static struct gpio_pin gpio_pins_mtcap_0_0[] = { { .name = "ETH_RESET", .pin = { .gpio = AT91_PIN_PC6, // NETH_RST .flags = GPIOF_OUT_INIT_HIGH, .label = "eth-reset", }, }, { .name = "RADIO_POWER_MONITOR", .pin = { .gpio = AT91_PIN_PD21, // PWRMON .flags = GPIOF_IN, .label = "radio-power-monitor", }, }, { .name = "RADIO_RESET", .pin = { .gpio = AT91_PIN_PA22, // 3G_RST .flags = GPIOF_OUT_INIT_HIGH, .label = "radio-reset", }, }, { .name = "RADIO_POWER", .pin = { .gpio = AT91_PIN_PA21, // 3G_ONOFF .flags = GPIOF_OUT_INIT_HIGH, .label = "radio-power", }, }, { .name = "DEVICE_RESET", .pin = { .gpio = AT91_PIN_PC4, // OPT_RST .flags = GPIOF_IN, .label = "reset", }, .active_low = 1, }, { .name = "LORA_RESET", .pin = { .gpio = AT91_PIN_PA8, // LORA_RST .flags = GPIOF_OUT_INIT_LOW, .label = "lora/reset", }, .capability = CAPA_LORA, .active_low = 1, }, { // gpio 1 for LORA 1.5 ref design .name = "LORA_CDONE", .pin = { .gpio = AT91_PIN_PA6, .flags = GPIOF_IN, .label = "lora/cdone", }, .capability = CAPA_LORA, }, { // gpio 2 for LORA 1.5 ref design .name = "LORA_CRESET", .pin = { .gpio = AT91_PIN_PA29, .flags = GPIOF_OUT_INIT_HIGH, .label = "lora/creset", }, .capability = CAPA_LORA, }, /* LEDs */ { .name = "STATUS_LED", // DEV_LED_GN .pin = { .gpio = AT91_PIN_PC25, .flags = GPIOF_OUT_INIT_LOW, .label = "led-status", }, .active_low = 1, }, { .name = "LED2", // LED2 is for LoRa status .pin = { .gpio = AT91_PIN_PC15, .flags = GPIOF_OUT_INIT_HIGH, .label = "led-lora", }, .active_low = 1, }, { .name = "LED3", // LED3 is for Cellular status (Modem can directly enable it) .pin = { .gpio = AT91_PIN_PC16, .flags = GPIOF_OUT_INIT_HIGH, .label = "led-cd", }, .active_low = 1, }, { .name = "LED4", // LED4 is for WiFi status .pin = { .gpio = AT91_PIN_PC20, .flags = GPIOF_OUT_INIT_HIGH, .label = "led-wifi", }, .active_low = 1, }, { }, }; static int radio_unconditional_shutdown_mtcap(void) { struct gpio_pin *rst_pin = gpio_pin_by_attr_name("radio-reset"); struct gpio_pin *pwrmon_pin = gpio_pin_by_attr_name("radio-power-monitor"); int value; int i; if (!rst_pin || !pwrmon_pin) { return -ENODEV; } // To unconditionally shutdown the LE910, the pad HW_SHUTDOWN* must // be tied low for at least 200 milliseconds and then released. reset_gpio_pin(rst_pin, 500, 0); msleep(100); // Wait for the power off for (i = 0; i < 5; i++) { value = gpio_get_value(pwrmon_pin->pin.gpio); if (value != 0) { log_warning("radio is still on."); msleep(500); continue; } log_warning("radio has been shutdown unconditionally"); break; } return 0; } /* radio control (power/reset) for mtcap */ static int radio_off_mtcap(void) { // ref: Telit_LE910_Hardware_User_Guide_r6.pdf (4.3.2 Hardware Shutdown) struct gpio_pin *pwrmon_pin = gpio_pin_by_attr_name("radio-power-monitor"); struct gpio_pin *onoff_pin = gpio_pin_by_attr_name("radio-power"); struct gpio_pin *rst_pin = gpio_pin_by_attr_name("radio-reset"); int value; int i; if (!onoff_pin || !pwrmon_pin || !rst_pin) { return -ENODEV; } value = gpio_get_value(pwrmon_pin->pin.gpio); if(value == 0) { log_warning("cell radio is already off"); return 0; } log_info("turning off cell radio"); // To turn OFF LE910 the pad ON/OFF# must be tied low for at least 2 seconds and then // released. Same circuitry and timing for the power on must be used. When the hold // time of ON/OFF# is above 2 seconds, LE910 goes into the finalization state and // finally will shut down PWRMON at the end of this state. The period of the // finalization state can differ according to the situation in which the LE910 is so it // cannot be fixed definitely. Normally it will be above 15 seconds later from releasing // ON/OFF# and DTE should monitor the status of PWRMON to see the actual power off. reset_gpio_pin(onoff_pin, 2500, 0); value = 0; for (i = 0; i < 15; i++) { // check that power is low value = gpio_get_value(pwrmon_pin->pin.gpio); if (value != 0) { log_info("cell radio is still on. keep waiting..."); msleep(2000); continue; } break; } if (value == 0) { log_info("cell radio has been shut down"); } else { log_warning("cell radio is still on. performing unconditional shutdown..."); radio_unconditional_shutdown_mtcap(); } return 0; } static int radio_on_mtcap(void) { // ref: Telit_LE910_Hardware_User_Guide_r6.pdf struct gpio_pin *pwrmon_pin = gpio_pin_by_attr_name("radio-power-monitor"); struct gpio_pin *onoff_pin = gpio_pin_by_attr_name("radio-power"); struct gpio_pin *rst_pin = gpio_pin_by_attr_name("radio-reset"); int value; if (!onoff_pin || !pwrmon_pin || !rst_pin) { return -ENODEV; } value = gpio_get_value(pwrmon_pin->pin.gpio); if(value != 0) { log_warning("cell radio is already on"); return 0; } log_info("turning on cell radio"); // drive on/off pin high for at least 1 seconoff_pin gpio_set_value(onoff_pin->pin.gpio, 1); msleep(1000); // 1) drive on/off pin low for < 2 sec // 2) drive on/off pin high reset_gpio_pin(onoff_pin, 1500, 0); // check that power is high value = gpio_get_value(pwrmon_pin->pin.gpio); if(value == 0) { log_warning("cell radio is still off."); } else { log_info("cell radio has been turned on"); } return 0; } static int radio_reset_mtcap(void) { // ref: Telit_LE910_Hardware_User_Guide_r6.pdf struct gpio_pin *rst_pin = gpio_pin_by_attr_name("radio-reset"); struct gpio_pin *onoff_pin = gpio_pin_by_attr_name("radio-power"); if (!rst_pin || !onoff_pin) { return -ENODEV; } // // Unconditional shutdown // log_info("performing unconditional cell radio shutdown"); radio_unconditional_shutdown_mtcap(); // // Turning on radio // log_info("turning on cell radio"); // drive on/off pin high for at least 1 sec gpio_set_value(onoff_pin->pin.gpio, 1); msleep(1000); // drive on/off pin low for < 2 sec // drive on/off pin high reset_gpio_pin(onoff_pin, 1500, 0); return 0; } static ssize_t mts_attr_store_radio_power_mtcap(struct device *dev, struct device_attribute *attr, const char *buf, size_t count) { int value; int err; if (sscanf(buf, "%i", &value) != 1) { return -EINVAL; } mutex_lock(&mts_io_mutex); if (value == 0) { err = radio_off_mtcap(); } else { err = radio_on_mtcap(); } mutex_unlock(&mts_io_mutex); if (err) { return err; } return count; } static ssize_t mts_attr_store_radio_reset_mtcap(struct device *dev, struct device_attribute *attr, const char *buf, size_t count) { int value; int err; if (sscanf(buf, "%i", &value) != 1) { return -EINVAL; } if (value != 0) { return -EINVAL; } /* check reset timings is enabled */ if (NULL != timings_data) { /* check reset timer is started */ if (radio_reset_timer_is_start == 1) { log_info("cell radio reset timer is running. \n"); return count; } /* check reset timer available is started */ if (radio_reset_available_timer_is_start == 1) { del_timer(&radio_reset_available_timer); radio_reset_available_timer_is_start = 0; } /* reset timer not started, start it */ mod_timer(&radio_reset_timer, jiffies + msecs_to_jiffies((timings_data[timings_data_index]) * 1000)); //log_info("radio reset timer is start = [%d]\n", time_now_secs()); /* save timings_data_stop_seconds */ timings_data_stop_seconds = timings_data[timings_data_index] + time_now_secs(); radio_reset_timer_is_start = 1; } mutex_lock(&mts_io_mutex); err = radio_reset_mtcap(); mutex_unlock(&mts_io_mutex); if (err) { return err; } return count; } static ssize_t mts_attr_show_radio_power_mtcap(struct device *dev, struct device_attribute *attr, char *buf) { int value; struct gpio_pin *pwrmon_pin = gpio_pin_by_attr_name("radio-power-monitor"); if ( !pwrmon_pin ) { return -ENODEV; } value = gpio_get_value(pwrmon_pin->pin.gpio); return sprintf(buf, "%d\n", value); } static DEVICE_ATTR_MTS(dev_attr_radio_reset_mtcap, "radio-reset", mts_attr_show_gpio_pin, mts_attr_store_radio_reset_mtcap); static DEVICE_ATTR_MTS(dev_attr_radio_power_mtcap, "radio-power", mts_attr_show_radio_power_mtcap, mts_attr_store_radio_power_mtcap); static DEVICE_ATTR_MTS(dev_attr_eth_reset_mtcap, "eth-reset", mts_attr_show_gpio_pin, mts_attr_store_gpio_pin); static DEVICE_ATTR_MTS(dev_attr_led_lora_gpio_mtcap, "led-lora", mts_attr_show_gpio_pin, mts_attr_store_gpio_pin); static DEVICE_ATTR_MTS(dev_attr_led_wifi_gpio_mtcap, "led-wifi", mts_attr_show_gpio_pin, mts_attr_store_gpio_pin); static struct attribute *mtcap_0_0_platform_attributes[] = { &dev_attr_vendor_id.attr, &dev_attr_product_id.attr, &dev_attr_device_id.attr, &dev_attr_uuid.attr, &dev_attr_hw_version.attr, &dev_attr_imei.attr, &dev_attr_eth_mac.attr, &dev_attr_reset.attr, &dev_attr_reset_monitor.attr, &dev_attr_reset_monitor_intervals.attr, &dev_attr_eth_reset_mtcap.attr, &dev_attr_radio_power_mtcap.attr, &dev_attr_radio_reset_mtcap.attr, &dev_attr_radio_reset_backoffs.attr, &dev_attr_radio_reset_backoff_index.attr, &dev_attr_radio_reset_backoff_seconds.attr, &dev_attr_led_status.attr, &dev_attr_led_cd_gpio.attr, &dev_attr_led_lora_gpio_mtcap.attr, &dev_attr_led_wifi_gpio_mtcap.attr, NULL, }; static struct attribute_group mtcap_0_0_platform_attribute_group = { .attrs = mtcap_0_0_platform_attributes }; // // on-board LORA attributes are to be stored in the lora/ sub-directory // // static DEVICE_ATTR_MTS(dev_attr_lora_reset_mtcap, "reset", mts_attr_show_lora_gpio_pin, mts_attr_store_lora_gpio_pin); static DEVICE_ATTR_RO_MTS(dev_attr_lora_cdone_mtcap, "cdone", mts_attr_show_lora_gpio_pin); static DEVICE_ATTR_MTS(dev_attr_lora_creset_mtcap, "creset", mts_attr_show_lora_gpio_pin, mts_attr_store_lora_gpio_pin); static DEVICE_ATTR_RO_MTS(dev_attr_lora_eui_mtcap, "eui", mts_attr_show_lora_product_info); static DEVICE_ATTR_RO_MTS(dev_attr_lora_product_id_mtcap, "product-id", mts_attr_show_lora_product_info); static DEVICE_ATTR_RO_MTS(dev_attr_lora_hw_version_mtcap, "hw-version", mts_attr_show_lora_product_info); static struct attribute *mtcap_0_0_lora_attributes[] = { &dev_attr_lora_eui_mtcap.attr, &dev_attr_lora_product_id_mtcap.attr, &dev_attr_lora_hw_version_mtcap.attr, &dev_attr_lora_reset_mtcap.attr, &dev_attr_lora_cdone_mtcap.attr, &dev_attr_lora_creset_mtcap.attr, NULL, }; static struct attribute_group mtcap_0_0_lora_attribute_group = { .attrs = mtcap_0_0_lora_attributes };