344, /* 13 */ 363, /* 12 */ 384, /* 11 */
406, /* 10 */ 429, /* 9 */ 454, /* 8 */ 480, /* 7 */
509, /* 6 */ 539, /* 5 */ 571, /* 4 */ 605, /* 3 */
641, /* 2 */ 680, /* 1 */ 722, /* 0 */ 766, /* -1 */
813, /* -2 */ 864, /* -3 */ 918, /* -4 */ 976, /* -5 */
};
unsigned int value = adc_read(ADC_BATTERY_TEMP);
if (value > 0)
{
unsigned i;
for (i = 1; i < ARRAYLEN(ntc_table); i++)
{
if (ntc_table[i] > value)
break;
}
return 71 - i;
}
return INT_MIN;
}
/** Charger control **/
/* All code has a preference for the main charger being connected over
* USB. USB is considered in the algorithm only if it is the sole source. */
static uint32_t int_sense0 = 0; /* Interrupt Sense 0 bits */
static unsigned int last_inputs = POWER_INPUT_NONE; /* Detect input changes */
static int charger_total_timer = 0; /* Total allowed charging time */
static int icharger_ave = 0; /* Filtered charging current */
static bool charger_close = false; /* Shutdown notification */
static bool service_wdt = true; /* Service the watchdog timer, if things
go very wrong, cease and shut down. */
static uint32_t charger_setting = 0; /* Current ICHRG and VCHRG regulator
* setting (register bits) */
#define CHARGER_ADJUST ((uint32_t)-1)/* Force change in regulator setting */
static int autorecharge_counter = 0 ; /* Battery < threshold debounce */
static int chgcurr_timer = 0; /* Countdown to CHGCURR error */
#define AUTORECHARGE_COUNTDOWN (10*2) /* 10s debounce */
#define WATCHDOG_TIMEOUT (10*2) /* If not serviced, poweroff in 10s */
#define CHGCURR_TIMEOUT (4*2) /* 4s debounce */
/* Temperature monitoring */
static enum
{
TEMP_STATE_NORMAL = 0, /* Within range */
TEMP_STATE_WAIT = 1, /* Went out of range, wait to come back */
TEMP_LOW_LIMIT = 0, /* Min temp */
TEMP_HIGH_LIMIT = 1, /* Max temp */
} temp_state = TEMP_STATE_NORMAL;
/* Set power thread priority for charging mode or not */
static inline void charging_set_thread_priority(bool charging)
{
#ifdef HAVE_PRIORITY_SCHEDULING
thread_set_priority(THREAD_ID_CURRENT,
charging ? PRIORITY_REALTIME : PRIORITY_SYSTEM);
#endif
(void)charging;
}
/* Update filtered charger current - exponential moving average */
static bool charger_current_filter_step(void)
{
int value = battery_adc_charge_current();
if (value == ADC_READ_ERROR)
return false;
icharger_ave += value - (icharger_ave / ICHARGER_AVE_SAMPLES);
return true;
}
/* Return true if the main charger is connected. */
static bool main_charger_connected(void)
{
return (last_inputs &
POWER_INPUT_MAIN_CHARGER &
POWER_INPUT_CHARGER) != 0;
}
/* Return the voltage level which should automatically trigger
* another recharge cycle based upon which power source is available.
* Assumes at least one is. */
static unsigned int auto_recharge_voltage(void)
{
if (main_charger_connected())
return BATT_VAUTO_RECHARGE;
else
return BATT_USB_VAUTO_RECHARGE;
}
/* Return greater of supply (BP) or filtered battery voltage. */
unsigned int input_millivolts(void)
{
unsigned int app_millivolts = application_supply_adc_voltage();
unsigned int bat_millivolts = battery_voltage();
return MAX(app_millivolts, bat_millivolts);
}
/* Get smoothed readings for initializing filtered data. */
static int stat_battery_reading(int type)
{
int high = INT_MIN, low = INT_MAX;
int value = 0;
int i;
for (i = 0; i < 7; i++)
{
int reading = ADC_READ_ERROR;
sleep(2); /* Get unique readings */
switch (type)
{
case ADC_BATTERY:
reading = battery_adc_voltage();
break;
case ADC_CHARGER_CURRENT:
reading = battery_adc_charge_current();
break;
}
if (reading == ADC_READ_ERROR)
return INT_MIN;
if (reading > high)
high = reading;
if (reading < low)
low = reading;
value += reading;
}
/* Discard extremes */
return (value - high - low) / 5;
}
/* Update filtered battery voltage instead of waiting for filter
* decay. */
static bool update_filtered_battery_voltage(void)
{
int millivolts = stat_battery_reading(ADC_BATTERY);
if (millivolts != INT_MIN)
{
reset_battery_filter(millivolts);
return true;
}
return false;
}
/* Sets the charge current limit based upon state. charge_state should be
* set before calling. */
static bool adjust_charger_current(void)
{
static const uint8_t charger_bits[][2] =
{
[DISCHARGING] =
{
/* These are actually zeros but reflect this setting */
MC13783_ICHRG_0MA | MC13783_VCHRG_4_050V,
MC13783_ICHRG_0MA | MC13783_VCHRG_4_050V,
},
/* Main(+USB): Charge slowly from the adapter until voltage is
* sufficient for normal charging.
*
* USB: The truth is that things will probably not make it this far.
* Cover the case, just in case the disk isn't used and it is
* manageable. */
[TRICKLE] =
{
BATTERY_ITRICKLE | BATTERY_VCHARGING,
BATTERY_ITRICKLE_USB | BATTERY_VCHARGING
},
[TOPOFF] =
{
BATTERY_IFAST | BATTERY_VCHARGING,
BATTERY_IFAST_USB | BATTERY_VCHARGING
},
[CHARGING] =
{
BATTERY_IFAST | BATTERY_VCHARGING,
BATTERY_IFAST_USB | BATTERY_VCHARGING
},
/* Must maintain battery when on USB power only - utterly nasty
* but true and something retailos does (it will even end up charging
* the battery but not reporting that it is doing so).
* Float lower than MAX - could end up slightly discharging after
* a full charge but this is safer than maxing it out. */
[CHARGING+1] =
{
BATTERY_IFLOAT_USB | BATTERY_VFLOAT_USB,
BATTERY_IMAINTAIN_USB | BATTERY_VMAINTAIN_USB
},
#if 0
/* Slower settings to so that the linear regulator doesn't dissipate
* an excessive amount of power when coming out of precharge state. */
[CHARGING+2] =
{
BATTERY_ISLOW | BATTERY_VCHARGING,
BATTERY_ISLOW_USB | BATTEYR_VCHARGING
},
#endif
};
bool success = false;
int usb_select;
uint32_t i;
usb_select = ((last_inputs & POWER_INPUT) == POWER_INPUT_USB)
? 1 : 0;
if (charge_state == DISCHARGING && usb_select == 1)
{
/* USB-only, DISCHARGING, = maintaining battery */
int select = (last_inputs & POWER_INPUT_CHARGER) ? 0 : 1;
charger_setting = charger_bits[CHARGING+1][select];
}
else
{
/* Take very good care not to write garbage. */
int state = charge_state;
if (state < DISCHARGING || state > CHARGING)
state = DISCHARGING;
charger_setting = charger_bits[state][usb_select];
}
if (charger_setting != 0)
{
charging_set_thread_priority(true);
/* Turn regulator logically ON. Hardware may still override. */
i = mc13783_write_masked(MC13783_CHARGER,
charger_setting | MC13783_CHRGRAWPDEN,
MC13783_ICHRG | MC13783_VCHRG |
MC13783_CHRGRAWPDEN);
if (i != MC13783_DATA_ERROR)
{
int icharger;
/* Enable charge current conversion */
adc_enable_channel(ADC_CHARGER_CURRENT, true);
/* Charge path regulator turn on takes ~100ms max. */
sleep(HZ/10);
icharger = stat_battery_reading(ADC_CHARGER_CURRENT);
if (icharger != INT_MIN)
{
icharger_ave = icharger * ICHARGER_AVE_SAMPLES;
if (update_filtered_battery_voltage())
return true;
}
}
/* Force regulator OFF. */
charge_state = CHARGE_STATE_ERROR;
}
/* Turn regulator OFF. */
icharger_ave = 0;
i = mc13783_write_masked(MC13783_CHARGER, charger_bits[0][0],
MC13783_ICHRG | MC13783_VCHRG |
MC13783_CHRGRAWPDEN);
if (MC13783_DATA_ERROR == i)
{
/* Failed. Force poweroff by not servicing the watchdog. */
service_wdt = false;
}
else if (0 == charger_setting)
{
/* Here because OFF was requested state */
success = true;
}
charger_setting = 0;
adc_enable_channel(ADC_CHARGER_CURRENT, false);
update_filtered_battery_voltage();
charging_set_thread_priority(false);
return success;
}
/* Stop the charger - if USB only then the regulator will not really be
* turned off. ERROR or DISABLED will turn it off however. */
static void stop_charger(void)
{
charger_total_timer = 0;
if (charge_state > DISCHARGING)
charge_state = DISCHARGING;
adjust_charger_current();
}
/* Return OK if it is acceptable to start the regulator. */
static bool charging_ok(void)
{
bool ok = charge_state >= DISCHARGING; /* Not an error condition? */
if (ok)
{
/* Is the battery even connected? */
ok = (last_inputs & POWER_INPUT_BATTERY) != 0;
}
if (ok)
{
/* No tolerance for any over/under temp - wait for it to
* come back into safe range. */
static const signed char temp_ranges[2][2] =
{
/* Temperature range before beginning charging */
{ BATTERY_CHARGE_MIN,
BATTERY_CHARGE_MAX },
/* Temperature range after out-of-range detected -
charging will self-resume */
{ BATTERY_CHARGE_RESTART_MIN,
BATTERY_CHARGE_RESTART_MAX },
};
int temp = battery_adc_temp();
const signed char *range = temp_ranges[temp_state];
ok = temp >= range[TEMP_LOW_LIMIT] &&
temp <= range[TEMP_HIGH_LIMIT];
switch (temp_state)
{
case TEMP_STATE_NORMAL:
if (!ok)
temp_state = TEMP_STATE_WAIT;
break;
case TEMP_STATE_WAIT:
if (ok)
temp_state = TEMP_STATE_NORMAL;
break;
default:
break;
}
}
if (ok)
{
/* Any events that should stop the regulator? */
/* Overvoltage at CHRGRAW? */
ok = (int_sense0 & MC13783_CHGOVS) == 0;
if (ok)
{
/* CHGCURR sensed? */
ok = (int_sense0 & MC13783_CHGCURRS) != 0;
if (!ok)
{
/* Debounce transient states */
if (chgcurr_timer > 0)
{
chgcurr_timer--;
ok = true;
}
}
else
{
chgcurr_timer = CHGCURR_TIMEOUT;
}
}
/* Charger may need to be reinserted */
if (!ok)
charge_state = CHARGE_STATE_ERROR;
}
if (charger_setting != 0)
{
if (ok)
{
/* Watch to not overheat FET (nothing should go over about 1012.7mW).
* Trying a higher voltage AC adapter can work (up to 6.90V) but
* we'll just reject that. Reducing current for adapters that bring
* CHRGRAW to > 4.900V is another possible action. */
ok = cccv_regulator_dissipation() < 1150;
if (!ok)
charge_state = CHARGE_STATE_ERROR;
}
if (!ok)
{
int state = charge_state;
if (state > DISCHARGING)
state = DISCHARGING;
/* Force off for all states including maintaining the battery level
* on USB. */
charge_state = CHARGE_STATE_ERROR;
stop_charger();
charge_state = state;
}
}
return ok;
}
void powermgmt_init_target(void)
{
#ifdef IMX31_ALLOW_CHARGING
const uint32_t regval_w =
MC13783_VCHRG_4_050V | MC13783_ICHRG_0MA |
MC13783_ICHRGTR_0MA | MC13783_OVCTRL_6_90V;
/* Use watchdog to shut system down if we lose control of the charging
* hardware. */
watchdog_init(WATCHDOG_TIMEOUT);
mc13783_write(MC13783_CHARGER, regval_w);
if (mc13783_read(MC13783_CHARGER) == regval_w)
{
/* Divide CHRGRAW input by 10 */
mc13783_clear(MC13783_ADC0, MC13783_CHRGRAWDIV);
/* Turn off BATTDETB. It's worthless on MESx0V since the battery
* isn't removable (nor the thermistor). */
mc13783_clear(MC13783_POWER_CONTROL0, MC13783_BATTDETEN);
}
else
{
/* Register has the wrong value - set error condition and disable
* since something is wrong. */
charge_state = CHARGE_STATE_DISABLED;
stop_charger();
}
#else
/* Disable charger use */
charge_state = CHARGE_STATE_DISABLED;
#endif
}
/* Returns true if the unit is charging the batteries. */
bool charging_state(void)
{
switch (charge_state)
{
case TRICKLE:
case TOPOFF:
case CHARGING:
return true;
default:
return false;
}
}
/* Filtered battery charge current */
int battery_charge_current(void)
{
return icharger_ave / ICHARGER_AVE_SAMPLES;
}
static void charger_plugged(void)
{
adc_enable_channel(ADC_BATTERY_TEMP, true);
autorecharge_counter = -1;
}
static void charger_unplugged(void)
{
/* Charger pulled - turn off current sources (though hardware
* will have done that anyway). */
if (charge_state > CHARGE_STATE_DISABLED)
{
/* Reset state and clear any error. If disabled, the charger
* will not have been started or will have been stopped already. */
stop_charger();
charge_state = DISCHARGING;
}
/* Might need to reevaluate these bits in charger_none. */
last_inputs &= ~(POWER_INPUT | POWER_INPUT_CHARGER);
temp_state = TEMP_STATE_NORMAL;
autorecharge_counter = 0;
chgcurr_timer = 0;
adc_enable_channel(ADC_BATTERY_TEMP, false);
}
static void charger_none(void)
{
unsigned int pwr = power_thread_inputs;
if (last_inputs != pwr)
{
last_inputs = pwr;
if (charge_state == CHARGE_STATE_DISABLED)
return;
if ((pwr & (POWER_INPUT | POWER_INPUT_CHARGER)) == POWER_INPUT_USB)
{
/* USB connected but not configured. Maintain battery to the
* greatest degree possible. It probably won't be enough but the
* discharge won't be so severe. */
charger_plugged();
charger_setting = CHARGER_ADJUST;
}
else
{
charger_unplugged();
last_inputs = pwr; /* Restore status */
}
}
else if (charger_setting != 0)
{
/* Maintaining - keep filter going and check charge state */
int_sense0 = mc13783_read(MC13783_INTERRUPT_SENSE0);
if (!charger_current_filter_step())
{
/* Failed to read current */
charge_state = CHARGE_STATE_ERROR;
}
charging_ok();
}
}
static void charger_control(void)
{
unsigned int pwr = power_thread_inputs;
if (last_inputs != pwr)
{
unsigned int changed = last_inputs ^ pwr;
last_inputs = pwr;
if (charger_setting != 0)
charger_setting = CHARGER_ADJUST;
if (charge_state == DISCHARGING)
{
if (main_charger_connected())
{
/* If main is connected, ignore USB plugs. */
if (changed & POWER_INPUT_MAIN_CHARGER)
{
/* Main charger plugged - try charge */
autorecharge_counter = -1;
}
}
else if (pwr & POWER_INPUT_USB_CHARGER
& POWER_INPUT_CHARGER)
{
/* USB power only */
if (changed & POWER_INPUT_USB_CHARGER)
{
/* USB charger plugged - try charge */
autorecharge_counter = -1;
}
else if (changed & POWER_INPUT_MAIN_CHARGER)
{
/* Main charger pulled - go to battery maintenence. */
charger_setting = CHARGER_ADJUST;
}
}
}
}
if (charger_setting != 0 && !charger_current_filter_step())
{
/* Failed to read current */
charge_state = CHARGE_STATE_ERROR;
}
int_sense0 = mc13783_read(MC13783_INTERRUPT_SENSE0);
if (!charging_ok())
return;
switch (charge_state)
{
case DISCHARGING:
{
/* Battery voltage may have dropped and a charge cycle should
* start again. Debounced. */
if (autorecharge_counter < 0 &&
battery_adc_voltage() < BATT_FULL_VOLTAGE)
{
/* Try starting a cycle now if battery isn't already topped
* off to allow user to ensure the battery is full. */
}
else if (battery_voltage() > auto_recharge_voltage())
{
/* Still above threshold - reset counter */
autorecharge_counter = AUTORECHARGE_COUNTDOWN;
break;
}
else if (autorecharge_counter > 0)
{
/* Coundown to restart */
autorecharge_counter--;
break;
}
autorecharge_counter = 0;
charging_set_thread_priority(true);
if (stat_battery_reading(ADC_BATTERY) < BATT_VTRICKLE_CHARGE)
{
/* Battery is deeply discharged - precharge at lower current. */
charge_state = TRICKLE;
}
else
{
/* Ok for fast charge */
charge_state = CHARGING;
}
charger_setting = CHARGER_ADJUST;
charger_total_timer = CHARGER_TOTAL_TIMER*60*2;
break;
} /* DISCHARGING: */
case TRICKLE: /* Very low - precharge */
{
if (battery_voltage() <= BATT_VTRICKLE_CHARGE)
break;
/* Switch to normal charge mode. */
charge_state = CHARGING;
charger_setting = CHARGER_ADJUST;
break;
} /* TRICKLE: */
case CHARGING: /* Constant-current stage */
case TOPOFF: /* Constant-voltage stage */
{
/* Reg. mode is more informative than an operational necessity. */
charge_state = (int_sense0 & MC13783_CCCVS) ? TOPOFF : CHARGING;
if (main_charger_connected())
{
/* Monitor and stop if current drops below threshold. */
if (battery_charge_current() > BATTERY_ICHARGE_COMPLETE)
break;
}
else
{
/* Accurate I-level can't be determined since device also
* powers through the I sense. This simply stops the reporting
* of charging but the regulator remains on. */
if (battery_voltage() <= BATT_USB_VSTOP)
break;
}
stop_charger();
break;
} /* CHARGING: TOPOFF: */
default:
break;
} /* switch */
/* Check if charger timer expired and stop it if so. */
if (charger_total_timer > 0 && --charger_total_timer == 0)
{
charge_state = CHARGE_STATE_ERROR;
stop_charger(); /* Time ran out - error */
}
}
/* Main charging algorithm - called from powermgmt.c */
void charging_algorithm_step(void)
{
#ifdef IMX31_ALLOW_CHARGING
if (service_wdt)
watchdog_service();
#endif
/* Switch by input state */
switch (charger_input_state)
{
case NO_CHARGER:
charger_none();
break;
case CHARGER_PLUGGED:
charger_plugged();
break;
case CHARGER:
charger_control();
break;
case CHARGER_UNPLUGGED:
charger_unplugged();
break;
} /* switch */
if (charger_close)
{
if (charge_state != CHARGE_STATE_DISABLED)
{
/* Disable starts while shutting down */
charge_state = CHARGE_STATE_DISABLED;
stop_charger();
}
charger_close = false;
return;
}
if (charger_setting != 0)
{
if ((mc13783_read(MC13783_CHARGER) & (MC13783_ICHRG | MC13783_VCHRG)) !=
charger_setting)
{
/* The hardware setting doesn't match. It could have turned the
* charger off in a race of plugging/unplugging or the setting
* was changed in one of the calls. */
adjust_charger_current();
}
}
}
/* Disable the charger and prepare for poweroff - called off-thread so we
* signal the charging thread to prepare to quit. */
void charging_algorithm_close(void)
{
charger_close = true;
/* Power management thread will set it false again */
while (charger_close)
sleep(HZ/10);
}