/* * Copyright (c) 2019-2020 Peter Bigot Consulting, LLC * * SPDX-License-Identifier: Apache-2.0 */ #define DT_DRV_COMPAT maxim_ds3231 #include #include #include #include #include #include #include #include LOG_MODULE_REGISTER(DS3231, CONFIG_COUNTER_LOG_LEVEL); #define REG_MONCEN_CENTURY 0x80 #define REG_HOURS_12H 0x40 #define REG_HOURS_PM 0x20 #define REG_HOURS_20 0x20 #define REG_HOURS_10 0x20 #define REG_DAYDATE_DOW 0x40 #define REG_ALARM_IGN 0x80 enum { SYNCSM_IDLE, SYNCSM_PREP_READ, SYNCSM_FINISH_READ, SYNCSM_PREP_WRITE, SYNCSM_FINISH_WRITE, }; struct register_map { uint8_t sec; uint8_t min; uint8_t hour; uint8_t dow; uint8_t dom; uint8_t moncen; uint8_t year; struct { uint8_t sec; uint8_t min; uint8_t hour; uint8_t date; } __packed alarm1; struct { uint8_t min; uint8_t hour; uint8_t date; } __packed alarm2; uint8_t ctrl; uint8_t ctrl_stat; uint8_t aging; int8_t temp_units; uint8_t temp_frac256; }; struct gpios { const char *ctrl; gpio_pin_t pin; gpio_dt_flags_t flags; }; struct ds3231_config { /* Common structure first because generic API expects this here. */ struct counter_config_info generic; const char *bus_name; struct gpios isw_gpios; uint16_t addr; }; struct ds3231_data { const struct device *ds3231; const struct device *i2c; const struct device *isw; struct register_map registers; struct k_sem lock; /* Timer structure used for synchronization */ struct k_timer sync_timer; /* Work structures for the various cases of ISW interrupt. */ struct k_work alarm_work; struct k_work sqw_work; struct k_work sync_work; /* Forward ISW interrupt to proper worker. */ struct gpio_callback isw_callback; /* syncclock captured in the last ISW interrupt handler */ uint32_t isw_syncclock; struct maxim_ds3231_syncpoint syncpoint; struct maxim_ds3231_syncpoint new_sp; time_t rtc_registers; time_t rtc_base; uint32_t syncclock_base; /* Pointer to the structure used to notify when a synchronize * or set operation completes. Null when nobody's waiting for * such an operation, or when doing a no-notify synchronize * through the signal API. */ union { void *ptr; struct sys_notify *notify; struct k_poll_signal *signal; } sync; /* Handlers and state when using the counter alarm API. */ counter_alarm_callback_t counter_handler[2]; uint32_t counter_ticks[2]; /* Handlers and state for DS3231 alarm API. */ maxim_ds3231_alarm_callback_handler_t alarm_handler[2]; void *alarm_user_data[2]; uint8_t alarm_flags[2]; /* Flags recording requests for ISW monitoring. */ uint8_t isw_mon_req; #define ISW_MON_REQ_Alarm 0x01 #define ISW_MON_REQ_Sync 0x02 /* Status of synchronization operations. */ uint8_t sync_state; bool sync_signal; }; /* * Set and clear specific bits in the control register. * * This function assumes the device register cache is valid and will * update the device only if the value changes as a result of applying * the set and clear changes. * * Caches and returns the value with the changes applied. */ static int sc_ctrl(const struct device *dev, uint8_t set, uint8_t clear) { struct ds3231_data *data = dev->data; const struct ds3231_config *cfg = dev->config; struct register_map *rp = &data->registers; uint8_t ctrl = (rp->ctrl & ~clear) | set; int rc = ctrl; if (rp->ctrl != ctrl) { uint8_t buf[2] = { offsetof(struct register_map, ctrl), ctrl, }; rc = i2c_write(data->i2c, buf, sizeof(buf), cfg->addr); if (rc >= 0) { rp->ctrl = ctrl; rc = ctrl; } } return rc; } int maxim_ds3231_ctrl_update(const struct device *dev, uint8_t set_bits, uint8_t clear_bits) { struct ds3231_data *data = dev->data; k_sem_take(&data->lock, K_FOREVER); int rc = sc_ctrl(dev, set_bits, clear_bits); k_sem_give(&data->lock); return rc; } /* * Read the ctrl_stat register then set and clear bits in it. * * OSF, A1F, and A2F will be written with 1s if the corresponding bits * do not appear in either set or clear. This ensures that if any * flag becomes set between the read and the write that indicator will * not be cleared. * * Returns the value as originally read (disregarding the effect of * clears and sets). */ static inline int rsc_stat(const struct device *dev, uint8_t set, uint8_t clear) { uint8_t const ign = MAXIM_DS3231_REG_STAT_OSF | MAXIM_DS3231_ALARM1 | MAXIM_DS3231_ALARM2; struct ds3231_data *data = dev->data; const struct ds3231_config *cfg = dev->config; struct register_map *rp = &data->registers; uint8_t addr = offsetof(struct register_map, ctrl_stat); int rc; rc = i2c_write_read(data->i2c, cfg->addr, &addr, sizeof(addr), &rp->ctrl_stat, sizeof(rp->ctrl_stat)); if (rc >= 0) { uint8_t stat = rp->ctrl_stat & ~clear; if (rp->ctrl_stat != stat) { uint8_t buf[2] = { addr, stat | (ign & ~(set | clear)), }; rc = i2c_write(data->i2c, buf, sizeof(buf), cfg->addr); } if (rc >= 0) { rc = rp->ctrl_stat; } } return rc; } int maxim_ds3231_stat_update(const struct device *dev, uint8_t set_bits, uint8_t clear_bits) { struct ds3231_data *data = dev->data; k_sem_take(&data->lock, K_FOREVER); int rv = rsc_stat(dev, set_bits, clear_bits); k_sem_give(&data->lock); return rv; } /* * Look for current users of the interrupt/square-wave signal and * enable monitoring iff at least one consumer is active. */ static void validate_isw_monitoring(const struct device *dev) { struct ds3231_data *data = dev->data; const struct ds3231_config *cfg = dev->config; const struct register_map *rp = &data->registers; uint8_t isw_mon_req = 0; if (rp->ctrl & (MAXIM_DS3231_ALARM1 | MAXIM_DS3231_ALARM2)) { isw_mon_req |= ISW_MON_REQ_Alarm; } if (data->sync_state != SYNCSM_IDLE) { isw_mon_req |= ISW_MON_REQ_Sync; } LOG_DBG("ISW %p : %d ?= %d", data->isw, isw_mon_req, data->isw_mon_req); if ((data->isw != NULL) && (isw_mon_req != data->isw_mon_req)) { int rc = 0; /* Disable before reconfigure */ rc = gpio_pin_interrupt_configure(data->isw, cfg->isw_gpios.pin, GPIO_INT_DISABLE); if ((rc >= 0) && ((isw_mon_req & ISW_MON_REQ_Sync) != (data->isw_mon_req & ISW_MON_REQ_Sync))) { if (isw_mon_req & ISW_MON_REQ_Sync) { rc = sc_ctrl(dev, 0, MAXIM_DS3231_REG_CTRL_INTCN | MAXIM_DS3231_REG_CTRL_RS_Msk); } else { rc = sc_ctrl(dev, MAXIM_DS3231_REG_CTRL_INTCN, 0); } } data->isw_mon_req = isw_mon_req; /* Enable if any requests active */ if ((rc >= 0) && (isw_mon_req != 0)) { rc = gpio_pin_interrupt_configure(data->isw, cfg->isw_gpios.pin, GPIO_INT_EDGE_TO_ACTIVE); } LOG_INF("ISW reconfigure to %x: %d", isw_mon_req, rc); } } static const uint8_t *decode_time(struct tm *tp, const uint8_t *rp, bool with_sec) { uint8_t reg; if (with_sec) { uint8_t reg = *rp++; tp->tm_sec = bcd2bin(reg & 0x7F); } reg = *rp++; tp->tm_min = bcd2bin(reg & 0x7F); reg = *rp++; tp->tm_hour = (reg & 0x0F); if (REG_HOURS_12H & reg) { /* 12-hour */ if (REG_HOURS_10 & reg) { tp->tm_hour += 10; } if (REG_HOURS_PM & reg) { tp->tm_hour += 12; } } else { /* 24 hour */ tp->tm_hour += 10 * ((reg >> 4) & 0x03); } return rp; } static uint8_t decode_alarm(const uint8_t *ap, bool with_sec, time_t *tp) { struct tm tm = { /* tm_year zero is 1900 with underflows a 32-bit counter * representation. Use 1978-01, the first January after the * POSIX epoch where the first day of the month is the first * day of the week. */ .tm_year = 78, }; const uint8_t *dp = decode_time(&tm, ap, with_sec); uint8_t flags = 0; uint8_t amf = MAXIM_DS3231_ALARM_FLAGS_IGNDA; /* Done decoding time, now decode day/date. */ if (REG_DAYDATE_DOW & *dp) { flags |= MAXIM_DS3231_ALARM_FLAGS_DOW; /* Because tm.tm_wday does not contribute to the UNIX * time that the civil time translates into, we need * to also record the tm_mday for our selected base * 1978-01 that will produce the correct tm_wday. */ tm.tm_mday = (*dp & 0x07); tm.tm_wday = tm.tm_mday - 1; } else { tm.tm_mday = bcd2bin(*dp & 0x3F); } /* Walk backwards to extract the alarm mask flags. */ while (true) { if (REG_ALARM_IGN & *dp) { flags |= amf; } amf >>= 1; if (dp-- == ap) { break; } } /* Convert to the reduced representation. */ *tp = timeutil_timegm(&tm); return flags; } static int encode_alarm(uint8_t *ap, bool with_sec, time_t time, uint8_t flags) { struct tm tm; uint8_t val; (void)gmtime_r(&time, &tm); /* For predictable behavior the low 4 bits of flags * (corresponding to AxMy) must be 0b1111, 0b1110, 0b1100, * 0b1000, or 0b0000. This corresponds to the bitwise inverse * being one less than a power of two. */ if (!is_power_of_two(1U + (0x0F & ~flags))) { LOG_DBG("invalid alarm mask in flags: %02x", flags); return -EINVAL; } if (with_sec) { if (flags & MAXIM_DS3231_ALARM_FLAGS_IGNSE) { val = REG_ALARM_IGN; } else { val = bin2bcd(tm.tm_sec); } *ap++ = val; } if (flags & MAXIM_DS3231_ALARM_FLAGS_IGNMN) { val = REG_ALARM_IGN; } else { val = bin2bcd(tm.tm_min); } *ap++ = val; if (flags & MAXIM_DS3231_ALARM_FLAGS_IGNHR) { val = REG_ALARM_IGN; } else { val = bin2bcd(tm.tm_hour); } *ap++ = val; if (flags & MAXIM_DS3231_ALARM_FLAGS_IGNDA) { val = REG_ALARM_IGN; } else if (flags & MAXIM_DS3231_ALARM_FLAGS_DOW) { val = REG_DAYDATE_DOW | (tm.tm_wday + 1); } else { val = bin2bcd(tm.tm_mday); } *ap++ = val; return 0; } static uint32_t decode_rtc(struct ds3231_data *data) { struct tm tm = { 0 }; const struct register_map *rp = &data->registers; decode_time(&tm, &rp->sec, true); tm.tm_wday = (rp->dow & 0x07) - 1; tm.tm_mday = bcd2bin(rp->dom & 0x3F); tm.tm_mon = 10 * (((0xF0 & ~REG_MONCEN_CENTURY) & rp->moncen) >> 4) + (rp->moncen & 0x0F) - 1; tm.tm_year = bcd2bin(rp->year); if (REG_MONCEN_CENTURY & rp->moncen) { tm.tm_year += 100; } data->rtc_registers = timeutil_timegm(&tm); return data->rtc_registers; } static int update_registers(const struct device *dev) { struct ds3231_data *data = dev->data; const struct ds3231_config *cfg = dev->config; uint32_t syncclock; int rc; uint8_t addr = 0; data->syncclock_base = maxim_ds3231_read_syncclock(dev); rc = i2c_write_read(data->i2c, cfg->addr, &addr, sizeof(addr), &data->registers, sizeof(data->registers)); syncclock = maxim_ds3231_read_syncclock(dev); if (rc < 0) { return rc; } data->rtc_base = decode_rtc(data); return 0; } int maxim_ds3231_get_alarm(const struct device *dev, uint8_t id, struct maxim_ds3231_alarm *cp) { struct ds3231_data *data = dev->data; const struct ds3231_config *cfg = dev->config; int rv = 0; uint8_t addr; uint8_t len; if (id == 0) { addr = offsetof(struct register_map, alarm1); len = sizeof(data->registers.alarm1); } else if (id < cfg->generic.channels) { addr = offsetof(struct register_map, alarm2); len = sizeof(data->registers.alarm2); } else { rv = -EINVAL; goto out; } k_sem_take(&data->lock, K_FOREVER); /* Update alarm structure */ uint8_t *rbp = &data->registers.sec + addr; rv = i2c_write_read(data->i2c, cfg->addr, &addr, sizeof(addr), rbp, len); if (rv < 0) { LOG_DBG("get_config at %02x failed: %d\n", addr, rv); goto out_locked; } *cp = (struct maxim_ds3231_alarm){ 0 }; cp->flags = decode_alarm(rbp, (id == 0), &cp->time); cp->handler = data->alarm_handler[id]; cp->user_data = data->alarm_user_data[id]; out_locked: k_sem_give(&data->lock); out: return rv; } static int cancel_alarm(const struct device *dev, uint8_t id) { struct ds3231_data *data = dev->data; data->alarm_handler[id] = NULL; data->alarm_user_data[id] = NULL; return sc_ctrl(dev, 0, MAXIM_DS3231_ALARM1 << id); } static int ds3231_counter_cancel_alarm(const struct device *dev, uint8_t id) { struct ds3231_data *data = dev->data; const struct ds3231_config *cfg = dev->config; int rv = 0; if (id >= cfg->generic.channels) { rv = -EINVAL; goto out; } k_sem_take(&data->lock, K_FOREVER); rv = cancel_alarm(dev, id); k_sem_give(&data->lock); out: /* Throw away information counter API disallows */ if (rv >= 0) { rv = 0; } return rv; } static int set_alarm(const struct device *dev, uint8_t id, const struct maxim_ds3231_alarm *cp) { struct ds3231_data *data = dev->data; const struct ds3231_config *cfg = dev->config; uint8_t addr; uint8_t len; if (id == 0) { addr = offsetof(struct register_map, alarm1); len = sizeof(data->registers.alarm1); } else if (id < cfg->generic.channels) { addr = offsetof(struct register_map, alarm2); len = sizeof(data->registers.alarm2); } else { return -EINVAL; } uint8_t buf[5] = { addr }; int rc = encode_alarm(buf + 1, (id == 0), cp->time, cp->flags); if (rc < 0) { return rc; } /* @todo resolve race condition: a previously stored alarm may * trigger between clear of AxF and the write of the new alarm * control. */ rc = rsc_stat(dev, 0U, (MAXIM_DS3231_ALARM1 << id)); if (rc >= 0) { rc = i2c_write(data->i2c, buf, len + 1, cfg->addr); } if ((rc >= 0) && (cp->handler != NULL)) { rc = sc_ctrl(dev, MAXIM_DS3231_ALARM1 << id, 0); } if (rc >= 0) { memmove(&data->registers.sec + addr, buf + 1, len); data->alarm_handler[id] = cp->handler; data->alarm_user_data[id] = cp->user_data; data->alarm_flags[id] = cp->flags; validate_isw_monitoring(dev); } return rc; } int maxim_ds3231_set_alarm(const struct device *dev, uint8_t id, const struct maxim_ds3231_alarm *cp) { struct ds3231_data *data = dev->data; k_sem_take(&data->lock, K_FOREVER); int rc = set_alarm(dev, id, cp); k_sem_give(&data->lock); return rc; } int maxim_ds3231_check_alarms(const struct device *dev) { struct ds3231_data *data = dev->data; const struct register_map *rp = &data->registers; uint8_t mask = (MAXIM_DS3231_ALARM1 | MAXIM_DS3231_ALARM2); k_sem_take(&data->lock, K_FOREVER); /* Fetch and clear only the alarm flags that are not * interrupt-enabled. */ int rv = rsc_stat(dev, 0U, (rp->ctrl & mask) ^ mask); if (rv >= 0) { rv &= mask; } k_sem_give(&data->lock); return rv; } static int check_handled_alarms(const struct device *dev) { struct ds3231_data *data = dev->data; const struct register_map *rp = &data->registers; uint8_t mask = (MAXIM_DS3231_ALARM1 | MAXIM_DS3231_ALARM2); /* Fetch and clear only the alarm flags that are * interrupt-enabled. Leave any flags that are not enabled; * it may be an alarm that triggered a wakeup. */ mask &= rp->ctrl; int rv = rsc_stat(dev, 0U, mask); if (rv > 0) { rv &= mask; } return rv; } static void counter_alarm_forwarder(const struct device *dev, uint8_t id, uint32_t syncclock, void *ud) { /* Dummy handler marking a counter callback. */ } static void alarm_worker(struct k_work *work) { struct ds3231_data *data = CONTAINER_OF(work, struct ds3231_data, alarm_work); const struct device *ds3231 = data->ds3231; const struct ds3231_config *cfg = ds3231->config; k_sem_take(&data->lock, K_FOREVER); int af = check_handled_alarms(ds3231); while (af > 0) { uint8_t id; for (id = 0; id < cfg->generic.channels; ++id) { if ((af & (MAXIM_DS3231_ALARM1 << id)) == 0) { continue; } maxim_ds3231_alarm_callback_handler_t handler = data->alarm_handler[id]; void *ud = data->alarm_user_data[id]; if (data->alarm_flags[id] & MAXIM_DS3231_ALARM_FLAGS_AUTODISABLE) { int rc = cancel_alarm(ds3231, id); LOG_DBG("autodisable %d: %d", id, rc); validate_isw_monitoring(ds3231); } if (handler == counter_alarm_forwarder) { counter_alarm_callback_t cb = data->counter_handler[id]; uint32_t ticks = data->counter_ticks[id]; data->counter_handler[id] = NULL; data->counter_ticks[id] = 0; if (cb) { k_sem_give(&data->lock); cb(ds3231, id, ticks, ud); k_sem_take(&data->lock, K_FOREVER); } } else if (handler != NULL) { k_sem_give(&data->lock); handler(ds3231, id, data->isw_syncclock, ud); k_sem_take(&data->lock, K_FOREVER); } } af = check_handled_alarms(ds3231); } k_sem_give(&data->lock); if (af < 0) { LOG_ERR("failed to read alarm flags"); return; } LOG_DBG("ALARM %02x at %u latency %u", af, data->isw_syncclock, maxim_ds3231_read_syncclock(ds3231) - data->isw_syncclock); } static void sqw_worker(struct k_work *work) { struct ds3231_data *data = CONTAINER_OF(work, struct ds3231_data, sqw_work); uint32_t syncclock = maxim_ds3231_read_syncclock(data->ds3231); /* This is a placeholder for potential application-controlled * use of the square wave functionality. */ LOG_DBG("SQW %u latency %u", data->isw_syncclock, syncclock - data->isw_syncclock); } static int read_time(const struct device *dev, time_t *time) { struct ds3231_data *data = dev->data; const struct ds3231_config *cfg = dev->config; uint8_t addr = 0; int rc = i2c_write_read(data->i2c, cfg->addr, &addr, sizeof(addr), &data->registers, 7); if (rc >= 0) { *time = decode_rtc(data); } return rc; } static int ds3231_counter_get_value(const struct device *dev, uint32_t *ticks) { struct ds3231_data *data = dev->data; time_t time = 0; k_sem_take(&data->lock, K_FOREVER); int rc = read_time(dev, &time); k_sem_give(&data->lock); if (rc >= 0) { *ticks = time; } return rc; } static void sync_finish(const struct device *dev, int rc) { struct ds3231_data *data = dev->data; struct sys_notify *notify = NULL; struct k_poll_signal *signal = NULL; if (data->sync_signal) { signal = data->sync.signal; } else { notify = data->sync.notify; } data->sync.ptr = NULL; data->sync_signal = false; data->sync_state = SYNCSM_IDLE; (void)validate_isw_monitoring(dev); LOG_DBG("sync complete, notify %d to %p or %p\n", rc, notify, signal); k_sem_give(&data->lock); if (notify != NULL) { maxim_ds3231_notify_callback cb = (maxim_ds3231_notify_callback)sys_notify_finalize(notify, rc); if (cb) { cb(dev, notify, rc); } } else if (signal != NULL) { k_poll_signal_raise(signal, rc); } } static void sync_prep_read(const struct device *dev) { struct ds3231_data *data = dev->data; int rc = sc_ctrl(dev, 0U, MAXIM_DS3231_REG_CTRL_INTCN | MAXIM_DS3231_REG_CTRL_RS_Msk); if (rc < 0) { sync_finish(dev, rc); return; } data->sync_state = SYNCSM_FINISH_READ; validate_isw_monitoring(dev); } static void sync_finish_read(const struct device *dev) { struct ds3231_data *data = dev->data; time_t time = 0; (void)read_time(dev, &time); data->syncpoint.rtc.tv_sec = time; data->syncpoint.rtc.tv_nsec = 0; data->syncpoint.syncclock = data->isw_syncclock; sync_finish(dev, 0); } static void sync_timer_handler(struct k_timer *tmr) { struct ds3231_data *data = CONTAINER_OF(tmr, struct ds3231_data, sync_timer); LOG_INF("sync_timer fired"); k_work_submit(&data->sync_work); } static void sync_prep_write(const struct device *dev) { struct ds3231_data *data = dev->data; uint32_t syncclock = maxim_ds3231_read_syncclock(dev); uint32_t offset = syncclock - data->new_sp.syncclock; uint32_t syncclock_Hz = maxim_ds3231_syncclock_frequency(dev); uint32_t offset_s = offset / syncclock_Hz; uint32_t offset_ms = (offset % syncclock_Hz) * 1000U / syncclock_Hz; time_t when = data->new_sp.rtc.tv_sec; when += offset_s; offset_ms += data->new_sp.rtc.tv_nsec / NSEC_PER_USEC / USEC_PER_MSEC; if (offset_ms >= MSEC_PER_SEC) { offset_ms -= MSEC_PER_SEC; } else { when += 1; } uint32_t rem_ms = MSEC_PER_SEC - offset_ms; if (rem_ms < 5) { when += 1; rem_ms += MSEC_PER_SEC; } data->new_sp.rtc.tv_sec = when; data->new_sp.rtc.tv_nsec = 0; data->sync_state = SYNCSM_FINISH_WRITE; k_timer_start(&data->sync_timer, K_MSEC(rem_ms), K_NO_WAIT); LOG_INF("sync %u in %u ms after %u", (uint32_t)when, rem_ms, syncclock); } static void sync_finish_write(const struct device *dev) { struct ds3231_data *data = dev->data; const struct ds3231_config *cfg = dev->config; time_t when = data->new_sp.rtc.tv_sec; struct tm tm; uint8_t buf[8]; uint8_t *bp = buf; uint8_t val; *bp++ = offsetof(struct register_map, sec); (void)gmtime_r(&when, &tm); val = bin2bcd(tm.tm_sec); *bp++ = val; val = bin2bcd(tm.tm_min); *bp++ = val; val = bin2bcd(tm.tm_hour); *bp++ = val; *bp++ = 1 + tm.tm_wday; val = bin2bcd(tm.tm_mday); *bp++ = val; tm.tm_mon += 1; val = bin2bcd(tm.tm_mon); if (tm.tm_year >= 100) { tm.tm_year -= 100; val |= REG_MONCEN_CENTURY; } *bp++ = val; val = bin2bcd(tm.tm_year); *bp++ = val; uint32_t syncclock = maxim_ds3231_read_syncclock(dev); int rc = i2c_write(data->i2c, buf, bp - buf, cfg->addr); if (rc >= 0) { data->syncpoint.rtc.tv_sec = when; data->syncpoint.rtc.tv_nsec = 0; data->syncpoint.syncclock = syncclock; LOG_INF("sync %u at %u", (uint32_t)when, syncclock); } sync_finish(dev, rc); } static void sync_worker(struct k_work *work) { struct ds3231_data *data = CONTAINER_OF(work, struct ds3231_data, sync_work); uint32_t syncclock = maxim_ds3231_read_syncclock(data->ds3231); bool unlock = true; k_sem_take(&data->lock, K_FOREVER); LOG_DBG("SYNC.%u %u latency %u", data->sync_state, data->isw_syncclock, syncclock - data->isw_syncclock); switch (data->sync_state) { default: case SYNCSM_IDLE: break; case SYNCSM_PREP_READ: sync_prep_read(data->ds3231); break; case SYNCSM_FINISH_READ: sync_finish_read(data->ds3231); break; case SYNCSM_PREP_WRITE: sync_prep_write(data->ds3231); break; case SYNCSM_FINISH_WRITE: sync_finish_write(data->ds3231); unlock = false; break; } if (unlock) { k_sem_give(&data->lock); } } static void isw_gpio_callback(const struct device *port, struct gpio_callback *cb, uint32_t pins) { struct ds3231_data *data = CONTAINER_OF(cb, struct ds3231_data, isw_callback); data->isw_syncclock = maxim_ds3231_read_syncclock(data->ds3231); if (data->registers.ctrl & MAXIM_DS3231_REG_CTRL_INTCN) { k_work_submit(&data->alarm_work); } else if (data->sync_state != SYNCSM_IDLE) { k_work_submit(&data->sync_work); } else { k_work_submit(&data->sqw_work); } } int z_impl_maxim_ds3231_get_syncpoint(const struct device *dev, struct maxim_ds3231_syncpoint *syncpoint) { struct ds3231_data *data = dev->data; int rv = 0; k_sem_take(&data->lock, K_FOREVER); if (data->syncpoint.rtc.tv_sec == 0) { rv = -ENOENT; } else { __ASSERT_NO_MSG(syncpoint != NULL); *syncpoint = data->syncpoint; } k_sem_give(&data->lock); return rv; } int maxim_ds3231_synchronize(const struct device *dev, struct sys_notify *notify) { struct ds3231_data *data = dev->data; int rv = 0; if (notify == NULL) { rv = -EINVAL; goto out; } if (data->isw == NULL) { rv = -ENOTSUP; goto out; } k_sem_take(&data->lock, K_FOREVER); if (data->sync_state != SYNCSM_IDLE) { rv = -EBUSY; goto out_locked; } data->sync_signal = false; data->sync.notify = notify; data->sync_state = SYNCSM_PREP_READ; out_locked: k_sem_give(&data->lock); if (rv >= 0) { k_work_submit(&data->sync_work); } out: return rv; } int z_impl_maxim_ds3231_req_syncpoint(const struct device *dev, struct k_poll_signal *sig) { struct ds3231_data *data = dev->data; int rv = 0; if (data->isw == NULL) { rv = -ENOTSUP; goto out; } k_sem_take(&data->lock, K_FOREVER); if (data->sync_state != SYNCSM_IDLE) { rv = -EBUSY; goto out_locked; } data->sync_signal = true; data->sync.signal = sig; data->sync_state = SYNCSM_PREP_READ; out_locked: k_sem_give(&data->lock); if (rv >= 0) { k_work_submit(&data->sync_work); } out: return rv; } int maxim_ds3231_set(const struct device *dev, const struct maxim_ds3231_syncpoint *syncpoint, struct sys_notify *notify) { struct ds3231_data *data = dev->data; int rv = 0; if ((syncpoint == NULL) || (notify == NULL)) { rv = -EINVAL; goto out; } if (data->isw == NULL) { rv = -ENOTSUP; goto out; } k_sem_take(&data->lock, K_FOREVER); if (data->sync_state != SYNCSM_IDLE) { rv = -EBUSY; goto out_locked; } data->new_sp = *syncpoint; data->sync_signal = false; data->sync.notify = notify; data->sync_state = SYNCSM_PREP_WRITE; out_locked: k_sem_give(&data->lock); if (rv >= 0) { k_work_submit(&data->sync_work); } out: return rv; } static int ds3231_init(const struct device *dev) { struct ds3231_data *data = dev->data; const struct ds3231_config *cfg = dev->config; const struct device *i2c = device_get_binding(cfg->bus_name); int rc; /* Initialize and take the lock */ k_sem_init(&data->lock, 0, 1); data->ds3231 = dev; if (i2c == NULL) { LOG_WRN("Failed to get I2C %s", cfg->bus_name); rc = -EINVAL; goto out; } data->i2c = i2c; rc = update_registers(dev); if (rc < 0) { LOG_WRN("Failed to fetch registers: %d", rc); goto out; } /* INTCN and AxIE to power-up default, RS to 1 Hz */ rc = sc_ctrl(dev, MAXIM_DS3231_REG_CTRL_INTCN, MAXIM_DS3231_REG_CTRL_RS_Msk | MAXIM_DS3231_ALARM1 | MAXIM_DS3231_ALARM2); if (rc < 0) { LOG_WRN("Failed to reset config: %d", rc); goto out; } /* Do not clear pending flags in the status register. This * device may have been used for external wakeup, which can be * detected using the extended API. */ if (cfg->isw_gpios.ctrl != NULL) { const struct device *gpio = device_get_binding(cfg->isw_gpios.ctrl); if (gpio == NULL) { LOG_WRN("Failed to get INTn/SQW GPIO %s", cfg->isw_gpios.ctrl); rc = -EINVAL; goto out; } k_timer_init(&data->sync_timer, sync_timer_handler, NULL); k_work_init(&data->alarm_work, alarm_worker); k_work_init(&data->sqw_work, sqw_worker); k_work_init(&data->sync_work, sync_worker); gpio_init_callback(&data->isw_callback, isw_gpio_callback, BIT(cfg->isw_gpios.pin)); rc = gpio_pin_configure(gpio, cfg->isw_gpios.pin, GPIO_INPUT | cfg->isw_gpios.flags); if (rc >= 0) { rc = gpio_pin_interrupt_configure(gpio, cfg->isw_gpios.pin, GPIO_INT_DISABLE); } if (rc >= 0) { rc = gpio_add_callback(gpio, &data->isw_callback); } if (rc >= 0) { data->isw = gpio; } else { LOG_WRN("Failed to configure ISW callback: %d", rc); } } out: k_sem_give(&data->lock); LOG_DBG("Initialized %d", rc); if (rc > 0) { rc = 0; } return rc; } static int ds3231_counter_start(const struct device *dev) { return -EALREADY; } static int ds3231_counter_stop(const struct device *dev) { return -ENOTSUP; } int ds3231_counter_set_alarm(const struct device *dev, uint8_t id, const struct counter_alarm_cfg *alarm_cfg) { struct ds3231_data *data = dev->data; const struct register_map *rp = &data->registers; const struct ds3231_config *cfg = dev->config; time_t when; int rc = 0; if (id >= cfg->generic.channels) { rc = -ENOTSUP; goto out; } k_sem_take(&data->lock, K_FOREVER); if (rp->ctrl & (MAXIM_DS3231_ALARM1 << id)) { rc = -EBUSY; goto out_locked; } if ((alarm_cfg->flags & COUNTER_ALARM_CFG_ABSOLUTE) == 0) { rc = read_time(dev, &when); if (rc >= 0) { when += alarm_cfg->ticks; } } else { when = alarm_cfg->ticks; } struct maxim_ds3231_alarm alarm = { .time = (uint32_t)when, .handler = counter_alarm_forwarder, .user_data = alarm_cfg->user_data, .flags = MAXIM_DS3231_ALARM_FLAGS_AUTODISABLE, }; if (rc >= 0) { data->counter_handler[id] = alarm_cfg->callback; data->counter_ticks[id] = alarm.time; rc = set_alarm(dev, id, &alarm); } out_locked: k_sem_give(&data->lock); out: /* Throw away information counter API disallows */ if (rc >= 0) { rc = 0; } return rc; } static uint32_t ds3231_counter_get_top_value(const struct device *dev) { return UINT32_MAX; } static uint32_t ds3231_counter_get_pending_int(const struct device *dev) { return 0; } static int ds3231_counter_set_top_value(const struct device *dev, const struct counter_top_cfg *cfg) { return -ENOTSUP; } static const struct counter_driver_api ds3231_api = { .start = ds3231_counter_start, .stop = ds3231_counter_stop, .get_value = ds3231_counter_get_value, .set_alarm = ds3231_counter_set_alarm, .cancel_alarm = ds3231_counter_cancel_alarm, .set_top_value = ds3231_counter_set_top_value, .get_pending_int = ds3231_counter_get_pending_int, .get_top_value = ds3231_counter_get_top_value, }; static const struct ds3231_config ds3231_0_config = { .generic = { .max_top_value = UINT32_MAX, .freq = 1, .flags = COUNTER_CONFIG_INFO_COUNT_UP, .channels = 2, }, .bus_name = DT_INST_BUS_LABEL(0), /* Driver does not currently use 32k GPIO. */ #if DT_INST_NODE_HAS_PROP(0, isw_gpios) .isw_gpios = { DT_INST_GPIO_LABEL(0, isw_gpios), DT_INST_GPIO_PIN(0, isw_gpios), DT_INST_GPIO_FLAGS(0, isw_gpios), }, #endif .addr = DT_INST_REG_ADDR(0), }; static struct ds3231_data ds3231_0_data; #if CONFIG_COUNTER_MAXIM_DS3231_INIT_PRIORITY <= CONFIG_I2C_INIT_PRIORITY #error COUNTER_MAXIM_DS3231_INIT_PRIORITY must be greater than I2C_INIT_PRIORITY #endif DEVICE_DT_INST_DEFINE(0, ds3231_init, NULL, &ds3231_0_data, &ds3231_0_config, POST_KERNEL, CONFIG_COUNTER_MAXIM_DS3231_INIT_PRIORITY, &ds3231_api); #ifdef CONFIG_USERSPACE #include int z_vrfy_maxim_ds3231_get_syncpoint(const struct device *dev, struct maxim_ds3231_syncpoint *syncpoint) { struct maxim_ds3231_syncpoint value; int rv; Z_OOPS(Z_SYSCALL_SPECIFIC_DRIVER(dev, K_OBJ_DRIVER_COUNTER, &ds3231_api)); Z_OOPS(Z_SYSCALL_MEMORY_WRITE(syncpoint, sizeof(*syncpoint))); rv = z_impl_maxim_ds3231_get_syncpoint(dev, &value); if (rv >= 0) { Z_OOPS(z_user_to_copy(syncpoint, &value, sizeof(*syncpoint))); } return rv; } #include int z_vrfy_maxim_ds3231_req_syncpoint(const struct device *dev, struct k_poll_signal *sig) { Z_OOPS(Z_SYSCALL_SPECIFIC_DRIVER(dev, K_OBJ_DRIVER_COUNTER, &ds3231_api)); if (sig != NULL) { Z_OOPS(Z_SYSCALL_OBJ(sig, K_OBJ_POLL_SIGNAL)); } return z_impl_maxim_ds3231_req_syncpoint(dev, sig); } #include #endif /* CONFIG_USERSPACE */