/* * Copyright (c) 2019 Vestas Wind Systems A/S * * SPDX-License-Identifier: Apache-2.0 */ /** * @file * @brief ADC driver for the LMP90xxx AFE. */ #include #include #include #include #include #include #include #include #define LOG_LEVEL CONFIG_ADC_LOG_LEVEL #include LOG_MODULE_REGISTER(adc_lmp90xxx); #define ADC_CONTEXT_USES_KERNEL_TIMER #include "adc_context.h" /* LMP90xxx register addresses */ #define LMP90XXX_REG_RESETCN 0x00U #define LMP90XXX_REG_SPI_HANDSHAKECN 0x01U #define LMP90XXX_REG_SPI_RESET 0x02U #define LMP90XXX_REG_SPI_STREAMCN 0x03U #define LMP90XXX_REG_PWRCN 0x08U #define LMP90XXX_REG_DATA_ONLY_1 0x09U #define LMP90XXX_REG_DATA_ONLY_2 0x0AU #define LMP90XXX_REG_ADC_RESTART 0x0BU #define LMP90XXX_REG_GPIO_DIRCN 0x0EU #define LMP90XXX_REG_GPIO_DAT 0x0FU #define LMP90XXX_REG_BGCALCN 0x10U #define LMP90XXX_REG_SPI_DRDYBCN 0x11U #define LMP90XXX_REG_ADC_AUXCN 0x12U #define LMP90XXX_REG_SPI_CRC_CN 0x13U #define LMP90XXX_REG_SENDIAG_THLDH 0x14U #define LMP90XXX_REG_SENDIAG_THLDL 0x15U #define LMP90XXX_REG_SCALCN 0x17U #define LMP90XXX_REG_ADC_DONE 0x18U #define LMP90XXX_REG_SENDIAG_FLAGS 0x19U #define LMP90XXX_REG_ADC_DOUT 0x1AU #define LMP90XXX_REG_SPI_CRC_DAT 0x1DU #define LMP90XXX_REG_CH_STS 0x1EU #define LMP90XXX_REG_CH_SCAN 0x1FU /* LMP90xxx channel input and configuration registers */ #define LMP90XXX_REG_CH_INPUTCN(ch) (0x20U + (2 * ch)) #define LMP90XXX_REG_CH_CONFIG(ch) (0x21U + (2 * ch)) /* LMP90xxx upper (URA) and lower (LRA) register addresses */ #define LMP90XXX_URA(addr) ((addr >> 4U) & GENMASK(2, 0)) #define LMP90XXX_LRA(addr) (addr & GENMASK(3, 0)) /* LMP90xxx instruction byte 1 (INST1) */ #define LMP90XXX_INST1_WAB 0x10U #define LMP90XXX_INST1_RA 0x90U /* LMP90xxx instruction byte 2 (INST2) */ #define LMP90XXX_INST2_WB 0U #define LMP90XXX_INST2_R BIT(7) #define LMP90XXX_INST2_SZ_1 (0x0U << 5) #define LMP90XXX_INST2_SZ_2 (0x1U << 5) #define LMP90XXX_INST2_SZ_3 (0x2U << 5) #define LMP90XXX_INST2_SZ_STREAM (0x3U << 5) /* LMP90xxx register values/commands */ #define LMP90XXX_REG_AND_CNV_RST 0xC3U #define LMP90XXX_SDO_DRDYB_DRIVER(x) ((x & BIT_MASK(3)) << 1) #define LMP90XXX_PWRCN(x) (x & BIT_MASK(2)) #define LMP90XXX_RTD_CUR_SEL(x) (x & BIT_MASK(4)) #define LMP90XXX_SPI_DRDYB_D6(x) ((x & BIT(0)) << 7) #define LMP90XXX_EN_CRC(x) ((x & BIT(0)) << 4) #define LMP90XXX_DRDYB_AFT_CRC(x) ((x & BIT(0)) << 2) #define LMP90XXX_CH_SCAN_SEL(x) ((x & BIT_MASK(2)) << 6) #define LMP90XXX_LAST_CH(x) ((x & BIT_MASK(3)) << 3) #define LMP90XXX_FIRST_CH(x) (x & BIT_MASK(3)) #define LMP90XXX_BURNOUT_EN(x) ((x & BIT(0)) << 7) #define LMP90XXX_VREF_SEL(x) ((x & BIT(0)) << 6) #define LMP90XXX_VINP(x) ((x & BIT_MASK(3)) << 3) #define LMP90XXX_VINN(x) (x & BIT_MASK(3)) #define LMP90XXX_BGCALN(x) (x & BIT_MASK(3)) #define LMP90XXX_ODR_SEL(x) ((x & BIT_MASK(3)) << 4) #define LMP90XXX_GAIN_SEL(x) ((x & BIT_MASK(3)) << 1) #define LMP90XXX_BUF_EN(x) (x & BIT(0)) #define LMP90XXX_GPIO_DAT_MASK BIT_MASK(LMP90XXX_GPIO_MAX) /* Invalid (never used) Upper Register Address */ #define LMP90XXX_INVALID_URA UINT8_MAX /* Maximum number of ADC channels */ #define LMP90XXX_MAX_CHANNELS 7 /* Maximum number of ADC inputs */ #define LMP90XXX_MAX_INPUTS 8 /* Default Output Data Rate (ODR) is 214.65 SPS */ #define LMP90XXX_DEFAULT_ODR 7 /* Macro for checking if Data Ready Bar IRQ is in use */ #define LMP90XXX_HAS_DRDYB(config) (config->drdyb_dev_name != NULL) struct lmp90xxx_config { const char *spi_dev_name; const char *spi_cs_dev_name; gpio_pin_t spi_cs_pin; gpio_dt_flags_t spi_cs_dt_flags; struct spi_config spi_cfg; const char *drdyb_dev_name; gpio_pin_t drdyb_pin; gpio_dt_flags_t drdyb_flags; uint8_t rtd_current; uint8_t resolution; uint8_t channels; }; struct lmp90xxx_data { struct adc_context ctx; const struct device *dev; const struct device *spi_dev; struct spi_cs_control spi_cs; struct gpio_callback drdyb_cb; struct k_mutex ura_lock; uint8_t ura; int32_t *buffer; int32_t *repeat_buffer; uint32_t channels; bool calibrate; uint8_t channel_odr[LMP90XXX_MAX_CHANNELS]; #ifdef CONFIG_ADC_LMP90XXX_GPIO struct k_mutex gpio_lock; uint8_t gpio_dircn; uint8_t gpio_dat; #endif /* CONFIG_ADC_LMP90XXX_GPIO */ struct k_thread thread; struct k_sem acq_sem; struct k_sem drdyb_sem; K_KERNEL_STACK_MEMBER(stack, CONFIG_ADC_LMP90XXX_ACQUISITION_THREAD_STACK_SIZE); }; /* * Approximated LMP90xxx acquisition times in milliseconds. These are * used for the initial delay when polling for data ready. */ static const int32_t lmp90xxx_odr_delay_tbl[8] = { 596, /* 13.42/8 = 1.6775 SPS */ 298, /* 13.42/4 = 3.355 SPS */ 149, /* 13.42/2 = 6.71 SPS */ 75, /* 13.42 SPS */ 37, /* 214.65/8 = 26.83125 SPS */ 19, /* 214.65/4 = 53.6625 SPS */ 9, /* 214.65/2 = 107.325 SPS */ 5, /* 214.65 SPS (default) */ }; static inline uint8_t lmp90xxx_inst2_sz(size_t len) { if (len == 1) { return LMP90XXX_INST2_SZ_1; } else if (len == 2) { return LMP90XXX_INST2_SZ_2; } else if (len == 3) { return LMP90XXX_INST2_SZ_3; } else { return LMP90XXX_INST2_SZ_STREAM; } } static int lmp90xxx_read_reg(const struct device *dev, uint8_t addr, uint8_t *dptr, size_t len) { const struct lmp90xxx_config *config = dev->config; struct lmp90xxx_data *data = dev->data; uint8_t ura = LMP90XXX_URA(addr); uint8_t inst1_uab[2] = { LMP90XXX_INST1_WAB, ura }; uint8_t inst2 = LMP90XXX_INST2_R | LMP90XXX_LRA(addr); struct spi_buf tx_buf[2]; struct spi_buf rx_buf[2]; struct spi_buf_set tx; struct spi_buf_set rx; int dummy = 0; int i = 0; int err; if (len == 0) { LOG_ERR("attempt to read 0 bytes from register 0x%02x", addr); return -EINVAL; } if (k_is_in_isr()) { /* Prevent SPI transactions from an ISR */ return -EWOULDBLOCK; } k_mutex_lock(&data->ura_lock, K_FOREVER); if (ura != data->ura) { /* Instruction Byte 1 + Upper Address Byte */ tx_buf[i].buf = inst1_uab; tx_buf[i].len = sizeof(inst1_uab); dummy += sizeof(inst1_uab); i++; } /* Instruction Byte 2 */ inst2 |= lmp90xxx_inst2_sz(len); tx_buf[i].buf = &inst2; tx_buf[i].len = sizeof(inst2); dummy += sizeof(inst2); i++; /* Dummy RX Bytes */ rx_buf[0].buf = NULL; rx_buf[0].len = dummy; /* Data Byte(s) */ rx_buf[1].buf = dptr; rx_buf[1].len = len; tx.buffers = tx_buf; tx.count = i; rx.buffers = rx_buf; rx.count = 2; err = spi_transceive(data->spi_dev, &config->spi_cfg, &tx, &rx); if (!err) { data->ura = ura; } else { /* Force INST1 + UAB on next access */ data->ura = LMP90XXX_INVALID_URA; } k_mutex_unlock(&data->ura_lock); return err; } static int lmp90xxx_read_reg8(const struct device *dev, uint8_t addr, uint8_t *val) { return lmp90xxx_read_reg(dev, addr, val, sizeof(val)); } static int lmp90xxx_write_reg(const struct device *dev, uint8_t addr, uint8_t *dptr, size_t len) { const struct lmp90xxx_config *config = dev->config; struct lmp90xxx_data *data = dev->data; uint8_t ura = LMP90XXX_URA(addr); uint8_t inst1_uab[2] = { LMP90XXX_INST1_WAB, ura }; uint8_t inst2 = LMP90XXX_INST2_WB | LMP90XXX_LRA(addr); struct spi_buf tx_buf[3]; struct spi_buf_set tx; int i = 0; int err; if (len == 0) { LOG_ERR("attempt write 0 bytes to register 0x%02x", addr); return -EINVAL; } if (k_is_in_isr()) { /* Prevent SPI transactions from an ISR */ return -EWOULDBLOCK; } k_mutex_lock(&data->ura_lock, K_FOREVER); if (ura != data->ura) { /* Instruction Byte 1 + Upper Address Byte */ tx_buf[i].buf = inst1_uab; tx_buf[i].len = sizeof(inst1_uab); i++; } /* Instruction Byte 2 */ inst2 |= lmp90xxx_inst2_sz(len); tx_buf[i].buf = &inst2; tx_buf[i].len = sizeof(inst2); i++; /* Data Byte(s) */ tx_buf[i].buf = dptr; tx_buf[i].len = len; i++; tx.buffers = tx_buf; tx.count = i; err = spi_write(data->spi_dev, &config->spi_cfg, &tx); if (!err) { data->ura = ura; } else { /* Force INST1 + UAB on next access */ data->ura = LMP90XXX_INVALID_URA; } k_mutex_unlock(&data->ura_lock); return err; } static int lmp90xxx_write_reg8(const struct device *dev, uint8_t addr, uint8_t val) { return lmp90xxx_write_reg(dev, addr, &val, sizeof(val)); } static int lmp90xxx_soft_reset(const struct device *dev) { int err; err = lmp90xxx_write_reg8(dev, LMP90XXX_REG_RESETCN, LMP90XXX_REG_AND_CNV_RST); if (err) { return err; } /* Write to RESETCN twice in order to reset mode as well as registers */ return lmp90xxx_write_reg8(dev, LMP90XXX_REG_RESETCN, LMP90XXX_REG_AND_CNV_RST); } static inline bool lmp90xxx_has_channel(const struct device *dev, uint8_t channel) { const struct lmp90xxx_config *config = dev->config; if (channel >= config->channels) { return false; } else { return true; } } static inline bool lmp90xxx_has_input(const struct device *dev, uint8_t input) { const struct lmp90xxx_config *config = dev->config; if (input >= LMP90XXX_MAX_INPUTS) { return false; } else if (config->channels < LMP90XXX_MAX_CHANNELS && (input >= 3 && input <= 5)) { /* This device only has inputs 0, 1, 2, 6, and 7 */ return false; } else { return true; } } static inline int lmp90xxx_acq_time_to_odr(uint16_t acq_time) { uint16_t acq_value; if (acq_time == ADC_ACQ_TIME_DEFAULT) { return LMP90XXX_DEFAULT_ODR; } if (ADC_ACQ_TIME_UNIT(acq_time) != ADC_ACQ_TIME_TICKS) { return -EINVAL; } /* * The LMP90xxx supports odd (and very slow) output data * rates. Allow the caller to specify the ODR directly using * ADC_ACQ_TIME_TICKS */ acq_value = ADC_ACQ_TIME_VALUE(acq_time); if (acq_value <= LMP90XXX_DEFAULT_ODR) { return acq_value; } return -EINVAL; } static int lmp90xxx_adc_channel_setup(const struct device *dev, const struct adc_channel_cfg *channel_cfg) { struct lmp90xxx_data *data = dev->data; uint8_t chx_inputcn = LMP90XXX_BURNOUT_EN(0); /* No burnout currents */ uint8_t chx_config = LMP90XXX_BUF_EN(0); /* No buffer */ uint8_t payload[2]; uint8_t addr; int ret; switch (channel_cfg->reference) { case ADC_REF_EXTERNAL0: chx_inputcn |= LMP90XXX_VREF_SEL(0); break; case ADC_REF_EXTERNAL1: chx_inputcn |= LMP90XXX_VREF_SEL(1); break; default: LOG_ERR("unsupported channel reference type '%d'", channel_cfg->reference); return -ENOTSUP; } if (!lmp90xxx_has_channel(dev, channel_cfg->channel_id)) { LOG_ERR("unsupported channel id '%d'", channel_cfg->channel_id); return -ENOTSUP; } if (!lmp90xxx_has_input(dev, channel_cfg->input_positive)) { LOG_ERR("unsupported positive input '%d'", channel_cfg->input_positive); return -ENOTSUP; } chx_inputcn |= LMP90XXX_VINP(channel_cfg->input_positive); if (!lmp90xxx_has_input(dev, channel_cfg->input_negative)) { LOG_ERR("unsupported negative input '%d'", channel_cfg->input_negative); return -ENOTSUP; } chx_inputcn |= LMP90XXX_VINN(channel_cfg->input_negative); ret = lmp90xxx_acq_time_to_odr(channel_cfg->acquisition_time); if (ret < 0) { LOG_ERR("unsupported channel acquisition time 0x%02x", channel_cfg->acquisition_time); return -ENOTSUP; } chx_config |= LMP90XXX_ODR_SEL(ret); data->channel_odr[channel_cfg->channel_id] = ret; switch (channel_cfg->gain) { case ADC_GAIN_1: chx_config |= LMP90XXX_GAIN_SEL(0); break; case ADC_GAIN_2: chx_config |= LMP90XXX_GAIN_SEL(1); break; case ADC_GAIN_4: chx_config |= LMP90XXX_GAIN_SEL(2); break; case ADC_GAIN_8: chx_config |= LMP90XXX_GAIN_SEL(3); break; case ADC_GAIN_16: chx_config |= LMP90XXX_GAIN_SEL(4); break; case ADC_GAIN_32: chx_config |= LMP90XXX_GAIN_SEL(5); break; case ADC_GAIN_64: chx_config |= LMP90XXX_GAIN_SEL(6); break; case ADC_GAIN_128: chx_config |= LMP90XXX_GAIN_SEL(7); break; default: LOG_ERR("unsupported channel gain '%d'", channel_cfg->gain); return -ENOTSUP; } payload[0] = chx_inputcn; payload[1] = chx_config; addr = LMP90XXX_REG_CH_INPUTCN(channel_cfg->channel_id); ret = lmp90xxx_write_reg(dev, addr, payload, sizeof(payload)); if (ret) { LOG_ERR("failed to configure channel (err %d)", ret); } return ret; } static int lmp90xxx_validate_buffer_size(const struct adc_sequence *sequence) { uint8_t channels = 0; size_t needed; uint32_t mask; for (mask = BIT(LMP90XXX_MAX_CHANNELS - 1); mask != 0; mask >>= 1) { if (mask & sequence->channels) { channels++; } } needed = channels * sizeof(int32_t); if (sequence->options) { needed *= (1 + sequence->options->extra_samplings); } if (sequence->buffer_size < needed) { return -ENOMEM; } return 0; } static int lmp90xxx_adc_start_read(const struct device *dev, const struct adc_sequence *sequence) { const struct lmp90xxx_config *config = dev->config; struct lmp90xxx_data *data = dev->data; int err; if (sequence->resolution != config->resolution) { LOG_ERR("unsupported resolution %d", sequence->resolution); return -ENOTSUP; } if (!lmp90xxx_has_channel(dev, find_msb_set(sequence->channels) - 1)) { LOG_ERR("unsupported channels in mask: 0x%08x", sequence->channels); return -ENOTSUP; } err = lmp90xxx_validate_buffer_size(sequence); if (err) { LOG_ERR("buffer size too small"); return err; } data->buffer = sequence->buffer; data->calibrate = sequence->calibrate; adc_context_start_read(&data->ctx, sequence); return adc_context_wait_for_completion(&data->ctx); } static int lmp90xxx_adc_read_async(const struct device *dev, const struct adc_sequence *sequence, struct k_poll_signal *async) { struct lmp90xxx_data *data = dev->data; int err; adc_context_lock(&data->ctx, async ? true : false, async); err = lmp90xxx_adc_start_read(dev, sequence); adc_context_release(&data->ctx, err); return err; } static int lmp90xxx_adc_read(const struct device *dev, const struct adc_sequence *sequence) { return lmp90xxx_adc_read_async(dev, sequence, NULL); } static void adc_context_start_sampling(struct adc_context *ctx) { struct lmp90xxx_data *data = CONTAINER_OF(ctx, struct lmp90xxx_data, ctx); data->channels = ctx->sequence.channels; data->repeat_buffer = data->buffer; k_sem_give(&data->acq_sem); } static void adc_context_update_buffer_pointer(struct adc_context *ctx, bool repeat_sampling) { struct lmp90xxx_data *data = CONTAINER_OF(ctx, struct lmp90xxx_data, ctx); if (repeat_sampling) { data->buffer = data->repeat_buffer; } } static int lmp90xxx_adc_read_channel(const struct device *dev, uint8_t channel, int32_t *result) { const struct lmp90xxx_config *config = dev->config; struct lmp90xxx_data *data = dev->data; uint8_t adc_done; uint8_t ch_scan; uint8_t buf[4]; /* ADC_DOUT + CRC */ int32_t delay; uint8_t odr; int err; /* Single channel, single scan mode */ ch_scan = LMP90XXX_CH_SCAN_SEL(0x1) | LMP90XXX_FIRST_CH(channel) | LMP90XXX_LAST_CH(channel); err = lmp90xxx_write_reg8(dev, LMP90XXX_REG_CH_SCAN, ch_scan); if (err) { LOG_ERR("failed to setup scan channels (err %d)", err); return err; } /* Start scan */ err = lmp90xxx_write_reg8(dev, LMP90XXX_REG_PWRCN, LMP90XXX_PWRCN(0)); if (err) { LOG_ERR("failed to set active mode (err %d)", err); return err; } if (LMP90XXX_HAS_DRDYB(config)) { k_sem_take(&data->drdyb_sem, K_FOREVER); } else { odr = data->channel_odr[channel]; delay = lmp90xxx_odr_delay_tbl[odr]; LOG_DBG("sleeping for %d ms", delay); k_msleep(delay); /* Poll for data ready */ do { err = lmp90xxx_read_reg8(dev, LMP90XXX_REG_ADC_DONE, &adc_done); if (adc_done == 0xFFU) { LOG_DBG("sleeping for 1 ms"); k_msleep(1); } else { break; } } while (true); } if (IS_ENABLED(CONFIG_ADC_LMP90XXX_CRC)) { err = lmp90xxx_read_reg(dev, LMP90XXX_REG_ADC_DOUT, buf, sizeof(buf)); } else { err = lmp90xxx_read_reg(dev, LMP90XXX_REG_ADC_DOUT, buf, config->resolution / 8); } if (err) { LOG_ERR("failed to read ADC DOUT (err %d)", err); return err; } if (IS_ENABLED(CONFIG_ADC_LMP90XXX_CRC)) { uint8_t crc = crc8(buf, 3, 0x31, 0, false) ^ 0xFFU; if (buf[3] != crc) { LOG_ERR("CRC mismatch (0x%02x vs. 0x%02x)", buf[3], crc); return err; } } /* Read result, get rid of CRC, and sign extend result */ *result = (int32_t)sys_get_be32(buf); *result >>= (32 - config->resolution); return 0; } static void lmp90xxx_acquisition_thread(struct lmp90xxx_data *data) { uint8_t bgcalcn = LMP90XXX_BGCALN(0x3); /* Default to BgCalMode3 */ int32_t result = 0; uint8_t channel; int err; while (true) { k_sem_take(&data->acq_sem, K_FOREVER); if (data->calibrate) { /* Use BgCalMode2 */ bgcalcn = LMP90XXX_BGCALN(0x2); } LOG_DBG("using BGCALCN = 0x%02x", bgcalcn); err = lmp90xxx_write_reg8(data->dev, LMP90XXX_REG_BGCALCN, bgcalcn); if (err) { LOG_ERR("failed to setup background calibration " "(err %d)", err); adc_context_complete(&data->ctx, err); break; } while (data->channels) { channel = find_lsb_set(data->channels) - 1; LOG_DBG("reading channel %d", channel); err = lmp90xxx_adc_read_channel(data->dev, channel, &result); if (err) { adc_context_complete(&data->ctx, err); break; } LOG_DBG("finished channel %d, result = %d", channel, result); /* * ADC samples are stored as int32_t regardless of the * resolution in order to provide a uniform interface * for the driver. */ *data->buffer++ = result; WRITE_BIT(data->channels, channel, 0); } adc_context_on_sampling_done(&data->ctx, data->dev); } } static void lmp90xxx_drdyb_callback(const struct device *port, struct gpio_callback *cb, uint32_t pins) { struct lmp90xxx_data *data = CONTAINER_OF(cb, struct lmp90xxx_data, drdyb_cb); /* Signal thread that data is now ready */ k_sem_give(&data->drdyb_sem); } #ifdef CONFIG_ADC_LMP90XXX_GPIO int lmp90xxx_gpio_set_output(const struct device *dev, uint8_t pin) { struct lmp90xxx_data *data = dev->data; int err = 0; uint8_t tmp; if (pin > LMP90XXX_GPIO_MAX) { return -EINVAL; } k_mutex_lock(&data->gpio_lock, K_FOREVER); tmp = data->gpio_dircn | BIT(pin); if (tmp != data->gpio_dircn) { err = lmp90xxx_write_reg8(dev, LMP90XXX_REG_GPIO_DIRCN, tmp); if (!err) { data->gpio_dircn = tmp; } } k_mutex_unlock(&data->gpio_lock); return err; } int lmp90xxx_gpio_set_input(const struct device *dev, uint8_t pin) { struct lmp90xxx_data *data = dev->data; int err = 0; uint8_t tmp; if (pin > LMP90XXX_GPIO_MAX) { return -EINVAL; } k_mutex_lock(&data->gpio_lock, K_FOREVER); tmp = data->gpio_dircn & ~BIT(pin); if (tmp != data->gpio_dircn) { err = lmp90xxx_write_reg8(dev, LMP90XXX_REG_GPIO_DIRCN, tmp); if (!err) { data->gpio_dircn = tmp; } } k_mutex_unlock(&data->gpio_lock); return err; } int lmp90xxx_gpio_set_pin_value(const struct device *dev, uint8_t pin, bool value) { struct lmp90xxx_data *data = dev->data; int err = 0; uint8_t tmp; if (pin > LMP90XXX_GPIO_MAX) { return -EINVAL; } k_mutex_lock(&data->gpio_lock, K_FOREVER); tmp = data->gpio_dat; WRITE_BIT(tmp, pin, value); if (tmp != data->gpio_dat) { err = lmp90xxx_write_reg8(dev, LMP90XXX_REG_GPIO_DAT, tmp); if (!err) { data->gpio_dat = tmp; } } k_mutex_unlock(&data->gpio_lock); return err; } int lmp90xxx_gpio_get_pin_value(const struct device *dev, uint8_t pin, bool *value) { struct lmp90xxx_data *data = dev->data; int err = 0; uint8_t tmp; if (pin > LMP90XXX_GPIO_MAX) { return -EINVAL; } k_mutex_lock(&data->gpio_lock, K_FOREVER); err = lmp90xxx_read_reg8(dev, LMP90XXX_REG_GPIO_DAT, &tmp); if (!err) { *value = tmp & BIT(pin); } k_mutex_unlock(&data->gpio_lock); return err; } int lmp90xxx_gpio_port_get_raw(const struct device *dev, gpio_port_value_t *value) { struct lmp90xxx_data *data = dev->data; uint8_t tmp; int err; k_mutex_lock(&data->gpio_lock, K_FOREVER); err = lmp90xxx_read_reg8(dev, LMP90XXX_REG_GPIO_DAT, &tmp); tmp &= ~(data->gpio_dircn); k_mutex_unlock(&data->gpio_lock); *value = tmp; return err; } int lmp90xxx_gpio_port_set_masked_raw(const struct device *dev, gpio_port_pins_t mask, gpio_port_value_t value) { struct lmp90xxx_data *data = dev->data; int err = 0; uint8_t tmp; mask &= LMP90XXX_GPIO_DAT_MASK; k_mutex_lock(&data->gpio_lock, K_FOREVER); tmp = (data->gpio_dat & ~mask) | (value & mask); if (tmp != data->gpio_dat) { err = lmp90xxx_write_reg8(dev, LMP90XXX_REG_GPIO_DAT, tmp); if (!err) { data->gpio_dat = tmp; } } k_mutex_unlock(&data->gpio_lock); return err; } int lmp90xxx_gpio_port_set_bits_raw(const struct device *dev, gpio_port_pins_t pins) { struct lmp90xxx_data *data = dev->data; int err = 0; uint8_t tmp; tmp = pins & LMP90XXX_GPIO_DAT_MASK; k_mutex_lock(&data->gpio_lock, K_FOREVER); if (tmp != data->gpio_dat) { tmp |= data->gpio_dat; err = lmp90xxx_write_reg8(dev, LMP90XXX_REG_GPIO_DAT, tmp); if (!err) { data->gpio_dat = tmp; } } k_mutex_unlock(&data->gpio_lock); return err; } int lmp90xxx_gpio_port_clear_bits_raw(const struct device *dev, gpio_port_pins_t pins) { struct lmp90xxx_data *data = dev->data; int err = 0; uint8_t tmp; tmp = pins & LMP90XXX_GPIO_DAT_MASK; k_mutex_lock(&data->gpio_lock, K_FOREVER); if ((tmp & data->gpio_dat) != 0) { tmp = data->gpio_dat & ~tmp; err = lmp90xxx_write_reg8(dev, LMP90XXX_REG_GPIO_DAT, tmp); if (!err) { data->gpio_dat = tmp; } } k_mutex_unlock(&data->gpio_lock); return err; } int lmp90xxx_gpio_port_toggle_bits(const struct device *dev, gpio_port_pins_t pins) { struct lmp90xxx_data *data = dev->data; uint8_t tmp; int err; tmp = pins & LMP90XXX_GPIO_DAT_MASK; k_mutex_lock(&data->gpio_lock, K_FOREVER); tmp ^= data->gpio_dat; err = lmp90xxx_write_reg8(dev, LMP90XXX_REG_GPIO_DAT, tmp); if (!err) { data->gpio_dat = tmp; } k_mutex_unlock(&data->gpio_lock); return err; } #endif /* CONFIG_ADC_LMP90XXX_GPIO */ static int lmp90xxx_init(const struct device *dev) { const struct lmp90xxx_config *config = dev->config; struct lmp90xxx_data *data = dev->data; const struct device *drdyb_dev; k_tid_t tid; int err; data->dev = dev; k_mutex_init(&data->ura_lock); k_sem_init(&data->acq_sem, 0, 1); k_sem_init(&data->drdyb_sem, 0, 1); #ifdef CONFIG_ADC_LMP90XXX_GPIO k_mutex_init(&data->gpio_lock); #endif /* CONFIG_ADC_LMP90XXX_GPIO */ /* Force INST1 + UAB on first access */ data->ura = LMP90XXX_INVALID_URA; data->spi_dev = device_get_binding(config->spi_dev_name); if (!data->spi_dev) { LOG_ERR("SPI master device '%s' not found", config->spi_dev_name); return -EINVAL; } if (config->spi_cs_dev_name) { data->spi_cs.gpio_dev = device_get_binding(config->spi_cs_dev_name); if (!data->spi_cs.gpio_dev) { LOG_ERR("SPI CS GPIO device '%s' not found", config->spi_cs_dev_name); return -EINVAL; } data->spi_cs.gpio_pin = config->spi_cs_pin; data->spi_cs.gpio_dt_flags = config->spi_cs_dt_flags; } err = lmp90xxx_soft_reset(dev); if (err) { LOG_ERR("failed to request soft reset (err %d)", err); return err; } err = lmp90xxx_write_reg8(dev, LMP90XXX_REG_SPI_HANDSHAKECN, LMP90XXX_SDO_DRDYB_DRIVER(0x4)); if (err) { LOG_ERR("failed to set SPI handshake control (err %d)", err); return err; } if (config->rtd_current) { err = lmp90xxx_write_reg8(dev, LMP90XXX_REG_ADC_AUXCN, LMP90XXX_RTD_CUR_SEL(config->rtd_current)); if (err) { LOG_ERR("failed to set RTD current (err %d)", err); return err; } } if (IS_ENABLED(CONFIG_ADC_LMP90XXX_CRC)) { err = lmp90xxx_write_reg8(dev, LMP90XXX_REG_SPI_CRC_CN, LMP90XXX_EN_CRC(1) | LMP90XXX_DRDYB_AFT_CRC(1)); if (err) { LOG_ERR("failed to enable CRC (err %d)", err); return err; } } if (LMP90XXX_HAS_DRDYB(config)) { drdyb_dev = device_get_binding(config->drdyb_dev_name); if (!drdyb_dev) { LOG_ERR("DRDYB GPIO device '%s' not found", config->drdyb_dev_name); return -EINVAL; } err = gpio_pin_configure(drdyb_dev, config->drdyb_pin, GPIO_INPUT | config->drdyb_flags); if (err) { LOG_ERR("failed to configure DRDYB GPIO pin (err %d)", err); return -EINVAL; } gpio_init_callback(&data->drdyb_cb, lmp90xxx_drdyb_callback, BIT(config->drdyb_pin)); err = gpio_add_callback(drdyb_dev, &data->drdyb_cb); if (err) { LOG_ERR("failed to add DRDYB callback (err %d)", err); return -EINVAL; } err = lmp90xxx_write_reg8(dev, LMP90XXX_REG_SPI_DRDYBCN, LMP90XXX_SPI_DRDYB_D6(1)); if (err) { LOG_ERR("failed to configure D6 as DRDYB (err %d)", err); return err; } err = gpio_pin_interrupt_configure(drdyb_dev, config->drdyb_pin, GPIO_INT_EDGE_TO_ACTIVE); if (err) { LOG_ERR("failed to configure DRDBY interrupt (err %d)", err); return -EINVAL; } } tid = k_thread_create(&data->thread, data->stack, CONFIG_ADC_LMP90XXX_ACQUISITION_THREAD_STACK_SIZE, (k_thread_entry_t)lmp90xxx_acquisition_thread, data, NULL, NULL, CONFIG_ADC_LMP90XXX_ACQUISITION_THREAD_PRIO, 0, K_NO_WAIT); k_thread_name_set(tid, "adc_lmp90xxx"); /* Put device in stand-by to prepare it for single-shot conversion */ err = lmp90xxx_write_reg8(dev, LMP90XXX_REG_PWRCN, LMP90XXX_PWRCN(0x3)); if (err) { LOG_ERR("failed to request stand-by mode (err %d)", err); return err; } adc_context_unlock_unconditionally(&data->ctx); return 0; } static const struct adc_driver_api lmp90xxx_adc_api = { .channel_setup = lmp90xxx_adc_channel_setup, .read = lmp90xxx_adc_read, #ifdef CONFIG_ADC_ASYNC .read_async = lmp90xxx_adc_read_async, #endif }; #define ASSERT_LMP90XXX_CURRENT_VALID(v) \ BUILD_ASSERT(v == 0 || v == 100 || v == 200 || v == 300 || \ v == 400 || v == 500 || v == 600 || v == 700 || \ v == 800 || v == 900 || v == 1000, \ "unsupported RTD current (" #v ")") #define LMP90XXX_UAMPS_TO_RTD_CUR_SEL(x) (x / 100) #define DT_INST_LMP90XXX(inst, t) DT_INST(inst, ti_lmp##t) #define LMP90XXX_DEVICE(t, n, res, ch) \ ASSERT_LMP90XXX_CURRENT_VALID(UTIL_AND( \ DT_NODE_HAS_PROP(DT_INST_LMP90XXX(n, t), rtd_current), \ DT_PROP(DT_INST_LMP90XXX(n, t), rtd_current))); \ static struct lmp90xxx_data lmp##t##_data_##n = { \ ADC_CONTEXT_INIT_TIMER(lmp##t##_data_##n, ctx), \ ADC_CONTEXT_INIT_LOCK(lmp##t##_data_##n, ctx), \ ADC_CONTEXT_INIT_SYNC(lmp##t##_data_##n, ctx), \ }; \ static const struct lmp90xxx_config lmp##t##_config_##n = { \ .spi_dev_name = DT_BUS_LABEL(DT_INST_LMP90XXX(n, t)), \ .spi_cs_dev_name = UTIL_AND( \ DT_SPI_DEV_HAS_CS_GPIOS(DT_INST_LMP90XXX(n, t)), \ DT_SPI_DEV_CS_GPIOS_LABEL(DT_INST_LMP90XXX(n, t)) \ ), \ .spi_cs_pin = UTIL_AND( \ DT_SPI_DEV_HAS_CS_GPIOS(DT_INST_LMP90XXX(n, t)), \ DT_SPI_DEV_CS_GPIOS_PIN(DT_INST_LMP90XXX(n, t)) \ ), \ .spi_cs_dt_flags = UTIL_AND( \ DT_SPI_DEV_HAS_CS_GPIOS(DT_INST_LMP90XXX(n, t)), \ DT_SPI_DEV_CS_GPIOS_FLAGS(DT_INST_LMP90XXX(n, t)) \ ), \ .spi_cfg = { \ .operation = (SPI_OP_MODE_MASTER | SPI_TRANSFER_MSB | \ SPI_WORD_SET(8)), \ .frequency = DT_PROP(DT_INST_LMP90XXX(n, t), \ spi_max_frequency), \ .slave = DT_REG_ADDR(DT_INST_LMP90XXX(n, t)), \ .cs = &lmp##t##_data_##n.spi_cs, \ }, \ .drdyb_dev_name = UTIL_AND( \ DT_NODE_HAS_PROP(DT_INST_LMP90XXX(n, t), drdyb_gpios), \ DT_GPIO_LABEL(DT_INST_LMP90XXX(n, t), drdyb_gpios) \ ), \ .drdyb_pin = UTIL_AND( \ DT_NODE_HAS_PROP(DT_INST_LMP90XXX(n, t), drdyb_gpios), \ DT_GPIO_PIN(DT_INST_LMP90XXX(n, t), drdyb_gpios) \ ), \ .drdyb_flags = UTIL_AND( \ DT_NODE_HAS_PROP(DT_INST_LMP90XXX(n, t), drdyb_gpios), \ DT_GPIO_FLAGS(DT_INST_LMP90XXX(n, t), drdyb_gpios) \ ), \ .rtd_current = UTIL_AND( \ DT_NODE_HAS_PROP(DT_INST_LMP90XXX(n, t), rtd_current), \ LMP90XXX_UAMPS_TO_RTD_CUR_SEL( \ DT_PROP(DT_INST_LMP90XXX(n, t), rtd_current)) \ ), \ .resolution = res, \ .channels = ch, \ }; \ DEVICE_AND_API_INIT(lmp##t##_##n, \ DT_LABEL(DT_INST_LMP90XXX(n, t)), \ &lmp90xxx_init, &lmp##t##_data_##n, \ &lmp##t##_config_##n, POST_KERNEL, \ CONFIG_ADC_LMP90XXX_INIT_PRIORITY, \ &lmp90xxx_adc_api) /* * LMP90077: 16 bit, 2 diff/4 se (4 channels), 0 currents */ #if DT_HAS_COMPAT_STATUS_OKAY(ti_lmp90077) LMP90XXX_DEVICE(90077, 0, 16, 4); #endif /* * LMP90078: 16 bit, 2 diff/4 se (4 channels), 2 currents */ #if DT_HAS_COMPAT_STATUS_OKAY(ti_lmp90078) LMP90XXX_DEVICE(90078, 0, 16, 4); #endif /* * LMP90079: 16 bit, 4 diff/7 se (7 channels), 0 currents, has VIN3-5 */ #if DT_HAS_COMPAT_STATUS_OKAY(ti_lmp90079) LMP90XXX_DEVICE(90079, 0, 16, 7); #endif /* * LMP90080: 16 bit, 4 diff/7 se (7 channels), 2 currents, has VIN3-5 */ #if DT_HAS_COMPAT_STATUS_OKAY(ti_lmp90080) LMP90XXX_DEVICE(90080, 0, 16, 7); #endif /* * LMP90097: 24 bit, 2 diff/4 se (4 channels), 0 currents */ #if DT_HAS_COMPAT_STATUS_OKAY(ti_lmp90097) LMP90XXX_DEVICE(90097, 0, 24, 4); #endif /* * LMP90098: 24 bit, 2 diff/4 se (4 channels), 2 currents */ #if DT_HAS_COMPAT_STATUS_OKAY(ti_lmp90098) LMP90XXX_DEVICE(90098, 0, 24, 4); #endif /* * LMP90099: 24 bit, 4 diff/7 se (7 channels), 0 currents, has VIN3-5 */ #if DT_HAS_COMPAT_STATUS_OKAY(ti_lmp90099) LMP90XXX_DEVICE(90099, 0, 24, 7); #endif /* * LMP90100: 24 bit, 4 diff/7 se (7 channels), 2 currents, has VIN3-5 */ #if DT_HAS_COMPAT_STATUS_OKAY(ti_lmp90100) LMP90XXX_DEVICE(90100, 0, 24, 7); #endif