// SPDX-License-Identifier: GPL-2.0+ /* * IIO driver for PAC1934 Multi-Channel DC Power/Energy Monitor * * Copyright (C) 2017-2024 Microchip Technology Inc. and its subsidiaries * * Author: Bogdan Bolocan * Author: Victor Tudose * Author: Marius Cristea * * Datasheet for PAC1931, PAC1932, PAC1933 and PAC1934 can be found here: * https://ww1.microchip.com/downloads/aemDocuments/documents/OTH/ProductDocuments/DataSheets/PAC1931-Family-Data-Sheet-DS20005850E.pdf */ #include #include #include #include #include #include #include #include /* * maximum accumulation time should be (17 * 60 * 1000) around 17 minutes@1024 sps * till PAC1934 accumulation registers starts to saturate */ #define PAC1934_MAX_RFSH_LIMIT_MS 60000 /* 50msec is the timeout for validity of the cached registers */ #define PAC1934_MIN_POLLING_TIME_MS 50 /* * 1000usec is the minimum wait time for normal conversions when sample * rate doesn't change */ #define PAC1934_MIN_UPDATE_WAIT_TIME_US 1000 /* 32000mV */ #define PAC1934_VOLTAGE_MILLIVOLTS_MAX 32000 /* voltage bits resolution when set for unsigned values */ #define PAC1934_VOLTAGE_U_RES 16 /* voltage bits resolution when set for signed values */ #define PAC1934_VOLTAGE_S_RES 15 /* * max signed value that can be stored on 32 bits and 8 digits fractional value * (2^31 - 1) * 10^8 + 99999999 */ #define PAC_193X_MAX_POWER_ACC 214748364799999999LL /* * min signed value that can be stored on 32 bits and 8 digits fractional value * -(2^31) * 10^8 - 99999999 */ #define PAC_193X_MIN_POWER_ACC -214748364899999999LL #define PAC1934_MAX_NUM_CHANNELS 4 #define PAC1934_MEAS_REG_LEN 76 #define PAC1934_CTRL_REG_LEN 12 #define PAC1934_DEFAULT_CHIP_SAMP_SPEED_HZ 1024 /* I2C address map */ #define PAC1934_REFRESH_REG_ADDR 0x00 #define PAC1934_CTRL_REG_ADDR 0x01 #define PAC1934_ACC_COUNT_REG_ADDR 0x02 #define PAC1934_VPOWER_ACC_1_ADDR 0x03 #define PAC1934_VPOWER_ACC_2_ADDR 0x04 #define PAC1934_VPOWER_ACC_3_ADDR 0x05 #define PAC1934_VPOWER_ACC_4_ADDR 0x06 #define PAC1934_VBUS_1_ADDR 0x07 #define PAC1934_VBUS_2_ADDR 0x08 #define PAC1934_VBUS_3_ADDR 0x09 #define PAC1934_VBUS_4_ADDR 0x0A #define PAC1934_VSENSE_1_ADDR 0x0B #define PAC1934_VSENSE_2_ADDR 0x0C #define PAC1934_VSENSE_3_ADDR 0x0D #define PAC1934_VSENSE_4_ADDR 0x0E #define PAC1934_VBUS_AVG_1_ADDR 0x0F #define PAC1934_VBUS_AVG_2_ADDR 0x10 #define PAC1934_VBUS_AVG_3_ADDR 0x11 #define PAC1934_VBUS_AVG_4_ADDR 0x12 #define PAC1934_VSENSE_AVG_1_ADDR 0x13 #define PAC1934_VSENSE_AVG_2_ADDR 0x14 #define PAC1934_VSENSE_AVG_3_ADDR 0x15 #define PAC1934_VSENSE_AVG_4_ADDR 0x16 #define PAC1934_VPOWER_1_ADDR 0x17 #define PAC1934_VPOWER_2_ADDR 0x18 #define PAC1934_VPOWER_3_ADDR 0x19 #define PAC1934_VPOWER_4_ADDR 0x1A #define PAC1934_REFRESH_V_REG_ADDR 0x1F #define PAC1934_CTRL_STAT_REGS_ADDR 0x1C #define PAC1934_PID_REG_ADDR 0xFD #define PAC1934_MID_REG_ADDR 0xFE #define PAC1934_RID_REG_ADDR 0xFF /* PRODUCT ID REGISTER + MANUFACTURER ID REGISTER + REVISION ID REGISTER */ #define PAC1934_ID_REG_LEN 3 #define PAC1934_PID_IDX 0 #define PAC1934_MID_IDX 1 #define PAC1934_RID_IDX 2 #define PAC1934_ACPI_GET_NAMES_AND_MOHMS_VALS 1 #define PAC1934_ACPI_GET_UOHMS_VALS 2 #define PAC1934_ACPI_GET_BIPOLAR_SETTINGS 4 #define PAC1934_ACPI_GET_SAMP 5 #define PAC1934_SAMPLE_RATE_SHIFT 6 #define PAC1934_VBUS_SENSE_REG_LEN 2 #define PAC1934_ACC_REG_LEN 3 #define PAC1934_VPOWER_REG_LEN 4 #define PAC1934_VPOWER_ACC_REG_LEN 6 #define PAC1934_MAX_REGISTER_LENGTH 6 #define PAC1934_CUSTOM_ATTR_FOR_CHANNEL 1 /* * relative offsets when using multi-byte reads/writes even though these * bytes are read one after the other, they are not at adjacent memory * locations within the I2C memory map. The chip can skip some addresses */ #define PAC1934_CHANNEL_DIS_REG_OFF 0 #define PAC1934_NEG_PWR_REG_OFF 1 /* * when reading/writing multiple bytes from offset PAC1934_CHANNEL_DIS_REG_OFF, * the chip jumps over the 0x1E (REFRESH_G) and 0x1F (REFRESH_V) offsets */ #define PAC1934_SLOW_REG_OFF 2 #define PAC1934_CTRL_ACT_REG_OFF 3 #define PAC1934_CHANNEL_DIS_ACT_REG_OFF 4 #define PAC1934_NEG_PWR_ACT_REG_OFF 5 #define PAC1934_CTRL_LAT_REG_OFF 6 #define PAC1934_CHANNEL_DIS_LAT_REG_OFF 7 #define PAC1934_NEG_PWR_LAT_REG_OFF 8 #define PAC1934_PID_REG_OFF 9 #define PAC1934_MID_REG_OFF 10 #define PAC1934_REV_REG_OFF 11 #define PAC1934_CTRL_STATUS_INFO_LEN 12 #define PAC1934_MID 0x5D #define PAC1931_PID 0x58 #define PAC1932_PID 0x59 #define PAC1933_PID 0x5A #define PAC1934_PID 0x5B /* Scale constant = (10^3 * 3.2 * 10^9 / 2^28) for mili Watt-second */ #define PAC1934_SCALE_CONSTANT 11921 #define PAC1934_MAX_VPOWER_RSHIFTED_BY_28B 11921 #define PAC1934_MAX_VSENSE_RSHIFTED_BY_16B 1525 #define PAC1934_DEV_ATTR(name) (&iio_dev_attr_##name.dev_attr.attr) #define PAC1934_CRTL_SAMPLE_RATE_MASK GENMASK(7, 6) #define PAC1934_CHAN_SLEEP_MASK BIT(5) #define PAC1934_CHAN_SLEEP_SET BIT(5) #define PAC1934_CHAN_SINGLE_MASK BIT(4) #define PAC1934_CHAN_SINGLE_SHOT_SET BIT(4) #define PAC1934_CHAN_ALERT_MASK BIT(3) #define PAC1934_CHAN_ALERT_EN BIT(3) #define PAC1934_CHAN_ALERT_CC_MASK BIT(2) #define PAC1934_CHAN_ALERT_CC_EN BIT(2) #define PAC1934_CHAN_OVF_ALERT_MASK BIT(1) #define PAC1934_CHAN_OVF_ALERT_EN BIT(1) #define PAC1934_CHAN_OVF_MASK BIT(0) #define PAC1934_CHAN_DIS_CH1_OFF_MASK BIT(7) #define PAC1934_CHAN_DIS_CH2_OFF_MASK BIT(6) #define PAC1934_CHAN_DIS_CH3_OFF_MASK BIT(5) #define PAC1934_CHAN_DIS_CH4_OFF_MASK BIT(4) #define PAC1934_SMBUS_TIMEOUT_MASK BIT(3) #define PAC1934_SMBUS_BYTECOUNT_MASK BIT(2) #define PAC1934_SMBUS_NO_SKIP_MASK BIT(1) #define PAC1934_NEG_PWR_CH1_BIDI_MASK BIT(7) #define PAC1934_NEG_PWR_CH2_BIDI_MASK BIT(6) #define PAC1934_NEG_PWR_CH3_BIDI_MASK BIT(5) #define PAC1934_NEG_PWR_CH4_BIDI_MASK BIT(4) #define PAC1934_NEG_PWR_CH1_BIDV_MASK BIT(3) #define PAC1934_NEG_PWR_CH2_BIDV_MASK BIT(2) #define PAC1934_NEG_PWR_CH3_BIDV_MASK BIT(1) #define PAC1934_NEG_PWR_CH4_BIDV_MASK BIT(0) /* * Universal Unique Identifier (UUID), * 033771E0-1705-47B4-9535-D1BBE14D9A09, * is reserved to Microchip for the PAC1934. */ #define PAC1934_DSM_UUID "033771E0-1705-47B4-9535-D1BBE14D9A09" enum pac1934_ids { PAC1931, PAC1932, PAC1933, PAC1934 }; enum pac1934_samps { PAC1934_SAMP_1024SPS, PAC1934_SAMP_256SPS, PAC1934_SAMP_64SPS, PAC1934_SAMP_8SPS }; /* * these indexes are exactly describing the element order within a single * PAC1934 phys channel IIO channel descriptor; see the static const struct * iio_chan_spec pac1934_single_channel[] declaration */ enum pac1934_ch_idx { PAC1934_CH_ENERGY, PAC1934_CH_POWER, PAC1934_CH_VOLTAGE, PAC1934_CH_CURRENT, PAC1934_CH_VOLTAGE_AVERAGE, PAC1934_CH_CURRENT_AVERAGE }; /** * struct pac1934_features - features of a pac1934 instance * @phys_channels: number of physical channels supported by the chip * @name: chip's name */ struct pac1934_features { u8 phys_channels; const char *name; }; struct samp_rate_mapping { u16 samp_rate; u8 shift2value; }; static const unsigned int samp_rate_map_tbl[] = { [PAC1934_SAMP_1024SPS] = 1024, [PAC1934_SAMP_256SPS] = 256, [PAC1934_SAMP_64SPS] = 64, [PAC1934_SAMP_8SPS] = 8, }; static const struct pac1934_features pac1934_chip_config[] = { [PAC1931] = { .phys_channels = 1, .name = "pac1931", }, [PAC1932] = { .phys_channels = 2, .name = "pac1932", }, [PAC1933] = { .phys_channels = 3, .name = "pac1933", }, [PAC1934] = { .phys_channels = 4, .name = "pac1934", }, }; /** * struct reg_data - data from the registers * @meas_regs: snapshot of raw measurements registers * @ctrl_regs: snapshot of control registers * @energy_sec_acc: snapshot of energy values * @vpower_acc: accumulated vpower values * @vpower: snapshot of vpower registers * @vbus: snapshot of vbus registers * @vbus_avg: averages of vbus registers * @vsense: snapshot of vsense registers * @vsense_avg: averages of vsense registers * @num_enabled_channels: count of how many chip channels are currently enabled */ struct reg_data { u8 meas_regs[PAC1934_MEAS_REG_LEN]; u8 ctrl_regs[PAC1934_CTRL_REG_LEN]; s64 energy_sec_acc[PAC1934_MAX_NUM_CHANNELS]; s64 vpower_acc[PAC1934_MAX_NUM_CHANNELS]; s32 vpower[PAC1934_MAX_NUM_CHANNELS]; s32 vbus[PAC1934_MAX_NUM_CHANNELS]; s32 vbus_avg[PAC1934_MAX_NUM_CHANNELS]; s32 vsense[PAC1934_MAX_NUM_CHANNELS]; s32 vsense_avg[PAC1934_MAX_NUM_CHANNELS]; u8 num_enabled_channels; }; /** * struct pac1934_chip_info - information about the chip * @client: the i2c-client attached to the device * @lock: synchronize access to driver's state members * @work_chip_rfsh: work queue used for refresh commands * @phys_channels: phys channels count * @active_channels: array of values, true means that channel is active * @enable_energy: array of values, true means that channel energy is measured * @bi_dir: array of bools, true means that channel is bidirectional * @chip_variant: chip variant * @chip_revision: chip revision * @shunts: shunts * @chip_reg_data: chip reg data * @sample_rate_value: sampling frequency * @labels: table with channels labels * @iio_info: iio_info * @tstamp: chip's uptime */ struct pac1934_chip_info { struct i2c_client *client; struct mutex lock; /* synchronize access to driver's state members */ struct delayed_work work_chip_rfsh; u8 phys_channels; bool active_channels[PAC1934_MAX_NUM_CHANNELS]; bool enable_energy[PAC1934_MAX_NUM_CHANNELS]; bool bi_dir[PAC1934_MAX_NUM_CHANNELS]; u8 chip_variant; u8 chip_revision; u32 shunts[PAC1934_MAX_NUM_CHANNELS]; struct reg_data chip_reg_data; s32 sample_rate_value; char *labels[PAC1934_MAX_NUM_CHANNELS]; struct iio_info iio_info; unsigned long tstamp; }; #define TO_PAC1934_CHIP_INFO(d) container_of(d, struct pac1934_chip_info, work_chip_rfsh) #define PAC1934_VPOWER_ACC_CHANNEL(_index, _si, _address) { \ .type = IIO_ENERGY, \ .address = (_address), \ .indexed = 1, \ .channel = (_index), \ .info_mask_separate = BIT(IIO_CHAN_INFO_RAW) | \ BIT(IIO_CHAN_INFO_SCALE) | \ BIT(IIO_CHAN_INFO_ENABLE), \ .info_mask_shared_by_all = BIT(IIO_CHAN_INFO_SAMP_FREQ), \ .info_mask_shared_by_all_available = BIT(IIO_CHAN_INFO_SAMP_FREQ), \ .scan_index = (_si), \ .scan_type = { \ .sign = 'u', \ .realbits = 48, \ .storagebits = 64, \ .endianness = IIO_CPU, \ } \ } #define PAC1934_VBUS_CHANNEL(_index, _si, _address) { \ .type = IIO_VOLTAGE, \ .address = (_address), \ .indexed = 1, \ .channel = (_index), \ .info_mask_separate = BIT(IIO_CHAN_INFO_RAW) | \ BIT(IIO_CHAN_INFO_SCALE), \ .info_mask_shared_by_all = BIT(IIO_CHAN_INFO_SAMP_FREQ), \ .info_mask_shared_by_all_available = BIT(IIO_CHAN_INFO_SAMP_FREQ), \ .scan_index = (_si), \ .scan_type = { \ .sign = 'u', \ .realbits = 16, \ .storagebits = 16, \ .endianness = IIO_CPU, \ } \ } #define PAC1934_VBUS_AVG_CHANNEL(_index, _si, _address) { \ .type = IIO_VOLTAGE, \ .address = (_address), \ .indexed = 1, \ .channel = (_index), \ .info_mask_separate = BIT(IIO_CHAN_INFO_AVERAGE_RAW) | \ BIT(IIO_CHAN_INFO_SCALE), \ .info_mask_shared_by_all = BIT(IIO_CHAN_INFO_SAMP_FREQ), \ .info_mask_shared_by_all_available = BIT(IIO_CHAN_INFO_SAMP_FREQ), \ .scan_index = (_si), \ .scan_type = { \ .sign = 'u', \ .realbits = 16, \ .storagebits = 16, \ .endianness = IIO_CPU, \ } \ } #define PAC1934_VSENSE_CHANNEL(_index, _si, _address) { \ .type = IIO_CURRENT, \ .address = (_address), \ .indexed = 1, \ .channel = (_index), \ .info_mask_separate = BIT(IIO_CHAN_INFO_RAW) | \ BIT(IIO_CHAN_INFO_SCALE), \ .info_mask_shared_by_all = BIT(IIO_CHAN_INFO_SAMP_FREQ), \ .info_mask_shared_by_all_available = BIT(IIO_CHAN_INFO_SAMP_FREQ), \ .scan_index = (_si), \ .scan_type = { \ .sign = 'u', \ .realbits = 16, \ .storagebits = 16, \ .endianness = IIO_CPU, \ } \ } #define PAC1934_VSENSE_AVG_CHANNEL(_index, _si, _address) { \ .type = IIO_CURRENT, \ .address = (_address), \ .indexed = 1, \ .channel = (_index), \ .info_mask_separate = BIT(IIO_CHAN_INFO_AVERAGE_RAW) | \ BIT(IIO_CHAN_INFO_SCALE), \ .info_mask_shared_by_all = BIT(IIO_CHAN_INFO_SAMP_FREQ), \ .info_mask_shared_by_all_available = BIT(IIO_CHAN_INFO_SAMP_FREQ), \ .scan_index = (_si), \ .scan_type = { \ .sign = 'u', \ .realbits = 16, \ .storagebits = 16, \ .endianness = IIO_CPU, \ } \ } #define PAC1934_VPOWER_CHANNEL(_index, _si, _address) { \ .type = IIO_POWER, \ .address = (_address), \ .indexed = 1, \ .channel = (_index), \ .info_mask_separate = BIT(IIO_CHAN_INFO_RAW) | \ BIT(IIO_CHAN_INFO_SCALE), \ .info_mask_shared_by_all = BIT(IIO_CHAN_INFO_SAMP_FREQ), \ .info_mask_shared_by_all_available = BIT(IIO_CHAN_INFO_SAMP_FREQ), \ .scan_index = (_si), \ .scan_type = { \ .sign = 'u', \ .realbits = 28, \ .storagebits = 32, \ .shift = 4, \ .endianness = IIO_CPU, \ } \ } static const struct iio_chan_spec pac1934_single_channel[] = { PAC1934_VPOWER_ACC_CHANNEL(0, 0, PAC1934_VPOWER_ACC_1_ADDR), PAC1934_VPOWER_CHANNEL(0, 0, PAC1934_VPOWER_1_ADDR), PAC1934_VBUS_CHANNEL(0, 0, PAC1934_VBUS_1_ADDR), PAC1934_VSENSE_CHANNEL(0, 0, PAC1934_VSENSE_1_ADDR), PAC1934_VBUS_AVG_CHANNEL(0, 0, PAC1934_VBUS_AVG_1_ADDR), PAC1934_VSENSE_AVG_CHANNEL(0, 0, PAC1934_VSENSE_AVG_1_ADDR), }; /* Low-level I2c functions used to transfer up to 76 bytes at once */ static int pac1934_i2c_read(struct i2c_client *client, u8 reg_addr, void *databuf, u8 len) { int ret; struct i2c_msg msgs[2] = { { .addr = client->addr, .len = 1, .buf = (u8 *)®_addr, }, { .addr = client->addr, .len = len, .buf = databuf, .flags = I2C_M_RD } }; ret = i2c_transfer(client->adapter, msgs, ARRAY_SIZE(msgs)); if (ret < 0) return ret; return 0; } static int pac1934_get_samp_rate_idx(struct pac1934_chip_info *info, u32 new_samp_rate) { int cnt; for (cnt = 0; cnt < ARRAY_SIZE(samp_rate_map_tbl); cnt++) if (new_samp_rate == samp_rate_map_tbl[cnt]) return cnt; /* not a valid sample rate value */ return -EINVAL; } static ssize_t pac1934_shunt_value_show(struct device *dev, struct device_attribute *attr, char *buf) { struct iio_dev *indio_dev = dev_to_iio_dev(dev); struct pac1934_chip_info *info = iio_priv(indio_dev); struct iio_dev_attr *this_attr = to_iio_dev_attr(attr); return sysfs_emit(buf, "%u\n", info->shunts[this_attr->address]); } static ssize_t pac1934_shunt_value_store(struct device *dev, struct device_attribute *attr, const char *buf, size_t count) { struct iio_dev *indio_dev = dev_to_iio_dev(dev); struct pac1934_chip_info *info = iio_priv(indio_dev); struct iio_dev_attr *this_attr = to_iio_dev_attr(attr); int sh_val; if (kstrtouint(buf, 10, &sh_val)) { dev_err(dev, "Shunt value is not valid\n"); return -EINVAL; } scoped_guard(mutex, &info->lock) info->shunts[this_attr->address] = sh_val; return count; } static int pac1934_read_avail(struct iio_dev *indio_dev, struct iio_chan_spec const *channel, const int **vals, int *type, int *length, long mask) { switch (mask) { case IIO_CHAN_INFO_SAMP_FREQ: *type = IIO_VAL_INT; *vals = samp_rate_map_tbl; *length = ARRAY_SIZE(samp_rate_map_tbl); return IIO_AVAIL_LIST; } return -EINVAL; } static int pac1934_send_refresh(struct pac1934_chip_info *info, u8 refresh_cmd, u32 wait_time) { /* this function only sends REFRESH or REFRESH_V */ struct i2c_client *client = info->client; int ret; u8 bidir_reg; bool revision_bug = false; if (info->chip_revision == 2 || info->chip_revision == 3) { /* * chip rev 2 and 3 bug workaround * see: PAC1934 Family Data Sheet Errata DS80000836A.pdf */ revision_bug = true; bidir_reg = FIELD_PREP(PAC1934_NEG_PWR_CH1_BIDI_MASK, info->bi_dir[0]) | FIELD_PREP(PAC1934_NEG_PWR_CH2_BIDI_MASK, info->bi_dir[1]) | FIELD_PREP(PAC1934_NEG_PWR_CH3_BIDI_MASK, info->bi_dir[2]) | FIELD_PREP(PAC1934_NEG_PWR_CH4_BIDI_MASK, info->bi_dir[3]) | FIELD_PREP(PAC1934_NEG_PWR_CH1_BIDV_MASK, info->bi_dir[0]) | FIELD_PREP(PAC1934_NEG_PWR_CH2_BIDV_MASK, info->bi_dir[1]) | FIELD_PREP(PAC1934_NEG_PWR_CH3_BIDV_MASK, info->bi_dir[2]) | FIELD_PREP(PAC1934_NEG_PWR_CH4_BIDV_MASK, info->bi_dir[3]); ret = i2c_smbus_write_byte_data(client, PAC1934_CTRL_STAT_REGS_ADDR + PAC1934_NEG_PWR_REG_OFF, bidir_reg); if (ret) return ret; } ret = i2c_smbus_write_byte(client, refresh_cmd); if (ret) { dev_err(&client->dev, "%s - cannot send 0x%02X\n", __func__, refresh_cmd); return ret; } if (revision_bug) { /* * chip rev 2 and 3 bug workaround - write again the same * register write the updated registers back */ ret = i2c_smbus_write_byte_data(client, PAC1934_CTRL_STAT_REGS_ADDR + PAC1934_NEG_PWR_REG_OFF, bidir_reg); if (ret) return ret; } /* register data retrieval timestamp */ info->tstamp = jiffies; /* wait till the data is available */ usleep_range(wait_time, wait_time + 100); return ret; } static int pac1934_reg_snapshot(struct pac1934_chip_info *info, bool do_refresh, u8 refresh_cmd, u32 wait_time) { int ret; struct i2c_client *client = info->client; u8 samp_shift, ctrl_regs_tmp; u8 *offset_reg_data_p; u16 tmp_value; u32 samp_rate, cnt, tmp; s64 curr_energy, inc; u64 tmp_energy; struct reg_data *reg_data; guard(mutex)(&info->lock); if (do_refresh) { ret = pac1934_send_refresh(info, refresh_cmd, wait_time); if (ret < 0) { dev_err(&client->dev, "%s - cannot send refresh\n", __func__); return ret; } } ret = i2c_smbus_read_i2c_block_data(client, PAC1934_CTRL_STAT_REGS_ADDR, PAC1934_CTRL_REG_LEN, (u8 *)info->chip_reg_data.ctrl_regs); if (ret < 0) { dev_err(&client->dev, "%s - cannot read ctrl/status registers\n", __func__); return ret; } reg_data = &info->chip_reg_data; /* read the data registers */ ret = pac1934_i2c_read(client, PAC1934_ACC_COUNT_REG_ADDR, (u8 *)reg_data->meas_regs, PAC1934_MEAS_REG_LEN); if (ret) { dev_err(&client->dev, "%s - cannot read ACC_COUNT register: %d:%d\n", __func__, ret, PAC1934_MEAS_REG_LEN); return ret; } /* see how much shift is required by the sample rate */ samp_rate = samp_rate_map_tbl[((reg_data->ctrl_regs[PAC1934_CTRL_LAT_REG_OFF]) >> 6)]; samp_shift = get_count_order(samp_rate); ctrl_regs_tmp = reg_data->ctrl_regs[PAC1934_CHANNEL_DIS_LAT_REG_OFF]; offset_reg_data_p = ®_data->meas_regs[PAC1934_ACC_REG_LEN]; /* start with VPOWER_ACC */ for (cnt = 0; cnt < info->phys_channels; cnt++) { /* check if the channel is active, skip all fields if disabled */ if ((ctrl_regs_tmp << cnt) & 0x80) continue; /* skip if the energy accumulation is disabled */ if (info->enable_energy[cnt]) { curr_energy = info->chip_reg_data.energy_sec_acc[cnt]; tmp_energy = get_unaligned_be48(offset_reg_data_p); if (info->bi_dir[cnt]) reg_data->vpower_acc[cnt] = sign_extend64(tmp_energy, 47); else reg_data->vpower_acc[cnt] = tmp_energy; /* * compute the scaled to 1 second accumulated energy value; * energy accumulator scaled to 1sec = VPOWER_ACC/2^samp_shift * the chip's sampling rate is 2^samp_shift samples/sec */ inc = (reg_data->vpower_acc[cnt] >> samp_shift); /* add the power_acc field */ curr_energy += inc; clamp(curr_energy, PAC_193X_MIN_POWER_ACC, PAC_193X_MAX_POWER_ACC); reg_data->energy_sec_acc[cnt] = curr_energy; } offset_reg_data_p += PAC1934_VPOWER_ACC_REG_LEN; } /* continue with VBUS */ for (cnt = 0; cnt < info->phys_channels; cnt++) { if ((ctrl_regs_tmp << cnt) & 0x80) continue; tmp_value = get_unaligned_be16(offset_reg_data_p); if (info->bi_dir[cnt]) reg_data->vbus[cnt] = sign_extend32((u32)(tmp_value), 15); else reg_data->vbus[cnt] = tmp_value; offset_reg_data_p += PAC1934_VBUS_SENSE_REG_LEN; } /* VSENSE */ for (cnt = 0; cnt < info->phys_channels; cnt++) { if ((ctrl_regs_tmp << cnt) & 0x80) continue; tmp_value = get_unaligned_be16(offset_reg_data_p); if (info->bi_dir[cnt]) reg_data->vsense[cnt] = sign_extend32((u32)(tmp_value), 15); else reg_data->vsense[cnt] = tmp_value; offset_reg_data_p += PAC1934_VBUS_SENSE_REG_LEN; } /* VBUS_AVG */ for (cnt = 0; cnt < info->phys_channels; cnt++) { if ((ctrl_regs_tmp << cnt) & 0x80) continue; tmp_value = get_unaligned_be16(offset_reg_data_p); if (info->bi_dir[cnt]) reg_data->vbus_avg[cnt] = sign_extend32((u32)(tmp_value), 15); else reg_data->vbus_avg[cnt] = tmp_value; offset_reg_data_p += PAC1934_VBUS_SENSE_REG_LEN; } /* VSENSE_AVG */ for (cnt = 0; cnt < info->phys_channels; cnt++) { if ((ctrl_regs_tmp << cnt) & 0x80) continue; tmp_value = get_unaligned_be16(offset_reg_data_p); if (info->bi_dir[cnt]) reg_data->vsense_avg[cnt] = sign_extend32((u32)(tmp_value), 15); else reg_data->vsense_avg[cnt] = tmp_value; offset_reg_data_p += PAC1934_VBUS_SENSE_REG_LEN; } /* VPOWER */ for (cnt = 0; cnt < info->phys_channels; cnt++) { if ((ctrl_regs_tmp << cnt) & 0x80) continue; tmp = get_unaligned_be32(offset_reg_data_p) >> 4; if (info->bi_dir[cnt]) reg_data->vpower[cnt] = sign_extend32(tmp, 27); else reg_data->vpower[cnt] = tmp; offset_reg_data_p += PAC1934_VPOWER_REG_LEN; } return 0; } static int pac1934_retrieve_data(struct pac1934_chip_info *info, u32 wait_time) { int ret = 0; /* * check if the minimal elapsed time has passed and if so, * re-read the chip, otherwise the cached info is just fine */ if (time_after(jiffies, info->tstamp + msecs_to_jiffies(PAC1934_MIN_POLLING_TIME_MS))) { ret = pac1934_reg_snapshot(info, true, PAC1934_REFRESH_REG_ADDR, wait_time); /* * Re-schedule the work for the read registers on timeout * (to prevent chip registers saturation) */ mod_delayed_work(system_wq, &info->work_chip_rfsh, msecs_to_jiffies(PAC1934_MAX_RFSH_LIMIT_MS)); } return ret; } static int pac1934_read_raw(struct iio_dev *indio_dev, struct iio_chan_spec const *chan, int *val, int *val2, long mask) { struct pac1934_chip_info *info = iio_priv(indio_dev); s64 curr_energy; int ret, channel = chan->channel - 1; ret = pac1934_retrieve_data(info, PAC1934_MIN_UPDATE_WAIT_TIME_US); if (ret < 0) return ret; switch (mask) { case IIO_CHAN_INFO_RAW: switch (chan->type) { case IIO_VOLTAGE: *val = info->chip_reg_data.vbus[channel]; return IIO_VAL_INT; case IIO_CURRENT: *val = info->chip_reg_data.vsense[channel]; return IIO_VAL_INT; case IIO_POWER: *val = info->chip_reg_data.vpower[channel]; return IIO_VAL_INT; case IIO_ENERGY: curr_energy = info->chip_reg_data.energy_sec_acc[channel]; *val = (u32)curr_energy; *val2 = (u32)(curr_energy >> 32); return IIO_VAL_INT_64; default: return -EINVAL; } case IIO_CHAN_INFO_AVERAGE_RAW: switch (chan->type) { case IIO_VOLTAGE: *val = info->chip_reg_data.vbus_avg[channel]; return IIO_VAL_INT; case IIO_CURRENT: *val = info->chip_reg_data.vsense_avg[channel]; return IIO_VAL_INT; default: return -EINVAL; } case IIO_CHAN_INFO_SCALE: switch (chan->address) { /* Voltages - scale for millivolts */ case PAC1934_VBUS_1_ADDR: case PAC1934_VBUS_2_ADDR: case PAC1934_VBUS_3_ADDR: case PAC1934_VBUS_4_ADDR: case PAC1934_VBUS_AVG_1_ADDR: case PAC1934_VBUS_AVG_2_ADDR: case PAC1934_VBUS_AVG_3_ADDR: case PAC1934_VBUS_AVG_4_ADDR: *val = PAC1934_VOLTAGE_MILLIVOLTS_MAX; if (chan->scan_type.sign == 'u') *val2 = PAC1934_VOLTAGE_U_RES; else *val2 = PAC1934_VOLTAGE_S_RES; return IIO_VAL_FRACTIONAL_LOG2; /* * Currents - scale for mA - depends on the * channel's shunt value * (100mV * 1000000) / (2^16 * shunt(uohm)) */ case PAC1934_VSENSE_1_ADDR: case PAC1934_VSENSE_2_ADDR: case PAC1934_VSENSE_3_ADDR: case PAC1934_VSENSE_4_ADDR: case PAC1934_VSENSE_AVG_1_ADDR: case PAC1934_VSENSE_AVG_2_ADDR: case PAC1934_VSENSE_AVG_3_ADDR: case PAC1934_VSENSE_AVG_4_ADDR: *val = PAC1934_MAX_VSENSE_RSHIFTED_BY_16B; if (chan->scan_type.sign == 'u') *val2 = info->shunts[channel]; else *val2 = info->shunts[channel] >> 1; return IIO_VAL_FRACTIONAL; /* * Power - uW - it will use the combined scale * for current and voltage * current(mA) * voltage(mV) = power (uW) */ case PAC1934_VPOWER_1_ADDR: case PAC1934_VPOWER_2_ADDR: case PAC1934_VPOWER_3_ADDR: case PAC1934_VPOWER_4_ADDR: *val = PAC1934_MAX_VPOWER_RSHIFTED_BY_28B; if (chan->scan_type.sign == 'u') *val2 = info->shunts[channel]; else *val2 = info->shunts[channel] >> 1; return IIO_VAL_FRACTIONAL; case PAC1934_VPOWER_ACC_1_ADDR: case PAC1934_VPOWER_ACC_2_ADDR: case PAC1934_VPOWER_ACC_3_ADDR: case PAC1934_VPOWER_ACC_4_ADDR: /* * expresses the 32 bit scale value here compute * the scale for energy (miliWatt-second or miliJoule) */ *val = PAC1934_SCALE_CONSTANT; if (chan->scan_type.sign == 'u') *val2 = info->shunts[channel]; else *val2 = info->shunts[channel] >> 1; return IIO_VAL_FRACTIONAL; default: return -EINVAL; } case IIO_CHAN_INFO_SAMP_FREQ: *val = info->sample_rate_value; return IIO_VAL_INT; case IIO_CHAN_INFO_ENABLE: *val = info->enable_energy[channel]; return IIO_VAL_INT; default: return -EINVAL; } } static int pac1934_write_raw(struct iio_dev *indio_dev, struct iio_chan_spec const *chan, int val, int val2, long mask) { struct pac1934_chip_info *info = iio_priv(indio_dev); struct i2c_client *client = info->client; int ret = -EINVAL; s32 old_samp_rate; u8 ctrl_reg; switch (mask) { case IIO_CHAN_INFO_SAMP_FREQ: ret = pac1934_get_samp_rate_idx(info, val); if (ret < 0) return ret; /* write the new sampling value and trigger a snapshot(incl refresh) */ scoped_guard(mutex, &info->lock) { ctrl_reg = FIELD_PREP(PAC1934_CRTL_SAMPLE_RATE_MASK, ret); ret = i2c_smbus_write_byte_data(client, PAC1934_CTRL_REG_ADDR, ctrl_reg); if (ret) { dev_err(&client->dev, "%s - can't update sample rate\n", __func__); return ret; } } old_samp_rate = info->sample_rate_value; info->sample_rate_value = val; /* * now, force a snapshot with refresh - call retrieve * data in order to update the refresh timer * alter the timestamp in order to force trigger a * register snapshot and a timestamp update */ info->tstamp -= msecs_to_jiffies(PAC1934_MIN_POLLING_TIME_MS); ret = pac1934_retrieve_data(info, (1024 / old_samp_rate) * 1000); if (ret < 0) { dev_err(&client->dev, "%s - cannot snapshot ctrl and measurement regs\n", __func__); return ret; } return 0; case IIO_CHAN_INFO_ENABLE: scoped_guard(mutex, &info->lock) { info->enable_energy[chan->channel - 1] = val ? true : false; if (!val) info->chip_reg_data.energy_sec_acc[chan->channel - 1] = 0; } return 0; default: return -EINVAL; } } static int pac1934_read_label(struct iio_dev *indio_dev, struct iio_chan_spec const *chan, char *label) { struct pac1934_chip_info *info = iio_priv(indio_dev); switch (chan->address) { case PAC1934_VBUS_1_ADDR: case PAC1934_VBUS_2_ADDR: case PAC1934_VBUS_3_ADDR: case PAC1934_VBUS_4_ADDR: return sysfs_emit(label, "%s_VBUS_%d\n", info->labels[chan->scan_index], chan->scan_index + 1); case PAC1934_VBUS_AVG_1_ADDR: case PAC1934_VBUS_AVG_2_ADDR: case PAC1934_VBUS_AVG_3_ADDR: case PAC1934_VBUS_AVG_4_ADDR: return sysfs_emit(label, "%s_VBUS_AVG_%d\n", info->labels[chan->scan_index], chan->scan_index + 1); case PAC1934_VSENSE_1_ADDR: case PAC1934_VSENSE_2_ADDR: case PAC1934_VSENSE_3_ADDR: case PAC1934_VSENSE_4_ADDR: return sysfs_emit(label, "%s_IBUS_%d\n", info->labels[chan->scan_index], chan->scan_index + 1); case PAC1934_VSENSE_AVG_1_ADDR: case PAC1934_VSENSE_AVG_2_ADDR: case PAC1934_VSENSE_AVG_3_ADDR: case PAC1934_VSENSE_AVG_4_ADDR: return sysfs_emit(label, "%s_IBUS_AVG_%d\n", info->labels[chan->scan_index], chan->scan_index + 1); case PAC1934_VPOWER_1_ADDR: case PAC1934_VPOWER_2_ADDR: case PAC1934_VPOWER_3_ADDR: case PAC1934_VPOWER_4_ADDR: return sysfs_emit(label, "%s_POWER_%d\n", info->labels[chan->scan_index], chan->scan_index + 1); case PAC1934_VPOWER_ACC_1_ADDR: case PAC1934_VPOWER_ACC_2_ADDR: case PAC1934_VPOWER_ACC_3_ADDR: case PAC1934_VPOWER_ACC_4_ADDR: return sysfs_emit(label, "%s_ENERGY_%d\n", info->labels[chan->scan_index], chan->scan_index + 1); } return 0; } static void pac1934_work_periodic_rfsh(struct work_struct *work) { struct pac1934_chip_info *info = TO_PAC1934_CHIP_INFO((struct delayed_work *)work); struct device *dev = &info->client->dev; dev_dbg(dev, "%s - Periodic refresh\n", __func__); /* do a REFRESH, then read */ pac1934_reg_snapshot(info, true, PAC1934_REFRESH_REG_ADDR, PAC1934_MIN_UPDATE_WAIT_TIME_US); schedule_delayed_work(&info->work_chip_rfsh, msecs_to_jiffies(PAC1934_MAX_RFSH_LIMIT_MS)); } static int pac1934_read_revision(struct pac1934_chip_info *info, u8 *buf) { int ret; struct i2c_client *client = info->client; ret = i2c_smbus_read_i2c_block_data(client, PAC1934_PID_REG_ADDR, PAC1934_ID_REG_LEN, buf); if (ret < 0) { dev_err(&client->dev, "cannot read revision\n"); return ret; } return 0; } static int pac1934_chip_identify(struct pac1934_chip_info *info) { u8 rev_info[PAC1934_ID_REG_LEN]; struct device *dev = &info->client->dev; int ret = 0; ret = pac1934_read_revision(info, (u8 *)rev_info); if (ret) return ret; info->chip_variant = rev_info[PAC1934_PID_IDX]; info->chip_revision = rev_info[PAC1934_RID_IDX]; dev_dbg(dev, "Chip variant: 0x%02X\n", info->chip_variant); dev_dbg(dev, "Chip revision: 0x%02X\n", info->chip_revision); switch (info->chip_variant) { case PAC1934_PID: return PAC1934; case PAC1933_PID: return PAC1933; case PAC1932_PID: return PAC1932; case PAC1931_PID: return PAC1931; default: return -EINVAL; } } /* * documentation related to the ACPI device definition * https://ww1.microchip.com/downloads/aemDocuments/documents/OTH/ApplicationNotes/ApplicationNotes/PAC1934-Integration-Notes-for-Microsoft-Windows-10-and-Windows-11-Driver-Support-DS00002534.pdf */ static bool pac1934_acpi_parse_channel_config(struct i2c_client *client, struct pac1934_chip_info *info) { acpi_handle handle; union acpi_object *rez; struct device *dev = &client->dev; unsigned short bi_dir_mask; int idx, i; guid_t guid; handle = ACPI_HANDLE(dev); guid_parse(PAC1934_DSM_UUID, &guid); rez = acpi_evaluate_dsm(handle, &guid, 0, PAC1934_ACPI_GET_NAMES_AND_MOHMS_VALS, NULL); if (!rez) return false; for (i = 0; i < rez->package.count; i += 2) { idx = i / 2; info->labels[idx] = devm_kmemdup(dev, rez->package.elements[i].string.pointer, (size_t)rez->package.elements[i].string.length + 1, GFP_KERNEL); info->labels[idx][rez->package.elements[i].string.length] = '\0'; info->shunts[idx] = rez->package.elements[i + 1].integer.value * 1000; info->active_channels[idx] = (info->shunts[idx] != 0); } ACPI_FREE(rez); rez = acpi_evaluate_dsm(handle, &guid, 1, PAC1934_ACPI_GET_UOHMS_VALS, NULL); if (!rez) { /* * initializing with default values * we assume all channels are unidirectional(the mask is zero) * and assign the default sampling rate */ info->sample_rate_value = PAC1934_DEFAULT_CHIP_SAMP_SPEED_HZ; return true; } for (i = 0; i < rez->package.count; i++) { idx = i; info->shunts[idx] = rez->package.elements[i].integer.value; info->active_channels[idx] = (info->shunts[idx] != 0); } ACPI_FREE(rez); rez = acpi_evaluate_dsm(handle, &guid, 1, PAC1934_ACPI_GET_BIPOLAR_SETTINGS, NULL); if (!rez) return false; bi_dir_mask = rez->package.elements[0].integer.value; info->bi_dir[0] = ((bi_dir_mask & (1 << 3)) | (bi_dir_mask & (1 << 7))) != 0; info->bi_dir[1] = ((bi_dir_mask & (1 << 2)) | (bi_dir_mask & (1 << 6))) != 0; info->bi_dir[2] = ((bi_dir_mask & (1 << 1)) | (bi_dir_mask & (1 << 5))) != 0; info->bi_dir[3] = ((bi_dir_mask & (1 << 0)) | (bi_dir_mask & (1 << 4))) != 0; ACPI_FREE(rez); rez = acpi_evaluate_dsm(handle, &guid, 1, PAC1934_ACPI_GET_SAMP, NULL); if (!rez) return false; info->sample_rate_value = rez->package.elements[0].integer.value; ACPI_FREE(rez); return true; } static bool pac1934_of_parse_channel_config(struct i2c_client *client, struct pac1934_chip_info *info) { struct fwnode_handle *node, *fwnode; struct device *dev = &client->dev; unsigned int current_channel; int idx, ret; info->sample_rate_value = 1024; current_channel = 1; fwnode = dev_fwnode(dev); fwnode_for_each_available_child_node(fwnode, node) { ret = fwnode_property_read_u32(node, "reg", &idx); if (ret) { dev_err_probe(dev, ret, "reading invalid channel index\n"); goto err_fwnode; } /* adjust idx to match channel index (1 to 4) from the datasheet */ idx--; if (current_channel >= (info->phys_channels + 1) || idx >= info->phys_channels || idx < 0) { dev_err_probe(dev, -EINVAL, "%s: invalid channel_index %d value\n", fwnode_get_name(node), idx); goto err_fwnode; } /* enable channel */ info->active_channels[idx] = true; ret = fwnode_property_read_u32(node, "shunt-resistor-micro-ohms", &info->shunts[idx]); if (ret) { dev_err_probe(dev, ret, "%s: invalid shunt-resistor value: %d\n", fwnode_get_name(node), info->shunts[idx]); goto err_fwnode; } if (fwnode_property_present(node, "label")) { ret = fwnode_property_read_string(node, "label", (const char **)&info->labels[idx]); if (ret) { dev_err_probe(dev, ret, "%s: invalid rail-name value\n", fwnode_get_name(node)); goto err_fwnode; } } info->bi_dir[idx] = fwnode_property_read_bool(node, "bipolar"); current_channel++; } return true; err_fwnode: fwnode_handle_put(node); return false; } static void pac1934_cancel_delayed_work(void *dwork) { cancel_delayed_work_sync(dwork); } static int pac1934_chip_configure(struct pac1934_chip_info *info) { int cnt, ret; struct i2c_client *client = info->client; u8 regs[PAC1934_CTRL_STATUS_INFO_LEN], idx, ctrl_reg; u32 wait_time; info->chip_reg_data.num_enabled_channels = 0; for (cnt = 0; cnt < info->phys_channels; cnt++) { if (info->active_channels[cnt]) info->chip_reg_data.num_enabled_channels++; } /* * read whatever information was gathered before the driver was loaded * establish which channels are enabled/disabled and then establish the * information retrieval mode (using SKIP or no). * Read the chip ID values */ ret = i2c_smbus_read_i2c_block_data(client, PAC1934_CTRL_STAT_REGS_ADDR, ARRAY_SIZE(regs), (u8 *)regs); if (ret < 0) { dev_err_probe(&client->dev, ret, "%s - cannot read regs from 0x%02X\n", __func__, PAC1934_CTRL_STAT_REGS_ADDR); return ret; } /* write the CHANNEL_DIS and the NEG_PWR registers */ regs[PAC1934_CHANNEL_DIS_REG_OFF] = FIELD_PREP(PAC1934_CHAN_DIS_CH1_OFF_MASK, info->active_channels[0] ? 0 : 1) | FIELD_PREP(PAC1934_CHAN_DIS_CH2_OFF_MASK, info->active_channels[1] ? 0 : 1) | FIELD_PREP(PAC1934_CHAN_DIS_CH3_OFF_MASK, info->active_channels[2] ? 0 : 1) | FIELD_PREP(PAC1934_CHAN_DIS_CH4_OFF_MASK, info->active_channels[3] ? 0 : 1) | FIELD_PREP(PAC1934_SMBUS_TIMEOUT_MASK, 0) | FIELD_PREP(PAC1934_SMBUS_BYTECOUNT_MASK, 0) | FIELD_PREP(PAC1934_SMBUS_NO_SKIP_MASK, 0); regs[PAC1934_NEG_PWR_REG_OFF] = FIELD_PREP(PAC1934_NEG_PWR_CH1_BIDI_MASK, info->bi_dir[0]) | FIELD_PREP(PAC1934_NEG_PWR_CH2_BIDI_MASK, info->bi_dir[1]) | FIELD_PREP(PAC1934_NEG_PWR_CH3_BIDI_MASK, info->bi_dir[2]) | FIELD_PREP(PAC1934_NEG_PWR_CH4_BIDI_MASK, info->bi_dir[3]) | FIELD_PREP(PAC1934_NEG_PWR_CH1_BIDV_MASK, info->bi_dir[0]) | FIELD_PREP(PAC1934_NEG_PWR_CH2_BIDV_MASK, info->bi_dir[1]) | FIELD_PREP(PAC1934_NEG_PWR_CH3_BIDV_MASK, info->bi_dir[2]) | FIELD_PREP(PAC1934_NEG_PWR_CH4_BIDV_MASK, info->bi_dir[3]); /* no SLOW triggered REFRESH, clear POR */ regs[PAC1934_SLOW_REG_OFF] = 0; ret = i2c_smbus_write_block_data(client, PAC1934_CTRL_STAT_REGS_ADDR, ARRAY_SIZE(regs), (u8 *)regs); if (ret) return ret; /* Default sampling rate */ ctrl_reg = FIELD_PREP(PAC1934_CRTL_SAMPLE_RATE_MASK, PAC1934_SAMP_1024SPS); ret = i2c_smbus_write_byte_data(client, PAC1934_CTRL_REG_ADDR, ctrl_reg); if (ret) return ret; /* * send a REFRESH to the chip, so the new settings take place * as well as resetting the accumulators */ ret = i2c_smbus_write_byte(client, PAC1934_REFRESH_REG_ADDR); if (ret) { dev_err(&client->dev, "%s - cannot send 0x%02X\n", __func__, PAC1934_REFRESH_REG_ADDR); return ret; } /* * get the current(in the chip) sampling speed and compute the * required timeout based on its value * the timeout is 1/sampling_speed */ idx = regs[PAC1934_CTRL_ACT_REG_OFF] >> PAC1934_SAMPLE_RATE_SHIFT; wait_time = (1024 / samp_rate_map_tbl[idx]) * 1000; /* * wait the maximum amount of time to be on the safe side * the maximum wait time is for 8sps */ usleep_range(wait_time, wait_time + 100); INIT_DELAYED_WORK(&info->work_chip_rfsh, pac1934_work_periodic_rfsh); /* Setup the latest moment for reading the regs before saturation */ schedule_delayed_work(&info->work_chip_rfsh, msecs_to_jiffies(PAC1934_MAX_RFSH_LIMIT_MS)); return devm_add_action_or_reset(&client->dev, pac1934_cancel_delayed_work, &info->work_chip_rfsh); } static int pac1934_prep_iio_channels(struct pac1934_chip_info *info, struct iio_dev *indio_dev) { struct iio_chan_spec *ch_sp; int channel_size, attribute_count, cnt; void *dyn_ch_struct, *tmp_data; struct device *dev = &info->client->dev; /* find out dynamically how many IIO channels we need */ attribute_count = 0; channel_size = 0; for (cnt = 0; cnt < info->phys_channels; cnt++) { if (!info->active_channels[cnt]) continue; /* add the size of the properties of one chip physical channel */ channel_size += sizeof(pac1934_single_channel); /* count how many enabled channels we have */ attribute_count += ARRAY_SIZE(pac1934_single_channel); dev_dbg(dev, ":%s: Channel %d active\n", __func__, cnt + 1); } dyn_ch_struct = devm_kzalloc(dev, channel_size, GFP_KERNEL); if (!dyn_ch_struct) return -EINVAL; tmp_data = dyn_ch_struct; /* populate the dynamic channels and make all the adjustments */ for (cnt = 0; cnt < info->phys_channels; cnt++) { if (!info->active_channels[cnt]) continue; memcpy(tmp_data, pac1934_single_channel, sizeof(pac1934_single_channel)); ch_sp = (struct iio_chan_spec *)tmp_data; ch_sp[PAC1934_CH_ENERGY].channel = cnt + 1; ch_sp[PAC1934_CH_ENERGY].scan_index = cnt; ch_sp[PAC1934_CH_ENERGY].address = cnt + PAC1934_VPOWER_ACC_1_ADDR; ch_sp[PAC1934_CH_POWER].channel = cnt + 1; ch_sp[PAC1934_CH_POWER].scan_index = cnt; ch_sp[PAC1934_CH_POWER].address = cnt + PAC1934_VPOWER_1_ADDR; ch_sp[PAC1934_CH_VOLTAGE].channel = cnt + 1; ch_sp[PAC1934_CH_VOLTAGE].scan_index = cnt; ch_sp[PAC1934_CH_VOLTAGE].address = cnt + PAC1934_VBUS_1_ADDR; ch_sp[PAC1934_CH_CURRENT].channel = cnt + 1; ch_sp[PAC1934_CH_CURRENT].scan_index = cnt; ch_sp[PAC1934_CH_CURRENT].address = cnt + PAC1934_VSENSE_1_ADDR; /* * In order to be able to use labels for PAC1934_CH_VOLTAGE, and * PAC1934_CH_VOLTAGE_AVERAGE,respectively PAC1934_CH_CURRENT * and PAC1934_CH_CURRENT_AVERAGE we need to use different * channel numbers. We will add +5 (+1 to maximum PAC channels). */ ch_sp[PAC1934_CH_VOLTAGE_AVERAGE].channel = cnt + 5; ch_sp[PAC1934_CH_VOLTAGE_AVERAGE].scan_index = cnt; ch_sp[PAC1934_CH_VOLTAGE_AVERAGE].address = cnt + PAC1934_VBUS_AVG_1_ADDR; ch_sp[PAC1934_CH_CURRENT_AVERAGE].channel = cnt + 5; ch_sp[PAC1934_CH_CURRENT_AVERAGE].scan_index = cnt; ch_sp[PAC1934_CH_CURRENT_AVERAGE].address = cnt + PAC1934_VSENSE_AVG_1_ADDR; /* * now modify the parameters in all channels if the * whole chip rail(channel) is bi-directional */ if (info->bi_dir[cnt]) { ch_sp[PAC1934_CH_ENERGY].scan_type.sign = 's'; ch_sp[PAC1934_CH_ENERGY].scan_type.realbits = 47; ch_sp[PAC1934_CH_POWER].scan_type.sign = 's'; ch_sp[PAC1934_CH_POWER].scan_type.realbits = 27; ch_sp[PAC1934_CH_VOLTAGE].scan_type.sign = 's'; ch_sp[PAC1934_CH_VOLTAGE].scan_type.realbits = 15; ch_sp[PAC1934_CH_CURRENT].scan_type.sign = 's'; ch_sp[PAC1934_CH_CURRENT].scan_type.realbits = 15; ch_sp[PAC1934_CH_VOLTAGE_AVERAGE].scan_type.sign = 's'; ch_sp[PAC1934_CH_VOLTAGE_AVERAGE].scan_type.realbits = 15; ch_sp[PAC1934_CH_CURRENT_AVERAGE].scan_type.sign = 's'; ch_sp[PAC1934_CH_CURRENT_AVERAGE].scan_type.realbits = 15; } tmp_data += sizeof(pac1934_single_channel); } /* * send the updated dynamic channel structure information towards IIO * prepare the required field for IIO class registration */ indio_dev->num_channels = attribute_count; indio_dev->channels = (const struct iio_chan_spec *)dyn_ch_struct; return 0; } static IIO_DEVICE_ATTR(in_shunt_resistor1, 0644, pac1934_shunt_value_show, pac1934_shunt_value_store, 0); static IIO_DEVICE_ATTR(in_shunt_resistor2, 0644, pac1934_shunt_value_show, pac1934_shunt_value_store, 1); static IIO_DEVICE_ATTR(in_shunt_resistor3, 0644, pac1934_shunt_value_show, pac1934_shunt_value_store, 2); static IIO_DEVICE_ATTR(in_shunt_resistor4, 0644, pac1934_shunt_value_show, pac1934_shunt_value_store, 3); static int pac1934_prep_custom_attributes(struct pac1934_chip_info *info, struct iio_dev *indio_dev) { int i, active_channels_count = 0; struct attribute **pac1934_custom_attr; struct attribute_group *pac1934_group; struct device *dev = &info->client->dev; for (i = 0 ; i < info->phys_channels; i++) if (info->active_channels[i]) active_channels_count++; pac1934_group = devm_kzalloc(dev, sizeof(*pac1934_group), GFP_KERNEL); if (!pac1934_group) return -ENOMEM; pac1934_custom_attr = devm_kzalloc(dev, (PAC1934_CUSTOM_ATTR_FOR_CHANNEL * active_channels_count) * sizeof(*pac1934_group) + 1, GFP_KERNEL); if (!pac1934_custom_attr) return -ENOMEM; i = 0; if (info->active_channels[0]) pac1934_custom_attr[i++] = PAC1934_DEV_ATTR(in_shunt_resistor1); if (info->active_channels[1]) pac1934_custom_attr[i++] = PAC1934_DEV_ATTR(in_shunt_resistor2); if (info->active_channels[2]) pac1934_custom_attr[i++] = PAC1934_DEV_ATTR(in_shunt_resistor3); if (info->active_channels[3]) pac1934_custom_attr[i] = PAC1934_DEV_ATTR(in_shunt_resistor4); pac1934_group->attrs = pac1934_custom_attr; info->iio_info.attrs = pac1934_group; return 0; } static void pac1934_mutex_destroy(void *data) { struct mutex *lock = data; mutex_destroy(lock); } static const struct iio_info pac1934_info = { .read_raw = pac1934_read_raw, .write_raw = pac1934_write_raw, .read_avail = pac1934_read_avail, .read_label = pac1934_read_label, }; static int pac1934_probe(struct i2c_client *client) { struct pac1934_chip_info *info; const struct pac1934_features *chip; struct iio_dev *indio_dev; int cnt, ret; bool match = false; struct device *dev = &client->dev; indio_dev = devm_iio_device_alloc(dev, sizeof(*info)); if (!indio_dev) return -ENOMEM; info = iio_priv(indio_dev); info->client = client; /* always start with energy accumulation enabled */ for (cnt = 0; cnt < PAC1934_MAX_NUM_CHANNELS; cnt++) info->enable_energy[cnt] = true; ret = pac1934_chip_identify(info); if (ret < 0) { /* * If failed to identify the hardware based on internal * registers, try using fallback compatible in device tree * to deal with some newer part number. */ chip = i2c_get_match_data(client); if (!chip) return -EINVAL; info->phys_channels = chip->phys_channels; indio_dev->name = chip->name; } else { info->phys_channels = pac1934_chip_config[ret].phys_channels; indio_dev->name = pac1934_chip_config[ret].name; } if (acpi_match_device(dev->driver->acpi_match_table, dev)) match = pac1934_acpi_parse_channel_config(client, info); else /* * This makes it possible to use also ACPI PRP0001 for * registering the device using device tree properties. */ match = pac1934_of_parse_channel_config(client, info); if (!match) return dev_err_probe(dev, -EINVAL, "parameter parsing returned an error\n"); mutex_init(&info->lock); ret = devm_add_action_or_reset(dev, pac1934_mutex_destroy, &info->lock); if (ret < 0) return ret; /* * do now any chip specific initialization (e.g. read/write * some registers), enable/disable certain channels, change the sampling * rate to the requested value */ ret = pac1934_chip_configure(info); if (ret < 0) return ret; /* prepare the channel information */ ret = pac1934_prep_iio_channels(info, indio_dev); if (ret < 0) return ret; info->iio_info = pac1934_info; indio_dev->info = &info->iio_info; indio_dev->modes = INDIO_DIRECT_MODE; ret = pac1934_prep_custom_attributes(info, indio_dev); if (ret < 0) return dev_err_probe(dev, ret, "Can't configure custom attributes for PAC1934 device\n"); /* * read whatever has been accumulated in the chip so far * and reset the accumulators */ ret = pac1934_reg_snapshot(info, true, PAC1934_REFRESH_REG_ADDR, PAC1934_MIN_UPDATE_WAIT_TIME_US); if (ret < 0) return ret; ret = devm_iio_device_register(dev, indio_dev); if (ret < 0) return dev_err_probe(dev, ret, "Can't register IIO device\n"); return 0; } static const struct i2c_device_id pac1934_id[] = { { .name = "pac1931", .driver_data = (kernel_ulong_t)&pac1934_chip_config[PAC1931] }, { .name = "pac1932", .driver_data = (kernel_ulong_t)&pac1934_chip_config[PAC1932] }, { .name = "pac1933", .driver_data = (kernel_ulong_t)&pac1934_chip_config[PAC1933] }, { .name = "pac1934", .driver_data = (kernel_ulong_t)&pac1934_chip_config[PAC1934] }, {} }; MODULE_DEVICE_TABLE(i2c, pac1934_id); static const struct of_device_id pac1934_of_match[] = { { .compatible = "microchip,pac1931", .data = &pac1934_chip_config[PAC1931] }, { .compatible = "microchip,pac1932", .data = &pac1934_chip_config[PAC1932] }, { .compatible = "microchip,pac1933", .data = &pac1934_chip_config[PAC1933] }, { .compatible = "microchip,pac1934", .data = &pac1934_chip_config[PAC1934] }, {} }; MODULE_DEVICE_TABLE(of, pac1934_of_match); /* * using MCHP1930 to be compatible with BIOS ACPI. See example: * https://ww1.microchip.com/downloads/aemDocuments/documents/OTH/ApplicationNotes/ApplicationNotes/PAC1934-Integration-Notes-for-Microsoft-Windows-10-and-Windows-11-Driver-Support-DS00002534.pdf */ static const struct acpi_device_id pac1934_acpi_match[] = { { "MCHP1930", .driver_data = (kernel_ulong_t)&pac1934_chip_config[PAC1934] }, {} }; MODULE_DEVICE_TABLE(acpi, pac1934_acpi_match); static struct i2c_driver pac1934_driver = { .driver = { .name = "pac1934", .of_match_table = pac1934_of_match, .acpi_match_table = pac1934_acpi_match }, .probe = pac1934_probe, .id_table = pac1934_id, }; module_i2c_driver(pac1934_driver); MODULE_AUTHOR("Bogdan Bolocan "); MODULE_AUTHOR("Victor Tudose"); MODULE_AUTHOR("Marius Cristea "); MODULE_DESCRIPTION("IIO driver for PAC1934 Multi-Channel DC Power/Energy Monitor"); MODULE_LICENSE("GPL");