coreboot-libre-fam15h-rdimm/3rdparty/chromeec/common/battery_fuel_gauge.c

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2024-03-04 11:14:53 +01:00
/* Copyright 2018 The Chromium OS Authors. All rights reserved.
* Use of this source code is governed by a BSD-style license that can be
* found in the LICENSE file.
*
* Battery fuel gauge parameters
*/
#include "battery_fuel_gauge.h"
#include "battery_smart.h"
#include "console.h"
#include "hooks.h"
#include "i2c.h"
#include "util.h"
#define CPRINTS(format, args...) cprints(CC_CHARGER, format, ## args)
/* Get type of the battery connected on the board */
static int get_battery_type(void)
{
char manuf_name[32], device_name[32];
int i;
static enum battery_type battery_type = BATTERY_TYPE_COUNT;
/*
* If battery_type is not the default value, then can return here
* as there is no need to query the fuel gauge.
*/
if (battery_type != BATTERY_TYPE_COUNT)
return battery_type;
/* Get the manufacturer name. If can't read then just exit */
if (battery_manufacturer_name(manuf_name, sizeof(manuf_name)))
return battery_type;
/*
* Compare the manufacturer name read from the fuel gauge to the
* manufacturer names defined in the board_battery_info table. If
* a device name has been specified in the board_battery_info table,
* then both the manufacturer and device name must match.
*/
for (i = 0; i < BATTERY_TYPE_COUNT; i++) {
const struct fuel_gauge_info * const fuel_gauge =
&board_battery_info[i].fuel_gauge;
if (strcasecmp(manuf_name, fuel_gauge->manuf_name))
continue;
if (fuel_gauge->device_name != NULL) {
if (battery_device_name(device_name,
sizeof(device_name)))
continue;
if (strcasecmp(device_name, fuel_gauge->device_name))
continue;
}
CPRINTS("found batt:%s", fuel_gauge->manuf_name);
battery_type = i;
break;
}
return battery_type;
}
/*
* Initialize the battery type for the board.
*
* The first call to battery_get_info() is when the charger task starts, so
* initialize the battery type as soon as I2C is initialized.
*/
static void init_battery_type(void)
{
if (get_battery_type() == BATTERY_TYPE_COUNT)
CPRINTS("battery not found");
}
DECLARE_HOOK(HOOK_INIT, init_battery_type, HOOK_PRIO_INIT_I2C + 1);
static inline const struct board_batt_params *get_batt_params(void)
{
int type = get_battery_type();
return &board_battery_info[type == BATTERY_TYPE_COUNT ?
DEFAULT_BATTERY_TYPE : type];
}
const struct battery_info *battery_get_info(void)
{
return &get_batt_params()->batt_info;
}
int cut_off_battery_block_write(const struct ship_mode_info *ship_mode)
{
int rv;
uint8_t cutdata[3] = {
0x02,
ship_mode->reg_data[0] & 0xFF,
ship_mode->reg_data[0] >> 8,
};
/* SMBus protocols are block write, which include byte count
* byte. Byte count segments are required to communicate
* required action and the number of data bytes.
* Due to ship mode command requires writing data values twice
* to cutoff the battery, so byte count is 0x02.
*/
rv = sb_write_block(ship_mode->reg_addr, cutdata, sizeof(cutdata));
if (rv)
return rv;
/* Use the next set of values */
cutdata[1] = ship_mode->reg_data[1] & 0xFF;
cutdata[2] = ship_mode->reg_data[1] >> 8;
return sb_write_block(ship_mode->reg_addr, cutdata, sizeof(cutdata));
}
int cut_off_battery_sb_write(const struct ship_mode_info *ship_mode)
{
int rv;
/* Ship mode command requires writing 2 data values */
rv = sb_write(ship_mode->reg_addr, ship_mode->reg_data[0]);
if (rv)
return rv;
return sb_write(ship_mode->reg_addr, ship_mode->reg_data[1]);
}
int board_cut_off_battery(void)
{
int rv;
int type = get_battery_type();
/* If battery type is unknown can't send ship mode command */
if (type == BATTERY_TYPE_COUNT)
return EC_RES_ERROR;
if (board_battery_info[type].fuel_gauge.ship_mode.wb_support)
rv = cut_off_battery_block_write(
&board_battery_info[type].fuel_gauge.ship_mode);
else
rv = cut_off_battery_sb_write(
&board_battery_info[type].fuel_gauge.ship_mode);
return rv ? EC_RES_ERROR : EC_RES_SUCCESS;
}
/*
* This function checks the charge/discharge FET status bits. Each battery type
* supported provides the register address, mask, and disconnect value for these
* 2 FET status bits. If the FET status matches the disconnected value, then
* BATTERY_DISCONNECTED is returned. This function is required to handle the
* cases when the fuel gauge is awake and will return a non-zero state of
* charge, but is not able yet to provide power (i.e. discharge FET is not
* active). By returning BATTERY_DISCONNECTED the AP will not be powered up
* until either the external charger is able to provided enough power, or
* the battery is able to provide power and thus prevent a brownout when the
* AP is powered on by the EC.
*/
enum battery_disconnect_state battery_get_disconnect_state(void)
{
int rv;
int reg;
uint8_t data[6];
int type = get_battery_type();
/* If battery type is not known, can't check CHG/DCHG FETs */
if (type == BATTERY_TYPE_COUNT) {
/* Still don't know, so return here */
return BATTERY_DISCONNECT_ERROR;
}
/* Read the status of charge/discharge FETs */
if (board_battery_info[type].fuel_gauge.fet.mfgacc_support == 1) {
rv = sb_read_mfgacc(PARAM_OPERATION_STATUS,
SB_ALT_MANUFACTURER_ACCESS, data, sizeof(data));
/* Get the lowest 16bits of the OperationStatus() data */
reg = data[2] | data[3] << 8;
} else
rv = sb_read(board_battery_info[type].fuel_gauge.fet.reg_addr,
&reg);
if (rv)
return BATTERY_DISCONNECT_ERROR;
if ((reg & board_battery_info[type].fuel_gauge.fet.reg_mask) ==
board_battery_info[type].fuel_gauge.fet.disconnect_val) {
CPRINTS("Batt disconnected: reg 0x%04x mask 0x%04x disc 0x%04x",
reg,
board_battery_info[type].fuel_gauge.fet.reg_mask,
board_battery_info[type].fuel_gauge.fet.disconnect_val);
return BATTERY_DISCONNECTED;
}
return BATTERY_NOT_DISCONNECTED;
}
#ifdef CONFIG_BATTERY_MEASURE_IMBALANCE
int battery_imbalance_mv(void)
{
int type = get_battery_type();
/*
* If battery type is unknown, we cannot safely access non-standard
* registers.
*/
return (type == BATTERY_TYPE_COUNT) ? 0 :
board_battery_info[type].fuel_gauge.imbalance_mv();
}
int battery_default_imbalance_mv(void)
{
return 0;
}
#endif /* CONFIG_BATTERY_MEASURE_IMBALANCE */