encryption and decryption of advertising data

#include <stdio.h>
#include <stdint.h>
#include <stdbool.h>
#include "nordic_common.h"
#include "app_error.h"
#include "app_uart.h"
#include "ble_db_discovery.h"
#include "app_timer.h"
#include "app_util.h"
#include "bsp_btn_ble.h"
#include "ble.h"
#include "ble_gap.h"
#include "ble_hci.h"
#include "nrf_sdh.h"
#include "nrf_sdh_ble.h"
#include "nrf_sdh_soc.h"
#include "ble_nus_c.h"
#include "nrf_ble_gatt.h"
#include "nrf_pwr_mgmt.h"
#include "nrf_ble_scan.h"

#include "nrf_log.h"
#include "nrf_log_ctrl.h"
#include "nrf_log_default_backends.h"

#include "nrf_delay.h"
#include "ble_srv_common.h"

#include "ble_advdata.h"

#define APP_BLE_CONN_CFG_TAG    1                                       /**< Tag that refers to the BLE stack configuration set with @ref sd_ble_cfg_set. The default tag is @ref BLE_CONN_CFG_TAG_DEFAULT. */
#define APP_BLE_OBSERVER_PRIO   3                                       /**< BLE observer priority of the application. There is no need to modify this value. */

#define UART_TX_BUF_SIZE        256                                     /**< UART TX buffer size. */
#define UART_RX_BUF_SIZE        256                                     /**< UART RX buffer size. */

#define NUS_SERVICE_UUID_TYPE   BLE_UUID_TYPE_VENDOR_BEGIN              /**< UUID type for the Nordic UART Service (vendor specific). */

#define ECHOBACK_BLE_UART_DATA  1                                       /**< Echo the UART data that is received over the Nordic UART Service (NUS) back to the sender. */
#define ECB_KEY_LEN            (16UL)
#define COUNTER_BYTE_LEN       (4UL)
#define NONCE_RAND_BYTE_LEN    (12UL)



// The RNG wait values are typical and not guaranteed. See Product Specifications for more info.
#ifdef NRF51
#define RNG_BYTE_WAIT_US       (677UL)
#elif defined NRF52
#define RNG_BYTE_WAIT_US       (124UL)
#else
#error "Either NRF51 or NRF52 must be defined."
#endif     

BLE_NUS_C_DEF(m_ble_nus_c);                                             /**< BLE Nordic UART Service (NUS) client instance. */
NRF_BLE_GATT_DEF(m_gatt);                                               /**< GATT module instance. */
BLE_DB_DISCOVERY_DEF(m_db_disc);                                        /**< Database discovery module instance. */
NRF_BLE_SCAN_DEF(m_scan);                                               /**< Scanning Module instance. */

static uint16_t m_ble_nus_max_data_len = BLE_GATT_ATT_MTU_DEFAULT - OPCODE_LENGTH - HANDLE_LENGTH; /**< Maximum length of data (in bytes) that can be transmitted to the peer by the Nordic UART service module. */

static bool m_initialized = false;
static nrf_ecb_hal_data_t m_ecb_data;
static uint8_t m_ecb_key[16] = {0x6E,0x88,0x90,0x8D,0x75,0xBB,0x95,0xEA,0x2C,0x65,0x93,0x01,0x43,0xF8,0x1B,0x5F};
static uint8_t nounce[16];
static uint8_t m_beacon_info[0x17];

/**@brief NUS UUID. */
static ble_uuid_t const m_nus_uuid =
{
    .uuid = BLE_UUID_IMMEDIATE_ALERT_SERVICE,
    .type = BLE_UUID_TYPE_BLE
};


void assert_nrf_callback(uint16_t line_num, const uint8_t * p_file_name)
{
    app_error_handler(0xDEADBEEF, line_num, p_file_name);
}


void ctr_init(const uint8_t * p_nonce, const uint8_t * p_ecb_key)
{
    m_initialized = true;

    // Save the key.
    memcpy(&m_ecb_data.key[0], p_ecb_key, ECB_KEY_LEN);

    // Copy the nonce.
    memcpy(&m_ecb_data.ciphertext[COUNTER_BYTE_LEN],
	          &p_nonce[COUNTER_BYTE_LEN],
	          NONCE_RAND_BYTE_LEN);

    // Zero the counter value.
    memset(&m_ecb_data.cleartext[0], 0x00, COUNTER_BYTE_LEN);
}

static uint32_t crypt(uint8_t * buf)
{
    uint8_t  i;
    uint32_t err_code;

    if (!m_initialized)
    {
	    return NRF_ERROR_INVALID_STATE;
    }

    err_code = sd_ecb_block_encrypt(&m_ecb_data);
    if (NRF_SUCCESS != err_code)
    {
	    return err_code;
    }

    for (i=0; i < ECB_KEY_LEN; i++)
    {
	    buf[i] ^= m_ecb_data.ciphertext[i];
    }

    // Increment the counter.
    (*((uint32_t*) m_ecb_data.cleartext))++;

    return NRF_SUCCESS;
}


uint32_t ctr_encrypt(uint8_t * p_clear_text)
{
    return crypt(p_clear_text);
}


uint32_t ctr_decrypt(uint8_t * p_cipher_text)
{
    return crypt(p_cipher_text);
}


/**@brief Function for starting scanning. */
static void scan_start(void)
{
    ret_code_t ret;

    ret = nrf_ble_scan_start(&m_scan);
    APP_ERROR_CHECK(ret);

    ret = bsp_indication_set(BSP_INDICATE_SCANNING);
    APP_ERROR_CHECK(ret);
}


/**@brief Function for handling Scanning Module events.
 */
static void scan_evt_handler(scan_evt_t const * p_scan_evt)
{
    ret_code_t err_code;

    switch(p_scan_evt->scan_evt_id)
    {
         case NRF_BLE_SCAN_EVT_CONNECTING_ERROR:
         {
              err_code = p_scan_evt->params.connecting_err.err_code;
              APP_ERROR_CHECK(err_code);
         } break;

         case NRF_BLE_SCAN_EVT_CONNECTED:
         {
              ble_gap_evt_connected_t const * p_connected =
                               p_scan_evt->params.connected.p_connected;
             // Scan is automatically stopped by the connection.
             NRF_LOG_INFO("Connecting to target %02x%02x%02x%02x%02x%02x",
                      p_connected->peer_addr.addr[0],
                      p_connected->peer_addr.addr[1],
                      p_connected->peer_addr.addr[2],
                      p_connected->peer_addr.addr[3],
                      p_connected->peer_addr.addr[4],
                      p_connected->peer_addr.addr[5]
                      );
         } break;

         case NRF_BLE_SCAN_EVT_SCAN_TIMEOUT:
         {
             NRF_LOG_INFO("Scan timed out.");
             scan_start();
         } break;

         case NRF_BLE_SCAN_EVT_SCAN_REQ_REPORT:
         {
            NRF_LOG_INFO("Scan Request Report received!");
            break;
         }
         case NRF_BLE_SCAN_EVT_FILTER_MATCH:
         {
            NRF_LOG_INFO("Received Advertisment Report that matches the scan filter(s)!");
            break;
         }
         default:
             break;
    }
}


/**@brief Function for initializing the scanning and setting the filters.
 */
static void scan_init(void)
{
    ret_code_t          err_code;
    nrf_ble_scan_init_t init_scan;
    ble_gap_scan_params_t scan_params;
    
    memset(&scan_params,0,sizeof(scan_params));
    scan_params.active        = 1;
    scan_params.interval      = NRF_BLE_SCAN_SCAN_INTERVAL;
    scan_params.window        = NRF_BLE_SCAN_SCAN_WINDOW;
    scan_params.timeout       = 0;
    scan_params.filter_policy = BLE_GAP_SCAN_FP_ACCEPT_ALL;
    scan_params.scan_phys     = BLE_GAP_PHY_1MBPS;
    //scan_params.report_incomplete_evts = true;

    memset(&init_scan, 0, sizeof(init_scan));

    init_scan.connect_if_match = false;
    init_scan.conn_cfg_tag     = APP_BLE_CONN_CFG_TAG;
    init_scan.p_scan_param = &scan_params;

    err_code = nrf_ble_scan_init(&m_scan, &init_scan, scan_evt_handler);
    APP_ERROR_CHECK(err_code);
/*
    err_code = nrf_ble_scan_filter_set(&m_scan, SCAN_UUID_FILTER, &m_nus_uuid);
    APP_ERROR_CHECK(err_code);

    err_code = nrf_ble_scan_filters_enable(&m_scan, NRF_BLE_SCAN_UUID_FILTER, false);
    APP_ERROR_CHECK(err_code);
*/
}



static void db_disc_handler(ble_db_discovery_evt_t * p_evt)
{
    ble_nus_c_on_db_disc_evt(&m_ble_nus_c, p_evt);
}



static void ble_nus_chars_received_uart_print(uint8_t * p_data, uint16_t data_len)
{
    ret_code_t ret_val;

    NRF_LOG_DEBUG("Receiving data.");
    NRF_LOG_HEXDUMP_DEBUG(p_data, data_len);

    for (uint32_t i = 0; i < data_len; i++)
    {
        do
        {
            ret_val = app_uart_put(p_data[i]);
            if ((ret_val != NRF_SUCCESS) && (ret_val != NRF_ERROR_BUSY))
            {
                NRF_LOG_ERROR("app_uart_put failed for index 0x%04x.", i);
                APP_ERROR_CHECK(ret_val);
            }
        } while (ret_val == NRF_ERROR_BUSY);
    }
    if (p_data[data_len-1] == '\r')
    {
        while (app_uart_put('\n') == NRF_ERROR_BUSY);
    }
    if (ECHOBACK_BLE_UART_DATA)
    {
        // Send data back to the peripheral.
        do
        {
            ret_val = ble_nus_c_string_send(&m_ble_nus_c, p_data, data_len);
            if ((ret_val != NRF_SUCCESS) && (ret_val != NRF_ERROR_BUSY))
            {
                NRF_LOG_ERROR("Failed sending NUS message. Error 0x%x. ", ret_val);
                APP_ERROR_CHECK(ret_val);
            }
        } while (ret_val == NRF_ERROR_BUSY);
    }
}



void uart_event_handle(app_uart_evt_t * p_event)
{
    static uint8_t data_array[BLE_NUS_MAX_DATA_LEN];
    static uint16_t index = 0;
    uint32_t ret_val;

    switch (p_event->evt_type)
    {
        /**@snippet [Handling data from UART] */
        case APP_UART_DATA_READY:
            UNUSED_VARIABLE(app_uart_get(&data_array[index]));
            index++;

            if ((data_array[index - 1] == '\n') || (index >= (m_ble_nus_max_data_len)))
            {
                NRF_LOG_DEBUG("Ready to send data over BLE NUS");
                NRF_LOG_HEXDUMP_DEBUG(data_array, index);

                do
                {
                    ret_val = ble_nus_c_string_send(&m_ble_nus_c, data_array, index);
                    if ( (ret_val != NRF_ERROR_INVALID_STATE) && (ret_val != NRF_ERROR_RESOURCES) )
                    {
                        APP_ERROR_CHECK(ret_val);
                    }
                } while (ret_val == NRF_ERROR_RESOURCES);

                index = 0;
            }
            break;

        /**@snippet [Handling data from UART] */
        case APP_UART_COMMUNICATION_ERROR:
            NRF_LOG_ERROR("Communication error occurred while handling UART.");
            APP_ERROR_HANDLER(p_event->data.error_communication);
            break;

        case APP_UART_FIFO_ERROR:
            NRF_LOG_ERROR("Error occurred in FIFO module used by UART.");
            APP_ERROR_HANDLER(p_event->data.error_code);
            break;

        default:
            break;
    }
}




/**@snippet [Handling events from the ble_nus_c module] */
static void ble_nus_c_evt_handler(ble_nus_c_t * p_ble_nus_c, ble_nus_c_evt_t const * p_ble_nus_evt)
{
    ret_code_t err_code;

    switch (p_ble_nus_evt->evt_type)
    {
        case BLE_NUS_C_EVT_DISCOVERY_COMPLETE:
            NRF_LOG_INFO("Discovery complete.");
            err_code = ble_nus_c_handles_assign(p_ble_nus_c, p_ble_nus_evt->conn_handle, &p_ble_nus_evt->handles);
            APP_ERROR_CHECK(err_code);

            err_code = ble_nus_c_tx_notif_enable(p_ble_nus_c);
            APP_ERROR_CHECK(err_code);
            NRF_LOG_INFO("Connected to device with Nordic UART Service.");
            break;

        case BLE_NUS_C_EVT_NUS_TX_EVT:
            ble_nus_chars_received_uart_print(p_ble_nus_evt->p_data, p_ble_nus_evt->data_len);
            break;

        case BLE_NUS_C_EVT_DISCONNECTED:
            NRF_LOG_INFO("Disconnected.");
            scan_start();
            break;
    }
}
/**@snippet [Handling events from the ble_nus_c module] */


/**
 * @brief Function for handling shutdown events.
 *
 * @param[in]   event       Shutdown type.
 */
static bool shutdown_handler(nrf_pwr_mgmt_evt_t event)
{
    ret_code_t err_code;

    err_code = bsp_indication_set(BSP_INDICATE_IDLE);
    APP_ERROR_CHECK(err_code);

    switch (event)
    {
        case NRF_PWR_MGMT_EVT_PREPARE_WAKEUP:
            // Prepare wakeup buttons.
            err_code = bsp_btn_ble_sleep_mode_prepare();
            APP_ERROR_CHECK(err_code);
            break;

        default:
            break;
    }

    return true;
}

NRF_PWR_MGMT_HANDLER_REGISTER(shutdown_handler, APP_SHUTDOWN_HANDLER_PRIORITY);


/**@brief Function for handling BLE events.
 *
 * @param[in]   p_ble_evt   Bluetooth stack event.
 * @param[in]   p_context   Unused.
 */
static void ble_evt_handler(ble_evt_t const * p_ble_evt, void * p_context)
{
    ret_code_t            err_code;
    ble_gap_evt_t const * p_gap_evt = &p_ble_evt->evt.gap_evt;
    uint8_t uuid[26];

    switch (p_ble_evt->header.evt_id)
    {
        case BLE_GAP_EVT_CONNECTED:
            err_code = ble_nus_c_handles_assign(&m_ble_nus_c, p_ble_evt->evt.gap_evt.conn_handle, NULL);
            APP_ERROR_CHECK(err_code);

            err_code = bsp_indication_set(BSP_INDICATE_CONNECTED);
            APP_ERROR_CHECK(err_code);

            // start discovery of services. The NUS Client waits for a discovery result
            err_code = ble_db_discovery_start(&m_db_disc, p_ble_evt->evt.gap_evt.conn_handle);
            APP_ERROR_CHECK(err_code);
            break;

        case BLE_GAP_EVT_DISCONNECTED:

            NRF_LOG_INFO("Disconnected. conn_handle: 0x%x, reason: 0x%x",
                         p_gap_evt->conn_handle,
                         p_gap_evt->params.disconnected.reason);
            break;

        case BLE_GAP_EVT_TIMEOUT:
            if (p_gap_evt->params.timeout.src == BLE_GAP_TIMEOUT_SRC_CONN)
            {
                NRF_LOG_INFO("Connection Request timed out.");
            }
            break;

        case BLE_GAP_EVT_SEC_PARAMS_REQUEST:
            // Pairing not supported.
            err_code = sd_ble_gap_sec_params_reply(p_ble_evt->evt.gap_evt.conn_handle, BLE_GAP_SEC_STATUS_PAIRING_NOT_SUPP, NULL, NULL);
            APP_ERROR_CHECK(err_code);
            break;

        case BLE_GAP_EVT_CONN_PARAM_UPDATE_REQUEST:
            // Accepting parameters requested by peer.
            err_code = sd_ble_gap_conn_param_update(p_gap_evt->conn_handle,
                                                    &p_gap_evt->params.conn_param_update_request.conn_params);
            APP_ERROR_CHECK(err_code);
            break;

        case BLE_GAP_EVT_PHY_UPDATE_REQUEST:
        {
            NRF_LOG_DEBUG("PHY update request.");
            ble_gap_phys_t const phys =
            {
                .rx_phys = BLE_GAP_PHY_AUTO,
                .tx_phys = BLE_GAP_PHY_AUTO,
            };
            err_code = sd_ble_gap_phy_update(p_ble_evt->evt.gap_evt.conn_handle, &phys);
            APP_ERROR_CHECK(err_code);
        } break;

        case BLE_GATTC_EVT_TIMEOUT:
            // Disconnect on GATT Client timeout event.
            NRF_LOG_DEBUG("GATT Client Timeout.");
            err_code = sd_ble_gap_disconnect(p_ble_evt->evt.gattc_evt.conn_handle,
                                             BLE_HCI_REMOTE_USER_TERMINATED_CONNECTION);
            APP_ERROR_CHECK(err_code);
            break;

        case BLE_GATTS_EVT_TIMEOUT:
            // Disconnect on GATT Server timeout event.
            NRF_LOG_DEBUG("GATT Server Timeout.");
            err_code = sd_ble_gap_disconnect(p_ble_evt->evt.gatts_evt.conn_handle,
                                             BLE_HCI_REMOTE_USER_TERMINATED_CONNECTION);
            APP_ERROR_CHECK(err_code);
            break;

            case BLE_GAP_EVT_ADV_REPORT:
            {
               //NRF_LOG_INFO("Advertise received");
               scan_start();

                /*//nrf_gpio_pin_toggle(LED1_PIN);    
                NRF_LOG_INFO("Scannable: %d",p_gap_evt->params.adv_report.type.scannable);
                NRF_LOG_INFO("Scan-response: %d",p_gap_evt->params.adv_report.type.scan_response);
                */
                ble_gap_addr_t  addr;
                memcpy(addr.addr, p_gap_evt->params.adv_report.peer_addr.addr, 6);
               /* NRF_LOG_INFO("Beacon address: %02x:%02x:%02x:%02x:%02x:%02x",
                p_gap_evt->params.adv_report.peer_addr.addr[5],
                p_gap_evt->params.adv_report.peer_addr.addr[4],
                p_gap_evt->params.adv_report.peer_addr.addr[3],
                p_gap_evt->params.adv_report.peer_addr.addr[2],
                p_gap_evt->params.adv_report.peer_addr.addr[1],
                p_gap_evt->params.adv_report.peer_addr.addr[0]);
                */
                
                // Filter on peripheral address. Should iterate over a list of known peripherals.
                uint8_t beacon_addr[6] ={0xec,0x97,0x40,0x5b,0xaf,0xfa};
                if(!memcmp(addr.addr,beacon_addr, sizeof(beacon_addr))){

                    //NRF_LOG_INFO("Scannable: %d",p_gap_evt->params.adv_report.type.scan_response);
                    uint16_t data_offset = 0;
                    uint16_t maunf_data_len;

                    //Check if it is a scan response packet
                    if(p_gap_evt->params.adv_report.type.scan_response)
                    {
                        NRF_LOG_INFO("Scan response report received");
                        
                        // Search for manuf data in the scan response packet
                         maunf_data_len = ble_advdata_search(p_gap_evt->params.adv_report.data.p_data, p_gap_evt->params.adv_report.data.len,&data_offset,BLE_GAP_AD_TYPE_MANUFACTURER_SPECIFIC_DATA);
                         NRF_LOG_HEXDUMP_INFO((p_gap_evt->params.adv_report.data.p_data+data_offset),maunf_data_len);
                          
                          // Extract nounce
                          memcpy(nounce,p_gap_evt->params.adv_report.data.p_data+data_offset,maunf_data_len);
                          // Intialize the crypto module
                          ctr_init(nounce,m_ecb_key);
                    } 
                    else 
                    {

                    // Find the manuf data in the advertisment packet
                     maunf_data_len = ble_advdata_search(p_gap_evt->params.adv_report.data.p_data, p_gap_evt->params.adv_report.data.len,&data_offset,BLE_GAP_AD_TYPE_MANUFACTURER_SPECIFIC_DATA);
                     NRF_LOG_HEXDUMP_INFO((p_gap_evt->params.adv_report.data.p_data+data_offset),maunf_data_len);
                     // Copy manuf data to beacon info array
                     memcpy(m_beacon_info,p_gap_evt->params.adv_report.data.p_data+data_offset,maunf_data_len);

                    // Decrypt the advertisment manuf data
                    ctr_decrypt(m_beacon_info);
                    ctr_decrypt(&m_beacon_info[16]);

                    NRF_LOG_INFO("Decrypted info:");
                    NRF_LOG_HEXDUMP_INFO(m_beacon_info, sizeof(m_beacon_info));

                    // Reset counter values for next decrypt
                    m_ecb_data.cleartext[0] = 0x00;
                    m_ecb_data.cleartext[1] = 0x00;
                    m_ecb_data.cleartext[2] = 0x00;
                    m_ecb_data.cleartext[3] = 0x00;

                    memmove(uuid, p_gap_evt->params.adv_report.data.p_data, p_gap_evt->params.adv_report.data.len);

                    NRF_LOG_INFO("UUID: %02x%02x%02x%02x%02x%02x", uuid[9], uuid[10], uuid[11], uuid[12], uuid[13], uuid[14]);

                    NRF_LOG_INFO("TX_POWER: %02x", p_gap_evt->params.adv_report.tx_power);

                    NRF_LOG_INFO("RSSI: %02x", p_gap_evt->params.adv_report.rssi);
                    }

                    // uint8_t           batt_lvl;
                    // NRF_LOG_INFO("battery level: %02x", p_gap_evt->params.adv_report.batt_lvl);
                }

            } break;

            case BLE_GAP_EVT_SCAN_REQ_REPORT:
              NRF_LOG_INFO("Scan response report received");
              break;

            default:
            break;
    }
}


/**@brief Function for initializing the BLE stack.
 *
 * @details Initializes the SoftDevice and the BLE event interrupt.
 */
static void ble_stack_init(void)
{
    ret_code_t err_code;

    err_code = nrf_sdh_enable_request();
    APP_ERROR_CHECK(err_code);

    // Configure the BLE stack using the default settings.
    // Fetch the start address of the application RAM.
    uint32_t ram_start = 0;
    err_code = nrf_sdh_ble_default_cfg_set(APP_BLE_CONN_CFG_TAG, &ram_start);
    APP_ERROR_CHECK(err_code);

    // Enable BLE stack.
    err_code = nrf_sdh_ble_enable(&ram_start);
    APP_ERROR_CHECK(err_code);

    // Register a handler for BLE events.
    NRF_SDH_BLE_OBSERVER(m_ble_observer, APP_BLE_OBSERVER_PRIO, ble_evt_handler, NULL);
}


/**@brief Function for handling events from the GATT library. */
void gatt_evt_handler(nrf_ble_gatt_t * p_gatt, nrf_ble_gatt_evt_t const * p_evt)
{
    if (p_evt->evt_id == NRF_BLE_GATT_EVT_ATT_MTU_UPDATED)
    {
        NRF_LOG_INFO("ATT MTU exchange completed.");

        m_ble_nus_max_data_len = p_evt->params.att_mtu_effective - OPCODE_LENGTH - HANDLE_LENGTH;
        NRF_LOG_INFO("Ble NUS max data length set to 0x%X(%d)", m_ble_nus_max_data_len, m_ble_nus_max_data_len);
    }
}


/**@brief Function for initializing the GATT library. */
void gatt_init(void)
{
    ret_code_t err_code;

    err_code = nrf_ble_gatt_init(&m_gatt, gatt_evt_handler);
    APP_ERROR_CHECK(err_code);

    err_code = nrf_ble_gatt_att_mtu_central_set(&m_gatt, NRF_SDH_BLE_GATT_MAX_MTU_SIZE);
    APP_ERROR_CHECK(err_code);
}


/**@brief Function for handling events from the BSP module.
 *
 * @param[in] event  Event generated by button press.
 */
void bsp_event_handler(bsp_event_t event)
{
    ret_code_t err_code;

    switch (event)
    {
        case BSP_EVENT_SLEEP:
            nrf_pwr_mgmt_shutdown(NRF_PWR_MGMT_SHUTDOWN_GOTO_SYSOFF);
            break;

        case BSP_EVENT_DISCONNECT:
            err_code = sd_ble_gap_disconnect(m_ble_nus_c.conn_handle,
                                             BLE_HCI_REMOTE_USER_TERMINATED_CONNECTION);
            if (err_code != NRF_ERROR_INVALID_STATE)
            {
                APP_ERROR_CHECK(err_code);
            }
            break;

        default:
            break;
    }
}

/**@brief Function for initializing the UART. */
static void uart_init(void)
{
    ret_code_t err_code;

    app_uart_comm_params_t const comm_params =
    {
        .rx_pin_no    = RX_PIN_NUMBER,
        .tx_pin_no    = TX_PIN_NUMBER,
        .rts_pin_no   = RTS_PIN_NUMBER,
        .cts_pin_no   = CTS_PIN_NUMBER,
        .flow_control = APP_UART_FLOW_CONTROL_DISABLED,
        .use_parity   = false,
        .baud_rate    = UART_BAUDRATE_BAUDRATE_Baud115200
    };

    APP_UART_FIFO_INIT(&comm_params,
                       UART_RX_BUF_SIZE,
                       UART_TX_BUF_SIZE,
                       uart_event_handle,
                       APP_IRQ_PRIORITY_LOWEST,
                       err_code);

    APP_ERROR_CHECK(err_code);
}

/**@brief Function for initializing the Nordic UART Service (NUS) client. */
static void nus_c_init(void)
{
    ret_code_t       err_code;
    ble_nus_c_init_t init;

    init.evt_handler = ble_nus_c_evt_handler;

    err_code = ble_nus_c_init(&m_ble_nus_c, &init);
    APP_ERROR_CHECK(err_code);
}


/**@brief Function for initializing buttons and leds. */
static void buttons_leds_init(void)
{
    ret_code_t err_code;
    bsp_event_t startup_event;

    err_code = bsp_init(BSP_INIT_LEDS, bsp_event_handler);
    APP_ERROR_CHECK(err_code);

    err_code = bsp_btn_ble_init(NULL, &startup_event);
    APP_ERROR_CHECK(err_code);
}


/**@brief Function for initializing the timer. */
static void timer_init(void)
{
    ret_code_t err_code = app_timer_init();
    APP_ERROR_CHECK(err_code);
}


/**@brief Function for initializing the nrf log module. */
static void log_init(void)
{
    ret_code_t err_code = NRF_LOG_INIT(NULL);
    APP_ERROR_CHECK(err_code);

    NRF_LOG_DEFAULT_BACKENDS_INIT();
}


/**@brief Function for initializing power management.
 */
static void power_management_init(void)
{
    ret_code_t err_code;
    err_code = nrf_pwr_mgmt_init();
    APP_ERROR_CHECK(err_code);
}


/** @brief Function for initializing the database discovery module. */
static void db_discovery_init(void)
{
    ret_code_t err_code = ble_db_discovery_init(db_disc_handler);
    APP_ERROR_CHECK(err_code);
}


/**@brief Function for handling the idle state (main loop).
 *
 * @details Handles any pending log operations, then sleeps until the next event occurs.
 */
static void idle_state_handle(void)
{
    if (NRF_LOG_PROCESS() == false)
    {
        nrf_pwr_mgmt_run();
    }
}

void nonce_generate(uint8_t * p_buf)
{
    uint8_t i         = COUNTER_BYTE_LEN;
    uint8_t remaining = NONCE_RAND_BYTE_LEN;


    while(0 != remaining)
    {
        uint32_t err_code;
        uint8_t  available = 0;

        err_code = sd_rand_application_bytes_available_get(&available);
        APP_ERROR_CHECK(err_code);

        available = ((available > remaining) ? remaining : available);
        if (0 != available)
        {
	        err_code = sd_rand_application_vector_get((p_buf + i), available);
	        APP_ERROR_CHECK(err_code);

	        i         += available;
	        remaining -= available;
	    }

	    if (0 != remaining)
	    {
	        nrf_delay_us(RNG_BYTE_WAIT_US * remaining);
	    }
    }
}



int main(void)
{
    uint32_t err_code;  

    // Initialize.
    log_init();
    timer_init();
    uart_init();
    buttons_leds_init();
    db_discovery_init();
    power_management_init();
    ble_stack_init();
    gatt_init();
    nus_c_init();
    scan_init();
    printf("BLE UART central example started.\r\n");
    NRF_LOG_INFO("BLE UART central example started.");
    scan_start();


    ble_gap_addr_t gap_address;
    err_code = sd_ble_gap_addr_get(&gap_address);
    APP_ERROR_CHECK(err_code);
    NRF_LOG_HEXDUMP_INFO(&gap_address.addr,sizeof(gap_address.addr));


    uint8_t nonce[16] = {0};
    uint8_t m_beacon_info[16];

    ctr_init(nonce,m_ecb_key);
    NRF_LOG_INFO("Encrypted info:");
    NRF_LOG_HEXDUMP_INFO(m_beacon_info, sizeof(m_beacon_info));

    
    m_ecb_data.cleartext[0] = 0x00;
    m_ecb_data.cleartext[1] = 0x00;
    m_ecb_data.cleartext[2] = 0x00;
    m_ecb_data.cleartext[3] = 0x00;

    // Decrypt the ciphertext with the same counter value, i.e. 0x00,0x00,0x00,0x00, that was used for encrypting. 
    ctr_decrypt(m_beacon_info);
    ctr_decrypt(&m_beacon_info[16]);
        
    NRF_LOG_INFO("Decrypted info:");
    NRF_LOG_HEXDUMP_INFO(m_beacon_info, sizeof(m_beacon_info));
    // Start execution.

    // Enter main loop.
    for (;;)
    {
        idle_state_handle();
    }
}

#include <stdint.h>
#include <string.h>

#include "ble_advertising.h"
#include "nordic_common.h"
#include "nrf.h"
#include "nrf_soc.h"
#include "nrf_drv_saadc.h"
#include "nrf_sdm.h"
#include "app_error.h"
#include "ble.h"
#include "ble_err.h"
#include "ble_hci.h"
#include "ble_srv_common.h"
#include "ble_advdata.h"
#include "ble_tps.h"
#include "ble_ias.h"
#include "ble_lls.h"
#include "ble_bas.h"
#include "ble_conn_params.h"
#include "ble_conn_state.h"
#include "sensorsim.h"
#include "nrf_sdh.h"
#include "nrf_sdh_soc.h"
#include "nrf_sdh_ble.h"
#include "nrf_delay.h"
#include "app_timer.h"
#include "app_error.h"
#include "ble_ias_c.h"
#include "app_util.h"
#include "bsp_btn_ble.h"
#include "ble_db_discovery.h"
#include "peer_manager.h"
#include "peer_manager_handler.h"
#include "fds.h"
#include "ble_conn_state.h"
#include "nrf_ble_gatt.h"
#include "nrf_ble_lesc.h"
#include "nrf_ble_qwr.h"
//#include "nrf_ble_scan.h"
#include "nrf_pwr_mgmt.h"
#include "nrf_fstorage.h"

#include "nrf_log.h"
#include "nrf_log_ctrl.h"
#include "nrf_log_default_backends.h"


#define DEVICE_NAME                     "NORDIC"                           

#define APP_BLE_OBSERVER_PRIO           3                                       
#define APP_BLE_CONN_CFG_TAG            1                                       

#define BATTERY_LEVEL_MEAS_INTERVAL     APP_TIMER_TICKS(120000)                 

#define MIN_CONN_INTERVAL               MSEC_TO_UNITS(500, UNIT_1_25_MS)        
#define MAX_CONN_INTERVAL               MSEC_TO_UNITS(1000, UNIT_1_25_MS)       
#define SLAVE_LATENCY                   0                                       
#define CONN_SUP_TIMEOUT                MSEC_TO_UNITS(4000, UNIT_10_MS)         

#define APP_ADV_INTERVAL                40 
#define APP_ADV_TIMEOUT_IN_SECONDS      80                                      
#define NON_CONNECTABLE_ADV_INTERVAL    MSEC_TO_UNITS(100, UNIT_0_625_MS)  

#define APP_ADV_DURATION                18000                                    
#define 	BLE_ADV_DIRECTED_ENABLED   true
#define 	BLE_ADV_DIRECTED_DISABLED   false
#define 	BLE_ADV_DIRECTED_SLOW_ENABLED   true
#define 	BLE_ADV_DIRECTED_SLOW_DISABLED   false
#define 	BLE_ADV_FAST_ENABLED   true
#define 	BLE_ADV_FAST_DISABLED   false
#define 	BLE_ADV_SLOW_ENABLED   true
#define 	BLE_ADV_SLOW_DISABLED   false
#define 	BLE_ADV_WHITELIST_ENABLED   true
#define 	BLE_ADV_WHITELIST_DISABLED   false

#define FIRST_CONN_PARAMS_UPDATE_DELAY  APP_TIMER_TICKS(5000)                   
#define NEXT_CONN_PARAMS_UPDATE_DELAY   APP_TIMER_TICKS(30000)                  
#define MAX_CONN_PARAMS_UPDATE_COUNT    3                                       

#define SEC_PARAM_BOND                  1                                       
#define SEC_PARAM_MITM                  0                                       
#define SEC_PARAM_LESC                  0                                       
#define SEC_PARAM_KEYPRESS              0                                       
#define SEC_PARAM_IO_CAPABILITIES       BLE_GAP_IO_CAPS_NONE                    
#define SEC_PARAM_OOB                   0                                       
#define SEC_PARAM_MIN_KEY_SIZE          7                                       
#define SEC_PARAM_MAX_KEY_SIZE          16
#define BLE_GAP_ADV_TYPE_ADV_IND          0x00
#define BLE_GAP_ADV_TYPE_ADV_DIRECT_IND   0x01
#define BLE_GAP_ADV_TYPE_ADV_SCAN_IND     0x02
#define BLE_GAP_ADV_TYPE_ADV_NONCONN_IND  0x03 
#define BLE_GAP_ADDR_TYPE_PUBLIC                        0x00
#define BLE_GAP_ADDR_TYPE_RANDOM_STATIC                 0x01
#define BLE_GAP_ADDR_TYPE_RANDOM_PRIVATE_RESOLVABLE     0x02
#define BLE_GAP_ADDR_TYPE_RANDOM_PRIVATE_NON_RESOLVABLE 0x03                                     

#define INITIAL_LLS_ALERT_LEVEL         BLE_CHAR_ALERT_LEVEL_NO_ALERT           
#define TX_POWER_LEVEL                  (-8)                                    

#define ADC_REF_VOLTAGE_IN_MILLIVOLTS   600                                     
#define ADC_PRE_SCALING_COMPENSATION    6                                       
#define DIODE_FWD_VOLT_DROP_MILLIVOLTS  270                                     
#define ADC_RES_10BIT                   1024                                    

#define DEAD_BEEF                       0xDEADBEEF  
#define ECB_KEY_LEN            (16UL)
#define COUNTER_BYTE_LEN       (4UL)
#define NONCE_RAND_BYTE_LEN    (12UL)

static uint8_t m_ecb_key[16] = {0xC4,0xB1,0xC4,0x95,0x81,0x1D,0x6D,0xD9,0x6A,0xAD,0x3E,0x09,0xFB,0x2D,0xAD,0xA3};

// The RNG wait values are typical and not guaranteed. See Product Specifications for more info.
#ifdef NRF51
#define RNG_BYTE_WAIT_US       (677UL)
#elif defined NRF52
#define RNG_BYTE_WAIT_US       (124UL)
#else
#error "Either NRF51 or NRF52 must be defined."
#endif                            

#define APP_BEACON_INFO_LENGTH          0x17                               
#define APP_ADV_DATA_LENGTH             0x15                               
#define APP_DEVICE_TYPE                 0x02                               
#define APP_MEASURED_RSSI               0xC5                               
#define APP_COMPANY_IDENTIFIER          0x004C                             
#define APP_MAJOR_VALUE                 0x00, 0x02                         
#define APP_MINOR_VALUE                 0x00, 0x02                         
#define APP_BEACON_UUID                 0x01, 0x12, 0x23, 0x34, \
                                        0x45, 0x56, 0x67, 0x78, \
                                        0x89, 0x9a, 0xab, 0xbc, \
                                        0xcd, 0xde, 0xef, 0xf0            

#if defined(USE_UICR_FOR_MAJ_MIN_VALUES)
#define MAJ_VAL_OFFSET_IN_BEACON_INFO   18                                
#define UICR_ADDRESS                    0x10001080                         
#endif


#define ADC_RESULT_IN_MILLI_VOLTS(ADC_VALUE)\
        ((((ADC_VALUE) * ADC_REF_VOLTAGE_IN_MILLIVOLTS) / ADC_RES_10BIT) * ADC_PRE_SCALING_COMPENSATION)


APP_TIMER_DEF(m_battery_timer_id);                      
BLE_TPS_DEF(m_tps);                                     
BLE_IAS_DEF(m_ias, NRF_SDH_BLE_TOTAL_LINK_COUNT);       
BLE_LLS_DEF(m_lls);                                     
BLE_BAS_DEF(m_bas);                                     
BLE_IAS_C_DEF(m_ias_c);                                 
NRF_BLE_GATT_DEF(m_gatt);                               
NRF_BLE_QWR_DEF(m_qwr);                                 
BLE_ADVERTISING_DEF(m_advertising);                     
BLE_DB_DISCOVERY_DEF(m_ble_db_discovery);               

static volatile bool m_is_high_alert_signalled;         
static volatile bool m_is_ias_present = false;          

static nrf_saadc_value_t adc_buf[2];

static ble_uuid_t m_adv_uuids[] =                       
{
    {BLE_UUID_IMMEDIATE_ALERT_SERVICE, BLE_UUID_TYPE_BLE},
    {BLE_UUID_BATTERY_SERVICE, BLE_UUID_TYPE_BLE},
    {BLE_UUID_TX_POWER_SERVICE, BLE_UUID_TYPE_BLE},
    {BLE_UUID_LINK_LOSS_SERVICE, BLE_UUID_TYPE_BLE}
};

static ble_gap_adv_params_t m_adv_params;                                  
static uint8_t              m_adv_handle = BLE_GAP_ADV_SET_HANDLE_NOT_SET; 
static uint8_t              m_enc_advdata[BLE_GAP_ADV_SET_DATA_SIZE_MAX];  
static uint8_t              m_enc_scandata[BLE_GAP_ADV_SET_DATA_SIZE_MAX];  


static ble_gap_adv_data_t m_adv_data =
{
    .adv_data =
    {
        .p_data = m_enc_advdata,
        .len    = BLE_GAP_ADV_SET_DATA_SIZE_MAX
    },
    .scan_rsp_data =
    {
        .p_data = m_enc_scandata,
        .len    = BLE_GAP_ADV_SET_DATA_SIZE_MAX

    }
};




static uint8_t m_beacon_info[APP_BEACON_INFO_LENGTH] =                    
{
    APP_DEVICE_TYPE,     
                         
    APP_ADV_DATA_LENGTH, 
                         
    APP_BEACON_UUID,     
    APP_MAJOR_VALUE,     
    APP_MINOR_VALUE,     
    APP_MEASURED_RSSI    
                         
};


static void on_ias_evt(ble_ias_t * p_ias, ble_ias_evt_t * p_evt);
static void on_lls_evt(ble_lls_t * p_lls, ble_lls_evt_t * p_evt);
static void on_ias_c_evt(ble_ias_c_t * p_lls, ble_ias_c_evt_t * p_evt);
static void on_bas_evt(ble_bas_t * p_bas, ble_bas_evt_t * p_evt);
static void advertising_init(void);
static void advertising_start(bool erase_bonds);



void assert_nrf_callback(uint16_t line_num, const uint8_t * p_file_name)
{
    app_error_handler(DEAD_BEEF, line_num, p_file_name);
}



static void service_error_handler(uint32_t nrf_error)
{
    APP_ERROR_HANDLER(nrf_error);
}



static void pm_evt_handler(pm_evt_t const * p_evt)
{
    pm_handler_on_pm_evt(p_evt);
    pm_handler_flash_clean(p_evt);

    switch (p_evt->evt_id)
    {
        case PM_EVT_PEERS_DELETE_SUCCEEDED:
            advertising_start(false);
            break;

        default:
            break;
    }
}



void saadc_event_handler(nrf_drv_saadc_evt_t const * p_event)
{
    if (p_event->type == NRF_DRV_SAADC_EVT_DONE)
    {
        nrf_saadc_value_t adc_result;
        uint16_t          batt_lvl_in_milli_volts;
        uint8_t           percentage_batt_lvl;
        uint32_t          err_code;

        adc_result = p_event->data.done.p_buffer[0];

        err_code = nrf_drv_saadc_buffer_convert(p_event->data.done.p_buffer, 1);
        APP_ERROR_CHECK(err_code);

        batt_lvl_in_milli_volts = ADC_RESULT_IN_MILLI_VOLTS(adc_result) +
                                  DIODE_FWD_VOLT_DROP_MILLIVOLTS;
        percentage_batt_lvl = battery_level_in_percent(batt_lvl_in_milli_volts);

        err_code = ble_bas_battery_level_update(&m_bas, percentage_batt_lvl, BLE_CONN_HANDLE_ALL);
        if ((err_code != NRF_SUCCESS) &&
            (err_code != NRF_ERROR_INVALID_STATE) &&
            (err_code != NRF_ERROR_RESOURCES) &&
            (err_code != NRF_ERROR_BUSY) &&
            (err_code != BLE_ERROR_GATTS_SYS_ATTR_MISSING)
           )
        {
            APP_ERROR_HANDLER(err_code);
        }
    }
}



static void db_disc_handler(ble_db_discovery_evt_t * p_evt)
{
    ble_ias_c_on_db_disc_evt(&m_ias_c, p_evt);
}



static void adc_configure(void)
{
    ret_code_t err_code = nrf_drv_saadc_init(NULL, saadc_event_handler);
    APP_ERROR_CHECK(err_code);

    nrf_saadc_channel_config_t config =
        NRF_DRV_SAADC_DEFAULT_CHANNEL_CONFIG_SE(NRF_SAADC_INPUT_VDD);
    err_code = nrf_drv_saadc_channel_init(0, &config);
    APP_ERROR_CHECK(err_code);

    err_code = nrf_drv_saadc_buffer_convert(&adc_buf[0], 1);
    APP_ERROR_CHECK(err_code);

    err_code = nrf_drv_saadc_buffer_convert(&adc_buf[1], 1);
    APP_ERROR_CHECK(err_code);
}



static void battery_level_meas_timeout_handler(void * p_context)
{
    UNUSED_PARAMETER(p_context);

    ret_code_t err_code;
    err_code = nrf_drv_saadc_sample();
    APP_ERROR_CHECK(err_code);
}



static void timers_init(void)
{
    ret_code_t err_code;

    
    err_code = app_timer_init();
    APP_ERROR_CHECK(err_code);

    
    err_code = app_timer_create(&m_battery_timer_id,
                                APP_TIMER_MODE_REPEATED,
                                battery_level_meas_timeout_handler);
    APP_ERROR_CHECK(err_code);
}



static void gap_params_init(void)
{
    ret_code_t              err_code;
    ble_gap_conn_params_t   gap_conn_params;
    ble_gap_conn_sec_mode_t sec_mode;

    BLE_GAP_CONN_SEC_MODE_SET_OPEN(&sec_mode);

    err_code = sd_ble_gap_device_name_set(&sec_mode,
                                          (const uint8_t *)DEVICE_NAME,
                                          strlen(DEVICE_NAME));
    APP_ERROR_CHECK(err_code);

    err_code = sd_ble_gap_appearance_set(BLE_APPEARANCE_GENERIC_KEYRING);
    APP_ERROR_CHECK(err_code);

    memset(&gap_conn_params, 0, sizeof(gap_conn_params));

    gap_conn_params.min_conn_interval = MIN_CONN_INTERVAL;
    gap_conn_params.max_conn_interval = MAX_CONN_INTERVAL;
    gap_conn_params.slave_latency     = SLAVE_LATENCY;
    gap_conn_params.conn_sup_timeout  = CONN_SUP_TIMEOUT;

    err_code = sd_ble_gap_ppcp_set(&gap_conn_params);
    APP_ERROR_CHECK(err_code);
}



static void gatt_init(void)
{
    ret_code_t err_code = nrf_ble_gatt_init(&m_gatt, NULL);
    APP_ERROR_CHECK(err_code);
}



static void sleep_mode_enter(void)
{
    ret_code_t err_code;

    err_code = bsp_indication_set(BSP_INDICATE_IDLE);
    APP_ERROR_CHECK(err_code);

    
    err_code = bsp_btn_ble_sleep_mode_prepare();
    APP_ERROR_CHECK(err_code);

    
    err_code = sd_power_system_off();
    APP_ERROR_CHECK(err_code);
}



static void on_adv_evt(ble_adv_evt_t ble_adv_evt)
{
    ret_code_t err_code;

    switch (ble_adv_evt)
    {
        case BLE_ADV_EVT_FAST:
            NRF_LOG_INFO("Fast advertising.");
            err_code = bsp_indication_set(BSP_INDICATE_ADVERTISING);
            APP_ERROR_CHECK(err_code);
            break; // BLE_ADV_EVT_FAST

        case BLE_ADV_EVT_IDLE:
            sleep_mode_enter();
            break; // BLE_ADV_EVT_IDLE

        default:
            break;
    }
}



static void delete_bonds(void)
{
    ret_code_t err_code;

    NRF_LOG_INFO("Erase bonds!");

    err_code = pm_peers_delete();
    APP_ERROR_CHECK(err_code);
}


static void advertising_init(void)
{
    uint32_t      err_code;
    ble_advdata_t advdata;
    ble_advdata_t scandata;
    uint8_t       flags = BLE_GAP_ADV_FLAG_BR_EDR_NOT_SUPPORTED;

    ble_advdata_manuf_data_t manuf_specific_data;

    manuf_specific_data.company_identifier = APP_COMPANY_IDENTIFIER;

#if defined(USE_UICR_FOR_MAJ_MIN_VALUES)

    uint16_t major_value = ((*(uint32_t *)UICR_ADDRESS) & 0xFFFF0000) >> 16;
    uint16_t minor_value = ((*(uint32_t *)UICR_ADDRESS) & 0x0000FFFF);

    uint8_t index = MAJ_VAL_OFFSET_IN_BEACON_INFO;

    m_beacon_info[index++] = MSB_16(major_value);
    m_beacon_info[index++] = LSB_16(major_value);

    m_beacon_info[index++] = MSB_16(minor_value);
    m_beacon_info[index++] = LSB_16(minor_value);
#endif

    manuf_specific_data.data.p_data = (uint8_t *) m_beacon_info;
    manuf_specific_data.data.size   = APP_BEACON_INFO_LENGTH;


    memset(&advdata, 0, sizeof(advdata));

    advdata.name_type             = BLE_ADVDATA_NO_NAME;
    advdata.flags                 = flags;
    advdata.p_manuf_specific_data = &manuf_specific_data;


    memset(&m_adv_params, 0, sizeof(m_adv_params));

    m_adv_params.properties.type = BLE_GAP_ADV_TYPE_CONNECTABLE_SCANNABLE_UNDIRECTED;
    m_adv_params.p_peer_addr     = NULL;    
    m_adv_params.filter_policy   = BLE_GAP_ADV_FP_ANY;
    m_adv_params.interval        = NON_CONNECTABLE_ADV_INTERVAL;
    m_adv_params.duration        = 0;       

    err_code = ble_advdata_encode(&advdata, m_adv_data.adv_data.p_data, &m_adv_data.adv_data.len);
    APP_ERROR_CHECK(err_code);


    memset(&scandata, 0, sizeof(scandata));

    scandata.name_type             = BLE_ADVDATA_FULL_NAME;
    scandata.uuids_complete.uuid_cnt = sizeof(m_adv_uuids) / sizeof(m_adv_uuids[0]);
    scandata.uuids_complete.p_uuids  = m_adv_uuids;

    ble_gap_addr_t gap_address;
    gap_address.addr_type = BLE_GAP_ADDR_TYPE_PUBLIC;
    memcpy(&gap_address.addr, "\xbb\xaa\xcc\xbb\xaa\xAC", sizeof(gap_address.addr));
    err_code = sd_ble_gap_addr_set(&gap_address);
    APP_ERROR_CHECK(err_code);

    err_code = ble_advdata_encode(&scandata, m_adv_data.scan_rsp_data.p_data, &m_adv_data.scan_rsp_data.len);
    APP_ERROR_CHECK(err_code);

    err_code = sd_ble_gap_adv_set_configure(&m_adv_handle, &m_adv_data, &m_adv_params);
    APP_ERROR_CHECK(err_code);
}



static void advertising_start(bool erase_bonds)
{
    ret_code_t err_code;
    if (erase_bonds == true){
        delete_bonds();
        
    }
    else
    {
        err_code = sd_ble_gap_adv_start(m_adv_handle, APP_BLE_CONN_CFG_TAG);
        APP_ERROR_CHECK(err_code);

        err_code = bsp_indication_set(BSP_INDICATE_ADVERTISING);
        APP_ERROR_CHECK(err_code);
    }
    
    
}

/**
 * @brief Uses the RNG to write a 12-byte nonce to a buffer
 * @details The 12 bytes will be written to the buffer starting at index 4 to leave
 *          space for the 4-byte counter value.
 *
 * @param[in]    p_buf    An array of length 16
 */
void nonce_generate(uint8_t * p_buf)
{
    uint8_t i         = COUNTER_BYTE_LEN;
    uint8_t remaining = NONCE_RAND_BYTE_LEN;

    // The random number pool may not contain enough bytes at the moment so
    // a busy wait may be necessary.
    while(0 != remaining)
    {
        uint32_t err_code;
        uint8_t  available = 0;

        err_code = sd_rand_application_bytes_available_get(&available);
        APP_ERROR_CHECK(err_code);

        available = ((available > remaining) ? remaining : available);
        if (0 != available)
        {
	        err_code = sd_rand_application_vector_get((p_buf + i), available);
	        APP_ERROR_CHECK(err_code);

	        i         += available;
	        remaining -= available;
	    }

	    if (0 != remaining)
	    {
	        nrf_delay_us(RNG_BYTE_WAIT_US * remaining);
	    }
    }
}

static bool m_initialized = false;

// NOTE: The ECB data must be located in RAM or a HardFault will be triggered.
static nrf_ecb_hal_data_t m_ecb_data;

/**
 * @brief Initializes the module with the given nonce and key
 * @details The nonce will be copied to an internal buffer so it does not need to
 *          be retained after the function returns. Additionally, a 32-bit counter
 *          will be initialized to zero and placed into the least-significant 4 bytes
 *          of the internal buffer. The nonce value should be generated in a
 *          reasonable manner (e.g. using this module's nonce_generate function).
 *
 * @param[in]    p_nonce    An array of length 16 containing 12 random bytes
 *                          starting at index 4
 * @param[in]    p_ecb_key  An array of length 16 containing the ECB key
 */
void ctr_init(const uint8_t * p_nonce, const uint8_t * p_ecb_key)
{
    m_initialized = true;

    // Save the key.
    memcpy(&m_ecb_data.key[0], p_ecb_key, ECB_KEY_LEN);

    // Copy the nonce.
    memcpy(&m_ecb_data.cleartext[COUNTER_BYTE_LEN],
	          &p_nonce[COUNTER_BYTE_LEN],
	          NONCE_RAND_BYTE_LEN);

    // Zero the counter value.
    memset(&m_ecb_data.cleartext[0], 0x00, COUNTER_BYTE_LEN);
}

static uint32_t crypt(uint8_t * buf)
{
    uint8_t  i;
    uint32_t err_code;

    if (!m_initialized)
    {
	    return NRF_ERROR_INVALID_STATE;
    }

    err_code = sd_ecb_block_encrypt(&m_ecb_data);
    if (NRF_SUCCESS != err_code)
    {
	    return err_code;
    }

    for (i=0; i < ECB_KEY_LEN; i++)
    {
	    buf[i] ^= m_ecb_data.ciphertext[i];
    }

    // Increment the counter.
    (*((uint32_t*) m_ecb_data.cleartext))++;

    return NRF_SUCCESS;
}

/**
 * @brief Encrypts the given buffer in-situ
 * @details The encryption step is done separately (using the nonce, counter, and
 *          key) and then the result from the encryption is XOR'd with the given
 *          buffer in-situ. The counter will be incremented only if no error occurs.
 *
 * @param[in]    p_clear_text    An array of length 16 containing the clear text
 *
 * @retval    NRF_SUCCESS                         Success
 * @retval    NRF_ERROR_INVALID_STATE             Module has not been initialized
 * @retval    NRF_ERROR_SOFTDEVICE_NOT_ENABLED    SoftDevice is present, but not enabled
 */
uint32_t ctr_encrypt(uint8_t * p_clear_text)
{
    return crypt(p_clear_text);
}

/**
 * @brief Decrypts the given buffer in-situ
 * @details The encryption step is done separately (using the nonce, counter, and
 *          key) and then the result from the encryption is XOR'd with the given
 *          buffer in-situ. The counter will be incremented only if no error occurs.
 *
 * @param[in]    p_cipher_text    An array of length 16 containing the cipher text
 *
 * @retval    NRF_SUCCESS                         Succeess
 * @retval    NRF_ERROR_INVALID_STATE             Module has not been initialized
 * @retval    NRF_ERROR_SOFTDEVICE_NOT_ENABLED    SoftDevice is present, but not enabled
 */
uint32_t ctr_decrypt(uint8_t * p_cipher_text)
{
    return crypt(p_cipher_text);
}


///**@brief Function for initializing the Advertising functionality.
// *
// * @details Encodes the required advertising data and passes it to the stack.
// *          Also builds a structure to be passed to the stack when starting advertising.
// */
//static void advertising_init(void)
//{
//    ret_code_t             err_code;
//    ble_advertising_init_t init;
//
//    memset(&init, 0, sizeof(init));
//
//    init.advdata.name_type               = BLE_ADVDATA_FULL_NAME;
//    init.advdata.include_appearance      = true;
//    init.advdata.flags                   = BLE_GAP_ADV_FLAGS_LE_ONLY_LIMITED_DISC_MODE;
//    init.advdata.uuids_complete.uuid_cnt = sizeof(m_adv_uuids) / sizeof(m_adv_uuids[0]);
//    init.advdata.uuids_complete.p_uuids  = m_adv_uuids;
//
//    init.config.ble_adv_fast_enabled  = true;
//    init.config.ble_adv_fast_interval = APP_ADV_INTERVAL;
//    init.config.ble_adv_fast_timeout  = APP_ADV_DURATION;
//
//    init.evt_handler = on_adv_evt;
//
//    err_code = ble_advertising_init(&m_advertising, &init);
//    APP_ERROR_CHECK(err_code);
//
//    ble_advertising_conn_cfg_tag_set(&m_advertising, APP_BLE_CONN_CFG_TAG);
//}



static void nrf_qwr_error_handler(uint32_t nrf_error)
{
    APP_ERROR_HANDLER(nrf_error);
}



static void qwr_init(void)
{
    ret_code_t         err_code;
    nrf_ble_qwr_init_t qwr_init_obj = {0};

 
    qwr_init_obj.error_handler = nrf_qwr_error_handler;

    err_code = nrf_ble_qwr_init(&m_qwr, &qwr_init_obj);
    APP_ERROR_CHECK(err_code);
}



static void tps_init(void)
{
    ret_code_t     err_code;
    ble_tps_init_t tps_init_obj;

    memset(&tps_init_obj, 0, sizeof(tps_init_obj));
    tps_init_obj.initial_tx_power_level = TX_POWER_LEVEL;

    tps_init_obj.tpl_rd_sec = SEC_JUST_WORKS;

    err_code = ble_tps_init(&m_tps, &tps_init_obj);
    APP_ERROR_CHECK(err_code);
}



static void ias_init(void)
{
    ret_code_t     err_code;
    ble_ias_init_t ias_init_obj;

    memset(&ias_init_obj, 0, sizeof(ias_init_obj));
    ias_init_obj.evt_handler  = on_ias_evt;

    ias_init_obj.alert_wr_sec = SEC_JUST_WORKS;

    err_code = ble_ias_init(&m_ias, &ias_init_obj);
    APP_ERROR_CHECK(err_code);
}



static void lls_init(void)
{
    ret_code_t     err_code;
    ble_lls_init_t lls_init_obj;

    // Initialize Link Loss Service
    memset(&lls_init_obj, 0, sizeof(lls_init_obj));

    lls_init_obj.evt_handler         = on_lls_evt;
    lls_init_obj.error_handler       = service_error_handler;
    lls_init_obj.initial_alert_level = INITIAL_LLS_ALERT_LEVEL;

    lls_init_obj.alert_level_rd_sec = SEC_JUST_WORKS;
    lls_init_obj.alert_level_wr_sec = SEC_JUST_WORKS;

    err_code = ble_lls_init(&m_lls, &lls_init_obj);
    APP_ERROR_CHECK(err_code);
}



static void bas_init(void)
{
    ret_code_t     err_code;
    ble_bas_init_t bas_init_obj;

    memset(&bas_init_obj, 0, sizeof(bas_init_obj));

    bas_init_obj.evt_handler          = on_bas_evt;
    bas_init_obj.support_notification = true;
    bas_init_obj.p_report_ref         = NULL;
    bas_init_obj.initial_batt_level   = 100;

    bas_init_obj.bl_rd_sec        = SEC_OPEN;
    bas_init_obj.bl_cccd_wr_sec   = SEC_OPEN;
    bas_init_obj.bl_report_rd_sec = SEC_OPEN;

    err_code = ble_bas_init(&m_bas, &bas_init_obj);
    APP_ERROR_CHECK(err_code);
}



static void ias_client_init(void)
{
    ret_code_t       err_code;
    ble_ias_c_init_t ias_c_init_obj;

    memset(&ias_c_init_obj, 0, sizeof(ias_c_init_obj));

    m_is_high_alert_signalled = false;

    ias_c_init_obj.evt_handler   = on_ias_c_evt;
    ias_c_init_obj.error_handler = service_error_handler;

    err_code = ble_ias_c_init(&m_ias_c, &ias_c_init_obj);
    APP_ERROR_CHECK(err_code);
}



static void services_init(void)
{
    qwr_init();
    tps_init();
    ias_init();
    lls_init();
    bas_init();
    ias_client_init();
}



static void db_discovery_init(void)
{
    ret_code_t err_code = ble_db_discovery_init(db_disc_handler);
    APP_ERROR_CHECK(err_code);
}


static void conn_params_error_handler(uint32_t nrf_error)
{
    APP_ERROR_HANDLER(nrf_error);
}



static void conn_params_init(void)
{
    ret_code_t             err_code;
    ble_conn_params_init_t cp_init;

    memset(&cp_init, 0, sizeof(cp_init));

    cp_init.p_conn_params                  = NULL;
    cp_init.first_conn_params_update_delay = FIRST_CONN_PARAMS_UPDATE_DELAY;
    cp_init.next_conn_params_update_delay  = NEXT_CONN_PARAMS_UPDATE_DELAY;
    cp_init.max_conn_params_update_count   = MAX_CONN_PARAMS_UPDATE_COUNT;
    cp_init.start_on_notify_cccd_handle    = BLE_GATT_HANDLE_INVALID;
    cp_init.disconnect_on_fail             = true;
    cp_init.evt_handler                    = NULL;
    cp_init.error_handler                  = conn_params_error_handler;

    err_code = ble_conn_params_init(&cp_init);
    APP_ERROR_CHECK(err_code);
}



static void alert_signal(uint8_t alert_level)
{
    ret_code_t err_code;

    switch (alert_level)
    {
        case BLE_CHAR_ALERT_LEVEL_NO_ALERT:
            NRF_LOG_INFO("No Alert.");
            err_code = bsp_indication_set(BSP_INDICATE_ALERT_OFF);
            APP_ERROR_CHECK(err_code);
            break; // BLE_CHAR_ALERT_LEVEL_NO_ALERT

        case BLE_CHAR_ALERT_LEVEL_MILD_ALERT:
            NRF_LOG_INFO("Mild Alert.");
            err_code = bsp_indication_set(BSP_INDICATE_ALERT_0);
            APP_ERROR_CHECK(err_code);
            break; // BLE_CHAR_ALERT_LEVEL_MILD_ALERT

        case BLE_CHAR_ALERT_LEVEL_HIGH_ALERT:
            NRF_LOG_INFO("HIGH Alert.");
            err_code = bsp_indication_set(BSP_INDICATE_ALERT_3);
            APP_ERROR_CHECK(err_code);
            break; // BLE_CHAR_ALERT_LEVEL_HIGH_ALERT

        default:

            break;
    }
}



static void on_ias_evt(ble_ias_t * p_ias, ble_ias_evt_t * p_evt)
{
    switch (p_evt->evt_type)
    {
        case BLE_IAS_EVT_ALERT_LEVEL_UPDATED:
            if (p_evt->p_link_ctx != NULL)
            {
                alert_signal(p_evt->p_link_ctx->alert_level);
            }
            break; // BLE_IAS_EVT_ALERT_LEVEL_UPDATED

        default:
            // No implementation needed.
            break;
    }
}



static void on_lls_evt(ble_lls_t * p_lls, ble_lls_evt_t * p_evt)
{
    switch (p_evt->evt_type)
    {
        case BLE_LLS_EVT_LINK_LOSS_ALERT:
            alert_signal(p_evt->params.alert_level);
            break; // BLE_LLS_EVT_LINK_LOSS_ALERT

        default:
            // No implementation needed.
            break;
    }
}




static void on_ias_c_evt(ble_ias_c_t * p_ias_c, ble_ias_c_evt_t * p_evt)
{
    ret_code_t err_code;

    switch (p_evt->evt_type)
    {
        case BLE_IAS_C_EVT_DISCOVERY_COMPLETE:
            // IAS is found on peer. The Find Me Locator functionality of this app will work.
            err_code = ble_ias_c_handles_assign(&m_ias_c,
                                                p_evt->conn_handle,
                                                p_evt->alert_level.handle_value);
            APP_ERROR_CHECK(err_code);

            m_is_ias_present = true;
            break; // BLE_IAS_C_EVT_DISCOVERY_COMPLETE

        case BLE_IAS_C_EVT_DISCOVERY_FAILED:
            // IAS is not found on peer. The Find Me Locator functionality of this app will NOT work.
            break; // BLE_IAS_C_EVT_DISCOVERY_FAILED

        case BLE_IAS_C_EVT_DISCONN_COMPLETE:
            // Disable alert buttons
            m_is_ias_present = false;
            break; // BLE_IAS_C_EVT_DISCONN_COMPLETE

        default:
            break;
    }
}



static void on_bas_evt(ble_bas_t * p_bas, ble_bas_evt_t * p_evt)
{
    ret_code_t err_code;

    switch (p_evt->evt_type)
    {
        case BLE_BAS_EVT_NOTIFICATION_ENABLED:
            // Start battery timer
            err_code = app_timer_start(m_battery_timer_id, BATTERY_LEVEL_MEAS_INTERVAL, NULL);
            APP_ERROR_CHECK(err_code);
            break; // BLE_BAS_EVT_NOTIFICATION_ENABLED

        case BLE_BAS_EVT_NOTIFICATION_DISABLED:
            err_code = app_timer_stop(m_battery_timer_id);
            APP_ERROR_CHECK(err_code);
            break; // BLE_BAS_EVT_NOTIFICATION_DISABLED

        default:
            // No implementation needed.
            break;
    }
}



static void ble_evt_handler(ble_evt_t const * p_ble_evt, void * p_context)
{
    ret_code_t err_code = NRF_SUCCESS;

    switch (p_ble_evt->header.evt_id)
    {
        case BLE_GAP_EVT_DISCONNECTED:
            NRF_LOG_INFO("Disconnected.");
            // LED indication will be changed when advertising starts.
            break;

        case BLE_GAP_EVT_CONNECTED:
        {
            NRF_LOG_INFO("Connected.");
            err_code = bsp_indication_set(BSP_INDICATE_CONNECTED);
            APP_ERROR_CHECK(err_code);

            // Assign connection handle to the Queued Write module.
            err_code = nrf_ble_qwr_conn_handle_assign(&m_qwr, p_ble_evt->evt.gap_evt.conn_handle);
            APP_ERROR_CHECK(err_code);

            // Discover peer's services.
            err_code = ble_db_discovery_start(&m_ble_db_discovery,
                                              p_ble_evt->evt.gap_evt.conn_handle);
            APP_ERROR_CHECK(err_code);
        } break;

        case BLE_GAP_EVT_PHY_UPDATE_REQUEST:
        {
            NRF_LOG_DEBUG("PHY update request.");
            ble_gap_phys_t const phys =
            {
                .rx_phys = BLE_GAP_PHY_AUTO,
                .tx_phys = BLE_GAP_PHY_AUTO,
            };
            err_code = sd_ble_gap_phy_update(p_ble_evt->evt.gap_evt.conn_handle, &phys);
            APP_ERROR_CHECK(err_code);
        } break;

        case BLE_GATTC_EVT_TIMEOUT:
            // Disconnect on GATT Client timeout event.
            NRF_LOG_DEBUG("GATT Client Timeout.");
            err_code = sd_ble_gap_disconnect(p_ble_evt->evt.gattc_evt.conn_handle,
                                             BLE_HCI_REMOTE_USER_TERMINATED_CONNECTION);
            APP_ERROR_CHECK(err_code);
            break;

        case BLE_GATTS_EVT_TIMEOUT:
            // Disconnect on GATT Server timeout event.
            NRF_LOG_DEBUG("GATT Server Timeout.");
            err_code = sd_ble_gap_disconnect(p_ble_evt->evt.gatts_evt.conn_handle,
                                             BLE_HCI_REMOTE_USER_TERMINATED_CONNECTION);
            APP_ERROR_CHECK(err_code);
            break;

        default:
            // No implementation needed.
            break;
    }
}



static void ble_stack_init(void)
{
    ret_code_t err_code;

    err_code = nrf_sdh_enable_request();
    APP_ERROR_CHECK(err_code);

    // Configure the BLE stack using the default settings.
    // Fetch the start address of the application RAM.
    uint32_t ram_start = 0;
    err_code = nrf_sdh_ble_default_cfg_set(APP_BLE_CONN_CFG_TAG, &ram_start);
    APP_ERROR_CHECK(err_code);

    // Enable BLE stack.
    err_code = nrf_sdh_ble_enable(&ram_start);
    APP_ERROR_CHECK(err_code);

    // Register a handler for BLE events.
    NRF_SDH_BLE_OBSERVER(m_ble_observer, APP_BLE_OBSERVER_PRIO, ble_evt_handler, NULL);
}


static void peer_manager_init(void)
{
    ble_gap_sec_params_t sec_param;
    ret_code_t           err_code;

    err_code = pm_init();
    APP_ERROR_CHECK(err_code);

    memset(&sec_param, 0, sizeof(ble_gap_sec_params_t));

    // Security parameters to be used for all security procedures.
    sec_param.bond           = SEC_PARAM_BOND;
    sec_param.mitm           = SEC_PARAM_MITM;
    sec_param.lesc           = SEC_PARAM_LESC;
    sec_param.keypress       = SEC_PARAM_KEYPRESS;
    sec_param.io_caps        = SEC_PARAM_IO_CAPABILITIES;
    sec_param.oob            = SEC_PARAM_OOB;
    sec_param.min_key_size   = SEC_PARAM_MIN_KEY_SIZE;
    sec_param.max_key_size   = SEC_PARAM_MAX_KEY_SIZE;
    sec_param.kdist_own.enc  = 1;
    sec_param.kdist_own.id   = 1;
    sec_param.kdist_peer.enc = 1;
    sec_param.kdist_peer.id  = 1;

    err_code = pm_sec_params_set(&sec_param);
    APP_ERROR_CHECK(err_code);

    err_code = pm_register(pm_evt_handler);
    APP_ERROR_CHECK(err_code);
}



static void bsp_event_handler(bsp_event_t event)
{
    ret_code_t err_code;

    switch (event)
    {
        case BSP_EVENT_SLEEP:
            sleep_mode_enter();
            break;

        case BSP_EVENT_DISCONNECT:
            err_code = sd_ble_gap_disconnect(m_ias_c.conn_handle,
                                             BLE_HCI_REMOTE_USER_TERMINATED_CONNECTION);
            if (err_code != NRF_ERROR_INVALID_STATE)
            {
                APP_ERROR_CHECK(err_code);
            }
            break;

        case BSP_EVENT_KEY_0:
        {
            if (m_is_ias_present)
            {
                if (!m_is_high_alert_signalled)
                {
                    err_code =
                        ble_ias_c_send_alert_level(&m_ias_c, BLE_CHAR_ALERT_LEVEL_HIGH_ALERT);
                }
                else
                {
                    err_code = ble_ias_c_send_alert_level(&m_ias_c, BLE_CHAR_ALERT_LEVEL_NO_ALERT);
                }

                if (err_code == NRF_SUCCESS)
                {
                    m_is_high_alert_signalled = !m_is_high_alert_signalled;
                }
                else if (
                    (err_code != NRF_ERROR_RESOURCES)
                    &&
                    (err_code != BLE_ERROR_GATTS_SYS_ATTR_MISSING)
                    &&
                    (err_code != NRF_ERROR_NOT_FOUND)
                        )
                {
                    APP_ERROR_HANDLER(err_code);
                }
            }
        } break;

        case BSP_EVENT_KEY_1:
            NRF_LOG_INFO("Alert Off.");
            err_code = bsp_indication_set(BSP_INDICATE_ALERT_OFF);
            APP_ERROR_CHECK(err_code);
            break;

        default:
            break;
    }
}



static void buttons_leds_init(bool * p_erase_bonds)
{
    ret_code_t err_code;
    bsp_event_t startup_event;

    err_code = bsp_init(BSP_INIT_LEDS | BSP_INIT_BUTTONS, bsp_event_handler);
    APP_ERROR_CHECK(err_code);

    err_code = bsp_btn_ble_init(NULL, &startup_event);
    APP_ERROR_CHECK(err_code);

    *p_erase_bonds = (startup_event == BSP_EVENT_CLEAR_BONDING_DATA);
}



static void log_init(void)
{
    ret_code_t err_code = NRF_LOG_INIT(NULL);
    APP_ERROR_CHECK(err_code);

    NRF_LOG_DEFAULT_BACKENDS_INIT();
}



static void power_management_init(void)
{
    ret_code_t err_code;
    err_code = nrf_pwr_mgmt_init();
    APP_ERROR_CHECK(err_code);
}



static void idle_state_handle(void)
{
    if (NRF_LOG_PROCESS() == false)
    {
        nrf_pwr_mgmt_run();
    }
}



///**@brief Function for starting advertising.
// */
//static void advertising_start(bool erase_bonds)
//{
//    if (erase_bonds == true){
//        delete_bonds();
//        // Advertising is started by PM_EVT_PEERS_DELETE_SUCEEDED event.
//    }
//    else
//    {
//        uint32_t err_code = ble_advertising_start(&m_advertising, BLE_ADV_MODE_FAST);
//
//        APP_ERROR_CHECK(err_code);
//    }
//}



static void tx_power_set(void)
{
    ret_code_t err_code = sd_ble_gap_tx_power_set(BLE_GAP_TX_POWER_ROLE_ADV, m_advertising.adv_handle, TX_POWER_LEVEL);
    APP_ERROR_CHECK(err_code);
}


int main(void)
{
    bool erase_bonds;

    // Initialize.
    log_init();
    timers_init();
    buttons_leds_init(&erase_bonds);
    power_management_init();
    ble_stack_init();
    adc_configure();
    gap_params_init();
    gatt_init();
    advertising_init();
    db_discovery_init();
    services_init();
    conn_params_init();
    peer_manager_init();

    // Start execution.
    NRF_LOG_INFO("Proximity example started.");
        NRF_LOG_INFO("Unencrypted plaintext:");
    uint8_t plaintext[] = "DATATOENCRYPT";
    uint8_t nounce[16] = {0};

    NRF_LOG_HEXDUMP_INFO(plaintext, sizeof(plaintext));
    
    nonce_generate(nounce);

    ctr_init(nounce,m_ecb_key);

    ctr_encrypt(plaintext);
    
    NRF_LOG_INFO("Encrypted plaintext:");
    NRF_LOG_HEXDUMP_INFO(plaintext, sizeof(plaintext));

    /* Reset the counter so that the message can be decrypted on this device.
    /  When ciphertext is sent to another device, then the counter will be incremented from zero and upwards after decrypting. 
    */
    
    m_ecb_data.cleartext[0] = 0x00;
    m_ecb_data.cleartext[1] = 0x00;
    m_ecb_data.cleartext[2] = 0x00;
    m_ecb_data.cleartext[3] = 0x00;

    // Decrypt the ciphertext with the same counter value, i.e. 0x00,0x00,0x00,0x00, that was used for encrypting. 
    ctr_decrypt(plaintext);
    
    
    NRF_LOG_INFO("Decrypted plaintext:");
    NRF_LOG_HEXDUMP_INFO(plaintext, sizeof(plaintext));
    advertising_start(erase_bonds);
    tx_power_set();

    // Enter main loop.
    for (;;)
    {
        idle_state_handle();
    }
}

#include <stdio.h>
#include <stdint.h>
#include <stdbool.h>
#include "nordic_common.h"
#include "app_error.h"
#include "app_uart.h"
#include "ble_db_discovery.h"
#include "app_timer.h"
#include "app_util.h"
#include "bsp_btn_ble.h"
#include "ble.h"
#include "ble_gap.h"
#include "ble_hci.h"
#include "nrf_sdh.h"
#include "nrf_sdh_ble.h"
#include "nrf_sdh_soc.h"
#include "ble_nus_c.h"
#include "nrf_ble_gatt.h"
#include "nrf_pwr_mgmt.h"
#include "nrf_ble_scan.h"

#include "nrf_log.h"
#include "nrf_log_ctrl.h"
#include "nrf_log_default_backends.h"

#include "nrf_delay.h"
#include "ble_srv_common.h"

#include "ble_advdata.h"

#define APP_BLE_CONN_CFG_TAG    1                                       /**< Tag that refers to the BLE stack configuration set with @ref sd_ble_cfg_set. The default tag is @ref BLE_CONN_CFG_TAG_DEFAULT. */
#define APP_BLE_OBSERVER_PRIO   3                                       /**< BLE observer priority of the application. There is no need to modify this value. */

#define UART_TX_BUF_SIZE        256                                     /**< UART TX buffer size. */
#define UART_RX_BUF_SIZE        256                                     /**< UART RX buffer size. */

#define NUS_SERVICE_UUID_TYPE   BLE_UUID_TYPE_VENDOR_BEGIN              /**< UUID type for the Nordic UART Service (vendor specific). */

#define ECHOBACK_BLE_UART_DATA  1                                       /**< Echo the UART data that is received over the Nordic UART Service (NUS) back to the sender. */
#define ECB_KEY_LEN            (16UL)
#define COUNTER_BYTE_LEN       (4UL)
#define NONCE_RAND_BYTE_LEN    (12UL)



// The RNG wait values are typical and not guaranteed. See Product Specifications for more info.
#ifdef NRF51
#define RNG_BYTE_WAIT_US       (677UL)
#elif defined NRF52
#define RNG_BYTE_WAIT_US       (124UL)
#else
#error "Either NRF51 or NRF52 must be defined."
#endif     

BLE_NUS_C_DEF(m_ble_nus_c);                                             /**< BLE Nordic UART Service (NUS) client instance. */
NRF_BLE_GATT_DEF(m_gatt);                                               /**< GATT module instance. */
BLE_DB_DISCOVERY_DEF(m_db_disc);                                        /**< Database discovery module instance. */
NRF_BLE_SCAN_DEF(m_scan);                                               /**< Scanning Module instance. */

static uint16_t m_ble_nus_max_data_len = BLE_GATT_ATT_MTU_DEFAULT - OPCODE_LENGTH - HANDLE_LENGTH; /**< Maximum length of data (in bytes) that can be transmitted to the peer by the Nordic UART service module. */

static bool m_initialized = false;
static nrf_ecb_hal_data_t m_ecb_data;
static uint8_t m_ecb_key[16] = {0x6E,0x88,0x90,0x8D,0x75,0xBB,0x95,0xEA,0x2C,0x65,0x93,0x01,0x43,0xF8,0x1B,0x5F};
static uint8_t nounce[16];
static uint8_t m_beacon_info[0x17];

/**@brief NUS UUID. */
static ble_uuid_t const m_nus_uuid =
{
    .uuid = BLE_UUID_IMMEDIATE_ALERT_SERVICE,
    .type = BLE_UUID_TYPE_BLE
};


void assert_nrf_callback(uint16_t line_num, const uint8_t * p_file_name)
{
    app_error_handler(0xDEADBEEF, line_num, p_file_name);
}


void ctr_init(const uint8_t * p_nonce, const uint8_t * p_ecb_key)
{
    m_initialized = true;

    // Save the key.
    memcpy(&m_ecb_data.key[0], p_ecb_key, ECB_KEY_LEN);

    // Copy the nonce.
    memcpy(&m_ecb_data.ciphertext[COUNTER_BYTE_LEN],
	          &p_nonce[COUNTER_BYTE_LEN],
	          NONCE_RAND_BYTE_LEN);

    // Zero the counter value.
    memset(&m_ecb_data.cleartext[0], 0x00, COUNTER_BYTE_LEN);
}

static uint32_t crypt(uint8_t * buf)
{
    uint8_t  i;
    uint32_t err_code;

    if (!m_initialized)
    {
	    return NRF_ERROR_INVALID_STATE;
    }

    err_code = sd_ecb_block_encrypt(&m_ecb_data);
    if (NRF_SUCCESS != err_code)
    {
	    return err_code;
    }

    for (i=0; i < ECB_KEY_LEN; i++)
    {
	    buf[i] ^= m_ecb_data.ciphertext[i];
    }

    // Increment the counter.
    (*((uint32_t*) m_ecb_data.cleartext))++;

    return NRF_SUCCESS;
}


uint32_t ctr_encrypt(uint8_t * p_clear_text)
{
    return crypt(p_clear_text);
}


uint32_t ctr_decrypt(uint8_t * p_cipher_text)
{
    return crypt(p_cipher_text);
}


/**@brief Function for starting scanning. */
static void scan_start(void)
{
    ret_code_t ret;

    ret = nrf_ble_scan_start(&m_scan);
    APP_ERROR_CHECK(ret);

    ret = bsp_indication_set(BSP_INDICATE_SCANNING);
    APP_ERROR_CHECK(ret);
}


/**@brief Function for handling Scanning Module events.
 */
static void scan_evt_handler(scan_evt_t const * p_scan_evt)
{
    ret_code_t err_code;

    switch(p_scan_evt->scan_evt_id)
    {
         case NRF_BLE_SCAN_EVT_CONNECTING_ERROR:
         {
              err_code = p_scan_evt->params.connecting_err.err_code;
              APP_ERROR_CHECK(err_code);
         } break;

         case NRF_BLE_SCAN_EVT_CONNECTED:
         {
              ble_gap_evt_connected_t const * p_connected =
                               p_scan_evt->params.connected.p_connected;
             // Scan is automatically stopped by the connection.
             NRF_LOG_INFO("Connecting to target %02x%02x%02x%02x%02x%02x",
                      p_connected->peer_addr.addr[0],
                      p_connected->peer_addr.addr[1],
                      p_connected->peer_addr.addr[2],
                      p_connected->peer_addr.addr[3],
                      p_connected->peer_addr.addr[4],
                      p_connected->peer_addr.addr[5]
                      );
         } break;

         case NRF_BLE_SCAN_EVT_SCAN_TIMEOUT:
         {
             NRF_LOG_INFO("Scan timed out.");
             scan_start();
         } break;

         case NRF_BLE_SCAN_EVT_SCAN_REQ_REPORT:
         {
            NRF_LOG_INFO("Scan Request Report received!");
            break;
         }
         case NRF_BLE_SCAN_EVT_FILTER_MATCH:
         {
            NRF_LOG_INFO("Received Advertisment Report that matches the scan filter(s)!");
            break;
         }
         default:
             break;
    }
}


/**@brief Function for initializing the scanning and setting the filters.
 */
static void scan_init(void)
{
    ret_code_t          err_code;
    nrf_ble_scan_init_t init_scan;
    ble_gap_scan_params_t scan_params;
    
    memset(&scan_params,0,sizeof(scan_params));
    scan_params.active        = 1;
    scan_params.interval      = NRF_BLE_SCAN_SCAN_INTERVAL;
    scan_params.window        = NRF_BLE_SCAN_SCAN_WINDOW;
    scan_params.timeout       = 0;
    scan_params.filter_policy = BLE_GAP_SCAN_FP_ACCEPT_ALL;
    scan_params.scan_phys     = BLE_GAP_PHY_1MBPS;
    //scan_params.report_incomplete_evts = true;

    memset(&init_scan, 0, sizeof(init_scan));

    init_scan.connect_if_match = false;
    init_scan.conn_cfg_tag     = APP_BLE_CONN_CFG_TAG;
    init_scan.p_scan_param = &scan_params;

    err_code = nrf_ble_scan_init(&m_scan, &init_scan, scan_evt_handler);
    APP_ERROR_CHECK(err_code);
/*
    err_code = nrf_ble_scan_filter_set(&m_scan, SCAN_UUID_FILTER, &m_nus_uuid);
    APP_ERROR_CHECK(err_code);

    err_code = nrf_ble_scan_filters_enable(&m_scan, NRF_BLE_SCAN_UUID_FILTER, false);
    APP_ERROR_CHECK(err_code);
*/
}



static void db_disc_handler(ble_db_discovery_evt_t * p_evt)
{
    ble_nus_c_on_db_disc_evt(&m_ble_nus_c, p_evt);
}



static void ble_nus_chars_received_uart_print(uint8_t * p_data, uint16_t data_len)
{
    ret_code_t ret_val;

    NRF_LOG_DEBUG("Receiving data.");
    NRF_LOG_HEXDUMP_DEBUG(p_data, data_len);

    for (uint32_t i = 0; i < data_len; i++)
    {
        do
        {
            ret_val = app_uart_put(p_data[i]);
            if ((ret_val != NRF_SUCCESS) && (ret_val != NRF_ERROR_BUSY))
            {
                NRF_LOG_ERROR("app_uart_put failed for index 0x%04x.", i);
                APP_ERROR_CHECK(ret_val);
            }
        } while (ret_val == NRF_ERROR_BUSY);
    }
    if (p_data[data_len-1] == '\r')
    {
        while (app_uart_put('\n') == NRF_ERROR_BUSY);
    }
    if (ECHOBACK_BLE_UART_DATA)
    {
        // Send data back to the peripheral.
        do
        {
            ret_val = ble_nus_c_string_send(&m_ble_nus_c, p_data, data_len);
            if ((ret_val != NRF_SUCCESS) && (ret_val != NRF_ERROR_BUSY))
            {
                NRF_LOG_ERROR("Failed sending NUS message. Error 0x%x. ", ret_val);
                APP_ERROR_CHECK(ret_val);
            }
        } while (ret_val == NRF_ERROR_BUSY);
    }
}



void uart_event_handle(app_uart_evt_t * p_event)
{
    static uint8_t data_array[BLE_NUS_MAX_DATA_LEN];
    static uint16_t index = 0;
    uint32_t ret_val;

    switch (p_event->evt_type)
    {
        /**@snippet [Handling data from UART] */
        case APP_UART_DATA_READY:
            UNUSED_VARIABLE(app_uart_get(&data_array[index]));
            index++;

            if ((data_array[index - 1] == '\n') || (index >= (m_ble_nus_max_data_len)))
            {
                NRF_LOG_DEBUG("Ready to send data over BLE NUS");
                NRF_LOG_HEXDUMP_DEBUG(data_array, index);

                do
                {
                    ret_val = ble_nus_c_string_send(&m_ble_nus_c, data_array, index);
                    if ( (ret_val != NRF_ERROR_INVALID_STATE) && (ret_val != NRF_ERROR_RESOURCES) )
                    {
                        APP_ERROR_CHECK(ret_val);
                    }
                } while (ret_val == NRF_ERROR_RESOURCES);

                index = 0;
            }
            break;

        /**@snippet [Handling data from UART] */
        case APP_UART_COMMUNICATION_ERROR:
            NRF_LOG_ERROR("Communication error occurred while handling UART.");
            APP_ERROR_HANDLER(p_event->data.error_communication);
            break;

        case APP_UART_FIFO_ERROR:
            NRF_LOG_ERROR("Error occurred in FIFO module used by UART.");
            APP_ERROR_HANDLER(p_event->data.error_code);
            break;

        default:
            break;
    }
}




/**@snippet [Handling events from the ble_nus_c module] */
static void ble_nus_c_evt_handler(ble_nus_c_t * p_ble_nus_c, ble_nus_c_evt_t const * p_ble_nus_evt)
{
    ret_code_t err_code;

    switch (p_ble_nus_evt->evt_type)
    {
        case BLE_NUS_C_EVT_DISCOVERY_COMPLETE:
            NRF_LOG_INFO("Discovery complete.");
            err_code = ble_nus_c_handles_assign(p_ble_nus_c, p_ble_nus_evt->conn_handle, &p_ble_nus_evt->handles);
            APP_ERROR_CHECK(err_code);

            err_code = ble_nus_c_tx_notif_enable(p_ble_nus_c);
            APP_ERROR_CHECK(err_code);
            NRF_LOG_INFO("Connected to device with Nordic UART Service.");
            break;

        case BLE_NUS_C_EVT_NUS_TX_EVT:
            ble_nus_chars_received_uart_print(p_ble_nus_evt->p_data, p_ble_nus_evt->data_len);
            break;

        case BLE_NUS_C_EVT_DISCONNECTED:
            NRF_LOG_INFO("Disconnected.");
            scan_start();
            break;
    }
}
/**@snippet [Handling events from the ble_nus_c module] */


/**
 * @brief Function for handling shutdown events.
 *
 * @param[in]   event       Shutdown type.
 */
static bool shutdown_handler(nrf_pwr_mgmt_evt_t event)
{
    ret_code_t err_code;

    err_code = bsp_indication_set(BSP_INDICATE_IDLE);
    APP_ERROR_CHECK(err_code);

    switch (event)
    {
        case NRF_PWR_MGMT_EVT_PREPARE_WAKEUP:
            // Prepare wakeup buttons.
            err_code = bsp_btn_ble_sleep_mode_prepare();
            APP_ERROR_CHECK(err_code);
            break;

        default:
            break;
    }

    return true;
}

NRF_PWR_MGMT_HANDLER_REGISTER(shutdown_handler, APP_SHUTDOWN_HANDLER_PRIORITY);


/**@brief Function for handling BLE events.
 *
 * @param[in]   p_ble_evt   Bluetooth stack event.
 * @param[in]   p_context   Unused.
 */
static void ble_evt_handler(ble_evt_t const * p_ble_evt, void * p_context)
{
    ret_code_t            err_code;
    ble_gap_evt_t const * p_gap_evt = &p_ble_evt->evt.gap_evt;
    uint8_t uuid[26];

    switch (p_ble_evt->header.evt_id)
    {
        case BLE_GAP_EVT_CONNECTED:
            err_code = ble_nus_c_handles_assign(&m_ble_nus_c, p_ble_evt->evt.gap_evt.conn_handle, NULL);
            APP_ERROR_CHECK(err_code);

            err_code = bsp_indication_set(BSP_INDICATE_CONNECTED);
            APP_ERROR_CHECK(err_code);

            // start discovery of services. The NUS Client waits for a discovery result
            err_code = ble_db_discovery_start(&m_db_disc, p_ble_evt->evt.gap_evt.conn_handle);
            APP_ERROR_CHECK(err_code);
            break;

        case BLE_GAP_EVT_DISCONNECTED:

            NRF_LOG_INFO("Disconnected. conn_handle: 0x%x, reason: 0x%x",
                         p_gap_evt->conn_handle,
                         p_gap_evt->params.disconnected.reason);
            break;

        case BLE_GAP_EVT_TIMEOUT:
            if (p_gap_evt->params.timeout.src == BLE_GAP_TIMEOUT_SRC_CONN)
            {
                NRF_LOG_INFO("Connection Request timed out.");
            }
            break;

        case BLE_GAP_EVT_SEC_PARAMS_REQUEST:
            // Pairing not supported.
            err_code = sd_ble_gap_sec_params_reply(p_ble_evt->evt.gap_evt.conn_handle, BLE_GAP_SEC_STATUS_PAIRING_NOT_SUPP, NULL, NULL);
            APP_ERROR_CHECK(err_code);
            break;

        case BLE_GAP_EVT_CONN_PARAM_UPDATE_REQUEST:
            // Accepting parameters requested by peer.
            err_code = sd_ble_gap_conn_param_update(p_gap_evt->conn_handle,
                                                    &p_gap_evt->params.conn_param_update_request.conn_params);
            APP_ERROR_CHECK(err_code);
            break;

        case BLE_GAP_EVT_PHY_UPDATE_REQUEST:
        {
            NRF_LOG_DEBUG("PHY update request.");
            ble_gap_phys_t const phys =
            {
                .rx_phys = BLE_GAP_PHY_AUTO,
                .tx_phys = BLE_GAP_PHY_AUTO,
            };
            err_code = sd_ble_gap_phy_update(p_ble_evt->evt.gap_evt.conn_handle, &phys);
            APP_ERROR_CHECK(err_code);
        } break;

        case BLE_GATTC_EVT_TIMEOUT:
            // Disconnect on GATT Client timeout event.
            NRF_LOG_DEBUG("GATT Client Timeout.");
            err_code = sd_ble_gap_disconnect(p_ble_evt->evt.gattc_evt.conn_handle,
                                             BLE_HCI_REMOTE_USER_TERMINATED_CONNECTION);
            APP_ERROR_CHECK(err_code);
            break;

        case BLE_GATTS_EVT_TIMEOUT:
            // Disconnect on GATT Server timeout event.
            NRF_LOG_DEBUG("GATT Server Timeout.");
            err_code = sd_ble_gap_disconnect(p_ble_evt->evt.gatts_evt.conn_handle,
                                             BLE_HCI_REMOTE_USER_TERMINATED_CONNECTION);
            APP_ERROR_CHECK(err_code);
            break;

            case BLE_GAP_EVT_ADV_REPORT:
            {
               //NRF_LOG_INFO("Advertise received");
               scan_start();

                /*//nrf_gpio_pin_toggle(LED1_PIN);    
                NRF_LOG_INFO("Scannable: %d",p_gap_evt->params.adv_report.type.scannable);
                NRF_LOG_INFO("Scan-response: %d",p_gap_evt->params.adv_report.type.scan_response);
                */
                ble_gap_addr_t  addr;
                memcpy(addr.addr, p_gap_evt->params.adv_report.peer_addr.addr, 6);
               /* NRF_LOG_INFO("Beacon address: %02x:%02x:%02x:%02x:%02x:%02x",
                p_gap_evt->params.adv_report.peer_addr.addr[5],
                p_gap_evt->params.adv_report.peer_addr.addr[4],
                p_gap_evt->params.adv_report.peer_addr.addr[3],
                p_gap_evt->params.adv_report.peer_addr.addr[2],
                p_gap_evt->params.adv_report.peer_addr.addr[1],
                p_gap_evt->params.adv_report.peer_addr.addr[0]);
                */
                
                // Filter on peripheral address. Should iterate over a list of known peripherals.
                uint8_t beacon_addr[6] ={0xec,0x97,0x40,0x5b,0xaf,0xfa};
                if(!memcmp(addr.addr,beacon_addr, sizeof(beacon_addr))){

                    //NRF_LOG_INFO("Scannable: %d",p_gap_evt->params.adv_report.type.scan_response);
                    uint16_t data_offset = 0;
                    uint16_t maunf_data_len;

                    //Check if it is a scan response packet
                    if(p_gap_evt->params.adv_report.type.scan_response)
                    {
                        NRF_LOG_INFO("Scan response report received");
                        
                        // Search for manuf data in the scan response packet
                         maunf_data_len = ble_advdata_search(p_gap_evt->params.adv_report.data.p_data, p_gap_evt->params.adv_report.data.len,&data_offset,BLE_GAP_AD_TYPE_MANUFACTURER_SPECIFIC_DATA);
                         NRF_LOG_HEXDUMP_INFO((p_gap_evt->params.adv_report.data.p_data+data_offset),maunf_data_len);
                          
                          // Extract nounce
                          memcpy(nounce,p_gap_evt->params.adv_report.data.p_data+data_offset,maunf_data_len);
                          // Intialize the crypto module
                          ctr_init(nounce,m_ecb_key);
                    } 
                    else 
                    {

                    // Find the manuf data in the advertisment packet
                     maunf_data_len = ble_advdata_search(p_gap_evt->params.adv_report.data.p_data, p_gap_evt->params.adv_report.data.len,&data_offset,BLE_GAP_AD_TYPE_MANUFACTURER_SPECIFIC_DATA);
                     NRF_LOG_HEXDUMP_INFO((p_gap_evt->params.adv_report.data.p_data+data_offset),maunf_data_len);
                     // Copy manuf data to beacon info array
                     memcpy(m_beacon_info,p_gap_evt->params.adv_report.data.p_data+data_offset,maunf_data_len);

                    // Decrypt the advertisment manuf data
                    ctr_decrypt(m_beacon_info);
                    ctr_decrypt(&m_beacon_info[16]);

                    NRF_LOG_INFO("Decrypted info:");
                    NRF_LOG_HEXDUMP_INFO(m_beacon_info, sizeof(m_beacon_info));

                    // Reset counter values for next decrypt
                    m_ecb_data.cleartext[0] = 0x00;
                    m_ecb_data.cleartext[1] = 0x00;
                    m_ecb_data.cleartext[2] = 0x00;
                    m_ecb_data.cleartext[3] = 0x00;

                    memmove(uuid, p_gap_evt->params.adv_report.data.p_data, p_gap_evt->params.adv_report.data.len);

                    NRF_LOG_INFO("UUID: %02x%02x%02x%02x%02x%02x", uuid[9], uuid[10], uuid[11], uuid[12], uuid[13], uuid[14]);

                    NRF_LOG_INFO("TX_POWER: %02x", p_gap_evt->params.adv_report.tx_power);

                    NRF_LOG_INFO("RSSI: %02x", p_gap_evt->params.adv_report.rssi);
                    }

                    // uint8_t           batt_lvl;
                    // NRF_LOG_INFO("battery level: %02x", p_gap_evt->params.adv_report.batt_lvl);
                }

            } break;

            case BLE_GAP_EVT_SCAN_REQ_REPORT:
              NRF_LOG_INFO("Scan response report received");
              break;

            default:
            break;
    }
}


/**@brief Function for initializing the BLE stack.
 *
 * @details Initializes the SoftDevice and the BLE event interrupt.
 */
static void ble_stack_init(void)
{
    ret_code_t err_code;

    err_code = nrf_sdh_enable_request();
    APP_ERROR_CHECK(err_code);

    // Configure the BLE stack using the default settings.
    // Fetch the start address of the application RAM.
    uint32_t ram_start = 0;
    err_code = nrf_sdh_ble_default_cfg_set(APP_BLE_CONN_CFG_TAG, &ram_start);
    APP_ERROR_CHECK(err_code);

    // Enable BLE stack.
    err_code = nrf_sdh_ble_enable(&ram_start);
    APP_ERROR_CHECK(err_code);

    // Register a handler for BLE events.
    NRF_SDH_BLE_OBSERVER(m_ble_observer, APP_BLE_OBSERVER_PRIO, ble_evt_handler, NULL);
}


/**@brief Function for handling events from the GATT library. */
void gatt_evt_handler(nrf_ble_gatt_t * p_gatt, nrf_ble_gatt_evt_t const * p_evt)
{
    if (p_evt->evt_id == NRF_BLE_GATT_EVT_ATT_MTU_UPDATED)
    {
        NRF_LOG_INFO("ATT MTU exchange completed.");

        m_ble_nus_max_data_len = p_evt->params.att_mtu_effective - OPCODE_LENGTH - HANDLE_LENGTH;
        NRF_LOG_INFO("Ble NUS max data length set to 0x%X(%d)", m_ble_nus_max_data_len, m_ble_nus_max_data_len);
    }
}


/**@brief Function for initializing the GATT library. */
void gatt_init(void)
{
    ret_code_t err_code;

    err_code = nrf_ble_gatt_init(&m_gatt, gatt_evt_handler);
    APP_ERROR_CHECK(err_code);

    err_code = nrf_ble_gatt_att_mtu_central_set(&m_gatt, NRF_SDH_BLE_GATT_MAX_MTU_SIZE);
    APP_ERROR_CHECK(err_code);
}


/**@brief Function for handling events from the BSP module.
 *
 * @param[in] event  Event generated by button press.
 */
void bsp_event_handler(bsp_event_t event)
{
    ret_code_t err_code;

    switch (event)
    {
        case BSP_EVENT_SLEEP:
            nrf_pwr_mgmt_shutdown(NRF_PWR_MGMT_SHUTDOWN_GOTO_SYSOFF);
            break;

        case BSP_EVENT_DISCONNECT:
            err_code = sd_ble_gap_disconnect(m_ble_nus_c.conn_handle,
                                             BLE_HCI_REMOTE_USER_TERMINATED_CONNECTION);
            if (err_code != NRF_ERROR_INVALID_STATE)
            {
                APP_ERROR_CHECK(err_code);
            }
            break;

        default:
            break;
    }
}

/**@brief Function for initializing the UART. */
static void uart_init(void)
{
    ret_code_t err_code;

    app_uart_comm_params_t const comm_params =
    {
        .rx_pin_no    = RX_PIN_NUMBER,
        .tx_pin_no    = TX_PIN_NUMBER,
        .rts_pin_no   = RTS_PIN_NUMBER,
        .cts_pin_no   = CTS_PIN_NUMBER,
        .flow_control = APP_UART_FLOW_CONTROL_DISABLED,
        .use_parity   = false,
        .baud_rate    = UART_BAUDRATE_BAUDRATE_Baud115200
    };

    APP_UART_FIFO_INIT(&comm_params,
                       UART_RX_BUF_SIZE,
                       UART_TX_BUF_SIZE,
                       uart_event_handle,
                       APP_IRQ_PRIORITY_LOWEST,
                       err_code);

    APP_ERROR_CHECK(err_code);
}

/**@brief Function for initializing the Nordic UART Service (NUS) client. */
static void nus_c_init(void)
{
    ret_code_t       err_code;
    ble_nus_c_init_t init;

    init.evt_handler = ble_nus_c_evt_handler;

    err_code = ble_nus_c_init(&m_ble_nus_c, &init);
    APP_ERROR_CHECK(err_code);
}


/**@brief Function for initializing buttons and leds. */
static void buttons_leds_init(void)
{
    ret_code_t err_code;
    bsp_event_t startup_event;

    err_code = bsp_init(BSP_INIT_LEDS, bsp_event_handler);
    APP_ERROR_CHECK(err_code);

    err_code = bsp_btn_ble_init(NULL, &startup_event);
    APP_ERROR_CHECK(err_code);
}


/**@brief Function for initializing the timer. */
static void timer_init(void)
{
    ret_code_t err_code = app_timer_init();
    APP_ERROR_CHECK(err_code);
}


/**@brief Function for initializing the nrf log module. */
static void log_init(void)
{
    ret_code_t err_code = NRF_LOG_INIT(NULL);
    APP_ERROR_CHECK(err_code);

    NRF_LOG_DEFAULT_BACKENDS_INIT();
}


/**@brief Function for initializing power management.
 */
static void power_management_init(void)
{
    ret_code_t err_code;
    err_code = nrf_pwr_mgmt_init();
    APP_ERROR_CHECK(err_code);
}


/** @brief Function for initializing the database discovery module. */
static void db_discovery_init(void)
{
    ret_code_t err_code = ble_db_discovery_init(db_disc_handler);
    APP_ERROR_CHECK(err_code);
}


/**@brief Function for handling the idle state (main loop).
 *
 * @details Handles any pending log operations, then sleeps until the next event occurs.
 */
static void idle_state_handle(void)
{
    if (NRF_LOG_PROCESS() == false)
    {
        nrf_pwr_mgmt_run();
    }
}

void nonce_generate(uint8_t * p_buf)
{
    uint8_t i         = COUNTER_BYTE_LEN;
    uint8_t remaining = NONCE_RAND_BYTE_LEN;


    while(0 != remaining)
    {
        uint32_t err_code;
        uint8_t  available = 0;

        err_code = sd_rand_application_bytes_available_get(&available);
        APP_ERROR_CHECK(err_code);

        available = ((available > remaining) ? remaining : available);
        if (0 != available)
        {
	        err_code = sd_rand_application_vector_get((p_buf + i), available);
	        APP_ERROR_CHECK(err_code);

	        i         += available;
	        remaining -= available;
	    }

	    if (0 != remaining)
	    {
	        nrf_delay_us(RNG_BYTE_WAIT_US * remaining);
	    }
    }
}



int main(void)
{
    uint32_t err_code;  

    // Initialize.
    log_init();
    timer_init();
    uart_init();
    buttons_leds_init();
    db_discovery_init();
    power_management_init();
    ble_stack_init();
    gatt_init();
    nus_c_init();
    scan_init();
    printf("BLE UART central example started.\r\n");
    NRF_LOG_INFO("BLE UART central example started.");
    scan_start();


    ble_gap_addr_t gap_address;
    err_code = sd_ble_gap_addr_get(&gap_address);
    APP_ERROR_CHECK(err_code);
    NRF_LOG_HEXDUMP_INFO(&gap_address.addr,sizeof(gap_address.addr));


    uint8_t nonce[16] = {0};
    uint8_t m_beacon_info[16];

    ctr_init(nonce,m_ecb_key);
    NRF_LOG_INFO("Encrypted info:");
    NRF_LOG_HEXDUMP_INFO(m_beacon_info, sizeof(m_beacon_info));

    
    m_ecb_data.cleartext[0] = 0x00;
    m_ecb_data.cleartext[1] = 0x00;
    m_ecb_data.cleartext[2] = 0x00;
    m_ecb_data.cleartext[3] = 0x00;

    // Decrypt the ciphertext with the same counter value, i.e. 0x00,0x00,0x00,0x00, that was used for encrypting. 
    ctr_decrypt(m_beacon_info);
    ctr_decrypt(&m_beacon_info[16]);
        
    NRF_LOG_INFO("Decrypted info:");
    NRF_LOG_HEXDUMP_INFO(m_beacon_info, sizeof(m_beacon_info));
    // Start execution.

    // Enter main loop.
    for (;;)
    {
        idle_state_handle();
    }
}