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/* Copyright (c) 2012-2013, The Linux Foundation. All rights reserved.
*
* This program is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License version 2 and
* only version 2 as published by the Free Software Foundation.
*
* 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.
*/
#ifndef __BMS_BATTERYDATA_H
#define __BMS_BATTERYDATA_H
#include <linux/errno.h>
#define FCC_CC_COLS 5
#define FCC_TEMP_COLS 8
#define PC_CC_ROWS 31
#define PC_CC_COLS 13
#define PC_TEMP_ROWS 31
#define PC_TEMP_COLS 8
#define MAX_SINGLE_LUT_COLS 20
struct single_row_lut {
int x[MAX_SINGLE_LUT_COLS];
int y[MAX_SINGLE_LUT_COLS];
int cols;
};
/**
* struct sf_lut -
* @rows: number of percent charge entries should be <= PC_CC_ROWS
* @cols: number of charge cycle entries should be <= PC_CC_COLS
* @row_entries: the charge cycles/temperature at which sf data
* is available in the table.
* The charge cycles must be in increasing order from 0 to rows.
* @percent: the percent charge at which sf data is available in the table
* The percentcharge must be in decreasing order from 0 to cols.
* @sf: the scaling factor data
*/
struct sf_lut {
int rows;
int cols;
int row_entries[PC_CC_COLS];
int percent[PC_CC_ROWS];
int sf[PC_CC_ROWS][PC_CC_COLS];
};
/**
* struct pc_temp_ocv_lut -
* @rows: number of percent charge entries should be <= PC_TEMP_ROWS
* @cols: number of temperature entries should be <= PC_TEMP_COLS
* @temp: the temperatures at which ocv data is available in the table
* The temperatures must be in increasing order from 0 to rows.
* @percent: the percent charge at which ocv data is available in the table
* The percentcharge must be in decreasing order from 0 to cols.
* @ocv: the open circuit voltage
*/
struct pc_temp_ocv_lut {
int rows;
int cols;
int temp[PC_TEMP_COLS];
int percent[PC_TEMP_ROWS];
int ocv[PC_TEMP_ROWS][PC_TEMP_COLS];
};
enum battery_type {
BATT_UNKNOWN = 0,
BATT_PALLADIUM,
BATT_DESAY,
BATT_OEM,
BATT_QRD_4V35_2000MAH,
BATT_QRD_4V2_1300MAH,
};
/**
* struct bms_battery_data -
* @fcc: full charge capacity (mAmpHour)
* @fcc_temp_lut: table to get fcc at a given temp
* @pc_temp_ocv_lut: table to get percent charge given batt temp and cycles
* @pc_sf_lut: table to get percent charge scaling factor given cycles
* and percent charge
* @rbatt_sf_lut: table to get battery resistance scaling factor given
* temperature and percent charge
* @default_rbatt_mohm: the default value of battery resistance to use when
* readings from bms are not available.
* @delta_rbatt_mohm: the resistance to be added towards lower soc to
* compensate for battery capacitance.
* @rbatt_capacitve_mohm: the resistance to be added to compensate for
* battery capacitance
* @flat_ocv_threshold_uv: the voltage where the battery's discharge curve
* starts flattening out.
* @max_voltage_uv: max voltage of the battery
* @cutoff_uv: cutoff voltage of the battery
* @iterm_ua: termination current of the battery when charging
* to 100%
* @batt_id_kohm: battery id resistor value
*/
struct bms_battery_data {
unsigned int fcc;
struct single_row_lut *fcc_temp_lut;
struct single_row_lut *fcc_sf_lut;
struct pc_temp_ocv_lut *pc_temp_ocv_lut;
struct sf_lut *pc_sf_lut;
struct sf_lut *rbatt_sf_lut;
int default_rbatt_mohm;
int delta_rbatt_mohm;
int rbatt_capacitive_mohm;
int flat_ocv_threshold_uv;
int max_voltage_uv;
int cutoff_uv;
int iterm_ua;
int batt_id_kohm;
};
#if defined(CONFIG_PM8921_BMS) || \
defined(CONFIG_PM8921_BMS_MODULE) || \
defined(CONFIG_QPNP_BMS)
extern struct bms_battery_data palladium_1500_data;
extern struct bms_battery_data desay_5200_data;
extern struct bms_battery_data oem_batt_data;
extern struct bms_battery_data QRD_4v35_2000mAh_data;
extern struct bms_battery_data qrd_4v2_1300mah_data;
int interpolate_fcc(struct single_row_lut *fcc_temp_lut, int batt_temp);
int interpolate_scalingfactor(struct sf_lut *sf_lut, int row_entry, int pc);
int interpolate_scalingfactor_fcc(struct single_row_lut *fcc_sf_lut,
int cycles);
int interpolate_pc(struct pc_temp_ocv_lut *pc_temp_ocv,
int batt_temp_degc, int ocv);
int interpolate_ocv(struct pc_temp_ocv_lut *pc_temp_ocv,
int batt_temp_degc, int pc);
int linear_interpolate(int y0, int x0, int y1, int x1, int x);
int is_between(int left, int right, int value);
#else
static inline int interpolate_fcc(struct single_row_lut *fcc_temp_lut,
int batt_temp)
{
return -EINVAL;
}
static inline int interpolate_scalingfactor(struct sf_lut *sf_lut,
int row_entry, int pc)
{
return -EINVAL;
}
static inline int interpolate_scalingfactor_fcc(
struct single_row_lut *fcc_sf_lut, int cycles)
{
return -EINVAL;
}
static inline int interpolate_pc(struct pc_temp_ocv_lut *pc_temp_ocv,
int batt_temp_degc, int ocv)
{
return -EINVAL;
}
static inline int interpolate_ocv(struct pc_temp_ocv_lut *pc_temp_ocv,
int batt_temp_degc, int pc)
{
return -EINVAL;
}
static inline int linear_interpolate(int y0, int x0, int y1, int x1, int x)
{
return -EINVAL;
}
static inline int is_between(int left, int right, int value)
{
return -EINVAL;
}
#endif
#endif