BTD.cpp

/* Copyright (C) 2012 Kristian Lauszus, TKJ Electronics. All rights reserved.
 
 This software may be distributed and modified under the terms of the GNU
 General Public License version 2 (GPL2) as published by the Free Software
 Foundation and appearing in the file GPL2.TXT included in the packaging of
 this file. Please note that GPL2 Section 2[b] requires that all works based
 on this software must also be made publicly available under the terms of
 the GPL2 ("Copyleft").
 
 Contact information
 -------------------
 
 Kristian Lauszus, TKJ Electronics
 Web      :  http://www.tkjelectronics.com
 e-mail   :  kristianl@tkjelectronics.com
 */

#include "BTD.h"
#define DEBUG // Uncomment to print data for debugging
//#define EXTRADEBUG // Uncomment to get even more debugging data

const uint8_t BTD::BTD_EVENT_PIPE  = 1;
const uint8_t BTD::BTD_DATAIN_PIPE = 2;
const uint8_t BTD::BTD_DATAOUT_PIPE = 3;

BTD::BTD(USB *p):
pUsb(p), // Pointer to USB class instance - mandatory
bAddress(0), // Device address - mandatory
bNumEP(1), // If config descriptor needs to be parsed
qNextPollTime(0), // Reset NextPollTime
bPollEnable(false) // Don't start polling before dongle is connected
{
    for(uint8_t i=0; i<BTD_MAX_ENDPOINTS; i++) {
		epInfo[i].epAddr		= 0;
		epInfo[i].maxPktSize	= (i) ? 0 : 8;
		epInfo[i].epAttribs		= 0;        
        epInfo[i].bmNakPower    = (i) ? USB_NAK_NOWAIT : USB_NAK_MAX_POWER;
	}
    
    if (pUsb) // register in USB subsystem
		pUsb->RegisterDeviceClass(this); //set devConfig[] entry
    
    wiiServiceID = -1;
}

uint8_t BTD::Init(uint8_t parent, uint8_t port, bool lowspeed) {
    uint8_t	buf[sizeof(USB_DEVICE_DESCRIPTOR)];
	uint8_t	rcode;
	UsbDevice *p = NULL;
	EpInfo *oldep_ptr = NULL;  
    uint8_t	num_of_conf; // number of configurations
    uint16_t PID;
    uint16_t VID;
    
    // get memory address of USB device address pool
	AddressPool	&addrPool = pUsb->GetAddressPool();    
#ifdef EXTRADEBUG
	Notify(PSTR("\r\nBTD Init"));
#endif
    // check if address has already been assigned to an instance
    if (bAddress) {
#ifdef DEBUG
        Notify(PSTR("\r\nAddress in use"));
#endif
        return USB_ERROR_CLASS_INSTANCE_ALREADY_IN_USE;
    }
    
    // Get pointer to pseudo device with address 0 assigned
    p = addrPool.GetUsbDevicePtr(0);
    
    if (!p) {        
#ifdef DEBUG
	    Notify(PSTR("\r\nAddress not found"));
#endif
        return USB_ERROR_ADDRESS_NOT_FOUND_IN_POOL;
    }
    
    if (!p->epinfo) {
#ifdef DEBUG
        Notify(PSTR("\r\nepinfo is null"));
#endif
        return USB_ERROR_EPINFO_IS_NULL;
    }
    
    // Save old pointer to EP_RECORD of address 0
    oldep_ptr = p->epinfo;
    
    // Temporary assign new pointer to epInfo to p->epinfo in order to avoid toggle inconsistence
    p->epinfo = epInfo;
    
    p->lowspeed = lowspeed;
    
    // Get device descriptor
    rcode = pUsb->getDevDescr(0, 0, sizeof(USB_DEVICE_DESCRIPTOR), (uint8_t*)buf);// Get device descriptor - addr, ep, nbytes, data
    
    // Restore p->epinfo
    p->epinfo = oldep_ptr;
    
    if(rcode)
        goto FailGetDevDescr;
    
    // Allocate new address according to device class
    bAddress = addrPool.AllocAddress(parent, false, port);
    
    if (!bAddress)
		return USB_ERROR_OUT_OF_ADDRESS_SPACE_IN_POOL;
    
    // Extract Max Packet Size from device descriptor
    epInfo[0].maxPktSize = (uint8_t)((USB_DEVICE_DESCRIPTOR*)buf)->bMaxPacketSize0; 
    
    // Assign new address to the device
    rcode = pUsb->setAddr( 0, 0, bAddress );
    if (rcode) {
        p->lowspeed = false;
        addrPool.FreeAddress(bAddress);
        bAddress = 0;
#ifdef DEBUG
        Notify(PSTR("\r\nsetAddr: "));
#endif
        PrintHex<uint8_t>(rcode);
        return rcode;
    }
#ifdef EXTRADEBUG
    Notify(PSTR("\r\nAddr: "));
    PrintHex<uint8_t>(bAddress);
#endif
    p->lowspeed = false;
    
    //get pointer to assigned address record
    p = addrPool.GetUsbDevicePtr(bAddress);
    if (!p) 
        return USB_ERROR_ADDRESS_NOT_FOUND_IN_POOL;
    
    p->lowspeed = lowspeed;        
    
    // Assign epInfo to epinfo pointer - only EP0 is known
    rcode = pUsb->setEpInfoEntry(bAddress, 1, epInfo);
    if (rcode)
        goto FailSetDevTblEntry;
    VID = ((USB_DEVICE_DESCRIPTOR*)buf)->idVendor;
    PID = ((USB_DEVICE_DESCRIPTOR*)buf)->idProduct;
    
    if(VID == PS3_VID && (PID == PS3_PID ||  PID == PS3NAVIGATION_PID || PID == PS3MOVE_PID)) {
        /* We only need the Control endpoint, so we don't have to initialize the other endpoints of device */                
        rcode = pUsb->setConf(bAddress, epInfo[ BTD_CONTROL_PIPE ].epAddr, 1);
        if( rcode )
            goto FailSetConf;
        
        if(PID == PS3_PID || PID == PS3NAVIGATION_PID) {
#ifdef DEBUG
            if(PID == PS3_PID)
                Notify(PSTR("\r\nDualshock 3 Controller Connected"));
            else // must be a navigation controller
                Notify(PSTR("\r\nNavigation Controller Connected"));
#endif
            /* Set internal bluetooth address */
            setBdaddr(my_bdaddr);
        }
        else { // must be a Motion controller
#ifdef DEBUG
            Notify(PSTR("\r\nMotion Controller Connected"));
#endif
            setMoveBdaddr(my_bdaddr);
        }
        rcode = pUsb->setConf(bAddress, epInfo[ BTD_CONTROL_PIPE ].epAddr, 0); // Reset configuration value
        pUsb->setAddr(bAddress, 0, 0); // Reset address
        Release(); // Release device
        return USB_DEV_CONFIG_ERROR_DEVICE_NOT_SUPPORTED; // return
    }
    else {
        num_of_conf = ((USB_DEVICE_DESCRIPTOR*)buf)->bNumConfigurations;

        // check if attached device is a Bluetooth dongle and fill endpoint data structure
        // first interface in the configuration must have Bluetooth assigned Class/Subclass/Protocol
        // and 3 endpoints - interrupt-IN, bulk-IN, bulk-OUT,
        // not necessarily in this order
        for (uint8_t i=0; i<num_of_conf; i++) {
            ConfigDescParser<USB_CLASS_WIRELESS_CTRL, WI_SUBCLASS_RF, WI_PROTOCOL_BT, CP_MASK_COMPARE_ALL> confDescrParser(this);
            rcode = pUsb->getConfDescr(bAddress, 0, i, &confDescrParser);
            if(rcode)
                goto FailGetConfDescr;
            if(bNumEP >= BTD_MAX_ENDPOINTS) // All endpoints extracted
                break;
        }
    
        if (bNumEP < BTD_MAX_ENDPOINTS)
            goto FailUnknownDevice;
        
        // Assign epInfo to epinfo pointer - this time all 3 endpoins
        rcode = pUsb->setEpInfoEntry(bAddress, bNumEP, epInfo);
        if(rcode)
            goto FailSetDevTblEntry;
        
        delay(200); // Give time for address change
    
        // Set Configuration Value
        rcode = pUsb->setConf(bAddress, epInfo[ BTD_CONTROL_PIPE ].epAddr, bConfNum);
        if(rcode)
            goto FailSetConf;
    
        hci_num_reset_loops = 100; // only loop 100 times before trying to send the hci reset command
        hci_counter = 0;
        hci_state = HCI_INIT_STATE;
        watingForConnection = false;
        bPollEnable = true;

#ifdef DEBUG
        Notify(PSTR("\r\nBluetooth Dongle Initialized"));
#endif
    }
    return 0; // Successful configuration
    
    /* diagnostic messages */  
FailGetDevDescr:
#ifdef DEBUG
    Notify(PSTR("\r\ngetDevDescr"));
#endif
    goto Fail;    
FailSetDevTblEntry:
#ifdef DEBUG
    Notify(PSTR("\r\nsetDevTblEn"));
#endif
    goto Fail;
FailGetConfDescr:
#ifdef DEBUG
    Notify(PSTR("\r\ngetConf"));
#endif
    goto Fail;
FailSetConf:
#ifdef DEBUG
    Notify(PSTR("\r\nsetConf"));
#endif
    goto Fail;
FailUnknownDevice:
#ifdef DEBUG
    Notify(PSTR("\r\nUnknown Device Connected - VID: "));
    PrintHex<uint16_t>(VID);
    Notify(PSTR(" PID: "));
    PrintHex<uint16_t>(PID);
#endif
    pUsb->setAddr(bAddress, 0, 0); // Reset address
    rcode = USB_DEV_CONFIG_ERROR_DEVICE_NOT_SUPPORTED;
    goto Fail;
Fail:
#ifdef DEBUG
    Notify(PSTR("\r\nBTD Init Failed, error code: "));
    //Serial.print(rcode);                     
#endif    
    Release();
    return rcode;
}
/* Extracts interrupt-IN, bulk-IN, bulk-OUT endpoint information from config descriptor */
void BTD::EndpointXtract(uint8_t conf, uint8_t iface, uint8_t alt, uint8_t proto, const USB_ENDPOINT_DESCRIPTOR *pep) {
	//ErrorMessage<uint8_t>(PSTR("Conf.Val"),conf);
	//ErrorMessage<uint8_t>(PSTR("Iface Num"),iface);
	//ErrorMessage<uint8_t>(PSTR("Alt.Set"),alt);
	
	if(alt) // wrong interface - by BT spec, no alt setting 
        return;
    
    bConfNum = conf;    
	uint8_t index;
    
    if ((pep->bmAttributes & 0x03) == 3 && (pep->bEndpointAddress & 0x80) == 0x80) // Interrupt In endpoint found
		index = BTD_EVENT_PIPE;
    
    else {
        if ((pep->bmAttributes & 0x02) == 2) // bulk endpoint found 
			index = ((pep->bEndpointAddress & 0x80) == 0x80) ? BTD_DATAIN_PIPE : BTD_DATAOUT_PIPE;
        else
            return;
    }
    
    // Fill the rest of endpoint data structure  
    epInfo[index].epAddr		= (pep->bEndpointAddress & 0x0F);
    epInfo[index].maxPktSize	= (uint8_t)pep->wMaxPacketSize;  
#ifdef EXTRADEBUG
    PrintEndpointDescriptor(pep);    
#endif
    if(pollInterval < pep->bInterval) // Set the polling interval as the largest polling interval obtained from endpoints
        pollInterval = pep->bInterval;   
    bNumEP++;
}
void BTD::PrintEndpointDescriptor(const USB_ENDPOINT_DESCRIPTOR* ep_ptr) {
	Notify(PSTR("\r\nEndpoint descriptor:"));
	Notify(PSTR("\r\nLength:\t\t"));
	PrintHex<uint8_t>(ep_ptr->bLength);
	Notify(PSTR("\r\nType:\t\t"));
	PrintHex<uint8_t>(ep_ptr->bDescriptorType);
	Notify(PSTR("\r\nAddress:\t"));
	PrintHex<uint8_t>(ep_ptr->bEndpointAddress);
	Notify(PSTR("\r\nAttributes:\t"));
	PrintHex<uint8_t>(ep_ptr->bmAttributes);
	Notify(PSTR("\r\nMaxPktSize:\t"));
	PrintHex<uint16_t>(ep_ptr->wMaxPacketSize);
	Notify(PSTR("\r\nPoll Intrv:\t"));
	PrintHex<uint8_t>(ep_ptr->bInterval);
}

/* Performs a cleanup after failed Init() attempt */
uint8_t BTD::Release() {
    for (uint8_t i=0; i<BTD_NUMSERVICES; i++)
        if (btService[i])
            btService[i]->Reset(); // Reset all Bluetooth services
	pUsb->GetAddressPool().FreeAddress(bAddress);    
	bAddress = 0;
    bPollEnable = false;
    bNumEP = 1; // must have to be reset to 1	
	return 0;
}
uint8_t BTD::Poll() {
	if (!bPollEnable)
		return 0;
    if (qNextPollTime <= millis()) { // Don't poll if shorter than polling interval
        qNextPollTime = millis() + pollInterval; // Set new poll time
        HCI_event_task(); // poll the HCI event pipe
        ACL_event_task(); // start polling the ACL input pipe too, though discard data until connected        
    }    
	return 0;
}

void BTD::HCI_event_task() {
    /* check the event pipe*/    
    uint16_t MAX_BUFFER_SIZE = BULK_MAXPKTSIZE; // Request more than 16 bytes anyway, the inTransfer routine will take care of this
    uint8_t rcode = pUsb->inTransfer(bAddress, epInfo[ BTD_EVENT_PIPE ].epAddr, &MAX_BUFFER_SIZE, hcibuf); // input on endpoint 1
    if(!rcode || rcode == hrNAK) // Check for errors
    {
        switch (hcibuf[0]) //switch on event type
        {
            case EV_COMMAND_COMPLETE:                
                if (!hcibuf[5]) { // Check if command succeeded
                    hci_event_flag |= HCI_FLAG_CMD_COMPLETE; // set command complete flag
                    if((hcibuf[3] == 0x01) && (hcibuf[4] == 0x10)) { // parameters from read local version information
                        hci_version = hcibuf[6]; // Used to check if it supports 2.0+EDR - see http://www.bluetooth.org/Technical/AssignedNumbers/hci.htm
                        hci_event_flag |= HCI_FLAG_READ_VERSION;
                    } else if((hcibuf[3] == 0x09) && (hcibuf[4] == 0x10)) { // parameters from read local bluetooth address
                        for (uint8_t i = 0; i < 6; i++) 
                            my_bdaddr[i] = hcibuf[6 + i];
                        hci_event_flag |= HCI_FLAG_READ_BDADDR;
                    }
                }
                break;
                
            case EV_COMMAND_STATUS:
                if(hcibuf[2]) { // show status on serial if not OK
#ifdef DEBUG
                    Notify(PSTR("\r\nHCI Command Failed: "));
                    PrintHex<uint8_t>(hcibuf[2]);
                    Notify(PSTR(" ")); 
                    PrintHex<uint8_t>(hcibuf[4]);
                    Notify(PSTR(" "));
                    PrintHex<uint8_t>(hcibuf[5]);                    
#endif
                }
                break;
                
            case EV_INQUIRY_COMPLETE:
                if(inquiry_counter >= 5) {
                    inquiry_counter = 0;
#ifdef DEBUG
                    Notify(PSTR("\r\nCouldn't find Wiimote"));
#endif
                    connectToWii = false;
                    pairWithWii = false;
                    hci_state = HCI_SCANNING_STATE;                    
                }
                inquiry_counter++;
                break;
                
            case EV_INQUIRY_RESULT:
                if (hcibuf[2]) { // Check that there is more than zero responses
#ifdef EXTRADEBUG
                    Notify(PSTR("\r\nNumber of responses: "));
                    //Serial.print(hcibuf[2]);
#endif
                    for(uint8_t i = 0; i < hcibuf[2]; i++) {
                        if((hcibuf[4+8*hcibuf[2]+3*i] == 0x04 && hcibuf[5+8*hcibuf[2]+3*i] == 0x25 && hcibuf[6+8*hcibuf[2]+3*i] == 0x00) || (hcibuf[4+8*hcibuf[2]+3*i] == 0x08 && hcibuf[5+8*hcibuf[2]+3*i] == 0x05 && hcibuf[6+8*hcibuf[2]+3*i] == 0x00)) { // See http://bluetooth-pentest.narod.ru/software/bluetooth_class_of_device-service_generator.html and http://wiibrew.org/wiki/Wiimote#SDP_information
                            disc_bdaddr[0] = hcibuf[3+6*i];
                            disc_bdaddr[1] = hcibuf[4+6*i];
                            disc_bdaddr[2] = hcibuf[5+6*i];
                            disc_bdaddr[3] = hcibuf[6+6*i];
                            disc_bdaddr[4] = hcibuf[7+6*i];
                            disc_bdaddr[5] = hcibuf[8+6*i];
                            hci_event_flag |= HCI_FLAG_WII_FOUND;
                            break;
                        }
#ifdef EXTRADEBUG
                        else {
                            Notify(PSTR("\r\nClass of device: "));
                            PrintHex<uint8_t>(hcibuf[6+8*hcibuf[2]+3*i]);
                            Notify(PSTR(" "));
                            PrintHex<uint8_t>(hcibuf[5+8*hcibuf[2]+3*i]);
                            Notify(PSTR(" "));
                            PrintHex<uint8_t>(hcibuf[4+8*hcibuf[2]+3*i]);
                        }
#endif
                    }
                }
                break;
                
            case EV_CONNECT_COMPLETE:
                hci_event_flag |= HCI_FLAG_CONNECT_EVENT;
                if (!hcibuf[2]) { // check if connected OK
                    hci_handle = hcibuf[3] | ((hcibuf[4] & 0x0F) << 8); // store the handle for the ACL connection
                    hci_event_flag |= HCI_FLAG_CONN_COMPLETE; // set connection complete flag
                }
#ifdef EXTRADEBUG
                else {
                    Notify(PSTR("\r\nConnection Failed"));
                }
#endif
                break;
                
            case EV_DISCONNECT_COMPLETE:            
                if (!hcibuf[2]) { // check if disconnected OK
                    hci_event_flag |= HCI_FLAG_DISCONN_COMPLETE; // set disconnect command complete flag
                    hci_event_flag &= ~HCI_FLAG_CONN_COMPLETE; // clear connection complete flag
                }
                break;                              
                
            case EV_REMOTE_NAME_COMPLETE:
                if (!hcibuf[2]) { // check if reading is OK
                    for (uint8_t i = 0; i < 30; i++)
                        remote_name[i] = hcibuf[9 + i];  //store first 30 bytes
                    hci_event_flag |= HCI_FLAG_REMOTE_NAME_COMPLETE;
                }
                break;
                
            case EV_INCOMING_CONNECT:
                disc_bdaddr[0] = hcibuf[2];
                disc_bdaddr[1] = hcibuf[3];
                disc_bdaddr[2] = hcibuf[4];
                disc_bdaddr[3] = hcibuf[5];
                disc_bdaddr[4] = hcibuf[6];
                disc_bdaddr[5] = hcibuf[7];
                hci_event_flag |= HCI_FLAG_INCOMING_REQUEST;
                break;
                
            case EV_PIN_CODE_REQUEST:
                if(pairWithWii) {
#ifdef DEBUG
                    Notify(PSTR("\r\nPairing with wiimote"));
#endif
                    hci_pin_code_request_reply();                    
                }
                else if(btdPin != NULL) {
#ifdef DEBUG
                    Notify(PSTR("\r\nBluetooth pin is set too: "));
                    //Serial.print(btdPin);
#endif
                    hci_pin_code_request_reply();
                }
                else {
#ifdef DEBUG
                    Notify(PSTR("\r\nNo pin was set"));
#endif
                    hci_pin_code_negative_request_reply();
                }
                break;
                
            case EV_LINK_KEY_REQUEST:
#ifdef DEBUG
                Notify(PSTR("\r\nReceived Key Request"));
#endif
                hci_link_key_request_negative_reply();
                break;
                
            case EV_AUTHENTICATION_COMPLETE:
                if(pairWithWii && !connectToWii) {
#ifdef DEBUG
                    Notify(PSTR("\r\nPairing successful"));
#endif
                    connectToWii = true; // Only send the ACL data to the Wii service
                }
                break;
            /* We will just ignore the following events */
            case EV_NUM_COMPLETE_PKT:                
            case EV_ROLE_CHANGED:                
            case EV_PAGE_SCAN_REP_MODE:                
            case EV_LOOPBACK_COMMAND:                
            case EV_DATA_BUFFER_OVERFLOW:
            case EV_CHANGE_CONNECTION_LINK:
            case EV_MAX_SLOTS_CHANGE:
            case EV_QOS_SETUP_COMPLETE:
            case EV_LINK_KEY_NOTIFICATION:
            case EV_ENCRYPTION_CHANGE:
            case EV_READ_REMOTE_VERSION_INFORMATION_COMPLETE:
                break;
#ifdef EXTRADEBUG
            default:
                if(hcibuf[0] != 0x00) {
                    Notify(PSTR("\r\nUnmanaged HCI Event: "));
                    PrintHex<uint8_t>(hcibuf[0]);
                }
                break;
#endif
        } // switch
        HCI_task();
    }
#ifdef EXTRADEBUG
    else {
        Notify(PSTR("\r\nHCI event error: "));
        PrintHex<uint8_t>(rcode);
    }
#endif
}

/* Poll Bluetooth and print result */
void BTD::HCI_task() {
    switch (hci_state){
        case HCI_INIT_STATE:
            hci_counter++;
            if (hci_counter > hci_num_reset_loops) { // wait until we have looped x times to clear any old events
                hci_reset();
                hci_state = HCI_RESET_STATE;
                hci_counter = 0;
            }
            break;
            
        case HCI_RESET_STATE:
            hci_counter++;
            if (hci_cmd_complete) {
                hci_counter = 0;
#ifdef DEBUG
                Notify(PSTR("\r\nHCI Reset complete"));
#endif
                hci_state = HCI_BDADDR_STATE;
                hci_read_bdaddr(); 
            }
            else if (hci_counter > hci_num_reset_loops) {
                hci_num_reset_loops *= 10;
                if(hci_num_reset_loops > 2000)
                    hci_num_reset_loops = 2000;
#ifdef DEBUG
                Notify(PSTR("\r\nNo response to HCI Reset"));
#endif
                hci_state = HCI_INIT_STATE;
                hci_counter = 0;
            }
            break;
            
        case HCI_BDADDR_STATE:
            if (hci_read_bdaddr_complete) {
#ifdef DEBUG
                Notify(PSTR("\r\nLocal Bluetooth Address: "));
                for(int8_t i = 5; i > 0;i--) {
                    PrintHex<uint8_t>(my_bdaddr[i]); 
                    Notify(PSTR(":"));
                }      
                PrintHex<uint8_t>(my_bdaddr[0]);
#endif
                hci_read_local_version_information();
                hci_state = HCI_LOCAL_VERSION_STATE;                
            }
            break;
            
        case HCI_LOCAL_VERSION_STATE: // The local version is used by the PS3BT class
            if (hci_read_version_complete) {
                if(btdName != NULL) {
                    hci_set_local_name(btdName);
                    hci_state = HCI_SET_NAME_STATE;
                } else
                    hci_state = HCI_CHECK_WII_SERVICE;                    
            }
            break;
            
        case HCI_SET_NAME_STATE:
            if (hci_cmd_complete) {
#ifdef DEBUG               
                Notify(PSTR("\r\nThe name is set to: "));
                //Serial.print(btdName);
#endif
                hci_state = HCI_CHECK_WII_SERVICE;
            }
            break;
            
        case HCI_CHECK_WII_SERVICE:
            if(pairWithWii) { // Check if it should try to connect to a wiimote
#ifdef DEBUG
                Notify(PSTR("\r\nStarting inquiry\r\nPress 1 & 2 on the Wiimote"));
#endif
                hci_inquiry();
                hci_state = HCI_INQUIRY_STATE;
            }
            else
                hci_state = HCI_SCANNING_STATE; // Don't try to connect to a Wiimote
            break;
            
        case HCI_INQUIRY_STATE:
            if(hci_wii_found) {
                hci_inquiry_cancel(); // Stop inquiry
#ifdef DEBUG
                Notify(PSTR("\r\nWiimote found"));
                Notify(PSTR("\r\nNow just create the instance like so:"));
                Notify(PSTR("\r\nWII Wii(&Btd);"));
                Notify(PSTR("\r\nAnd then press any button on the Wiimote"));                
#endif                                
                hci_state = HCI_CONNECT_WII_STATE;
            }
            break;
            
        case HCI_CONNECT_WII_STATE:
            if(hci_cmd_complete) {
#ifdef DEBUG
                Notify(PSTR("\r\nConnecting to Wiimote"));
#endif            
                hci_connect();
                hci_state = HCI_CONNECTED_WII_STATE;
            }
            break;
            
        case HCI_CONNECTED_WII_STATE:
            if(hci_connect_event) {
                if(hci_connect_complete) {
#ifdef DEBUG
                    Notify(PSTR("\r\nConnected to Wiimote"));
#endif                    
                    hci_authentication_request(); // This will start the pairing with the wiimote
                    hci_state = HCI_SCANNING_STATE;
                } else {
#ifdef DEBUG
                    Notify(PSTR("\r\nTrying to connect one more time..."));
#endif
                    hci_connect(); // Try to connect one more time
                }
            }
            break;
            
        case HCI_SCANNING_STATE:
            if(!connectToWii && !pairWithWii) {
#ifdef DEBUG
                Notify(PSTR("\r\nWait For Incoming Connection Request"));
#endif            
                hci_write_scan_enable();
                watingForConnection = true;
                hci_state = HCI_CONNECT_IN_STATE;
            }
            break;
            
        case HCI_CONNECT_IN_STATE:
            if(hci_incoming_connect_request) {
                watingForConnection = false;
#ifdef DEBUG
                Notify(PSTR("\r\nIncoming Connection Request"));
#endif                
                hci_remote_name();
                hci_state = HCI_REMOTE_NAME_STATE;
            } else if (hci_disconnect_complete)
                hci_state = HCI_DISCONNECT_STATE;
            break;     
            
        case HCI_REMOTE_NAME_STATE:
            if(hci_remote_name_complete) {
#ifdef DEBUG
                Notify(PSTR("\r\nRemote Name: "));
                for (uint8_t i = 0; i < 30; i++) {
                    if(remote_name[i] == NULL)
                        break;
                    //Serial.write(remote_name[i]);   
                }             
#endif
                hci_accept_connection();
                hci_state = HCI_CONNECTED_STATE;                                
            }      
            break;
            
        case HCI_CONNECTED_STATE:
            if (hci_connect_complete) {     
#ifdef DEBUG
                Notify(PSTR("\r\nConnected to Device: "));
                for(int8_t i = 5; i>0;i--) {
                    PrintHex<uint8_t>(disc_bdaddr[i]);
                    Notify(PSTR(":"));
                }      
                PrintHex<uint8_t>(disc_bdaddr[0]);
#endif
                l2capConnectionClaimed = false;
                if(strncmp((const char*)remote_name, "Nintendo", 8) == 0) {
#ifdef DEBUG
                    Notify(PSTR("\r\nWiimote is connecting"));
#endif
                    incomingWii = true;
                }
                hci_event_flag = 0;
                hci_state = HCI_DONE_STATE;
            }
            break;

        case HCI_DONE_STATE:
            hci_counter++;
            if (hci_counter > 1000) { // Wait until we have looped 1000 times to make sure that the L2CAP connection has been started
                hci_counter = 0;
                hci_state = HCI_SCANNING_STATE;                
            }            
            break;
            
        case HCI_DISCONNECT_STATE:
            if (hci_disconnect_complete) {
#ifdef DEBUG
                Notify(PSTR("\r\nHCI Disconnected from Device"));
#endif
                hci_event_flag = 0; // Clear all flags 
                
                // Reset all buffers                        
                for (uint8_t i = 0; i < BULK_MAXPKTSIZE; i++)
                    hcibuf[i] = 0;        
                for (uint8_t i = 0; i < BULK_MAXPKTSIZE; i++)
                    l2capinbuf[i] = 0;
                                                        
                hci_state = HCI_SCANNING_STATE;
            }
            break;
        default:
            break;
    }
}

void BTD::ACL_event_task() {
    uint16_t MAX_BUFFER_SIZE = BULK_MAXPKTSIZE;
    uint8_t rcode = pUsb->inTransfer(bAddress, epInfo[ BTD_DATAIN_PIPE ].epAddr, &MAX_BUFFER_SIZE, l2capinbuf); // input on endpoint 2  
    if(!rcode) { // Check for errors
        if(connectToWii) // Only send the data to the Wii service
            btService[wiiServiceID]->ACLData(l2capinbuf);
        else {
            for (uint8_t i=0; i<BTD_NUMSERVICES; i++)
                if (btService[i])
                    btService[i]->ACLData(l2capinbuf);
        }
    }
#ifdef EXTRADEBUG
    else if (rcode != hrNAK) {
        Notify(PSTR("\r\nACL data in error: "));
        PrintHex<uint8_t>(rcode);
    }
#endif
    for (uint8_t i=0; i<BTD_NUMSERVICES; i++)
        if (btService[i])
            btService[i]->Run();
}

/************************************************************/
/*                    HCI Commands                        */
/************************************************************/
void BTD::HCI_Command(uint8_t* data, uint16_t nbytes) {
    hci_event_flag &= ~HCI_FLAG_CMD_COMPLETE;
    pUsb->ctrlReq(bAddress, epInfo[ BTD_CONTROL_PIPE ].epAddr, bmREQ_HCI_OUT, 0x00, 0x00, 0x00 ,0x00, nbytes, nbytes, data, NULL);    
}
void BTD::hci_reset() {
    hci_event_flag = 0; // Clear all the flags
    hcibuf[0] = 0x03; // HCI OCF = 3
    hcibuf[1] = 0x03 << 2; // HCI OGF = 3
    hcibuf[2] = 0x00;
    HCI_Command(hcibuf, 3);
}
void BTD::hci_write_scan_enable() {
    hci_event_flag &= ~HCI_FLAG_INCOMING_REQUEST;
    hcibuf[0] = 0x1A; // HCI OCF = 1A
    hcibuf[1] = 0x03 << 2; // HCI OGF = 3
    hcibuf[2] = 0x01; // parameter length = 1
    if(btdName != NULL)
        hcibuf[3] = 0x03; // Inquiry Scan enabled. Page Scan enabled.
    else
        hcibuf[3] = 0x02; // Inquiry Scan disabled. Page Scan enabled.
    HCI_Command(hcibuf, 4);
}
void BTD::hci_write_scan_disable() {
    hcibuf[0] = 0x1A; // HCI OCF = 1A
    hcibuf[1] = 0x03 << 2; // HCI OGF = 3
    hcibuf[2] = 0x01; // parameter length = 1
    hcibuf[3] = 0x00; // Inquiry Scan disabled. Page Scan disabled.
    HCI_Command(hcibuf, 4);
}
void BTD::hci_read_bdaddr() {   
    hcibuf[0] = 0x09; // HCI OCF = 9
    hcibuf[1] = 0x04 << 2; // HCI OGF = 4
    hcibuf[2] = 0x00;
    HCI_Command(hcibuf, 3);
}
void BTD::hci_read_local_version_information() {
    hcibuf[0] = 0x01; // HCI OCF = 1
    hcibuf[1] = 0x04 << 2; // HCI OGF = 4
    hcibuf[2] = 0x00;
    HCI_Command(hcibuf, 3);
}
void BTD::hci_accept_connection() {
    hci_event_flag &= ~HCI_FLAG_CONN_COMPLETE;
    hcibuf[0] = 0x09; // HCI OCF = 9
    hcibuf[1] = 0x01 << 2; // HCI OGF = 1
    hcibuf[2] = 0x07; // parameter length 7
    hcibuf[3] = disc_bdaddr[0]; // 6 octet bdaddr
    hcibuf[4] = disc_bdaddr[1];
    hcibuf[5] = disc_bdaddr[2];
    hcibuf[6] = disc_bdaddr[3];
    hcibuf[7] = disc_bdaddr[4];
    hcibuf[8] = disc_bdaddr[5];
    hcibuf[9] = 0x00; //switch role to master
    
    HCI_Command(hcibuf, 10);
}
void BTD::hci_remote_name() {
    hci_event_flag &= ~HCI_FLAG_REMOTE_NAME_COMPLETE;
    hcibuf[0] = 0x19; // HCI OCF = 19
    hcibuf[1] = 0x01 << 2; // HCI OGF = 1
    hcibuf[2] = 0x0A; // parameter length = 10
    hcibuf[3] = disc_bdaddr[0]; // 6 octet bdaddr
    hcibuf[4] = disc_bdaddr[1];
    hcibuf[5] = disc_bdaddr[2];
    hcibuf[6] = disc_bdaddr[3];
    hcibuf[7] = disc_bdaddr[4];
    hcibuf[8] = disc_bdaddr[5];
    hcibuf[9] = 0x01; //Page Scan Repetition Mode
    hcibuf[10] = 0x00; //Reserved
    hcibuf[11] = 0x00; //Clock offset - low byte
    hcibuf[12] = 0x00; //Clock offset - high byte
    
    HCI_Command(hcibuf, 13);
}
void BTD::hci_set_local_name(const char* name) {
    hcibuf[0] = 0x13; // HCI OCF = 13
    hcibuf[1] = 0x03 << 2; // HCI OGF = 3
    hcibuf[2] = strlen(name)+1; // parameter length = the length of the string + end byte
    uint8_t i;
    for(i = 0; i < strlen(name); i++)
        hcibuf[i+3] = name[i];
    hcibuf[i+3] = 0x00; // End of string

    HCI_Command(hcibuf, 4+strlen(name));
}
void BTD::hci_inquiry() {
    hci_event_flag &= ~HCI_FLAG_WII_FOUND;
    hcibuf[0] = 0x01;
    hcibuf[1] = 0x01 << 2; // HCI OGF = 1
    hcibuf[2] = 0x05;  // Parameter Total Length = 5
    hcibuf[3] = 0x33;  // LAP: Genera/Unlimited Inquiry Access Code (GIAC = 0x9E8B33) - see https://www.bluetooth.org/Technical/AssignedNumbers/baseband.htm
    hcibuf[4] = 0x8B;
    hcibuf[5] = 0x9E;
    hcibuf[6] = 0x30;  // Inquiry time = 61.44 sec (maximum)
    hcibuf[7] = 0x0A;  // 10 number of responses
    
    HCI_Command(hcibuf, 8);
}
void BTD::hci_inquiry_cancel() {
    hcibuf[0] = 0x02;
    hcibuf[1] = 0x01 << 2; // HCI OGF = 1
    hcibuf[2] = 0x0;   // Parameter Total Length = 0
    
    HCI_Command(hcibuf, 3);
}
void BTD::hci_connect() {
    hci_event_flag &= ~(HCI_FLAG_CONN_COMPLETE | HCI_FLAG_CONNECT_EVENT);
    hcibuf[0] = 0x05;
    hcibuf[1] = 0x01 << 2; // HCI OGF = 1
    hcibuf[2] = 0x0D;  // parameter Total Length = 13
    hcibuf[3] = disc_bdaddr[0]; // 6 octet bdaddr
    hcibuf[4] = disc_bdaddr[1];
    hcibuf[5] = disc_bdaddr[2];
    hcibuf[6] = disc_bdaddr[3];
    hcibuf[7] = disc_bdaddr[4];
    hcibuf[8] = disc_bdaddr[5];
    hcibuf[9] = 0x18; // DM1 or DH1 may be used
    hcibuf[10] = 0xCC; // DM3, DH3, DM5, DH5 may be used
    hcibuf[11] = 0x01; // Page repetition mode R1
    hcibuf[12] = 0x00; // Reserved
    hcibuf[13] = 0x00; // Clock offset
    hcibuf[14] = 0x00; // Invalid clock offset
    hcibuf[15] = 0x00; // Do not allow role switch
    
    HCI_Command(hcibuf, 16);
}
void BTD::hci_pin_code_request_reply() {
    hcibuf[0] = 0x0D; // HCI OCF = 0D
    hcibuf[1] = 0x01 << 2; // HCI OGF = 1
    hcibuf[2] = 0x17; // parameter length 23
    hcibuf[3] = disc_bdaddr[0]; // 6 octet bdaddr
    hcibuf[4] = disc_bdaddr[1];
    hcibuf[5] = disc_bdaddr[2];
    hcibuf[6] = disc_bdaddr[3];
    hcibuf[7] = disc_bdaddr[4];
    hcibuf[8] = disc_bdaddr[5];    
    if(pairWithWii) {
        hcibuf[9] = 6; // Pin length is the length of the bt address
        hcibuf[10] = disc_bdaddr[0]; // The pin is the Wiimotes bt address backwards
        hcibuf[11] = disc_bdaddr[1];
        hcibuf[12] = disc_bdaddr[2];
        hcibuf[13] = disc_bdaddr[3];
        hcibuf[14] = disc_bdaddr[4];
        hcibuf[15] = disc_bdaddr[5];
        for(uint8_t i = 16; i < 26; i++)
            hcibuf[i] = 0x00; // The rest should be 0
    } else {
        hcibuf[9] = strlen(btdPin); // Length of pin
        uint8_t i;
        for(i = 0; i < strlen(btdPin); i++) // The maximum size of the pin is 16
            hcibuf[i+10] = btdPin[i];
        for(;i < 16; i++)
            hcibuf[i+10] = 0x00; // The rest should be 0
    }
    
    HCI_Command(hcibuf, 26);
}
void BTD::hci_pin_code_negative_request_reply() {
    hcibuf[0] = 0x0E; // HCI OCF = 0E
    hcibuf[1] = 0x01 << 2; // HCI OGF = 1
    hcibuf[2] = 0x06; // parameter length 6
    hcibuf[3] = disc_bdaddr[0]; // 6 octet bdaddr
    hcibuf[4] = disc_bdaddr[1];
    hcibuf[5] = disc_bdaddr[2];
    hcibuf[6] = disc_bdaddr[3];
    hcibuf[7] = disc_bdaddr[4];
    hcibuf[8] = disc_bdaddr[5];
    
    HCI_Command(hcibuf, 9);    
}
void BTD::hci_link_key_request_negative_reply() {
    hcibuf[0] = 0x0C; // HCI OCF = 0C
    hcibuf[1] = 0x01 << 2; // HCI OGF = 1
    hcibuf[2] = 0x06; // parameter length 6
    hcibuf[3] = disc_bdaddr[0]; // 6 octet bdaddr
    hcibuf[4] = disc_bdaddr[1];
    hcibuf[5] = disc_bdaddr[2];
    hcibuf[6] = disc_bdaddr[3];
    hcibuf[7] = disc_bdaddr[4];
    hcibuf[8] = disc_bdaddr[5];
    
    HCI_Command(hcibuf, 9);    
}
void BTD::hci_authentication_request() {
    hcibuf[0] = 0x11; // HCI OCF = 11
    hcibuf[1] = 0x01 << 2; // HCI OGF = 1
    hcibuf[2] = 0x02; // parameter length = 2
    hcibuf[3] = (uint8_t)(hci_handle & 0xFF);//connection handle - low byte
    hcibuf[4] = (uint8_t)((hci_handle >> 8) & 0x0F);//connection handle - high byte
    
    HCI_Command(hcibuf, 5);    
}
void BTD::hci_disconnect(uint16_t handle) { // This is called by the different services
    hci_event_flag &= ~HCI_FLAG_DISCONN_COMPLETE;
    hcibuf[0] = 0x06; // HCI OCF = 6
    hcibuf[1] = 0x01 << 2; // HCI OGF = 1
    hcibuf[2] = 0x03; // parameter length = 3
    hcibuf[3] = (uint8_t)(handle & 0xFF);//connection handle - low byte
    hcibuf[4] = (uint8_t)((handle >> 8) & 0x0F);//connection handle - high byte
    hcibuf[5] = 0x13; // reason
    
    HCI_Command(hcibuf, 6);
}
/*******************************************************************
 *                                                                 *
 *                        HCI ACL Data Packet                      *
 *                                                                 *
 *   buf[0]          buf[1]          buf[2]          buf[3]
 *   0       4       8    11 12      16              24            31 MSB
 *  .-+-+-+-+-+-+-+-|-+-+-+-|-+-|-+-|-+-+-+-+-+-+-+-|-+-+-+-+-+-+-+-.
 *  |      HCI Handle       |PB |BC |       Data Total Length       |   HCI ACL Data Packet
 *  .-+-+-+-+-+-+-+-|-+-+-+-|-+-|-+-|-+-+-+-+-+-+-+-|-+-+-+-+-+-+-+-.
 *
 *   buf[4]          buf[5]          buf[6]          buf[7]
 *   0               8               16                            31 MSB
 *  .-+-+-+-+-+-+-+-|-+-+-+-+-+-+-+-|-+-+-+-+-+-+-+-|-+-+-+-+-+-+-+-.
 *  |            Length             |          Channel ID           |   Basic L2CAP header
 *  .-+-+-+-+-+-+-+-|-+-+-+-+-+-+-+-|-+-+-+-+-+-+-+-|-+-+-+-+-+-+-+-.
 *
 *   buf[8]          buf[9]          buf[10]         buf[11]
 *   0               8               16                            31 MSB
 *  .-+-+-+-+-+-+-+-|-+-+-+-+-+-+-+-|-+-+-+-+-+-+-+-|-+-+-+-+-+-+-+-.
 *  |     Code      |  Identifier   |            Length             |   Control frame (C-frame)
 *  .-+-+-+-+-+-+-+-|-+-+-+-+-+-+-+-|-+-+-+-+-+-+-+-|-+-+-+-+-+-+-+-.   (signaling packet format)
 */
/************************************************************/
/*                    L2CAP Commands                        */
/************************************************************/
void BTD::L2CAP_Command(uint16_t handle, uint8_t* data, uint8_t nbytes, uint8_t channelLow, uint8_t channelHigh) {
    uint8_t buf[8+nbytes];
    buf[0] = (uint8_t)(handle & 0xff); // HCI handle with PB,BC flag
    buf[1] = (uint8_t)(((handle >> 8) & 0x0f) | 0x20);
    buf[2] = (uint8_t)((4 + nbytes) & 0xff); // HCI ACL total data length
    buf[3] = (uint8_t)((4 + nbytes) >> 8);
    buf[4] = (uint8_t)(nbytes & 0xff); // L2CAP header: Length
    buf[5] = (uint8_t)(nbytes >> 8);
    buf[6] = channelLow;
    buf[7] = channelHigh;
    
    for (uint16_t i = 0; i < nbytes; i++) // L2CAP C-frame
        buf[8 + i] = data[i];        
    
    uint8_t rcode = pUsb->outTransfer(bAddress, epInfo[ BTD_DATAOUT_PIPE ].epAddr, (8 + nbytes), buf);
    if(rcode) {
        delay(100); // This small delay prevents it from overflowing if it fails
#ifdef DEBUG
        Notify(PSTR("\r\nError sending L2CAP message: 0x"));
        PrintHex<uint8_t>(rcode);
        Notify(PSTR(" - Channel ID: "));
        //Serial.print(channelHigh);
        Notify(PSTR(" "));
        //Serial.print(channelLow);
#endif        
    }
}
void BTD::l2cap_connection_request(uint16_t handle, uint8_t rxid, uint8_t* scid, uint16_t psm) {
    l2capoutbuf[0] = L2CAP_CMD_CONNECTION_REQUEST;  // Code
    l2capoutbuf[1] = rxid; // Identifier
    l2capoutbuf[2] = 0x04; // Length
    l2capoutbuf[3] = 0x00;
    l2capoutbuf[4] = (uint8_t)(psm & 0xff); // PSM
    l2capoutbuf[5] = (uint8_t)(psm >> 8);
    l2capoutbuf[6] = scid[0]; // Source CID
    l2capoutbuf[7] = scid[1];
    
    L2CAP_Command(handle, l2capoutbuf, 8);
}
void BTD::l2cap_connection_response(uint16_t handle, uint8_t rxid, uint8_t* dcid, uint8_t* scid, uint8_t result) {            
    l2capoutbuf[0] = L2CAP_CMD_CONNECTION_RESPONSE; // Code
    l2capoutbuf[1] = rxid; // Identifier
    l2capoutbuf[2] = 0x08; // Length
    l2capoutbuf[3] = 0x00;
    l2capoutbuf[4] = dcid[0]; // Destination CID
    l2capoutbuf[5] = dcid[1];
    l2capoutbuf[6] = scid[0]; // Source CID
    l2capoutbuf[7] = scid[1];
    l2capoutbuf[8] = result; // Result: Pending or Success
    l2capoutbuf[9] = 0x00;
    l2capoutbuf[10] = 0x00; // No further information
    l2capoutbuf[11] = 0x00;
    
    L2CAP_Command(handle, l2capoutbuf, 12);
}        
void BTD::l2cap_config_request(uint16_t handle, uint8_t rxid, uint8_t* dcid) {
    l2capoutbuf[0] = L2CAP_CMD_CONFIG_REQUEST; // Code
    l2capoutbuf[1] = rxid; // Identifier
    l2capoutbuf[2] = 0x08; // Length
    l2capoutbuf[3] = 0x00;
    l2capoutbuf[4] = dcid[0]; // Destination CID
    l2capoutbuf[5] = dcid[1];
    l2capoutbuf[6] = 0x00; // Flags
    l2capoutbuf[7] = 0x00;
    l2capoutbuf[8] = 0x01; // Config Opt: type = MTU (Maximum Transmission Unit) - Hint
    l2capoutbuf[9] = 0x02; // Config Opt: length
    l2capoutbuf[10] = 0xFF; // MTU
    l2capoutbuf[11] = 0xFF;
    
    L2CAP_Command(handle, l2capoutbuf, 12);
}
void BTD::l2cap_config_response(uint16_t handle, uint8_t rxid, uint8_t* scid) {            
    l2capoutbuf[0] = L2CAP_CMD_CONFIG_RESPONSE; // Code
    l2capoutbuf[1] = rxid; // Identifier
    l2capoutbuf[2] = 0x0A; // Length
    l2capoutbuf[3] = 0x00;
    l2capoutbuf[4] = scid[0]; // Source CID
    l2capoutbuf[5] = scid[1];
    l2capoutbuf[6] = 0x00; // Flag
    l2capoutbuf[7] = 0x00;
    l2capoutbuf[8] = 0x00; // Result
    l2capoutbuf[9] = 0x00;    
    l2capoutbuf[10] = 0x01; // Config
    l2capoutbuf[11] = 0x02;
    l2capoutbuf[12] = 0xA0;
    l2capoutbuf[13] = 0x02;
    
    L2CAP_Command(handle, l2capoutbuf, 14);
}
void BTD::l2cap_disconnection_request(uint16_t handle, uint8_t rxid, uint8_t* dcid, uint8_t* scid) {
    l2capoutbuf[0] = L2CAP_CMD_DISCONNECT_REQUEST; // Code
    l2capoutbuf[1] = rxid; // Identifier
    l2capoutbuf[2] = 0x04; // Length
    l2capoutbuf[3] = 0x00;
    l2capoutbuf[4] = dcid[0];
    l2capoutbuf[5] = dcid[1];
    l2capoutbuf[6] = scid[0];
    l2capoutbuf[7] = scid[1];
    L2CAP_Command(handle, l2capoutbuf, 8);
}
void BTD::l2cap_disconnection_response(uint16_t handle, uint8_t rxid, uint8_t* dcid, uint8_t* scid) {
    l2capoutbuf[0] = L2CAP_CMD_DISCONNECT_RESPONSE; // Code
    l2capoutbuf[1] = rxid; // Identifier
    l2capoutbuf[2] = 0x04; // Length
    l2capoutbuf[3] = 0x00;
    l2capoutbuf[4] = dcid[0];
    l2capoutbuf[5] = dcid[1];
    l2capoutbuf[6] = scid[0];
    l2capoutbuf[7] = scid[1];
    L2CAP_Command(handle, l2capoutbuf, 8);
}
void BTD::l2cap_information_response(uint16_t handle, uint8_t rxid, uint8_t infoTypeLow, uint8_t infoTypeHigh) {
    l2capoutbuf[0] = L2CAP_CMD_INFORMATION_RESPONSE; // Code
    l2capoutbuf[1] = rxid; // Identifier
    l2capoutbuf[2] = 0x08; // Length
    l2capoutbuf[3] = 0x00;
    l2capoutbuf[4] = infoTypeLow;
    l2capoutbuf[5] = infoTypeHigh;
    l2capoutbuf[6] = 0x00; // Result = success
    l2capoutbuf[7] = 0x00; // Result = success
    l2capoutbuf[8] = 0x00;
    l2capoutbuf[9] = 0x00;
    l2capoutbuf[10] = 0x00;
    l2capoutbuf[11] = 0x00;
    L2CAP_Command(handle, l2capoutbuf, 12);
}

/* PS3 Commands - only set Bluetooth address is implemented */
void BTD::setBdaddr(uint8_t* BDADDR) {
    /* Set the internal bluetooth address */
    uint8_t buf[8];
    buf[0] = 0x01;
    buf[1] = 0x00;
    for (uint8_t i = 0; i < 6; i++)
        buf[i+2] = BDADDR[5 - i];//Copy into buffer, has to be written reversed
    
    //bmRequest = Host to device (0x00) | Class (0x20) | Interface (0x01) = 0x21, bRequest = Set Report (0x09), Report ID (0xF5), Report Type (Feature 0x03), interface (0x00), datalength, datalength, data)
    pUsb->ctrlReq(bAddress,epInfo[BTD_CONTROL_PIPE].epAddr, bmREQ_HID_OUT, HID_REQUEST_SET_REPORT, 0xF5, 0x03, 0x00, 8, 8, buf, NULL);
#ifdef DEBUG
    Notify(PSTR("\r\nBluetooth Address was set to: "));
    for(int8_t i = 5; i > 0; i--) {
        PrintHex<uint8_t>(my_bdaddr[i]);
        Notify(PSTR(":"));
    }
    PrintHex<uint8_t>(my_bdaddr[0]);
#endif
}
void BTD::setMoveBdaddr(uint8_t* BDADDR) {
	/* Set the internal bluetooth address */
    uint8_t buf[11];
    buf[0] = 0x05;
    buf[7] = 0x10;
    buf[8] = 0x01;
    buf[9] = 0x02;
    buf[10] = 0x12;
    
    for (uint8_t i = 0; i < 6; i++)
        buf[i + 1] = BDADDR[i];
    
    //bmRequest = Host to device (0x00) | Class (0x20) | Interface (0x01) = 0x21, bRequest = Set Report (0x09), Report ID (0x05), Report Type (Feature 0x03), interface (0x00), datalength, datalength, data)
    pUsb->ctrlReq(bAddress,epInfo[BTD_CONTROL_PIPE].epAddr, bmREQ_HID_OUT, HID_REQUEST_SET_REPORT, 0x05, 0x03, 0x00,11,11, buf, NULL);
#ifdef DEBUG
    Notify(PSTR("\r\nBluetooth Address was set to: "));
    for(int8_t i = 5; i > 0; i--) {
        PrintHex<uint8_t>(my_bdaddr[i]);
        Notify(PSTR(":"));
    }
    PrintHex<uint8_t>(my_bdaddr[0]);
#endif
}