int main()
{
/* Initializing all the Flags and Indexes to 0 */
ALL_LED_OFF ();
Count = 0;
Index = 0;
AddRequest = 0;
DelRequest = 0;
CyGlobalIntEnable; /* Comment this line to disable global interrupts. */
/* Start BLE component and register Event handler function */
CyBle_Start(StackEventHandler);
/* Start UART Component which is used for receiving inputs and Debugging */
UART_Start();
printf("BLE WhiteList Example \r\n");
printf("Press A to add a Device to WhiteList. R to remove the Device from Whitelist \r\n");
/* Continuous loop scans for inputs from UART Terminal and accordingly
handles Addition to and Removal from Whitelist. Also processes
BLE events */
for(;;)
{
//Checks the internal task queue in the BLE Stack
CyBle_ProcessEvents();
if(UART_SpiUartGetRxBufferSize())
{
UartRxDataSim = UART_UartGetChar();
if (UartRxDataSim == 'A' || UartRxDataSim == 'a') // The user has to Enter D for disconnection
{
printf ("Enter the Address of the Device. Press Z to Go Back \r\n");
for (;;)
{
if (Count ==12)
{
//If the user had entered the full address, stop advertisement
//for addition process
CyBle_GappStopAdvertisement ();
/*Once We stop advertisement, the
CYBLE_EVT_GAPP_ADVERTISEMENT_START_STOP event is invoked.
After this, the API for adding the device to whitelist is invoked
in the StackEventHandler*/
RED_LED_ON ();
AddRequest = 1;
printf ("\r\n");
printf ("Address is 0x%2.2x%2.2x%2.2x%2.2x%2.2x%2.2x \r\n",
whitelistdeviceaddress.bdAddr[5],
whitelistdeviceaddress.bdAddr[4],
whitelistdeviceaddress.bdAddr[3],
whitelistdeviceaddress.bdAddr[2],
whitelistdeviceaddress.bdAddr[1],
whitelistdeviceaddress.bdAddr[0]);
printf ("Attempting to Add to whitelist \r \n");
Count = 0;
break;
}
if(UART_SpiUartGetRxBufferSize())
{
UartRxDataSim = UART_UartGetChar();
if (UartRxDataSim == 'Z' || UartRxDataSim == 'z')
{
Count = 0;
printf("Press A to add a Device to WhiteList \r\n");
break;
}
else
{
if ((UartRxDataSim >= '0') && (UartRxDataSim <= '9' ))
{
AddrNibble = UartRxDataSim - '0';
UART_UartPutChar (UartRxDataSim);
}
else if ((UartRxDataSim >= 'A') && (UartRxDataSim <= 'F' ))
{
AddrNibble = UartRxDataSim - 'A' + 0xA;
UART_UartPutChar (UartRxDataSim);
}
else if ((UartRxDataSim >= 'a') && (UartRxDataSim <= 'f' ))
{
AddrNibble = UartRxDataSim - 'a' + 0xA;
UART_UartPutChar (UartRxDataSim);
}
else
{
printf ("\nplease Enter a Valid Address. Press A to Enter a New Address. R ro remove the Device\r\n");
Count = 0;
break;
}
//Receiving the addresss Nibble by Nibble
whitelistdeviceaddress.bdAddr[5 - (Count/2)] =
(whitelistdeviceaddress.bdAddr[5 - (Count/2)]<<4)|AddrNibble;
Count ++;
}
}
}
}
else if (UartRxDataSim == 'R' || UartRxDataSim == 'r')
{
if (Index == 0)
{
printf ("No Devices in WhiteList. press A to Add \r\n");
}
else
{
printf (" The List of Devices are given below \4\n");
uint8 i = 0;
// Retrieving the list of added devices for user to choose
for (i = 0; i< Index; i++)
{
printf ("Device %d 0x%2.2x%2.2x%2.2x%2.2x%2.2x%2.2x \r\n",i + 1,
whitelistdeviceaddressBackup[i].bdAddr[5],
whitelistdeviceaddressBackup[i].bdAddr[4],
whitelistdeviceaddressBackup[i].bdAddr[3],
whitelistdeviceaddressBackup[i].bdAddr[2],
whitelistdeviceaddressBackup[i].bdAddr[1],
whitelistdeviceaddressBackup[i].bdAddr[0]);
}
printf ("Enter the Index of the device to be removed. Press Z to go back \r\n");
for (;;)
{
if(UART_SpiUartGetRxBufferSize())
{
UartRxDataSim = UART_UartGetChar();
if (UartRxDataSim == 'Z' || UartRxDataSim == 'z')
{
printf("Press A to add a Device to WhiteList. R to remove \r\n");
break;
}
else if (UartRxDataSim >= '1' || UartRxDataSim <= '0' + Index)
{
RemoveIndex = UartRxDataSim - '1';
if(RemoveIndex < Index)
{
CyBle_GappStopAdvertisement ();
/*Once We stop advertisement, the
CYBLE_EVT_GAPP_ADVERTISEMENT_START_STOP event is invoked.
After this, the API for removing the device from whitelist
is invoked in the StackEventHandler*/
DelRequest = 1;
break;
}
else
{
printf("There is no device with that number.\r\n");
}
}
else
{
printf ("Invaid Index. Press A to Add and R to remove a Device");
break;
}
}
}
}
}
}
}
}
/*******************************************************************************
* Function Name: SwitchRole
********************************************************************************
* Summary:
* This function switches the role between Central and Peripheral. If device
* is connected while switching role, then it is first disconnected.
*
* Parameters:
* void
*
* Return:
* void
*
*******************************************************************************/
void SwitchRole(void)
{
CYBLE_API_RESULT_T apiResult;
/* if the switch role flag is set... */
if(switch_Role == TRUE)
{
/* Process pending BLE events */
CyBle_ProcessEvents();
/* If there is an existing connection, then disconnect before switching
* role. */
if((cyBle_connHandle.bdHandle != 0))
{
/* Disconnect the device and process the event */
CyBle_GapDisconnect(cyBle_connHandle.bdHandle);
CyBle_ProcessEvents();
#ifdef DEBUG_ENABLED
UART_UartPutString("Peripheral closed connection ");
SendBLEStatetoUART(CyBle_GetState());
UART_UartPutCRLF(' ');
#endif
}
switch(ble_gap_state)
{
case BLE_PERIPHERAL:
/* If the current role is Peripheral and system is advertising,
* then stop advertisement before switching role */
if(CyBle_GetState() == CYBLE_STATE_ADVERTISING)
{
CyBle_GappStopAdvertisement();
CyBle_ProcessEvents();
#ifdef DEBUG_ENABLED
UART_UartPutString("Peripheral Advertisment Stopped ");
SendBLEStatetoUART(CyBle_GetState());
UART_UartPutCRLF(' ');
#endif
}
if(CyBle_GetState() == CYBLE_STATE_DISCONNECTED)
{
/* Switch BLE role by starting scan. This way, the system is set
* to Central role */
apiResult = CyBle_GapcStartScan(CYBLE_SCANNING_FAST);
if(CYBLE_ERROR_OK == apiResult)
{
#ifdef DEBUG_ENABLED
UART_UartPutString("Start Scan API called ");
SendBLEStatetoUART(CyBle_GetState());
UART_UartPutCRLF(' ');
#endif
/* Record the time at which Central role was started. This will be
* used for timeout and switching to Peripheral operation*/
centralStartedTime = WatchDog_CurrentCount();
/* Update the current BLE role to Central */
ble_gap_state = BLE_CENTRAL;
/* Reset the switch role flag*/
switch_Role = FALSE;
}
else
{
/* If scanning did not start, maintain the current role and retry later */
ble_gap_state = BLE_PERIPHERAL;
#ifdef DEBUG_ENABLED
UART_UartPutString("Start Scan API failed ");
SendBLEStatetoUART(CyBle_GetState());
UART_UartPutCRLF(' ');
#endif
}
}
/* Process Pending BLE Events */
CyBle_ProcessEvents();
break;
case BLE_CENTRAL:
/* If the current role is Central and system is scanning,
* then stop scanning before switching role */
if(CyBle_GetState() == CYBLE_STATE_SCANNING)
{
CyBle_GapcStopScan();
CyBle_ProcessEvents();
#ifdef DEBUG_ENABLED
UART_UartPutString("Central Scan stopped ");
UART_UartPutCRLF(' ');
#endif
}
if(CyBle_GetState() == CYBLE_STATE_DISCONNECTED)
{
#ifdef ENABLE_ADV_DATA_COUNTER
/* Increment data counter */
new_advData.advData[new_advData.advDataLen - 1] = dataADVCounter;
cyBle_discoveryModeInfo.advData = &new_advData;
#ifdef DEBUG_ENABLED
UART_UartPutString("Updated ADV data = ");
PrintNum(dataADVCounter);
UART_UartPutCRLF(' ');
#endif
#endif
/* Switch BLE role by starting advertisement. This way, the system is
* set to Peripheral role */
apiResult = CyBle_GappStartAdvertisement(CYBLE_ADVERTISING_FAST);
if(apiResult == CYBLE_ERROR_OK)
{
/* If advertisement started successfully, set the BLE state and
* reset the switch role flag*/
ble_gap_state = BLE_PERIPHERAL;
clientConnectToDevice = FALSE;
switch_Role = FALSE;
#ifdef DEBUG_ENABLED
UART_UartPutString("Peripheral Advertisment called ");
SendBLEStatetoUART(CyBle_GetState());
UART_UartPutCRLF(' ');
#endif
}
else
{
/* If advertisement did not start, maintain the current role and retry later */
ble_gap_state = BLE_CENTRAL;
#ifdef DEBUG_ENABLED
UART_UartPutString("Start Peripheral Advertisment Failed ");
SendBLEStatetoUART(CyBle_GetState());
UART_UartPutCRLF(' ');
#endif
}
}
/* Process Pending BLE Events */
CyBle_ProcessEvents();
break;
default:
break;
}
}
}
/*******************************************************************************
* Function Name: BondingImplementation()
********************************************************************************
* Summary:
* Implements bonding of peer BLE device information.
*
* Parameters:
* None
*
* Return:
* None
*
* Theory:
* The function stores the peer BLE device information to flash (called bonding)
* when the device is ready. When the user wants to clear the bond information,
* it is cleared in this function.
*
*******************************************************************************/
static void BondingImplementation(void)
{
uint8 command;
CYBLE_GAP_BD_ADDR_T clearAllDevices = {{0,0,0,0,0,0},0};
switch(authState)
{
case AUTHENTICATION_COMPLETE_BONDING_REQD:
/* Store bonding data of the current connection */
while(CYBLE_ERROR_OK != CyBle_StoreBondingData(1));
authState = AUTHENTICATION_BONDING_COMPLETE;
UART_UartPutString("Bonding complete. ");
break;
case AUTHENTICATION_BONDING_COMPLETE:
/* See if the user pressed 'R' button to clear the bond list. */
command = UART_UartGetChar();
if(command != 0u)
{
if((command == 'r') || (command == 'R'))
{
/* User wants the bond to be removed */
UART_UartPutString("\n\rClear the bond list. ");
if(CyBle_GetState() == CYBLE_STATE_CONNECTED)
{
/* Disconnect */
authState = AUTHENTICATION_BONDING_REMOVE_WAITING_EVENT;
CyBle_GapDisconnect(cyBle_connHandle.bdHandle);
}
else if(CyBle_GetState() == CYBLE_STATE_ADVERTISING)
{
/* Stop advertisement */
authState = AUTHENTICATION_BONDING_REMOVE_WAITING_EVENT;
CyBle_GappStopAdvertisement();
}
else
{
authState = AUTHENTICATION_BONDING_REMOVE_GO_AHEAD;
}
}
}
break;
case AUTHENTICATION_BONDING_REMOVE_GO_AHEAD:
/* Remove all bonded devices in the list */
CyBle_GapRemoveDeviceFromWhiteList(&clearAllDevices);
while(CYBLE_ERROR_OK != CyBle_StoreBondingData(1));
UART_UartPutString("Cleared the list of bonded devices. \n\n\r");
authState = AUTHENTICATION_NOT_CONNECTED;
/* Start advertisement again */
UART_UartPutString("Advertising. ");
CyBle_GappStartAdvertisement(CYBLE_ADVERTISING_FAST);
break;
default:
break;
}
}
