Author | Tokens | Token Proportion | Commits | Commit Proportion |
---|---|---|---|---|
Tony Lindgren | 4297 | 99.24% | 4 | 33.33% |
Jonathan Cameron | 23 | 0.53% | 3 | 25.00% |
Gustavo A. R. Silva | 3 | 0.07% | 2 | 16.67% |
Lee Jones | 3 | 0.07% | 1 | 8.33% |
Pan Bian | 2 | 0.05% | 1 | 8.33% |
Thomas Gleixner | 2 | 0.05% | 1 | 8.33% |
Total | 4330 | 12 |
// SPDX-License-Identifier: GPL-2.0-only /* * Copyright (C) 2017 Tony Lindgren <tony@atomide.com> * * Rewritten for Linux IIO framework with some code based on * earlier driver found in the Motorola Linux kernel: * * Copyright (C) 2009-2010 Motorola, Inc. */ #include <linux/delay.h> #include <linux/device.h> #include <linux/err.h> #include <linux/init.h> #include <linux/interrupt.h> #include <linux/kernel.h> #include <linux/module.h> #include <linux/mod_devicetable.h> #include <linux/platform_device.h> #include <linux/property.h> #include <linux/regmap.h> #include <linux/iio/buffer.h> #include <linux/iio/driver.h> #include <linux/iio/iio.h> #include <linux/iio/kfifo_buf.h> #include <linux/mfd/motorola-cpcap.h> /* Register CPCAP_REG_ADCC1 bits */ #define CPCAP_BIT_ADEN_AUTO_CLR BIT(15) /* Currently unused */ #define CPCAP_BIT_CAL_MODE BIT(14) /* Set with BIT_RAND0 */ #define CPCAP_BIT_ADC_CLK_SEL1 BIT(13) /* Currently unused */ #define CPCAP_BIT_ADC_CLK_SEL0 BIT(12) /* Currently unused */ #define CPCAP_BIT_ATOX BIT(11) #define CPCAP_BIT_ATO3 BIT(10) #define CPCAP_BIT_ATO2 BIT(9) #define CPCAP_BIT_ATO1 BIT(8) #define CPCAP_BIT_ATO0 BIT(7) #define CPCAP_BIT_ADA2 BIT(6) #define CPCAP_BIT_ADA1 BIT(5) #define CPCAP_BIT_ADA0 BIT(4) #define CPCAP_BIT_AD_SEL1 BIT(3) /* Set for bank1 */ #define CPCAP_BIT_RAND1 BIT(2) /* Set for channel 16 & 17 */ #define CPCAP_BIT_RAND0 BIT(1) /* Set with CAL_MODE */ #define CPCAP_BIT_ADEN BIT(0) /* Currently unused */ #define CPCAP_REG_ADCC1_DEFAULTS (CPCAP_BIT_ADEN_AUTO_CLR | \ CPCAP_BIT_ADC_CLK_SEL0 | \ CPCAP_BIT_RAND1) /* Register CPCAP_REG_ADCC2 bits */ #define CPCAP_BIT_CAL_FACTOR_ENABLE BIT(15) /* Currently unused */ #define CPCAP_BIT_BATDETB_EN BIT(14) /* Currently unused */ #define CPCAP_BIT_ADTRIG_ONESHOT BIT(13) /* Set for !TIMING_IMM */ #define CPCAP_BIT_ASC BIT(12) /* Set for TIMING_IMM */ #define CPCAP_BIT_ATOX_PS_FACTOR BIT(11) #define CPCAP_BIT_ADC_PS_FACTOR1 BIT(10) #define CPCAP_BIT_ADC_PS_FACTOR0 BIT(9) #define CPCAP_BIT_AD4_SELECT BIT(8) /* Currently unused */ #define CPCAP_BIT_ADC_BUSY BIT(7) /* Currently unused */ #define CPCAP_BIT_THERMBIAS_EN BIT(6) /* Bias for AD0_BATTDETB */ #define CPCAP_BIT_ADTRIG_DIS BIT(5) /* Disable interrupt */ #define CPCAP_BIT_LIADC BIT(4) /* Currently unused */ #define CPCAP_BIT_TS_REFEN BIT(3) /* Currently unused */ #define CPCAP_BIT_TS_M2 BIT(2) /* Currently unused */ #define CPCAP_BIT_TS_M1 BIT(1) /* Currently unused */ #define CPCAP_BIT_TS_M0 BIT(0) /* Currently unused */ #define CPCAP_REG_ADCC2_DEFAULTS (CPCAP_BIT_AD4_SELECT | \ CPCAP_BIT_ADTRIG_DIS | \ CPCAP_BIT_LIADC | \ CPCAP_BIT_TS_M2 | \ CPCAP_BIT_TS_M1) #define CPCAP_MAX_TEMP_LVL 27 #define CPCAP_FOUR_POINT_TWO_ADC 801 #define ST_ADC_CAL_CHRGI_HIGH_THRESHOLD 530 #define ST_ADC_CAL_CHRGI_LOW_THRESHOLD 494 #define ST_ADC_CAL_BATTI_HIGH_THRESHOLD 530 #define ST_ADC_CAL_BATTI_LOW_THRESHOLD 494 #define ST_ADC_CALIBRATE_DIFF_THRESHOLD 3 #define CPCAP_ADC_MAX_RETRIES 5 /* Calibration */ /* * struct cpcap_adc_ato - timing settings for cpcap adc * * Unfortunately no cpcap documentation available, please document when * using these. */ struct cpcap_adc_ato { unsigned short ato_in; unsigned short atox_in; unsigned short adc_ps_factor_in; unsigned short atox_ps_factor_in; unsigned short ato_out; unsigned short atox_out; unsigned short adc_ps_factor_out; unsigned short atox_ps_factor_out; }; /** * struct cpcap_adc - cpcap adc device driver data * @reg: cpcap regmap * @dev: struct device * @vendor: cpcap vendor * @irq: interrupt * @lock: mutex * @ato: request timings * @wq_data_avail: work queue * @done: work done */ struct cpcap_adc { struct regmap *reg; struct device *dev; u16 vendor; int irq; struct mutex lock; /* ADC register access lock */ const struct cpcap_adc_ato *ato; wait_queue_head_t wq_data_avail; bool done; }; /* * enum cpcap_adc_channel - cpcap adc channels */ enum cpcap_adc_channel { /* Bank0 channels */ CPCAP_ADC_AD0, /* Battery temperature */ CPCAP_ADC_BATTP, /* Battery voltage */ CPCAP_ADC_VBUS, /* USB VBUS voltage */ CPCAP_ADC_AD3, /* Die temperature when charging */ CPCAP_ADC_BPLUS_AD4, /* Another battery or system voltage */ CPCAP_ADC_CHG_ISENSE, /* Calibrated charge current */ CPCAP_ADC_BATTI, /* Calibrated system current */ CPCAP_ADC_USB_ID, /* USB OTG ID, unused on droid 4? */ /* Bank1 channels */ CPCAP_ADC_AD8, /* Seems unused */ CPCAP_ADC_AD9, /* Seems unused */ CPCAP_ADC_LICELL, /* Maybe system voltage? Always 3V */ CPCAP_ADC_HV_BATTP, /* Another battery detection? */ CPCAP_ADC_TSX1_AD12, /* Seems unused, for touchscreen? */ CPCAP_ADC_TSX2_AD13, /* Seems unused, for touchscreen? */ CPCAP_ADC_TSY1_AD14, /* Seems unused, for touchscreen? */ CPCAP_ADC_TSY2_AD15, /* Seems unused, for touchscreen? */ /* Remuxed channels using bank0 entries */ CPCAP_ADC_BATTP_PI16, /* Alternative mux mode for BATTP */ CPCAP_ADC_BATTI_PI17, /* Alternative mux mode for BATTI */ CPCAP_ADC_CHANNEL_NUM, }; /* * enum cpcap_adc_timing - cpcap adc timing options * * CPCAP_ADC_TIMING_IMM seems to be immediate with no timings. * Please document when using. */ enum cpcap_adc_timing { CPCAP_ADC_TIMING_IMM, CPCAP_ADC_TIMING_IN, CPCAP_ADC_TIMING_OUT, }; /** * struct cpcap_adc_phasing_tbl - cpcap phasing table * @offset: offset in the phasing table * @multiplier: multiplier in the phasing table * @divider: divider in the phasing table * @min: minimum value * @max: maximum value */ struct cpcap_adc_phasing_tbl { short offset; unsigned short multiplier; unsigned short divider; short min; short max; }; /** * struct cpcap_adc_conversion_tbl - cpcap conversion table * @conv_type: conversion type * @align_offset: align offset * @conv_offset: conversion offset * @cal_offset: calibration offset * @multiplier: conversion multiplier * @divider: conversion divider */ struct cpcap_adc_conversion_tbl { enum iio_chan_info_enum conv_type; int align_offset; int conv_offset; int cal_offset; int multiplier; int divider; }; /** * struct cpcap_adc_request - cpcap adc request * @channel: request channel * @phase_tbl: channel phasing table * @conv_tbl: channel conversion table * @bank_index: channel index within the bank * @timing: timing settings * @result: result */ struct cpcap_adc_request { int channel; const struct cpcap_adc_phasing_tbl *phase_tbl; const struct cpcap_adc_conversion_tbl *conv_tbl; int bank_index; enum cpcap_adc_timing timing; int result; }; /* Phasing table for channels. Note that channels 16 & 17 use BATTP and BATTI */ static const struct cpcap_adc_phasing_tbl bank_phasing[] = { /* Bank0 */ [CPCAP_ADC_AD0] = {0, 0x80, 0x80, 0, 1023}, [CPCAP_ADC_BATTP] = {0, 0x80, 0x80, 0, 1023}, [CPCAP_ADC_VBUS] = {0, 0x80, 0x80, 0, 1023}, [CPCAP_ADC_AD3] = {0, 0x80, 0x80, 0, 1023}, [CPCAP_ADC_BPLUS_AD4] = {0, 0x80, 0x80, 0, 1023}, [CPCAP_ADC_CHG_ISENSE] = {0, 0x80, 0x80, -512, 511}, [CPCAP_ADC_BATTI] = {0, 0x80, 0x80, -512, 511}, [CPCAP_ADC_USB_ID] = {0, 0x80, 0x80, 0, 1023}, /* Bank1 */ [CPCAP_ADC_AD8] = {0, 0x80, 0x80, 0, 1023}, [CPCAP_ADC_AD9] = {0, 0x80, 0x80, 0, 1023}, [CPCAP_ADC_LICELL] = {0, 0x80, 0x80, 0, 1023}, [CPCAP_ADC_HV_BATTP] = {0, 0x80, 0x80, 0, 1023}, [CPCAP_ADC_TSX1_AD12] = {0, 0x80, 0x80, 0, 1023}, [CPCAP_ADC_TSX2_AD13] = {0, 0x80, 0x80, 0, 1023}, [CPCAP_ADC_TSY1_AD14] = {0, 0x80, 0x80, 0, 1023}, [CPCAP_ADC_TSY2_AD15] = {0, 0x80, 0x80, 0, 1023}, }; /* * Conversion table for channels. Updated during init based on calibration. * Here too channels 16 & 17 use BATTP and BATTI. */ static struct cpcap_adc_conversion_tbl bank_conversion[] = { /* Bank0 */ [CPCAP_ADC_AD0] = { IIO_CHAN_INFO_PROCESSED, 0, 0, 0, 1, 1, }, [CPCAP_ADC_BATTP] = { IIO_CHAN_INFO_PROCESSED, 0, 2400, 0, 2300, 1023, }, [CPCAP_ADC_VBUS] = { IIO_CHAN_INFO_PROCESSED, 0, 0, 0, 10000, 1023, }, [CPCAP_ADC_AD3] = { IIO_CHAN_INFO_PROCESSED, 0, 0, 0, 1, 1, }, [CPCAP_ADC_BPLUS_AD4] = { IIO_CHAN_INFO_PROCESSED, 0, 2400, 0, 2300, 1023, }, [CPCAP_ADC_CHG_ISENSE] = { IIO_CHAN_INFO_PROCESSED, -512, 2, 0, 5000, 1023, }, [CPCAP_ADC_BATTI] = { IIO_CHAN_INFO_PROCESSED, -512, 2, 0, 5000, 1023, }, [CPCAP_ADC_USB_ID] = { IIO_CHAN_INFO_RAW, 0, 0, 0, 1, 1, }, /* Bank1 */ [CPCAP_ADC_AD8] = { IIO_CHAN_INFO_RAW, 0, 0, 0, 1, 1, }, [CPCAP_ADC_AD9] = { IIO_CHAN_INFO_RAW, 0, 0, 0, 1, 1, }, [CPCAP_ADC_LICELL] = { IIO_CHAN_INFO_PROCESSED, 0, 0, 0, 3400, 1023, }, [CPCAP_ADC_HV_BATTP] = { IIO_CHAN_INFO_RAW, 0, 0, 0, 1, 1, }, [CPCAP_ADC_TSX1_AD12] = { IIO_CHAN_INFO_RAW, 0, 0, 0, 1, 1, }, [CPCAP_ADC_TSX2_AD13] = { IIO_CHAN_INFO_RAW, 0, 0, 0, 1, 1, }, [CPCAP_ADC_TSY1_AD14] = { IIO_CHAN_INFO_RAW, 0, 0, 0, 1, 1, }, [CPCAP_ADC_TSY2_AD15] = { IIO_CHAN_INFO_RAW, 0, 0, 0, 1, 1, }, }; /* * Temperature lookup table of register values to milliCelcius. * REVISIT: Check the duplicate 0x3ff entry in a freezer */ static const int temp_map[CPCAP_MAX_TEMP_LVL][2] = { { 0x03ff, -40000 }, { 0x03ff, -35000 }, { 0x03ef, -30000 }, { 0x03b2, -25000 }, { 0x036c, -20000 }, { 0x0320, -15000 }, { 0x02d0, -10000 }, { 0x027f, -5000 }, { 0x022f, 0 }, { 0x01e4, 5000 }, { 0x019f, 10000 }, { 0x0161, 15000 }, { 0x012b, 20000 }, { 0x00fc, 25000 }, { 0x00d4, 30000 }, { 0x00b2, 35000 }, { 0x0095, 40000 }, { 0x007d, 45000 }, { 0x0069, 50000 }, { 0x0059, 55000 }, { 0x004b, 60000 }, { 0x003f, 65000 }, { 0x0036, 70000 }, { 0x002e, 75000 }, { 0x0027, 80000 }, { 0x0022, 85000 }, { 0x001d, 90000 }, }; #define CPCAP_CHAN(_type, _index, _address, _datasheet_name) { \ .type = (_type), \ .address = (_address), \ .indexed = 1, \ .channel = (_index), \ .info_mask_separate = BIT(IIO_CHAN_INFO_RAW) | \ BIT(IIO_CHAN_INFO_PROCESSED), \ .scan_index = (_index), \ .scan_type = { \ .sign = 'u', \ .realbits = 10, \ .storagebits = 16, \ .endianness = IIO_CPU, \ }, \ .datasheet_name = (_datasheet_name), \ } /* * The datasheet names are from Motorola mapphone Linux kernel except * for the last two which might be uncalibrated charge voltage and * current. */ static const struct iio_chan_spec cpcap_adc_channels[] = { /* Bank0 */ CPCAP_CHAN(IIO_TEMP, 0, CPCAP_REG_ADCD0, "battdetb"), CPCAP_CHAN(IIO_VOLTAGE, 1, CPCAP_REG_ADCD1, "battp"), CPCAP_CHAN(IIO_VOLTAGE, 2, CPCAP_REG_ADCD2, "vbus"), CPCAP_CHAN(IIO_TEMP, 3, CPCAP_REG_ADCD3, "ad3"), CPCAP_CHAN(IIO_VOLTAGE, 4, CPCAP_REG_ADCD4, "ad4"), CPCAP_CHAN(IIO_CURRENT, 5, CPCAP_REG_ADCD5, "chg_isense"), CPCAP_CHAN(IIO_CURRENT, 6, CPCAP_REG_ADCD6, "batti"), CPCAP_CHAN(IIO_VOLTAGE, 7, CPCAP_REG_ADCD7, "usb_id"), /* Bank1 */ CPCAP_CHAN(IIO_CURRENT, 8, CPCAP_REG_ADCD0, "ad8"), CPCAP_CHAN(IIO_VOLTAGE, 9, CPCAP_REG_ADCD1, "ad9"), CPCAP_CHAN(IIO_VOLTAGE, 10, CPCAP_REG_ADCD2, "licell"), CPCAP_CHAN(IIO_VOLTAGE, 11, CPCAP_REG_ADCD3, "hv_battp"), CPCAP_CHAN(IIO_VOLTAGE, 12, CPCAP_REG_ADCD4, "tsx1_ad12"), CPCAP_CHAN(IIO_VOLTAGE, 13, CPCAP_REG_ADCD5, "tsx2_ad13"), CPCAP_CHAN(IIO_VOLTAGE, 14, CPCAP_REG_ADCD6, "tsy1_ad14"), CPCAP_CHAN(IIO_VOLTAGE, 15, CPCAP_REG_ADCD7, "tsy2_ad15"), /* There are two registers with multiplexed functionality */ CPCAP_CHAN(IIO_VOLTAGE, 16, CPCAP_REG_ADCD0, "chg_vsense"), CPCAP_CHAN(IIO_CURRENT, 17, CPCAP_REG_ADCD1, "batti2"), }; static irqreturn_t cpcap_adc_irq_thread(int irq, void *data) { struct iio_dev *indio_dev = data; struct cpcap_adc *ddata = iio_priv(indio_dev); int error; error = regmap_update_bits(ddata->reg, CPCAP_REG_ADCC2, CPCAP_BIT_ADTRIG_DIS, CPCAP_BIT_ADTRIG_DIS); if (error) return IRQ_NONE; ddata->done = true; wake_up_interruptible(&ddata->wq_data_avail); return IRQ_HANDLED; } /* ADC calibration functions */ static void cpcap_adc_setup_calibrate(struct cpcap_adc *ddata, enum cpcap_adc_channel chan) { unsigned int value = 0; unsigned long timeout = jiffies + msecs_to_jiffies(3000); int error; if ((chan != CPCAP_ADC_CHG_ISENSE) && (chan != CPCAP_ADC_BATTI)) return; value |= CPCAP_BIT_CAL_MODE | CPCAP_BIT_RAND0; value |= ((chan << 4) & (CPCAP_BIT_ADA2 | CPCAP_BIT_ADA1 | CPCAP_BIT_ADA0)); error = regmap_update_bits(ddata->reg, CPCAP_REG_ADCC1, CPCAP_BIT_CAL_MODE | CPCAP_BIT_ATOX | CPCAP_BIT_ATO3 | CPCAP_BIT_ATO2 | CPCAP_BIT_ATO1 | CPCAP_BIT_ATO0 | CPCAP_BIT_ADA2 | CPCAP_BIT_ADA1 | CPCAP_BIT_ADA0 | CPCAP_BIT_AD_SEL1 | CPCAP_BIT_RAND1 | CPCAP_BIT_RAND0, value); if (error) return; error = regmap_update_bits(ddata->reg, CPCAP_REG_ADCC2, CPCAP_BIT_ATOX_PS_FACTOR | CPCAP_BIT_ADC_PS_FACTOR1 | CPCAP_BIT_ADC_PS_FACTOR0, 0); if (error) return; error = regmap_update_bits(ddata->reg, CPCAP_REG_ADCC2, CPCAP_BIT_ADTRIG_DIS, CPCAP_BIT_ADTRIG_DIS); if (error) return; error = regmap_update_bits(ddata->reg, CPCAP_REG_ADCC2, CPCAP_BIT_ASC, CPCAP_BIT_ASC); if (error) return; do { schedule_timeout_uninterruptible(1); error = regmap_read(ddata->reg, CPCAP_REG_ADCC2, &value); if (error) return; } while ((value & CPCAP_BIT_ASC) && time_before(jiffies, timeout)); if (value & CPCAP_BIT_ASC) dev_err(ddata->dev, "Timeout waiting for calibration to complete\n"); error = regmap_update_bits(ddata->reg, CPCAP_REG_ADCC1, CPCAP_BIT_CAL_MODE, 0); if (error) return; } static int cpcap_adc_calibrate_one(struct cpcap_adc *ddata, int channel, u16 calibration_register, int lower_threshold, int upper_threshold) { unsigned int calibration_data[2]; unsigned short cal_data_diff; int i, error; for (i = 0; i < CPCAP_ADC_MAX_RETRIES; i++) { calibration_data[0] = 0; calibration_data[1] = 0; cpcap_adc_setup_calibrate(ddata, channel); error = regmap_read(ddata->reg, calibration_register, &calibration_data[0]); if (error) return error; cpcap_adc_setup_calibrate(ddata, channel); error = regmap_read(ddata->reg, calibration_register, &calibration_data[1]); if (error) return error; if (calibration_data[0] > calibration_data[1]) cal_data_diff = calibration_data[0] - calibration_data[1]; else cal_data_diff = calibration_data[1] - calibration_data[0]; if (((calibration_data[1] >= lower_threshold) && (calibration_data[1] <= upper_threshold) && (cal_data_diff <= ST_ADC_CALIBRATE_DIFF_THRESHOLD)) || (ddata->vendor == CPCAP_VENDOR_TI)) { bank_conversion[channel].cal_offset = ((short)calibration_data[1] * -1) + 512; dev_dbg(ddata->dev, "ch%i calibration complete: %i\n", channel, bank_conversion[channel].cal_offset); break; } usleep_range(5000, 10000); } return 0; } static int cpcap_adc_calibrate(struct cpcap_adc *ddata) { int error; error = cpcap_adc_calibrate_one(ddata, CPCAP_ADC_CHG_ISENSE, CPCAP_REG_ADCAL1, ST_ADC_CAL_CHRGI_LOW_THRESHOLD, ST_ADC_CAL_CHRGI_HIGH_THRESHOLD); if (error) return error; error = cpcap_adc_calibrate_one(ddata, CPCAP_ADC_BATTI, CPCAP_REG_ADCAL2, ST_ADC_CAL_BATTI_LOW_THRESHOLD, ST_ADC_CAL_BATTI_HIGH_THRESHOLD); if (error) return error; return 0; } /* ADC setup, read and scale functions */ static void cpcap_adc_setup_bank(struct cpcap_adc *ddata, struct cpcap_adc_request *req) { const struct cpcap_adc_ato *ato = ddata->ato; unsigned short value1 = 0; unsigned short value2 = 0; int error; if (!ato) return; switch (req->channel) { case CPCAP_ADC_AD0: value2 |= CPCAP_BIT_THERMBIAS_EN; error = regmap_update_bits(ddata->reg, CPCAP_REG_ADCC2, CPCAP_BIT_THERMBIAS_EN, value2); if (error) return; usleep_range(800, 1000); break; case CPCAP_ADC_AD8 ... CPCAP_ADC_TSY2_AD15: value1 |= CPCAP_BIT_AD_SEL1; break; case CPCAP_ADC_BATTP_PI16 ... CPCAP_ADC_BATTI_PI17: value1 |= CPCAP_BIT_RAND1; break; default: break; } switch (req->timing) { case CPCAP_ADC_TIMING_IN: value1 |= ato->ato_in; value1 |= ato->atox_in; value2 |= ato->adc_ps_factor_in; value2 |= ato->atox_ps_factor_in; break; case CPCAP_ADC_TIMING_OUT: value1 |= ato->ato_out; value1 |= ato->atox_out; value2 |= ato->adc_ps_factor_out; value2 |= ato->atox_ps_factor_out; break; case CPCAP_ADC_TIMING_IMM: default: break; } error = regmap_update_bits(ddata->reg, CPCAP_REG_ADCC1, CPCAP_BIT_CAL_MODE | CPCAP_BIT_ATOX | CPCAP_BIT_ATO3 | CPCAP_BIT_ATO2 | CPCAP_BIT_ATO1 | CPCAP_BIT_ATO0 | CPCAP_BIT_ADA2 | CPCAP_BIT_ADA1 | CPCAP_BIT_ADA0 | CPCAP_BIT_AD_SEL1 | CPCAP_BIT_RAND1 | CPCAP_BIT_RAND0, value1); if (error) return; error = regmap_update_bits(ddata->reg, CPCAP_REG_ADCC2, CPCAP_BIT_ATOX_PS_FACTOR | CPCAP_BIT_ADC_PS_FACTOR1 | CPCAP_BIT_ADC_PS_FACTOR0 | CPCAP_BIT_THERMBIAS_EN, value2); if (error) return; if (req->timing == CPCAP_ADC_TIMING_IMM) { error = regmap_update_bits(ddata->reg, CPCAP_REG_ADCC2, CPCAP_BIT_ADTRIG_DIS, CPCAP_BIT_ADTRIG_DIS); if (error) return; error = regmap_update_bits(ddata->reg, CPCAP_REG_ADCC2, CPCAP_BIT_ASC, CPCAP_BIT_ASC); if (error) return; } else { error = regmap_update_bits(ddata->reg, CPCAP_REG_ADCC2, CPCAP_BIT_ADTRIG_ONESHOT, CPCAP_BIT_ADTRIG_ONESHOT); if (error) return; error = regmap_update_bits(ddata->reg, CPCAP_REG_ADCC2, CPCAP_BIT_ADTRIG_DIS, 0); if (error) return; } } static int cpcap_adc_start_bank(struct cpcap_adc *ddata, struct cpcap_adc_request *req) { int i, error; req->timing = CPCAP_ADC_TIMING_IMM; ddata->done = false; for (i = 0; i < CPCAP_ADC_MAX_RETRIES; i++) { cpcap_adc_setup_bank(ddata, req); error = wait_event_interruptible_timeout(ddata->wq_data_avail, ddata->done, msecs_to_jiffies(50)); if (error > 0) return 0; if (error == 0) { error = -ETIMEDOUT; continue; } if (error < 0) return error; } return error; } static int cpcap_adc_stop_bank(struct cpcap_adc *ddata) { int error; error = regmap_update_bits(ddata->reg, CPCAP_REG_ADCC1, 0xffff, CPCAP_REG_ADCC1_DEFAULTS); if (error) return error; return regmap_update_bits(ddata->reg, CPCAP_REG_ADCC2, 0xffff, CPCAP_REG_ADCC2_DEFAULTS); } static void cpcap_adc_phase(struct cpcap_adc_request *req) { const struct cpcap_adc_conversion_tbl *conv_tbl = req->conv_tbl; const struct cpcap_adc_phasing_tbl *phase_tbl = req->phase_tbl; int index = req->channel; /* Remuxed channels 16 and 17 use BATTP and BATTI entries */ switch (req->channel) { case CPCAP_ADC_BATTP: case CPCAP_ADC_BATTP_PI16: index = req->bank_index; req->result -= phase_tbl[index].offset; req->result -= CPCAP_FOUR_POINT_TWO_ADC; req->result *= phase_tbl[index].multiplier; if (phase_tbl[index].divider == 0) return; req->result /= phase_tbl[index].divider; req->result += CPCAP_FOUR_POINT_TWO_ADC; break; case CPCAP_ADC_BATTI_PI17: index = req->bank_index; fallthrough; default: req->result += conv_tbl[index].cal_offset; req->result += conv_tbl[index].align_offset; req->result *= phase_tbl[index].multiplier; if (phase_tbl[index].divider == 0) return; req->result /= phase_tbl[index].divider; req->result += phase_tbl[index].offset; break; } if (req->result < phase_tbl[index].min) req->result = phase_tbl[index].min; else if (req->result > phase_tbl[index].max) req->result = phase_tbl[index].max; } /* Looks up temperatures in a table and calculates averages if needed */ static int cpcap_adc_table_to_millicelcius(unsigned short value) { int i, result = 0, alpha; if (value <= temp_map[CPCAP_MAX_TEMP_LVL - 1][0]) return temp_map[CPCAP_MAX_TEMP_LVL - 1][1]; if (value >= temp_map[0][0]) return temp_map[0][1]; for (i = 0; i < CPCAP_MAX_TEMP_LVL - 1; i++) { if ((value <= temp_map[i][0]) && (value >= temp_map[i + 1][0])) { if (value == temp_map[i][0]) { result = temp_map[i][1]; } else if (value == temp_map[i + 1][0]) { result = temp_map[i + 1][1]; } else { alpha = ((value - temp_map[i][0]) * 1000) / (temp_map[i + 1][0] - temp_map[i][0]); result = temp_map[i][1] + ((alpha * (temp_map[i + 1][1] - temp_map[i][1])) / 1000); } break; } } return result; } static void cpcap_adc_convert(struct cpcap_adc_request *req) { const struct cpcap_adc_conversion_tbl *conv_tbl = req->conv_tbl; int index = req->channel; /* Remuxed channels 16 and 17 use BATTP and BATTI entries */ switch (req->channel) { case CPCAP_ADC_BATTP_PI16: index = CPCAP_ADC_BATTP; break; case CPCAP_ADC_BATTI_PI17: index = CPCAP_ADC_BATTI; break; default: break; } /* No conversion for raw channels */ if (conv_tbl[index].conv_type == IIO_CHAN_INFO_RAW) return; /* Temperatures use a lookup table instead of conversion table */ if ((req->channel == CPCAP_ADC_AD0) || (req->channel == CPCAP_ADC_AD3)) { req->result = cpcap_adc_table_to_millicelcius(req->result); return; } /* All processed channels use a conversion table */ req->result *= conv_tbl[index].multiplier; if (conv_tbl[index].divider == 0) return; req->result /= conv_tbl[index].divider; req->result += conv_tbl[index].conv_offset; } /* * REVISIT: Check if timed sampling can use multiple channels at the * same time. If not, replace channel_mask with just channel. */ static int cpcap_adc_read_bank_scaled(struct cpcap_adc *ddata, struct cpcap_adc_request *req) { int calibration_data, error, addr; if (ddata->vendor == CPCAP_VENDOR_TI) { error = regmap_read(ddata->reg, CPCAP_REG_ADCAL1, &calibration_data); if (error) return error; bank_conversion[CPCAP_ADC_CHG_ISENSE].cal_offset = ((short)calibration_data * -1) + 512; error = regmap_read(ddata->reg, CPCAP_REG_ADCAL2, &calibration_data); if (error) return error; bank_conversion[CPCAP_ADC_BATTI].cal_offset = ((short)calibration_data * -1) + 512; } addr = CPCAP_REG_ADCD0 + req->bank_index * 4; error = regmap_read(ddata->reg, addr, &req->result); if (error) return error; req->result &= 0x3ff; cpcap_adc_phase(req); cpcap_adc_convert(req); return 0; } static int cpcap_adc_init_request(struct cpcap_adc_request *req, int channel) { req->channel = channel; req->phase_tbl = bank_phasing; req->conv_tbl = bank_conversion; switch (channel) { case CPCAP_ADC_AD0 ... CPCAP_ADC_USB_ID: req->bank_index = channel; break; case CPCAP_ADC_AD8 ... CPCAP_ADC_TSY2_AD15: req->bank_index = channel - 8; break; case CPCAP_ADC_BATTP_PI16: req->bank_index = CPCAP_ADC_BATTP; break; case CPCAP_ADC_BATTI_PI17: req->bank_index = CPCAP_ADC_BATTI; break; default: return -EINVAL; } return 0; } static int cpcap_adc_read_st_die_temp(struct cpcap_adc *ddata, int addr, int *val) { int error; error = regmap_read(ddata->reg, addr, val); if (error) return error; *val -= 282; *val *= 114; *val += 25000; return 0; } static int cpcap_adc_read(struct iio_dev *indio_dev, struct iio_chan_spec const *chan, int *val, int *val2, long mask) { struct cpcap_adc *ddata = iio_priv(indio_dev); struct cpcap_adc_request req; int error; error = cpcap_adc_init_request(&req, chan->channel); if (error) return error; switch (mask) { case IIO_CHAN_INFO_RAW: mutex_lock(&ddata->lock); error = cpcap_adc_start_bank(ddata, &req); if (error) goto err_unlock; error = regmap_read(ddata->reg, chan->address, val); if (error) goto err_unlock; error = cpcap_adc_stop_bank(ddata); if (error) goto err_unlock; mutex_unlock(&ddata->lock); break; case IIO_CHAN_INFO_PROCESSED: mutex_lock(&ddata->lock); error = cpcap_adc_start_bank(ddata, &req); if (error) goto err_unlock; if ((ddata->vendor == CPCAP_VENDOR_ST) && (chan->channel == CPCAP_ADC_AD3)) { error = cpcap_adc_read_st_die_temp(ddata, chan->address, &req.result); if (error) goto err_unlock; } else { error = cpcap_adc_read_bank_scaled(ddata, &req); if (error) goto err_unlock; } error = cpcap_adc_stop_bank(ddata); if (error) goto err_unlock; mutex_unlock(&ddata->lock); *val = req.result; break; default: return -EINVAL; } return IIO_VAL_INT; err_unlock: mutex_unlock(&ddata->lock); dev_err(ddata->dev, "error reading ADC: %i\n", error); return error; } static const struct iio_info cpcap_adc_info = { .read_raw = &cpcap_adc_read, }; /* * Configuration for Motorola mapphone series such as droid 4. * Copied from the Motorola mapphone kernel tree. */ static const struct cpcap_adc_ato mapphone_adc = { .ato_in = 0x0480, .atox_in = 0, .adc_ps_factor_in = 0x0200, .atox_ps_factor_in = 0, .ato_out = 0, .atox_out = 0, .adc_ps_factor_out = 0, .atox_ps_factor_out = 0, }; static const struct of_device_id cpcap_adc_id_table[] = { { .compatible = "motorola,cpcap-adc", }, { .compatible = "motorola,mapphone-cpcap-adc", .data = &mapphone_adc, }, { /* sentinel */ }, }; MODULE_DEVICE_TABLE(of, cpcap_adc_id_table); static int cpcap_adc_probe(struct platform_device *pdev) { struct cpcap_adc *ddata; struct iio_dev *indio_dev; int error; indio_dev = devm_iio_device_alloc(&pdev->dev, sizeof(*ddata)); if (!indio_dev) { dev_err(&pdev->dev, "failed to allocate iio device\n"); return -ENOMEM; } ddata = iio_priv(indio_dev); ddata->ato = device_get_match_data(&pdev->dev); if (!ddata->ato) return -ENODEV; ddata->dev = &pdev->dev; mutex_init(&ddata->lock); init_waitqueue_head(&ddata->wq_data_avail); indio_dev->modes = INDIO_DIRECT_MODE | INDIO_BUFFER_SOFTWARE; indio_dev->channels = cpcap_adc_channels; indio_dev->num_channels = ARRAY_SIZE(cpcap_adc_channels); indio_dev->name = dev_name(&pdev->dev); indio_dev->info = &cpcap_adc_info; ddata->reg = dev_get_regmap(pdev->dev.parent, NULL); if (!ddata->reg) return -ENODEV; error = cpcap_get_vendor(ddata->dev, ddata->reg, &ddata->vendor); if (error) return error; platform_set_drvdata(pdev, indio_dev); ddata->irq = platform_get_irq_byname(pdev, "adcdone"); if (ddata->irq < 0) return -ENODEV; error = devm_request_threaded_irq(&pdev->dev, ddata->irq, NULL, cpcap_adc_irq_thread, IRQF_TRIGGER_NONE | IRQF_ONESHOT, "cpcap-adc", indio_dev); if (error) { dev_err(&pdev->dev, "could not get irq: %i\n", error); return error; } error = cpcap_adc_calibrate(ddata); if (error) return error; dev_info(&pdev->dev, "CPCAP ADC device probed\n"); return devm_iio_device_register(&pdev->dev, indio_dev); } static struct platform_driver cpcap_adc_driver = { .driver = { .name = "cpcap_adc", .of_match_table = cpcap_adc_id_table, }, .probe = cpcap_adc_probe, }; module_platform_driver(cpcap_adc_driver); MODULE_ALIAS("platform:cpcap_adc"); MODULE_DESCRIPTION("CPCAP ADC driver"); MODULE_AUTHOR("Tony Lindgren <tony@atomide.com"); MODULE_LICENSE("GPL v2");
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