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CC2640R2F: Reading Bluetooth Address using HCI_ReadBDADDRCmd() does not work?

Part Number: CC2640R2F

Hi,

     Our product goes into test mode for reading BDA. The procedure is first write the BDA using SmartRF Flash Programmer 2 at Secondary MAC Address. I write BDA 0x112233445566 and was able to read the BDA using SmartRF Flash Programmer2. At test mode for reading BDA,  I type the command at Tera Term to read Bluetooth Device, the program goes to C Function that reads BDA using HCI_ReadBDADDRCmd(). The BDA read is corrupted, see below.

For further verification if the HCI_ReadBDADDRCmd() works, I first write BDA using  HCI_EXT_SetBDADDRCmd(), then I read the BDA using HCI_ReadBDADDRCmd(). The BDA read is corrupted, see below.

How do I make the reading of BDA work for CC2640R2F?


- kel

  • Hello kel,

    I'm surprised it compiled w/o throwing a warning. Please see the function prototype in hci.h:

    /**
    * @brief Read this device's BLE address (BDADDR).
    *
    * @par Corresponding Events
    * @ref hciEvt_CmdComplete_t with cmdOpcode @ref HCI_READ_BDADDR
    *
    * @return @ref HCI_SUCCESS
    */
    extern hciStatus_t HCI_ReadBDADDRCmd( void );

    Note there are no input params and the command complete contains the BDADDR.
    Hint: The cmd complete buffer will be 6+1 bytes to account for the return status.
    Ref: 7.4.6 Read BD_ADDR Command in BT Core 4.x, Vol 2, Part E.

    Best wishes
  • HI JXS,

         My team member made that code line HCI_ReadBDADDRCmd(readbdAddress);. I do not know where she got that idea.

         Anyway to get the BDA is the same way of getting the RSSI? So the code to get the BDA should be like this below? From which " command_complete->pReturnParam[x]", do I get the BDA?

    static uint8_t SimpleBLEPeripheral_processStackMsg(ICall_Hdr *pMsg)
    {
      uint8_t safeToDealloc = TRUE;
      uint8 bdAddress[6+1];
    
      switch (pMsg->event)
      {
        case GATT_MSG_EVENT:
          // Process GATT message
          safeToDealloc = SimpleBLEPeripheral_processGATTMsg((gattMsgEvent_t *)pMsg);
          break;
    
        case HCI_GAP_EVENT_EVENT:
          {
            // Process HCI message
            switch(pMsg->status)
            {
              case HCI_COMMAND_COMPLETE_EVENT_CODE:
                // Process HCI Command Complete Event
                // Parse Command Complete Event for opcode and status
                hciEvt_CmdComplete_t* command_complete = (hciEvt_CmdComplete_t*)pMsg;
                uint8_t status = command_complete->pReturnParam[0];
    
                //find which command this command complete is for
                switch (command_complete->cmdOpcode)
                {
                    case HCI_READ_BDADDR:
                    {
                        if (status == SUCCESS)
                        {
                            uint16_t handle = BUILD_UINT16( command_complete->pReturnParam[2],
                            command_complete->pReturnParam[1]);
                            //check handle
                            if (handle == 0x00)
                            {
                                
                                //store BDA at bdAddress[]
                            }
                        }
                    }
                    break;
    
                      default:
                        break;
                }
            }
          }
          break;
    
        default:
          // do nothing
          break;
      }
    
      return (safeToDealloc);
    }

    JXS said:
    Ref: 7.4.6 Read BD_ADDR Command in BT Core 4.x, Vol 2, Part E.

    At the moment I can not find a link to BT Core 4.x

    - kel

  • Hi,

        I tried this code at simple peripheral but I am not able to get the correct BDA. What is the correct code to get the BDA?

    C Function: SimpleBLEPeripheral_init

    /* Hard code the DB Address till CC2640R2 board gets its own IEEE address */
      uint8 bdAddress[B_ADDR_LEN] = { 0x22, 0x22, 0x22, 0x22, 0x22, 0x5A };
      HCI_EXT_SetBDADDRCmd(bdAddress);

    C Function: SimpleBLEPeripheral_taskFxn()

    // Initialize application
      SimpleBLEPeripheral_init();
    
      // Application main loop
      for (;;)
      {
        uint32_t events;
    
        // Waits for an event to be posted associated with the calling thread.
        // Note that an event associated with a thread is posted when a
        // message is queued to the message receive queue of the thread
        events = Event_pend(syncEvent, Event_Id_NONE, SBP_ALL_EVENTS,
                            ICALL_TIMEOUT_FOREVER);
    
        HCI_ReadBDADDRCmd();

    C Function: SimpleBLEPeripheral_processStackMsg()

    static uint8_t SimpleBLEPeripheral_processStackMsg(ICall_Hdr *pMsg)
    {
      uint8_t safeToDealloc = TRUE;
      uint8 bdAddress[6+1];
    
        switch (pMsg->event)
        {
            case GATT_MSG_EVENT:
              // Process GATT message
              safeToDealloc = SimpleBLEPeripheral_processGATTMsg((gattMsgEvent_t *)pMsg);
              break;
    
            case HCI_GAP_EVENT_EVENT:
            {
                // Process HCI message
                switch(pMsg->status)
                {
                    // Process HCI Command Complete Event
                    case HCI_COMMAND_COMPLETE_EVENT_CODE:
                    {
                        // Parse Command Complete Event for opcode and status
                        hciEvt_CmdComplete_t* command_complete = (hciEvt_CmdComplete_t*)pMsg;
                        uint8_t status = command_complete->pReturnParam[0];
    
                        //find which command this command complete is for
                        switch (command_complete->cmdOpcode)
                        {
                            case HCI_READ_BDADDR:
                            {
                                if (status == SUCCESS)
                                {
                                    memcpy( &bdAddress, &command_complete->pReturnParam[1], 6 );
                                }
                            }
                        }
                    }
    
                }
            }
            break;
    
            default:
            // do nothing
            break;
        }
    
        return (safeToDealloc);
    }

    The BDA read is 0x2000126C which is not the correct BDA.

    - kel

  • Hi,

        I set a BDA to this below.

    uint8 bdAddress[B_ADDR_LEN] = { 0xAA, 0x55, 0xAA, 0x55, 0xAA, 0x55 };
      HCI_EXT_SetBDADDRCmd(bdAddress);

        The  0x2000126C is a memory location. so I go to memory view and check the contents. This is what I get at location  0x2000126C. So, the BDA was copied to bdAddress[]. But, it is sort of weird how the BDA is being stored at memory location. Next I need to convert the hexadecimal value to string so I can print it out at Tera Term.

    - kel

  • Hi JXS,

    The secondary MAC Address gets erased for whatever reason. My objective is to read that in test mode. Why does the secondary MAC Address gets erased?

    I have already a working code to read the primary BDA or MAC Address. I used "GAPRole_GetParameter(GAPROLE_BD_ADDR, bdAddress);", then reverse order the array so I can print the BDA in correct order.

    The procedure for this BDA test mode is below.

    1. Write Secondary MAC Address using SmartRF Flash Programmer 2.
    2. Read Secondary MAC Address using Test Mode Program.

    How the reading of the Secondary MAC Address going to happen if the secondary MAC Address gets erased? When I read the Secondary MAC Address using SmartRF Flash Programmer it becomes FF FF FF FF FF.

    - kel
  • Never mind my previous reply. The secondary MAC Address get erased when I do debug.

    From other post says the secondary MAC Address becomes the primary MAC Address if it is present in Flash.

    Problem solved.

    - kel
  • Hi

    In my test, flash programmer 2 cannot get correct secondary address(I set 66 55 44 33 22 11)but I can get correct address from sniffer. I think, maybe secondary address flash address in R1/R2 is different.

    By the way, I also can get correct secondary address by HCI_ReadBDADDRCmd();

    /******************************************************************************
    
     @file  simple_peripheral.c
    
     @brief This file contains the Simple BLE Peripheral sample application for use
            with the CC2650 Bluetooth Low Energy Protocol Stack.
    
     Group: CMCU, SCS
     Target Device: CC2640R2
    
     ******************************************************************************
     
     Copyright (c) 2013-2017, Texas Instruments Incorporated
     All rights reserved.
    
     Redistribution and use in source and binary forms, with or without
     modification, are permitted provided that the following conditions
     are met:
    
     *  Redistributions of source code must retain the above copyright
        notice, this list of conditions and the following disclaimer.
    
     *  Redistributions in binary form must reproduce the above copyright
        notice, this list of conditions and the following disclaimer in the
        documentation and/or other materials provided with the distribution.
    
     *  Neither the name of Texas Instruments Incorporated nor the names of
        its contributors may be used to endorse or promote products derived
        from this software without specific prior written permission.
    
     THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
     AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO,
     THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
     PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR
     CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL,
     EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO,
     PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS;
     OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY,
     WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR
     OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE,
     EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
    
     ******************************************************************************
     Release Name: simplelink_cc2640r2_sdk_1_30_00_25
     Release Date: 2017-03-02 20:08:31
     *****************************************************************************/
    
    /*********************************************************************
     * INCLUDES
     */
    #include <string.h>
    
    #include <ti/sysbios/knl/Task.h>
    #include <ti/sysbios/knl/Clock.h>
    #include <ti/sysbios/knl/Event.h>
    #include <ti/sysbios/knl/Queue.h>
    
    #include "hci_tl.h"
    #include "gatt.h"
    #include "linkdb.h"
    #include "gapgattserver.h"
    #include "gattservapp.h"
    #include "devinfoservice.h"
    #include "simple_gatt_profile.h"
    #include "ll_common.h"
    
    #if defined(FEATURE_OAD) || defined(IMAGE_INVALIDATE)
    #include "oad_target.h"
    #include "oad.h"
    #endif //FEATURE_OAD || IMAGE_INVALIDATE
    
    #include "peripheral.h"
    #include "gapbondmgr.h"
    
    #include "osal_snv.h"
    #include "icall_apimsg.h"
    
    #include "util.h"
    
    #ifdef USE_RCOSC
    #include "rcosc_calibration.h"
    #endif //USE_RCOSC
    
    #ifdef USE_CORE_SDK
      #include <ti/display/Display.h>
    #else // !USE_CORE_SDK
      #include <ti/mw/display/Display.h>
    #endif // USE_CORE_SDK
    #include "board_key.h"
    
    #include "board.h"
    
    #include "simple_peripheral.h"
    
    #if defined( USE_FPGA ) || defined( DEBUG_SW_TRACE )
    #include <driverlib/ioc.h>
    #endif // USE_FPGA | DEBUG_SW_TRACE
    
    #include "icall_api.h"
    /*********************************************************************
     * CONSTANTS
     */
    
    // Advertising interval when device is discoverable (units of 625us, 160=100ms)
    #define DEFAULT_ADVERTISING_INTERVAL          160
    
    // Limited discoverable mode advertises for 30.72s, and then stops
    // General discoverable mode advertises indefinitely
    #define DEFAULT_DISCOVERABLE_MODE             GAP_ADTYPE_FLAGS_GENERAL
    
    #ifndef FEATURE_OAD
    // Minimum connection interval (units of 1.25ms, 80=100ms) if automatic
    // parameter update request is enabled
    #define DEFAULT_DESIRED_MIN_CONN_INTERVAL     80
    
    // Maximum connection interval (units of 1.25ms, 800=1000ms) if automatic
    // parameter update request is enabled
    #define DEFAULT_DESIRED_MAX_CONN_INTERVAL     800
    #else //!FEATURE_OAD
    // Minimum connection interval (units of 1.25ms, 8=10ms) if automatic
    // parameter update request is enabled
    #define DEFAULT_DESIRED_MIN_CONN_INTERVAL     8
    
    // Maximum connection interval (units of 1.25ms, 8=10ms) if automatic
    // parameter update request is enabled
    #define DEFAULT_DESIRED_MAX_CONN_INTERVAL     8
    #endif // FEATURE_OAD
    
    // Slave latency to use if automatic parameter update request is enabled
    #define DEFAULT_DESIRED_SLAVE_LATENCY         0
    
    // Supervision timeout value (units of 10ms, 1000=10s) if automatic parameter
    // update request is enabled
    #define DEFAULT_DESIRED_CONN_TIMEOUT          1000
    
    // Whether to enable automatic parameter update request when a connection is
    // formed
    #define DEFAULT_ENABLE_UPDATE_REQUEST         GAPROLE_LINK_PARAM_UPDATE_WAIT_REMOTE_PARAMS
    
    // Connection Pause Peripheral time value (in seconds)
    #define DEFAULT_CONN_PAUSE_PERIPHERAL         6
    
    // How often to perform periodic event (in msec)
    #define SBP_PERIODIC_EVT_PERIOD               5000
    
    // Application specific event ID for HCI Connection Event End Events
    #define SBP_HCI_CONN_EVT_END_EVT              0x0001
    
    // Type of Display to open
    #if !defined(Display_DISABLE_ALL)
      #ifdef USE_CORE_SDK
        #if defined(BOARD_DISPLAY_USE_LCD) && (BOARD_DISPLAY_USE_LCD!=0)
          #define SBP_DISPLAY_TYPE Display_Type_LCD
        #elif defined (BOARD_DISPLAY_USE_UART) && (BOARD_DISPLAY_USE_UART!=0)
          #define SBP_DISPLAY_TYPE Display_Type_UART
        #else // !BOARD_DISPLAY_USE_LCD && !BOARD_DISPLAY_USE_UART
          #define SBP_DISPLAY_TYPE 0 // Option not supported
        #endif // BOARD_DISPLAY_USE_LCD && BOARD_DISPLAY_USE_UART
      #else // !USE_CORE_SDK
        #if !defined(BOARD_DISPLAY_EXCLUDE_LCD)
          #define SBP_DISPLAY_TYPE Display_Type_LCD
        #elif !defined (BOARD_DISPLAY_EXCLUDE_UART)
          #define SBP_DISPLAY_TYPE Display_Type_UART
        #else // BOARD_DISPLAY_EXCLUDE_LCD && BOARD_DISPLAY_EXCLUDE_UART
          #define SBP_DISPLAY_TYPE 0 // Option not supported
        #endif // !BOARD_DISPLAY_EXCLUDE_LCD || !BOARD_DISPLAY_EXCLUDE_UART
      #endif // USE_CORE_SDK
    #else // BOARD_DISPLAY_USE_LCD && BOARD_DISPLAY_USE_UART
      #define SBP_DISPLAY_TYPE 0 // No Display
    #endif // Display_DISABLE_ALL
    
    #ifdef FEATURE_OAD
    // The size of an OAD packet.
    #define OAD_PACKET_SIZE                       ((OAD_BLOCK_SIZE) + 2)
    #endif // FEATURE_OAD
    
    // Task configuration
    #define SBP_TASK_PRIORITY                     1
    
    #ifndef SBP_TASK_STACK_SIZE
    #define SBP_TASK_STACK_SIZE                   644
    #endif
    
    #define SBP_STATE_CHANGE_EVT                  0x0001
    #define SBP_CHAR_CHANGE_EVT                   0x0002
    
    // Internal Events for RTOS application
    #define SBP_ICALL_EVT                         ICALL_MSG_EVENT_ID // Event_Id_31
    #define SBP_QUEUE_EVT                         UTIL_QUEUE_EVENT_ID // Event_Id_30
    #define SBP_PERIODIC_EVT                      Event_Id_00
    
    #ifdef FEATURE_OAD
    #define SBP_QUEUE_PING_EVT                    Event_Id_01
    
    #define SBP_ALL_EVENTS                        (SBP_ICALL_EVT        | \
                                                   SBP_QUEUE_EVT        | \
                                                   SBP_PERIODIC_EVT     | \
                                                   SBP_QUEUE_PING_EVT)
    #else
    #define SBP_ALL_EVENTS                        (SBP_ICALL_EVT        | \
                                                   SBP_QUEUE_EVT        | \
                                                   SBP_PERIODIC_EVT)
    #endif /* FEATURE_OAD */
    
    /*********************************************************************
     * TYPEDEFS
     */
    
    // App event passed from profiles.
    typedef struct
    {
      appEvtHdr_t hdr;  // event header.
    } sbpEvt_t;
    
    /*********************************************************************
     * GLOBAL VARIABLES
     */
    
    // Display Interface
    Display_Handle dispHandle = NULL;
    
    /*********************************************************************
     * LOCAL VARIABLES
     */
    
    // Entity ID globally used to check for source and/or destination of messages
    static ICall_EntityID selfEntity;
    
    // Event globally used to post local events and pend on system and
    // local events.
    static ICall_SyncHandle syncEvent;
    
    // Clock instances for internal periodic events.
    static Clock_Struct periodicClock;
    
    // Queue object used for app messages
    static Queue_Struct appMsg;
    static Queue_Handle appMsgQueue;
    
    #if defined(FEATURE_OAD)
    // Event data from OAD profile.
    static Queue_Struct oadQ;
    static Queue_Handle hOadQ;
    #endif //FEATURE_OAD
    
    // Task configuration
    Task_Struct sbpTask;
    Char sbpTaskStack[SBP_TASK_STACK_SIZE];
    
    // Profile state and parameters
    //static gaprole_States_t gapProfileState = GAPROLE_INIT;
    
    // GAP - SCAN RSP data (max size = 31 bytes)
    static uint8_t scanRspData[] =
    {
      // complete name
      0x14,   // length of this data
      GAP_ADTYPE_LOCAL_NAME_COMPLETE,
      'S',
      'i',
      'm',
      'p',
      'l',
      'e',
      'B',
      'L',
      'E',
      'P',
      'e',
      'r',
      'i',
      'p',
      'h',
      'e',
      'r',
      'a',
      'l',
    
      // connection interval range
      0x05,   // length of this data
      GAP_ADTYPE_SLAVE_CONN_INTERVAL_RANGE,
      LO_UINT16(DEFAULT_DESIRED_MIN_CONN_INTERVAL),   // 100ms
      HI_UINT16(DEFAULT_DESIRED_MIN_CONN_INTERVAL),
      LO_UINT16(DEFAULT_DESIRED_MAX_CONN_INTERVAL),   // 1s
      HI_UINT16(DEFAULT_DESIRED_MAX_CONN_INTERVAL),
    
      // Tx power level
      0x02,   // length of this data
      GAP_ADTYPE_POWER_LEVEL,
      0       // 0dBm
    };
    
    // GAP - Advertisement data (max size = 31 bytes, though this is
    // best kept short to conserve power while advertisting)
    static uint8_t advertData[] =
    {
      // Flags; this sets the device to use limited discoverable
      // mode (advertises for 30 seconds at a time) instead of general
      // discoverable mode (advertises indefinitely)
      0x02,   // length of this data
      GAP_ADTYPE_FLAGS,
      DEFAULT_DISCOVERABLE_MODE | GAP_ADTYPE_FLAGS_BREDR_NOT_SUPPORTED,
    
      // service UUID, to notify central devices what services are included
      // in this peripheral
    #if !defined(FEATURE_OAD) || defined(FEATURE_OAD_ONCHIP)
      0x03,   // length of this data
    #else //OAD for external flash
      0x05,  // lenght of this data
    #endif //FEATURE_OAD
      GAP_ADTYPE_16BIT_MORE,      // some of the UUID's, but not all
    #ifdef FEATURE_OAD
      LO_UINT16(OAD_SERVICE_UUID),
      HI_UINT16(OAD_SERVICE_UUID),
    #endif //FEATURE_OAD
    #ifndef FEATURE_OAD_ONCHIP
      LO_UINT16(SIMPLEPROFILE_SERV_UUID),
      HI_UINT16(SIMPLEPROFILE_SERV_UUID)
    #endif //FEATURE_OAD_ONCHIP
    };
    
    // GAP GATT Attributes
    static uint8_t attDeviceName[GAP_DEVICE_NAME_LEN] = "Simple BLE Peripheral";
    
    // Globals used for ATT Response retransmission
    static gattMsgEvent_t *pAttRsp = NULL;
    static uint8_t rspTxRetry = 0;
    
    /*********************************************************************
     * LOCAL FUNCTIONS
     */
    
    static void SimpleBLEPeripheral_init( void );
    static void SimpleBLEPeripheral_taskFxn(UArg a0, UArg a1);
    
    static uint8_t SimpleBLEPeripheral_processStackMsg(ICall_Hdr *pMsg);
    static uint8_t SimpleBLEPeripheral_processGATTMsg(gattMsgEvent_t *pMsg);
    static void SimpleBLEPeripheral_processAppMsg(sbpEvt_t *pMsg);
    static void SimpleBLEPeripheral_processStateChangeEvt(gaprole_States_t newState);
    static void SimpleBLEPeripheral_processCharValueChangeEvt(uint8_t paramID);
    static void SimpleBLEPeripheral_performPeriodicTask(void);
    static void SimpleBLEPeripheral_clockHandler(UArg arg);
    
    static void SimpleBLEPeripheral_sendAttRsp(void);
    static void SimpleBLEPeripheral_freeAttRsp(uint8_t status);
    
    static void SimpleBLEPeripheral_stateChangeCB(gaprole_States_t newState);
    #ifndef FEATURE_OAD_ONCHIP
    static void SimpleBLEPeripheral_charValueChangeCB(uint8_t paramID);
    #endif //!FEATURE_OAD_ONCHIP
    static void SimpleBLEPeripheral_enqueueMsg(uint8_t event, uint8_t state);
    
    #ifdef FEATURE_OAD
    void SimpleBLEPeripheral_processOadWriteCB(uint8_t event, uint16_t connHandle,
                                               uint8_t *pData);
    #endif //FEATURE_OAD
    
    /*********************************************************************
     * EXTERN FUNCTIONS
     */
    extern void AssertHandler(uint8 assertCause, uint8 assertSubcause);
    
    /*********************************************************************
     * PROFILE CALLBACKS
     */
    
    // GAP Role Callbacks
    static gapRolesCBs_t SimpleBLEPeripheral_gapRoleCBs =
    {
      SimpleBLEPeripheral_stateChangeCB     // Profile State Change Callbacks
    };
    
    // GAP Bond Manager Callbacks
    static gapBondCBs_t simpleBLEPeripheral_BondMgrCBs =
    {
      NULL, // Passcode callback (not used by application)
      NULL  // Pairing / Bonding state Callback (not used by application)
    };
    
    // Simple GATT Profile Callbacks
    #ifndef FEATURE_OAD_ONCHIP
    static simpleProfileCBs_t SimpleBLEPeripheral_simpleProfileCBs =
    {
      SimpleBLEPeripheral_charValueChangeCB // Characteristic value change callback
    };
    #endif //!FEATURE_OAD_ONCHIP
    
    #ifdef FEATURE_OAD
    static oadTargetCBs_t simpleBLEPeripheral_oadCBs =
    {
      SimpleBLEPeripheral_processOadWriteCB // Write Callback.
    };
    #endif //FEATURE_OAD
    
    /*********************************************************************
     * PUBLIC FUNCTIONS
     */
    
    /*********************************************************************
     * @fn      SimpleBLEPeripheral_createTask
     *
     * @brief   Task creation function for the Simple BLE Peripheral.
     *
     * @param   None.
     *
     * @return  None.
     */
    void SimpleBLEPeripheral_createTask(void)
    {
      Task_Params taskParams;
    
      // Configure task
      Task_Params_init(&taskParams);
      taskParams.stack = sbpTaskStack;
      taskParams.stackSize = SBP_TASK_STACK_SIZE;
      taskParams.priority = SBP_TASK_PRIORITY;
    
      Task_construct(&sbpTask, SimpleBLEPeripheral_taskFxn, &taskParams, NULL);
    }
    
    /*********************************************************************
     * @fn      SimpleBLEPeripheral_init
     *
     * @brief   Called during initialization and contains application
     *          specific initialization (ie. hardware initialization/setup,
     *          table initialization, power up notification, etc), and
     *          profile initialization/setup.
     *
     * @param   None.
     *
     * @return  None.
     */
    static void SimpleBLEPeripheral_init(void)
    {
      // ******************************************************************
      // N0 STACK API CALLS CAN OCCUR BEFORE THIS CALL TO ICall_registerApp
      // ******************************************************************
      // Register the current thread as an ICall dispatcher application
      // so that the application can send and receive messages.
      ICall_registerApp(&selfEntity, &syncEvent);
      
      uint8 bdAddress[B_ADDR_LEN] = { 0x11, 0x22, 0x33, 0x44, 0x55, 0x66 };
      HCI_EXT_SetBDADDRCmd(bdAddress);
    
    #ifdef USE_RCOSC
      RCOSC_enableCalibration();
    #endif // USE_RCOSC
    
    #if defined( USE_FPGA )
      // configure RF Core SMI Data Link
      IOCPortConfigureSet(IOID_12, IOC_PORT_RFC_GPO0, IOC_STD_OUTPUT);
      IOCPortConfigureSet(IOID_11, IOC_PORT_RFC_GPI0, IOC_STD_INPUT);
    
      // configure RF Core SMI Command Link
      IOCPortConfigureSet(IOID_10, IOC_IOCFG0_PORT_ID_RFC_SMI_CL_OUT, IOC_STD_OUTPUT);
      IOCPortConfigureSet(IOID_9, IOC_IOCFG0_PORT_ID_RFC_SMI_CL_IN, IOC_STD_INPUT);
    
      // configure RF Core tracer IO
      IOCPortConfigureSet(IOID_8, IOC_PORT_RFC_TRC, IOC_STD_OUTPUT);
    #else // !USE_FPGA
      #if defined( DEBUG_SW_TRACE )
        // configure RF Core tracer IO
        IOCPortConfigureSet(IOID_8, IOC_PORT_RFC_TRC, IOC_STD_OUTPUT | IOC_CURRENT_4MA | IOC_SLEW_ENABLE);
      #endif // DEBUG_SW_TRACE
    #endif // USE_FPGA
    
      // Create an RTOS queue for message from profile to be sent to app.
      appMsgQueue = Util_constructQueue(&appMsg);
    
      // Create one-shot clocks for internal periodic events.
      Util_constructClock(&periodicClock, SimpleBLEPeripheral_clockHandler,
                          SBP_PERIODIC_EVT_PERIOD, 0, false, SBP_PERIODIC_EVT);
    
      dispHandle = Display_open(SBP_DISPLAY_TYPE, NULL);
    
      // Setup the GAP
      GAP_SetParamValue(TGAP_CONN_PAUSE_PERIPHERAL, DEFAULT_CONN_PAUSE_PERIPHERAL);
    
      // Setup the GAP Peripheral Role Profile
      {
        // For all hardware platforms, device starts advertising upon initialization
        uint8_t initialAdvertEnable = TRUE;
    
        // By setting this to zero, the device will go into the waiting state after
        // being discoverable for 30.72 second, and will not being advertising again
        // until the enabler is set back to TRUE
        uint16_t advertOffTime = 0;
    
        uint8_t enableUpdateRequest = DEFAULT_ENABLE_UPDATE_REQUEST;
        uint16_t desiredMinInterval = DEFAULT_DESIRED_MIN_CONN_INTERVAL;
        uint16_t desiredMaxInterval = DEFAULT_DESIRED_MAX_CONN_INTERVAL;
        uint16_t desiredSlaveLatency = DEFAULT_DESIRED_SLAVE_LATENCY;
        uint16_t desiredConnTimeout = DEFAULT_DESIRED_CONN_TIMEOUT;
    
        // Set the GAP Role Parameters
        GAPRole_SetParameter(GAPROLE_ADVERT_ENABLED, sizeof(uint8_t),
                             &initialAdvertEnable);
        GAPRole_SetParameter(GAPROLE_ADVERT_OFF_TIME, sizeof(uint16_t),
                             &advertOffTime);
    
        GAPRole_SetParameter(GAPROLE_SCAN_RSP_DATA, sizeof(scanRspData),
                             scanRspData);
        GAPRole_SetParameter(GAPROLE_ADVERT_DATA, sizeof(advertData), advertData);
    
        GAPRole_SetParameter(GAPROLE_PARAM_UPDATE_ENABLE, sizeof(uint8_t),
                             &enableUpdateRequest);
        GAPRole_SetParameter(GAPROLE_MIN_CONN_INTERVAL, sizeof(uint16_t),
                             &desiredMinInterval);
        GAPRole_SetParameter(GAPROLE_MAX_CONN_INTERVAL, sizeof(uint16_t),
                             &desiredMaxInterval);
        GAPRole_SetParameter(GAPROLE_SLAVE_LATENCY, sizeof(uint16_t),
                             &desiredSlaveLatency);
        GAPRole_SetParameter(GAPROLE_TIMEOUT_MULTIPLIER, sizeof(uint16_t),
                             &desiredConnTimeout);
      }
    
      // Set the GAP Characteristics
      GGS_SetParameter(GGS_DEVICE_NAME_ATT, GAP_DEVICE_NAME_LEN, attDeviceName);
    
      // Set advertising interval
      {
        uint16_t advInt = DEFAULT_ADVERTISING_INTERVAL;
    
        GAP_SetParamValue(TGAP_LIM_DISC_ADV_INT_MIN, advInt);
        GAP_SetParamValue(TGAP_LIM_DISC_ADV_INT_MAX, advInt);
        GAP_SetParamValue(TGAP_GEN_DISC_ADV_INT_MIN, advInt);
        GAP_SetParamValue(TGAP_GEN_DISC_ADV_INT_MAX, advInt);
      }
    
      // Setup the GAP Bond Manager
      {
        uint32_t passkey = 0; // passkey "000000"
        uint8_t pairMode = GAPBOND_PAIRING_MODE_WAIT_FOR_REQ;
        uint8_t mitm = TRUE;
        uint8_t ioCap = GAPBOND_IO_CAP_DISPLAY_ONLY;
        uint8_t bonding = TRUE;
    
        GAPBondMgr_SetParameter(GAPBOND_DEFAULT_PASSCODE, sizeof(uint32_t),
                                &passkey);
        GAPBondMgr_SetParameter(GAPBOND_PAIRING_MODE, sizeof(uint8_t), &pairMode);
        GAPBondMgr_SetParameter(GAPBOND_MITM_PROTECTION, sizeof(uint8_t), &mitm);
        GAPBondMgr_SetParameter(GAPBOND_IO_CAPABILITIES, sizeof(uint8_t), &ioCap);
        GAPBondMgr_SetParameter(GAPBOND_BONDING_ENABLED, sizeof(uint8_t), &bonding);
      }
    
       // Initialize GATT attributes
      GGS_AddService(GATT_ALL_SERVICES);           // GAP
      GATTServApp_AddService(GATT_ALL_SERVICES);   // GATT attributes
      DevInfo_AddService();                        // Device Information Service
    
    #ifndef FEATURE_OAD_ONCHIP
      SimpleProfile_AddService(GATT_ALL_SERVICES); // Simple GATT Profile
    #endif //!FEATURE_OAD_ONCHIP
    
    #ifdef FEATURE_OAD
      VOID OAD_addService();                 // OAD Profile
      OAD_register((oadTargetCBs_t *)&simpleBLEPeripheral_oadCBs);
      hOadQ = Util_constructQueue(&oadQ);
    #endif //FEATURE_OAD
    
    #ifdef IMAGE_INVALIDATE
      Reset_addService();
    #endif //IMAGE_INVALIDATE
    
    
    #ifndef FEATURE_OAD_ONCHIP
      // Setup the SimpleProfile Characteristic Values
      {
        uint8_t charValue1 = 1;
        uint8_t charValue2 = 2;
        uint8_t charValue3 = 3;
        uint8_t charValue4 = 4;
        uint8_t charValue5[SIMPLEPROFILE_CHAR5_LEN] = { 1, 2, 3, 4, 5 };
    
        SimpleProfile_SetParameter(SIMPLEPROFILE_CHAR1, sizeof(uint8_t),
                                   &charValue1);
        SimpleProfile_SetParameter(SIMPLEPROFILE_CHAR2, sizeof(uint8_t),
                                   &charValue2);
        SimpleProfile_SetParameter(SIMPLEPROFILE_CHAR3, sizeof(uint8_t),
                                   &charValue3);
        SimpleProfile_SetParameter(SIMPLEPROFILE_CHAR4, sizeof(uint8_t),
                                   &charValue4);
        SimpleProfile_SetParameter(SIMPLEPROFILE_CHAR5, SIMPLEPROFILE_CHAR5_LEN,
                                   charValue5);
      }
    
      // Register callback with SimpleGATTprofile
      SimpleProfile_RegisterAppCBs(&SimpleBLEPeripheral_simpleProfileCBs);
    #endif //!FEATURE_OAD_ONCHIP
    
      // Start the Device
      VOID GAPRole_StartDevice(&SimpleBLEPeripheral_gapRoleCBs);
    
      // Start Bond Manager
      VOID GAPBondMgr_Register(&simpleBLEPeripheral_BondMgrCBs);
    
      // Register with GAP for HCI/Host messages
      GAP_RegisterForMsgs(selfEntity);
    
      // Register for GATT local events and ATT Responses pending for transmission
      GATT_RegisterForMsgs(selfEntity);
    
      //This should be included only if 4.2 length extension feature is enable....
      //HCI_LE_ReadMaxDataLenCmd();
    
    #if !defined (USE_LL_CONN_PARAM_UPDATE)
      // Get the currently set local supported LE features
      // The HCI will generate an HCI event that will get received in the main
      // loop
      HCI_LE_ReadLocalSupportedFeaturesCmd();
    #endif // !defined (USE_LL_CONN_PARAM_UPDATE)
    
    #if defined FEATURE_OAD
    #if defined (HAL_IMAGE_A)
      Display_print0(dispHandle, 0, 0, "BLE Peripheral A");
    #else
      Display_print0(dispHandle, 0, 0, "BLE Peripheral B");
    #endif // HAL_IMAGE_A
    #else
      Display_print0(dispHandle, 0, 0, "BLE Peripheral");
    #endif // FEATURE_OAD
    }
    
    /*********************************************************************
     * @fn      SimpleBLEPeripheral_taskFxn
     *
     * @brief   Application task entry point for the Simple BLE Peripheral.
     *
     * @param   a0, a1 - not used.
     *
     * @return  None.
     */
    static void SimpleBLEPeripheral_taskFxn(UArg a0, UArg a1)
    {
      // Initialize application
      SimpleBLEPeripheral_init();
    
      // Application main loop
      for (;;)
      {
        uint32_t events;
    
        // Waits for an event to be posted associated with the calling thread.
        // Note that an event associated with a thread is posted when a
        // message is queued to the message receive queue of the thread
        events = Event_pend(syncEvent, Event_Id_NONE, SBP_ALL_EVENTS,
                            ICALL_TIMEOUT_FOREVER);
    
        if (events)
        {
          ICall_EntityID dest;
          ICall_ServiceEnum src;
          ICall_HciExtEvt *pMsg = NULL;
    
          if (ICall_fetchServiceMsg(&src, &dest,
                                    (void **)&pMsg) == ICALL_ERRNO_SUCCESS)
          {
            uint8 safeToDealloc = TRUE;
    
            if ((src == ICALL_SERVICE_CLASS_BLE) && (dest == selfEntity))
            {
              ICall_Stack_Event *pEvt = (ICall_Stack_Event *)pMsg;
    
              // Check for BLE stack events first
              if (pEvt->signature == 0xffff)
              {
                if (pEvt->event_flag & SBP_HCI_CONN_EVT_END_EVT)
                {
                  // Try to retransmit pending ATT Response (if any)
                  SimpleBLEPeripheral_sendAttRsp();
                }
              }
              else
              {
                // Process inter-task message
                safeToDealloc = SimpleBLEPeripheral_processStackMsg((ICall_Hdr *)pMsg);
              }
            }
    
            if (pMsg && safeToDealloc)
            {
              ICall_freeMsg(pMsg);
            }
          }
    
          // If RTOS queue is not empty, process app message.
          if (events & SBP_QUEUE_EVT)
          {
            while (!Queue_empty(appMsgQueue))
            {
              sbpEvt_t *pMsg = (sbpEvt_t *)Util_dequeueMsg(appMsgQueue);
              if (pMsg)
              {
                // Process message.
                SimpleBLEPeripheral_processAppMsg(pMsg);
    
                // Free the space from the message.
                ICall_free(pMsg);
              }
            }
          }
    
          if (events & SBP_PERIODIC_EVT)
          {
            //Util_startClock(&periodicClock);
    
            // Perform periodic application task
            //SimpleBLEPeripheral_performPeriodicTask();
            HCI_ReadBDADDRCmd();
          }
    
    #ifdef FEATURE_OAD
          if (events & SBP_QUEUE_PING_EVT)
          {
            while (!Queue_empty(hOadQ))
            {
              oadTargetWrite_t *oadWriteEvt = Queue_get(hOadQ);
    
              // Identify new image.
              if (oadWriteEvt->event == OAD_WRITE_IDENTIFY_REQ)
              {
                OAD_imgIdentifyWrite(oadWriteEvt->connHandle, oadWriteEvt->pData);
              }
              // Write a next block request.
              else if (oadWriteEvt->event == OAD_WRITE_BLOCK_REQ)
              {
                OAD_imgBlockWrite(oadWriteEvt->connHandle, oadWriteEvt->pData);
              }
    
              // Free buffer.
              ICall_free(oadWriteEvt);
            }
          }
    #endif //FEATURE_OAD
        }
      }
    }
    
    /*********************************************************************
     * @fn      SimpleBLEPeripheral_processStackMsg
     *
     * @brief   Process an incoming stack message.
     *
     * @param   pMsg - message to process
     *
     * @return  TRUE if safe to deallocate incoming message, FALSE otherwise.
     */
    static uint8_t SimpleBLEPeripheral_processStackMsg(ICall_Hdr *pMsg)
    {
      uint8_t safeToDealloc = TRUE;
    
      switch (pMsg->event)
      {
        case GATT_MSG_EVENT:
          // Process GATT message
          safeToDealloc = SimpleBLEPeripheral_processGATTMsg((gattMsgEvent_t *)pMsg);
          break;
    
        case HCI_GAP_EVENT_EVENT:
          {
    
            // Process HCI message
            switch(pMsg->status)
            {
              case HCI_COMMAND_COMPLETE_EVENT_CODE:
                // Process HCI Command Complete Event
                {
    
    #if !defined (USE_LL_CONN_PARAM_UPDATE)
                  // This code will disable the use of the LL_CONNECTION_PARAM_REQ
                  // control procedure (for connection parameter updates, the 
                  // L2CAP Connection Parameter Update procedure will be used 
                  // instead). To re-enable the LL_CONNECTION_PARAM_REQ control
                  // procedures, define the symbol USE_LL_CONN_PARAM_UPDATE                
                  
                  // Parse Command Complete Event for opcode and status
                  hciEvt_CmdComplete_t* command_complete = (hciEvt_CmdComplete_t*) pMsg;
                  uint8_t   pktStatus = command_complete->pReturnParam[0]; 
                  
                  //find which command this command complete is for
                  switch (command_complete->cmdOpcode)
                  {
                    case HCI_LE_READ_LOCAL_SUPPORTED_FEATURES:
                      {
                        if (pktStatus == SUCCESS)
                        {
                          uint8_t featSet[8];
                          
                          // get current feature set from received event (bits 1-9 of
                          // the returned data
                          memcpy( featSet, &command_complete->pReturnParam[1], 8 );                          
                          
                          // Clear bit 1 of byte 0 of feature set to disable LL
                          // Connection Parameter Updates
                          CLR_FEATURE_FLAG( featSet[0], LL_FEATURE_CONN_PARAMS_REQ );
                            
                          // Update controller with modified features
                          HCI_EXT_SetLocalSupportedFeaturesCmd( featSet );
                        }
                      }
                  case HCI_READ_BDADDR:
                    {
                      if (pktStatus == SUCCESS)
                        {
                          static uint8_t addr[6];
                          
                          // get current feature set from received event (bits 1-9 of
                          // the returned data
                          memcpy( addr, &command_complete->pReturnParam[1], 6 );
                          asm("NOP");
                        }
                    }
                      break;
                    
                    default:
                      //do nothing
                      break;
                  }   
    #endif // !defined (USE_LL_CONN_PARAM_UPDATE)
                  
                }
                break;
    
              case HCI_BLE_HARDWARE_ERROR_EVENT_CODE:
                AssertHandler(HAL_ASSERT_CAUSE_HARDWARE_ERROR,0);
                break;
    
              default:
                break;
            }
          }
          break;
    
          default:
            // do nothing
            break;
    
        }
      
      return (safeToDealloc);
    }
    
    /*********************************************************************
     * @fn      SimpleBLEPeripheral_processGATTMsg
     *
     * @brief   Process GATT messages and events.
     *
     * @return  TRUE if safe to deallocate incoming message, FALSE otherwise.
     */
    static uint8_t SimpleBLEPeripheral_processGATTMsg(gattMsgEvent_t *pMsg)
    {
      // See if GATT server was unable to transmit an ATT response
      if (pMsg->hdr.status == blePending)
      {
        // No HCI buffer was available. Let's try to retransmit the response
        // on the next connection event.
        if (HCI_EXT_ConnEventNoticeCmd(pMsg->connHandle, selfEntity,
                                       SBP_HCI_CONN_EVT_END_EVT) == SUCCESS)
        {
          // First free any pending response
          SimpleBLEPeripheral_freeAttRsp(FAILURE);
    
          // Hold on to the response message for retransmission
          pAttRsp = pMsg;
    
          // Don't free the response message yet
          return (FALSE);
        }
      }
      else if (pMsg->method == ATT_FLOW_CTRL_VIOLATED_EVENT)
      {
        // ATT request-response or indication-confirmation flow control is
        // violated. All subsequent ATT requests or indications will be dropped.
        // The app is informed in case it wants to drop the connection.
    
        // Display the opcode of the message that caused the violation.
        Display_print1(dispHandle, 5, 0, "FC Violated: %d", pMsg->msg.flowCtrlEvt.opcode);
      }
      else if (pMsg->method == ATT_MTU_UPDATED_EVENT)
      {
        // MTU size updated
        Display_print1(dispHandle, 5, 0, "MTU Size: %d", pMsg->msg.mtuEvt.MTU);
      }
    
      // Free message payload. Needed only for ATT Protocol messages
      GATT_bm_free(&pMsg->msg, pMsg->method);
    
      // It's safe to free the incoming message
      return (TRUE);
    }
    
    /*********************************************************************
     * @fn      SimpleBLEPeripheral_sendAttRsp
     *
     * @brief   Send a pending ATT response message.
     *
     * @param   none
     *
     * @return  none
     */
    static void SimpleBLEPeripheral_sendAttRsp(void)
    {
      // See if there's a pending ATT Response to be transmitted
      if (pAttRsp != NULL)
      {
        uint8_t status;
    
        // Increment retransmission count
        rspTxRetry++;
    
        // Try to retransmit ATT response till either we're successful or
        // the ATT Client times out (after 30s) and drops the connection.
        status = GATT_SendRsp(pAttRsp->connHandle, pAttRsp->method, &(pAttRsp->msg));
        if ((status != blePending) && (status != MSG_BUFFER_NOT_AVAIL))
        {
          // Disable connection event end notice
          HCI_EXT_ConnEventNoticeCmd(pAttRsp->connHandle, selfEntity, 0);
    
          // We're done with the response message
          SimpleBLEPeripheral_freeAttRsp(status);
        }
        else
        {
          // Continue retrying
          Display_print1(dispHandle, 5, 0, "Rsp send retry: %d", rspTxRetry);
        }
      }
    }
    
    /*********************************************************************
     * @fn      SimpleBLEPeripheral_freeAttRsp
     *
     * @brief   Free ATT response message.
     *
     * @param   status - response transmit status
     *
     * @return  none
     */
    static void SimpleBLEPeripheral_freeAttRsp(uint8_t status)
    {
      // See if there's a pending ATT response message
      if (pAttRsp != NULL)
      {
        // See if the response was sent out successfully
        if (status == SUCCESS)
        {
          Display_print1(dispHandle, 5, 0, "Rsp sent retry: %d", rspTxRetry);
        }
        else
        {
          // Free response payload
          GATT_bm_free(&pAttRsp->msg, pAttRsp->method);
    
          Display_print1(dispHandle, 5, 0, "Rsp retry failed: %d", rspTxRetry);
        }
    
        // Free response message
        ICall_freeMsg(pAttRsp);
    
        // Reset our globals
        pAttRsp = NULL;
        rspTxRetry = 0;
      }
    }
    
    /*********************************************************************
     * @fn      SimpleBLEPeripheral_processAppMsg
     *
     * @brief   Process an incoming callback from a profile.
     *
     * @param   pMsg - message to process
     *
     * @return  None.
     */
    static void SimpleBLEPeripheral_processAppMsg(sbpEvt_t *pMsg)
    {
      switch (pMsg->hdr.event)
      {
        case SBP_STATE_CHANGE_EVT:
          SimpleBLEPeripheral_processStateChangeEvt((gaprole_States_t)pMsg->
                                                    hdr.state);
          break;
    
        case SBP_CHAR_CHANGE_EVT:
          SimpleBLEPeripheral_processCharValueChangeEvt(pMsg->hdr.state);
          break;
    
        default:
          // Do nothing.
          break;
      }
    }
    
    /*********************************************************************
     * @fn      SimpleBLEPeripheral_stateChangeCB
     *
     * @brief   Callback from GAP Role indicating a role state change.
     *
     * @param   newState - new state
     *
     * @return  None.
     */
    static void SimpleBLEPeripheral_stateChangeCB(gaprole_States_t newState)
    {
      SimpleBLEPeripheral_enqueueMsg(SBP_STATE_CHANGE_EVT, newState);
    }
    
    /*********************************************************************
     * @fn      SimpleBLEPeripheral_processStateChangeEvt
     *
     * @brief   Process a pending GAP Role state change event.
     *
     * @param   newState - new state
     *
     * @return  None.
     */
    static void SimpleBLEPeripheral_processStateChangeEvt(gaprole_States_t newState)
    {
    #ifdef PLUS_BROADCASTER
      static bool firstConnFlag = false;
    #endif // PLUS_BROADCASTER
    
      switch ( newState )
      {
        case GAPROLE_STARTED:
          {
            uint8_t ownAddress[B_ADDR_LEN];
            uint8_t systemId[DEVINFO_SYSTEM_ID_LEN];
    
            GAPRole_GetParameter(GAPROLE_BD_ADDR, ownAddress);
    
            // use 6 bytes of device address for 8 bytes of system ID value
            systemId[0] = ownAddress[0];
            systemId[1] = ownAddress[1];
            systemId[2] = ownAddress[2];
    
            // set middle bytes to zero
            systemId[4] = 0x00;
            systemId[3] = 0x00;
    
            // shift three bytes up
            systemId[7] = ownAddress[5];
            systemId[6] = ownAddress[4];
            systemId[5] = ownAddress[3];
    
            DevInfo_SetParameter(DEVINFO_SYSTEM_ID, DEVINFO_SYSTEM_ID_LEN, systemId);
    
            // Display device address
            Display_print0(dispHandle, 1, 0, Util_convertBdAddr2Str(ownAddress));
            Display_print0(dispHandle, 2, 0, "Initialized");
          }
          break;
    
        case GAPROLE_ADVERTISING:
          Display_print0(dispHandle, 2, 0, "Advertising");
          break;
    
    #ifdef PLUS_BROADCASTER
        /* After a connection is dropped a device in PLUS_BROADCASTER will continue
         * sending non-connectable advertisements and shall sending this change of
         * state to the application.  These are then disabled here so that sending
         * connectable advertisements can resume.
         */
        case GAPROLE_ADVERTISING_NONCONN:
          {
            uint8_t advertEnabled = FALSE;
    
            // Disable non-connectable advertising.
            GAPRole_SetParameter(GAPROLE_ADV_NONCONN_ENABLED, sizeof(uint8_t),
                               &advertEnabled);
    
            advertEnabled = TRUE;
    
            // Enabled connectable advertising.
            GAPRole_SetParameter(GAPROLE_ADVERT_ENABLED, sizeof(uint8_t),
                                 &advertEnabled);
    
            // Reset flag for next connection.
            firstConnFlag = false;
    
            SimpleBLEPeripheral_freeAttRsp(bleNotConnected);
          }
          break;
    #endif //PLUS_BROADCASTER
    
        case GAPROLE_CONNECTED:
          {
            linkDBInfo_t linkInfo;
            uint8_t numActive = 0;
    
            Util_startClock(&periodicClock);
    
            numActive = linkDB_NumActive();
    
            // Use numActive to determine the connection handle of the last
            // connection
            if ( linkDB_GetInfo( numActive - 1, &linkInfo ) == SUCCESS )
            {
              Display_print1(dispHandle, 2, 0, "Num Conns: %d", (uint16_t)numActive);
              Display_print0(dispHandle, 3, 0, Util_convertBdAddr2Str(linkInfo.addr));
            }
            else
            {
              uint8_t peerAddress[B_ADDR_LEN];
    
              GAPRole_GetParameter(GAPROLE_CONN_BD_ADDR, peerAddress);
    
              Display_print0(dispHandle, 2, 0, "Connected");
              Display_print0(dispHandle, 3, 0, Util_convertBdAddr2Str(peerAddress));
            }
    
            #ifdef PLUS_BROADCASTER
              // Only turn advertising on for this state when we first connect
              // otherwise, when we go from connected_advertising back to this state
              // we will be turning advertising back on.
              if (firstConnFlag == false)
              {
                uint8_t advertEnabled = FALSE; // Turn on Advertising
    
                // Disable connectable advertising.
                GAPRole_SetParameter(GAPROLE_ADVERT_ENABLED, sizeof(uint8_t),
                                     &advertEnabled);
    
                // Set to true for non-connectabel advertising.
                advertEnabled = TRUE;
    
                // Enable non-connectable advertising.
                GAPRole_SetParameter(GAPROLE_ADV_NONCONN_ENABLED, sizeof(uint8_t),
                                     &advertEnabled);
                firstConnFlag = true;
              }
            #endif // PLUS_BROADCASTER
          }
          break;
    
        case GAPROLE_CONNECTED_ADV:
          Display_print0(dispHandle, 2, 0, "Connected Advertising");
          break;
    
        case GAPROLE_WAITING:
          Util_stopClock(&periodicClock);
          SimpleBLEPeripheral_freeAttRsp(bleNotConnected);
    
          Display_print0(dispHandle, 2, 0, "Disconnected");
    
          // Clear remaining lines
          Display_clearLines(dispHandle, 3, 5);
          break;
    
        case GAPROLE_WAITING_AFTER_TIMEOUT:
          SimpleBLEPeripheral_freeAttRsp(bleNotConnected);
    
          Display_print0(dispHandle, 2, 0, "Timed Out");
    
          // Clear remaining lines
          Display_clearLines(dispHandle, 3, 5);
    
          #ifdef PLUS_BROADCASTER
            // Reset flag for next connection.
            firstConnFlag = false;
          #endif //#ifdef (PLUS_BROADCASTER)
          break;
    
        case GAPROLE_ERROR:
          Display_print0(dispHandle, 2, 0, "Error");
          break;
    
        default:
          Display_clearLine(dispHandle, 2);
          break;
      }
    
      // Update the state
      //gapProfileState = newState;
    }
    
    #ifndef FEATURE_OAD_ONCHIP
    /*********************************************************************
     * @fn      SimpleBLEPeripheral_charValueChangeCB
     *
     * @brief   Callback from Simple Profile indicating a characteristic
     *          value change.
     *
     * @param   paramID - parameter ID of the value that was changed.
     *
     * @return  None.
     */
    static void SimpleBLEPeripheral_charValueChangeCB(uint8_t paramID)
    {
      SimpleBLEPeripheral_enqueueMsg(SBP_CHAR_CHANGE_EVT, paramID);
    }
    #endif //!FEATURE_OAD_ONCHIP
    
    /*********************************************************************
     * @fn      SimpleBLEPeripheral_processCharValueChangeEvt
     *
     * @brief   Process a pending Simple Profile characteristic value change
     *          event.
     *
     * @param   paramID - parameter ID of the value that was changed.
     *
     * @return  None.
     */
    static void SimpleBLEPeripheral_processCharValueChangeEvt(uint8_t paramID)
    {
    #ifndef FEATURE_OAD_ONCHIP
      uint8_t newValue;
    
      switch(paramID)
      {
        case SIMPLEPROFILE_CHAR1:
          SimpleProfile_GetParameter(SIMPLEPROFILE_CHAR1, &newValue);
    
          Display_print1(dispHandle, 4, 0, "Char 1: %d", (uint16_t)newValue);
          break;
    
        case SIMPLEPROFILE_CHAR3:
          SimpleProfile_GetParameter(SIMPLEPROFILE_CHAR3, &newValue);
    
          Display_print1(dispHandle, 4, 0, "Char 3: %d", (uint16_t)newValue);
          break;
    
        default:
          // should not reach here!
          break;
      }
    #endif //!FEATURE_OAD_ONCHIP
    }
    
    /*********************************************************************
     * @fn      SimpleBLEPeripheral_performPeriodicTask
     *
     * @brief   Perform a periodic application task. This function gets called
     *          every five seconds (SBP_PERIODIC_EVT_PERIOD). In this example,
     *          the value of the third characteristic in the SimpleGATTProfile
     *          service is retrieved from the profile, and then copied into the
     *          value of the the fourth characteristic.
     *
     * @param   None.
     *
     * @return  None.
     */
    static void SimpleBLEPeripheral_performPeriodicTask(void)
    {
    #ifndef FEATURE_OAD_ONCHIP
      uint8_t valueToCopy;
    
      // Call to retrieve the value of the third characteristic in the profile
      if (SimpleProfile_GetParameter(SIMPLEPROFILE_CHAR3, &valueToCopy) == SUCCESS)
      {
        // Call to set that value of the fourth characteristic in the profile.
        // Note that if notifications of the fourth characteristic have been
        // enabled by a GATT client device, then a notification will be sent
        // every time this function is called.
        SimpleProfile_SetParameter(SIMPLEPROFILE_CHAR4, sizeof(uint8_t),
                                   &valueToCopy);
      }
    #endif //!FEATURE_OAD_ONCHIP
    }
    
    
    #ifdef FEATURE_OAD
    /*********************************************************************
     * @fn      SimpleBLEPeripheral_processOadWriteCB
     *
     * @brief   Process a write request to the OAD profile.
     *
     * @param   event      - event type:
     *                       OAD_WRITE_IDENTIFY_REQ
     *                       OAD_WRITE_BLOCK_REQ
     * @param   connHandle - the connection Handle this request is from.
     * @param   pData      - pointer to data for processing and/or storing.
     *
     * @return  None.
     */
    void SimpleBLEPeripheral_processOadWriteCB(uint8_t event, uint16_t connHandle,
                                               uint8_t *pData)
    {
      oadTargetWrite_t *oadWriteEvt = ICall_malloc( sizeof(oadTargetWrite_t) + \
                                                 sizeof(uint8_t) * OAD_PACKET_SIZE);
    
      if ( oadWriteEvt != NULL )
      {
        oadWriteEvt->event = event;
        oadWriteEvt->connHandle = connHandle;
    
        oadWriteEvt->pData = (uint8_t *)(&oadWriteEvt->pData + 1);
        memcpy(oadWriteEvt->pData, pData, OAD_PACKET_SIZE);
    
        Queue_put(hOadQ, (Queue_Elem *)oadWriteEvt);
    
        // Post the application's event.  For OAD, no event flag is used.
        Event_post(syncEvent, SBP_QUEUE_PING_EVT);
      }
      else
      {
        // Fail silently.
      }
    }
    #endif //FEATURE_OAD
    
    /*********************************************************************
     * @fn      SimpleBLEPeripheral_clockHandler
     *
     * @brief   Handler function for clock timeouts.
     *
     * @param   arg - event type
     *
     * @return  None.
     */
    static void SimpleBLEPeripheral_clockHandler(UArg arg)
    {
      // Wake up the application.
      Event_post(syncEvent, arg);
    }
    
    /*********************************************************************
     * @fn      SimpleBLEPeripheral_enqueueMsg
     *
     * @brief   Creates a message and puts the message in RTOS queue.
     *
     * @param   event - message event.
     * @param   state - message state.
     *
     * @return  None.
     */
    static void SimpleBLEPeripheral_enqueueMsg(uint8_t event, uint8_t state)
    {
      sbpEvt_t *pMsg;
    
      // Create dynamic pointer to message.
      if ((pMsg = ICall_malloc(sizeof(sbpEvt_t))))
      {
        pMsg->hdr.event = event;
        pMsg->hdr.state = state;
    
        // Enqueue the message.
        Util_enqueueMsg(appMsgQueue, syncEvent, (uint8*)pMsg);
      }
    }
    
    /*********************************************************************
    *********************************************************************/
    

  • Hi kel,

    Glad you have it working. Looks like you found and fixed the unneeded "&bdaddr" in the memcpy, no need to use double pointers here.

    Regarding why you don't see the 2nd BDADDR in Flash Programmer 2, calling HCI_EXT_SetBDADDRCmd does not program the flash memory and only sets the BD address in the Controller's local RAM until the next reboot. If you want to program the 2nd BDADDR, you must write the addr to the CCFG region in flash. See the Device Configuration section of the CC26xx TRM SWCU117.

    Best wishes

    PS: No need to blame the co-worker!