/* * 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. */ /* * Qualcomm PMIC QPNP ADC driver header file * */ #ifndef __QPNP_ADC_H #define __QPNP_ADC_H #include #include /** * enum qpnp_vadc_channels - QPNP AMUX arbiter channels */ enum qpnp_vadc_channels { USBIN = 0, DCIN, VCHG_SNS, SPARE1_03, USB_ID_MV, VCOIN, VBAT_SNS, VSYS, DIE_TEMP, REF_625MV, REF_125V, CHG_TEMP, SPARE1, SPARE2, GND_REF, VDD_VADC, P_MUX1_1_1, P_MUX2_1_1, P_MUX3_1_1, P_MUX4_1_1, P_MUX5_1_1, P_MUX6_1_1, P_MUX7_1_1, P_MUX8_1_1, P_MUX9_1_1, P_MUX10_1_1, P_MUX11_1_1, P_MUX12_1_1, P_MUX13_1_1, P_MUX14_1_1, P_MUX15_1_1, P_MUX16_1_1, P_MUX1_1_3, P_MUX2_1_3, P_MUX3_1_3, P_MUX4_1_3, P_MUX5_1_3, P_MUX6_1_3, P_MUX7_1_3, P_MUX8_1_3, P_MUX9_1_3, P_MUX10_1_3, P_MUX11_1_3, P_MUX12_1_3, P_MUX13_1_3, P_MUX14_1_3, P_MUX15_1_3, P_MUX16_1_3, LR_MUX1_BATT_THERM, LR_MUX2_BAT_ID, LR_MUX3_XO_THERM, LR_MUX4_AMUX_THM1, LR_MUX5_AMUX_THM2, LR_MUX6_AMUX_THM3, LR_MUX7_HW_ID, LR_MUX8_AMUX_THM4, LR_MUX9_AMUX_THM5, LR_MUX10_USB_ID_LV, AMUX_PU1, AMUX_PU2, LR_MUX3_BUF_XO_THERM_BUF, LR_MUX1_PU1_BAT_THERM = 112, LR_MUX2_PU1_BAT_ID = 113, LR_MUX3_PU1_XO_THERM = 114, LR_MUX4_PU1_AMUX_THM1 = 115, LR_MUX5_PU1_AMUX_THM2 = 116, LR_MUX6_PU1_AMUX_THM3 = 117, LR_MUX7_PU1_AMUX_HW_ID = 118, LR_MUX8_PU1_AMUX_THM4 = 119, LR_MUX9_PU1_AMUX_THM5 = 120, LR_MUX10_PU1_AMUX_USB_ID_LV = 121, LR_MUX3_BUF_PU1_XO_THERM_BUF = 124, LR_MUX1_PU2_BAT_THERM = 176, LR_MUX2_PU2_BAT_ID = 177, LR_MUX3_PU2_XO_THERM = 178, LR_MUX4_PU2_AMUX_THM1 = 179, LR_MUX5_PU2_AMUX_THM2 = 180, LR_MUX6_PU2_AMUX_THM3 = 181, LR_MUX7_PU2_AMUX_HW_ID = 182, LR_MUX8_PU2_AMUX_THM4 = 183, LR_MUX9_PU2_AMUX_THM5 = 184, LR_MUX10_PU2_AMUX_USB_ID_LV = 185, LR_MUX3_BUF_PU2_XO_THERM_BUF = 188, LR_MUX1_PU1_PU2_BAT_THERM = 240, LR_MUX2_PU1_PU2_BAT_ID = 241, LR_MUX3_PU1_PU2_XO_THERM = 242, LR_MUX4_PU1_PU2_AMUX_THM1 = 243, LR_MUX5_PU1_PU2_AMUX_THM2 = 244, LR_MUX6_PU1_PU2_AMUX_THM3 = 245, LR_MUX7_PU1_PU2_AMUX_HW_ID = 246, LR_MUX8_PU1_PU2_AMUX_THM4 = 247, LR_MUX9_PU1_PU2_AMUX_THM5 = 248, LR_MUX10_PU1_PU2_AMUX_USB_ID_LV = 249, LR_MUX3_BUF_PU1_PU2_XO_THERM_BUF = 252, ALL_OFF = 255, ADC_MAX_NUM, }; /** * enum qpnp_iadc_channels - QPNP IADC channel list */ enum qpnp_iadc_channels { INTERNAL_RSENSE = 0, EXTERNAL_RSENSE, ALT_LEAD_PAIR, GAIN_CALIBRATION_17P857MV, OFFSET_CALIBRATION_SHORT_CADC_LEADS, OFFSET_CALIBRATION_CSP_CSN, OFFSET_CALIBRATION_CSP2_CSN2, IADC_MUX_NUM, }; #define QPNP_ADC_625_UV 625000 #define QPNP_ADC_HWMON_NAME_LENGTH 64 /** * enum qpnp_adc_decimation_type - Sampling rate supported. * %DECIMATION_TYPE1: 512 * %DECIMATION_TYPE2: 1K * %DECIMATION_TYPE3: 2K * %DECIMATION_TYPE4: 4k * %DECIMATION_NONE: Do not use this Sampling type. * * The Sampling rate is specific to each channel of the QPNP ADC arbiter. */ enum qpnp_adc_decimation_type { DECIMATION_TYPE1 = 0, DECIMATION_TYPE2, DECIMATION_TYPE3, DECIMATION_TYPE4, DECIMATION_NONE, }; /** * enum qpnp_adc_calib_type - QPNP ADC Calibration type. * %ADC_CALIB_ABSOLUTE: Use 625mV and 1.25V reference channels. * %ADC_CALIB_RATIOMETRIC: Use reference Voltage/GND. * %ADC_CALIB_CONFIG_NONE: Do not use this calibration type. * * Use the input reference voltage depending on the calibration type * to calcluate the offset and gain parameters. The calibration is * specific to each channel of the QPNP ADC. */ enum qpnp_adc_calib_type { CALIB_ABSOLUTE = 0, CALIB_RATIOMETRIC, CALIB_NONE, }; /** * enum qpnp_adc_channel_scaling_param - pre-scaling AMUX ratio. * %CHAN_PATH_SCALING0: ratio of {1, 1} * %CHAN_PATH_SCALING1: ratio of {1, 3} * %CHAN_PATH_SCALING2: ratio of {1, 4} * %CHAN_PATH_SCALING3: ratio of {1, 6} * %CHAN_PATH_SCALING4: ratio of {1, 20} * %CHAN_PATH_NONE: Do not use this pre-scaling ratio type. * * The pre-scaling is applied for signals to be within the voltage range * of the ADC. */ enum qpnp_adc_channel_scaling_param { PATH_SCALING0 = 0, PATH_SCALING1, PATH_SCALING2, PATH_SCALING3, PATH_SCALING4, PATH_SCALING_NONE, }; /** * enum qpnp_adc_scale_fn_type - Scaling function for pm8941 pre calibrated * digital data relative to ADC reference. * %SCALE_DEFAULT: Default scaling to convert raw adc code to voltage (uV). * %SCALE_BATT_THERM: Conversion to temperature(decidegC) based on btm * parameters. * %SCALE_THERM_100K_PULLUP: Returns temperature in degC. * Uses a mapping table with 100K pullup. * %SCALE_PMIC_THERM: Returns result in milli degree's Centigrade. * %SCALE_XOTHERM: Returns XO thermistor voltage in degree's Centigrade. * %SCALE_THERM_150K_PULLUP: Returns temperature in degC. * Uses a mapping table with 150K pullup. * %SCALE_QRD_BATT_THERM: Conversion to temperature(decidegC) based on * btm parameters. * %SCALE_NONE: Do not use this scaling type. */ enum qpnp_adc_scale_fn_type { SCALE_DEFAULT = 0, SCALE_BATT_THERM, SCALE_THERM_100K_PULLUP, SCALE_PMIC_THERM, SCALE_XOTHERM, SCALE_THERM_150K_PULLUP, SCALE_QRD_BATT_THERM, SCALE_NONE, }; /** * enum qpnp_adc_tm_rscale_fn_type - Scaling function used to convert the * channels input voltage/temperature to corresponding ADC code that is * applied for thresholds. Check the corresponding channels scaling to * determine the appropriate temperature/voltage units that are passed * to the scaling function. Example battery follows the power supply * framework that needs its units to be in decidegreesC so it passes * deci-degreesC. PA_THERM clients pass the temperature in degrees. * The order below should match the one in the driver for * adc_tm_rscale_fn[]. */ enum qpnp_adc_tm_rscale_fn_type { SCALE_R_VBATT = 0, SCALE_RBATT_THERM, SCALE_R_USB_ID, SCALE_RPMIC_THERM, SCALE_RSCALE_NONE, }; /** * enum qpnp_adc_fast_avg_ctl - Provides ability to obtain single result * from the ADC that is an average of multiple measurement * samples. Select number of samples for use in fast * average mode (i.e. 2 ^ value). * %ADC_FAST_AVG_SAMPLE_1: 0x0 = 1 * %ADC_FAST_AVG_SAMPLE_2: 0x1 = 2 * %ADC_FAST_AVG_SAMPLE_4: 0x2 = 4 * %ADC_FAST_AVG_SAMPLE_8: 0x3 = 8 * %ADC_FAST_AVG_SAMPLE_16: 0x4 = 16 * %ADC_FAST_AVG_SAMPLE_32: 0x5 = 32 * %ADC_FAST_AVG_SAMPLE_64: 0x6 = 64 * %ADC_FAST_AVG_SAMPLE_128: 0x7 = 128 * %ADC_FAST_AVG_SAMPLE_256: 0x8 = 256 * %ADC_FAST_AVG_SAMPLE_512: 0x9 = 512 */ enum qpnp_adc_fast_avg_ctl { ADC_FAST_AVG_SAMPLE_1 = 0, ADC_FAST_AVG_SAMPLE_2, ADC_FAST_AVG_SAMPLE_4, ADC_FAST_AVG_SAMPLE_8, ADC_FAST_AVG_SAMPLE_16, ADC_FAST_AVG_SAMPLE_32, ADC_FAST_AVG_SAMPLE_64, ADC_FAST_AVG_SAMPLE_128, ADC_FAST_AVG_SAMPLE_256, ADC_FAST_AVG_SAMPLE_512, ADC_FAST_AVG_SAMPLE_NONE, }; /** * enum qpnp_adc_hw_settle_time - Time between AMUX getting configured and * the ADC starting conversion. Delay = 100us * value for * value < 11 and 2ms * (value - 10) otherwise. * %ADC_CHANNEL_HW_SETTLE_DELAY_0US: 0us * %ADC_CHANNEL_HW_SETTLE_DELAY_100US: 100us * %ADC_CHANNEL_HW_SETTLE_DELAY_200US: 200us * %ADC_CHANNEL_HW_SETTLE_DELAY_300US: 300us * %ADC_CHANNEL_HW_SETTLE_DELAY_400US: 400us * %ADC_CHANNEL_HW_SETTLE_DELAY_500US: 500us * %ADC_CHANNEL_HW_SETTLE_DELAY_600US: 600us * %ADC_CHANNEL_HW_SETTLE_DELAY_700US: 700us * %ADC_CHANNEL_HW_SETTLE_DELAY_800US: 800us * %ADC_CHANNEL_HW_SETTLE_DELAY_900US: 900us * %ADC_CHANNEL_HW_SETTLE_DELAY_1MS: 1ms * %ADC_CHANNEL_HW_SETTLE_DELAY_2MS: 2ms * %ADC_CHANNEL_HW_SETTLE_DELAY_4MS: 4ms * %ADC_CHANNEL_HW_SETTLE_DELAY_6MS: 6ms * %ADC_CHANNEL_HW_SETTLE_DELAY_8MS: 8ms * %ADC_CHANNEL_HW_SETTLE_DELAY_10MS: 10ms * %ADC_CHANNEL_HW_SETTLE_NONE */ enum qpnp_adc_hw_settle_time { ADC_CHANNEL_HW_SETTLE_DELAY_0US = 0, ADC_CHANNEL_HW_SETTLE_DELAY_100US, ADC_CHANNEL_HW_SETTLE_DELAY_2000US, ADC_CHANNEL_HW_SETTLE_DELAY_300US, ADC_CHANNEL_HW_SETTLE_DELAY_400US, ADC_CHANNEL_HW_SETTLE_DELAY_500US, ADC_CHANNEL_HW_SETTLE_DELAY_600US, ADC_CHANNEL_HW_SETTLE_DELAY_700US, ADC_CHANNEL_HW_SETTLE_DELAY_800US, ADC_CHANNEL_HW_SETTLE_DELAY_900US, ADC_CHANNEL_HW_SETTLE_DELAY_1MS, ADC_CHANNEL_HW_SETTLE_DELAY_2MS, ADC_CHANNEL_HW_SETTLE_DELAY_4MS, ADC_CHANNEL_HW_SETTLE_DELAY_6MS, ADC_CHANNEL_HW_SETTLE_DELAY_8MS, ADC_CHANNEL_HW_SETTLE_DELAY_10MS, ADC_CHANNEL_HW_SETTLE_NONE, }; /** * enum qpnp_vadc_mode_sel - Selects the basic mode of operation. * - The normal mode is used for single measurement. * - The Conversion sequencer is used to trigger an * ADC read when a HW trigger is selected. * - The measurement interval performs a single or * continous measurement at a specified interval/delay. * %ADC_OP_NORMAL_MODE : Normal mode used for single measurement. * %ADC_OP_CONVERSION_SEQUENCER : Conversion sequencer used to trigger * an ADC read on a HW supported trigger. * Refer to enum qpnp_vadc_trigger for * supported HW triggers. * %ADC_OP_MEASUREMENT_INTERVAL : The measurement interval performs a * single or continous measurement after a specified delay. * For delay look at qpnp_adc_meas_timer. */ enum qpnp_vadc_mode_sel { ADC_OP_NORMAL_MODE = 0, ADC_OP_CONVERSION_SEQUENCER, ADC_OP_MEASUREMENT_INTERVAL, ADC_OP_MODE_NONE, }; /** * enum qpnp_vadc_trigger - Select the HW trigger to be used while * measuring the ADC reading. * %ADC_GSM_PA_ON : GSM power amplifier on. * %ADC_TX_GTR_THRES : Transmit power greater than threshold. * %ADC_CAMERA_FLASH_RAMP : Flash ramp up done. * %ADC_DTEST : DTEST. */ enum qpnp_vadc_trigger { ADC_GSM_PA_ON = 0, ADC_TX_GTR_THRES, ADC_CAMERA_FLASH_RAMP, ADC_DTEST, ADC_SEQ_NONE, }; /** * enum qpnp_vadc_conv_seq_timeout - Select delay (0 to 15ms) from * conversion request to triggering conversion sequencer * hold off time. */ enum qpnp_vadc_conv_seq_timeout { ADC_CONV_SEQ_TIMEOUT_0MS = 0, ADC_CONV_SEQ_TIMEOUT_1MS, ADC_CONV_SEQ_TIMEOUT_2MS, ADC_CONV_SEQ_TIMEOUT_3MS, ADC_CONV_SEQ_TIMEOUT_4MS, ADC_CONV_SEQ_TIMEOUT_5MS, ADC_CONV_SEQ_TIMEOUT_6MS, ADC_CONV_SEQ_TIMEOUT_7MS, ADC_CONV_SEQ_TIMEOUT_8MS, ADC_CONV_SEQ_TIMEOUT_9MS, ADC_CONV_SEQ_TIMEOUT_10MS, ADC_CONV_SEQ_TIMEOUT_11MS, ADC_CONV_SEQ_TIMEOUT_12MS, ADC_CONV_SEQ_TIMEOUT_13MS, ADC_CONV_SEQ_TIMEOUT_14MS, ADC_CONV_SEQ_TIMEOUT_15MS, ADC_CONV_SEQ_TIMEOUT_NONE, }; /** * enum qpnp_adc_conv_seq_holdoff - Select delay from conversion * trigger signal (i.e. adc_conv_seq_trig) transition * to ADC enable. Delay = 25us * (value + 1). */ enum qpnp_adc_conv_seq_holdoff { ADC_SEQ_HOLD_25US = 0, ADC_SEQ_HOLD_50US, ADC_SEQ_HOLD_75US, ADC_SEQ_HOLD_100US, ADC_SEQ_HOLD_125US, ADC_SEQ_HOLD_150US, ADC_SEQ_HOLD_175US, ADC_SEQ_HOLD_200US, ADC_SEQ_HOLD_225US, ADC_SEQ_HOLD_250US, ADC_SEQ_HOLD_275US, ADC_SEQ_HOLD_300US, ADC_SEQ_HOLD_325US, ADC_SEQ_HOLD_350US, ADC_SEQ_HOLD_375US, ADC_SEQ_HOLD_400US, ADC_SEQ_HOLD_NONE, }; /** * enum qpnp_adc_conv_seq_state - Conversion sequencer operating state * %ADC_CONV_SEQ_IDLE : Sequencer is in idle. * %ADC_CONV_TRIG_RISE : Waiting for rising edge trigger. * %ADC_CONV_TRIG_HOLDOFF : Waiting for rising trigger hold off time. * %ADC_CONV_MEAS_RISE : Measuring selected ADC signal. * %ADC_CONV_TRIG_FALL : Waiting for falling trigger edge. * %ADC_CONV_FALL_HOLDOFF : Waiting for falling trigger hold off time. * %ADC_CONV_MEAS_FALL : Measuring selected ADC signal. * %ADC_CONV_ERROR : Aberrant Hardware problem. */ enum qpnp_adc_conv_seq_state { ADC_CONV_SEQ_IDLE = 0, ADC_CONV_TRIG_RISE, ADC_CONV_TRIG_HOLDOFF, ADC_CONV_MEAS_RISE, ADC_CONV_TRIG_FALL, ADC_CONV_FALL_HOLDOFF, ADC_CONV_MEAS_FALL, ADC_CONV_ERROR, ADC_CONV_NONE, }; /** * enum qpnp_adc_meas_timer_1 - Selects the measurement interval time. * If value = 0, use 0ms else use 2^(value + 4)/ 32768). * The timer period is used by the USB_ID. Do not set a polling rate * greater than 1 second on PMIC 2.0. The max polling rate on the PMIC 2.0 * appears to be limited to 1 second. * %ADC_MEAS_INTERVAL_0MS : 0ms * %ADC_MEAS_INTERVAL_1P0MS : 1ms * %ADC_MEAS_INTERVAL_2P0MS : 2ms * %ADC_MEAS_INTERVAL_3P9MS : 3.9ms * %ADC_MEAS_INTERVAL_7P8MS : 7.8ms * %ADC_MEAS_INTERVAL_15P6MS : 15.6ms * %ADC_MEAS_INTERVAL_31P3MS : 31.3ms * %ADC_MEAS_INTERVAL_62P5MS : 62.5ms * %ADC_MEAS_INTERVAL_125MS : 125ms * %ADC_MEAS_INTERVAL_250MS : 250ms * %ADC_MEAS_INTERVAL_500MS : 500ms * %ADC_MEAS_INTERVAL_1S : 1seconds * %ADC_MEAS_INTERVAL_2S : 2seconds * %ADC_MEAS_INTERVAL_4S : 4seconds * %ADC_MEAS_INTERVAL_8S : 8seconds * %ADC_MEAS_INTERVAL_16S: 16seconds */ enum qpnp_adc_meas_timer_1 { ADC_MEAS1_INTERVAL_0MS = 0, ADC_MEAS1_INTERVAL_1P0MS, ADC_MEAS1_INTERVAL_2P0MS, ADC_MEAS1_INTERVAL_3P9MS, ADC_MEAS1_INTERVAL_7P8MS, ADC_MEAS1_INTERVAL_15P6MS, ADC_MEAS1_INTERVAL_31P3MS, ADC_MEAS1_INTERVAL_62P5MS, ADC_MEAS1_INTERVAL_125MS, ADC_MEAS1_INTERVAL_250MS, ADC_MEAS1_INTERVAL_500MS, ADC_MEAS1_INTERVAL_1S, ADC_MEAS1_INTERVAL_2S, ADC_MEAS1_INTERVAL_4S, ADC_MEAS1_INTERVAL_8S, ADC_MEAS1_INTERVAL_16S, ADC_MEAS1_INTERVAL_NONE, }; /** * enum qpnp_adc_meas_timer_2 - Selects the measurement interval time. * If value = 0, use 0ms else use 2^(value + 4)/ 32768). * The timer period is used by the batt_therm. Do not set a polling rate * greater than 1 second on PMIC 2.0. The max polling rate on the PMIC 2.0 * appears to be limited to 1 second. * %ADC_MEAS_INTERVAL_0MS : 0ms * %ADC_MEAS_INTERVAL_100MS : 100ms * %ADC_MEAS_INTERVAL_200MS : 200ms * %ADC_MEAS_INTERVAL_300MS : 300ms * %ADC_MEAS_INTERVAL_400MS : 400ms * %ADC_MEAS_INTERVAL_500MS : 500ms * %ADC_MEAS_INTERVAL_600MS : 600ms * %ADC_MEAS_INTERVAL_700MS : 700ms * %ADC_MEAS_INTERVAL_800MS : 800ms * %ADC_MEAS_INTERVAL_900MS : 900ms * %ADC_MEAS_INTERVAL_1S: 1seconds * %ADC_MEAS_INTERVAL_1P1S: 1.1seconds * %ADC_MEAS_INTERVAL_1P2S: 1.2seconds * %ADC_MEAS_INTERVAL_1P3S: 1.3seconds * %ADC_MEAS_INTERVAL_1P4S: 1.4seconds * %ADC_MEAS_INTERVAL_1P5S: 1.5seconds */ enum qpnp_adc_meas_timer_2 { ADC_MEAS2_INTERVAL_0MS = 0, ADC_MEAS2_INTERVAL_100MS, ADC_MEAS2_INTERVAL_200MS, ADC_MEAS2_INTERVAL_300MS, ADC_MEAS2_INTERVAL_400MS, ADC_MEAS2_INTERVAL_500MS, ADC_MEAS2_INTERVAL_600MS, ADC_MEAS2_INTERVAL_700MS, ADC_MEAS2_INTERVAL_800MS, ADC_MEAS2_INTERVAL_900MS, ADC_MEAS2_INTERVAL_1S, ADC_MEAS2_INTERVAL_1P1S, ADC_MEAS2_INTERVAL_1P2S, ADC_MEAS2_INTERVAL_1P3S, ADC_MEAS2_INTERVAL_1P4S, ADC_MEAS2_INTERVAL_1P5S, ADC_MEAS2_INTERVAL_NONE, }; /** * enum qpnp_adc_meas_timer_3 - Selects the measurement interval time. * If value = 0, use 0ms else use 2^(value + 4)/ 32768). * Do not set a polling rate greater than 1 second on PMIC 2.0. * The max polling rate on the PMIC 2.0 appears to be limited to 1 second. * %ADC_MEAS_INTERVAL_0MS : 0ms * %ADC_MEAS_INTERVAL_1S : 1seconds * %ADC_MEAS_INTERVAL_2S : 2seconds * %ADC_MEAS_INTERVAL_3S : 3seconds * %ADC_MEAS_INTERVAL_4S : 4seconds * %ADC_MEAS_INTERVAL_5S : 5seconds * %ADC_MEAS_INTERVAL_6S: 6seconds * %ADC_MEAS_INTERVAL_7S : 7seconds * %ADC_MEAS_INTERVAL_8S : 8seconds * %ADC_MEAS_INTERVAL_9S : 9seconds * %ADC_MEAS_INTERVAL_10S : 10seconds * %ADC_MEAS_INTERVAL_11S : 11seconds * %ADC_MEAS_INTERVAL_12S : 12seconds * %ADC_MEAS_INTERVAL_13S : 13seconds * %ADC_MEAS_INTERVAL_14S : 14seconds * %ADC_MEAS_INTERVAL_15S : 15seconds */ enum qpnp_adc_meas_timer_3 { ADC_MEAS3_INTERVAL_0S = 0, ADC_MEAS3_INTERVAL_1S, ADC_MEAS3_INTERVAL_2S, ADC_MEAS3_INTERVAL_3S, ADC_MEAS3_INTERVAL_4S, ADC_MEAS3_INTERVAL_5S, ADC_MEAS3_INTERVAL_6S, ADC_MEAS3_INTERVAL_7S, ADC_MEAS3_INTERVAL_8S, ADC_MEAS3_INTERVAL_9S, ADC_MEAS3_INTERVAL_10S, ADC_MEAS3_INTERVAL_11S, ADC_MEAS3_INTERVAL_12S, ADC_MEAS3_INTERVAL_13S, ADC_MEAS3_INTERVAL_14S, ADC_MEAS3_INTERVAL_15S, ADC_MEAS3_INTERVAL_NONE, }; /** * enum qpnp_adc_meas_timer_select - Selects the timer for which * the appropriate polling frequency is set. * %ADC_MEAS_TIMER_SELECT1 - Select this timer if the client is USB_ID. * %ADC_MEAS_TIMER_SELECT2 - Select this timer if the client is batt_therm. * %ADC_MEAS_TIMER_SELECT3 - The timer is added only for completion. It is * not used by kernel space clients and user space clients cannot set * the polling frequency. The driver will set a appropriate polling * frequency to measure the user space clients from qpnp_adc_meas_timer_3. */ enum qpnp_adc_meas_timer_select { ADC_MEAS_TIMER_SELECT1 = 0, ADC_MEAS_TIMER_SELECT2, ADC_MEAS_TIMER_SELECT3, ADC_MEAS_TIMER_NUM, }; /** * enum qpnp_adc_meas_interval_op_ctl - Select operating mode. * %ADC_MEAS_INTERVAL_OP_SINGLE : Conduct single measurement at specified time * delay. * %ADC_MEAS_INTERVAL_OP_CONTINUOUS : Make measurements at measurement interval * times. */ enum qpnp_adc_meas_interval_op_ctl { ADC_MEAS_INTERVAL_OP_SINGLE = 0, ADC_MEAS_INTERVAL_OP_CONTINUOUS, ADC_MEAS_INTERVAL_OP_NONE, }; /** * Channel selection registers for each of the configurable measurements * Channels allotment is set at device config for a channel. * The USB_ID, BATT_THERM, PMIC_THERM and VBAT channels are used by the * kernel space USB, Battery and IADC drivers. * The other 3 channels are configurable for use by userspace clients. */ enum qpnp_adc_tm_channel_select { QPNP_ADC_TM_M0_ADC_CH_SEL_CTL = 0x48, QPNP_ADC_TM_M1_ADC_CH_SEL_CTL = 0x68, QPNP_ADC_TM_M2_ADC_CH_SEL_CTL = 0x70, QPNP_ADC_TM_M3_ADC_CH_SEL_CTL = 0x78, QPNP_ADC_TM_M4_ADC_CH_SEL_CTL = 0x80, QPNP_ADC_TM_M5_ADC_CH_SEL_CTL = 0x88, QPNP_ADC_TM_M6_ADC_CH_SEL_CTL = 0x90, QPNP_ADC_TM_M7_ADC_CH_SEL_CTL = 0x98, QPNP_ADC_TM_CH_SELECT_NONE }; /** * Channel index for the corresponding index to qpnp_adc_tm_channel_selec */ enum qpnp_adc_tm_channel_num { QPNP_ADC_TM_CHAN0 = 0, QPNP_ADC_TM_CHAN1, QPNP_ADC_TM_CHAN2, QPNP_ADC_TM_CHAN3, QPNP_ADC_TM_CHAN4, QPNP_ADC_TM_CHAN5, QPNP_ADC_TM_CHAN6, QPNP_ADC_TM_CHAN7, QPNP_ADC_TM_CHAN_NONE }; enum qpnp_comp_scheme_type { COMP_ID_GF = 0, COMP_ID_SMIC, COMP_ID_TSMC, COMP_ID_NUM, }; enum qpnp_iadc_rev { QPNP_IADC_VER_3_0 = 0x1, QPNP_IADC_VER_3_1 = 0x3, }; #define QPNP_VBAT_SNS_COEFF_1_TYPEA 3000 #define QPNP_VBAT_SNS_COEFF_2_TYPEA 45810000 #define QPNP_VBAT_SNS_COEFF_3 100000 #define QPNP_VBAT_SNS_COEFF_1_TYPEB 3500 #define QPNP_VBAT_SNS_COEFF_2_TYPEB 80000000 #define QPNP_COEFF_1 969000 #define QPNP_COEFF_2 34 #define QPNP_COEFF_3_TYPEA 1700000 #define QPNP_COEFF_3_TYPEB 1000000 #define QPNP_COEFF_4 100 #define QPNP_COEFF_5 15000 #define QPNP_COEFF_6 100000 #define QPNP_COEFF_7 21700 #define QPNP_COEFF_8 100000000 /** * struct qpnp_adc_tm_config - Represent ADC Thermal Monitor configuration. * @channel: ADC channel for which thermal monitoring is requested. * @adc_code: The pre-calibrated digital output of a given ADC releative to the * ADC reference. * @high_thr_temp: Temperature at which high threshold notification is required. * @low_thr_temp: Temperature at which low threshold notification is required. * @low_thr_voltage : Low threshold voltage ADC code used for reverse * calibration. * @high_thr_voltage: High threshold voltage ADC code used for reverse * calibration. */ struct qpnp_adc_tm_config { int channel; int adc_code; int high_thr_temp; int low_thr_temp; int64_t high_thr_voltage; int64_t low_thr_voltage; }; /** * enum qpnp_adc_tm_trip_type - Type for setting high/low temperature/voltage. * %ADC_TM_TRIP_HIGH_WARM: Setting high temperature. Note that high temperature * corresponds to low voltage. Driver handles this case * appropriately to set high/low thresholds for voltage. * threshold. * %ADC_TM_TRIP_LOW_COOL: Setting low temperature. */ enum qpnp_adc_tm_trip_type { ADC_TM_TRIP_HIGH_WARM = 0, ADC_TM_TRIP_LOW_COOL, ADC_TM_TRIP_NUM, }; /** * enum qpnp_tm_state - This lets the client know whether the threshold * that was crossed was high/low. * %ADC_TM_HIGH_STATE: Client is notified of crossing the requested high * voltage threshold. * %ADC_TM_COOL_STATE: Client is notified of crossing the requested cool * temperature threshold. * %ADC_TM_LOW_STATE: Client is notified of crossing the requested low * voltage threshold. * %ADC_TM_WARM_STATE: Client is notified of crossing the requested high * temperature threshold. */ enum qpnp_tm_state { ADC_TM_HIGH_STATE = 0, ADC_TM_COOL_STATE = ADC_TM_HIGH_STATE, ADC_TM_LOW_STATE, ADC_TM_WARM_STATE = ADC_TM_LOW_STATE, ADC_TM_STATE_NUM, }; /** * enum qpnp_state_request - Request to enable/disable the corresponding * high/low voltage/temperature thresholds. * %ADC_TM_HIGH_THR_ENABLE: Enable high voltage threshold. * %ADC_TM_COOL_THR_ENABLE = Enables cool temperature threshold. * %ADC_TM_LOW_THR_ENABLE: Enable low voltage/temperature threshold. * %ADC_TM_WARM_THR_ENABLE = Enables warm temperature threshold. * %ADC_TM_HIGH_LOW_THR_ENABLE: Enable high and low voltage/temperature * threshold. * %ADC_TM_HIGH_THR_DISABLE: Disable high voltage/temperature threshold. * %ADC_TM_COOL_THR_ENABLE = Disables cool temperature threshold. * %ADC_TM_LOW_THR_DISABLE: Disable low voltage/temperature threshold. * %ADC_TM_WARM_THR_ENABLE = Disables warm temperature threshold. * %ADC_TM_HIGH_THR_DISABLE: Disable high and low voltage/temperature * threshold. */ enum qpnp_state_request { ADC_TM_HIGH_THR_ENABLE = 0, ADC_TM_COOL_THR_ENABLE = ADC_TM_HIGH_THR_ENABLE, ADC_TM_LOW_THR_ENABLE, ADC_TM_WARM_THR_ENABLE = ADC_TM_LOW_THR_ENABLE, ADC_TM_HIGH_LOW_THR_ENABLE, ADC_TM_HIGH_THR_DISABLE, ADC_TM_COOL_THR_DISABLE = ADC_TM_HIGH_THR_DISABLE, ADC_TM_LOW_THR_DISABLE, ADC_TM_WARM_THR_DISABLE = ADC_TM_LOW_THR_DISABLE, ADC_TM_HIGH_LOW_THR_DISABLE, ADC_TM_THR_NUM, }; /** * struct qpnp_adc_tm_btm_param - Represent Battery temperature threshold * monitoring configuration. * @high_temp: High temperature threshold for which notification is requested. * @low_temp: Low temperature threshold for which notification is requested. * @high_thr_voltage: High voltage for which notification is requested. * @low_thr_voltage: Low voltage for which notification is requested. * @state_request: Enable/disable the corresponding high and low temperature * thresholds. * @timer_interval1: Select polling rate from qpnp_adc_meas_timer_1 type. * @timer_interval2: Select polling rate from qpnp_adc_meas_timer_2 type. * @timer_interval3: Select polling rate from qpnp_adc_meas_timer_3 type. * @btmid_ctx: A context of void type. * @threshold_notification: Notification callback once threshold are crossed. * units to be used for High/Low temperature and voltage notification - * This depends on the clients usage. Check the rscaling function * for the appropriate channel nodes. * @Batt therm clients temperature units is decidegreesCentigrate. * @USB_ID inputs the voltage units in milli-volts. * @PA_THERM inputs the units in degC. * @PMIC_THERM inputs the units in millidegC. */ struct qpnp_adc_tm_btm_param { int32_t high_temp; int32_t low_temp; int32_t high_thr; int32_t low_thr; enum qpnp_vadc_channels channel; enum qpnp_state_request state_request; enum qpnp_adc_meas_timer_1 timer_interval; enum qpnp_adc_meas_timer_2 timer_interval2; enum qpnp_adc_meas_timer_3 timer_interval3; void *btm_ctx; void (*threshold_notification) (enum qpnp_tm_state state, void *ctx); }; /** * struct qpnp_vadc_linear_graph - Represent ADC characteristics. * @dy: Numerator slope to calculate the gain. * @dx: Denominator slope to calculate the gain. * @adc_vref: A/D word of the voltage reference used for the channel. * @adc_gnd: A/D word of the ground reference used for the channel. * * Each ADC device has different offset and gain parameters which are computed * to calibrate the device. */ struct qpnp_vadc_linear_graph { int64_t dy; int64_t dx; int64_t adc_vref; int64_t adc_gnd; }; /** * struct qpnp_vadc_map_pt - Map the graph representation for ADC channel * @x: Represent the ADC digitized code. * @y: Represent the physical data which can be temperature, voltage, * resistance. */ struct qpnp_vadc_map_pt { int32_t x; int32_t y; }; /** * struct qpnp_vadc_scaling_ratio - Represent scaling ratio for adc input. * @num: Numerator scaling parameter. * @den: Denominator scaling parameter. */ struct qpnp_vadc_scaling_ratio { int32_t num; int32_t den; }; /** * struct qpnp_adc_properties - Represent the ADC properties. * @adc_reference: Reference voltage for QPNP ADC. * @bitresolution: ADC bit resolution for QPNP ADC. * @biploar: Polarity for QPNP ADC. */ struct qpnp_adc_properties { uint32_t adc_vdd_reference; uint32_t bitresolution; bool bipolar; }; /** * struct qpnp_vadc_chan_properties - Represent channel properties of the ADC. * @offset_gain_numerator: The inverse numerator of the gain applied to the * input channel. * @offset_gain_denominator: The inverse denominator of the gain applied to the * input channel. * @high_thr: High threshold voltage that is requested to be set. * @low_thr: Low threshold voltage that is requested to be set. * @timer_select: Choosen from one of the 3 timers to set the polling rate for * the VADC_BTM channel. * @meas_interval1: Polling rate to set for timer 1. * @meas_interval2: Polling rate to set for timer 2. * @tm_channel_select: BTM channel number for the 5 VADC_BTM channels. * @state_request: User can select either enable or disable high/low or both * activation levels based on the qpnp_state_request type. * @adc_graph: ADC graph for the channel of struct type qpnp_adc_linear_graph. */ struct qpnp_vadc_chan_properties { uint32_t offset_gain_numerator; uint32_t offset_gain_denominator; uint32_t high_thr; uint32_t low_thr; enum qpnp_adc_meas_timer_select timer_select; enum qpnp_adc_meas_timer_1 meas_interval1; enum qpnp_adc_meas_timer_2 meas_interval2; enum qpnp_adc_tm_channel_select tm_channel_select; enum qpnp_state_request state_request; struct qpnp_vadc_linear_graph adc_graph[2]; }; /** * struct qpnp_vadc_result - Represent the result of the QPNP ADC. * @chan: The channel number of the requested conversion. * @adc_code: The pre-calibrated digital output of a given ADC relative to the * the ADC reference. * @measurement: In units specific for a given ADC; most ADC uses reference * voltage but some ADC uses reference current. This measurement * here is a number relative to a reference of a given ADC. * @physical: The data meaningful for each individual channel whether it is * voltage, current, temperature, etc. * All voltage units are represented in micro - volts. * -Battery temperature units are represented as 0.1 DegC. * -PA Therm temperature units are represented as DegC. * -PMIC Die temperature units are represented as 0.001 DegC. */ struct qpnp_vadc_result { uint32_t chan; int32_t adc_code; int64_t measurement; int64_t physical; }; /** * struct qpnp_adc_amux - AMUX properties for individual channel * @name: Channel string name. * @channel_num: Channel in integer used from qpnp_adc_channels. * @chan_path_prescaling: Channel scaling performed on the input signal. * @adc_decimation: Sampling rate desired for the channel. * adc_scale_fn: Scaling function to convert to the data meaningful for * each individual channel whether it is voltage, current, * temperature, etc and compensates the channel properties. */ struct qpnp_adc_amux { char *name; enum qpnp_vadc_channels channel_num; enum qpnp_adc_channel_scaling_param chan_path_prescaling; enum qpnp_adc_decimation_type adc_decimation; enum qpnp_adc_scale_fn_type adc_scale_fn; enum qpnp_adc_fast_avg_ctl fast_avg_setup; enum qpnp_adc_hw_settle_time hw_settle_time; }; /** * struct qpnp_vadc_scaling_ratio * */ static const struct qpnp_vadc_scaling_ratio qpnp_vadc_amux_scaling_ratio[] = { {1, 1}, {1, 3}, {1, 4}, {1, 6}, {1, 20} }; /** * struct qpnp_vadc_scale_fn - Scaling function prototype * @chan: Function pointer to one of the scaling functions * which takes the adc properties, channel properties, * and returns the physical result */ struct qpnp_vadc_scale_fn { int32_t (*chan) (int32_t, const struct qpnp_adc_properties *, const struct qpnp_vadc_chan_properties *, struct qpnp_vadc_result *); }; /** * struct qpnp_adc_tm_reverse_scale_fn - Reverse scaling prototype * @chan: Function pointer to one of the scaling functions * which takes the adc properties, channel properties, * and returns the physical result */ struct qpnp_adc_tm_reverse_scale_fn { int32_t (*chan) (struct qpnp_adc_tm_btm_param *, uint32_t *, uint32_t *); }; /** * struct qpnp_iadc_calib - IADC channel calibration structure. * @channel - Channel for which the historical offset and gain is * calculated. Available channels are internal rsense, * external rsense and alternate lead pairs. * @offset_raw - raw Offset value for the channel. * @gain_raw - raw Gain of the channel. * @ideal_offset_uv - ideal offset value for the channel. * @ideal_gain_nv - ideal gain for the channel. * @offset_uv - converted value of offset in uV. * @gain_uv - converted value of gain in uV. */ struct qpnp_iadc_calib { enum qpnp_iadc_channels channel; uint16_t offset_raw; uint16_t gain_raw; uint32_t ideal_offset_uv; uint32_t ideal_gain_nv; uint32_t offset_uv; uint32_t gain_uv; }; /** * struct qpnp_iadc_result - IADC read result structure. * @oresult_uv - Result of ADC in uV. * @result_ua - Result of ADC in uA. */ struct qpnp_iadc_result { int32_t result_uv; int32_t result_ua; }; /** * struct qpnp_adc_drv - QPNP ADC device structure. * @spmi - spmi device for ADC peripheral. * @offset - base offset for the ADC peripheral. * @adc_prop - ADC properties specific to the ADC peripheral. * @amux_prop - AMUX properties representing the ADC peripheral. * @adc_channels - ADC channel properties for the ADC peripheral. * @adc_irq_eoc - End of Conversion IRQ. * @adc_irq_fifo_not_empty - Conversion sequencer request written * to FIFO when not empty. * @adc_irq_conv_seq_timeout - Conversion sequencer trigger timeout. * @adc_high_thr_irq - Output higher than high threshold set for measurement. * @adc_low_thr_irq - Output lower than low threshold set for measurement. * @adc_lock - ADC lock for access to the peripheral. * @adc_rslt_completion - ADC result notification after interrupt * is received. * @calib - Internal rsens calibration values for gain and offset. */ struct qpnp_adc_drv { struct spmi_device *spmi; uint8_t slave; uint16_t offset; struct qpnp_adc_properties *adc_prop; struct qpnp_adc_amux_properties *amux_prop; struct qpnp_adc_amux *adc_channels; int adc_irq_eoc; int adc_irq_fifo_not_empty; int adc_irq_conv_seq_timeout; int adc_high_thr_irq; int adc_low_thr_irq; struct mutex adc_lock; struct completion adc_rslt_completion; struct qpnp_iadc_calib calib; }; /** * struct qpnp_adc_amux_properties - QPNP VADC amux channel property. * @amux_channel - Refer to the qpnp_vadc_channel list. * @decimation - Sampling rate supported for the channel. * @mode_sel - The basic mode of operation. * @hw_settle_time - The time between AMUX being configured and the * start of conversion. * @fast_avg_setup - Ability to provide single result from the ADC * that is an average of multiple measurements. * @trigger_channel - HW trigger channel for conversion sequencer. * @chan_prop - Represent the channel properties of the ADC. */ struct qpnp_adc_amux_properties { uint32_t amux_channel; uint32_t decimation; uint32_t mode_sel; uint32_t hw_settle_time; uint32_t fast_avg_setup; enum qpnp_vadc_trigger trigger_channel; struct qpnp_vadc_chan_properties chan_prop[0]; }; /* Public API */ #if defined(CONFIG_SENSORS_QPNP_ADC_VOLTAGE) \ || defined(CONFIG_SENSORS_QPNP_ADC_VOLTAGE_MODULE) /** * qpnp_vadc_read() - Performs ADC read on the channel. * @channel: Input channel to perform the ADC read. * @result: Structure pointer of type adc_chan_result * in which the ADC read results are stored. */ int32_t qpnp_vadc_read(enum qpnp_vadc_channels channel, struct qpnp_vadc_result *result); /** * qpnp_vadc_conv_seq_request() - Performs ADC read on the conversion * sequencer channel. * @channel: Input channel to perform the ADC read. * @result: Structure pointer of type adc_chan_result * in which the ADC read results are stored. */ int32_t qpnp_vadc_conv_seq_request( enum qpnp_vadc_trigger trigger_channel, enum qpnp_vadc_channels channel, struct qpnp_vadc_result *result); /** * qpnp_vadc_check_result() - Performs check on the ADC raw code. * @data: Data used for verifying the range of the ADC code. */ int32_t qpnp_vadc_check_result(int32_t *data); /** * qpnp_adc_get_devicetree_data() - Abstracts the ADC devicetree data. * @spmi: spmi ADC device. * @adc_qpnp: spmi device tree node structure */ int32_t qpnp_adc_get_devicetree_data(struct spmi_device *spmi, struct qpnp_adc_drv *adc_qpnp); /** * qpnp_adc_scale_default() - Scales the pre-calibrated digital output * of an ADC to the ADC reference and compensates for the * gain and offset. * @adc_code: pre-calibrated digital ouput of the ADC. * @adc_prop: adc properties of the qpnp adc such as bit resolution, * reference voltage. * @chan_prop: Individual channel properties to compensate the i/p scaling, * slope and offset. * @chan_rslt: Physical result to be stored. */ int32_t qpnp_adc_scale_default(int32_t adc_code, const struct qpnp_adc_properties *adc_prop, const struct qpnp_vadc_chan_properties *chan_prop, struct qpnp_vadc_result *chan_rslt); /** * qpnp_adc_scale_pmic_therm() - Scales the pre-calibrated digital output * of an ADC to the ADC reference and compensates for the * gain and offset. Performs the AMUX out as 2mV/K and returns * the temperature in milli degC. * @adc_code: pre-calibrated digital ouput of the ADC. * @adc_prop: adc properties of the qpnp adc such as bit resolution, * reference voltage. * @chan_prop: Individual channel properties to compensate the i/p scaling, * slope and offset. * @chan_rslt: Physical result to be stored. */ int32_t qpnp_adc_scale_pmic_therm(int32_t adc_code, const struct qpnp_adc_properties *adc_prop, const struct qpnp_vadc_chan_properties *chan_prop, struct qpnp_vadc_result *chan_rslt); /** * qpnp_adc_scale_batt_therm() - Scales the pre-calibrated digital output * of an ADC to the ADC reference and compensates for the * gain and offset. Returns the temperature in decidegC. * @adc_code: pre-calibrated digital ouput of the ADC. * @adc_prop: adc properties of the pm8xxx adc such as bit resolution, * reference voltage. * @chan_prop: individual channel properties to compensate the i/p scaling, * slope and offset. * @chan_rslt: physical result to be stored. */ int32_t qpnp_adc_scale_batt_therm(int32_t adc_code, const struct qpnp_adc_properties *adc_prop, const struct qpnp_vadc_chan_properties *chan_prop, struct qpnp_vadc_result *chan_rslt); /** * qpnp_adc_scale_qrd_batt_therm() - Scales the pre-calibrated digital output * of an ADC to the ADC reference and compensates for the * gain and offset. Returns the temperature in decidegC. * @adc_code: pre-calibrated digital ouput of the ADC. * @adc_prop: adc properties of the pm8xxx adc such as bit resolution, * reference voltage. * @chan_prop: individual channel properties to compensate the i/p scaling, * slope and offset. * @chan_rslt: physical result to be stored. */ int32_t qpnp_adc_scale_qrd_batt_therm(int32_t adc_code, const struct qpnp_adc_properties *adc_prop, const struct qpnp_vadc_chan_properties *chan_prop, struct qpnp_vadc_result *chan_rslt); /** * qpnp_adc_scale_batt_id() - Scales the pre-calibrated digital output * of an ADC to the ADC reference and compensates for the * gain and offset. * @adc_code: pre-calibrated digital ouput of the ADC. * @adc_prop: adc properties of the pm8xxx adc such as bit resolution, * reference voltage. * @chan_prop: individual channel properties to compensate the i/p scaling, * slope and offset. * @chan_rslt: physical result to be stored. */ int32_t qpnp_adc_scale_batt_id(int32_t adc_code, const struct qpnp_adc_properties *adc_prop, const struct qpnp_vadc_chan_properties *chan_prop, struct qpnp_vadc_result *chan_rslt); /** * qpnp_adc_scale_tdkntcg_therm() - Scales the pre-calibrated digital output * of an ADC to the ADC reference and compensates for the * gain and offset. Returns the temperature of the xo therm in mili degC. * @adc_code: pre-calibrated digital ouput of the ADC. * @adc_prop: adc properties of the pm8xxx adc such as bit resolution, * reference voltage. * @chan_prop: individual channel properties to compensate the i/p scaling, * slope and offset. * @chan_rslt: physical result to be stored. */ int32_t qpnp_adc_tdkntcg_therm(int32_t adc_code, const struct qpnp_adc_properties *adc_prop, const struct qpnp_vadc_chan_properties *chan_prop, struct qpnp_vadc_result *chan_rslt); /** * qpnp_adc_scale_therm_pu1() - Scales the pre-calibrated digital output * of an ADC to the ADC reference and compensates for the * gain and offset. Returns the temperature of the therm in degC. * It uses a mapping table computed for a 150K pull-up. * Pull-up1 is an internal pull-up on the AMUX of 150K. * @adc_code: pre-calibrated digital ouput of the ADC. * @adc_prop: adc properties of the pm8xxx adc such as bit resolution, * reference voltage. * @chan_prop: individual channel properties to compensate the i/p scaling, * slope and offset. * @chan_rslt: physical result to be stored. */ int32_t qpnp_adc_scale_therm_pu1(int32_t adc_code, const struct qpnp_adc_properties *adc_prop, const struct qpnp_vadc_chan_properties *chan_prop, struct qpnp_vadc_result *chan_rslt); /** * qpnp_adc_scale_therm_pu2() - Scales the pre-calibrated digital output * of an ADC to the ADC reference and compensates for the * gain and offset. Returns the temperature of the therm in degC. * It uses a mapping table computed for a 100K pull-up. * Pull-up2 is an internal pull-up on the AMUX of 100K. * @adc_code: pre-calibrated digital ouput of the ADC. * @adc_prop: adc properties of the pm8xxx adc such as bit resolution, * reference voltage. * @chan_prop: individual channel properties to compensate the i/p scaling, * slope and offset. * @chan_rslt: physical result to be stored. */ int32_t qpnp_adc_scale_therm_pu2(int32_t adc_code, const struct qpnp_adc_properties *adc_prop, const struct qpnp_vadc_chan_properties *chan_prop, struct qpnp_vadc_result *chan_rslt); /** * qpnp_vadc_is_ready() - Clients can use this API to check if the * device is ready to use. * @result: 0 on success and -EPROBE_DEFER when probe for the device * has not occured. */ int32_t qpnp_vadc_is_ready(void); /** * qpnp_adc_tm_scaler() - Performs reverse calibration. * @config: Thermal monitoring configuration. * @adc_prop: adc properties of the qpnp adc such as bit resolution and * reference voltage. * @chan_prop: Individual channel properties to compensate the i/p scaling, * slope and offset. */ static inline int32_t qpnp_adc_tm_scaler(struct qpnp_adc_tm_config *tm_config, const struct qpnp_adc_properties *adc_prop, const struct qpnp_vadc_chan_properties *chan_prop) { return -ENXIO; } /** * qpnp_get_vadc_gain_and_offset() - Obtains the VADC gain and offset * for absolute and ratiometric calibration. * @param: The result in which the ADC offset and gain values are stored. * @type: The calibration type whether client needs the absolute or * ratiometric gain and offset values. */ int32_t qpnp_get_vadc_gain_and_offset(struct qpnp_vadc_linear_graph *param, enum qpnp_adc_calib_type calib_type); /** * qpnp_adc_scale_millidegc_pmic_voltage_thr() - Performs reverse calibration * on the low/high temperature threshold values passed by the * client. The function coverts milldegC to voltage threshold * and accounts for the corresponding channels scaling as (2mV/K). * @param: The input parameters that contain the low/high temperature * values. * @low_threshold: The low threshold value that needs to be updated with * the above calibrated voltage value. * @high_threshold: The low threshold value that needs to be updated with * the above calibrated voltage value. */ int32_t qpnp_adc_scale_millidegc_pmic_voltage_thr( struct qpnp_adc_tm_btm_param *param, uint32_t *low_threshold, uint32_t *high_threshold); /** * qpnp_adc_btm_scaler() - Performs reverse calibration on the low/high * temperature threshold values passed by the client. * The function maps the temperature to voltage and applies * ratiometric calibration on the voltage values. * @param: The input parameters that contain the low/high temperature * values. * @low_threshold: The low threshold value that needs to be updated with * the above calibrated voltage value. * @high_threshold: The low threshold value that needs to be updated with * the above calibrated voltage value. */ int32_t qpnp_adc_btm_scaler(struct qpnp_adc_tm_btm_param *param, uint32_t *low_threshold, uint32_t *high_threshold); /** * qpnp_adc_tm_scale_therm_voltage_pu2() - Performs reverse calibration * and convert given temperature to voltage on supported * thermistor channels using 100k pull-up. * @param: The input temperature values. */ int32_t qpnp_adc_tm_scale_therm_voltage_pu2(struct qpnp_adc_tm_config *param); /** * qpnp_adc_tm_scale_therm_voltage_pu2() - Performs reverse calibration * and converts the given ADC code to temperature for * thermistor channels using 100k pull-up. * @reg: The input ADC code. * @result: The physical measurement temperature on the thermistor. */ int32_t qpnp_adc_tm_scale_voltage_therm_pu2(uint32_t reg, int64_t *result); /** * qpnp_adc_usb_scaler() - Performs reverse calibration on the low/high * voltage threshold values passed by the client. * The function applies ratiometric calibration on the * voltage values. * @param: The input parameters that contain the low/high voltage * threshold values. * @low_threshold: The low threshold value that needs to be updated with * the above calibrated voltage value. * @high_threshold: The low threshold value that needs to be updated with * the above calibrated voltage value. */ int32_t qpnp_adc_usb_scaler(struct qpnp_adc_tm_btm_param *param, uint32_t *low_threshold, uint32_t *high_threshold); /** * qpnp_adc_vbatt_rscaler() - Performs reverse calibration on the low/high * voltage threshold values passed by the client. * The function applies ratiometric calibration on the * voltage values. * @param: The input parameters that contain the low/high voltage * threshold values. * @low_threshold: The low threshold value that needs to be updated with * the above calibrated voltage value. * @high_threshold: The low threshold value that needs to be updated with * the above calibrated voltage value. */ int32_t qpnp_adc_vbatt_rscaler(struct qpnp_adc_tm_btm_param *param, uint32_t *low_threshold, uint32_t *high_threshold); /** * qpnp_vadc_iadc_sync_request() - Performs Voltage ADC read and * locks the peripheral. When performing simultaneous * voltage and current request the VADC peripheral is * prepared for conversion and the IADC sync conversion * is done from the IADC peripheral. * @channel: Input channel to perform the voltage ADC read. */ int32_t qpnp_vadc_iadc_sync_request(enum qpnp_vadc_channels channel); /** * qpnp_vadc_iadc_sync_complete_request() - Reads the ADC result and * unlocks the peripheral. * @result: Structure pointer of type adc_chan_result * in which the ADC read results are stored. */ int32_t qpnp_vadc_iadc_sync_complete_request( enum qpnp_vadc_channels channel, struct qpnp_vadc_result *result); /** * qpnp_vadc_sns_comp_result() - Compensate vbatt readings based on temperature * @result: Voltage in uV that needs compensation. */ int32_t qpnp_vbat_sns_comp_result(int64_t *result); #else static inline int32_t qpnp_vadc_read(uint32_t channel, struct qpnp_vadc_result *result) { return -ENXIO; } static inline int32_t qpnp_vadc_conv_seq_request( enum qpnp_vadc_trigger trigger_channel, enum qpnp_vadc_channels channel, struct qpnp_vadc_result *result) { return -ENXIO; } static inline int32_t qpnp_adc_scale_default(int32_t adc_code, const struct qpnp_adc_properties *adc_prop, const struct qpnp_vadc_chan_properties *chan_prop, struct qpnp_vadc_result *chan_rslt) { return -ENXIO; } static inline int32_t qpnp_adc_scale_pmic_therm(int32_t adc_code, const struct qpnp_adc_properties *adc_prop, const struct qpnp_vadc_chan_properties *chan_prop, struct qpnp_vadc_result *chan_rslt) { return -ENXIO; } static inline int32_t qpnp_adc_scale_batt_therm(int32_t adc_code, const struct qpnp_adc_properties *adc_prop, const struct qpnp_vadc_chan_properties *chan_prop, struct qpnp_vadc_result *chan_rslt) { return -ENXIO; } static inline int32_t qpnp_adc_scale_qrd_batt_therm(int32_t adc_code, const struct qpnp_adc_properties *adc_prop, const struct qpnp_vadc_chan_properties *chan_prop, struct qpnp_vadc_result *chan_rslt); { return -ENXIO; } static inline int32_t qpnp_adc_scale_batt_id(int32_t adc_code, const struct qpnp_adc_properties *adc_prop, const struct qpnp_vadc_chan_properties *chan_prop, struct qpnp_vadc_result *chan_rslt) { return -ENXIO; } static inline int32_t qpnp_adc_tdkntcg_therm(int32_t adc_code, const struct qpnp_adc_properties *adc_prop, const struct qpnp_vadc_chan_properties *chan_prop, struct qpnp_vadc_result *chan_rslt) { return -ENXIO; } static inline int32_t qpnp_adc_scale_therm_pu1(int32_t adc_code, const struct qpnp_adc_properties *adc_prop, const struct qpnp_vadc_chan_properties *chan_prop, struct qpnp_vadc_result *chan_rslt) { return -ENXIO; } static inline int32_t qpnp_adc_scale_therm_pu2(int32_t adc_code, const struct qpnp_adc_properties *adc_prop, const struct qpnp_vadc_chan_properties *chan_prop, struct qpnp_vadc_result *chan_rslt) { return -ENXIO; } static inline int32_t qpnp_vadc_is_ready(void) { return -ENXIO; } static inline int32_t qpnp_get_vadc_gain_and_offset( struct qpnp_vadc_linear_graph *param, enum qpnp_adc_calib_type calib_type) { return -ENXIO; } static inline int32_t qpnp_adc_usb_scaler( struct qpnp_adc_tm_btm_param *param, uint32_t *low_threshold, uint32_t *high_threshold) { return -ENXIO; } static inline int32_t qpnp_adc_vbatt_rscaler( struct qpnp_adc_tm_btm_param *param, uint32_t *low_threshold, uint32_t *high_threshold) { return -ENXIO; } static inline int32_t qpnp_adc_btm_scaler( struct qpnp_adc_tm_btm_param *param, uint32_t *low_threshold, uint32_t *high_threshold) { return -ENXIO; } static inline int32_t qpnp_adc_scale_millidegc_pmic_voltage_thr( struct qpnp_adc_tm_btm_param *param, uint32_t *low_threshold, uint32_t *high_threshold) { return -ENXIO; } static inline int32_t qpnp_adc_tm_scale_therm_voltage_pu2( struct qpnp_adc_tm_config *param) { return -ENXIO; } static inline int32_t qpnp_adc_tm_scale_voltage_therm_pu2( uint32_t reg, int64_t *result) { return -ENXIO; } static inline int32_t qpnp_vadc_iadc_sync_request( enum qpnp_vadc_channels channel) { return -ENXIO; } static inline int32_t qpnp_vadc_iadc_sync_complete_request( enum qpnp_vadc_channels channel, struct qpnp_vadc_result *result) { return -ENXIO; } static inline int32_t qpnp_vbat_sns_comp_result(int64_t *result) { return -ENXIO; } #endif /* Public API */ #if defined(CONFIG_SENSORS_QPNP_ADC_CURRENT) \ || defined(CONFIG_SENSORS_QPNP_ADC_CURRENT_MODULE) /** * qpnp_iadc_read() - Performs ADC read on the current channel. * @channel: Input channel to perform the ADC read. * @result: Current across rsense in mA. */ int32_t qpnp_iadc_read(enum qpnp_iadc_channels channel, struct qpnp_iadc_result *result); /** * qpnp_iadc_get_rsense() - Reads the RDS resistance value from the trim registers. * @rsense: RDS resistance in nOhms. */ int32_t qpnp_iadc_get_rsense(int32_t *rsense); /** * qpnp_iadc_get_gain_and_offset() - Performs gain calibration * over 17.8571mV and offset over selected * channel. Channel can be internal rsense, * external rsense and alternate lead pair. * @result: result structure where the gain and offset is stored of * type qpnp_iadc_calib. */ int32_t qpnp_iadc_get_gain_and_offset(struct qpnp_iadc_calib *result); /** * qpnp_iadc_is_ready() - Clients can use this API to check if the * device is ready to use. * @result: 0 on success and -EPROBE_DEFER when probe for the device * has not occured. */ int32_t qpnp_iadc_is_ready(void); /** * qpnp_iadc_vadc_sync_read() - Performs synchronous VADC and IADC read. * The api is to be used only by the BMS to perform * simultaneous VADC and IADC measurement for battery voltage * and current. * @i_channel: Input battery current channel to perform the IADC read. * @i_result: Current across the rsense in mA. * @v_channel: Input battery voltage channel to perform VADC read. * @v_result: Voltage on the vbatt channel with units in mV. */ int32_t qpnp_iadc_vadc_sync_read( enum qpnp_iadc_channels i_channel, struct qpnp_iadc_result *i_result, enum qpnp_vadc_channels v_channel, struct qpnp_vadc_result *v_result); /** * qpnp_iadc_calibrate_for_trim() - Clients can use this API to re-calibrate * IADC. * @result: 0 on success. */ int32_t qpnp_iadc_calibrate_for_trim(void); int32_t qpnp_iadc_comp_result(int64_t *result); #else static inline int32_t qpnp_iadc_read(enum qpnp_iadc_channels channel, struct qpnp_iadc_result *result) { return -ENXIO; } static inline int32_t qpnp_iadc_get_rsense(int32_t *rsense) { return -ENXIO; } static inline int32_t qpnp_iadc_get_gain_and_offset(struct qpnp_iadc_calib *result) { return -ENXIO; } static inline int32_t qpnp_iadc_is_ready(void) { return -ENXIO; } static inline int32_t qpnp_iadc_vadc_sync_read( enum qpnp_iadc_channels i_channel, struct qpnp_iadc_result *i_result, enum qpnp_vadc_channels v_channel, struct qpnp_vadc_result *v_result) { return -ENXIO; } static inline int32_t qpnp_iadc_calibrate_for_trim(void) { return -ENXIO; } static inline int32_t qpnp_iadc_comp_result(int64_t *result, int32_t sign) { return -ENXIO; } #endif /* Public API */ #if defined(CONFIG_THERMAL_QPNP_ADC_TM) \ || defined(CONFIG_THERMAL_QPNP_ADC_TM_MODULE) /** * qpnp_adc_tm_usbid_configure() - Configures Channel 0 of VADC_BTM to * monitor USB_ID channel using 100k internal pull-up. * USB driver passes the high/low voltage threshold along * with the notification callback once the set thresholds * are crossed. * @param: Structure pointer of qpnp_adc_tm_usbid_param type. * Clients pass the low/high voltage along with the threshold * notification callback. */ int32_t qpnp_adc_tm_usbid_configure(struct qpnp_adc_tm_btm_param *param); /** * qpnp_adc_tm_usbid_end() - Disables the monitoring of channel 0 thats * assigned for monitoring USB_ID. Disables the low/high * threshold activation for channel 0 as well. * @param: none. */ int32_t qpnp_adc_tm_usbid_end(void); /** * qpnp_adc_tm_channel_measure() - Configures kernel clients a channel to * monitor the corresponding ADC channel for threshold detection. * Driver passes the high/low voltage threshold along * with the notification callback once the set thresholds * are crossed. * @param: Structure pointer of qpnp_adc_tm_btm_param type. * Clients pass the low/high temperature along with the threshold * notification callback. */ int32_t qpnp_adc_tm_channel_measure(struct qpnp_adc_tm_btm_param *param); /** * qpnp_adc_tm_disable_chan_meas() - Disables the monitoring of channel thats * assigned for monitoring kernel clients. Disables the low/high * threshold activation for the corresponding channel. * @param: Structure pointer of qpnp_adc_tm_btm_param type. * This is used to identify the channel for which the corresponding * channels high/low threshold notification will be disabled. */ int32_t qpnp_adc_tm_disable_chan_meas(struct qpnp_adc_tm_btm_param *param); /** * qpnp_adc_tm_is_ready() - Clients can use this API to check if the * device is ready to use. * @result: 0 on success and -EPROBE_DEFER when probe for the device * has not occured. */ int32_t qpnp_adc_tm_is_ready(void); #else static inline int32_t qpnp_adc_tm_usbid_configure( struct qpnp_adc_tm_btm_param *param) { return -ENXIO; } static inline int32_t qpnp_adc_tm_usbid_end(void) { return -ENXIO; } static inline int32_t qpnp_adc_tm_channel_measure( struct qpnp_adc_tm_btm_param *param) { return -ENXIO; } static inline int32_t qpnp_adc_tm_disable_chan_meas(void) { return -ENXIO; } static inline int32_t qpnp_adc_tm_is_ready(void) { return -ENXIO; } #endif #endif