added Exposure code, DS3231, SSD1306, interfaces, started with protocol buffers impl.

2024-11-24 19:06:10 +01:00 · 2020-07-22 21:44:17 +02:00 · 2020-07-22 21:44:17 +02:00 · 4ba1352a05
commit 4ba1352a05
parent 04f7e8e1d6
38 changed files with 5800 additions and 178 deletions
--- a/README.md
+++ b/README.md
@ -1,28 +1,29 @@
 *worked on this a few days offtime, now here is the first working source*
 # esp-ena
-Implementation of the Covid-19 Exposure Notification API by Apple and Google on an ESP32 (with ESP-IDF). 
+Implementation of contact tracing with the Covid-19 Exposure Notification API by Apple and Google on an ESP32 (with [ESP-IDF](https://docs.espressif.com/projects/esp-idf/en/latest/esp32/index.html)). 
 More information about the Covid-19 Exposure Notification at [Apple](https://www.apple.com/covid19/contacttracing/) and [Google](https://www.google.com/covid19/exposurenotifications/). This is meant for people without smartphone or without smartphones with Apples/Googles implementation.
 [Demo Video](https://twitter.com/Lurkars/status/1282223547579019264)
-This implementation covers for now the BLE part including the cryptography specifications needed (see Bluetooth Specifications and Cryptography Specifications documents in the links above):
+This implementation fully covers for the BLE part including the cryptography specifications needed (see Bluetooth Specifications and Cryptography Specifications documents in the links above):
 * send beacons
 * store TEKs on flash (last 14)
 * receive beacons
 * received beacons are stored after 5 minutes threshold (storage is limited, ~100k beacons can be stored)
-Features missing for now are:
+Additional features for full ENA device
-* compare received beacons with infected list
+* calculating risks scores (after adding reported keys and storing exposure information)
-* calculating risks scores
+* RTC support with DS3231
-
+* display support with SSD1306
 Extensions planned:
 * add RTC (will test DS3231)
 * add display (added SSD1306)
 * interface to
    * set time
-    * delete beacons
+
 Features missing for now are:
 * retrieve infected list and parse from binary (started with binary parsing)
 Extensions planned:
 * interface to
    * delete data
    * show status
    * report infection?
 * receive infected beacons list (will test [Corona Warn App](https://github.com/corona-warn-app))
@ -44,9 +45,7 @@ The following acronyms will be used in code and comments:
 * *AEM* Associated Encrypted Metadata - send and received metadata
 Open questions
 * now save ENIN for stored beacons (documentation says timestamp), but for infection status ENIN should be enough!?
 * service UUID is send reversed, must RPI and AEM also beeing send in reverse? Don't know BLE specification enough
 * fixed change of advertise payload every 10 minutes, random value between ~15 minutes better?
 ## How to use
--- a/components/ds3231/CMakeLists.txt
+++ b/components/ds3231/CMakeLists.txt
@ -0,0 +1,7 @@
 idf_component_register(
    SRCS 
        "ds3231.c"
    INCLUDE_DIRS "include"
    PRIV_REQUIRES 
        i2c-main
 )
--- a/components/ds3231/ds3231.c
+++ b/components/ds3231/ds3231.c
@ -0,0 +1,119 @@
 // Copyright 2020 Lukas Haubaum
 //
 // Licensed under the GNU Affero General Public License, Version 3;
 // you may not use this file except in compliance with the License.
 // You may obtain a copy of the License at
 //     https://www.gnu.org/licenses/agpl-3.0.html
 //
 // Unless required by applicable law or agreed to in writing, software
 // distributed under the License is distributed on an "AS IS" BASIS,
 // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 // See the License for the specific language governing permissions and
 // limitations under the License.
 #include <stdio.h>
 #include <time.h>
 #include "driver/i2c.h"
 #include "esp_log.h"
 #include "i2c-main.h"
 #include "ds3231.h"
 uint8_t ds3231_dec2bcd(uint8_t value)
 {
    return ((value / 10 * 16) + (value % 10));
 }
 uint8_t ds3231_bcd2dec(uint8_t value)
 {
    return ((value / 16 * 10) + (value % 16));
 }
 void ds3231_get_time(struct tm *time)
 {
    if (!i2c_is_initialized())
    {
        i2c_main_init();
    }
    uint8_t data[7];
    i2c_cmd_handle_t cmd;
    cmd = i2c_cmd_link_create();
    i2c_master_start(cmd);
    i2c_master_write_byte(cmd, (DS3231_ADDRESS << 1) | I2C_MASTER_WRITE, true);
    i2c_master_write_byte(cmd, DS3231_TIME, true);
    i2c_master_start(cmd);
    i2c_master_write_byte(cmd, (DS3231_ADDRESS << 1) | I2C_MASTER_READ, true);
    i2c_master_read(cmd, data, 7, I2C_MASTER_LAST_NACK);
    i2c_master_stop(cmd);
    ESP_ERROR_CHECK_WITHOUT_ABORT(i2c_master_cmd_begin(I2C_NUM_0, cmd, 10 / portTICK_PERIOD_MS));
    i2c_cmd_link_delete(cmd);
    time->tm_sec = ds3231_bcd2dec(data[0]);
    time->tm_min = ds3231_bcd2dec(data[1]);
    if (data[2] & DS3231_12_HOUR_FLAG)
    {
        time->tm_hour = ds3231_bcd2dec(data[2] & DS3231_12_HOUR_MASK) - 1;
        if (data[2] & DS3231_PM_HOUR_FLAG)
        {
            time->tm_hour += 12;
        }
    }
    else
    {
        time->tm_hour = ds3231_bcd2dec(data[2]);
    }
    time->tm_wday = ds3231_bcd2dec(data[3]) - 1;
    time->tm_mday = ds3231_bcd2dec(data[4]);
    time->tm_mon = ds3231_bcd2dec(data[5] & DS3231_MONTH_MASK) - 1;
    uint8_t century = (data[5] & DS3231_CENTURY_FLAG) >> 7;
    if (century)
    {
        time->tm_year = ds3231_bcd2dec(data[6]) + 100;
    }
    else
    {
        time->tm_year = ds3231_bcd2dec(data[6]);
    }
    time->tm_isdst = 0;
 }
 void ds3231_set_time(struct tm *time)
 {
    if (!i2c_is_initialized())
    {
        i2c_main_init();
    }
    uint8_t data[7] = {0};
    data[0] = ds3231_dec2bcd(time->tm_sec);
    data[1] = ds3231_dec2bcd(time->tm_min);
    data[2] = ds3231_dec2bcd(time->tm_hour); // write 24h format
    data[3] = ds3231_dec2bcd(time->tm_wday + 1);
    data[4] = ds3231_dec2bcd(time->tm_mday);
    uint8_t century = 0;
    if (time->tm_year > 100)
    {
        century = DS3231_CENTURY_FLAG;
        data[6] = ds3231_dec2bcd(time->tm_year - 100);
    }
    else
    {
        data[6] = ds3231_dec2bcd(time->tm_year);
    }
    data[5] = ds3231_dec2bcd(time->tm_mon + 1) + century;
    i2c_cmd_handle_t cmd;
    cmd = i2c_cmd_link_create();
    i2c_master_start(cmd);
    i2c_master_write_byte(cmd, (DS3231_ADDRESS << 1) | I2C_MASTER_WRITE, true);
    i2c_master_write_byte(cmd, DS3231_TIME, true);
    i2c_master_write(cmd, data, 7, true);
    i2c_master_stop(cmd);
    ESP_ERROR_CHECK_WITHOUT_ABORT(i2c_master_cmd_begin(I2C_NUM_0, cmd, 10 / portTICK_PERIOD_MS));
    i2c_cmd_link_delete(cmd);
 }
--- a/components/ds3231/include/ds3231.h
+++ b/components/ds3231/include/ds3231.h
@ -0,0 +1,78 @@
 // Copyright 2020 Lukas Haubaum
 //
 // Licensed under the GNU Affero General Public License, Version 3;
 // you may not use this file except in compliance with the License.
 // You may obtain a copy of the License at
 //     https://www.gnu.org/licenses/agpl-3.0.html
 //
 // Unless required by applicable law or agreed to in writing, software
 // distributed under the License is distributed on an "AS IS" BASIS,
 // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 // See the License for the specific language governing permissions and
 // limitations under the License.
 #ifndef _ds3231_H_
 #define _ds3231_H_
 #include <time.h>
 // I2C address
 #define DS3231_ADDRESS 0x68
 // I2C registers
 #define DS3231_TIME 0x00
 #define DS3231_SECONDS 0x00
 #define DS3231_MINUTES 0x01
 #define DS3231_HOURS 0x02
 #define DS3231_DAY 0x03
 #define DS3231_DATE 0x04
 #define DS3231_MONTH 0x05
 #define DS3231_YEAR 0x06
 #define DS3231_ALARM1_SECONDS 0x07
 #define DS3231_ALARM1_MINUTES 0x08
 #define DS3231_ALARM1_HOURS 0x09
 #define DS3231_ALARM1_DATE 0x0A
 #define DS3231_ALARM2_MINUTES 0x0B
 #define DS3231_ALARM2_HOURS 0x0C
 #define DS3231_ALARM2_DATE 0x0D
 #define DS3231_CONTROL 0x0E
 #define DS3231_STATUS 0x0F
 #define DS3231_AGING_OFFSET 0x10
 #define DS3231_MSB_TEMP 0x11
 #define DS3231_LSB_TEMP 0x12
 // control registers
 #define DS3231_CONTROL_A1IE 0x01
 #define DS3231_CONTROL_A2IE 0x02
 #define DS3231_CONTROL_INTCN 0x04
 #define DS3231_CONTROL_RS1 0x08
 #define DS3231_CONTROL_RS2 0x10
 #define DS3231_CONTROL_CONV 0x20
 #define DS3231_CONTROL_BBSQW 0x40
 #define DS3231_CONTROL_EOSC 0x80
 // status registers
 #define DS3231_STATUSL_A1F 0x01
 #define DS3231_STATUSL_A2F 0x02
 #define DS3231_STATUSL_BSY 0x04
 #define DS3231_STATUSL_EN32KHZ 0x08
 #define DS3231_STATUSL_OSF 0x80
 // flags
 #define DS3231_CENTURY_FLAG 0x80
 #define DS3231_12_HOUR_FLAG 0x40
 #define DS3231_PM_HOUR_FLAG 0x20
 #define DS3231_12_HOUR_MASK 0x1F
 #define DS3231_MONTH_MASK 0x1F
 /**
 * @brief Read time from DS3231
 */
 void ds3231_get_time(struct tm *time);
 /**
 * @brief Write time to DS3231
 */
 void ds3231_set_time(struct tm *time);
 #endif
--- a/components/ena-interface/CMakeLists.txt
+++ b/components/ena-interface/CMakeLists.txt
@ -3,6 +3,7 @@ idf_component_register(
        "ena-interface.c"
        "ena-interface-datetime.c"
        "ena-interface-menu.c"
        "ena-interface-status.c"
    INCLUDE_DIRS "include"
    PRIV_REQUIRES 
        ena
--- a/components/ena-interface/ena-interface-datetime.c
+++ b/components/ena-interface/ena-interface-datetime.c
@ -12,6 +12,8 @@
 // See the License for the specific language governing permissions and
 // limitations under the License.
 #include <stdio.h>
 #include <time.h>
 #include <sys/time.h>
 #include "esp_log.h"
 #include "ena-interface.h"
@ -22,15 +24,51 @@
 static int interface_datetime_state = ENA_INTERFACE_DATETIME_STATE_YEAR;
 const uint32_t interface_datetime_steps[6] = {
    31557600, 2629800, 86400, 3600, 60, 1};
 void ena_interface_datetime_esc(void)
 {
    ena_interface_menu_start();
 }
 void ena_interface_datetime_ok(void)
 {
    interface_datetime_state++;
    if (interface_datetime_state > ENA_INTERFACE_DATETIME_STATE_SECONDS)
    {
        interface_datetime_state = ENA_INTERFACE_DATETIME_STATE_YEAR;
    }
    ESP_LOGD(ENA_INTERFACE_LOG, "datetime to %d", interface_datetime_state);
 }
 void ena_interface_datetime_up(void)
 {
    time_t curtime = time(NULL);
    curtime += interface_datetime_steps[interface_datetime_state];
    struct timeval tv = {0};
    tv.tv_sec = curtime;
    settimeofday(&tv, NULL);
    ESP_LOGD(ENA_INTERFACE_LOG, "increment %d about %u %s", interface_datetime_state, interface_datetime_steps[interface_datetime_state], ctime(&curtime));
 }
 void ena_interface_datetime_down(void)
 {
    time_t curtime = time(NULL);
    curtime -= interface_datetime_steps[interface_datetime_state];
    struct timeval tv = {0};
    tv.tv_sec = curtime;
    settimeofday(&tv, NULL);
    ESP_LOGD(ENA_INTERFACE_LOG, "decrement %d about %u %s", interface_datetime_state, interface_datetime_steps[interface_datetime_state], ctime(&curtime));
 }
 void ena_interface_datetime_start(void)
 {
-    ena_interface_set_state(ENA_INTERFACE_STATE_SET_YEAR);
+    ena_interface_set_state(ENA_INTERFACE_STATE_SET_DATETIME);
    ena_interface_register_touch_callback(TOUCH_PAD_ESC, &ena_interface_datetime_esc);
    ena_interface_register_touch_callback(TOUCH_PAD_OK, &ena_interface_datetime_ok);
    ena_interface_register_touch_callback(TOUCH_PAD_UP, &ena_interface_datetime_up);
    ena_interface_register_touch_callback(TOUCH_PAD_DOWN, &ena_interface_datetime_down);
    ESP_LOGD(ENA_INTERFACE_LOG, "start datetime interface");
 }
--- a/components/ena-interface/ena-interface-menu.c
+++ b/components/ena-interface/ena-interface-menu.c
@ -17,6 +17,7 @@
 #include "driver/touch_pad.h"
 #include "ena-interface.h"
 #include "ena-interface-datetime.h"
 #include "ena-interface-status.h"
 #include "ena-interface-menu.h"
@ -24,17 +25,35 @@ static int interface_menu_state = ENA_INTERFACE_MENU_STATE_IDLE;
 void ena_interface_menu_ok(void)
 {
-    if (interface_menu_state == ENA_INTERFACE_MENU_STATE_SELECT_TIME) {
+    if (interface_menu_state == ENA_INTERFACE_MENU_STATE_SELECT_TIME)
    {
        ena_interface_datetime_start();
    }
    else if (interface_menu_state == ENA_INTERFACE_MENU_STATE_SELECT_STATUS)
    {
        ena_interface_status_start();
    }
    else if (interface_menu_state == ENA_INTERFACE_MENU_STATE_IDLE)
    {
        if (ena_interface_get_state() == ENA_INTERFACE_STATE_MENU)
        {
            ena_interface_set_state(ENA_INTERFACE_STATE_IDLE);
            ena_interface_register_touch_callback(TOUCH_PAD_UP, NULL);
            ena_interface_register_touch_callback(TOUCH_PAD_DOWN, NULL);
        }
        else
        {
            ena_interface_menu_start();
        }
    }
 }
 void ena_interface_menu_up(void)
 {
    interface_menu_state--;
-    if (interface_menu_state < 0)
+    if (interface_menu_state < ENA_INTERFACE_MENU_STATE_IDLE)
    {
-        interface_menu_state = sizeof(interface_menu_state) - 1;
+        interface_menu_state = ENA_INTERFACE_MENU_STATE_SELECT_STATUS;
    }
    ESP_LOGD(ENA_INTERFACE_LOG, "menu up to %d", interface_menu_state);
 }
@ -42,9 +61,9 @@ void ena_interface_menu_up(void)
 void ena_interface_menu_down(void)
 {
    interface_menu_state++;
-    if (interface_menu_state == sizeof(interface_menu_state))
+    if (interface_menu_state > ENA_INTERFACE_MENU_STATE_SELECT_STATUS)
    {
-        interface_menu_state = 0;
+        interface_menu_state = ENA_INTERFACE_MENU_STATE_IDLE;
    }
    ESP_LOGD(ENA_INTERFACE_LOG, "menu down to %d", interface_menu_state);
 }
--- a/components/ena-interface/ena-interface-status.c
+++ b/components/ena-interface/ena-interface-status.c
@ -0,0 +1,37 @@
 // Copyright 2020 Lukas Haubaum
 //
 // Licensed under the GNU Affero General Public License, Version 3;
 // you may not use this file except in compliance with the License.
 // You may obtain a copy of the License at
 //     https://www.gnu.org/licenses/agpl-3.0.html
 //
 // Unless required by applicable law or agreed to in writing, software
 // distributed under the License is distributed on an "AS IS" BASIS,
 // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 // See the License for the specific language governing permissions and
 // limitations under the License.
 #include <stdio.h>
 #include "esp_log.h"
 #include "driver/touch_pad.h"
 #include "ena-interface.h"
 #include "ena-interface-menu.h"
 #include "ena-interface-status.h"
 void ena_interface_status_esc(void)
 {
    ena_interface_menu_start();
 }
 void ena_interface_status_start(void)
 {
    ena_interface_set_state(ENA_INTERFACE_STATE_STATUS);
    ena_interface_register_touch_callback(TOUCH_PAD_ESC, &ena_interface_status_esc);
    ena_interface_register_touch_callback(TOUCH_PAD_OK, NULL);
    ena_interface_register_touch_callback(TOUCH_PAD_UP, NULL);
    ena_interface_register_touch_callback(TOUCH_PAD_DOWN, NULL);
    ESP_LOGD(ENA_INTERFACE_LOG, "start status interface");
 }
--- a/components/ena-interface/ena-interface.c
+++ b/components/ena-interface/ena-interface.c
@ -33,24 +33,23 @@ void ena_interface_register_touch_callback(int touch_pad, ena_interface_touch_ca
 void ena_interface_run(void *pvParameter)
 {
-    uint16_t touch_value;
+    static uint16_t touch_value;
-    uint16_t touch_thresh;
+    static uint16_t touch_thresh;
-    bool touch_status_current[4] = {0};
+    static bool touch_status_current[TOUCH_PAD_MAX] = {0};
    while (1)
    {
        for (int i = 0; i < TOUCH_PAD_COUNT; i++)
        {
-            int touch_id = touch_mapping[i];
+            ESP_ERROR_CHECK_WITHOUT_ABORT(touch_pad_read_filtered(touch_mapping[i], &touch_value));
-            ESP_ERROR_CHECK_WITHOUT_ABORT(touch_pad_read_filtered(touch_id, &touch_value));
+            ESP_ERROR_CHECK_WITHOUT_ABORT(touch_pad_get_thresh(touch_mapping[i], &touch_thresh));
            ESP_ERROR_CHECK_WITHOUT_ABORT(touch_pad_get_thresh(touch_id, &touch_thresh));
            touch_status_current[i] = touch_value < touch_thresh;
            if (!touch_status[i] & touch_status_current[i])
            {
-                ESP_LOGD(ENA_INTERFACE_LOG, "touch %u at %d (thresh %u)", touch_value, touch_id, touch_thresh);
+                ESP_LOGD(ENA_INTERFACE_LOG, "touch %u at %d (thresh %u)", touch_value, touch_mapping[i], touch_thresh);
-                if (touch_callbacks[touch_id] != NULL)
+                if (touch_callbacks[touch_mapping[i]] != NULL)
                {
-                    (*touch_callbacks[touch_id])();
+                    (*touch_callbacks[touch_mapping[i]])();
                }
            }
            touch_status[i] = touch_status_current[i];
@ -73,22 +72,19 @@ void ena_interface_start(void)
    for (int i = 0; i < TOUCH_PAD_COUNT; i++)
    {
-        int touch_id = touch_mapping[i];
+        ESP_ERROR_CHECK(touch_pad_config(touch_mapping[i], 0));
        ESP_ERROR_CHECK(touch_pad_config(touch_id, 0));
    }
    ESP_ERROR_CHECK(touch_pad_filter_start(TOUCHPAD_FILTER_TOUCH_PERIOD));
    uint16_t touch_value;
    for (int i = 0; i < TOUCH_PAD_COUNT; i++)
    {
-        int touch_id = touch_mapping[i];
+        ESP_ERROR_CHECK(touch_pad_read_filtered(touch_mapping[i], &touch_value));
-        ESP_ERROR_CHECK(touch_pad_read_filtered(touch_id, &touch_value));
+        ESP_ERROR_CHECK(touch_pad_set_thresh(touch_mapping[i], touch_value * 2 / 3));
-        ESP_ERROR_CHECK(touch_pad_set_thresh(touch_id, touch_value * 2 / 3));
+        ESP_LOGD(ENA_INTERFACE_LOG, "calibrate %u at %u (thresh %u)", touch_mapping[i], touch_value, (touch_value * 2 / 3));
        ESP_LOGD(ENA_INTERFACE_LOG, "calibrate %u at %u (thresh %u)", touch_id, touch_value, (touch_value * 2 / 3));
    }
-    xTaskCreate(&ena_interface_run, "ena_interface_run", configMINIMAL_STACK_SIZE * 4, NULL, 5, NULL);
+    xTaskCreate(&ena_interface_run, "ena_interface_run", 4096, NULL, 5, NULL);
 }
 int ena_interface_get_state(void)
--- a/components/ena-interface/include/ena-interface-menu.h
+++ b/components/ena-interface/include/ena-interface-menu.h
@ -18,7 +18,7 @@ typedef enum
 {
    ENA_INTERFACE_MENU_STATE_IDLE = 0,
    ENA_INTERFACE_MENU_STATE_SELECT_TIME,
-    ENA_INTERFACE_MENU_STATE_SELECT_INFO,
+    ENA_INTERFACE_MENU_STATE_SELECT_STATUS,
 } ena_interface_menu_state;
 void ena_interface_menu_start(void);
--- a/components/ena-interface/include/ena-interface-status.h
+++ b/components/ena-interface/include/ena-interface-status.h
@ -0,0 +1,19 @@
 // Copyright 2020 Lukas Haubaum
 //
 // Licensed under the GNU Affero General Public License, Version 3;
 // you may not use this file except in compliance with the License.
 // You may obtain a copy of the License at
 //     https://www.gnu.org/licenses/agpl-3.0.html
 //
 // Unless required by applicable law or agreed to in writing, software
 // distributed under the License is distributed on an "AS IS" BASIS,
 // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 // See the License for the specific language governing permissions and
 // limitations under the License.
 #ifndef _ena_INTERFACE_STATUS_H_
 #define _ena_INTERFACE_STATUS_H_
 void ena_interface_status_start(void);
 #endif
--- a/components/ena-interface/include/ena-interface.h
+++ b/components/ena-interface/include/ena-interface.h
@ -28,15 +28,10 @@
 */
 typedef enum
 {
-    ENA_INTERFACE_STATE_IDLE = 0,    // ilde state, do nothing
+    ENA_INTERFACE_STATE_IDLE = 0,     // ilde state, do nothing
-    ENA_INTERFACE_STATE_MENU,        // main menu
+    ENA_INTERFACE_STATE_MENU,         // main menu
-    ENA_INTERFACE_STATE_SET_YEAR,    // set current year
+    ENA_INTERFACE_STATE_SET_DATETIME, // set current date and time
-    ENA_INTERFACE_STATE_SET_MONTH,   // set current month
+    ENA_INTERFACE_STATE_STATUS,       // current status
    ENA_INTERFACE_STATE_SET_DAY,     // set current day
    ENA_INTERFACE_STATE_SET_HOUR,    // set current hour
    ENA_INTERFACE_STATE_SET_MINUTE,  // set current minute
    ENA_INTERFACE_STATE_SET_SECONDS, // set current second
    ENA_INTERFACE_STATE_STATUS,      // view current status
 } ena_interface_state;
 /**
--- a/components/ena/CMakeLists.txt
+++ b/components/ena/CMakeLists.txt
@ -5,10 +5,15 @@ idf_component_register(
        "ena-bluetooth-advertise.c"
        "ena-bluetooth-scan.c"
        "ena-crypto.c"
        "ena-exposure.c"
        "ena-storage.c"
    INCLUDE_DIRS "include"
-    PRIV_REQUIRES 
+    PRIV_REQUIRES
        spi_flash
        mbedtls
        bt
        nanopb
    EMBED_FILES
        "test/export.bin"
        "test/export.sig"
 )
--- a/components/ena/Kconfig
+++ b/components/ena/Kconfig
@ -14,6 +14,12 @@ menu "Exposure Notification API"
      help
        Defines the maximum number of TEKs to be stored. (Default 14 [14 * 144 => 14 days])
    config ENA_STORAGE_EXPOSURE_INFORMATION_MAX
      int "Max. exporure information"
      default 500
      help
        Defines the maximum number of exposure information to be stored. (Default 500)
    config ENA_STORAGE_TEMP_BEACONS_MAX
      int "Max. temporary beacons"
      default 1000
@ -81,5 +87,12 @@ menu "Exposure Notification API"
        Defines the TEK rolling period in 10 minute steps. (Default 144 => 24 hours)
  endmenu
  menu "Miscellaneous"
    config ENA_RAM
      int "ENA RAM"
      default 100000
      help
        RAM required for main task. (Default 100 KB)
  endmenu
 endmenu
--- a/components/ena/ena-beacons.c
+++ b/components/ena/ena-beacons.c
@ -12,6 +12,7 @@
 // See the License for the specific language governing permissions and
 // limitations under the License.
 #include <string.h>
 #include <time.h>
 #include "esp_log.h"
@ -21,17 +22,7 @@
 #include "ena-beacons.h"
 static uint32_t temp_beacons_count = 0;
-static ena_temp_beacon_t temp_beacons[ENA_STORAGE_TEMP_BEACONS_MAX];
+static ena_beacon_t temp_beacons[ENA_STORAGE_TEMP_BEACONS_MAX];
 ena_beacon_t ena_beacons_convert(ena_temp_beacon_t temp_beacon)
 {
    ena_beacon_t beacon;
    memcpy(beacon.rpi, temp_beacon.rpi, ENA_KEY_LENGTH);
    memcpy(beacon.aem, temp_beacon.aem, ENA_AEM_METADATA_LENGTH);
    beacon.timestamp = temp_beacon.timestamp_last;
    beacon.rssi = temp_beacon.rssi;
    return beacon;
 }
 int ena_get_temp_beacon_index(uint8_t *rpi, uint8_t *aem)
 {
@ -55,8 +46,7 @@ void ena_beacons_temp_refresh(uint32_t unix_timestamp)
        {
            ESP_LOGD(ENA_BEACON_LOG, "create beacon after treshold");
            ESP_LOG_BUFFER_HEXDUMP(ENA_BEACON_LOG, temp_beacons[i].rpi, ENA_KEY_LENGTH, ESP_LOG_DEBUG);
-            ena_beacon_t beacon = ena_beacons_convert(temp_beacons[i]);
+            ena_storage_add_beacon(&temp_beacons[i]);
            ena_storage_add_beacon(&beacon);
            ena_storage_remove_temp_beacon(i);
        }
        else
@ -77,7 +67,8 @@ void ena_beacons_temp_refresh(uint32_t unix_timestamp)
 #if (CONFIG_ENA_STORAGE_DUMP)
    // DEBUG dump
-    ena_storage_dump_tek();
+    ena_storage_dump_teks();
    ena_storage_dump_exposure_information();
    ena_storage_dump_temp_beacons();
    ena_storage_dump_beacons();
 #endif
@ -86,7 +77,6 @@ void ena_beacons_temp_refresh(uint32_t unix_timestamp)
 void ena_beacon(uint32_t unix_timestamp, uint8_t *rpi, uint8_t *aem, int rssi)
 {
    uint32_t beacon_index = ena_get_temp_beacon_index(rpi, aem);
    if (beacon_index == -1)
    {
        temp_beacons[temp_beacons_count].timestamp_first = unix_timestamp;
@ -95,8 +85,7 @@ void ena_beacon(uint32_t unix_timestamp, uint8_t *rpi, uint8_t *aem, int rssi)
        temp_beacons[temp_beacons_count].rssi = rssi;
        temp_beacons[temp_beacons_count].timestamp_last = unix_timestamp;
        beacon_index = ena_storage_add_temp_beacon(&temp_beacons[temp_beacons_count]);
-
+        ESP_LOGD(ENA_BEACON_LOG, "new temporary beacon %d at %u", temp_beacons_count, unix_timestamp);
        ESP_LOGD(ENA_BEACON_LOG, "New temporary beacon at %d with timestamp %u", temp_beacons_count, unix_timestamp);
        ESP_LOG_BUFFER_HEX_LEVEL(ENA_BEACON_LOG, rpi, ENA_KEY_LENGTH, ESP_LOG_DEBUG);
        ESP_LOG_BUFFER_HEX_LEVEL(ENA_BEACON_LOG, aem, ENA_AEM_METADATA_LENGTH, ESP_LOG_DEBUG);
        ESP_LOGD(ENA_BEACON_LOG, "RSSI %d", rssi);
@ -111,9 +100,10 @@ void ena_beacon(uint32_t unix_timestamp, uint8_t *rpi, uint8_t *aem, int rssi)
    {
        temp_beacons[beacon_index].rssi = (temp_beacons[beacon_index].rssi + rssi) / 2;
        temp_beacons[beacon_index].timestamp_last = unix_timestamp;
-        ESP_LOGD(ENA_BEACON_LOG, "New Timestamp for temporary beacon %d: %u", beacon_index, unix_timestamp);
+        ESP_LOGD(ENA_BEACON_LOG, "update temporary beacon %d at %u", beacon_index, unix_timestamp);
-        ESP_LOG_BUFFER_HEX_LEVEL(ENA_BEACON_LOG, rpi, ENA_KEY_LENGTH, ESP_LOG_DEBUG);
+        ESP_LOG_BUFFER_HEX_LEVEL(ENA_BEACON_LOG, temp_beacons[beacon_index].rpi, ENA_KEY_LENGTH, ESP_LOG_DEBUG);
-        ESP_LOG_BUFFER_HEX_LEVEL(ENA_BEACON_LOG, aem, ENA_AEM_METADATA_LENGTH, ESP_LOG_DEBUG);
+        ESP_LOG_BUFFER_HEX_LEVEL(ENA_BEACON_LOG, temp_beacons[beacon_index].aem, ENA_AEM_METADATA_LENGTH, ESP_LOG_DEBUG);
        ESP_LOGD(ENA_BEACON_LOG, "RSSI %d", temp_beacons[beacon_index].rssi);
        ena_storage_set_temp_beacon(temp_beacons_count, &temp_beacons[temp_beacons_count]);
    }
 }
--- a/components/ena/ena-exposure.c
+++ b/components/ena/ena-exposure.c
@ -0,0 +1,280 @@
 // Copyright 2020 Lukas Haubaum
 //
 // Licensed under the GNU Affero General Public License, Version 3;
 // you may not use this file except in compliance with the License.
 // You may obtain a copy of the License at
 //     https://www.gnu.org/licenses/agpl-3.0.html
 //
 // Unless required by applicable law or agreed to in writing, software
 // distributed under the License is distributed on an "AS IS" BASIS,
 // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 // See the License for the specific language governing permissions and
 // limitations under the License.
 #include <string.h>
 #include <time.h>
 #include <limits.h>
 #include "esp_log.h"
 #include "ena-crypto.h"
 #include "ena-storage.h"
 #include "ena-beacons.h"
 #include "ena-exposure.h"
 static ena_exposure_config_t DEFAULT_ENA_EXPOSURE_CONFIG = {
    // transmission_risk_values
    {
        MINIMAL,   // UNKNOWN
        LOW,       // CONFIRMED_TEST_LOW
        MEDIUM,    // CONFIRMED_TEST_STANDARD
        HIGH,      // CONFIRMED_TEST_HIGH
        VERY_HIGH, // CONFIRMED_CLINICAL_DIAGNOSIS
        VERY_LOW,  // SELF_REPORT
        ZERO,      // NEGATIVE
        MINIMAL    // RECURSIVE
    },
    // duration_risk_values
    {
        MINIMAL,   // D = 0 min
        MINIMAL,   // D <= 5 min
        MEDIUM,    // D <= 10 min
        VERY_HIGH, // D <= 15 min
        VERY_HIGH, // D <= 20 min
        MAXIMUM,   // D <= 25 min
        MAXIMUM,   // D <= 30 min
        MAXIMUM    //  D > 30 min
    },
    // days_risk_values
    {
        MINIMAL,  // >= 14 days
        VERY_LOW, // 12-13 days
        VERY_LOW, // 10-11 days
        MEDIUM,   // 8-9 days
        HIGH,     // 6-7 days
        MAXIMUM,  // 4-5 days
        MAXIMUM,  // 2-3 days
        MAXIMUM   // 0-1 days
    },
    // attenuation_risk_values
    {
        MINIMAL, // A > 73 dB
        MINIMAL, // 73 >= A > 63
        MINIMAL, // 63 >= A > 61
        MAXIMUM, // 51 >= A > 33
        MAXIMUM, // 33 >= A > 27
        MAXIMUM, // 27 >= A > 15
        MAXIMUM, // 15 >= A > 10
        MAXIMUM  // A <= 10
    },
 };
 static const char kFileHeader[] = "EK Export v1    ";
 static size_t kFileHeaderSize = sizeof(kFileHeader) - 1;
 extern const uint8_t export_bin_start[] asm("_binary_export_bin_start");
 extern const uint8_t export_bin_end[] asm("_binary_export_bin_end");
 void ena_exposure_keyfiletest(void)
 {
    ESP_LOG_BUFFER_HEXDUMP(ENA_EXPOSURE_LOG, export_bin_start, (export_bin_end - export_bin_start), ESP_LOG_INFO);
 }
 void ena_exposure_check(ena_tek_reported_t tek_reported)
 {
    bool match = false;
    ena_beacon_t beacon;
    ena_exposure_information_t exposure_info;
    exposure_info.duration_minutes = 0;
    exposure_info.min_attenuation = INT_MAX;
    exposure_info.typical_attenuation = 0;
    exposure_info.report_type = tek_reported.report_type;
    uint8_t rpi[ENA_KEY_LENGTH];
    uint8_t rpik[ENA_KEY_LENGTH];
    ena_crypto_rpik(rpik, tek_reported.key_data);
    uint32_t beacons_count = ena_storage_beacons_count();
    for (int i = 0; i < tek_reported.rolling_period; i++)
    {
        ena_crypto_rpi(rpi, rpik, tek_reported.rolling_start_interval_number + i);
        for (int y = 0; y < beacons_count; y++)
        {
            ena_storage_get_beacon(y, &beacon);
            if (memcmp(beacon.rpi, rpi, sizeof(ENA_KEY_LENGTH)) == 0)
            {
                match = true;
                exposure_info.day = tek_reported.rolling_start_interval_number * ENA_TIME_WINDOW;
                exposure_info.duration_minutes += (ENA_BEACON_TRESHOLD / 60);
                exposure_info.typical_attenuation = (exposure_info.typical_attenuation + beacon.rssi) / 2;
                if (beacon.rssi < exposure_info.min_attenuation)
                {
                    exposure_info.min_attenuation = beacon.rssi;
                }
            }
        }
    }
    if (match)
    {
        ena_storage_add_exposure_information(&exposure_info);
    }
 }
 int ena_exposure_risk_score(ena_exposure_config_t *config, ena_exposure_parameter_t params)
 {
    int score = 1;
    score *= config->transmission_risk_values[params.report_type];
    // calc duration level
    int duration_level = MINUTES_0;
    if (params.duration > 0)
    {
        if (params.duration <= 5)
        {
            duration_level = MINUTES_5;
        }
        else if (params.duration <= 10)
        {
            duration_level = MINUTES_10;
        }
        if (params.duration <= 15)
        {
            duration_level = MINUTES_15;
        }
        if (params.duration <= 20)
        {
            duration_level = MINUTES_20;
        }
        if (params.duration <= 25)
        {
            duration_level = MINUTES_25;
        }
        if (params.duration <= 30)
        {
            duration_level = MINUTES_30;
        }
        else
        {
            duration_level = MINUTES_LONGER;
        }
    }
    score *= config->duration_risk_values[duration_level];
    // calc days level
    int days_level = DAYS_14;
    if (params.days < 2)
    {
        days_level = DAYS_0;
    }
    else if (params.days < 4)
    {
        days_level = DAYS_3;
    }
    else if (params.days < 6)
    {
        days_level = DAYS_5;
    }
    else if (params.days < 8)
    {
        days_level = DAYS_7;
    }
    else if (params.days < 10)
    {
        days_level = DAYS_9;
    }
    else if (params.days < 12)
    {
        days_level = DAYS_11;
    }
    else if (params.days < 14)
    {
        days_level = DAYS_13;
    }
    score *= config->days_risk_values[days_level];
    // calc attenuation level
    int attenuation_level = ATTENUATION_73;
    if (params.attenuation <= 10)
    {
        attenuation_level = ATTENUATION_LOWER;
    }
    else if (params.attenuation <= 15)
    {
        attenuation_level = ATTENUATION_10;
    }
    else if (params.attenuation <= 27)
    {
        attenuation_level = ATTENUATION_15;
    }
    else if (params.attenuation <= 33)
    {
        attenuation_level = ATTENUATION_27;
    }
    else if (params.attenuation <= 51)
    {
        attenuation_level = ATTENUATION_33;
    }
    else if (params.attenuation <= 63)
    {
        attenuation_level = ATTENUATION_51;
    }
    else if (params.attenuation <= 73)
    {
        attenuation_level = ATTENUATION_63;
    }
    score *= config->attenuation_risk_values[attenuation_level];
    if (score > 255)
    {
        score = 255;
    }
    return score;
 }
 void ena_exposure_summary(ena_exposure_config_t *config, ena_exposure_summary_t *summary)
 {
    uint32_t count = ena_storage_exposure_information_count();
    uint32_t current_time = (uint32_t)time(NULL);
    summary->days_since_last_exposure = INT_MAX;
    summary->max_risk_score = 0;
    summary->risk_score_sum = 0;
    summary->num_exposures = count;
    if (count == 0)
    {
        summary->days_since_last_exposure = -1;
    }
    ena_exposure_information_t exposure_info;
    ena_exposure_parameter_t params;
    for (int i = 0; i < count; i++)
    {
        ena_storage_get_exposure_information(i, &exposure_info);
        params.days = (current_time - exposure_info.day) / (60 * 60 * 24); // difference in days
        if (params.days < summary->days_since_last_exposure)
        {
            summary->days_since_last_exposure = params.days;
        }
        params.duration = exposure_info.duration_minutes;
        params.attenuation = exposure_info.typical_attenuation;
        int score = ena_exposure_risk_score(config, params);
        if (score > summary->max_risk_score)
        {
            summary->max_risk_score = score;
        }
        summary->risk_score_sum += score;
    }
    ena_exposure_keyfiletest();
 }
 ena_exposure_config_t *ena_exposure_default_config(void)
 {
    return &DEFAULT_ENA_EXPOSURE_CONFIG;
 }
--- a/components/ena/ena-storage.c
+++ b/components/ena/ena-storage.c
@ -24,14 +24,15 @@
 const int ENA_STORAGE_TEK_COUNT_ADDRESS = (ENA_STORAGE_START_ADDRESS); // starting address for TEK COUNT
 const int ENA_STORAGE_TEK_START_ADDRESS = (ENA_STORAGE_TEK_COUNT_ADDRESS + sizeof(uint32_t));
-const int ENA_STORAGE_TEMP_BEACONS_COUNT_ADDRESS = (ENA_STORAGE_TEK_START_ADDRESS + sizeof(ena_tek_t) * ENA_STORAGE_TEK_MAX);
+const int ENA_STORAGE_EXPOSURE_INFORMATION_COUNT_ADDRESS = (ENA_STORAGE_TEK_START_ADDRESS + sizeof(ena_tek_t) * ENA_STORAGE_TEK_MAX);
 const int ENA_STORAGE_EXPOSURE_INFORMATION_START_ADDRESS = (ENA_STORAGE_EXPOSURE_INFORMATION_COUNT_ADDRESS + sizeof(uint32_t));
 const int ENA_STORAGE_TEMP_BEACONS_COUNT_ADDRESS = (ENA_STORAGE_EXPOSURE_INFORMATION_COUNT_ADDRESS + sizeof(ena_exposure_information_t) * ENA_STORAGE_EXPOSURE_INFORMATION_MAX);
 const int ENA_STORAGE_TEMP_BEACONS_START_ADDRESS = (ENA_STORAGE_TEMP_BEACONS_COUNT_ADDRESS + sizeof(uint32_t));
-const int ENA_STORAGE_BEACONS_COUNT_ADDRESS = (ENA_STORAGE_TEMP_BEACONS_START_ADDRESS + sizeof(ena_temp_beacon_t) * ENA_STORAGE_TEMP_BEACONS_MAX);
+const int ENA_STORAGE_BEACONS_COUNT_ADDRESS = (ENA_STORAGE_TEMP_BEACONS_START_ADDRESS + sizeof(ena_beacon_t) * ENA_STORAGE_TEMP_BEACONS_MAX);
 const int ENA_STORAGE_BEACONS_START_ADDRESS = (ENA_STORAGE_BEACONS_COUNT_ADDRESS + sizeof(uint32_t));
 void ena_storage_read(size_t address, void *data, size_t size)
 {
    ESP_LOGD(ENA_STORAGE_LOG, "START ena_storage_read");
    const esp_partition_t *partition = esp_partition_find_first(
        ESP_PARTITION_TYPE_DATA, ESP_PARTITION_SUBTYPE_ANY, ENA_STORAGE_PARTITION_NAME);
    assert(partition);
@ -39,12 +40,10 @@ void ena_storage_read(size_t address, void *data, size_t size)
    vTaskDelay(1);
    ESP_LOGD(ENA_STORAGE_LOG, "read data at %u", address);
    ESP_LOG_BUFFER_HEXDUMP(ENA_STORAGE_LOG, data, size, ESP_LOG_DEBUG);
    ESP_LOGD(ENA_STORAGE_LOG, "END ena_storage_read");
 }
 void ena_storage_write(size_t address, void *data, size_t size)
 {
    ESP_LOGD(ENA_STORAGE_LOG, "START ena_storage_write");
    const int block_num = address / BLOCK_SIZE;
    // check for overflow
    if (address + size <= (block_num + 1) * BLOCK_SIZE)
@ -90,13 +89,10 @@ void ena_storage_write(size_t address, void *data, size_t size)
        ena_storage_write(block2_address, data2, data2_size);
        free(data2);
    }
    ESP_LOGD(ENA_STORAGE_LOG, "END ena_storage_write");
 }
 void ena_storage_shift_delete(size_t address, size_t end_address, size_t size)
 {
    ESP_LOGD(ENA_STORAGE_LOG, "START ena_storage_shift_delete");
    int block_num_start = address / BLOCK_SIZE;
    // check for overflow
    if (address + size <= (block_num_start + 1) * BLOCK_SIZE)
@ -146,12 +142,10 @@ void ena_storage_shift_delete(size_t address, size_t end_address, size_t size)
        ena_storage_shift_delete(block1_address, block2_address, data1_size);
        ena_storage_shift_delete(block2_address, end_address - data1_size, data2_size);
    }
    ESP_LOGD(ENA_STORAGE_LOG, "END ena_storage_shift_delete");
 }
 uint32_t ena_storage_read_last_tek(ena_tek_t *tek)
 {
    ESP_LOGD(ENA_STORAGE_LOG, "START ena_storage_read_tek");
    uint32_t tek_count = 0;
    ena_storage_read(ENA_STORAGE_TEK_COUNT_ADDRESS, &tek_count, sizeof(uint32_t));
    if (tek_count < 1)
@ -163,14 +157,11 @@ uint32_t ena_storage_read_last_tek(ena_tek_t *tek)
    ESP_LOGD(ENA_STORAGE_LOG, "read last tek %u:", tek->enin);
    ESP_LOG_BUFFER_HEXDUMP(ENA_STORAGE_LOG, tek->key_data, ENA_KEY_LENGTH, ESP_LOG_DEBUG);
    ESP_LOGD(ENA_STORAGE_LOG, "END ena_storage_read_tek");
    return tek_count;
 }
 void ena_storage_write_tek(ena_tek_t *tek)
 {
    ESP_LOGD(ENA_STORAGE_LOG, "START ena_storage_write_tek");
    uint32_t tek_count = 0;
    ena_storage_read(ENA_STORAGE_TEK_COUNT_ADDRESS, &tek_count, sizeof(uint32_t));
    uint8_t index = (tek_count % ENA_STORAGE_TEK_MAX);
@ -181,33 +172,49 @@ void ena_storage_write_tek(ena_tek_t *tek)
    ESP_LOGD(ENA_STORAGE_LOG, "write tek: ENIN %u", tek->enin);
    ESP_LOG_BUFFER_HEXDUMP(ENA_STORAGE_LOG, tek->key_data, ENA_KEY_LENGTH, ESP_LOG_DEBUG);
-    ESP_LOGD(ENA_STORAGE_LOG, "END ena_storage_write_tek");
+}
 uint32_t ena_storage_exposure_information_count(void)
 {
    uint32_t count = 0;
    ena_storage_read(ENA_STORAGE_EXPOSURE_INFORMATION_COUNT_ADDRESS, &count, sizeof(uint32_t));
    ESP_LOGD(ENA_STORAGE_LOG, "read exposure information count: %u", count);
    return count;
 }
 void ena_storage_get_exposure_information(uint32_t index, ena_exposure_information_t *exposure_info)
 {
    ena_storage_read(ENA_STORAGE_EXPOSURE_INFORMATION_START_ADDRESS + index * sizeof(ena_exposure_information_t), exposure_info, sizeof(ena_exposure_information_t));
    ESP_LOGD(ENA_STORAGE_LOG, "read exporuse information: day %u, duration %d", exposure_info->day, exposure_info->duration_minutes);
 }
 void ena_storage_add_exposure_information(ena_exposure_information_t *exposure_info)
 {
    uint32_t count = ena_storage_exposure_information_count();
    ena_storage_write(ENA_STORAGE_EXPOSURE_INFORMATION_START_ADDRESS + count * sizeof(ena_exposure_information_t), exposure_info, sizeof(ena_exposure_information_t));
    count++;
    ena_storage_write(ENA_STORAGE_EXPOSURE_INFORMATION_COUNT_ADDRESS, &count, sizeof(uint32_t));
    ESP_LOGD(ENA_STORAGE_LOG, "write exposure info:  day %u, duration %d", exposure_info->day, exposure_info->duration_minutes);
 }
 uint32_t ena_storage_temp_beacons_count(void)
 {
    ESP_LOGD(ENA_STORAGE_LOG, "START ena_storage_temp_beacons_count");
    uint32_t count = 0;
    ena_storage_read(ENA_STORAGE_TEMP_BEACONS_COUNT_ADDRESS, &count, sizeof(uint32_t));
-    ESP_LOGD(ENA_STORAGE_LOG, "read temp contancts count: %u", count);
+    ESP_LOGD(ENA_STORAGE_LOG, "read temp beacons count: %u", count);
    ESP_LOGD(ENA_STORAGE_LOG, "END ena_storage_temp_beacons_count");
    return count;
 }
-void ena_storage_get_temp_beacon(uint32_t index, ena_temp_beacon_t *beacon)
+void ena_storage_get_temp_beacon(uint32_t index, ena_beacon_t *beacon)
 {
-    ESP_LOGD(ENA_STORAGE_LOG, "START ena_storage_read_temp_beacon");
+    ena_storage_read(ENA_STORAGE_TEMP_BEACONS_START_ADDRESS + index * sizeof(ena_beacon_t), beacon, sizeof(ena_beacon_t));
    ena_storage_read(ENA_STORAGE_TEMP_BEACONS_START_ADDRESS + index * sizeof(ena_temp_beacon_t), beacon, sizeof(ena_temp_beacon_t));
    ESP_LOGD(ENA_STORAGE_LOG, "read temp beacon: first %u, last %u and rssi %d", beacon->timestamp_first, beacon->timestamp_last, beacon->rssi);
    ESP_LOG_BUFFER_HEXDUMP(ENA_STORAGE_LOG, beacon->rpi, ENA_KEY_LENGTH, ESP_LOG_DEBUG);
    ESP_LOG_BUFFER_HEXDUMP(ENA_STORAGE_LOG, beacon->aem, ENA_AEM_METADATA_LENGTH, ESP_LOG_DEBUG);
    ESP_LOGD(ENA_STORAGE_LOG, "END ena_storage_read_temp_beacon");
 }
-uint32_t ena_storage_add_temp_beacon(ena_temp_beacon_t *beacon)
+uint32_t ena_storage_add_temp_beacon(ena_beacon_t *beacon)
 {
    ESP_LOGD(ENA_STORAGE_LOG, "START ena_storage_add_temp_beacon");
    uint32_t count = ena_storage_temp_beacons_count();
    // overwrite older temporary beacons?!
    uint8_t index = count % ENA_STORAGE_TEMP_BEACONS_MAX;
@ -217,73 +224,60 @@ uint32_t ena_storage_add_temp_beacon(ena_temp_beacon_t *beacon)
    ESP_LOG_BUFFER_HEXDUMP(ENA_STORAGE_LOG, beacon->aem, ENA_AEM_METADATA_LENGTH, ESP_LOG_DEBUG);
    count++;
    ena_storage_write(ENA_STORAGE_TEMP_BEACONS_COUNT_ADDRESS, &count, sizeof(uint32_t));
    ESP_LOGD(ENA_STORAGE_LOG, "END ena_storage_add_temp_beacon");
    return count - 1;
 }
-void ena_storage_set_temp_beacon(uint32_t index, ena_temp_beacon_t *beacon)
+void ena_storage_set_temp_beacon(uint32_t index, ena_beacon_t *beacon)
 {
-    ESP_LOGD(ENA_STORAGE_LOG, "START ena_storage_set_temp_beacon");
+    ena_storage_write(ENA_STORAGE_TEMP_BEACONS_START_ADDRESS + index * sizeof(ena_beacon_t), beacon, sizeof(ena_beacon_t));
    ena_storage_write(ENA_STORAGE_TEMP_BEACONS_START_ADDRESS + index * sizeof(ena_temp_beacon_t), beacon, sizeof(ena_temp_beacon_t));
    ESP_LOGD(ENA_STORAGE_LOG, "set temp beacon at %u: first %u, last %u  and rssi %d", index, beacon->timestamp_first, beacon->timestamp_last, beacon->rssi);
    ESP_LOG_BUFFER_HEXDUMP(ENA_STORAGE_LOG, beacon->rpi, ENA_KEY_LENGTH, ESP_LOG_DEBUG);
    ESP_LOG_BUFFER_HEXDUMP(ENA_STORAGE_LOG, beacon->aem, ENA_AEM_METADATA_LENGTH, ESP_LOG_DEBUG);
    ESP_LOGD(ENA_STORAGE_LOG, "END ena_storage_set_temp_beacon");
 }
 void ena_storage_remove_temp_beacon(uint32_t index)
 {
    ESP_LOGD(ENA_STORAGE_LOG, "START ena_storage_remove_temp_beacon");
    uint32_t count = ena_storage_temp_beacons_count();
-    size_t address_from = ENA_STORAGE_TEMP_BEACONS_START_ADDRESS + index * sizeof(ena_temp_beacon_t);
+    size_t address_from = ENA_STORAGE_TEMP_BEACONS_START_ADDRESS + index * sizeof(ena_beacon_t);
-    size_t address_to = ENA_STORAGE_TEMP_BEACONS_START_ADDRESS + count * sizeof(ena_temp_beacon_t);
+    size_t address_to = ENA_STORAGE_TEMP_BEACONS_START_ADDRESS + count * sizeof(ena_beacon_t);
-    ena_storage_shift_delete(address_from, address_to, sizeof(ena_temp_beacon_t));
+    ena_storage_shift_delete(address_from, address_to, sizeof(ena_beacon_t));
    count--;
    ena_storage_write(ENA_STORAGE_TEMP_BEACONS_COUNT_ADDRESS, &count, sizeof(uint32_t));
    ESP_LOGD(ENA_STORAGE_LOG, "remove temp beacon: %u", index);
    ESP_LOGD(ENA_STORAGE_LOG, "END ena_storage_remove_temp_beacon");
 }
 uint32_t ena_storage_beacons_count(void)
 {
    ESP_LOGD(ENA_STORAGE_LOG, "START ena_storage_beacons_count");
    uint32_t count = 0;
    ena_storage_read(ENA_STORAGE_BEACONS_COUNT_ADDRESS, &count, sizeof(uint32_t));
    ESP_LOGD(ENA_STORAGE_LOG, "read contancts count: %u", count);
    ESP_LOGD(ENA_STORAGE_LOG, "END ena_storage_beacons_count");
    return count;
 }
 void ena_storage_get_beacon(uint32_t index, ena_beacon_t *beacon)
 {
    ESP_LOGD(ENA_STORAGE_LOG, "START ena_storage_read_beacon");
    ena_storage_read(ENA_STORAGE_BEACONS_START_ADDRESS + index * sizeof(ena_beacon_t), beacon, sizeof(ena_beacon_t));
-    ESP_LOGD(ENA_STORAGE_LOG, "read beacon: timestamp %u and rssi %d", beacon->timestamp, beacon->rssi);
+    ESP_LOGD(ENA_STORAGE_LOG, "read beacon: first %u, last %u and rssi %d", beacon->timestamp_first, beacon->timestamp_last, beacon->rssi);
    ESP_LOG_BUFFER_HEXDUMP(ENA_STORAGE_LOG, beacon->rpi, ENA_KEY_LENGTH, ESP_LOG_DEBUG);
    ESP_LOG_BUFFER_HEXDUMP(ENA_STORAGE_LOG, beacon->aem, ENA_AEM_METADATA_LENGTH, ESP_LOG_DEBUG);
    ESP_LOGD(ENA_STORAGE_LOG, "END ena_storage_read_beacon");
 }
 void ena_storage_add_beacon(ena_beacon_t *beacon)
 {
    ESP_LOGD(ENA_STORAGE_LOG, "START ena_storage_write_beacon");
    ESP_LOG_BUFFER_HEXDUMP(ENA_STORAGE_LOG, beacon->rpi, ENA_KEY_LENGTH, ESP_LOG_DEBUG);
    uint32_t count = ena_storage_beacons_count();
    ena_storage_write(ENA_STORAGE_BEACONS_START_ADDRESS + count * sizeof(ena_beacon_t), beacon, sizeof(ena_beacon_t));
    count++;
    ena_storage_write(ENA_STORAGE_BEACONS_COUNT_ADDRESS, &count, sizeof(uint32_t));
-    ESP_LOGD(ENA_STORAGE_LOG, "write beacon: timestamp %u and rssi %d", beacon->timestamp, beacon->rssi);
+    ESP_LOGD(ENA_STORAGE_LOG, "write beacon: first %u, last %u  and rssi %d", beacon->timestamp_first, beacon->timestamp_last, beacon->rssi);
    ESP_LOG_BUFFER_HEXDUMP(ENA_STORAGE_LOG, beacon->rpi, ENA_KEY_LENGTH, ESP_LOG_DEBUG);
    ESP_LOG_BUFFER_HEXDUMP(ENA_STORAGE_LOG, beacon->aem, ENA_AEM_METADATA_LENGTH, ESP_LOG_DEBUG);
    ESP_LOGD(ENA_STORAGE_LOG, "END ena_storage_write_beacon");
 }
 void ena_storage_erase(void)
 {
    ESP_LOGD(ENA_STORAGE_LOG, "START ena_storage_erase");
    const esp_partition_t *partition = esp_partition_find_first(
        ESP_PARTITION_TYPE_DATA, ESP_PARTITION_SUBTYPE_ANY, ENA_STORAGE_PARTITION_NAME);
    assert(partition);
@ -292,23 +286,20 @@ void ena_storage_erase(void)
    uint32_t count = 0;
    ena_storage_write(ENA_STORAGE_TEK_COUNT_ADDRESS, &count, sizeof(uint32_t));
    ena_storage_write(ENA_STORAGE_EXPOSURE_INFORMATION_COUNT_ADDRESS, &count, sizeof(uint32_t));
    ena_storage_write(ENA_STORAGE_TEMP_BEACONS_COUNT_ADDRESS, &count, sizeof(uint32_t));
    ena_storage_write(ENA_STORAGE_BEACONS_COUNT_ADDRESS, &count, sizeof(uint32_t));
    ESP_LOGD(ENA_STORAGE_LOG, "END ena_storage_erase");
 }
 void ena_storage_erase_tek(void)
 {
    uint32_t count = 0;
    ena_storage_read(ENA_STORAGE_TEK_COUNT_ADDRESS, &count, sizeof(uint32_t));
    uint32_t stored = ENA_STORAGE_TEK_MAX;
-    ESP_LOGD(ENA_STORAGE_LOG, "START ena_storage_erase_teks");
+    if (count < ENA_STORAGE_TEK_MAX)
    uint32_t tek_count = 0;
    ena_storage_read(ENA_STORAGE_TEK_COUNT_ADDRESS, &tek_count, sizeof(uint32_t));
    uint8_t stored = ENA_STORAGE_TEK_MAX;
    if (tek_count < ENA_STORAGE_TEK_MAX)
    {
-        stored = tek_count;
+        stored = count;
    }
    size_t size = sizeof(uint32_t) + stored * sizeof(ena_tek_t);
@ -316,12 +307,27 @@ void ena_storage_erase_tek(void)
    ena_storage_write(ENA_STORAGE_TEK_COUNT_ADDRESS, zeros, size);
    free(zeros);
    ESP_LOGI(ENA_STORAGE_LOG, "erased %d teks (size %u at %u)", stored, size, ENA_STORAGE_TEK_COUNT_ADDRESS);
-    ESP_LOGD(ENA_STORAGE_LOG, "END ena_storage_erase_teks");
+}
 void ena_storage_erase_exposure_information(void)
 {
    uint32_t count = ena_storage_exposure_information_count();
    uint32_t stored = ENA_STORAGE_EXPOSURE_INFORMATION_MAX;
    if (count < ENA_STORAGE_EXPOSURE_INFORMATION_MAX)
    {
        stored = count;
    }
    size_t size = sizeof(uint32_t) + stored * sizeof(ena_exposure_information_t);
    uint8_t *zeros = calloc(size, sizeof(uint8_t));
    ena_storage_write(ENA_STORAGE_EXPOSURE_INFORMATION_COUNT_ADDRESS, zeros, size);
    free(zeros);
    ESP_LOGI(ENA_STORAGE_LOG, "erased %d exposure information (size %u at %u)", stored, size, ENA_STORAGE_EXPOSURE_INFORMATION_COUNT_ADDRESS);
 }
 void ena_storage_erase_temporary_beacon(void)
 {
    ESP_LOGD(ENA_STORAGE_LOG, "START ena_storage_erase_temporary_beacons");
    uint32_t beacon_count = 0;
    ena_storage_read(ENA_STORAGE_TEMP_BEACONS_COUNT_ADDRESS, &beacon_count, sizeof(uint32_t));
    uint32_t stored = ENA_STORAGE_TEMP_BEACONS_MAX;
@ -331,18 +337,16 @@ void ena_storage_erase_temporary_beacon(void)
        stored = beacon_count;
    }
-    size_t size = sizeof(uint32_t) + stored * sizeof(ena_temp_beacon_t);
+    size_t size = sizeof(uint32_t) + stored * sizeof(ena_beacon_t);
    uint8_t *zeros = calloc(size, sizeof(uint8_t));
    ena_storage_write(ENA_STORAGE_TEMP_BEACONS_COUNT_ADDRESS, zeros, size);
    free(zeros);
    ESP_LOGI(ENA_STORAGE_LOG, "erased %d temporary beacons (size %u at %u)", stored, size, ENA_STORAGE_TEMP_BEACONS_COUNT_ADDRESS);
    ESP_LOGD(ENA_STORAGE_LOG, "END ena_storage_erase_temporary_beacons");
 }
 void ena_storage_erase_beacon(void)
 {
    ESP_LOGD(ENA_STORAGE_LOG, "START ena_storage_erase_beacon");
    uint32_t beacon_count = 0;
    ena_storage_read(ENA_STORAGE_BEACONS_COUNT_ADDRESS, &beacon_count, sizeof(uint32_t));
@ -352,7 +356,6 @@ void ena_storage_erase_beacon(void)
    free(zeros);
    ESP_LOGI(ENA_STORAGE_LOG, "erased %d beacons (size %u at %u)", beacon_count, size, ENA_STORAGE_BEACONS_COUNT_ADDRESS);
    ESP_LOGD(ENA_STORAGE_LOG, "END ena_storage_erase_beacon");
 }
 void ena_storage_dump_hash_array(uint8_t *data, size_t size)
@ -370,12 +373,12 @@ void ena_storage_dump_hash_array(uint8_t *data, size_t size)
    }
 }
-void ena_storage_dump_tek(void)
+void ena_storage_dump_teks(void)
 {
    ena_tek_t tek;
    uint32_t tek_count = 0;
    ena_storage_read(ENA_STORAGE_TEK_COUNT_ADDRESS, &tek_count, sizeof(uint32_t));
-    uint8_t stored = ENA_STORAGE_TEK_MAX;
+    uint32_t stored = ENA_STORAGE_TEK_MAX;
    if (tek_count < ENA_STORAGE_TEK_MAX)
    {
@ -395,9 +398,31 @@ void ena_storage_dump_tek(void)
    }
 }
 void ena_storage_dump_exposure_information(void)
 {
    ena_exposure_information_t exposure_info;
    uint32_t exposure_information_count = ena_storage_exposure_information_count();
    uint32_t stored = ENA_STORAGE_EXPOSURE_INFORMATION_MAX;
    if (exposure_information_count < ENA_STORAGE_EXPOSURE_INFORMATION_MAX)
    {
        stored = exposure_information_count;
    }
    ESP_LOGD(ENA_STORAGE_LOG, "%u exposure information (%u stored)\n", exposure_information_count, stored);
    printf("#,day,typical_attenuation,min_attenuation,duration_minutes,report_type\n");
    for (int i = 0; i < stored; i++)
    {
        size_t address = ENA_STORAGE_EXPOSURE_INFORMATION_START_ADDRESS + i * sizeof(ena_exposure_information_t);
        ena_storage_read(address, &exposure_info, sizeof(ena_exposure_information_t));
        printf("%d,%u,%d,%d,%d,%d\n", i, exposure_info.day, exposure_info.typical_attenuation, exposure_info.min_attenuation, exposure_info.duration_minutes, exposure_info.report_type);
    }
 }
 void ena_storage_dump_temp_beacons(void)
 {
-    ena_temp_beacon_t beacon;
+    ena_beacon_t beacon;
    uint32_t beacon_count = 0;
    ena_storage_read(ENA_STORAGE_TEMP_BEACONS_COUNT_ADDRESS, &beacon_count, sizeof(uint32_t));
    uint32_t stored = ENA_STORAGE_TEMP_BEACONS_MAX;
@ -426,11 +451,11 @@ void ena_storage_dump_beacons(void)
    uint32_t beacon_count = 0;
    ena_storage_read(ENA_STORAGE_BEACONS_COUNT_ADDRESS, &beacon_count, sizeof(uint32_t));
    ESP_LOGD(ENA_STORAGE_LOG, "%u beacons\n", beacon_count);
-    printf("#,timestamp,rpi,aem,rssi\n");
+    printf("#,timestamp_first,timestamp_last,rpi,aem,rssi\n");
    for (int i = 0; i < beacon_count; i++)
    {
        ena_storage_get_beacon(i, &beacon);
-        printf("%d,%u,", i, beacon.timestamp);
+        printf("%d,%u,%u,", i, beacon.timestamp_first, beacon.timestamp_last);
        ena_storage_dump_hash_array(beacon.rpi, ENA_KEY_LENGTH);
        printf(",");
        ena_storage_dump_hash_array(beacon.aem, ENA_AEM_METADATA_LENGTH);
--- a/components/ena/ena.c
+++ b/components/ena/ena.c
@ -49,8 +49,8 @@ void ena_next_rpi_timestamp(uint32_t timestamp)
 void ena_run(void *pvParameter)
 {
-    uint32_t unix_timestamp = 0;
+    static uint32_t unix_timestamp = 0;
-    uint32_t current_enin = 0;
+    static uint32_t current_enin = 0;
    while (1)
    {
        unix_timestamp = (uint32_t)time(NULL);
@ -97,6 +97,7 @@ void ena_start(void)
 #if (CONFIG_ENA_STORAGE_ERASE)
    ena_storage_erase();
 #endif
    // init NVS for BLE
    esp_err_t ret;
    ret = nvs_flash_init();
@ -146,7 +147,7 @@ void ena_start(void)
    ena_crypto_init();
    uint32_t unix_timestamp = (uint32_t)time(NULL);
-    
+
    uint32_t current_enin = ena_crypto_enin(unix_timestamp);
    uint32_t tek_count = ena_storage_read_last_tek(&last_tek);
@ -172,5 +173,5 @@ void ena_start(void)
    ena_bluetooth_scan_start(ENA_SCANNING_TIME);
    // what is a good stack size here?
-    xTaskCreate(&ena_run, "ena_run", configMINIMAL_STACK_SIZE * 8, NULL, 5, NULL);
+    xTaskCreate(&ena_run, "ena_run", ENA_RAM, NULL, 5, NULL);
 }
--- a/components/ena/include/ena-exposure.h
+++ b/components/ena/include/ena-exposure.h
@ -0,0 +1,177 @@
 // Copyright 2020 Lukas Haubaum
 //
 // Licensed under the GNU Affero General Public License, Version 3;
 // you may not use this file except in compliance with the License.
 // You may obtain a copy of the License at
 //     https://www.gnu.org/licenses/agpl-3.0.html
 //
 // Unless required by applicable law or agreed to in writing, software
 // distributed under the License is distributed on an "AS IS" BASIS,
 // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 // See the License for the specific language governing permissions and
 // limitations under the License.
 #ifndef _ena_EXPOSURE_H_
 #define _ena_EXPOSURE_H_
 #include <stdio.h>
 #include "ena-crypto.h"
 #define ENA_EXPOSURE_LOG "ESP-ENA-exposure" // TAG for Logging
 /**
 * @brief report type
 */
 typedef enum
 {
    UNKNOWN = 0,
    CONFIRMED_TEST_LOW = 1,
    CONFIRMED_TEST_STANDARD = 2,
    CONFIRMED_TEST_HIGH = 3,
    CONFIRMED_CLINICAL_DIAGNOSIS = 4,
    SELF_REPORT = 5,
    NEGATIVE = 6,
    RECURSIVE = 7,
 } ena_report_type_t;
 /**
 * @brief duration risk
 */
 typedef enum
 {
    MINUTES_0 = 0,      // D = 0 min
    MINUTES_5 = 1,      // D <= 5 min
    MINUTES_10 = 2,     // D <= 10 min
    MINUTES_15 = 3,     // D <= 15 min
    MINUTES_20 = 4,     // D <= 20 min
    MINUTES_25 = 5,     // D <= 25 min
    MINUTES_30 = 6,     // D <= 30 min
    MINUTES_LONGER = 7, // D > 30 min
 } ena_duration_risk_t;
 /**
 * @brief day risk
 */
 typedef enum
 {
    DAYS_14 = 0, // >= 14 days
    DAYS_13 = 1, // 12-13 days
    DAYS_11 = 2, // 10-11 days
    DAYS_9 = 3,  // 8-9 days
    DAYS_7 = 4,  // 6-7 days
    DAYS_5 = 5,  // 4-5 days
    DAYS_3 = 6,  // 2-3 days
    DAYS_0 = 7,  // 0-1 days
 } ena_day_risk_t;
 /**
 * @brief attenuation risk
 */
 typedef enum
 {
    ATTENUATION_73 = 0,    // A > 73 dB
    ATTENUATION_63 = 1,    // 73 >= A > 63
    ATTENUATION_51 = 2,    // 63 >= A > 61
    ATTENUATION_33 = 3,    // 51 >= A > 33
    ATTENUATION_27 = 4,    // 33 >= A > 27
    ATTENUATION_15 = 5,    // 27 >= A > 15
    ATTENUATION_10 = 6,    // 15 >= A > 10
    ATTENUATION_LOWER = 7, // A <= 10
 } ena_attenuation_risk_t;
 /**
 * @brief risk level from 0-8
 */
 typedef enum
 {
    ZERO = 0,
    MINIMAL = 1,
    VERY_LOW = 2,
    LOW = 3,
    MEDIUM = 4,
    INCREASED = 5,
    HIGH = 6,
    VERY_HIGH = 7,
    MAXIMUM = 8,
 } ena_risk_level_t;
 /**
 * @brief structure for exposure configuration
 * 
 * The exposure configuration is used to calculate the risk score.
 */
 typedef struct __attribute__((__packed__))
 {
    uint8_t transmission_risk_values[8];
    uint8_t duration_risk_values[8];
    uint8_t days_risk_values[8];
    uint8_t attenuation_risk_values[8];
 } ena_exposure_config_t;
 /**
 * @brief structure for exposure parameter
 * 
 * These parameter are obtained from an exposure information to calculate the risk score.
 */
 typedef struct __attribute__((__packed__))
 {
    ena_report_type_t report_type;
    int days;
    int duration;
    int attenuation;
 } ena_exposure_parameter_t;
 /**
 * @brief structure for exposure summary
 * 
 * This represents the current state of all exposures.
 */
 typedef struct __attribute__((__packed__))
 {
    int days_since_last_exposure; // Number of days since the most recent exposure.
    int num_exposures;            // Number of all exposure information
    int max_risk_score;           // max. risk score of all exposure information
    int risk_score_sum;           // sum of all risk_scores
 } ena_exposure_summary_t;
 /**
 * @brief structure for a reported TEK
 */
 typedef struct __attribute__((__packed__))
 {
    uint8_t key_data[ENA_KEY_LENGTH];       // Key of infected user
    uint32_t rolling_start_interval_number; // The interval number since epoch for which a key starts
    uint8_t rolling_period;                 // Increments of 10 minutes describing how long a key is valid
    ena_report_type_t report_type;          // Type of diagnosis associated with a key.
    uint32_t days_since_onset_of_symptoms;  // Number of days elapsed between symptom onset and the TEK being used. E.g. 2 means TEK is 2 days after onset of symptoms.
 } ena_tek_reported_t;
 /**
 * @brief check for exposure for a reported tek and store exposure information on finding
 * 
 * @param[in] tek_reported the reported tek to check
 */
 void ena_exposure_check(ena_tek_reported_t tek_reported);
 /**
 * @brief calculate risk score
 * 
 * @param[in] config the exposure configuration used for calculating score
 * @param[in] params the exposure parameter to calculate with
 */
 int ena_exposure_risk_score(ena_exposure_config_t *config, ena_exposure_parameter_t params);
 /**
 * @brief returns the current exposure summary
 * 
 * @param[in] config the exposure configuration used for calculating scores
 * @param[out] summary pointer to exposure summary to write to
 */
 void ena_exposure_summary(ena_exposure_config_t *config, ena_exposure_summary_t *summary);
 /**
 * @brief return a default exposure configuration
 */
 ena_exposure_config_t *ena_exposure_default_config(void);
 #endif
--- a/components/ena/include/ena-storage.h
+++ b/components/ena/include/ena-storage.h
@ -16,11 +16,12 @@
 #include "ena-crypto.h"
-#define ENA_STORAGE_LOG "ESP-ENA-storage"                                  // TAG for Logging
+#define ENA_STORAGE_LOG "ESP-ENA-storage"                                    // TAG for Logging
-#define ENA_STORAGE_PARTITION_NAME (CONFIG_ENA_STORAGE_PARTITION_NAME)     // name of partition to use for storing
+#define ENA_STORAGE_PARTITION_NAME (CONFIG_ENA_STORAGE_PARTITION_NAME)       // name of partition to use for storing
-#define ENA_STORAGE_START_ADDRESS (CONFIG_ENA_STORAGE_START_ADDRESS)      // start address of storage
+#define ENA_STORAGE_START_ADDRESS (CONFIG_ENA_STORAGE_START_ADDRESS)         // start address of storage
-#define ENA_STORAGE_TEK_MAX (CONFIG_ENA_STORAGE_TEK_MAX)                   // Period of storing TEKs                                                                            // length of a stored beacon -> RPI keysize + AEM size + 4 Bytes for ENIN + 4 Bytes for RSSI
+#define ENA_STORAGE_TEK_MAX (CONFIG_ENA_STORAGE_TEK_MAX)                     // Period of storing TEKs                                                                            // length of a stored beacon -> RPI keysize + AEM size + 4 Bytes for ENIN + 4 Bytes for RSSI
-#define ENA_STORAGE_TEMP_BEACONS_MAX (CONFIG_ENA_STORAGE_TEMP_BEACONS_MAX) // Maximum number of temporary stored beacons
+#define ENA_STORAGE_TEMP_BEACONS_MAX (CONFIG_ENA_STORAGE_TEMP_BEACONS_MAX)   // Maximum number of temporary stored beacons                                                    // length of a stored beacon -> RPI keysize + AEM size + 4 Bytes for ENIN + 4 Bytes for RSSI
 #define ENA_STORAGE_EXPOSURE_INFORMATION_MAX (CONFIG_ENA_STORAGE_EXPOSURE_INFORMATION_MAX) // Maximum number of stored exposure information
 /**
 * @brief structure for TEK
@ -33,7 +34,7 @@ typedef struct __attribute__((__packed__))
 } ena_tek_t;
 /**
- * @brief sturcture for storing a temporary beacon
+ * @brief sturcture for storing a beacons
 */
 typedef struct __attribute__((__packed__))
 {
@ -42,18 +43,19 @@ typedef struct __attribute__((__packed__))
    uint32_t timestamp_first;             // timestamp of first recognition
    uint32_t timestamp_last;              // timestamp of last recognition
    int rssi;                             // average measured RSSI
-} ena_temp_beacon_t;
+} ena_beacon_t;
 /**
- * @brief sturcture for permanently storing a beacon after threshold reached
+ * @brief structure for storing a Exposure Information (combined ExposureInformation, ExposureWindow and ScanInstance from Google API >= 1.5)
 */
 typedef struct __attribute__((__packed__))
 {
-    uint8_t rpi[ENA_KEY_LENGTH];          // received RPI of beacon
+    uint32_t day;            // Day of the exposure, using UTC, encapsulated as the time of the beginning of that day.
-    uint8_t aem[ENA_AEM_METADATA_LENGTH]; // received AEM of beacon
+    int typical_attenuation; // Aggregation of the attenuations of all of a given diagnosis key's beacons received during the scan, in dB.
-    uint32_t timestamp;                   // timestamp of last recognition
+    int min_attenuation;     // Minimum attenuation of all of a given diagnosis key's beacons received during the scan, in dB.
-    int rssi;                             // average measured RSSI
+    int duration_minutes;     //The duration of the exposure in minutes.
-} ena_beacon_t;
+    int report_type;         // Type of diagnosis associated with a key.
 } ena_exposure_information_t;
 /**
 * @brief       read bytes at given address
@ -101,6 +103,29 @@ uint32_t ena_storage_read_last_tek(ena_tek_t *tek);
 */
 void ena_storage_write_tek(ena_tek_t *tek);
 /**
 * @brief       get number of stored exposure information
 * 
 * @return
 *              total number of exposure information stored
 */
 uint32_t ena_storage_exposure_information_count(void);
 /**
 * @brief       get exposure information at given index
 * 
 * @param[in]   index       the index of the exposure information to read
 * @param[out]  exposure_info   pointer to exposure information to write to
 */
 void ena_storage_get_exposure_information(uint32_t index, ena_exposure_information_t *exposure_info);
 /**
 * @brief       store exposure information
 * 
 * @param[in]   exposure_info   new exposure information to store 
 */
 void ena_storage_add_exposure_information(ena_exposure_information_t *exposure_info);
 /**
 * @brief       get number of stored temporary beacons
 * 
@ -113,9 +138,9 @@ uint32_t ena_storage_temp_beacons_count(void);
 * @brief       get temporary beacon at given index
 * 
 * @param[in]   index       the index of the temporary beacon to read
- * @param[out]  beacon   pointer to temporary to write to
+ * @param[out]  beacon   pointer to temporary beacon to write to
 */
-void ena_storage_get_temp_beacon(uint32_t index, ena_temp_beacon_t *beacon);
+void ena_storage_get_temp_beacon(uint32_t index, ena_beacon_t *beacon);
 /**
 * @brief       store temporary beacon
@ -125,7 +150,7 @@ void ena_storage_get_temp_beacon(uint32_t index, ena_temp_beacon_t *beacon);
 * @return 
 *              index of new stored beacon
 */
-uint32_t ena_storage_add_temp_beacon(ena_temp_beacon_t *beacon);
+uint32_t ena_storage_add_temp_beacon(ena_beacon_t *beacon);
 /**
 * @brief       store temporary beacon at given index
@ -133,7 +158,7 @@ uint32_t ena_storage_add_temp_beacon(ena_temp_beacon_t *beacon);
 * @param[in]   index       the index of the temporary beacon to overwrite
 * @param[in]   beacon   temporary beacon to store 
 */
-void ena_storage_set_temp_beacon(uint32_t index, ena_temp_beacon_t *beacon);
+void ena_storage_set_temp_beacon(uint32_t index, ena_beacon_t *beacon);
 /**
 * @brief       remove temporary beacon at given index
@ -180,6 +205,14 @@ void ena_storage_erase(void);
 */
 void ena_storage_erase_tek(void);
 /**
 * @brief       erase all stored exposure information
 * 
 * This function deletes all stored exposure information and resets counter to zero.
 */
 void ena_storage_erase_exposure_information(void);
 /**
 * @brief       erase all stored temporary beacons
 * 
@ -200,7 +233,16 @@ void ena_storage_erase_beacon(void);
 * This function prints all stored TEKs to serial output in
 * the following CSV format: #,enin,tek
 */
-void ena_storage_dump_tek(void);
+void ena_storage_dump_teks(void);
 /**
 * @brief       dump all stored exposure information to serial output
 * 
 * This function prints all stored exposure information to serial output in
 * the following CSV format: #,day,typical_attenuation,min_attenuation,duration_minutes,report_type
 */
 void ena_storage_dump_exposure_information(void);
 /**
 * @brief       dump all stored temporary beacons to serial output
--- a/components/ena/include/ena.h
+++ b/components/ena/include/ena.h
@ -15,6 +15,7 @@
 #define _ena_H_
 #define ENA_LOG "ESP-ENA"                                                                              // TAG for Logging
 #define ENA_RAM (CONFIG_ENA_RAM)                                                                       // change advertising payload and therefore the BT address
 #define ENA_BT_ROTATION_TIMEOUT_INTERVAL (CONFIG_ENA_BT_ROTATION_TIMEOUT_INTERVAL)                     // change advertising payload and therefore the BT address
 #define ENA_BT_RANDOMIZE_ROTATION_TIMEOUT_INTERVAL (CONFIG_ENA_BT_RANDOMIZE_ROTATION_TIMEOUT_INTERVAL) // random intervall change for BT address change
--- a/components/ena/test/export.bin
+++ b/components/ena/test/export.bin
--- a/components/ena/test/export.sig
+++ b/components/ena/test/export.sig
--- a/components/i2c-main/i2c-main.c
+++ b/components/i2c-main/i2c-main.c
@ -31,6 +31,7 @@ void i2c_main_init()
        .master.clk_speed = I2C_CLK_SPEED};
    ESP_ERROR_CHECK(i2c_param_config(I2C_NUM_0, &i2c_config));
    ESP_ERROR_CHECK(i2c_driver_install(I2C_NUM_0, I2C_MODE_MASTER, 0, 0, 0));
    i2c_initialized = true;
 }
 bool i2c_is_initialized()
--- a/components/nanopb/CMakeLists.txt
+++ b/components/nanopb/CMakeLists.txt
@ -0,0 +1,8 @@
 idf_component_register(
    SRCS 
        "pb_common.c"
        "pb_decode.c"
        "pb_encode.c"
        "TemporaryExposureKeyExport.pb.c"
    INCLUDE_DIRS "."
 )
--- a/components/nanopb/TemporaryExposureKeyExport.pb.c
+++ b/components/nanopb/TemporaryExposureKeyExport.pb.c
@ -0,0 +1,19 @@
 /* Automatically generated nanopb constant definitions */
 /* Generated by nanopb-0.4.2 */
 #include "TemporaryExposureKeyExport.pb.h"
 #if PB_PROTO_HEADER_VERSION != 40
 #error Regenerate this file with the current version of nanopb generator.
 #endif
 PB_BIND(TemporaryExposureKeyExport, TemporaryExposureKeyExport, AUTO)
 PB_BIND(SignatureInfo, SignatureInfo, AUTO)
 PB_BIND(TemporaryExposureKey, TemporaryExposureKey, AUTO)
--- a/components/nanopb/TemporaryExposureKeyExport.pb.h
+++ b/components/nanopb/TemporaryExposureKeyExport.pb.h
@ -0,0 +1,147 @@
 /* Automatically generated nanopb header */
 /* Generated by nanopb-0.4.2 */
 #ifndef PB_TEMPORARYEXPOSUREKEYEXPORT_PB_H_INCLUDED
 #define PB_TEMPORARYEXPOSUREKEYEXPORT_PB_H_INCLUDED
 #include <pb.h>
 #if PB_PROTO_HEADER_VERSION != 40
 #error Regenerate this file with the current version of nanopb generator.
 #endif
 #ifdef __cplusplus
 extern "C" {
 #endif
 /* Enum definitions */
 typedef enum _TemporaryExposureKey_ReportType {
    TemporaryExposureKey_ReportType_UNKNOWN = 0,
    TemporaryExposureKey_ReportType_CONFIRMED_TEST = 1,
    TemporaryExposureKey_ReportType_CONFIRMED_CLINICAL_DIAGNOSIS = 2,
    TemporaryExposureKey_ReportType_SELF_REPORT = 3,
    TemporaryExposureKey_ReportType_RECURSIVE = 4,
    TemporaryExposureKey_ReportType_REVOKED = 5
 } TemporaryExposureKey_ReportType;
 /* Struct definitions */
 typedef struct _SignatureInfo {
    pb_callback_t verification_key_version;
    pb_callback_t verification_key_id;
    pb_callback_t signature_algorithm;
 } SignatureInfo;
 typedef struct _TemporaryExposureKey {
    pb_callback_t key_data;
    bool has_transmission_risk_level;
    int32_t transmission_risk_level;
    bool has_rolling_start_interval_number;
    int32_t rolling_start_interval_number;
    bool has_rolling_period;
    int32_t rolling_period;
    bool has_report_type;
    TemporaryExposureKey_ReportType report_type;
    bool has_days_since_onset_of_symptoms;
    int32_t days_since_onset_of_symptoms;
 } TemporaryExposureKey;
 typedef struct _TemporaryExposureKeyExport {
    bool has_start_timestamp;
    uint64_t start_timestamp;
    bool has_end_timestamp;
    uint64_t end_timestamp;
    pb_callback_t region;
    bool has_batch_num;
    int32_t batch_num;
    bool has_batch_size;
    int32_t batch_size;
    pb_callback_t signature_infos;
    pb_callback_t keys;
    pb_callback_t revised_keys;
 } TemporaryExposureKeyExport;
 /* Helper constants for enums */
 #define _TemporaryExposureKey_ReportType_MIN TemporaryExposureKey_ReportType_UNKNOWN
 #define _TemporaryExposureKey_ReportType_MAX TemporaryExposureKey_ReportType_REVOKED
 #define _TemporaryExposureKey_ReportType_ARRAYSIZE ((TemporaryExposureKey_ReportType)(TemporaryExposureKey_ReportType_REVOKED+1))
 /* Initializer values for message structs */
 #define TemporaryExposureKeyExport_init_default  {false, 0, false, 0, {{NULL}, NULL}, false, 0, false, 0, {{NULL}, NULL}, {{NULL}, NULL}, {{NULL}, NULL}}
 #define SignatureInfo_init_default               {{{NULL}, NULL}, {{NULL}, NULL}, {{NULL}, NULL}}
 #define TemporaryExposureKey_init_default        {{{NULL}, NULL}, false, 0, false, 0, false, 144, false, _TemporaryExposureKey_ReportType_MIN, false, 0}
 #define TemporaryExposureKeyExport_init_zero     {false, 0, false, 0, {{NULL}, NULL}, false, 0, false, 0, {{NULL}, NULL}, {{NULL}, NULL}, {{NULL}, NULL}}
 #define SignatureInfo_init_zero                  {{{NULL}, NULL}, {{NULL}, NULL}, {{NULL}, NULL}}
 #define TemporaryExposureKey_init_zero           {{{NULL}, NULL}, false, 0, false, 0, false, 0, false, _TemporaryExposureKey_ReportType_MIN, false, 0}
 /* Field tags (for use in manual encoding/decoding) */
 #define SignatureInfo_verification_key_version_tag 3
 #define SignatureInfo_verification_key_id_tag    4
 #define SignatureInfo_signature_algorithm_tag    5
 #define TemporaryExposureKey_key_data_tag        1
 #define TemporaryExposureKey_transmission_risk_level_tag 2
 #define TemporaryExposureKey_rolling_start_interval_number_tag 3
 #define TemporaryExposureKey_rolling_period_tag  4
 #define TemporaryExposureKey_report_type_tag     5
 #define TemporaryExposureKey_days_since_onset_of_symptoms_tag 6
 #define TemporaryExposureKeyExport_start_timestamp_tag 1
 #define TemporaryExposureKeyExport_end_timestamp_tag 2
 #define TemporaryExposureKeyExport_region_tag    3
 #define TemporaryExposureKeyExport_batch_num_tag 4
 #define TemporaryExposureKeyExport_batch_size_tag 5
 #define TemporaryExposureKeyExport_signature_infos_tag 6
 #define TemporaryExposureKeyExport_keys_tag      7
 #define TemporaryExposureKeyExport_revised_keys_tag 8
 /* Struct field encoding specification for nanopb */
 #define TemporaryExposureKeyExport_FIELDLIST(X, a) \
 X(a, STATIC,   OPTIONAL, FIXED64,  start_timestamp,   1) \
 X(a, STATIC,   OPTIONAL, FIXED64,  end_timestamp,     2) \
 X(a, CALLBACK, OPTIONAL, STRING,   region,            3) \
 X(a, STATIC,   OPTIONAL, INT32,    batch_num,         4) \
 X(a, STATIC,   OPTIONAL, INT32,    batch_size,        5) \
 X(a, CALLBACK, REPEATED, MESSAGE,  signature_infos,   6) \
 X(a, CALLBACK, REPEATED, MESSAGE,  keys,              7) \
 X(a, CALLBACK, REPEATED, MESSAGE,  revised_keys,      8)
 #define TemporaryExposureKeyExport_CALLBACK pb_default_field_callback
 #define TemporaryExposureKeyExport_DEFAULT NULL
 #define TemporaryExposureKeyExport_signature_infos_MSGTYPE SignatureInfo
 #define TemporaryExposureKeyExport_keys_MSGTYPE TemporaryExposureKey
 #define TemporaryExposureKeyExport_revised_keys_MSGTYPE TemporaryExposureKey
 #define SignatureInfo_FIELDLIST(X, a) \
 X(a, CALLBACK, OPTIONAL, STRING,   verification_key_version,   3) \
 X(a, CALLBACK, OPTIONAL, STRING,   verification_key_id,   4) \
 X(a, CALLBACK, OPTIONAL, STRING,   signature_algorithm,   5)
 #define SignatureInfo_CALLBACK pb_default_field_callback
 #define SignatureInfo_DEFAULT NULL
 #define TemporaryExposureKey_FIELDLIST(X, a) \
 X(a, CALLBACK, OPTIONAL, BYTES,    key_data,          1) \
 X(a, STATIC,   OPTIONAL, INT32,    transmission_risk_level,   2) \
 X(a, STATIC,   OPTIONAL, INT32,    rolling_start_interval_number,   3) \
 X(a, STATIC,   OPTIONAL, INT32,    rolling_period,    4) \
 X(a, STATIC,   OPTIONAL, UENUM,    report_type,       5) \
 X(a, STATIC,   OPTIONAL, SINT32,   days_since_onset_of_symptoms,   6)
 #define TemporaryExposureKey_CALLBACK pb_default_field_callback
 #define TemporaryExposureKey_DEFAULT (const pb_byte_t*)"\x20\x90\x01\x00"
 extern const pb_msgdesc_t TemporaryExposureKeyExport_msg;
 extern const pb_msgdesc_t SignatureInfo_msg;
 extern const pb_msgdesc_t TemporaryExposureKey_msg;
 /* Defines for backwards compatibility with code written before nanopb-0.4.0 */
 #define TemporaryExposureKeyExport_fields &TemporaryExposureKeyExport_msg
 #define SignatureInfo_fields &SignatureInfo_msg
 #define TemporaryExposureKey_fields &TemporaryExposureKey_msg
 /* Maximum encoded size of messages (where known) */
 /* TemporaryExposureKeyExport_size depends on runtime parameters */
 /* SignatureInfo_size depends on runtime parameters */
 /* TemporaryExposureKey_size depends on runtime parameters */
 #ifdef __cplusplus
 } /* extern "C" */
 #endif
 #endif
--- a/components/nanopb/TemporaryExposureKeyExport.proto
+++ b/components/nanopb/TemporaryExposureKeyExport.proto
@ -0,0 +1,65 @@
 syntax = "proto2";
 message TemporaryExposureKeyExport {
  // Time window of keys in this batch based on arrival to server, in UTC seconds.
  optional fixed64 start_timestamp = 1;
  optional fixed64 end_timestamp = 2;
  // Region for which these keys came from, such as country.
  optional string region = 3;
  // For example, file 2 in batch size of 10. Ordinal, 1-based numbering.
  // Note: Not yet supported on iOS.
  optional int32 batch_num = 4;
  optional int32 batch_size = 5;
  // Information about associated signatures
  repeated SignatureInfo signature_infos = 6;
  // The TemporaryExposureKeys for initial release of keys.
  // Keys should be included in this list for initial release,
  // whereas revised or revoked keys should go in revised_keys.
  repeated TemporaryExposureKey keys = 7;
  // TemporaryExposureKeys that have changed status.
  // Keys should be included in this list if they have changed status
  // or have been revoked.
  repeated TemporaryExposureKey revised_keys = 8;
 }
 message SignatureInfo {
  // The first two fields have been deprecated
  reserved 1, 2;
  reserved "app_bundle_id", "android_package";
  // Key version for rollovers
  // Must be in character class [a-zA-Z0-9_]. For example, 'v1'
  optional string verification_key_version = 3;
  // Alias with which to identify public key to be used for verification
  // Must be in character class [a-zA-Z0-9_.]
  // For cross-compatibility with Apple, you can use your region's three-digit
  // mobile country code (MCC). If your region has more than one MCC, choose the
  // one that Apple has configured.
  optional string verification_key_id = 4;
  // ASN.1 OID for Algorithm Identifier. For example, `1.2.840.10045.4.3.2'
  optional string signature_algorithm = 5;
 }
 message TemporaryExposureKey {
  // Key of infected user
  optional bytes key_data = 1;
  // Varying risk associated with a key depending on diagnosis method
  optional int32 transmission_risk_level = 2 [deprecated = true];
  // The interval number since epoch for which a key starts
  optional int32 rolling_start_interval_number = 3;
  // Increments of 10 minutes describing how long a key is valid
  optional int32 rolling_period = 4
  [default = 144]; // defaults to 24 hours
  // Data type representing why this key was published.
  enum ReportType {
    UNKNOWN = 0;  // Never returned by the client API.
    CONFIRMED_TEST = 1;
    CONFIRMED_CLINICAL_DIAGNOSIS = 2;
    SELF_REPORT = 3;
    RECURSIVE = 4;  // Reserved for future use.
    REVOKED = 5;  // Used to revoke a key, never returned by client API.
  }
  // Type of diagnosis associated with a key.
  optional ReportType report_type = 5;
  // Number of days elapsed between symptom onset and the TEK being used.
  // E.g. 2 means TEK is 2 days after onset of symptoms.
  optional sint32 days_since_onset_of_symptoms = 6;
 }
--- a/components/nanopb/pb.h
+++ b/components/nanopb/pb.h
@ -0,0 +1,868 @@
 /* Common parts of the nanopb library. Most of these are quite low-level
 * stuff. For the high-level interface, see pb_encode.h and pb_decode.h.
 */
 #ifndef PB_H_INCLUDED
 #define PB_H_INCLUDED
 /*****************************************************************
 * Nanopb compilation time options. You can change these here by *
 * uncommenting the lines, or on the compiler command line.      *
 *****************************************************************/
 /* Enable support for dynamically allocated fields */
 /* #define PB_ENABLE_MALLOC 1 */
 /* Define this if your CPU / compiler combination does not support
 * unaligned memory access to packed structures. */
 /* #define PB_NO_PACKED_STRUCTS 1 */
 /* Increase the number of required fields that are tracked.
 * A compiler warning will tell if you need this. */
 /* #define PB_MAX_REQUIRED_FIELDS 256 */
 /* Add support for tag numbers > 65536 and fields larger than 65536 bytes. */
 /* #define PB_FIELD_32BIT 1 */
 /* Disable support for error messages in order to save some code space. */
 /* #define PB_NO_ERRMSG 1 */
 /* Disable support for custom streams (support only memory buffers). */
 /* #define PB_BUFFER_ONLY 1 */
 /* Disable support for 64-bit datatypes, for compilers without int64_t
   or to save some code space. */
 /* #define PB_WITHOUT_64BIT 1 */
 /* Don't encode scalar arrays as packed. This is only to be used when
 * the decoder on the receiving side cannot process packed scalar arrays.
 * Such example is older protobuf.js. */
 /* #define PB_ENCODE_ARRAYS_UNPACKED 1 */
 /* Enable conversion of doubles to floats for platforms that do not
 * support 64-bit doubles. Most commonly AVR. */
 /* #define PB_CONVERT_DOUBLE_FLOAT 1 */
 /* Check whether incoming strings are valid UTF-8 sequences. Slows down
 * the string processing slightly and slightly increases code size. */
 /* #define PB_VALIDATE_UTF8 1 */
 /******************************************************************
 * You usually don't need to change anything below this line.     *
 * Feel free to look around and use the defined macros, though.   *
 ******************************************************************/
 /* Version of the nanopb library. Just in case you want to check it in
 * your own program. */
 #define NANOPB_VERSION nanopb-0.4.2
 /* Include all the system headers needed by nanopb. You will need the
 * definitions of the following:
 * - strlen, memcpy, memset functions
 * - [u]int_least8_t, uint_fast8_t, [u]int_least16_t, [u]int32_t, [u]int64_t
 * - size_t
 * - bool
 *
 * If you don't have the standard header files, you can instead provide
 * a custom header that defines or includes all this. In that case,
 * define PB_SYSTEM_HEADER to the path of this file.
 */
 #ifdef PB_SYSTEM_HEADER
 #include PB_SYSTEM_HEADER
 #else
 #include <stdint.h>
 #include <stddef.h>
 #include <stdbool.h>
 #include <string.h>
 #include <limits.h>
 #ifdef PB_ENABLE_MALLOC
 #include <stdlib.h>
 #endif
 #endif
 #ifdef __cplusplus
 extern "C" {
 #endif
 /* Macro for defining packed structures (compiler dependent).
 * This just reduces memory requirements, but is not required.
 */
 #if defined(PB_NO_PACKED_STRUCTS)
    /* Disable struct packing */
 #   define PB_PACKED_STRUCT_START
 #   define PB_PACKED_STRUCT_END
 #   define pb_packed
 #elif defined(__GNUC__) || defined(__clang__)
    /* For GCC and clang */
 #   define PB_PACKED_STRUCT_START
 #   define PB_PACKED_STRUCT_END
 #   define pb_packed __attribute__((packed))
 #elif defined(__ICCARM__) || defined(__CC_ARM)
    /* For IAR ARM and Keil MDK-ARM compilers */
 #   define PB_PACKED_STRUCT_START _Pragma("pack(push, 1)")
 #   define PB_PACKED_STRUCT_END _Pragma("pack(pop)")
 #   define pb_packed
 #elif defined(_MSC_VER) && (_MSC_VER >= 1500)
    /* For Microsoft Visual C++ */
 #   define PB_PACKED_STRUCT_START __pragma(pack(push, 1))
 #   define PB_PACKED_STRUCT_END __pragma(pack(pop))
 #   define pb_packed
 #else
    /* Unknown compiler */
 #   define PB_PACKED_STRUCT_START
 #   define PB_PACKED_STRUCT_END
 #   define pb_packed
 #endif
 /* Handly macro for suppressing unreferenced-parameter compiler warnings. */
 #ifndef PB_UNUSED
 #define PB_UNUSED(x) (void)(x)
 #endif
 /* Harvard-architecture processors may need special attributes for storing
 * field information in program memory. */
 #ifndef PB_PROGMEM
 #ifdef __AVR__
 #include <avr/pgmspace.h>
 #define PB_PROGMEM             PROGMEM
 #define PB_PROGMEM_READU32(x)  pgm_read_dword(&x)
 #else
 #define PB_PROGMEM
 #define PB_PROGMEM_READU32(x)  (x)
 #endif
 #endif
 /* Compile-time assertion, used for checking compatible compilation options.
 * If this does not work properly on your compiler, use
 * #define PB_NO_STATIC_ASSERT to disable it.
 *
 * But before doing that, check carefully the error message / place where it
 * comes from to see if the error has a real cause. Unfortunately the error
 * message is not always very clear to read, but you can see the reason better
 * in the place where the PB_STATIC_ASSERT macro was called.
 */
 #ifndef PB_NO_STATIC_ASSERT
 #  ifndef PB_STATIC_ASSERT
 #    if defined(__STDC_VERSION__) && __STDC_VERSION__ >= 201112L
       /* C11 standard _Static_assert mechanism */
 #      define PB_STATIC_ASSERT(COND,MSG) _Static_assert(COND,#MSG);
 #    else
       /* Classic negative-size-array static assert mechanism */
 #      define PB_STATIC_ASSERT(COND,MSG) typedef char PB_STATIC_ASSERT_MSG(MSG, __LINE__, __COUNTER__)[(COND)?1:-1];
 #      define PB_STATIC_ASSERT_MSG(MSG, LINE, COUNTER) PB_STATIC_ASSERT_MSG_(MSG, LINE, COUNTER)
 #      define PB_STATIC_ASSERT_MSG_(MSG, LINE, COUNTER) pb_static_assertion_##MSG##_##LINE##_##COUNTER
 #    endif
 #  endif
 #else
   /* Static asserts disabled by PB_NO_STATIC_ASSERT */
 #  define PB_STATIC_ASSERT(COND,MSG)
 #endif
 /* Number of required fields to keep track of. */
 #ifndef PB_MAX_REQUIRED_FIELDS
 #define PB_MAX_REQUIRED_FIELDS 64
 #endif
 #if PB_MAX_REQUIRED_FIELDS < 64
 #error You should not lower PB_MAX_REQUIRED_FIELDS from the default value (64).
 #endif
 #ifdef PB_WITHOUT_64BIT
 #ifdef PB_CONVERT_DOUBLE_FLOAT
 /* Cannot use doubles without 64-bit types */
 #undef PB_CONVERT_DOUBLE_FLOAT
 #endif
 #endif
 /* List of possible field types. These are used in the autogenerated code.
 * Least-significant 4 bits tell the scalar type
 * Most-significant 4 bits specify repeated/required/packed etc.
 */
 typedef uint_least8_t pb_type_t;
 /**** Field data types ****/
 /* Numeric types */
 #define PB_LTYPE_BOOL    0x00U /* bool */
 #define PB_LTYPE_VARINT  0x01U /* int32, int64, enum, bool */
 #define PB_LTYPE_UVARINT 0x02U /* uint32, uint64 */
 #define PB_LTYPE_SVARINT 0x03U /* sint32, sint64 */
 #define PB_LTYPE_FIXED32 0x04U /* fixed32, sfixed32, float */
 #define PB_LTYPE_FIXED64 0x05U /* fixed64, sfixed64, double */
 /* Marker for last packable field type. */
 #define PB_LTYPE_LAST_PACKABLE 0x05U
 /* Byte array with pre-allocated buffer.
 * data_size is the length of the allocated PB_BYTES_ARRAY structure. */
 #define PB_LTYPE_BYTES 0x06U
 /* String with pre-allocated buffer.
 * data_size is the maximum length. */
 #define PB_LTYPE_STRING 0x07U
 /* Submessage
 * submsg_fields is pointer to field descriptions */
 #define PB_LTYPE_SUBMESSAGE 0x08U
 /* Submessage with pre-decoding callback
 * The pre-decoding callback is stored as pb_callback_t right before pSize.
 * submsg_fields is pointer to field descriptions */
 #define PB_LTYPE_SUBMSG_W_CB 0x09U
 /* Extension pseudo-field
 * The field contains a pointer to pb_extension_t */
 #define PB_LTYPE_EXTENSION 0x0AU
 /* Byte array with inline, pre-allocated byffer.
 * data_size is the length of the inline, allocated buffer.
 * This differs from PB_LTYPE_BYTES by defining the element as
 * pb_byte_t[data_size] rather than pb_bytes_array_t. */
 #define PB_LTYPE_FIXED_LENGTH_BYTES 0x0BU
 /* Number of declared LTYPES */
 #define PB_LTYPES_COUNT 0x0CU
 #define PB_LTYPE_MASK 0x0FU
 /**** Field repetition rules ****/
 #define PB_HTYPE_REQUIRED 0x00U
 #define PB_HTYPE_OPTIONAL 0x10U
 #define PB_HTYPE_SINGULAR 0x10U
 #define PB_HTYPE_REPEATED 0x20U
 #define PB_HTYPE_FIXARRAY 0x20U
 #define PB_HTYPE_ONEOF    0x30U
 #define PB_HTYPE_MASK     0x30U
 /**** Field allocation types ****/
 #define PB_ATYPE_STATIC   0x00U
 #define PB_ATYPE_POINTER  0x80U
 #define PB_ATYPE_CALLBACK 0x40U
 #define PB_ATYPE_MASK     0xC0U
 #define PB_ATYPE(x) ((x) & PB_ATYPE_MASK)
 #define PB_HTYPE(x) ((x) & PB_HTYPE_MASK)
 #define PB_LTYPE(x) ((x) & PB_LTYPE_MASK)
 #define PB_LTYPE_IS_SUBMSG(x) (PB_LTYPE(x) == PB_LTYPE_SUBMESSAGE || \
                               PB_LTYPE(x) == PB_LTYPE_SUBMSG_W_CB)
 /* Data type used for storing sizes of struct fields
 * and array counts.
 */
 #if defined(PB_FIELD_32BIT)
    typedef uint32_t pb_size_t;
    typedef int32_t pb_ssize_t;
 #else
    typedef uint_least16_t pb_size_t;
    typedef int_least16_t pb_ssize_t;
 #endif
 #define PB_SIZE_MAX ((pb_size_t)-1)
 /* Data type for storing encoded data and other byte streams.
 * This typedef exists to support platforms where uint8_t does not exist.
 * You can regard it as equivalent on uint8_t on other platforms.
 */
 typedef uint_least8_t pb_byte_t;
 /* Forward declaration of struct types */
 typedef struct pb_istream_s pb_istream_t;
 typedef struct pb_ostream_s pb_ostream_t;
 typedef struct pb_field_iter_s pb_field_iter_t;
 /* This structure is used in auto-generated constants
 * to specify struct fields.
 */
 PB_PACKED_STRUCT_START
 typedef struct pb_msgdesc_s pb_msgdesc_t;
 struct pb_msgdesc_s {
    pb_size_t field_count;
    const uint32_t *field_info;
    const pb_msgdesc_t * const * submsg_info;
    const pb_byte_t *default_value;
    bool (*field_callback)(pb_istream_t *istream, pb_ostream_t *ostream, const pb_field_iter_t *field);
 } pb_packed;
 PB_PACKED_STRUCT_END
 /* Iterator for message descriptor */
 struct pb_field_iter_s {
    const pb_msgdesc_t *descriptor;  /* Pointer to message descriptor constant */
    void *message;                   /* Pointer to start of the structure */
    pb_size_t index;                 /* Index of the field */
    pb_size_t field_info_index;      /* Index to descriptor->field_info array */
    pb_size_t required_field_index;  /* Index that counts only the required fields */
    pb_size_t submessage_index;      /* Index that counts only submessages */
    pb_size_t tag;                   /* Tag of current field */
    pb_size_t data_size;             /* sizeof() of a single item */
    pb_size_t array_size;            /* Number of array entries */
    pb_type_t type;                  /* Type of current field */
    void *pField;                    /* Pointer to current field in struct */
    void *pData;                     /* Pointer to current data contents. Different than pField for arrays and pointers. */
    void *pSize;                     /* Pointer to count/has field */
    const pb_msgdesc_t *submsg_desc; /* For submessage fields, pointer to field descriptor for the submessage. */
 };
 /* For compatibility with legacy code */
 typedef pb_field_iter_t pb_field_t;
 /* Make sure that the standard integer types are of the expected sizes.
 * Otherwise fixed32/fixed64 fields can break.
 *
 * If you get errors here, it probably means that your stdint.h is not
 * correct for your platform.
 */
 #ifndef PB_WITHOUT_64BIT
 PB_STATIC_ASSERT(sizeof(int64_t) == 2 * sizeof(int32_t), INT64_T_WRONG_SIZE)
 PB_STATIC_ASSERT(sizeof(uint64_t) == 2 * sizeof(uint32_t), UINT64_T_WRONG_SIZE)
 #endif
 /* This structure is used for 'bytes' arrays.
 * It has the number of bytes in the beginning, and after that an array.
 * Note that actual structs used will have a different length of bytes array.
 */
 #define PB_BYTES_ARRAY_T(n) struct { pb_size_t size; pb_byte_t bytes[n]; }
 #define PB_BYTES_ARRAY_T_ALLOCSIZE(n) ((size_t)n + offsetof(pb_bytes_array_t, bytes))
 struct pb_bytes_array_s {
    pb_size_t size;
    pb_byte_t bytes[1];
 };
 typedef struct pb_bytes_array_s pb_bytes_array_t;
 /* This structure is used for giving the callback function.
 * It is stored in the message structure and filled in by the method that
 * calls pb_decode.
 *
 * The decoding callback will be given a limited-length stream
 * If the wire type was string, the length is the length of the string.
 * If the wire type was a varint/fixed32/fixed64, the length is the length
 * of the actual value.
 * The function may be called multiple times (especially for repeated types,
 * but also otherwise if the message happens to contain the field multiple
 * times.)
 *
 * The encoding callback will receive the actual output stream.
 * It should write all the data in one call, including the field tag and
 * wire type. It can write multiple fields.
 *
 * The callback can be null if you want to skip a field.
 */
 typedef struct pb_callback_s pb_callback_t;
 struct pb_callback_s {
    /* Callback functions receive a pointer to the arg field.
     * You can access the value of the field as *arg, and modify it if needed.
     */
    union {
        bool (*decode)(pb_istream_t *stream, const pb_field_t *field, void **arg);
        bool (*encode)(pb_ostream_t *stream, const pb_field_t *field, void * const *arg);
    } funcs;
    /* Free arg for use by callback */
    void *arg;
 };
 extern bool pb_default_field_callback(pb_istream_t *istream, pb_ostream_t *ostream, const pb_field_t *field);
 /* Wire types. Library user needs these only in encoder callbacks. */
 typedef enum {
    PB_WT_VARINT = 0,
    PB_WT_64BIT  = 1,
    PB_WT_STRING = 2,
    PB_WT_32BIT  = 5
 } pb_wire_type_t;
 /* Structure for defining the handling of unknown/extension fields.
 * Usually the pb_extension_type_t structure is automatically generated,
 * while the pb_extension_t structure is created by the user. However,
 * if you want to catch all unknown fields, you can also create a custom
 * pb_extension_type_t with your own callback.
 */
 typedef struct pb_extension_type_s pb_extension_type_t;
 typedef struct pb_extension_s pb_extension_t;
 struct pb_extension_type_s {
    /* Called for each unknown field in the message.
     * If you handle the field, read off all of its data and return true.
     * If you do not handle the field, do not read anything and return true.
     * If you run into an error, return false.
     * Set to NULL for default handler.
     */
    bool (*decode)(pb_istream_t *stream, pb_extension_t *extension,
                   uint32_t tag, pb_wire_type_t wire_type);
    /* Called once after all regular fields have been encoded.
     * If you have something to write, do so and return true.
     * If you do not have anything to write, just return true.
     * If you run into an error, return false.
     * Set to NULL for default handler.
     */
    bool (*encode)(pb_ostream_t *stream, const pb_extension_t *extension);
    /* Free field for use by the callback. */
    const void *arg;
 };
 struct pb_extension_s {
    /* Type describing the extension field. Usually you'll initialize
     * this to a pointer to the automatically generated structure. */
    const pb_extension_type_t *type;
    /* Destination for the decoded data. This must match the datatype
     * of the extension field. */
    void *dest;
    /* Pointer to the next extension handler, or NULL.
     * If this extension does not match a field, the next handler is
     * automatically called. */
    pb_extension_t *next;
    /* The decoder sets this to true if the extension was found.
     * Ignored for encoding. */
    bool found;
 };
 #define pb_extension_init_zero {NULL,NULL,NULL,false}
 /* Memory allocation functions to use. You can define pb_realloc and
 * pb_free to custom functions if you want. */
 #ifdef PB_ENABLE_MALLOC
 #   ifndef pb_realloc
 #       define pb_realloc(ptr, size) realloc(ptr, size)
 #   endif
 #   ifndef pb_free
 #       define pb_free(ptr) free(ptr)
 #   endif
 #endif
 /* This is used to inform about need to regenerate .pb.h/.pb.c files. */
 #define PB_PROTO_HEADER_VERSION 40
 /* These macros are used to declare pb_field_t's in the constant array. */
 /* Size of a structure member, in bytes. */
 #define pb_membersize(st, m) (sizeof ((st*)0)->m)
 /* Number of entries in an array. */
 #define pb_arraysize(st, m) (pb_membersize(st, m) / pb_membersize(st, m[0]))
 /* Delta from start of one member to the start of another member. */
 #define pb_delta(st, m1, m2) ((int)offsetof(st, m1) - (int)offsetof(st, m2))
 /* Force expansion of macro value */
 #define PB_EXPAND(x) x
 /* Binding of a message field set into a specific structure */
 #define PB_BIND(msgname, structname, width) \
    const uint32_t structname ## _field_info[] PB_PROGMEM = \
    { \
        msgname ## _FIELDLIST(PB_GEN_FIELD_INFO_ ## width, structname) \
        0 \
    }; \
    const pb_msgdesc_t* const structname ## _submsg_info[] = \
    { \
        msgname ## _FIELDLIST(PB_GEN_SUBMSG_INFO, structname) \
        NULL \
    }; \
    const pb_msgdesc_t structname ## _msg = \
    { \
       0 msgname ## _FIELDLIST(PB_GEN_FIELD_COUNT, structname), \
       structname ## _field_info, \
       structname ## _submsg_info, \
       msgname ## _DEFAULT, \
       msgname ## _CALLBACK, \
    }; \
    msgname ## _FIELDLIST(PB_GEN_FIELD_INFO_ASSERT_ ## width, structname)
 #define PB_GEN_FIELD_COUNT(structname, atype, htype, ltype, fieldname, tag) +1
 /* X-macro for generating the entries in struct_field_info[] array. */
 #define PB_GEN_FIELD_INFO_1(structname, atype, htype, ltype, fieldname, tag) \
    PB_FIELDINFO_1(tag, PB_ATYPE_ ## atype | PB_HTYPE_ ## htype | PB_LTYPE_MAP_ ## ltype, \
                   PB_DATA_OFFSET_ ## atype(_PB_HTYPE_ ## htype, structname, fieldname), \
                   PB_DATA_SIZE_ ## atype(_PB_HTYPE_ ## htype, structname, fieldname), \
                   PB_SIZE_OFFSET_ ## atype(_PB_HTYPE_ ## htype, structname, fieldname), \
                   PB_ARRAY_SIZE_ ## atype(_PB_HTYPE_ ## htype, structname, fieldname))
 #define PB_GEN_FIELD_INFO_2(structname, atype, htype, ltype, fieldname, tag) \
    PB_FIELDINFO_2(tag, PB_ATYPE_ ## atype | PB_HTYPE_ ## htype | PB_LTYPE_MAP_ ## ltype, \
                   PB_DATA_OFFSET_ ## atype(_PB_HTYPE_ ## htype, structname, fieldname), \
                   PB_DATA_SIZE_ ## atype(_PB_HTYPE_ ## htype, structname, fieldname), \
                   PB_SIZE_OFFSET_ ## atype(_PB_HTYPE_ ## htype, structname, fieldname), \
                   PB_ARRAY_SIZE_ ## atype(_PB_HTYPE_ ## htype, structname, fieldname))
 #define PB_GEN_FIELD_INFO_4(structname, atype, htype, ltype, fieldname, tag) \
    PB_FIELDINFO_4(tag, PB_ATYPE_ ## atype | PB_HTYPE_ ## htype | PB_LTYPE_MAP_ ## ltype, \
                   PB_DATA_OFFSET_ ## atype(_PB_HTYPE_ ## htype, structname, fieldname), \
                   PB_DATA_SIZE_ ## atype(_PB_HTYPE_ ## htype, structname, fieldname), \
                   PB_SIZE_OFFSET_ ## atype(_PB_HTYPE_ ## htype, structname, fieldname), \
                   PB_ARRAY_SIZE_ ## atype(_PB_HTYPE_ ## htype, structname, fieldname))
 #define PB_GEN_FIELD_INFO_8(structname, atype, htype, ltype, fieldname, tag) \
    PB_FIELDINFO_8(tag, PB_ATYPE_ ## atype | PB_HTYPE_ ## htype | PB_LTYPE_MAP_ ## ltype, \
                   PB_DATA_OFFSET_ ## atype(_PB_HTYPE_ ## htype, structname, fieldname), \
                   PB_DATA_SIZE_ ## atype(_PB_HTYPE_ ## htype, structname, fieldname), \
                   PB_SIZE_OFFSET_ ## atype(_PB_HTYPE_ ## htype, structname, fieldname), \
                   PB_ARRAY_SIZE_ ## atype(_PB_HTYPE_ ## htype, structname, fieldname))
 #define PB_GEN_FIELD_INFO_AUTO(structname, atype, htype, ltype, fieldname, tag) \
    PB_FIELDINFO_AUTO2(PB_FIELDINFO_WIDTH_AUTO(_PB_ATYPE_ ## atype, _PB_HTYPE_ ## htype, _PB_LTYPE_ ## ltype), \
                   tag, PB_ATYPE_ ## atype | PB_HTYPE_ ## htype | PB_LTYPE_MAP_ ## ltype, \
                   PB_DATA_OFFSET_ ## atype(_PB_HTYPE_ ## htype, structname, fieldname), \
                   PB_DATA_SIZE_ ## atype(_PB_HTYPE_ ## htype, structname, fieldname), \
                   PB_SIZE_OFFSET_ ## atype(_PB_HTYPE_ ## htype, structname, fieldname), \
                   PB_ARRAY_SIZE_ ## atype(_PB_HTYPE_ ## htype, structname, fieldname))
 #define PB_FIELDINFO_AUTO2(width, tag, type, data_offset, data_size, size_offset, array_size) \
    PB_FIELDINFO_AUTO3(width, tag, type, data_offset, data_size, size_offset, array_size)
 #define PB_FIELDINFO_AUTO3(width, tag, type, data_offset, data_size, size_offset, array_size) \
    PB_FIELDINFO_ ## width(tag, type, data_offset, data_size, size_offset, array_size)
 /* X-macro for generating asserts that entries fit in struct_field_info[] array.
 * The structure of macros here must match the structure above in PB_GEN_FIELD_INFO_x(),
 * but it is not easily reused because of how macro substitutions work. */
 #define PB_GEN_FIELD_INFO_ASSERT_1(structname, atype, htype, ltype, fieldname, tag) \
    PB_FIELDINFO_ASSERT_1(tag, PB_ATYPE_ ## atype | PB_HTYPE_ ## htype | PB_LTYPE_MAP_ ## ltype, \
                   PB_DATA_OFFSET_ ## atype(_PB_HTYPE_ ## htype, structname, fieldname), \
                   PB_DATA_SIZE_ ## atype(_PB_HTYPE_ ## htype, structname, fieldname), \
                   PB_SIZE_OFFSET_ ## atype(_PB_HTYPE_ ## htype, structname, fieldname), \
                   PB_ARRAY_SIZE_ ## atype(_PB_HTYPE_ ## htype, structname, fieldname))
 #define PB_GEN_FIELD_INFO_ASSERT_2(structname, atype, htype, ltype, fieldname, tag) \
    PB_FIELDINFO_ASSERT_2(tag, PB_ATYPE_ ## atype | PB_HTYPE_ ## htype | PB_LTYPE_MAP_ ## ltype, \
                   PB_DATA_OFFSET_ ## atype(_PB_HTYPE_ ## htype, structname, fieldname), \
                   PB_DATA_SIZE_ ## atype(_PB_HTYPE_ ## htype, structname, fieldname), \
                   PB_SIZE_OFFSET_ ## atype(_PB_HTYPE_ ## htype, structname, fieldname), \
                   PB_ARRAY_SIZE_ ## atype(_PB_HTYPE_ ## htype, structname, fieldname))
 #define PB_GEN_FIELD_INFO_ASSERT_4(structname, atype, htype, ltype, fieldname, tag) \
    PB_FIELDINFO_ASSERT_4(tag, PB_ATYPE_ ## atype | PB_HTYPE_ ## htype | PB_LTYPE_MAP_ ## ltype, \
                   PB_DATA_OFFSET_ ## atype(_PB_HTYPE_ ## htype, structname, fieldname), \
                   PB_DATA_SIZE_ ## atype(_PB_HTYPE_ ## htype, structname, fieldname), \
                   PB_SIZE_OFFSET_ ## atype(_PB_HTYPE_ ## htype, structname, fieldname), \
                   PB_ARRAY_SIZE_ ## atype(_PB_HTYPE_ ## htype, structname, fieldname))
 #define PB_GEN_FIELD_INFO_ASSERT_8(structname, atype, htype, ltype, fieldname, tag) \
    PB_FIELDINFO_ASSERT_8(tag, PB_ATYPE_ ## atype | PB_HTYPE_ ## htype | PB_LTYPE_MAP_ ## ltype, \
                   PB_DATA_OFFSET_ ## atype(_PB_HTYPE_ ## htype, structname, fieldname), \
                   PB_DATA_SIZE_ ## atype(_PB_HTYPE_ ## htype, structname, fieldname), \
                   PB_SIZE_OFFSET_ ## atype(_PB_HTYPE_ ## htype, structname, fieldname), \
                   PB_ARRAY_SIZE_ ## atype(_PB_HTYPE_ ## htype, structname, fieldname))
 #define PB_GEN_FIELD_INFO_ASSERT_AUTO(structname, atype, htype, ltype, fieldname, tag) \
    PB_FIELDINFO_ASSERT_AUTO2(PB_FIELDINFO_WIDTH_AUTO(_PB_ATYPE_ ## atype, _PB_HTYPE_ ## htype, _PB_LTYPE_ ## ltype), \
                   tag, PB_ATYPE_ ## atype | PB_HTYPE_ ## htype | PB_LTYPE_MAP_ ## ltype, \
                   PB_DATA_OFFSET_ ## atype(_PB_HTYPE_ ## htype, structname, fieldname), \
                   PB_DATA_SIZE_ ## atype(_PB_HTYPE_ ## htype, structname, fieldname), \
                   PB_SIZE_OFFSET_ ## atype(_PB_HTYPE_ ## htype, structname, fieldname), \
                   PB_ARRAY_SIZE_ ## atype(_PB_HTYPE_ ## htype, structname, fieldname))
 #define PB_FIELDINFO_ASSERT_AUTO2(width, tag, type, data_offset, data_size, size_offset, array_size) \
    PB_FIELDINFO_ASSERT_AUTO3(width, tag, type, data_offset, data_size, size_offset, array_size)
 #define PB_FIELDINFO_ASSERT_AUTO3(width, tag, type, data_offset, data_size, size_offset, array_size) \
    PB_FIELDINFO_ASSERT_ ## width(tag, type, data_offset, data_size, size_offset, array_size)
 #define PB_DATA_OFFSET_STATIC(htype, structname, fieldname) PB_DO ## htype(structname, fieldname)
 #define PB_DATA_OFFSET_POINTER(htype, structname, fieldname) PB_DO ## htype(structname, fieldname)
 #define PB_DATA_OFFSET_CALLBACK(htype, structname, fieldname) PB_DO ## htype(structname, fieldname)
 #define PB_DO_PB_HTYPE_REQUIRED(structname, fieldname) offsetof(structname, fieldname)
 #define PB_DO_PB_HTYPE_SINGULAR(structname, fieldname) offsetof(structname, fieldname)
 #define PB_DO_PB_HTYPE_ONEOF(structname, fieldname) offsetof(structname, PB_ONEOF_NAME(FULL, fieldname))
 #define PB_DO_PB_HTYPE_OPTIONAL(structname, fieldname) offsetof(structname, fieldname)
 #define PB_DO_PB_HTYPE_REPEATED(structname, fieldname) offsetof(structname, fieldname)
 #define PB_DO_PB_HTYPE_FIXARRAY(structname, fieldname) offsetof(structname, fieldname)
 #define PB_SIZE_OFFSET_STATIC(htype, structname, fieldname) PB_SO ## htype(structname, fieldname)
 #define PB_SIZE_OFFSET_POINTER(htype, structname, fieldname) PB_SO_PTR ## htype(structname, fieldname)
 #define PB_SIZE_OFFSET_CALLBACK(htype, structname, fieldname) PB_SO_CB ## htype(structname, fieldname)
 #define PB_SO_PB_HTYPE_REQUIRED(structname, fieldname) 0
 #define PB_SO_PB_HTYPE_SINGULAR(structname, fieldname) 0
 #define PB_SO_PB_HTYPE_ONEOF(structname, fieldname) PB_SO_PB_HTYPE_ONEOF2(structname, PB_ONEOF_NAME(FULL, fieldname), PB_ONEOF_NAME(UNION, fieldname))
 #define PB_SO_PB_HTYPE_ONEOF2(structname, fullname, unionname) PB_SO_PB_HTYPE_ONEOF3(structname, fullname, unionname)
 #define PB_SO_PB_HTYPE_ONEOF3(structname, fullname, unionname) pb_delta(structname, fullname, which_ ## unionname)
 #define PB_SO_PB_HTYPE_OPTIONAL(structname, fieldname) pb_delta(structname, fieldname, has_ ## fieldname)
 #define PB_SO_PB_HTYPE_REPEATED(structname, fieldname) pb_delta(structname, fieldname, fieldname ## _count)
 #define PB_SO_PB_HTYPE_FIXARRAY(structname, fieldname) 0
 #define PB_SO_PTR_PB_HTYPE_REQUIRED(structname, fieldname) 0
 #define PB_SO_PTR_PB_HTYPE_SINGULAR(structname, fieldname) 0
 #define PB_SO_PTR_PB_HTYPE_ONEOF(structname, fieldname) PB_SO_PB_HTYPE_ONEOF(structname, fieldname)
 #define PB_SO_PTR_PB_HTYPE_OPTIONAL(structname, fieldname) 0
 #define PB_SO_PTR_PB_HTYPE_REPEATED(structname, fieldname) PB_SO_PB_HTYPE_REPEATED(structname, fieldname)
 #define PB_SO_PTR_PB_HTYPE_FIXARRAY(structname, fieldname) 0
 #define PB_SO_CB_PB_HTYPE_REQUIRED(structname, fieldname) 0
 #define PB_SO_CB_PB_HTYPE_SINGULAR(structname, fieldname) 0
 #define PB_SO_CB_PB_HTYPE_ONEOF(structname, fieldname) PB_SO_PB_HTYPE_ONEOF(structname, fieldname)
 #define PB_SO_CB_PB_HTYPE_OPTIONAL(structname, fieldname) 0
 #define PB_SO_CB_PB_HTYPE_REPEATED(structname, fieldname) 0
 #define PB_SO_CB_PB_HTYPE_FIXARRAY(structname, fieldname) 0
 #define PB_ARRAY_SIZE_STATIC(htype, structname, fieldname) PB_AS ## htype(structname, fieldname)
 #define PB_ARRAY_SIZE_POINTER(htype, structname, fieldname) PB_AS_PTR ## htype(structname, fieldname)
 #define PB_ARRAY_SIZE_CALLBACK(htype, structname, fieldname) 1
 #define PB_AS_PB_HTYPE_REQUIRED(structname, fieldname) 1
 #define PB_AS_PB_HTYPE_SINGULAR(structname, fieldname) 1
 #define PB_AS_PB_HTYPE_OPTIONAL(structname, fieldname) 1
 #define PB_AS_PB_HTYPE_ONEOF(structname, fieldname) 1
 #define PB_AS_PB_HTYPE_REPEATED(structname, fieldname) pb_arraysize(structname, fieldname)
 #define PB_AS_PB_HTYPE_FIXARRAY(structname, fieldname) pb_arraysize(structname, fieldname)
 #define PB_AS_PTR_PB_HTYPE_REQUIRED(structname, fieldname) 1
 #define PB_AS_PTR_PB_HTYPE_SINGULAR(structname, fieldname) 1
 #define PB_AS_PTR_PB_HTYPE_OPTIONAL(structname, fieldname) 1
 #define PB_AS_PTR_PB_HTYPE_ONEOF(structname, fieldname) 1
 #define PB_AS_PTR_PB_HTYPE_REPEATED(structname, fieldname) 1
 #define PB_AS_PTR_PB_HTYPE_FIXARRAY(structname, fieldname) pb_arraysize(structname, fieldname[0])
 #define PB_DATA_SIZE_STATIC(htype, structname, fieldname) PB_DS ## htype(structname, fieldname)
 #define PB_DATA_SIZE_POINTER(htype, structname, fieldname) PB_DS_PTR ## htype(structname, fieldname)
 #define PB_DATA_SIZE_CALLBACK(htype, structname, fieldname) PB_DS_CB ## htype(structname, fieldname)
 #define PB_DS_PB_HTYPE_REQUIRED(structname, fieldname) pb_membersize(structname, fieldname)
 #define PB_DS_PB_HTYPE_SINGULAR(structname, fieldname) pb_membersize(structname, fieldname)
 #define PB_DS_PB_HTYPE_OPTIONAL(structname, fieldname) pb_membersize(structname, fieldname)
 #define PB_DS_PB_HTYPE_ONEOF(structname, fieldname) pb_membersize(structname, PB_ONEOF_NAME(FULL, fieldname))
 #define PB_DS_PB_HTYPE_REPEATED(structname, fieldname) pb_membersize(structname, fieldname[0])
 #define PB_DS_PB_HTYPE_FIXARRAY(structname, fieldname) pb_membersize(structname, fieldname[0])
 #define PB_DS_PTR_PB_HTYPE_REQUIRED(structname, fieldname) pb_membersize(structname, fieldname[0])
 #define PB_DS_PTR_PB_HTYPE_SINGULAR(structname, fieldname) pb_membersize(structname, fieldname[0])
 #define PB_DS_PTR_PB_HTYPE_OPTIONAL(structname, fieldname) pb_membersize(structname, fieldname[0])
 #define PB_DS_PTR_PB_HTYPE_ONEOF(structname, fieldname) pb_membersize(structname, PB_ONEOF_NAME(FULL, fieldname)[0])
 #define PB_DS_PTR_PB_HTYPE_REPEATED(structname, fieldname) pb_membersize(structname, fieldname[0])
 #define PB_DS_PTR_PB_HTYPE_FIXARRAY(structname, fieldname) pb_membersize(structname, fieldname[0][0])
 #define PB_DS_CB_PB_HTYPE_REQUIRED(structname, fieldname) pb_membersize(structname, fieldname)
 #define PB_DS_CB_PB_HTYPE_SINGULAR(structname, fieldname) pb_membersize(structname, fieldname)
 #define PB_DS_CB_PB_HTYPE_OPTIONAL(structname, fieldname) pb_membersize(structname, fieldname)
 #define PB_DS_CB_PB_HTYPE_ONEOF(structname, fieldname) pb_membersize(structname, PB_ONEOF_NAME(FULL, fieldname))
 #define PB_DS_CB_PB_HTYPE_REPEATED(structname, fieldname) pb_membersize(structname, fieldname)
 #define PB_DS_CB_PB_HTYPE_FIXARRAY(structname, fieldname) pb_membersize(structname, fieldname)
 #define PB_ONEOF_NAME(type, tuple) PB_EXPAND(PB_ONEOF_NAME_ ## type tuple)
 #define PB_ONEOF_NAME_UNION(unionname,membername,fullname) unionname
 #define PB_ONEOF_NAME_MEMBER(unionname,membername,fullname) membername
 #define PB_ONEOF_NAME_FULL(unionname,membername,fullname) fullname
 #define PB_GEN_SUBMSG_INFO(structname, atype, htype, ltype, fieldname, tag) \
    PB_SUBMSG_INFO_ ## htype(_PB_LTYPE_ ## ltype, structname, fieldname)
 #define PB_SUBMSG_INFO_REQUIRED(ltype, structname, fieldname) PB_SI ## ltype(structname ## _ ## fieldname ## _MSGTYPE)
 #define PB_SUBMSG_INFO_SINGULAR(ltype, structname, fieldname) PB_SI ## ltype(structname ## _ ## fieldname ## _MSGTYPE)
 #define PB_SUBMSG_INFO_OPTIONAL(ltype, structname, fieldname) PB_SI ## ltype(structname ## _ ## fieldname ## _MSGTYPE)
 #define PB_SUBMSG_INFO_ONEOF(ltype, structname, fieldname) PB_SUBMSG_INFO_ONEOF2(ltype, structname, PB_ONEOF_NAME(UNION, fieldname), PB_ONEOF_NAME(MEMBER, fieldname))
 #define PB_SUBMSG_INFO_ONEOF2(ltype, structname, unionname, membername) PB_SUBMSG_INFO_ONEOF3(ltype, structname, unionname, membername)
 #define PB_SUBMSG_INFO_ONEOF3(ltype, structname, unionname, membername) PB_SI ## ltype(structname ## _ ## unionname ## _ ## membername ## _MSGTYPE)
 #define PB_SUBMSG_INFO_REPEATED(ltype, structname, fieldname) PB_SI ## ltype(structname ## _ ## fieldname ## _MSGTYPE)
 #define PB_SUBMSG_INFO_FIXARRAY(ltype, structname, fieldname) PB_SI ## ltype(structname ## _ ## fieldname ## _MSGTYPE)
 #define PB_SI_PB_LTYPE_BOOL(t)
 #define PB_SI_PB_LTYPE_BYTES(t)
 #define PB_SI_PB_LTYPE_DOUBLE(t)
 #define PB_SI_PB_LTYPE_ENUM(t)
 #define PB_SI_PB_LTYPE_UENUM(t)
 #define PB_SI_PB_LTYPE_FIXED32(t)
 #define PB_SI_PB_LTYPE_FIXED64(t)
 #define PB_SI_PB_LTYPE_FLOAT(t)
 #define PB_SI_PB_LTYPE_INT32(t)
 #define PB_SI_PB_LTYPE_INT64(t)
 #define PB_SI_PB_LTYPE_MESSAGE(t)  PB_SUBMSG_DESCRIPTOR(t)
 #define PB_SI_PB_LTYPE_MSG_W_CB(t) PB_SUBMSG_DESCRIPTOR(t)
 #define PB_SI_PB_LTYPE_SFIXED32(t)
 #define PB_SI_PB_LTYPE_SFIXED64(t)
 #define PB_SI_PB_LTYPE_SINT32(t)
 #define PB_SI_PB_LTYPE_SINT64(t)
 #define PB_SI_PB_LTYPE_STRING(t)
 #define PB_SI_PB_LTYPE_UINT32(t)
 #define PB_SI_PB_LTYPE_UINT64(t)
 #define PB_SI_PB_LTYPE_EXTENSION(t)
 #define PB_SI_PB_LTYPE_FIXED_LENGTH_BYTES(t)
 #define PB_SUBMSG_DESCRIPTOR(t)    &(t ## _msg),
 /* The field descriptors use a variable width format, with width of either
 * 1, 2, 4 or 8 of 32-bit words. The two lowest bytes of the first byte always
 * encode the descriptor size, 6 lowest bits of field tag number, and 8 bits
 * of the field type.
 *
 * Descriptor size is encoded as 0 = 1 word, 1 = 2 words, 2 = 4 words, 3 = 8 words.
 *
 * Formats, listed starting with the least significant bit of the first word.
 * 1 word:  [2-bit len] [6-bit tag] [8-bit type] [8-bit data_offset] [4-bit size_offset] [4-bit data_size]
 *
 * 2 words: [2-bit len] [6-bit tag] [8-bit type] [12-bit array_size] [4-bit size_offset]
 *          [16-bit data_offset] [12-bit data_size] [4-bit tag>>6]
 *
 * 4 words: [2-bit len] [6-bit tag] [8-bit type] [16-bit array_size]
 *          [8-bit size_offset] [24-bit tag>>6]
 *          [32-bit data_offset]
 *          [32-bit data_size]
 *
 * 8 words: [2-bit len] [6-bit tag] [8-bit type] [16-bit reserved]
 *          [8-bit size_offset] [24-bit tag>>6]
 *          [32-bit data_offset]
 *          [32-bit data_size]
 *          [32-bit array_size]
 *          [32-bit reserved]
 *          [32-bit reserved]
 *          [32-bit reserved]
 */
 #define PB_FIELDINFO_1(tag, type, data_offset, data_size, size_offset, array_size) \
    (0 | (((tag) << 2) & 0xFF) | ((type) << 8) | (((uint32_t)(data_offset) & 0xFF) << 16) | \
     (((uint32_t)(size_offset) & 0x0F) << 24) | (((uint32_t)(data_size) & 0x0F) << 28)),
 #define PB_FIELDINFO_2(tag, type, data_offset, data_size, size_offset, array_size) \
    (1 | (((tag) << 2) & 0xFF) | ((type) << 8) | (((uint32_t)(array_size) & 0xFFF) << 16) | (((uint32_t)(size_offset) & 0x0F) << 28)), \
    (((uint32_t)(data_offset) & 0xFFFF) | (((uint32_t)(data_size) & 0xFFF) << 16) | (((uint32_t)(tag) & 0x3c0) << 22)),
 #define PB_FIELDINFO_4(tag, type, data_offset, data_size, size_offset, array_size) \
    (2 | (((tag) << 2) & 0xFF) | ((type) << 8) | (((uint32_t)(array_size) & 0xFFFF) << 16)), \
    ((uint32_t)(int_least8_t)(size_offset) | (((uint32_t)(tag) << 2) & 0xFFFFFF00)), \
    (data_offset), (data_size),
 #define PB_FIELDINFO_8(tag, type, data_offset, data_size, size_offset, array_size) \
    (3 | (((tag) << 2) & 0xFF) | ((type) << 8)), \
    ((uint32_t)(int_least8_t)(size_offset) | (((uint32_t)(tag) << 2) & 0xFFFFFF00)), \
    (data_offset), (data_size), (array_size), 0, 0, 0,
 /* These assertions verify that the field information fits in the allocated space.
 * The generator tries to automatically determine the correct width that can fit all
 * data associated with a message. These asserts will fail only if there has been a
 * problem in the automatic logic - this may be worth reporting as a bug. As a workaround,
 * you can increase the descriptor width by defining PB_FIELDINFO_WIDTH or by setting
 * descriptorsize option in .options file.
 */
 #define PB_FITS(value,bits) ((uint32_t)(value) < ((uint32_t)1<<bits))
 #define PB_FIELDINFO_ASSERT_1(tag, type, data_offset, data_size, size_offset, array_size) \
    PB_STATIC_ASSERT(PB_FITS(tag,6) && PB_FITS(data_offset,8) && PB_FITS(size_offset,4) && PB_FITS(data_size,4) && PB_FITS(array_size,1), FIELDINFO_DOES_NOT_FIT_width1_field ## tag)
 #define PB_FIELDINFO_ASSERT_2(tag, type, data_offset, data_size, size_offset, array_size) \
    PB_STATIC_ASSERT(PB_FITS(tag,10) && PB_FITS(data_offset,16) && PB_FITS(size_offset,4) && PB_FITS(data_size,12) && PB_FITS(array_size,12), FIELDINFO_DOES_NOT_FIT_width2_field ## tag)
 #ifndef PB_FIELD_32BIT
 /* Maximum field sizes are still 16-bit if pb_size_t is 16-bit */
 #define PB_FIELDINFO_ASSERT_4(tag, type, data_offset, data_size, size_offset, array_size) \
    PB_STATIC_ASSERT(PB_FITS(tag,16) && PB_FITS(data_offset,16) && PB_FITS((int_least8_t)size_offset,8) && PB_FITS(data_size,16) && PB_FITS(array_size,16), FIELDINFO_DOES_NOT_FIT_width4_field ## tag)
 #define PB_FIELDINFO_ASSERT_8(tag, type, data_offset, data_size, size_offset, array_size) \
    PB_STATIC_ASSERT(PB_FITS(tag,16) && PB_FITS(data_offset,16) && PB_FITS((int_least8_t)size_offset,8) && PB_FITS(data_size,16) && PB_FITS(array_size,16), FIELDINFO_DOES_NOT_FIT_width8_field ## tag)
 #else
 /* Up to 32-bit fields supported.
 * Note that the checks are against 31 bits to avoid compiler warnings about shift wider than type in the test.
 * I expect that there is no reasonable use for >2GB messages with nanopb anyway.
 */
 #define PB_FIELDINFO_ASSERT_4(tag, type, data_offset, data_size, size_offset, array_size) \
    PB_STATIC_ASSERT(PB_FITS(tag,30) && PB_FITS(data_offset,31) && PB_FITS(size_offset,8) && PB_FITS(data_size,31) && PB_FITS(array_size,16), FIELDINFO_DOES_NOT_FIT_width4_field ## tag)
 #define PB_FIELDINFO_ASSERT_8(tag, type, data_offset, data_size, size_offset, array_size) \
    PB_STATIC_ASSERT(PB_FITS(tag,30) && PB_FITS(data_offset,31) && PB_FITS(size_offset,8) && PB_FITS(data_size,31) && PB_FITS(array_size,31), FIELDINFO_DOES_NOT_FIT_width8_field ## tag)
 #endif
 /* Automatic picking of FIELDINFO width:
 * Uses width 1 when possible, otherwise resorts to width 2.
 * This is used when PB_BIND() is called with "AUTO" as the argument.
 * The generator will give explicit size argument when it knows that a message
 * structure grows beyond 1-word format limits.
 */
 #define PB_FIELDINFO_WIDTH_AUTO(atype, htype, ltype) PB_FI_WIDTH ## atype(htype, ltype)
 #define PB_FI_WIDTH_PB_ATYPE_STATIC(htype, ltype) PB_FI_WIDTH ## htype(ltype)
 #define PB_FI_WIDTH_PB_ATYPE_POINTER(htype, ltype) PB_FI_WIDTH ## htype(ltype)
 #define PB_FI_WIDTH_PB_ATYPE_CALLBACK(htype, ltype) 2
 #define PB_FI_WIDTH_PB_HTYPE_REQUIRED(ltype) PB_FI_WIDTH ## ltype
 #define PB_FI_WIDTH_PB_HTYPE_SINGULAR(ltype) PB_FI_WIDTH ## ltype
 #define PB_FI_WIDTH_PB_HTYPE_OPTIONAL(ltype) PB_FI_WIDTH ## ltype
 #define PB_FI_WIDTH_PB_HTYPE_ONEOF(ltype) PB_FI_WIDTH ## ltype
 #define PB_FI_WIDTH_PB_HTYPE_REPEATED(ltype) 2
 #define PB_FI_WIDTH_PB_HTYPE_FIXARRAY(ltype) 2
 #define PB_FI_WIDTH_PB_LTYPE_BOOL      1
 #define PB_FI_WIDTH_PB_LTYPE_BYTES     2
 #define PB_FI_WIDTH_PB_LTYPE_DOUBLE    1
 #define PB_FI_WIDTH_PB_LTYPE_ENUM      1
 #define PB_FI_WIDTH_PB_LTYPE_UENUM     1
 #define PB_FI_WIDTH_PB_LTYPE_FIXED32   1
 #define PB_FI_WIDTH_PB_LTYPE_FIXED64   1
 #define PB_FI_WIDTH_PB_LTYPE_FLOAT     1
 #define PB_FI_WIDTH_PB_LTYPE_INT32     1
 #define PB_FI_WIDTH_PB_LTYPE_INT64     1
 #define PB_FI_WIDTH_PB_LTYPE_MESSAGE   2
 #define PB_FI_WIDTH_PB_LTYPE_MSG_W_CB  2
 #define PB_FI_WIDTH_PB_LTYPE_SFIXED32  1
 #define PB_FI_WIDTH_PB_LTYPE_SFIXED64  1
 #define PB_FI_WIDTH_PB_LTYPE_SINT32    1
 #define PB_FI_WIDTH_PB_LTYPE_SINT64    1
 #define PB_FI_WIDTH_PB_LTYPE_STRING    2
 #define PB_FI_WIDTH_PB_LTYPE_UINT32    1
 #define PB_FI_WIDTH_PB_LTYPE_UINT64    1
 #define PB_FI_WIDTH_PB_LTYPE_EXTENSION 1
 #define PB_FI_WIDTH_PB_LTYPE_FIXED_LENGTH_BYTES 2
 /* The mapping from protobuf types to LTYPEs is done using these macros. */
 #define PB_LTYPE_MAP_BOOL               PB_LTYPE_BOOL
 #define PB_LTYPE_MAP_BYTES              PB_LTYPE_BYTES
 #define PB_LTYPE_MAP_DOUBLE             PB_LTYPE_FIXED64
 #define PB_LTYPE_MAP_ENUM               PB_LTYPE_VARINT
 #define PB_LTYPE_MAP_UENUM              PB_LTYPE_UVARINT
 #define PB_LTYPE_MAP_FIXED32            PB_LTYPE_FIXED32
 #define PB_LTYPE_MAP_FIXED64            PB_LTYPE_FIXED64
 #define PB_LTYPE_MAP_FLOAT              PB_LTYPE_FIXED32
 #define PB_LTYPE_MAP_INT32              PB_LTYPE_VARINT
 #define PB_LTYPE_MAP_INT64              PB_LTYPE_VARINT
 #define PB_LTYPE_MAP_MESSAGE            PB_LTYPE_SUBMESSAGE
 #define PB_LTYPE_MAP_MSG_W_CB           PB_LTYPE_SUBMSG_W_CB
 #define PB_LTYPE_MAP_SFIXED32           PB_LTYPE_FIXED32
 #define PB_LTYPE_MAP_SFIXED64           PB_LTYPE_FIXED64
 #define PB_LTYPE_MAP_SINT32             PB_LTYPE_SVARINT
 #define PB_LTYPE_MAP_SINT64             PB_LTYPE_SVARINT
 #define PB_LTYPE_MAP_STRING             PB_LTYPE_STRING
 #define PB_LTYPE_MAP_UINT32             PB_LTYPE_UVARINT
 #define PB_LTYPE_MAP_UINT64             PB_LTYPE_UVARINT
 #define PB_LTYPE_MAP_EXTENSION          PB_LTYPE_EXTENSION
 #define PB_LTYPE_MAP_FIXED_LENGTH_BYTES PB_LTYPE_FIXED_LENGTH_BYTES
 /* These macros are used for giving out error messages.
 * They are mostly a debugging aid; the main error information
 * is the true/false return value from functions.
 * Some code space can be saved by disabling the error
 * messages if not used.
 *
 * PB_SET_ERROR() sets the error message if none has been set yet.
 *                msg must be a constant string literal.
 * PB_GET_ERROR() always returns a pointer to a string.
 * PB_RETURN_ERROR() sets the error and returns false from current
 *                   function.
 */
 #ifdef PB_NO_ERRMSG
 #define PB_SET_ERROR(stream, msg) PB_UNUSED(stream)
 #define PB_GET_ERROR(stream) "(errmsg disabled)"
 #else
 #define PB_SET_ERROR(stream, msg) (stream->errmsg = (stream)->errmsg ? (stream)->errmsg : (msg))
 #define PB_GET_ERROR(stream) ((stream)->errmsg ? (stream)->errmsg : "(none)")
 #endif
 #define PB_RETURN_ERROR(stream, msg) return PB_SET_ERROR(stream, msg), false
 #ifdef __cplusplus
 } /* extern "C" */
 #endif
 #ifdef __cplusplus
 #if __cplusplus >= 201103L
 #define PB_CONSTEXPR constexpr
 #else  // __cplusplus >= 201103L
 #define PB_CONSTEXPR
 #endif  // __cplusplus >= 201103L
 #if __cplusplus >= 201703L
 #define PB_INLINE_CONSTEXPR inline constexpr
 #else  // __cplusplus >= 201703L
 #define PB_INLINE_CONSTEXPR PB_CONSTEXPR
 #endif  // __cplusplus >= 201703L
 namespace nanopb {
 // Each type will be partially specialized by the generator.
 template <typename GenMessageT> struct MessageDescriptor;
 }  // namespace nanopb
 #endif  /* __cplusplus */
 #endif
--- a/components/nanopb/pb_common.c
+++ b/components/nanopb/pb_common.c
@ -0,0 +1,345 @@
 /* pb_common.c: Common support functions for pb_encode.c and pb_decode.c.
 *
 * 2014 Petteri Aimonen <jpa@kapsi.fi>
 */
 #include "pb_common.h"
 static bool load_descriptor_values(pb_field_iter_t *iter)
 {
    uint32_t word0;
    uint32_t data_offset;
    uint_least8_t format;
    int_least8_t size_offset;
    if (iter->index >= iter->descriptor->field_count)
        return false;
    word0 = PB_PROGMEM_READU32(iter->descriptor->field_info[iter->field_info_index]);
    format = word0 & 3;
    iter->tag = (pb_size_t)((word0 >> 2) & 0x3F);
    iter->type = (pb_type_t)((word0 >> 8) & 0xFF);
    if (format == 0)
    {
        /* 1-word format */
        iter->array_size = 1;
        size_offset = (int_least8_t)((word0 >> 24) & 0x0F);
        data_offset = (word0 >> 16) & 0xFF;
        iter->data_size = (pb_size_t)((word0 >> 28) & 0x0F);
    }
    else if (format == 1)
    {
        /* 2-word format */
        uint32_t word1 = PB_PROGMEM_READU32(iter->descriptor->field_info[iter->field_info_index + 1]);
        iter->array_size = (pb_size_t)((word0 >> 16) & 0x0FFF);
        iter->tag = (pb_size_t)(iter->tag | ((word1 >> 28) << 6));
        size_offset = (int_least8_t)((word0 >> 28) & 0x0F);
        data_offset = word1 & 0xFFFF;
        iter->data_size = (pb_size_t)((word1 >> 16) & 0x0FFF);
    }
    else if (format == 2)
    {
        /* 4-word format */
        uint32_t word1 = PB_PROGMEM_READU32(iter->descriptor->field_info[iter->field_info_index + 1]);
        uint32_t word2 = PB_PROGMEM_READU32(iter->descriptor->field_info[iter->field_info_index + 2]);
        uint32_t word3 = PB_PROGMEM_READU32(iter->descriptor->field_info[iter->field_info_index + 3]);
        iter->array_size = (pb_size_t)(word0 >> 16);
        iter->tag = (pb_size_t)(iter->tag | ((word1 >> 8) << 6));
        size_offset = (int_least8_t)(word1 & 0xFF);
        data_offset = word2;
        iter->data_size = (pb_size_t)word3;
    }
    else
    {
        /* 8-word format */
        uint32_t word1 = PB_PROGMEM_READU32(iter->descriptor->field_info[iter->field_info_index + 1]);
        uint32_t word2 = PB_PROGMEM_READU32(iter->descriptor->field_info[iter->field_info_index + 2]);
        uint32_t word3 = PB_PROGMEM_READU32(iter->descriptor->field_info[iter->field_info_index + 3]);
        uint32_t word4 = PB_PROGMEM_READU32(iter->descriptor->field_info[iter->field_info_index + 4]);
        iter->array_size = (pb_size_t)word4;
        iter->tag = (pb_size_t)(iter->tag | ((word1 >> 8) << 6));
        size_offset = (int_least8_t)(word1 & 0xFF);
        data_offset = word2;
        iter->data_size = (pb_size_t)word3;
    }
    if (!iter->message)
    {
        /* Avoid doing arithmetic on null pointers, it is undefined */
        iter->pField = NULL;
        iter->pSize = NULL;
    }
    else
    {
        iter->pField = (char*)iter->message + data_offset;
        if (size_offset)
        {
            iter->pSize = (char*)iter->pField - size_offset;
        }
        else if (PB_HTYPE(iter->type) == PB_HTYPE_REPEATED &&
                 (PB_ATYPE(iter->type) == PB_ATYPE_STATIC ||
                  PB_ATYPE(iter->type) == PB_ATYPE_POINTER))
        {
            /* Fixed count array */
            iter->pSize = &iter->array_size;
        }
        else
        {
            iter->pSize = NULL;
        }
        if (PB_ATYPE(iter->type) == PB_ATYPE_POINTER && iter->pField != NULL)
        {
            iter->pData = *(void**)iter->pField;
        }
        else
        {
            iter->pData = iter->pField;
        }
    }
    if (PB_LTYPE_IS_SUBMSG(iter->type))
    {
        iter->submsg_desc = iter->descriptor->submsg_info[iter->submessage_index];
    }
    else
    {
        iter->submsg_desc = NULL;
    }
    return true;
 }
 static void advance_iterator(pb_field_iter_t *iter)
 {
    iter->index++;
    if (iter->index >= iter->descriptor->field_count)
    {
        /* Restart */
        iter->index = 0;
        iter->field_info_index = 0;
        iter->submessage_index = 0;
        iter->required_field_index = 0;
    }
    else
    {
        /* Increment indexes based on previous field type.
         * All field info formats have the following fields:
         * - lowest 2 bits tell the amount of words in the descriptor (2^n words)
         * - bits 2..7 give the lowest bits of tag number.
         * - bits 8..15 give the field type.
         */
        uint32_t prev_descriptor = PB_PROGMEM_READU32(iter->descriptor->field_info[iter->field_info_index]);
        pb_type_t prev_type = (prev_descriptor >> 8) & 0xFF;
        pb_size_t descriptor_len = (pb_size_t)(1 << (prev_descriptor & 3));
        iter->field_info_index = (pb_size_t)(iter->field_info_index + descriptor_len);
        if (PB_HTYPE(prev_type) == PB_HTYPE_REQUIRED)
        {
            iter->required_field_index++;
        }
        if (PB_LTYPE_IS_SUBMSG(prev_type))
        {
            iter->submessage_index++;
        }
    }
 }
 bool pb_field_iter_begin(pb_field_iter_t *iter, const pb_msgdesc_t *desc, void *message)
 {
    memset(iter, 0, sizeof(*iter));
    iter->descriptor = desc;
    iter->message = message;
    return load_descriptor_values(iter);
 }
 bool pb_field_iter_begin_extension(pb_field_iter_t *iter, pb_extension_t *extension)
 {
    const pb_msgdesc_t *msg = (const pb_msgdesc_t*)extension->type->arg;
    bool status;
    uint32_t word0 = PB_PROGMEM_READU32(msg->field_info[0]);
    if (PB_ATYPE(word0 >> 8) == PB_ATYPE_POINTER)
    {
        /* For pointer extensions, the pointer is stored directly
         * in the extension structure. This avoids having an extra
         * indirection. */
        status = pb_field_iter_begin(iter, msg, &extension->dest);
    }
    else
    {
        status = pb_field_iter_begin(iter, msg, extension->dest);
    }
    iter->pSize = &extension->found;
    return status;
 }
 bool pb_field_iter_next(pb_field_iter_t *iter)
 {
    advance_iterator(iter);
    (void)load_descriptor_values(iter);
    return iter->index != 0;
 }
 bool pb_field_iter_find(pb_field_iter_t *iter, uint32_t tag)
 {
    if (iter->tag == tag)
    {
        return true; /* Nothing to do, correct field already. */
    }
    else
    {
        pb_size_t start = iter->index;
        uint32_t fieldinfo;
        do
        {
            /* Advance iterator but don't load values yet */
            advance_iterator(iter);
            /* Do fast check for tag number match */
            fieldinfo = PB_PROGMEM_READU32(iter->descriptor->field_info[iter->field_info_index]);
            if (((fieldinfo >> 2) & 0x3F) == (tag & 0x3F))
            {
                /* Good candidate, check further */
                (void)load_descriptor_values(iter);
                if (iter->tag == tag &&
                    PB_LTYPE(iter->type) != PB_LTYPE_EXTENSION)
                {
                    /* Found it */
                    return true;
                }
            }
        } while (iter->index != start);
        /* Searched all the way back to start, and found nothing. */
        (void)load_descriptor_values(iter);
        return false;
    }
 }
 static void *pb_const_cast(const void *p)
 {
    /* Note: this casts away const, in order to use the common field iterator
     * logic for both encoding and decoding. The cast is done using union
     * to avoid spurious compiler warnings. */
    union {
        void *p1;
        const void *p2;
    } t;
    t.p2 = p;
    return t.p1;
 }
 bool pb_field_iter_begin_const(pb_field_iter_t *iter, const pb_msgdesc_t *desc, const void *message)
 {
    return pb_field_iter_begin(iter, desc, pb_const_cast(message));
 }
 bool pb_field_iter_begin_extension_const(pb_field_iter_t *iter, const pb_extension_t *extension)
 {
    return pb_field_iter_begin_extension(iter, (pb_extension_t*)pb_const_cast(extension));
 }
 bool pb_default_field_callback(pb_istream_t *istream, pb_ostream_t *ostream, const pb_field_t *field)
 {
    if (field->data_size == sizeof(pb_callback_t))
    {
        pb_callback_t *pCallback = (pb_callback_t*)field->pData;
        if (pCallback != NULL)
        {
            if (istream != NULL && pCallback->funcs.decode != NULL)
            {
                return pCallback->funcs.decode(istream, field, &pCallback->arg);
            }
            if (ostream != NULL && pCallback->funcs.encode != NULL)
            {
                return pCallback->funcs.encode(ostream, field, &pCallback->arg);
            }
        }
    }
    return true; /* Success, but didn't do anything */
 }
 #ifdef PB_VALIDATE_UTF8
 /* This function checks whether a string is valid UTF-8 text.
 *
 * Algorithm is adapted from https://www.cl.cam.ac.uk/~mgk25/ucs/utf8_check.c
 * Original copyright: Markus Kuhn <http://www.cl.cam.ac.uk/~mgk25/> 2005-03-30
 * Licensed under "Short code license", which allows use under MIT license or
 * any compatible with it.
 */
 bool pb_validate_utf8(const char *str)
 {
    const pb_byte_t *s = (const pb_byte_t*)str;
    while (*s)
    {
        if (*s < 0x80)
        {
            /* 0xxxxxxx */
            s++;
        }
        else if ((s[0] & 0xe0) == 0xc0)
        {
            /* 110XXXXx 10xxxxxx */
            if ((s[1] & 0xc0) != 0x80 ||
                (s[0] & 0xfe) == 0xc0)                        /* overlong? */
                return false;
            else
                s += 2;
        }
        else if ((s[0] & 0xf0) == 0xe0)
        {
            /* 1110XXXX 10Xxxxxx 10xxxxxx */
            if ((s[1] & 0xc0) != 0x80 ||
                (s[2] & 0xc0) != 0x80 ||
                (s[0] == 0xe0 && (s[1] & 0xe0) == 0x80) ||    /* overlong? */
                (s[0] == 0xed && (s[1] & 0xe0) == 0xa0) ||    /* surrogate? */
                (s[0] == 0xef && s[1] == 0xbf &&
                (s[2] & 0xfe) == 0xbe))                 /* U+FFFE or U+FFFF? */
                return false;
            else
                s += 3;
        }
        else if ((s[0] & 0xf8) == 0xf0)
        {
            /* 11110XXX 10XXxxxx 10xxxxxx 10xxxxxx */
            if ((s[1] & 0xc0) != 0x80 ||
                (s[2] & 0xc0) != 0x80 ||
                (s[3] & 0xc0) != 0x80 ||
                (s[0] == 0xf0 && (s[1] & 0xf0) == 0x80) ||    /* overlong? */
                (s[0] == 0xf4 && s[1] > 0x8f) || s[0] > 0xf4) /* > U+10FFFF? */
                return false;
            else
                s += 4;
        }
        else
        {
            return false;
        }
    }
    return true;
 }
 #endif
--- a/components/nanopb/pb_common.h
+++ b/components/nanopb/pb_common.h
@ -0,0 +1,45 @@
 /* pb_common.h: Common support functions for pb_encode.c and pb_decode.c.
 * These functions are rarely needed by applications directly.
 */
 #ifndef PB_COMMON_H_INCLUDED
 #define PB_COMMON_H_INCLUDED
 #include "pb.h"
 #ifdef __cplusplus
 extern "C" {
 #endif
 /* Initialize the field iterator structure to beginning.
 * Returns false if the message type is empty. */
 bool pb_field_iter_begin(pb_field_iter_t *iter, const pb_msgdesc_t *desc, void *message);
 /* Get a field iterator for extension field. */
 bool pb_field_iter_begin_extension(pb_field_iter_t *iter, pb_extension_t *extension);
 /* Same as pb_field_iter_begin(), but for const message pointer.
 * Note that the pointers in pb_field_iter_t will be non-const but shouldn't
 * be written to when using these functions. */
 bool pb_field_iter_begin_const(pb_field_iter_t *iter, const pb_msgdesc_t *desc, const void *message);
 bool pb_field_iter_begin_extension_const(pb_field_iter_t *iter, const pb_extension_t *extension);
 /* Advance the iterator to the next field.
 * Returns false when the iterator wraps back to the first field. */
 bool pb_field_iter_next(pb_field_iter_t *iter);
 /* Advance the iterator until it points at a field with the given tag.
 * Returns false if no such field exists. */
 bool pb_field_iter_find(pb_field_iter_t *iter, uint32_t tag);
 #ifdef PB_VALIDATE_UTF8
 /* Validate UTF-8 text string */
 bool pb_validate_utf8(const char *s);
 #endif
 #ifdef __cplusplus
 } /* extern "C" */
 #endif
 #endif
--- a/components/nanopb/pb_decode.c
+++ b/components/nanopb/pb_decode.c
--- a/components/nanopb/pb_decode.h
+++ b/components/nanopb/pb_decode.h
@ -0,0 +1,196 @@
 /* pb_decode.h: Functions to decode protocol buffers. Depends on pb_decode.c.
 * The main function is pb_decode. You also need an input stream, and the
 * field descriptions created by nanopb_generator.py.
 */
 #ifndef PB_DECODE_H_INCLUDED
 #define PB_DECODE_H_INCLUDED
 #include "pb.h"
 #ifdef __cplusplus
 extern "C" {
 #endif
 /* Structure for defining custom input streams. You will need to provide
 * a callback function to read the bytes from your storage, which can be
 * for example a file or a network socket.
 * 
 * The callback must conform to these rules:
 *
 * 1) Return false on IO errors. This will cause decoding to abort.
 * 2) You can use state to store your own data (e.g. buffer pointer),
 *    and rely on pb_read to verify that no-body reads past bytes_left.
 * 3) Your callback may be used with substreams, in which case bytes_left
 *    is different than from the main stream. Don't use bytes_left to compute
 *    any pointers.
 */
 struct pb_istream_s
 {
 #ifdef PB_BUFFER_ONLY
    /* Callback pointer is not used in buffer-only configuration.
     * Having an int pointer here allows binary compatibility but
     * gives an error if someone tries to assign callback function.
     */
    int *callback;
 #else
    bool (*callback)(pb_istream_t *stream, pb_byte_t *buf, size_t count);
 #endif
    void *state; /* Free field for use by callback implementation */
    size_t bytes_left;
 #ifndef PB_NO_ERRMSG
    const char *errmsg;
 #endif
 };
 #ifndef PB_NO_ERRMSG
 #define PB_ISTREAM_EMPTY {0,0,0,0}
 #else
 #define PB_ISTREAM_EMPTY {0,0,0}
 #endif
 /***************************
 * Main decoding functions *
 ***************************/
 /* Decode a single protocol buffers message from input stream into a C structure.
 * Returns true on success, false on any failure.
 * The actual struct pointed to by dest must match the description in fields.
 * Callback fields of the destination structure must be initialized by caller.
 * All other fields will be initialized by this function.
 *
 * Example usage:
 *    MyMessage msg = {};
 *    uint8_t buffer[64];
 *    pb_istream_t stream;
 *    
 *    // ... read some data into buffer ...
 *
 *    stream = pb_istream_from_buffer(buffer, count);
 *    pb_decode(&stream, MyMessage_fields, &msg);
 */
 bool pb_decode(pb_istream_t *stream, const pb_msgdesc_t *fields, void *dest_struct);
 /* Extended version of pb_decode, with several options to control
 * the decoding process:
 *
 * PB_DECODE_NOINIT:         Do not initialize the fields to default values.
 *                           This is slightly faster if you do not need the default
 *                           values and instead initialize the structure to 0 using
 *                           e.g. memset(). This can also be used for merging two
 *                           messages, i.e. combine already existing data with new
 *                           values.
 *
 * PB_DECODE_DELIMITED:      Input message starts with the message size as varint.
 *                           Corresponds to parseDelimitedFrom() in Google's
 *                           protobuf API.
 *
 * PB_DECODE_NULLTERMINATED: Stop reading when field tag is read as 0. This allows
 *                           reading null terminated messages.
 *                           NOTE: Until nanopb-0.4.0, pb_decode() also allows
 *                           null-termination. This behaviour is not supported in
 *                           most other protobuf implementations, so PB_DECODE_DELIMITED
 *                           is a better option for compatibility.
 *
 * Multiple flags can be combined with bitwise or (| operator)
 */
 #define PB_DECODE_NOINIT          0x01U
 #define PB_DECODE_DELIMITED       0x02U
 #define PB_DECODE_NULLTERMINATED  0x04U
 bool pb_decode_ex(pb_istream_t *stream, const pb_msgdesc_t *fields, void *dest_struct, unsigned int flags);
 /* Defines for backwards compatibility with code written before nanopb-0.4.0 */
 #define pb_decode_noinit(s,f,d) pb_decode_ex(s,f,d, PB_DECODE_NOINIT)
 #define pb_decode_delimited(s,f,d) pb_decode_ex(s,f,d, PB_DECODE_DELIMITED)
 #define pb_decode_delimited_noinit(s,f,d) pb_decode_ex(s,f,d, PB_DECODE_DELIMITED | PB_DECODE_NOINIT)
 #define pb_decode_nullterminated(s,f,d) pb_decode_ex(s,f,d, PB_DECODE_NULLTERMINATED)
 #ifdef PB_ENABLE_MALLOC
 /* Release any allocated pointer fields. If you use dynamic allocation, you should
 * call this for any successfully decoded message when you are done with it. If
 * pb_decode() returns with an error, the message is already released.
 */
 void pb_release(const pb_msgdesc_t *fields, void *dest_struct);
 #endif
 /**************************************
 * Functions for manipulating streams *
 **************************************/
 /* Create an input stream for reading from a memory buffer.
 *
 * msglen should be the actual length of the message, not the full size of
 * allocated buffer.
 *
 * Alternatively, you can use a custom stream that reads directly from e.g.
 * a file or a network socket.
 */
 pb_istream_t pb_istream_from_buffer(const pb_byte_t *buf, size_t msglen);
 /* Function to read from a pb_istream_t. You can use this if you need to
 * read some custom header data, or to read data in field callbacks.
 */
 bool pb_read(pb_istream_t *stream, pb_byte_t *buf, size_t count);
 /************************************************
 * Helper functions for writing field callbacks *
 ************************************************/
 /* Decode the tag for the next field in the stream. Gives the wire type and
 * field tag. At end of the message, returns false and sets eof to true. */
 bool pb_decode_tag(pb_istream_t *stream, pb_wire_type_t *wire_type, uint32_t *tag, bool *eof);
 /* Skip the field payload data, given the wire type. */
 bool pb_skip_field(pb_istream_t *stream, pb_wire_type_t wire_type);
 /* Decode an integer in the varint format. This works for enum, int32,
 * int64, uint32 and uint64 field types. */
 #ifndef PB_WITHOUT_64BIT
 bool pb_decode_varint(pb_istream_t *stream, uint64_t *dest);
 #else
 #define pb_decode_varint pb_decode_varint32
 #endif
 /* Decode an integer in the varint format. This works for enum, int32,
 * and uint32 field types. */
 bool pb_decode_varint32(pb_istream_t *stream, uint32_t *dest);
 /* Decode a bool value in varint format. */
 bool pb_decode_bool(pb_istream_t *stream, bool *dest);
 /* Decode an integer in the zig-zagged svarint format. This works for sint32
 * and sint64. */
 #ifndef PB_WITHOUT_64BIT
 bool pb_decode_svarint(pb_istream_t *stream, int64_t *dest);
 #else
 bool pb_decode_svarint(pb_istream_t *stream, int32_t *dest);
 #endif
 /* Decode a fixed32, sfixed32 or float value. You need to pass a pointer to
 * a 4-byte wide C variable. */
 bool pb_decode_fixed32(pb_istream_t *stream, void *dest);
 #ifndef PB_WITHOUT_64BIT
 /* Decode a fixed64, sfixed64 or double value. You need to pass a pointer to
 * a 8-byte wide C variable. */
 bool pb_decode_fixed64(pb_istream_t *stream, void *dest);
 #endif
 #ifdef PB_CONVERT_DOUBLE_FLOAT
 /* Decode a double value into float variable. */
 bool pb_decode_double_as_float(pb_istream_t *stream, float *dest);
 #endif
 /* Make a limited-length substream for reading a PB_WT_STRING field. */
 bool pb_make_string_substream(pb_istream_t *stream, pb_istream_t *substream);
 bool pb_close_string_substream(pb_istream_t *stream, pb_istream_t *substream);
 #ifdef __cplusplus
 } /* extern "C" */
 #endif
 #endif
--- a/components/nanopb/pb_encode.c
+++ b/components/nanopb/pb_encode.c
@ -0,0 +1,978 @@
 /* pb_encode.c -- encode a protobuf using minimal resources
 *
 * 2011 Petteri Aimonen <jpa@kapsi.fi>
 */
 #include "pb.h"
 #include "pb_encode.h"
 #include "pb_common.h"
 /* Use the GCC warn_unused_result attribute to check that all return values
 * are propagated correctly. On other compilers and gcc before 3.4.0 just
 * ignore the annotation.
 */
 #if !defined(__GNUC__) || ( __GNUC__ < 3) || (__GNUC__ == 3 && __GNUC_MINOR__ < 4)
    #define checkreturn
 #else
    #define checkreturn __attribute__((warn_unused_result))
 #endif
 /**************************************
 * Declarations internal to this file *
 **************************************/
 static bool checkreturn buf_write(pb_ostream_t *stream, const pb_byte_t *buf, size_t count);
 static bool checkreturn encode_array(pb_ostream_t *stream, pb_field_iter_t *field);
 static bool checkreturn pb_check_proto3_default_value(const pb_field_iter_t *field);
 static bool checkreturn encode_basic_field(pb_ostream_t *stream, const pb_field_iter_t *field);
 static bool checkreturn encode_callback_field(pb_ostream_t *stream, const pb_field_iter_t *field);
 static bool checkreturn encode_field(pb_ostream_t *stream, pb_field_iter_t *field);
 static bool checkreturn encode_extension_field(pb_ostream_t *stream, const pb_field_iter_t *field);
 static bool checkreturn default_extension_encoder(pb_ostream_t *stream, const pb_extension_t *extension);
 static bool checkreturn pb_encode_varint_32(pb_ostream_t *stream, uint32_t low, uint32_t high);
 static bool checkreturn pb_enc_bool(pb_ostream_t *stream, const pb_field_iter_t *field);
 static bool checkreturn pb_enc_varint(pb_ostream_t *stream, const pb_field_iter_t *field);
 static bool checkreturn pb_enc_fixed(pb_ostream_t *stream, const pb_field_iter_t *field);
 static bool checkreturn pb_enc_bytes(pb_ostream_t *stream, const pb_field_iter_t *field);
 static bool checkreturn pb_enc_string(pb_ostream_t *stream, const pb_field_iter_t *field);
 static bool checkreturn pb_enc_submessage(pb_ostream_t *stream, const pb_field_iter_t *field);
 static bool checkreturn pb_enc_fixed_length_bytes(pb_ostream_t *stream, const pb_field_iter_t *field);
 #ifdef PB_WITHOUT_64BIT
 #define pb_int64_t int32_t
 #define pb_uint64_t uint32_t
 #else
 #define pb_int64_t int64_t
 #define pb_uint64_t uint64_t
 #endif
 /*******************************
 * pb_ostream_t implementation *
 *******************************/
 static bool checkreturn buf_write(pb_ostream_t *stream, const pb_byte_t *buf, size_t count)
 {
    size_t i;
    pb_byte_t *dest = (pb_byte_t*)stream->state;
    stream->state = dest + count;
    for (i = 0; i < count; i++)
        dest[i] = buf[i];
    return true;
 }
 pb_ostream_t pb_ostream_from_buffer(pb_byte_t *buf, size_t bufsize)
 {
    pb_ostream_t stream;
 #ifdef PB_BUFFER_ONLY
    stream.callback = (void*)1; /* Just a marker value */
 #else
    stream.callback = &buf_write;
 #endif
    stream.state = buf;
    stream.max_size = bufsize;
    stream.bytes_written = 0;
 #ifndef PB_NO_ERRMSG
    stream.errmsg = NULL;
 #endif
    return stream;
 }
 bool checkreturn pb_write(pb_ostream_t *stream, const pb_byte_t *buf, size_t count)
 {
    if (count > 0 && stream->callback != NULL)
    {
        if (stream->bytes_written + count < stream->bytes_written ||
            stream->bytes_written + count > stream->max_size)
        {
            PB_RETURN_ERROR(stream, "stream full");
        }
 #ifdef PB_BUFFER_ONLY
        if (!buf_write(stream, buf, count))
            PB_RETURN_ERROR(stream, "io error");
 #else        
        if (!stream->callback(stream, buf, count))
            PB_RETURN_ERROR(stream, "io error");
 #endif
    }
    stream->bytes_written += count;
    return true;
 }
 /*************************
 * Encode a single field *
 *************************/
 /* Read a bool value without causing undefined behavior even if the value
 * is invalid. See issue #434 and
 * https://stackoverflow.com/questions/27661768/weird-results-for-conditional
 */
 static bool safe_read_bool(const void *pSize)
 {
    const char *p = (const char *)pSize;
    size_t i;
    for (i = 0; i < sizeof(bool); i++)
    {
        if (p[i] != 0)
            return true;
    }
    return false;
 }
 /* Encode a static array. Handles the size calculations and possible packing. */
 static bool checkreturn encode_array(pb_ostream_t *stream, pb_field_iter_t *field)
 {
    pb_size_t i;
    pb_size_t count;
 #ifndef PB_ENCODE_ARRAYS_UNPACKED
    size_t size;
 #endif
    count = *(pb_size_t*)field->pSize;
    if (count == 0)
        return true;
    if (PB_ATYPE(field->type) != PB_ATYPE_POINTER && count > field->array_size)
        PB_RETURN_ERROR(stream, "array max size exceeded");
 #ifndef PB_ENCODE_ARRAYS_UNPACKED
    /* We always pack arrays if the datatype allows it. */
    if (PB_LTYPE(field->type) <= PB_LTYPE_LAST_PACKABLE)
    {
        if (!pb_encode_tag(stream, PB_WT_STRING, field->tag))
            return false;
        /* Determine the total size of packed array. */
        if (PB_LTYPE(field->type) == PB_LTYPE_FIXED32)
        {
            size = 4 * (size_t)count;
        }
        else if (PB_LTYPE(field->type) == PB_LTYPE_FIXED64)
        {
            size = 8 * (size_t)count;
        }
        else
        { 
            pb_ostream_t sizestream = PB_OSTREAM_SIZING;
            void *pData_orig = field->pData;
            for (i = 0; i < count; i++)
            {
                if (!pb_enc_varint(&sizestream, field))
                    PB_RETURN_ERROR(stream, PB_GET_ERROR(&sizestream));
                field->pData = (char*)field->pData + field->data_size;
            }
            field->pData = pData_orig;
            size = sizestream.bytes_written;
        }
        if (!pb_encode_varint(stream, (pb_uint64_t)size))
            return false;
        if (stream->callback == NULL)
            return pb_write(stream, NULL, size); /* Just sizing.. */
        /* Write the data */
        for (i = 0; i < count; i++)
        {
            if (PB_LTYPE(field->type) == PB_LTYPE_FIXED32 || PB_LTYPE(field->type) == PB_LTYPE_FIXED64)
            {
                if (!pb_enc_fixed(stream, field))
                    return false;
            }
            else
            {
                if (!pb_enc_varint(stream, field))
                    return false;
            }
            field->pData = (char*)field->pData + field->data_size;
        }
    }
    else /* Unpacked fields */
 #endif
    {
        for (i = 0; i < count; i++)
        {
            /* Normally the data is stored directly in the array entries, but
             * for pointer-type string and bytes fields, the array entries are
             * actually pointers themselves also. So we have to dereference once
             * more to get to the actual data. */
            if (PB_ATYPE(field->type) == PB_ATYPE_POINTER &&
                (PB_LTYPE(field->type) == PB_LTYPE_STRING ||
                 PB_LTYPE(field->type) == PB_LTYPE_BYTES))
            {
                bool status;
                void *pData_orig = field->pData;
                field->pData = *(void* const*)field->pData;
                if (!field->pData)
                {
                    /* Null pointer in array is treated as empty string / bytes */
                    status = pb_encode_tag_for_field(stream, field) &&
                             pb_encode_varint(stream, 0);
                }
                else
                {
                    status = encode_basic_field(stream, field);
                }
                field->pData = pData_orig;
                if (!status)
                    return false;
            }
            else
            {
                if (!encode_basic_field(stream, field))
                    return false;
            }
            field->pData = (char*)field->pData + field->data_size;
        }
    }
    return true;
 }
 /* In proto3, all fields are optional and are only encoded if their value is "non-zero".
 * This function implements the check for the zero value. */
 static bool checkreturn pb_check_proto3_default_value(const pb_field_iter_t *field)
 {
    pb_type_t type = field->type;
    if (PB_ATYPE(type) == PB_ATYPE_STATIC)
    {
        if (PB_HTYPE(type) == PB_HTYPE_REQUIRED)
        {
            /* Required proto2 fields inside proto3 submessage, pretty rare case */
            return false;
        }
        else if (PB_HTYPE(type) == PB_HTYPE_REPEATED)
        {
            /* Repeated fields inside proto3 submessage: present if count != 0 */
            return *(const pb_size_t*)field->pSize == 0;
        }
        else if (PB_HTYPE(type) == PB_HTYPE_ONEOF)
        {
            /* Oneof fields */
            return *(const pb_size_t*)field->pSize == 0;
        }
        else if (PB_HTYPE(type) == PB_HTYPE_OPTIONAL && field->pSize != NULL)
        {
            /* Proto2 optional fields inside proto3 message, or proto3
             * submessage fields. */
            return safe_read_bool(field->pSize) == false;
        }
        /* Rest is proto3 singular fields */
        if (PB_LTYPE(type) <= PB_LTYPE_LAST_PACKABLE)
        {
            /* Simple integer / float fields */
            pb_size_t i;
            const char *p = (const char*)field->pData;
            for (i = 0; i < field->data_size; i++)
            {
                if (p[i] != 0)
                {
                    return false;
                }
            }
            return true;
        }
        else if (PB_LTYPE(type) == PB_LTYPE_BYTES)
        {
            const pb_bytes_array_t *bytes = (const pb_bytes_array_t*)field->pData;
            return bytes->size == 0;
        }
        else if (PB_LTYPE(type) == PB_LTYPE_STRING)
        {
            return *(const char*)field->pData == '\0';
        }
        else if (PB_LTYPE(type) == PB_LTYPE_FIXED_LENGTH_BYTES)
        {
            /* Fixed length bytes is only empty if its length is fixed
             * as 0. Which would be pretty strange, but we can check
             * it anyway. */
            return field->data_size == 0;
        }
        else if (PB_LTYPE_IS_SUBMSG(type))
        {
            /* Check all fields in the submessage to find if any of them
             * are non-zero. The comparison cannot be done byte-per-byte
             * because the C struct may contain padding bytes that must
             * be skipped. Note that usually proto3 submessages have
             * a separate has_field that is checked earlier in this if.
             */
            pb_field_iter_t iter;
            if (pb_field_iter_begin(&iter, field->submsg_desc, field->pData))
            {
                do
                {
                    if (!pb_check_proto3_default_value(&iter))
                    {
                        return false;
                    }
                } while (pb_field_iter_next(&iter));
            }
            return true;
        }
    }
    else if (PB_ATYPE(type) == PB_ATYPE_POINTER)
    {
        return field->pData == NULL;
    }
    else if (PB_ATYPE(type) == PB_ATYPE_CALLBACK)
    {
        if (PB_LTYPE(type) == PB_LTYPE_EXTENSION)
        {
            const pb_extension_t *extension = *(const pb_extension_t* const *)field->pData;
            return extension == NULL;
        }
        else if (field->descriptor->field_callback == pb_default_field_callback)
        {
            pb_callback_t *pCallback = (pb_callback_t*)field->pData;
            return pCallback->funcs.encode == NULL;
        }
        else
        {
            return field->descriptor->field_callback == NULL;
        }
    }
    return false; /* Not typically reached, safe default for weird special cases. */
 }
 /* Encode a field with static or pointer allocation, i.e. one whose data
 * is available to the encoder directly. */
 static bool checkreturn encode_basic_field(pb_ostream_t *stream, const pb_field_iter_t *field)
 {
    if (!field->pData)
    {
        /* Missing pointer field */
        return true;
    }
    if (!pb_encode_tag_for_field(stream, field))
        return false;
    switch (PB_LTYPE(field->type))
    {
        case PB_LTYPE_BOOL:
            return pb_enc_bool(stream, field);
        case PB_LTYPE_VARINT:
        case PB_LTYPE_UVARINT:
        case PB_LTYPE_SVARINT:
            return pb_enc_varint(stream, field);
        case PB_LTYPE_FIXED32:
        case PB_LTYPE_FIXED64:
            return pb_enc_fixed(stream, field);
        case PB_LTYPE_BYTES:
            return pb_enc_bytes(stream, field);
        case PB_LTYPE_STRING:
            return pb_enc_string(stream, field);
        case PB_LTYPE_SUBMESSAGE:
        case PB_LTYPE_SUBMSG_W_CB:
            return pb_enc_submessage(stream, field);
        case PB_LTYPE_FIXED_LENGTH_BYTES:
            return pb_enc_fixed_length_bytes(stream, field);
        default:
            PB_RETURN_ERROR(stream, "invalid field type");
    }
 }
 /* Encode a field with callback semantics. This means that a user function is
 * called to provide and encode the actual data. */
 static bool checkreturn encode_callback_field(pb_ostream_t *stream, const pb_field_iter_t *field)
 {
    if (field->descriptor->field_callback != NULL)
    {
        if (!field->descriptor->field_callback(NULL, stream, field))
            PB_RETURN_ERROR(stream, "callback error");
    }
    return true;
 }
 /* Encode a single field of any callback, pointer or static type. */
 static bool checkreturn encode_field(pb_ostream_t *stream, pb_field_iter_t *field)
 {
    /* Check field presence */
    if (PB_HTYPE(field->type) == PB_HTYPE_ONEOF)
    {
        if (*(const pb_size_t*)field->pSize != field->tag)
        {
            /* Different type oneof field */
            return true;
        }
    }
    else if (PB_HTYPE(field->type) == PB_HTYPE_OPTIONAL)
    {
        if (field->pSize)
        {
            if (safe_read_bool(field->pSize) == false)
            {
                /* Missing optional field */
                return true;
            }
        }
        else if (PB_ATYPE(field->type) == PB_ATYPE_STATIC)
        {
            /* Proto3 singular field */
            if (pb_check_proto3_default_value(field))
                return true;
        }
    }
    if (!field->pData)
    {
        if (PB_HTYPE(field->type) == PB_HTYPE_REQUIRED)
            PB_RETURN_ERROR(stream, "missing required field");
        /* Pointer field set to NULL */
        return true;
    }
    /* Then encode field contents */
    if (PB_ATYPE(field->type) == PB_ATYPE_CALLBACK)
    {
        return encode_callback_field(stream, field);
    }
    else if (PB_HTYPE(field->type) == PB_HTYPE_REPEATED)
    {
        return encode_array(stream, field);
    }
    else
    {
        return encode_basic_field(stream, field);
    }
 }
 /* Default handler for extension fields. Expects to have a pb_msgdesc_t
 * pointer in the extension->type->arg field, pointing to a message with
 * only one field in it.  */
 static bool checkreturn default_extension_encoder(pb_ostream_t *stream, const pb_extension_t *extension)
 {
    pb_field_iter_t iter;
    if (!pb_field_iter_begin_extension_const(&iter, extension))
        PB_RETURN_ERROR(stream, "invalid extension");
    return encode_field(stream, &iter);
 }
 /* Walk through all the registered extensions and give them a chance
 * to encode themselves. */
 static bool checkreturn encode_extension_field(pb_ostream_t *stream, const pb_field_iter_t *field)
 {
    const pb_extension_t *extension = *(const pb_extension_t* const *)field->pData;
    while (extension)
    {
        bool status;
        if (extension->type->encode)
            status = extension->type->encode(stream, extension);
        else
            status = default_extension_encoder(stream, extension);
        if (!status)
            return false;
        extension = extension->next;
    }
    return true;
 }
 /*********************
 * Encode all fields *
 *********************/
 bool checkreturn pb_encode(pb_ostream_t *stream, const pb_msgdesc_t *fields, const void *src_struct)
 {
    pb_field_iter_t iter;
    if (!pb_field_iter_begin_const(&iter, fields, src_struct))
        return true; /* Empty message type */
    do {
        if (PB_LTYPE(iter.type) == PB_LTYPE_EXTENSION)
        {
            /* Special case for the extension field placeholder */
            if (!encode_extension_field(stream, &iter))
                return false;
        }
        else
        {
            /* Regular field */
            if (!encode_field(stream, &iter))
                return false;
        }
    } while (pb_field_iter_next(&iter));
    return true;
 }
 bool checkreturn pb_encode_ex(pb_ostream_t *stream, const pb_msgdesc_t *fields, const void *src_struct, unsigned int flags)
 {
  if ((flags & PB_ENCODE_DELIMITED) != 0)
  {
    return pb_encode_submessage(stream, fields, src_struct);
  }
  else if ((flags & PB_ENCODE_NULLTERMINATED) != 0)
  {
    const pb_byte_t zero = 0;
    if (!pb_encode(stream, fields, src_struct))
        return false;
    return pb_write(stream, &zero, 1);
  }
  else
  {
    return pb_encode(stream, fields, src_struct);
  }
 }
 bool pb_get_encoded_size(size_t *size, const pb_msgdesc_t *fields, const void *src_struct)
 {
    pb_ostream_t stream = PB_OSTREAM_SIZING;
    if (!pb_encode(&stream, fields, src_struct))
        return false;
    *size = stream.bytes_written;
    return true;
 }
 /********************
 * Helper functions *
 ********************/
 /* This function avoids 64-bit shifts as they are quite slow on many platforms. */
 static bool checkreturn pb_encode_varint_32(pb_ostream_t *stream, uint32_t low, uint32_t high)
 {
    size_t i = 0;
    pb_byte_t buffer[10];
    pb_byte_t byte = (pb_byte_t)(low & 0x7F);
    low >>= 7;
    while (i < 4 && (low != 0 || high != 0))
    {
        byte |= 0x80;
        buffer[i++] = byte;
        byte = (pb_byte_t)(low & 0x7F);
        low >>= 7;
    }
    if (high)
    {
        byte = (pb_byte_t)(byte | ((high & 0x07) << 4));
        high >>= 3;
        while (high)
        {
            byte |= 0x80;
            buffer[i++] = byte;
            byte = (pb_byte_t)(high & 0x7F);
            high >>= 7;
        }
    }
    buffer[i++] = byte;
    return pb_write(stream, buffer, i);
 }
 bool checkreturn pb_encode_varint(pb_ostream_t *stream, pb_uint64_t value)
 {
    if (value <= 0x7F)
    {
        /* Fast path: single byte */
        pb_byte_t byte = (pb_byte_t)value;
        return pb_write(stream, &byte, 1);
    }
    else
    {
 #ifdef PB_WITHOUT_64BIT
        return pb_encode_varint_32(stream, value, 0);
 #else
        return pb_encode_varint_32(stream, (uint32_t)value, (uint32_t)(value >> 32));
 #endif
    }
 }
 bool checkreturn pb_encode_svarint(pb_ostream_t *stream, pb_int64_t value)
 {
    pb_uint64_t zigzagged;
    if (value < 0)
        zigzagged = ~((pb_uint64_t)value << 1);
    else
        zigzagged = (pb_uint64_t)value << 1;
    return pb_encode_varint(stream, zigzagged);
 }
 bool checkreturn pb_encode_fixed32(pb_ostream_t *stream, const void *value)
 {
    uint32_t val = *(const uint32_t*)value;
    pb_byte_t bytes[4];
    bytes[0] = (pb_byte_t)(val & 0xFF);
    bytes[1] = (pb_byte_t)((val >> 8) & 0xFF);
    bytes[2] = (pb_byte_t)((val >> 16) & 0xFF);
    bytes[3] = (pb_byte_t)((val >> 24) & 0xFF);
    return pb_write(stream, bytes, 4);
 }
 #ifndef PB_WITHOUT_64BIT
 bool checkreturn pb_encode_fixed64(pb_ostream_t *stream, const void *value)
 {
    uint64_t val = *(const uint64_t*)value;
    pb_byte_t bytes[8];
    bytes[0] = (pb_byte_t)(val & 0xFF);
    bytes[1] = (pb_byte_t)((val >> 8) & 0xFF);
    bytes[2] = (pb_byte_t)((val >> 16) & 0xFF);
    bytes[3] = (pb_byte_t)((val >> 24) & 0xFF);
    bytes[4] = (pb_byte_t)((val >> 32) & 0xFF);
    bytes[5] = (pb_byte_t)((val >> 40) & 0xFF);
    bytes[6] = (pb_byte_t)((val >> 48) & 0xFF);
    bytes[7] = (pb_byte_t)((val >> 56) & 0xFF);
    return pb_write(stream, bytes, 8);
 }
 #endif
 bool checkreturn pb_encode_tag(pb_ostream_t *stream, pb_wire_type_t wiretype, uint32_t field_number)
 {
    pb_uint64_t tag = ((pb_uint64_t)field_number << 3) | wiretype;
    return pb_encode_varint(stream, tag);
 }
 bool pb_encode_tag_for_field ( pb_ostream_t* stream, const pb_field_iter_t* field )
 {
    pb_wire_type_t wiretype;
    switch (PB_LTYPE(field->type))
    {
        case PB_LTYPE_BOOL:
        case PB_LTYPE_VARINT:
        case PB_LTYPE_UVARINT:
        case PB_LTYPE_SVARINT:
            wiretype = PB_WT_VARINT;
            break;
        case PB_LTYPE_FIXED32:
            wiretype = PB_WT_32BIT;
            break;
        case PB_LTYPE_FIXED64:
            wiretype = PB_WT_64BIT;
            break;
        case PB_LTYPE_BYTES:
        case PB_LTYPE_STRING:
        case PB_LTYPE_SUBMESSAGE:
        case PB_LTYPE_SUBMSG_W_CB:
        case PB_LTYPE_FIXED_LENGTH_BYTES:
            wiretype = PB_WT_STRING;
            break;
        default:
            PB_RETURN_ERROR(stream, "invalid field type");
    }
    return pb_encode_tag(stream, wiretype, field->tag);
 }
 bool checkreturn pb_encode_string(pb_ostream_t *stream, const pb_byte_t *buffer, size_t size)
 {
    if (!pb_encode_varint(stream, (pb_uint64_t)size))
        return false;
    return pb_write(stream, buffer, size);
 }
 bool checkreturn pb_encode_submessage(pb_ostream_t *stream, const pb_msgdesc_t *fields, const void *src_struct)
 {
    /* First calculate the message size using a non-writing substream. */
    pb_ostream_t substream = PB_OSTREAM_SIZING;
    size_t size;
    bool status;
    if (!pb_encode(&substream, fields, src_struct))
    {
 #ifndef PB_NO_ERRMSG
        stream->errmsg = substream.errmsg;
 #endif
        return false;
    }
    size = substream.bytes_written;
    if (!pb_encode_varint(stream, (pb_uint64_t)size))
        return false;
    if (stream->callback == NULL)
        return pb_write(stream, NULL, size); /* Just sizing */
    if (stream->bytes_written + size > stream->max_size)
        PB_RETURN_ERROR(stream, "stream full");
    /* Use a substream to verify that a callback doesn't write more than
     * what it did the first time. */
    substream.callback = stream->callback;
    substream.state = stream->state;
    substream.max_size = size;
    substream.bytes_written = 0;
 #ifndef PB_NO_ERRMSG
    substream.errmsg = NULL;
 #endif
    status = pb_encode(&substream, fields, src_struct);
    stream->bytes_written += substream.bytes_written;
    stream->state = substream.state;
 #ifndef PB_NO_ERRMSG
    stream->errmsg = substream.errmsg;
 #endif
    if (substream.bytes_written != size)
        PB_RETURN_ERROR(stream, "submsg size changed");
    return status;
 }
 /* Field encoders */
 static bool checkreturn pb_enc_bool(pb_ostream_t *stream, const pb_field_iter_t *field)
 {
    uint32_t value = safe_read_bool(field->pData) ? 1 : 0;
    PB_UNUSED(field);
    return pb_encode_varint(stream, value);
 }
 static bool checkreturn pb_enc_varint(pb_ostream_t *stream, const pb_field_iter_t *field)
 {
    if (PB_LTYPE(field->type) == PB_LTYPE_UVARINT)
    {
        /* Perform unsigned integer extension */
        pb_uint64_t value = 0;
        if (field->data_size == sizeof(uint_least8_t))
            value = *(const uint_least8_t*)field->pData;
        else if (field->data_size == sizeof(uint_least16_t))
            value = *(const uint_least16_t*)field->pData;
        else if (field->data_size == sizeof(uint32_t))
            value = *(const uint32_t*)field->pData;
        else if (field->data_size == sizeof(pb_uint64_t))
            value = *(const pb_uint64_t*)field->pData;
        else
            PB_RETURN_ERROR(stream, "invalid data_size");
        return pb_encode_varint(stream, value);
    }
    else
    {
        /* Perform signed integer extension */
        pb_int64_t value = 0;
        if (field->data_size == sizeof(int_least8_t))
            value = *(const int_least8_t*)field->pData;
        else if (field->data_size == sizeof(int_least16_t))
            value = *(const int_least16_t*)field->pData;
        else if (field->data_size == sizeof(int32_t))
            value = *(const int32_t*)field->pData;
        else if (field->data_size == sizeof(pb_int64_t))
            value = *(const pb_int64_t*)field->pData;
        else
            PB_RETURN_ERROR(stream, "invalid data_size");
        if (PB_LTYPE(field->type) == PB_LTYPE_SVARINT)
            return pb_encode_svarint(stream, value);
 #ifdef PB_WITHOUT_64BIT
        else if (value < 0)
            return pb_encode_varint_32(stream, (uint32_t)value, (uint32_t)-1);
 #endif
        else
            return pb_encode_varint(stream, (pb_uint64_t)value);
    }
 }
 static bool checkreturn pb_enc_fixed(pb_ostream_t *stream, const pb_field_iter_t *field)
 {
 #ifdef PB_CONVERT_DOUBLE_FLOAT
    if (field->data_size == sizeof(float) && PB_LTYPE(field->type) == PB_LTYPE_FIXED64)
    {
        return pb_encode_float_as_double(stream, *(float*)field->pData);
    }
 #endif
    if (field->data_size == sizeof(uint32_t))
    {
        return pb_encode_fixed32(stream, field->pData);
    }
 #ifndef PB_WITHOUT_64BIT
    else if (field->data_size == sizeof(uint64_t))
    {
        return pb_encode_fixed64(stream, field->pData);
    }
 #endif
    else
    {
        PB_RETURN_ERROR(stream, "invalid data_size");
    }
 }
 static bool checkreturn pb_enc_bytes(pb_ostream_t *stream, const pb_field_iter_t *field)
 {
    const pb_bytes_array_t *bytes = NULL;
    bytes = (const pb_bytes_array_t*)field->pData;
    if (bytes == NULL)
    {
        /* Treat null pointer as an empty bytes field */
        return pb_encode_string(stream, NULL, 0);
    }
    if (PB_ATYPE(field->type) == PB_ATYPE_STATIC &&
        bytes->size > field->data_size - offsetof(pb_bytes_array_t, bytes))
    {
        PB_RETURN_ERROR(stream, "bytes size exceeded");
    }
    return pb_encode_string(stream, bytes->bytes, (size_t)bytes->size);
 }
 static bool checkreturn pb_enc_string(pb_ostream_t *stream, const pb_field_iter_t *field)
 {
    size_t size = 0;
    size_t max_size = (size_t)field->data_size;
    const char *str = (const char*)field->pData;
    if (PB_ATYPE(field->type) == PB_ATYPE_POINTER)
    {
        max_size = (size_t)-1;
    }
    else
    {
        /* pb_dec_string() assumes string fields end with a null
         * terminator when the type isn't PB_ATYPE_POINTER, so we
         * shouldn't allow more than max-1 bytes to be written to
         * allow space for the null terminator.
         */
        if (max_size == 0)
            PB_RETURN_ERROR(stream, "zero-length string");
        max_size -= 1;
    }
    if (str == NULL)
    {
        size = 0; /* Treat null pointer as an empty string */
    }
    else
    {
        const char *p = str;
        /* strnlen() is not always available, so just use a loop */
        while (size < max_size && *p != '\0')
        {
            size++;
            p++;
        }
        if (*p != '\0')
        {
            PB_RETURN_ERROR(stream, "unterminated string");
        }
    }
 #ifdef PB_VALIDATE_UTF8
    if (!pb_validate_utf8(str))
        PB_RETURN_ERROR(stream, "invalid utf8");
 #endif
    return pb_encode_string(stream, (const pb_byte_t*)str, size);
 }
 static bool checkreturn pb_enc_submessage(pb_ostream_t *stream, const pb_field_iter_t *field)
 {
    if (field->submsg_desc == NULL)
        PB_RETURN_ERROR(stream, "invalid field descriptor");
    if (PB_LTYPE(field->type) == PB_LTYPE_SUBMSG_W_CB && field->pSize != NULL)
    {
        /* Message callback is stored right before pSize. */
        pb_callback_t *callback = (pb_callback_t*)field->pSize - 1;
        if (callback->funcs.encode)
        {
            if (!callback->funcs.encode(stream, field, &callback->arg))
                return false;
        }
    }
    return pb_encode_submessage(stream, field->submsg_desc, field->pData);
 }
 static bool checkreturn pb_enc_fixed_length_bytes(pb_ostream_t *stream, const pb_field_iter_t *field)
 {
    return pb_encode_string(stream, (const pb_byte_t*)field->pData, (size_t)field->data_size);
 }
 #ifdef PB_CONVERT_DOUBLE_FLOAT
 bool pb_encode_float_as_double(pb_ostream_t *stream, float value)
 {
    union { float f; uint32_t i; } in;
    uint_least8_t sign;
    int exponent;
    uint64_t mantissa;
    in.f = value;
    /* Decompose input value */
    sign = (uint_least8_t)((in.i >> 31) & 1);
    exponent = (int)((in.i >> 23) & 0xFF) - 127;
    mantissa = in.i & 0x7FFFFF;
    if (exponent == 128)
    {
        /* Special value (NaN etc.) */
        exponent = 1024;
    }
    else if (exponent == -127)
    {
        if (!mantissa)
        {
            /* Zero */
            exponent = -1023;
        }
        else
        {
            /* Denormalized */
            mantissa <<= 1;
            while (!(mantissa & 0x800000))
            {
                mantissa <<= 1;
                exponent--;
            }
            mantissa &= 0x7FFFFF;
        }
    }
    /* Combine fields */
    mantissa <<= 29;
    mantissa |= (uint64_t)(exponent + 1023) << 52;
    mantissa |= (uint64_t)sign << 63;
    return pb_encode_fixed64(stream, &mantissa);
 }
 #endif
--- a/components/nanopb/pb_encode.h
+++ b/components/nanopb/pb_encode.h
@ -0,0 +1,185 @@
 /* pb_encode.h: Functions to encode protocol buffers. Depends on pb_encode.c.
 * The main function is pb_encode. You also need an output stream, and the
 * field descriptions created by nanopb_generator.py.
 */
 #ifndef PB_ENCODE_H_INCLUDED
 #define PB_ENCODE_H_INCLUDED
 #include "pb.h"
 #ifdef __cplusplus
 extern "C" {
 #endif
 /* Structure for defining custom output streams. You will need to provide
 * a callback function to write the bytes to your storage, which can be
 * for example a file or a network socket.
 *
 * The callback must conform to these rules:
 *
 * 1) Return false on IO errors. This will cause encoding to abort.
 * 2) You can use state to store your own data (e.g. buffer pointer).
 * 3) pb_write will update bytes_written after your callback runs.
 * 4) Substreams will modify max_size and bytes_written. Don't use them
 *    to calculate any pointers.
 */
 struct pb_ostream_s
 {
 #ifdef PB_BUFFER_ONLY
    /* Callback pointer is not used in buffer-only configuration.
     * Having an int pointer here allows binary compatibility but
     * gives an error if someone tries to assign callback function.
     * Also, NULL pointer marks a 'sizing stream' that does not
     * write anything.
     */
    int *callback;
 #else
    bool (*callback)(pb_ostream_t *stream, const pb_byte_t *buf, size_t count);
 #endif
    void *state;          /* Free field for use by callback implementation. */
    size_t max_size;      /* Limit number of output bytes written (or use SIZE_MAX). */
    size_t bytes_written; /* Number of bytes written so far. */
 #ifndef PB_NO_ERRMSG
    const char *errmsg;
 #endif
 };
 /***************************
 * Main encoding functions *
 ***************************/
 /* Encode a single protocol buffers message from C structure into a stream.
 * Returns true on success, false on any failure.
 * The actual struct pointed to by src_struct must match the description in fields.
 * All required fields in the struct are assumed to have been filled in.
 *
 * Example usage:
 *    MyMessage msg = {};
 *    uint8_t buffer[64];
 *    pb_ostream_t stream;
 *
 *    msg.field1 = 42;
 *    stream = pb_ostream_from_buffer(buffer, sizeof(buffer));
 *    pb_encode(&stream, MyMessage_fields, &msg);
 */
 bool pb_encode(pb_ostream_t *stream, const pb_msgdesc_t *fields, const void *src_struct);
 /* Extended version of pb_encode, with several options to control the
 * encoding process:
 *
 * PB_ENCODE_DELIMITED:      Prepend the length of message as a varint.
 *                           Corresponds to writeDelimitedTo() in Google's
 *                           protobuf API.
 *
 * PB_ENCODE_NULLTERMINATED: Append a null byte to the message for termination.
 *                           NOTE: This behaviour is not supported in most other
 *                           protobuf implementations, so PB_ENCODE_DELIMITED
 *                           is a better option for compatibility.
 */
 #define PB_ENCODE_DELIMITED       0x02U
 #define PB_ENCODE_NULLTERMINATED  0x04U
 bool pb_encode_ex(pb_ostream_t *stream, const pb_msgdesc_t *fields, const void *src_struct, unsigned int flags);
 /* Defines for backwards compatibility with code written before nanopb-0.4.0 */
 #define pb_encode_delimited(s,f,d) pb_encode_ex(s,f,d, PB_ENCODE_DELIMITED)
 #define pb_encode_nullterminated(s,f,d) pb_encode_ex(s,f,d, PB_ENCODE_NULLTERMINATED)
 /* Encode the message to get the size of the encoded data, but do not store
 * the data. */
 bool pb_get_encoded_size(size_t *size, const pb_msgdesc_t *fields, const void *src_struct);
 /**************************************
 * Functions for manipulating streams *
 **************************************/
 /* Create an output stream for writing into a memory buffer.
 * The number of bytes written can be found in stream.bytes_written after
 * encoding the message.
 *
 * Alternatively, you can use a custom stream that writes directly to e.g.
 * a file or a network socket.
 */
 pb_ostream_t pb_ostream_from_buffer(pb_byte_t *buf, size_t bufsize);
 /* Pseudo-stream for measuring the size of a message without actually storing
 * the encoded data.
 * 
 * Example usage:
 *    MyMessage msg = {};
 *    pb_ostream_t stream = PB_OSTREAM_SIZING;
 *    pb_encode(&stream, MyMessage_fields, &msg);
 *    printf("Message size is %d\n", stream.bytes_written);
 */
 #ifndef PB_NO_ERRMSG
 #define PB_OSTREAM_SIZING {0,0,0,0,0}
 #else
 #define PB_OSTREAM_SIZING {0,0,0,0}
 #endif
 /* Function to write into a pb_ostream_t stream. You can use this if you need
 * to append or prepend some custom headers to the message.
 */
 bool pb_write(pb_ostream_t *stream, const pb_byte_t *buf, size_t count);
 /************************************************
 * Helper functions for writing field callbacks *
 ************************************************/
 /* Encode field header based on type and field number defined in the field
 * structure. Call this from the callback before writing out field contents. */
 bool pb_encode_tag_for_field(pb_ostream_t *stream, const pb_field_iter_t *field);
 /* Encode field header by manually specifing wire type. You need to use this
 * if you want to write out packed arrays from a callback field. */
 bool pb_encode_tag(pb_ostream_t *stream, pb_wire_type_t wiretype, uint32_t field_number);
 /* Encode an integer in the varint format.
 * This works for bool, enum, int32, int64, uint32 and uint64 field types. */
 #ifndef PB_WITHOUT_64BIT
 bool pb_encode_varint(pb_ostream_t *stream, uint64_t value);
 #else
 bool pb_encode_varint(pb_ostream_t *stream, uint32_t value);
 #endif
 /* Encode an integer in the zig-zagged svarint format.
 * This works for sint32 and sint64. */
 #ifndef PB_WITHOUT_64BIT
 bool pb_encode_svarint(pb_ostream_t *stream, int64_t value);
 #else
 bool pb_encode_svarint(pb_ostream_t *stream, int32_t value);
 #endif
 /* Encode a string or bytes type field. For strings, pass strlen(s) as size. */
 bool pb_encode_string(pb_ostream_t *stream, const pb_byte_t *buffer, size_t size);
 /* Encode a fixed32, sfixed32 or float value.
 * You need to pass a pointer to a 4-byte wide C variable. */
 bool pb_encode_fixed32(pb_ostream_t *stream, const void *value);
 #ifndef PB_WITHOUT_64BIT
 /* Encode a fixed64, sfixed64 or double value.
 * You need to pass a pointer to a 8-byte wide C variable. */
 bool pb_encode_fixed64(pb_ostream_t *stream, const void *value);
 #endif
 #ifdef PB_CONVERT_DOUBLE_FLOAT
 /* Encode a float value so that it appears like a double in the encoded
 * message. */
 bool pb_encode_float_as_double(pb_ostream_t *stream, float value);
 #endif
 /* Encode a submessage field.
 * You need to pass the pb_field_t array and pointer to struct, just like
 * with pb_encode(). This internally encodes the submessage twice, first to
 * calculate message size and then to actually write it out.
 */
 bool pb_encode_submessage(pb_ostream_t *stream, const pb_msgdesc_t *fields, const void *src_struct);
 #ifdef __cplusplus
 } /* extern "C" */
 #endif
 #endif
--- a/components/ssd1306/include/ssd1306.h
+++ b/components/ssd1306/include/ssd1306.h
@ -91,8 +91,27 @@ void ssd1306_clear_line(uint8_t i2address, uint8_t line, bool invert);
 */
 void ssd1306_clear(uint8_t i2address);
 /**
- * @brief write text to display
+ * @brief set display on or offf
 * 
 * @param[in] i2address I2C address of SSD1306 
 * @param[in] on true if display on, false if display off
 */
 void ssd1306_on(uint8_t i2address, bool on);
 /**
 * @brief write text to display line at starting column
 * 
 * @param[in] i2address I2C address of SSD1306
 * @param[in] text text to display  
 * @param[in] line the line to write to
 * @param[in] offset number of offset chars to start
 */
 void ssd1306_text_line_column(uint8_t i2address, char *text, uint8_t line, uint8_t offset, bool invert);
 /**
 * @brief write text to display line
 * 
 * @param[in] i2address I2C address of SSD1306
 * @param[in] text text to display  
--- a/components/ssd1306/ssd1306.c
+++ b/components/ssd1306/ssd1306.c
@ -80,7 +80,7 @@ void ssd1306_start(uint8_t i2address)
    // Turn the Display ON
    i2c_master_write_byte(cmd, SSD1306_CMD_ON, true);
    i2c_master_stop(cmd);
-    ESP_ERROR_CHECK(i2c_master_cmd_begin(I2C_NUM_0, cmd, 10 / portTICK_PERIOD_MS));
+    ESP_ERROR_CHECK_WITHOUT_ABORT(i2c_master_cmd_begin(I2C_NUM_0, cmd, 10 / portTICK_PERIOD_MS));
    i2c_cmd_link_delete(cmd);
 }
@ -101,7 +101,7 @@ void ssd1306_init_data(uint8_t i2address)
    i2c_master_write_byte(cmd, SSD1306_CMD_PAGE, true);
    i2c_master_stop(cmd);
-    ESP_ERROR_CHECK(i2c_master_cmd_begin(I2C_NUM_0, cmd, 10 / portTICK_PERIOD_MS));
+    ESP_ERROR_CHECK_WITHOUT_ABORT(i2c_master_cmd_begin(I2C_NUM_0, cmd, 10 / portTICK_PERIOD_MS));
    i2c_cmd_link_delete(cmd);
 }
@ -144,8 +144,46 @@ void ssd1306_clear(uint8_t i2address)
    }
 }
-void ssd1306_text_line(uint8_t i2address, char *text, uint8_t line, bool invert)
+void ssd1306_on(uint8_t i2address, bool on)
 {
    i2c_cmd_handle_t cmd = i2c_cmd_link_create();
    i2c_master_start(cmd);
    // Begin the I2C comm with SSD1306's address (SLA+Write)
    i2c_master_write_byte(cmd, (i2address << 1) | I2C_MASTER_WRITE, true);
    // Tell the SSD1306 that a command stream is incoming
    i2c_master_write_byte(cmd, SSD1306_CONTROL_CMD_STREAM, true);
    if (on)
    {
        // Turn the Display ON
        i2c_master_write_byte(cmd, SSD1306_CMD_ON, true);
    }
    else
    {
        // Turn the Display OFF
        i2c_master_write_byte(cmd, SSD1306_CMD_OFF, true);
    }
    i2c_master_stop(cmd);
    i2c_master_cmd_begin(I2C_NUM_0, cmd, 10 / portTICK_PERIOD_MS);
    i2c_cmd_link_delete(cmd);
 }
 void ssd1306_text_line_column(uint8_t i2address, char *text, uint8_t line, uint8_t offset, bool invert)
 {
    uint8_t font_width = sizeof(ascii_font_5x8[0]);
    uint8_t column = offset * font_width;
    if (column > SSD1306_COLUMNS)
    {
        column = 0;
    }
    size_t columns = strlen(text) * font_width;
    if (columns > (SSD1306_COLUMNS - column))
    {
        columns = (SSD1306_COLUMNS - column);
    }
    ssd1306_init_data(i2address);
    i2c_cmd_handle_t cmd;
@ -155,24 +193,23 @@ void ssd1306_text_line(uint8_t i2address, char *text, uint8_t line, bool invert)
    i2c_master_write_byte(cmd, (i2address << 1) | I2C_MASTER_WRITE, true);
    i2c_master_write_byte(cmd, SSD1306_CONTROL_CMD_STREAM, true);
-    i2c_master_write_byte(cmd, SSD1306_CMD_COLUMN_LOW, true);
+    i2c_master_write_byte(cmd, SSD1306_CMD_COLUMN_LOW | (column & 0XF), true);
-    i2c_master_write_byte(cmd, SSD1306_CMD_COLUMN_HIGH, true);
+    i2c_master_write_byte(cmd, SSD1306_CMD_COLUMN_HIGH | (column >> 4), true);
    i2c_master_write_byte(cmd, SSD1306_CMD_PAGE | line, true);
    i2c_master_stop(cmd);
    i2c_master_cmd_begin(I2C_NUM_0, cmd, 10 / portTICK_PERIOD_MS);
    i2c_cmd_link_delete(cmd);
-    uint8_t *linedata = calloc(SSD1306_COLUMNS, sizeof(uint8_t));
+    uint8_t *linedata = calloc(columns, sizeof(uint8_t));
-    uint8_t font_width = sizeof(ascii_font_5x8[0]);
+    for (uint8_t i = 0; i < (columns / font_width); i++)
    for (uint8_t i = 0; i < strlen(text); i++)
    {
        memcpy(&linedata[i * font_width], ascii_font_5x8[(uint8_t)text[i]], font_width);
    }
    if (invert)
    {
-        for (uint8_t i = 0; i < SSD1306_COLUMNS; i++)
+        for (uint8_t i = 0; i < columns; i++)
        {
            linedata[i] = ~linedata[i];
        }
@ -183,11 +220,16 @@ void ssd1306_text_line(uint8_t i2address, char *text, uint8_t line, bool invert)
    i2c_master_write_byte(cmd, (i2address << 1) | I2C_MASTER_WRITE, true);
    i2c_master_write_byte(cmd, SSD1306_CONTROL_DATA_STREAM, true);
-    i2c_master_write(cmd, linedata, SSD1306_COLUMNS, true);
+    i2c_master_write(cmd, linedata, columns, true);
    i2c_master_stop(cmd);
    i2c_master_cmd_begin(I2C_NUM_0, cmd, 10 / portTICK_PERIOD_MS);
    i2c_cmd_link_delete(cmd);
    free(linedata);
 }
 void ssd1306_text_line(uint8_t i2address, char *text, uint8_t line, bool invert)
 {
    ssd1306_text_line_column(i2address, text, line, 0, invert);
 }
--- a/main/main.c
+++ b/main/main.c
@ -22,34 +22,151 @@
 #include "ena.h"
 #include "ena-storage.h"
 #include "ena-beacons.h"
 #include "ena-exposure.h"
 #include "ena-interface.h"
 #include "ena-interface-menu.h"
 #include "ena-interface-datetime.h"
 #include "ssd1306.h"
 #include "ds3231.h"
 #include "sdkconfig.h"
 static time_t curtime;
 void interface_display_time(void *pvParameter)
 {
    static char *curtime_text;
    static struct tm rtc_time;
    static bool edit_invert = false;
    while (1)
    {
        curtime = time(NULL);
        localtime_r(&curtime, &rtc_time);
        curtime_text = asctime(&rtc_time);
        ssd1306_text_line(SSD1306_ADDRESS, curtime_text, 0, false);
        gmtime_r(&curtime, &rtc_time);
        curtime_text = asctime(&rtc_time);
        ssd1306_text_line(SSD1306_ADDRESS, curtime_text, 1, false);
        if (ena_interface_get_state() == ENA_INTERFACE_STATE_SET_DATETIME)
        {
            edit_invert = !edit_invert;
            ds3231_set_time(&rtc_time);
            char edit_year[4] = "";
            char edit_month[3] = "";
            char edit_day[2] = "";
            char edit_hour[2] = "";
            char edit_minute[2] = "";
            char edit_second[2] = "";
            switch (ena_interface_datetime_state())
            {
            case ENA_INTERFACE_DATETIME_STATE_YEAR:
                memcpy(&edit_year, &curtime_text[20], 4);
                ssd1306_text_line_column(SSD1306_ADDRESS, edit_year, 0, 20, edit_invert);
                break;
            case ENA_INTERFACE_DATETIME_STATE_MONTH:
                memcpy(&edit_month, &curtime_text[4], 3);
                ssd1306_text_line_column(SSD1306_ADDRESS, edit_month, 0, 4, edit_invert);
                break;
            case ENA_INTERFACE_DATETIME_STATE_DAY:
                memcpy(&edit_day, &curtime_text[8], 2);
                ssd1306_text_line_column(SSD1306_ADDRESS, edit_day, 0, 8, edit_invert);
                break;
            case ENA_INTERFACE_DATETIME_STATE_HOUR:
                memcpy(&edit_hour, &curtime_text[11], 2);
                ssd1306_text_line_column(SSD1306_ADDRESS, edit_hour, 0, 11, edit_invert);
                break;
            case ENA_INTERFACE_DATETIME_STATE_MINUTE:
                memcpy(&edit_minute, &curtime_text[14], 2);
                ssd1306_text_line_column(SSD1306_ADDRESS, edit_minute, 0, 14, edit_invert);
                break;
            case ENA_INTERFACE_DATETIME_STATE_SECONDS:
                memcpy(&edit_second[0], &curtime_text[17], 2);
                ssd1306_text_line_column(SSD1306_ADDRESS, edit_second, 0, 17, edit_invert);
                break;
            }
        }
        vTaskDelay(500 / portTICK_PERIOD_MS);
    }
 }
 void interface_display_status(void *pvParameter)
 {
    static bool get_status = true;
    while (1)
    {
        if (ena_interface_get_state() == ENA_INTERFACE_STATE_STATUS)
        {
            if (get_status)
            {
                ena_exposure_summary_t summary;
                ena_exposure_summary(ena_exposure_default_config(), &summary);
                char buffer[23];
                sprintf(buffer, "Days: %d", summary.days_since_last_exposure);
                ssd1306_text_line(SSD1306_ADDRESS, buffer, 3, false);
                sprintf(buffer, "Exposures: %d", summary.num_exposures);
                ssd1306_text_line(SSD1306_ADDRESS, buffer, 4, false);
                sprintf(buffer, "Score: %d, Max: %d", summary.risk_score_sum, summary.max_risk_score);
                ssd1306_text_line(SSD1306_ADDRESS, buffer, 5, false);
                get_status = false;
            }
        }
        else if (!get_status)
        {
            ssd1306_clear_line(SSD1306_ADDRESS, 2, false);
            ssd1306_clear_line(SSD1306_ADDRESS, 3, false);
            ssd1306_clear_line(SSD1306_ADDRESS, 4, false);
            get_status = true;
        }
        vTaskDelay(500 / portTICK_PERIOD_MS);
    }
 }
 void interface_display_idle(void *pvParameter)
 {
    static bool set_status = true;
    while (1)
    {
        if (ena_interface_get_state() == ENA_INTERFACE_STATE_IDLE)
        {
            if (set_status)
            {
                ssd1306_on(SSD1306_ADDRESS, false);
                set_status = false;
            }
        }
        else if (!set_status)
        {
            ssd1306_on(SSD1306_ADDRESS, true);
            set_status = true;
        }
        vTaskDelay(500 / portTICK_PERIOD_MS);
    }
 }
 void app_main(void)
 {
-    // DEBUG set time
+    struct tm rtc_time;
-    struct timeval tv = {1594843200, 0}; // current hardcoded timestamp ¯\_(ツ)_/¯
+    ds3231_get_time(&rtc_time);
    curtime = mktime(&rtc_time);
    struct timeval tv = {0};
    tv.tv_sec = curtime;
    settimeofday(&tv, NULL);
    esp_log_level_set(ENA_STORAGE_LOG, ESP_LOG_INFO);
    setenv("TZ", "UTC-2", 1);
    tzset();
    ssd1306_start(SSD1306_ADDRESS);
    ssd1306_clear(SSD1306_ADDRESS);
    // TODO
    ssd1306_text_line(SSD1306_ADDRESS, "     TODO       TODO", 0, false);
    ssd1306_text_line(SSD1306_ADDRESS, "           TODO", 1, true);
    ssd1306_text_line(SSD1306_ADDRESS, "     TODO       TODO", 2, false);
    ssd1306_text_line(SSD1306_ADDRESS, "           TODO", 3, true);
    ssd1306_text_line(SSD1306_ADDRESS, "     TODO       TODO", 4, false);
    ssd1306_text_line(SSD1306_ADDRESS, "           TODO", 5, true);
    ssd1306_text_line(SSD1306_ADDRESS, "     TODO       TODO", 6, false);
    ssd1306_text_line(SSD1306_ADDRESS, "           TODO", 7, true);
    ena_interface_start();
    ena_interface_menu_start();
    ena_start();
    xTaskCreate(&interface_display_time, "interface_display_time", 4096, NULL, 5, NULL);
    xTaskCreate(&interface_display_status, "interface_display_status", 4096, NULL, 5, NULL);
    xTaskCreate(&interface_display_idle, "interface_display_idle", 4096, NULL, 5, NULL);
 }