/* * Copyright (c) 2020 Nuvoton Technology Corporation. * * SPDX-License-Identifier: Apache-2.0 */ #define DT_DRV_COMPAT nuvoton_npcx_adc #include #include #include #include #include #include #include #include #define ADC_CONTEXT_USES_KERNEL_TIMER #include "adc_context.h" #include #include LOG_MODULE_REGISTER(adc_npcx, CONFIG_ADC_LOG_LEVEL); /* ADC speed/delay values during initialization */ #define ADC_REGULAR_DLY_VAL 0x03 #define ADC_REGULAR_ADCCNF2_VAL 0x8B07 #define ADC_REGULAR_GENDLY_VAL 0x0100 #define ADC_REGULAR_MEAST_VAL 0x0001 /* ADC targeted operating frequency (2MHz) */ #define NPCX_ADC_CLK 2000000 /* ADC conversion mode */ #define NPCX_ADC_CHN_CONVERSION_MODE 0 #define NPCX_ADC_SCAN_CONVERSION_MODE 1 /* Max channel number to be converted in ADCCS */ #define NPCX_ADCCS_MAX_CHANNEL_COUNT 16 #define ADC_NPCX_THRVAL_RESOLUTION 10 #define ADC_NPCX_THRVAL_MAX BIT_MASK(ADC_NPCX_THRVAL_RESOLUTION) /* Device config */ struct adc_npcx_config { /* adc controller base address */ uintptr_t base; /* clock configuration */ struct npcx_clk_cfg clk_cfg; /* the number of ADC channels */ const uint8_t channel_count; /* amount of thresholds supported */ const uint8_t threshold_count; /* routine for configuring ADC's ISR */ void (*irq_cfg_func)(void); const struct pinctrl_dev_config *pcfg; }; struct adc_npcx_threshold_control { /* * Selects ADC channel number, for which the measured data is compared * for threshold detection. */ uint8_t chnsel; /* * Sets relation between measured value and assetion threshold value. * in thrval: * 0: Threshold event is generated if Measured data > thrval. * 1: Threshold event is generated if Measured data <= thrval. */ bool l_h; /* Sets the threshold value to which measured data is compared. */ uint16_t thrval; /* * Pointer of work queue item to be notified when threshold assertion * occurs. */ struct k_work *work; }; struct adc_npcx_threshold_data { /* * While threshold interruption is enabled we need to resume to repetitive * sampling mode after adc_npcx_read is called. This variable records * channels being used in repetitive mode in order to set ADC registers * back to threshold detection when adc_npcx_read is completed. */ uint32_t repetitive_channels; /* * While threshold interruption is enabled, adc_npcx_read must disable * all active threshold running to avoid race condition, this variable * helps restore active threshods after adc_npcs_read has finnished. */ uint8_t active_thresholds; /* This array holds current configuration for each threshold. */ struct adc_npcx_threshold_control control[DT_INST_PROP(0, threshold_count)]; }; /* Driver data */ struct adc_npcx_data { /* Input clock for ADC converter */ uint32_t input_clk; /* mutex of ADC channels */ struct adc_context ctx; /* * Bit-mask indicating the channels to be included in each sampling * of this sequence. */ uint32_t channels; /* ADC Device pointer used in api functions */ const struct device *adc_dev; uint16_t *buffer; uint16_t *repeat_buffer; /* end pointer of buffer to ensure enough space for storing ADC data. */ uint16_t *buf_end; /* Threshold comparator data pointer */ struct adc_npcx_threshold_data *threshold_data; #ifdef CONFIG_PM atomic_t current_pm_lock; #endif }; /* * Pointer of internal work queue thread to be notified when threshold assertion * occurs if CONFIG_ADC_CMP_NPCX_WORKQUEUE is enabled. */ struct k_work_q *work_q; /* Driver convenience defines */ #define HAL_INSTANCE(dev) ((struct adc_reg *)((const struct adc_npcx_config *)(dev)->config)->base) /* ADC local functions */ #ifdef CONFIG_PM static void adc_npcx_pm_policy_state_lock_get(struct adc_npcx_data *data) { if (atomic_test_and_set_bit(&data->current_pm_lock, 0) == 0) { pm_policy_state_lock_get(PM_STATE_SUSPEND_TO_IDLE, PM_ALL_SUBSTATES); } } static void adc_npcx_pm_policy_state_lock_put(struct adc_npcx_data *data) { if (atomic_test_and_clear_bit(&data->current_pm_lock, 0) == 1) { pm_policy_state_lock_put(PM_STATE_SUSPEND_TO_IDLE, PM_ALL_SUBSTATES); } } #endif static inline void adc_npcx_config_channels(const struct device *dev, uint32_t channels) { const struct adc_npcx_config *config = dev->config; struct adc_reg *const inst = HAL_INSTANCE(dev); inst->ADCCS = channels & BIT_MASK(NPCX_ADCCS_MAX_CHANNEL_COUNT); /* Only npcx4 and later series support over 16 ADC channels */ if (config->channel_count > NPCX_ADCCS_MAX_CHANNEL_COUNT) { inst->ADCCS2 = (channels >> NPCX_ADCCS_MAX_CHANNEL_COUNT) & BIT_MASK(NPCX_ADCCS_MAX_CHANNEL_COUNT); } } static inline void adc_npcx_enable_threshold_detect(const struct device *dev, uint8_t th_sel, bool enable) { const struct adc_npcx_config *config = dev->config; if (enable) { #ifdef CONFIG_SOC_SERIES_NPCX4 THEN(config->base) |= BIT(th_sel); #else THRCTL(config->base, th_sel) |= BIT(NPCX_THRCTL_THEN); #endif } else { #ifdef CONFIG_SOC_SERIES_NPCX4 THEN(config->base) &= ~BIT(th_sel); #else THRCTL(config->base, th_sel) &= ~BIT(NPCX_THRCTL_THEN); #endif } } static void adc_npcx_isr(const struct device *dev) { const struct adc_npcx_config *config = dev->config; struct adc_npcx_data *const data = dev->data; struct adc_reg *const inst = HAL_INSTANCE(dev); struct adc_npcx_threshold_data *const t_data = data->threshold_data; uint16_t status = inst->ADCSTS; uint16_t result, channel; /* Clear status pending bits first */ inst->ADCSTS = status; LOG_DBG("%s: status is %04X\n", __func__, status); /* Is end of conversion cycle event? ie. Scan conversion is done. */ if (IS_BIT_SET(status, NPCX_ADCSTS_EOCCEV) && IS_BIT_SET(inst->ADCCNF, NPCX_ADCCNF_INTECCEN)) { /* Stop conversion for scan conversion mode */ inst->ADCCNF |= BIT(NPCX_ADCCNF_STOP); /* Get result for each ADC selected channel */ while (data->channels) { channel = find_lsb_set(data->channels) - 1; result = GET_FIELD(CHNDAT(config->base, channel), NPCX_CHNDAT_CHDAT_FIELD); /* * Save ADC result and adc_npcx_validate_buffer_size() * already ensures that the buffer has enough space for * storing result. */ if (data->buffer < data->buf_end) { *data->buffer++ = result; } data->channels &= ~BIT(channel); } /* Disable End of cyclic conversion interruption */ inst->ADCCNF &= ~BIT(NPCX_ADCCNF_INTECCEN); if (IS_ENABLED(CONFIG_ADC_CMP_NPCX) && t_data->active_thresholds) { /* Set repetitive channels back */ adc_npcx_config_channels(dev, t_data->repetitive_channels); /* Start conversion */ inst->ADCCNF |= BIT(NPCX_ADCCNF_START); } else { /* Disable all channels */ adc_npcx_config_channels(dev, 0); /* Turn off ADC */ inst->ADCCNF &= ~(BIT(NPCX_ADCCNF_ADCEN)); #ifdef CONFIG_PM adc_npcx_pm_policy_state_lock_put(data); #endif } /* Inform sampling is done */ adc_context_on_sampling_done(&data->ctx, data->adc_dev); } if (!(IS_ENABLED(CONFIG_ADC_CMP_NPCX) && t_data->active_thresholds)) { return; } uint16_t thrcts; for (uint8_t i = 0; i < config->threshold_count; i++) { if (IS_BIT_SET(inst->THRCTS, i) && IS_BIT_SET(inst->THRCTS, (NPCX_THRCTS_THR1_IEN + i))) { /* Avoid clearing other threshold status */ thrcts = inst->THRCTS & ~GENMASK(config->threshold_count - 1, 0); /* Clear threshold status */ thrcts |= BIT(i); inst->THRCTS = thrcts; if (t_data->control[i].work) { /* Notify work thread */ k_work_submit_to_queue(work_q ? work_q : &k_sys_work_q, t_data->control[i].work); } } } } /* * Validate the buffer size with adc channels mask. If it is lower than what * we need return -ENOSPC. */ static int adc_npcx_validate_buffer_size(const struct device *dev, const struct adc_sequence *sequence) { const struct adc_npcx_config *config = dev->config; uint8_t channels = 0; uint32_t mask; size_t needed; for (mask = BIT(config->channel_count - 1); mask != 0; mask >>= 1) { if (mask & sequence->channels) { channels++; } } needed = channels * sizeof(uint16_t); if (sequence->options) { needed *= (1 + sequence->options->extra_samplings); } if (sequence->buffer_size < needed) { return -ENOSPC; } return 0; } static void adc_npcx_start_scan(const struct device *dev) { const struct adc_npcx_config *config = dev->config; struct adc_npcx_data *const data = dev->data; struct adc_reg *const inst = HAL_INSTANCE(dev); #ifdef CONFIG_PM adc_npcx_pm_policy_state_lock_get(data); #endif /* Turn on ADC first */ inst->ADCCNF |= BIT(NPCX_ADCCNF_ADCEN); /* Stop conversion for scan conversion mode */ inst->ADCCNF |= BIT(NPCX_ADCCNF_STOP); /* Clear end of cyclic conversion event status flag */ inst->ADCSTS |= BIT(NPCX_ADCSTS_EOCCEV); /* Update selected channels in scan mode by channels mask */ adc_npcx_config_channels(dev, data->channels); /* Select 'Scan' Conversion mode. */ SET_FIELD(inst->ADCCNF, NPCX_ADCCNF_ADCMD_FIELD, NPCX_ADC_SCAN_CONVERSION_MODE); /* Enable end of cyclic conversion event interrupt */ inst->ADCCNF |= BIT(NPCX_ADCCNF_INTECCEN); /* Start conversion */ inst->ADCCNF |= BIT(NPCX_ADCCNF_START); if (config->channel_count > NPCX_ADCCS_MAX_CHANNEL_COUNT) { LOG_DBG("Start ADC scan conversion and ADCCNF,ADCCS, ADCCS2 are " "(%04X,%04X,%04X)\n", inst->ADCCNF, inst->ADCCS, inst->ADCCS2); } else { LOG_DBG("Start ADC scan conversion and ADCCNF,ADCCS are (%04X,%04X)\n", inst->ADCCNF, inst->ADCCS); } } static int adc_npcx_start_read(const struct device *dev, const struct adc_sequence *sequence) { const struct adc_npcx_config *config = dev->config; struct adc_npcx_data *const data = dev->data; int error = 0; if (!sequence->channels || (sequence->channels & ~BIT_MASK(config->channel_count))) { LOG_ERR("Invalid ADC channels"); return -EINVAL; } /* Fixed 10 bit resolution of npcx ADC */ if (sequence->resolution != 10) { LOG_ERR("Unfixed 10 bit ADC resolution"); return -ENOTSUP; } error = adc_npcx_validate_buffer_size(dev, sequence); if (error) { LOG_ERR("ADC buffer size too small"); return error; } /* Save ADC sequence sampling buffer and its end pointer address */ data->buffer = sequence->buffer; data->buf_end = data->buffer + sequence->buffer_size / sizeof(uint16_t); /* Start ADC conversion */ adc_context_start_read(&data->ctx, sequence); error = adc_context_wait_for_completion(&data->ctx); return error; } /* ADC api functions */ static void adc_context_start_sampling(struct adc_context *ctx) { struct adc_npcx_data *const data = CONTAINER_OF(ctx, struct adc_npcx_data, ctx); data->repeat_buffer = data->buffer; data->channels = ctx->sequence.channels; /* Start ADC scan conversion */ adc_npcx_start_scan(data->adc_dev); } static void adc_context_update_buffer_pointer(struct adc_context *ctx, bool repeat_sampling) { struct adc_npcx_data *const data = CONTAINER_OF(ctx, struct adc_npcx_data, ctx); if (repeat_sampling) { data->buffer = data->repeat_buffer; } } static int adc_npcx_channel_setup(const struct device *dev, const struct adc_channel_cfg *channel_cfg) { const struct adc_npcx_config *config = dev->config; uint8_t channel_id = channel_cfg->channel_id; if (channel_id >= config->channel_count) { LOG_ERR("Invalid channel %d", channel_id); return -EINVAL; } if (channel_cfg->acquisition_time != ADC_ACQ_TIME_DEFAULT) { LOG_ERR("Unsupported channel acquisition time"); return -ENOTSUP; } if (channel_cfg->differential) { LOG_ERR("Differential channels are not supported"); return -ENOTSUP; } if (channel_cfg->gain != ADC_GAIN_1) { LOG_ERR("Unsupported channel gain %d", channel_cfg->gain); return -ENOTSUP; } if (channel_cfg->reference != ADC_REF_INTERNAL) { LOG_ERR("Unsupported channel reference"); return -ENOTSUP; } LOG_DBG("ADC channel %d configured", channel_cfg->channel_id); return 0; } static int adc_npcx_read(const struct device *dev, const struct adc_sequence *sequence) { struct adc_npcx_data *const data = dev->data; int error; adc_context_lock(&data->ctx, false, NULL); error = adc_npcx_start_read(dev, sequence); adc_context_release(&data->ctx, error); return error; } #if defined(CONFIG_ADC_ASYNC) static int adc_npcx_read_async(const struct device *dev, const struct adc_sequence *sequence, struct k_poll_signal *async) { struct adc_npcx_data *const data = dev->data; int error; adc_context_lock(&data->ctx, true, async); error = adc_npcx_start_read(dev, sequence); adc_context_release(&data->ctx, error); return error; } #endif /* CONFIG_ADC_ASYNC */ static void adc_npcx_set_repetitive(const struct device *dev, int chnsel, uint8_t enable) { struct adc_reg *const inst = HAL_INSTANCE(dev); struct adc_npcx_data *const data = dev->data; struct adc_npcx_threshold_data *const t_data = data->threshold_data; /* Stop ADC conversion */ inst->ADCCNF |= BIT(NPCX_ADCCNF_STOP); if (enable) { #ifdef CONFIG_PM adc_npcx_pm_policy_state_lock_get(data); #endif /* Turn on ADC */ inst->ADCCNF |= BIT(NPCX_ADCCNF_ADCEN); /* Set ADC conversion code to SW conversion mode */ SET_FIELD(inst->ADCCNF, NPCX_ADCCNF_ADCMD_FIELD, NPCX_ADC_SCAN_CONVERSION_MODE); /* Add selected ADC channel to be converted */ t_data->repetitive_channels |= BIT(chnsel); adc_npcx_config_channels(dev, t_data->repetitive_channels); /* Set conversion type to repetitive (runs continuously) */ inst->ADCCNF |= BIT(NPCX_ADCCNF_ADCRPTC); /* Start conversion */ inst->ADCCNF |= BIT(NPCX_ADCCNF_START); } else { /* Remove selected ADC channel to be converted */ t_data->repetitive_channels &= ~BIT(chnsel); adc_npcx_config_channels(dev, t_data->repetitive_channels); if (!t_data->repetitive_channels) { /* No thesholdd active left, disable repetitive mode */ inst->ADCCNF &= ~BIT(NPCX_ADCCNF_ADCRPTC); /* Turn off ADC */ inst->ADCCNF &= ~BIT(NPCX_ADCCNF_ADCEN); #ifdef CONFIG_PM adc_npcx_pm_policy_state_lock_put(data); #endif } else { /* Start conversion again */ inst->ADCCNF |= BIT(NPCX_ADCCNF_START); } } } int adc_npcx_threshold_ctrl_set_param(const struct device *dev, const uint8_t th_sel, const struct adc_npcx_threshold_param *param) { const struct adc_npcx_config *config = dev->config; struct adc_npcx_data *const data = dev->data; struct adc_npcx_threshold_data *const t_data = data->threshold_data; struct adc_npcx_threshold_control *const t_ctrl = &t_data->control[th_sel]; int ret = 0; if (!IS_ENABLED(CONFIG_ADC_CMP_NPCX)) { return -EOPNOTSUPP; } if (!param || th_sel >= config->threshold_count) { return -EINVAL; } adc_context_lock(&data->ctx, false, NULL); switch (param->type) { case ADC_NPCX_THRESHOLD_PARAM_CHNSEL: if (param->val >= config->channel_count) { ret = -EINVAL; break; } t_ctrl->chnsel = (uint8_t)param->val; break; case ADC_NPCX_THRESHOLD_PARAM_L_H: t_ctrl->l_h = !!param->val; break; case ADC_NPCX_THRESHOLD_PARAM_THVAL: if (param->val == 0 || param->val >= ADC_NPCX_THRVAL_MAX) { ret = -EINVAL; break; } t_ctrl->thrval = (uint16_t)param->val; break; case ADC_NPCX_THRESHOLD_PARAM_WORK: if (param->val == 0) { ret = -EINVAL; break; } t_ctrl->work = (struct k_work *)param->val; break; default: ret = -EINVAL; } adc_context_release(&data->ctx, 0); return ret; } static int adc_npcx_threshold_ctrl_setup(const struct device *dev, const uint8_t th_sel) { struct adc_npcx_data *const data = dev->data; struct adc_driver_api *api = (struct adc_driver_api *)dev->api; struct adc_npcx_threshold_data *const t_data = data->threshold_data; const struct adc_npcx_config *config = dev->config; struct adc_npcx_threshold_control *const t_ctrl = &t_data->control[th_sel]; if (th_sel >= config->threshold_count) { return -EINVAL; } adc_context_lock(&data->ctx, false, NULL); if (t_data->active_thresholds & BIT(th_sel)) { /* Unable to setup threshold parameters while active */ adc_context_release(&data->ctx, 0); LOG_ERR("Threshold selected (%d) is active!", th_sel); return -EBUSY; } if (t_ctrl->chnsel >= config->channel_count || t_ctrl->thrval >= api->ref_internal || t_ctrl->thrval == 0 || t_ctrl->work == 0) { adc_context_release(&data->ctx, 0); LOG_ERR("Threshold selected (%d) is not configured!", th_sel); return -EINVAL; } SET_FIELD(THRCTL(config->base, th_sel), NPCX_THRCTL_CHNSEL, t_ctrl->chnsel); if (t_ctrl->l_h) { THRCTL(config->base, th_sel) |= BIT(NPCX_THRCTL_L_H); } else { THRCTL(config->base, th_sel) &= ~BIT(NPCX_THRCTL_L_H); } /* Set the threshold value. */ SET_FIELD(THRCTL(config->base, th_sel), NPCX_THRCTL_THRVAL, t_ctrl->thrval); adc_context_release(&data->ctx, 0); return 0; } static int adc_npcx_threshold_enable_irq(const struct device *dev, const uint8_t th_sel) { struct adc_reg *const inst = HAL_INSTANCE(dev); struct adc_driver_api *api = (struct adc_driver_api *)dev->api; struct adc_npcx_data *const data = dev->data; const struct adc_npcx_config *config = dev->config; struct adc_npcx_threshold_data *const t_data = data->threshold_data; struct adc_npcx_threshold_control *const t_ctrl = &t_data->control[th_sel]; uint16_t thrcts; if (th_sel >= config->threshold_count) { LOG_ERR("Invalid ADC threshold selection! (%d)", th_sel); return -EINVAL; } adc_context_lock(&data->ctx, false, NULL); if (t_ctrl->chnsel >= config->channel_count || t_ctrl->thrval >= api->ref_internal || t_ctrl->thrval == 0 || t_ctrl->work == 0) { adc_context_release(&data->ctx, 0); LOG_ERR("Threshold selected (%d) is not configured!", th_sel); return -EINVAL; } /* Record new active threshold */ t_data->active_thresholds |= BIT(th_sel); /* avoid clearing other threshold status */ thrcts = inst->THRCTS & ~GENMASK(config->threshold_count - 1, 0); /* Enable threshold detection */ adc_npcx_enable_threshold_detect(dev, th_sel, true); /* clear threshold status */ thrcts |= BIT(th_sel); /* set enable threshold status */ thrcts |= BIT(NPCX_THRCTS_THR1_IEN + th_sel); inst->THRCTS = thrcts; adc_npcx_set_repetitive(dev, t_data->control[th_sel].chnsel, true); adc_context_release(&data->ctx, 0); return 0; } int adc_npcx_threshold_disable_irq(const struct device *dev, const uint8_t th_sel) { struct adc_reg *const inst = HAL_INSTANCE(dev); const struct adc_npcx_config *config = dev->config; struct adc_npcx_data *const data = dev->data; struct adc_npcx_threshold_data *const t_data = data->threshold_data; uint16_t thrcts; if (!IS_ENABLED(CONFIG_ADC_CMP_NPCX)) { return -EOPNOTSUPP; } if (th_sel >= config->threshold_count) { LOG_ERR("Invalid ADC threshold selection! (%d)", th_sel); return -EINVAL; } adc_context_lock(&data->ctx, false, NULL); if (!(t_data->active_thresholds & BIT(th_sel))) { adc_context_release(&data->ctx, 0); LOG_ERR("Threshold selection (%d) is not enabled", th_sel); return -ENODEV; } /* avoid clearing other threshold status */ thrcts = inst->THRCTS & ~GENMASK(config->threshold_count - 1, 0); /* set enable threshold status */ thrcts &= ~BIT(NPCX_THRCTS_THR1_IEN + th_sel); inst->THRCTS = thrcts; /* Disable threshold detection */ adc_npcx_enable_threshold_detect(dev, th_sel, false); /* Update active threshold */ t_data->active_thresholds &= ~BIT(th_sel); adc_npcx_set_repetitive(dev, t_data->control[th_sel].chnsel, false); adc_context_release(&data->ctx, 0); return 0; } int adc_npcx_threshold_ctrl_enable(const struct device *dev, uint8_t th_sel, const bool enable) { int ret; if (!IS_ENABLED(CONFIG_ADC_CMP_NPCX)) { return -EOPNOTSUPP; } /* Enable/Disable threshold IRQ */ if (enable) { /* Set control threshold registers */ ret = adc_npcx_threshold_ctrl_setup(dev, th_sel); if (ret) { return ret; } ret = adc_npcx_threshold_enable_irq(dev, th_sel); } else { ret = adc_npcx_threshold_disable_irq(dev, th_sel); } return ret; } int adc_npcx_threshold_mv_to_thrval(const struct device *dev, uint32_t val_mv, uint32_t *thrval) { struct adc_driver_api *api = (struct adc_driver_api *)dev->api; if (!IS_ENABLED(CONFIG_ADC_CMP_NPCX)) { return -EOPNOTSUPP; } if (val_mv >= api->ref_internal) { return -EINVAL; } *thrval = (val_mv << ADC_NPCX_THRVAL_RESOLUTION) / api->ref_internal; return 0; } #if defined(CONFIG_ADC_CMP_NPCX_WORKQUEUE) struct k_work_q adc_npcx_work_q; static K_KERNEL_STACK_DEFINE(adc_npcx_work_q_stack, CONFIG_ADC_CMP_NPCX_WORKQUEUE_STACK_SIZE); static int adc_npcx_init_cmp_work_q(void) { struct k_work_queue_config cfg = { .name = "adc_cmp_work", .no_yield = false, }; k_work_queue_start(&adc_npcx_work_q, adc_npcx_work_q_stack, K_KERNEL_STACK_SIZEOF(adc_npcx_work_q_stack), CONFIG_ADC_CMP_NPCX_WORKQUEUE_PRIORITY, &cfg); work_q = &adc_npcx_work_q; return 0; } SYS_INIT(adc_npcx_init_cmp_work_q, POST_KERNEL, CONFIG_SENSOR_INIT_PRIORITY); #endif static int adc_npcx_init(const struct device *dev) { const struct adc_npcx_config *const config = dev->config; struct adc_npcx_data *const data = dev->data; struct adc_reg *const inst = HAL_INSTANCE(dev); const struct device *const clk_dev = DEVICE_DT_GET(NPCX_CLK_CTRL_NODE); int prescaler = 0, ret; if (!device_is_ready(clk_dev)) { LOG_ERR("clock control device not ready"); return -ENODEV; } /* Save ADC device in data */ data->adc_dev = dev; /* Turn on device clock first and get source clock freq. */ ret = clock_control_on(clk_dev, (clock_control_subsys_t) &config->clk_cfg); if (ret < 0) { LOG_ERR("Turn on ADC clock fail %d", ret); return ret; } ret = clock_control_get_rate(clk_dev, (clock_control_subsys_t) &config->clk_cfg, &data->input_clk); if (ret < 0) { LOG_ERR("Get ADC clock rate error %d", ret); return ret; } /* Configure the ADC clock */ prescaler = DIV_ROUND_UP(data->input_clk, NPCX_ADC_CLK); if (prescaler > 0x40) { prescaler = 0x40; } /* Set Core Clock Division Factor in order to obtain the ADC clock */ SET_FIELD(inst->ATCTL, NPCX_ATCTL_SCLKDIV_FIELD, prescaler - 1); /* Set regular ADC delay */ SET_FIELD(inst->ATCTL, NPCX_ATCTL_DLY_FIELD, ADC_REGULAR_DLY_VAL); /* Set ADC speed sequentially */ inst->ADCCNF2 = ADC_REGULAR_ADCCNF2_VAL; inst->GENDLY = ADC_REGULAR_GENDLY_VAL; inst->MEAST = ADC_REGULAR_MEAST_VAL; /* Configure ADC interrupt and enable it */ config->irq_cfg_func(); /* Initialize mutex of ADC channels */ adc_context_unlock_unconditionally(&data->ctx); /* Configure pin-mux for ADC device */ ret = pinctrl_apply_state(config->pcfg, PINCTRL_STATE_DEFAULT); if (ret < 0) { LOG_ERR("ADC pinctrl setup failed (%d)", ret); return ret; } return 0; } #define NPCX_ADC_INIT(n) \ \ static void adc_npcx_irq_cfg_func_##n(void) \ { \ IRQ_CONNECT(DT_INST_IRQN(n), DT_INST_IRQ(n, priority), \ adc_npcx_isr, DEVICE_DT_INST_GET(n), 0); \ irq_enable(DT_INST_IRQN(n)); \ } \ \ static const struct adc_driver_api adc_npcx_driver_api_##n = { \ .channel_setup = adc_npcx_channel_setup, \ .read = adc_npcx_read, \ .ref_internal = DT_INST_PROP(n, vref_mv), \ IF_ENABLED(CONFIG_ADC_ASYNC, \ (.read_async = adc_npcx_read_async,)) \ }; \ \ PINCTRL_DT_INST_DEFINE(n); \ \ static const struct adc_npcx_config adc_npcx_cfg_##n = { \ .base = DT_INST_REG_ADDR(n), \ .clk_cfg = NPCX_DT_CLK_CFG_ITEM(n), \ .channel_count = DT_INST_PROP(n, channel_count), \ .threshold_count = DT_INST_PROP(n, threshold_count), \ .pcfg = PINCTRL_DT_INST_DEV_CONFIG_GET(n), \ .irq_cfg_func = adc_npcx_irq_cfg_func_##n, \ }; \ static struct adc_npcx_threshold_data threshold_data_##n; \ static struct adc_npcx_data adc_npcx_data_##n = { \ ADC_CONTEXT_INIT_TIMER(adc_npcx_data_##n, ctx), \ ADC_CONTEXT_INIT_LOCK(adc_npcx_data_##n, ctx), \ ADC_CONTEXT_INIT_SYNC(adc_npcx_data_##n, ctx), \ .threshold_data = &threshold_data_##n, \ }; \ DEVICE_DT_INST_DEFINE(n, \ adc_npcx_init, NULL, \ &adc_npcx_data_##n, &adc_npcx_cfg_##n, \ PRE_KERNEL_1, CONFIG_ADC_INIT_PRIORITY, \ &adc_npcx_driver_api_##n); DT_INST_FOREACH_STATUS_OKAY(NPCX_ADC_INIT)