/******************************************************************************
* @fn StubAPS_SetIntraPanChannel
*
* @brief This function sets the device's channel back to the NIB channel.
*
* @param none
*
* @return ZStatus_t
*/
ZStatus_t StubAPS_SetIntraPanChannel( void )
{
uint8 currChannel;
uint8 rxOnIdle;
if ( channelChangeInProgress )
return ( ZFailure );
ZMacGetReq( ZMacChannel, &currChannel );
if ( currChannel == _NIB.nwkLogicalChannel )
return ( ZSuccess );
channelChangeInProgress = TRUE;
// turn MAC receiver off
rxOnIdle = false;
ZMacSetReq( ZMacRxOnIdle, &rxOnIdle );
// set the NIB channel
ZMacSetReq( ZMacChannel, &(_NIB.nwkLogicalChannel) );
// turn MAC receiver back on
rxOnIdle = true;
ZMacSetReq( ZMacRxOnIdle, &rxOnIdle );
// set NWK task to run
nwk_setStateIdle( FALSE );
channelChangeInProgress = FALSE;
return ( ZSuccess );
} /* StubAPS_SetIntraPanChannel */
/**************************************************************************************************
* @fn MT_SysStackTune
*
* @brief ZAccel RPC interface for tuning the stack parameters to adjust performance
*
* @param uint8 pData - Pointer to the data.
*
* @return None
*************************************************************************************************/
void MT_SysStackTune(uint8 *pBuf)
{
uint8 cmd, rtrn;
cmd = pBuf[MT_RPC_POS_CMD1];
pBuf += MT_RPC_FRAME_HDR_SZ;
switch (*pBuf++)
{
case STK_TX_PWR:
rtrn = ZMacSetReq(ZMacPhyTransmitPowerSigned, pBuf);
break;
case STK_RX_ON_IDLE:
if ((*pBuf != TRUE) && (*pBuf != FALSE))
{
(void)ZMacGetReq(ZMacRxOnIdle, &rtrn);
}
else
{
rtrn = ZMacSetReq(ZMacRxOnIdle, pBuf);
}
break;
default:
rtrn = ZInvalidParameter;
break;
}
MT_BuildAndSendZToolResponse(((uint8)MT_RPC_CMD_SRSP | (uint8)MT_RPC_SYS_SYS), cmd, 1, &rtrn);
}
/****************************************************************************
* @fn ZDiagsRestoreStatsFromNV
*
* @brief Restores the statistics table from NV into the RAM table.
*
* @param none.
*
* @return ZSuccess - if NV data was restored from NV.
* ZFailure - Otherwise, NV_OPER_FAILED for failure.
*/
uint8 ZDiagsRestoreStatsFromNV( void )
{
uint8 retValue = ZFailure;
#if defined ( FEATURE_SYSTEM_STATS )
// restore diagnostics table from NV into RAM table
if ( osal_nv_read( ZCD_NV_DIAGNOSTIC_STATS, 0,
(uint16)sizeof( DiagStatistics_t ),
&DiagsStatsTable ) == SUCCESS )
{
// restore MAC values into the PIB
ZMacSetReq( ZMacDiagsRxCrcPass, (uint8 *)&(DiagsStatsTable.MacRxCrcPass) );
ZMacSetReq( ZMacDiagsRxCrcFail, (uint8 *)&(DiagsStatsTable.MacRxCrcFail) );
ZMacSetReq( ZMacDiagsRxBcast, (uint8 *)&(DiagsStatsTable.MacRxBcast) );
ZMacSetReq( ZMacDiagsTxBcast, (uint8 *)&(DiagsStatsTable.MacTxBcast) );
ZMacSetReq( ZMacDiagsRxUcast, (uint8 *)&(DiagsStatsTable.MacRxUcast) );
ZMacSetReq( ZMacDiagsTxUcast, (uint8 *)&(DiagsStatsTable.MacTxUcast) );
ZMacSetReq( ZMacDiagsTxUcastRetry, (uint8 *)&(DiagsStatsTable.MacTxUcastRetry) );
ZMacSetReq( ZMacDiagsTxUcastFail, (uint8 *)&(DiagsStatsTable.MacTxUcastFail) );
retValue = ZSuccess;
}
#endif // FEATURE_SYSTEM_STATS
return ( retValue );
}
/*********************************************************************
* @fn OTA_Dongle_Init
*
* @brief Initialization function for the zclGeneral layer.
*
* @param none
*
* @return none
*/
void OTA_Dongle_Init( byte task_id )
{
OTA_Dongle_TaskID = task_id;
uint8 RxOnIdle = TRUE;
OTA_Dongle_SeqNo = 0;
ZMacSetReq( ZMacRxOnIdle, &RxOnIdle );
// Register the ZCL General Cluster Library callback functions
zclGeneral_RegisterCmdCallbacks( OTA_DONGLE_ENDPOINT, &OTA_Dongle_CmdCallbacks );
// Register the application's attribute list
zcl_registerAttrList( OTA_DONGLE_ENDPOINT, OTA_DONGLE_MAX_ATTRIBUTES, OTA_Dongle_Attrs );
// Register the application's cluster option list
zcl_registerClusterOptionList( OTA_DONGLE_ENDPOINT, OTA_DONGLE_MAX_OPTIONS, OTA_Dongle_Options );
// Register the Application to receive the unprocessed Foundation command/response messages
zcl_registerForMsg( OTA_Dongle_TaskID );
// Register for all key events - This app will handle all key events
RegisterForKeys( OTA_Dongle_TaskID );
// Register endpoints
afRegister( &ota_DongleEp );
afRegister( &ota_SysAppEp );
// Register with the ZDO to receive Match Descriptor Responses
ZDO_RegisterForZDOMsg(task_id, Match_Desc_rsp);
ZDO_RegisterForZDOMsg(task_id, Device_annce);
// Start a timer to notify the console about the dongle
osal_start_timerEx( OTA_Dongle_TaskID, OTA_DONGLE_DONGLE_NOTIFY_EVT, 4000 );
}
/*********************************************************************
* @fn StubAPS_ProcessEvent()
*
* @brief Main event loop for Stub APS task. This function should be called
* at periodic intervals when event occur.
*
* @param task_id - Task ID
* @param events - Bitmap of events
*
* @return none
*/
UINT16 StubAPS_ProcessEvent( uint8 task_id, uint16 events )
{
(void)task_id; // Intentionally unreferenced parameter
if ( events & SYS_EVENT_MSG )
{
osal_event_hdr_t *msg_ptr;
while ( (msg_ptr = (osal_event_hdr_t *)osal_msg_receive( StubAPS_TaskID )) != NULL )
{
if ( msg_ptr->event == MAC_MCPS_DATA_CNF )
{
INTERP_DataConfirm( (ZMacDataCnf_t *)msg_ptr );
}
else if ( msg_ptr->event == MAC_MCPS_DATA_IND )
{
INTERP_DataIndication( (macMcpsDataInd_t *)msg_ptr );
}
osal_msg_deallocate( (uint8 *)msg_ptr );
}
// Return unproccessed events
return ( events ^ SYS_EVENT_MSG );
}
if ( events & CHANNEL_CHANGE_EVT )
{
// try to change to the new channel
ZStatus_t status = StubAPS_SetNewChannel( newChannel );
if ( status != ZSuccess )
{
// turn MAC receiver back on
uint8 rxOnIdle = true;
ZMacSetReq( ZMacRxOnIdle, &rxOnIdle );
// set NWK task to run
nwk_setStateIdle( FALSE );
channelChangeInProgress = FALSE;
}
// notify the application
StubAPS_NotifyApp( status );
return ( events ^ CHANNEL_CHANGE_EVT );
}
// If reach here, the events are unknown
// Discard or make more handlers
return 0;
} /* StubAPS_ProcessEvent() */
/******************************************************************************
* @fn StubAPS_setNewChannel
*
* @brief This function changes the device's channel.
*
* @param none
*
* @return ZStatus_t
*/
static ZStatus_t StubAPS_SetNewChannel( uint8 channel )
{
uint8 rxOnIdle;
// make sure MAC has nothing to transmit
if ( ( nwkDB_CountTypes( NWK_DATABUF_SENT ) == 0 ) && ZMacStateIdle() )
{
// set the new channel
ZMacSetReq( ZMacChannel, &channel );
// turn MAC receiver back on
rxOnIdle = true;
ZMacSetReq( ZMacRxOnIdle, &rxOnIdle );
channelChangeInProgress = FALSE;
return ( ZSuccess );
}
return ( ZFailure );
} /* StubAPS_setNewChannel */
/*********************************************************************
* @fn zclSampleSw_ProcessOTAMsgs
*
* @brief Called to process callbacks from the ZCL OTA.
*
* @param none
*
* @return none
*/
static void zclSampleSw_ProcessOTAMsgs( zclOTA_CallbackMsg_t* pMsg )
{
uint8 RxOnIdle;
switch(pMsg->ota_event)
{
case ZCL_OTA_START_CALLBACK:
if (pMsg->hdr.status == ZSuccess)
{
// Speed up the poll rate
RxOnIdle = TRUE;
ZMacSetReq( ZMacRxOnIdle, &RxOnIdle );
NLME_SetPollRate( 2000 );
}
break;
case ZCL_OTA_DL_COMPLETE_CALLBACK:
if (pMsg->hdr.status == ZSuccess)
{
// Reset the CRC Shadow and reboot. The bootloader will see the
// CRC shadow has been cleared and switch to the new image
HalOTAInvRC();
SystemReset();
}
else
{
// slow the poll rate back down.
RxOnIdle = FALSE;
ZMacSetReq( ZMacRxOnIdle, &RxOnIdle );
NLME_SetPollRate(DEVICE_POLL_RATE);
}
break;
default:
break;
}
}
/*********************************************************************
* @fn ipd_PublishPriceCB
*
* @brief Callback from the ZCL SE Profile Pricing Cluster Library when
* it received a Publish Price for this application.
*
* @param pCmd - pointer to structure for Publish Price command
* @param srcAddr - source address
* @param seqNum - sequence number for this command
*
* @return none
*/
static void ipd_PublishPriceCB( zclCCPublishPrice_t *pCmd,
afAddrType_t *srcAddr, uint8 seqNum )
{
if ( pCmd )
{
// display Provider ID field
HalLcdWriteString("Provider ID", HAL_LCD_LINE_1);
HalLcdWriteValue( pCmd->providerId, 10, HAL_LCD_LINE_2 );
}
#if defined ( INTER_PAN )
ZMacSetReq( ZMacRxOnIdle, &rxOnIdle ); // set receiver on when idle flag to false
// after getting publish price command via INTER-PAN
#endif
}
void set_panid( uint16 u16NewPanid)
{
uint8 u8BackCode;
_NIB.nwkPanId = u16NewPanid;
macRadioSetPanID ( _NIB.nwkPanId);
ZMacSetReq( ZMacPanId, (byte *)& _NIB.nwkPanId);
u8BackCode = osal_nv_write(ZCD_NV_PANID, 0, 2, &u16NewPanid);
if( u8BackCode == ZSUCCESS)
{
NLME_UpdateNV(0x01);
// HAL_SYSTEM_RESET();
}
else
{
uprint("set_panid failed");
}
}
/***************************************************************************************************
* @fn MT_SysSetExtAddr
*
* @brief Set the Extended Address
*
* @param pBuf
*
* @return None
***************************************************************************************************/
void MT_SysSetExtAddr(uint8 *pBuf)
{
uint8 retValue = ZFailure;
uint8 cmdId;
/* parse header */
cmdId = pBuf[MT_RPC_POS_CMD1];
pBuf += MT_RPC_FRAME_HDR_SZ;
if ( ZMacSetReq(ZMacExtAddr, pBuf) == ZMacSuccess )
{
// CC253X MAC Network Processor does not have NV support
#if !defined(CC253X_MACNP)
retValue = osal_nv_write(ZCD_NV_EXTADDR, 0, Z_EXTADDR_LEN, pBuf);
#endif
}
/* Build and send back the response */
MT_BuildAndSendZToolResponse(((uint8)MT_RPC_CMD_SRSP | (uint8)MT_RPC_SYS_SYS), cmdId, 1, &retValue);
}
/***************************************************************************************************
* @fn MT_SysOsalNVWrite
*
* @brief
*
* @param uint8 pData - pointer to the data
*
* @return None
***************************************************************************************************/
void MT_SysOsalNVWrite(uint8 *pBuf)
{
uint16 nvId;
uint8 nvItemLen=0, nvItemOffset=0;
uint8 rtrn;
/* Skip over RPC header */
pBuf += MT_RPC_FRAME_HDR_SZ;
/* Get the ID */
nvId = BUILD_UINT16(pBuf[0], pBuf[1]);
/* Get the offset */
nvItemOffset = pBuf[2];
/* Get the length */
nvItemLen = pBuf[3];
pBuf += 4;
/* Default to ZFailure */
rtrn = ZFailure;
/* Set the Z-Globals value of this NV item. */
zgSetItem( nvId, (uint16)nvItemLen, pBuf );
if ((osal_nv_write(nvId, (uint16)nvItemOffset, (uint16)nvItemLen, pBuf)) == ZSUCCESS)
{
if (nvId == ZCD_NV_EXTADDR)
{
rtrn = ZMacSetReq(ZMacExtAddr, pBuf);
}
else
{
rtrn = ZSuccess;
}
}
/* Build and send back the response */
MT_BuildAndSendZToolResponse(((uint8)MT_RPC_CMD_SRSP | (uint8)MT_RPC_SYS_SYS),
MT_SYS_OSAL_NV_WRITE, 1, &rtrn);
}
/******************************************************************************
* @fn StubAPS_SetInterPanChannel
*
* @brief This function changes the device's channel for inter-PAN communication.
*
* @param channel - new channel
*
* @return ZStatus_t
*/
ZStatus_t StubAPS_SetInterPanChannel( uint8 channel )
{
uint8 currChannel;
uint8 rxOnIdle;
if ( channelChangeInProgress )
return ( ZFailure );
ZMacGetReq( ZMacChannel, &currChannel );
if ( currChannel == channel )
{
// inter PANs communication within the same channel
return ( ZSuccess );
}
// go into channel transition state
channelChangeInProgress = TRUE;
// set NWK task to idle
nwk_setStateIdle( TRUE );
// turn MAC receiver off
rxOnIdle = false;
ZMacSetReq( ZMacRxOnIdle, &rxOnIdle );
// try to change to the new channel
if ( StubAPS_SetNewChannel( channel ) == ZSuccess )
return ( ZSuccess );
// save the new channel for retry
newChannel = channel;
// ask StubAPS task to retry it later
osal_start_timerEx( StubAPS_TaskID, CHANNEL_CHANGE_EVT, CHANNEL_CHANGE_RETRY_TIMEOUT );
return ( ZApsNotAllowed );
} /* StubAPS_SetInterPanChannel */
void Serial_callBack(uint8 port, uint8 event)
{
char theMessageData[] = "Hello";
zAddrType_t dstAddr;
zAddrType_t ZAddr;
afAddrType_t myaddr; // use for p2p
char pbuf[3];
char pbuf1[3];
uint16 cmd;
uint8 buff[128];
uint8 readBytes = 0;
uint16 short_ddr;
uint16 panid;
uint8 *ieeeAddr;
uint16 *p1;
byte cnt = 0;
uint8 yy1;
uint8 yy2;
uint8 i;
byte nr;
uint16 devlist[ NWK_MAX_DEVICES + 1];
associated_devices_t *adp; // delete devices
//short_ddr = GenericApp_DstAddr.addr.shortAddr;
uint8 startOptions;
uint8 logicalType;
logicalType = (uint8)ZDO_Config_Node_Descriptor.LogicalType;
readBytes = HalUARTRead(SER_PORT, buff, 127);
if (readBytes > 0)
{
//HalUARTWrite( SER_PORT, "DataRead: ",10);
// HalUARTWrite( SER_PORT, buff, readBytes);
if(readBytes == 4)
{
if(buff[0] == 'p' && buff[1] == 'i' && buff[2]=='n' && buff[3] == 'g')
{
UART_Send_String( "pong", 4 );
}
}
if( readBytes == 1)
{
yy1 = 1;
if(buff[0]== 's')
{
/// short address
short_ddr = _NIB.nwkDevAddress;
UART_Send_String( (uint8*)&short_ddr, 2);
}
if(buff[0] == 'p')
{
/// pan id
panid = _NIB.nwkPanId;
UART_Send_String( (uint8*)&panid, 2);
}
if(buff[0] == 'c')/// channel
{
yy2 = _NIB.nwkLogicalChannel;
UART_Send_String( (uint8*)&yy2, 1);
}
if(buff[0] =='m') // mac address
{
ieeeAddr = NLME_GetExtAddr();
UART_Send_String( ieeeAddr, 8);
}
if( buff[0] ==0xc0) // coordinator
{
set_coordi();
return;
}
if( buff[0] ==0xe0) // router
{
set_router();
return;
}
if(buff[0] == 0xCA)
{
// 使命的招唤
// read self AssociatedDevList
for(i=0;i< NWK_MAX_DEVICES; i++)
{
nr = AssociatedDevList[ i ].nodeRelation;
if(nr > 0 && nr < 5) //CHILD_RFD CHILD_RFD_RX_IDLE CHILD_FFD CHILD_FFD_RX_IDLE
//if( nr != 0XFF)
{
// myaddr.addrMode = (afAddrMode_t)Addr16Bit;
// myaddr.endPoint = GENERICAPP_ENDPOINT;
// if( AssociatedDevList[ i ].shortAddr != 0x0000)
// {
//if( AssocIsChild( AssociatedDevList[ i ].shortAddr ) != 1 || AssociatedDevList[ i ].age > NWK_ROUTE_AGE_LIMIT)
//if( AssocIsChild( AssociatedDevList[ i ].shortAddr ) == 1 && AssociatedDevList[ i ].age > NWK_ROUTE_AGE_LIMIT )
// {
// myaddr.addr.shortAddr = AssociatedDevList[ i ].shortAddr;
/*
if ( AF_DataRequest( &myaddr, &GenericApp_epDesc, GENERICAPP_CLUSTERID,(byte)osal_strlen( theMessageData ) + 1,
(byte *)&theMessageData,
&GenericApp_TransID,
AF_ACK_REQUEST, AF_DEFAULT_RADIUS ) != afStatus_SUCCESS )
{
uprint("delete asso");
*/
// delete_asso( AssociatedDevList[ i ]. addrIdx);
// }
// else
// {
devlist[yy1] = AssociatedDevList[ i ].shortAddr;
yy1++;
// }
// }
}//else {break;}
}
devlist[0] = BUILD_UINT16(0xce, AssocCount(1, 4) );
UART_Send_String( (uint8*)&devlist[0], yy1*2);
//p1 = AssocMakeList( &cnt );
//UART_Send_String( (uint8*)p1, AssocCount(1, 4)*2);
//osal_mem_free(p1);
return;
}
}
#if defined( ZDO_COORDINATOR )
// only coordinator can have this function
if(readBytes == 3)
{
if( buff[0] == 0xCA || buff[0] == 0x6d)
{
// CA xx xx ,send CA to a node ,with it's short address
///uprint("it's CA ");
short_ddr = BUILD_UINT16( buff[1], buff[2] );
myaddr.addrMode = (afAddrMode_t)Addr16Bit;
myaddr.endPoint = GENERICAPP_ENDPOINT;
myaddr.addr.shortAddr = short_ddr;
if ( AF_DataRequest( &myaddr, &GenericApp_epDesc, GENERICAPP_CLUSTERID, 1,
(byte *)&buff,
&GenericApp_TransID,
AF_DISCV_ROUTE, AF_DEFAULT_RADIUS ) != afStatus_SUCCESS )
{
AF_DataRequest( &myaddr, &GenericApp_epDesc, GENERICAPP_CLUSTERID, 1,
(byte *)&buff,
&GenericApp_TransID,
AF_DISCV_ROUTE, AF_DEFAULT_RADIUS );
// send twice only, if it is still not ok, f**k it
}
return;
}
}
#endif
if( readBytes >= 2)
{
if( buff[0] == 'e' && buff[1] == '#')
{
uprint("EndDevice match");
HalLedSet ( HAL_LED_1, HAL_LED_MODE_OFF );
dstAddr.addrMode = Addr16Bit;
dstAddr.addr.shortAddr = 0x0000; // Coordinator
ZDP_EndDeviceBindReq( &dstAddr, NLME_GetShortAddr(), GenericApp_epDesc.endPoint,
GENERICAPP_PROFID,
GENERICAPP_MAX_CLUSTERS, (cId_t *)GenericApp_ClusterList,
GENERICAPP_MAX_CLUSTERS, (cId_t *)GenericApp_ClusterList,
FALSE );
}
if( buff[0] == 'r' && buff[1] == '#')
{
uprint("Router Device match");
HalLedSet ( HAL_LED_1, HAL_LED_MODE_FLASH );
dstAddr.addrMode = AddrBroadcast;
dstAddr.addr.shortAddr = NWK_BROADCAST_SHORTADDR;
ZDP_MatchDescReq( &dstAddr, NWK_BROADCAST_SHORTADDR,
GENERICAPP_PROFID,
GENERICAPP_MAX_CLUSTERS, (cId_t *)GenericApp_ClusterList,
GENERICAPP_MAX_CLUSTERS, (cId_t *)GenericApp_ClusterList,
FALSE );
}
if(readBytes == 6)
{
if(buff[0] == 'p' && buff[1]==':') // pan id
{
strncpy(pbuf, &buff[2],2); pbuf[2] = '\0';
strncpy(pbuf1, &buff[4],2); pbuf1[2] = '\0';
set_panid( BUILD_UINT16( strtol(pbuf1,NULL,16),strtol(pbuf,NULL,16) ));
if(_NIB.nwkPanId == 0xffff)
{
zgWriteStartupOptions (ZG_STARTUP_SET, ZCD_STARTOPT_DEFAULT_NETWORK_STATE);
SystemReset();
}
//SystemResetSoft();
}
if(buff[0] == 's' && buff[1]==':') // short address
{
/*
strncpy(pbuf, &buff[2],2); pbuf[2] = '\0';
strncpy(pbuf1, &buff[4],2); pbuf1[2] = '\0';
_NIB.nwkDevAddress = BUILD_UINT16( strtol(pbuf1,NULL,16),strtol(pbuf,NULL,16));
*/
}
}
cmd = BUILD_UINT16(buff[ 1 + 1], buff[1]);
if( ( buff[ 0 ] == CPT_SOP) && (cmd == SYS_PING_REQUEST) )
{
sysPingReqRcvd();
return;
}
if( readBytes == 2)
{
if( buff[0] == 0xcc )
{
if( buff[1] > 0x0a && buff[1] < 0x1b )
{
_NIB.nwkLogicalChannel = buff[1];
NLME_UpdateNV(0x01);
ZMacSetReq( ZMacChannel, &buff[1]);
osal_nv_item_init( ZCD_NV_CHANLIST, sizeof(zgDefaultChannelList), &zgDefaultChannelList);
if( buff[1] == 0x0b)
{
zgDefaultChannelList = 0x00000800;
}
if (buff[1] == 0x0c )
{
zgDefaultChannelList = 0x00001000;
}
if (buff[1] == 0x0d )
{
zgDefaultChannelList = 0x00002000;
}
if (buff[1] == 0x0e )
{
zgDefaultChannelList = 0x00004000;
}
if (buff[1] == 0x0f )
{
zgDefaultChannelList = 0x00008000;
}
if (buff[1] == 0x10 )
{
zgDefaultChannelList = 0x00010000;
}
if (buff[1] == 0x11 )
{
zgDefaultChannelList = 0x00020000;
}
if (buff[1] == 0x12 )
{
zgDefaultChannelList = 0x00040000;
}
if (buff[1] == 0x13 )
{
zgDefaultChannelList = 0x00080000;
}
if (buff[1] == 0x14 )
{
zgDefaultChannelList = 0x00100000;
}
if (buff[1] == 0x15 )
{
zgDefaultChannelList = 0x00200000;
}
if (buff[1] == 0x16 )
{
zgDefaultChannelList = 0x00400000;
}
if (buff[1] == 0x17 )
{
zgDefaultChannelList = 0x00800000;
}
if (buff[1] == 0x18 )
{
zgDefaultChannelList = 0x01000000;
}
if (buff[1] == 0x19 )
{
zgDefaultChannelList = 0x02000000;
}
if (buff[1] == 0x1a )
{
zgDefaultChannelList = 0x04000000;
}
osal_nv_write( ZCD_NV_CHANLIST, 0 ,sizeof(zgDefaultChannelList), &zgDefaultChannelList);
UART_Send_String( (uint8*)&zgDefaultChannelList, sizeof(zgDefaultChannelList) );
/*
_NIB.nwkLogicalChannel = buff[1];
NLME_UpdateNV(0x01);
if( osal_nv_write(ZCD_NV_CHANLIST, 0, osal_nv_item_len( ZCD_NV_CHANLIST ), &tmp32) != ZSUCCESS)
{
uprint("change channel to nv failed");
}
*/
/*
_NIB.nwkLogicalChannel = buff[1];
ZMacSetReq( ZMacChannel, &buff[1]);
ZDApp_NwkStateUpdateCB();
_NIB.nwkTotalTransmissions = 0;
nwkTransmissionFailures( TRUE );
*/
}
}
}// readBytes==2
ser_process( buff,readBytes );// 中讯威易的协议最小也是2 字节
}//if( readBytes >= 2)
AF_DataRequest( &GenericApp_DstAddr, &GenericApp_epDesc,
GENERICAPP_CLUSTERID,
readBytes,
(byte *)&buff,
&GenericApp_TransID,
AF_DISCV_ROUTE, AF_DEFAULT_RADIUS );
} //if (readBytes > 0)
}
/*********************************************************************
* @fn ipd_HandleKeys
*
* @brief Handles all key events for this device.
*
* @param shift - true if in shift/alt.
* @param keys - bit field for key events. Valid entries:
* HAL_KEY_SW_4
* HAL_KEY_SW_3
* HAL_KEY_SW_2
* HAL_KEY_SW_1
*
* @return none
*/
static void ipd_HandleKeys( uint8 shift, uint8 keys )
{
// Shift is used to make each button/switch dual purpose.
if ( shift )
{
if ( keys & HAL_KEY_SW_1 )
{
}
if ( keys & HAL_KEY_SW_2 )
{
}
if ( keys & HAL_KEY_SW_3 )
{
}
if ( keys & HAL_KEY_SW_4 )
{
}
}
else
{
if ( keys & HAL_KEY_SW_1 )
{
ZDOInitDevice(0); // join the network
}
if ( keys & HAL_KEY_SW_2 )
{
#if defined( INTER_PAN )
uint8 x = true;
ZMacGetReq( ZMacRxOnIdle, &rxOnIdle );
ZMacSetReq( ZMacRxOnIdle, &x );
afAddrType_t dstAddr;
uint8 option = 1;
// Send a request for public pricing information using the INTERP-DATA SAP.
// The request is sent as a broadcast to all PANs within the discovered
// channel. Receiving devices that implement the INTRP-DATA SAP will process
// it and, if any such device is able to respond, it will respond directly
// to the requestor. After receiving at least one response the requestor may
// store the PAN ID and device address of one or more responders so that it
// may query them directly in future.
dstAddr.addrMode = afAddrBroadcast;
dstAddr.addr.shortAddr = NWK_BROADCAST_SHORTADDR_DEVALL;
dstAddr.endPoint = STUBAPS_INTER_PAN_EP;
dstAddr.panId = 0xFFFF;
zclSE_Pricing_Send_GetCurrentPrice( IPD_ENDPOINT, &dstAddr, option, TRUE, 0 );
#endif
}
if ( keys & HAL_KEY_SW_3 )
{
}
if ( keys & HAL_KEY_SW_4 )
{
}
}
}
