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/**************************************************************************************************
Filename: ZDProfile.c
Revised: $Date: 2010-10-13 10:54:13 -0700 (Wed, 13 Oct 2010) $
Revision: $Revision: 24112 $
Description: This is the Zigbee Device Profile.
Copyright 2004-2010 Texas Instruments Incorporated. All rights reserved.
IMPORTANT: Your use of this Software is limited to those specific rights
granted under the terms of a software license agreement between the user
who downloaded the software, his/her employer (which must be your employer)
and Texas Instruments Incorporated (the "License"). You may not use this
Software unless you agree to abide by the terms of the License. The License
limits your use, and you acknowledge, that the Software may not be modified,
copied or distributed unless embedded on a Texas Instruments microcontroller
or used solely and exclusively in conjunction with a Texas Instruments radio
frequency transceiver, which is integrated into your product. Other than for
the foregoing purpose, you may not use, reproduce, copy, prepare derivative
works of, modify, distribute, perform, display or sell this Software and/or
its documentation for any purpose.
YOU FURTHER ACKNOWLEDGE AND AGREE THAT THE SOFTWARE AND DOCUMENTATION ARE
PROVIDED “AS IS” WITHOUT WARRANTY OF ANY KIND, EITHER EXPRESS OR IMPLIED,
INCLUDING WITHOUT LIMITATION, ANY WARRANTY OF MERCHANTABILITY, TITLE,
NON-INFRINGEMENT AND FITNESS FOR A PARTICULAR PURPOSE. IN NO EVENT SHALL
TEXAS INSTRUMENTS OR ITS LICENSORS BE LIABLE OR OBLIGATED UNDER CONTRACT,
NEGLIGENCE, STRICT LIABILITY, CONTRIBUTION, BREACH OF WARRANTY, OR OTHER
LEGAL EQUITABLE THEORY ANY DIRECT OR INDIRECT DAMAGES OR EXPENSES
INCLUDING BUT NOT LIMITED TO ANY INCIDENTAL, SPECIAL, INDIRECT, PUNITIVE
OR CONSEQUENTIAL DAMAGES, LOST PROFITS OR LOST DATA, COST OF PROCUREMENT
OF SUBSTITUTE GOODS, TECHNOLOGY, SERVICES, OR ANY CLAIMS BY THIRD PARTIES
(INCLUDING BUT NOT LIMITED TO ANY DEFENSE THEREOF), OR OTHER SIMILAR COSTS.
Should you have any questions regarding your right to use this Software,
contact Texas Instruments Incorporated at www.TI.com.
**************************************************************************************************/
/*********************************************************************
* INCLUDES
*/
#include "ZComdef.h"
#include "OSAL.h"
#include "AF.h"
#include "NLMEDE.h"
#include "nwk_util.h"
#include "APS.h"
#include "AddrMgr.h"
#include "ZDConfig.h"
#include "ZDProfile.h"
#include "ZDObject.h"
#include "ZDNwkMgr.h"
#if defined( LCD_SUPPORTED )
#include "OnBoard.h"
#endif
#include "nwk_util.h"
#if defined( MT_ZDO_FUNC )
#include "MT_ZDO.h"
#endif
/*********************************************************************
* MACROS
*/
#define ZADDR_TO_AFADDR( pZADDR, AFADDR ) { \
(AFADDR).endPoint = ZDP_AF_ENDPOINT; \
(AFADDR).addrMode = (afAddrMode_t)(pZADDR)->addrMode; \
(AFADDR).addr.shortAddr = (pZADDR)->addr.shortAddr; \
}
#define FillAndSendBuffer( TRANSSEQ, ADDR, ID, LEN, BUF ) { \
afStatus_t stat; \
ZDP_TmpBuf = (BUF)+1; \
stat = fillAndSend( (TRANSSEQ), (ADDR), (ID), (LEN) ); \
osal_mem_free( (BUF) ); \
ZDP_TmpBuf = ZDP_Buf+1; \
return stat; \
}
#define FillAndSendTxOptions( TRANSSEQ, ADDR, ID, LEN, TxO ) { \
afStatus_t stat; \
ZDP_TxOptions = (TxO); \
stat = fillAndSend( (TRANSSEQ), (ADDR), (ID), (LEN) ); \
ZDP_TxOptions = AF_TX_OPTIONS_NONE; \
return stat; \
}
#define FillAndSendBufferTxOptions( TRANSSEQ, ADDR, ID, LEN, BUF, TxO ) { \
afStatus_t stat; \
ZDP_TmpBuf = (BUF)+1; \
ZDP_TxOptions = (TxO); \
stat = fillAndSend( (TRANSSEQ), (ADDR), (ID), (LEN) ); \
osal_mem_free( (BUF) ); \
ZDP_TmpBuf = ZDP_Buf+1; \
ZDP_TxOptions = AF_TX_OPTIONS_NONE; \
return stat; \
}
/*********************************************************************
* CONSTANTS
*/
#define ZDP_BUF_SZ 80
CONST byte ZDP_AF_ENDPOINT = 0;
/*********************************************************************
* TYPEDEFS
*/
typedef struct
{
void *next;
uint8 taskID;
uint16 clusterID;
} ZDO_MsgCB_t;
/*********************************************************************
* GLOBAL VARIABLES
*/
byte ZDP_TransID = 0;
/*********************************************************************
* EXTERNAL VARIABLES
*/
extern endPointDesc_t ZDApp_epDesc;
/*********************************************************************
* EXTERNAL FUNCTIONS
*/
/*********************************************************************
* LOCAL FUNCTIONS
*/
static afStatus_t fillAndSend( uint8 *transSeq, zAddrType_t *addr, cId_t clusterID, byte len );
uint8 ZDO_SendMsgCBs( zdoIncomingMsg_t *inMsg );
void zdpProcessAddrReq( zdoIncomingMsg_t *inMsg );
/*********************************************************************
* LOCAL VARIABLES
*/
static uint8 ZDP_Buf[ ZDP_BUF_SZ ];
static uint8 *ZDP_TmpBuf = ZDP_Buf+1;
byte ZDP_TxOptions = AF_TX_OPTIONS_NONE;
ZDO_MsgCB_t *zdoMsgCBs = (ZDO_MsgCB_t *)NULL;
/*********************************************************************
* ZDO Message Processing table
*/
typedef void (*pfnZDPMsgProcessor)( zdoIncomingMsg_t *inMsg );
typedef struct
{
uint16 clusterID;
pfnZDPMsgProcessor pFn;
} zdpMsgProcItem_t;
CONST zdpMsgProcItem_t zdpMsgProcs[] =
{
#if ( RFD_RCVC_ALWAYS_ON==TRUE ) || ( ZG_BUILD_RTR_TYPE )
// These aren't processed by sleeping end devices.
{ NWK_addr_req, zdpProcessAddrReq },
{ Device_annce, ZDO_ProcessDeviceAnnce },
#endif
{ IEEE_addr_req, zdpProcessAddrReq },
{ Node_Desc_req, ZDO_ProcessNodeDescReq },
{ Power_Desc_req, ZDO_ProcessPowerDescReq },
{ Simple_Desc_req, ZDO_ProcessSimpleDescReq },
{ Active_EP_req, ZDO_ProcessActiveEPReq },
{ Match_Desc_req, ZDO_ProcessMatchDescReq },
#if defined ( ZDO_MGMT_NWKDISC_RESPONSE )
{ Mgmt_NWK_Disc_req, ZDO_ProcessMgmtNwkDiscReq },
#endif
#if defined ( ZDO_MGMT_LQI_RESPONSE ) && ( ZG_BUILD_RTR_TYPE )
{ Mgmt_Lqi_req, ZDO_ProcessMgmtLqiReq },
#endif
#if defined ( ZDO_MGMT_RTG_RESPONSE ) && ( ZG_BUILD_RTR_TYPE )
{ Mgmt_Rtg_req, ZDO_ProcessMgmtRtgReq },
#endif
#if defined ( ZDO_MGMT_BIND_RESPONSE ) && defined ( REFLECTOR )
{ Mgmt_Bind_req, ZDO_ProcessMgmtBindReq },
#endif
#if defined ( ZDO_MGMT_JOINDIRECT_RESPONSE ) && ( ZG_BUILD_RTR_TYPE )
{ Mgmt_Direct_Join_req, ZDO_ProcessMgmtDirectJoinReq },
#endif
#if defined ( ZDO_MGMT_LEAVE_RESPONSE )
{ Mgmt_Leave_req, ZDO_ProcessMgmtLeaveReq },
#endif
#if defined ( ZDO_MGMT_PERMIT_JOIN_RESPONSE ) && ( ZG_BUILD_RTR_TYPE )
{ Mgmt_Permit_Join_req, ZDO_ProcessMgmtPermitJoinReq },
#endif
#if defined ( ZDO_USERDESC_RESPONSE )
{ User_Desc_req, ZDO_ProcessUserDescReq },
#endif
#if defined ( ZDO_USERDESCSET_RESPONSE )
{ User_Desc_set, ZDO_ProcessUserDescSet },
#endif
#if defined ( ZDO_SERVERDISC_RESPONSE )
{ Server_Discovery_req, ZDO_ProcessServerDiscReq },
#endif
{0xFFFF, NULL} // Last
};
/*********************************************************************
* @fn fillAndSend
*
* @brief Combined to reduce space
*
* @param
* @param
*
* @return afStatus_t
*/
static afStatus_t fillAndSend( uint8 *transSeq, zAddrType_t *addr, cId_t clusterID, byte len )
{
afAddrType_t afAddr;
osal_memset( &afAddr, 0, sizeof(afAddrType_t) );
ZADDR_TO_AFADDR( addr, afAddr );
*(ZDP_TmpBuf-1) = *transSeq;
return AF_DataRequest( &afAddr, &ZDApp_epDesc, clusterID,
(uint16)(len+1), (uint8*)(ZDP_TmpBuf-1),
transSeq, ZDP_TxOptions, AF_DEFAULT_RADIUS );
}
/*********************************************************************
* @fn ZDP_SendData
*
* @brief This builds and send a request message that has
* NWKAddrOfInterest as its only parameter.
*
* @param dstAddr - destination address
* @param cmd - clusterID
* @param dataLen - number of bytes of data
* @param data - pointer to the data
* @param SecurityEnable - Security Options
*
* @return afStatus_t
*/
afStatus_t ZDP_SendData( uint8 *TransSeq, zAddrType_t *dstAddr, uint16 cmd,
byte len, uint8 *buf, byte SecurityEnable )
{
uint8 *pBuf = ZDP_TmpBuf;
byte cnt = len;
while ( cnt-- )
{
*pBuf++ = *buf++;
}
FillAndSendTxOptions( TransSeq, dstAddr, cmd, len, ((SecurityEnable) ? AF_EN_SECURITY : 0) );
}
/*********************************************************************
* @fn ZDP_NWKAddrOfInterestReq
*
* @brief This builds and send a request message that has
* NWKAddrOfInterest as its only parameter.
*
* @param dstAddr - destination address
* @param nwkAddr - 16 bit address
* @param SecurityEnable - Security Options
*
* @return afStatus_t
*/
afStatus_t ZDP_NWKAddrOfInterestReq( zAddrType_t *dstAddr, uint16 nwkAddr,
byte cmd, byte SecurityEnable )
{
(void)SecurityEnable; // Intentionally unreferenced parameter
ZDP_TmpBuf[0] = LO_UINT16( nwkAddr );
ZDP_TmpBuf[1] = HI_UINT16( nwkAddr );
return fillAndSend( &ZDP_TransID, dstAddr, cmd, 2 );
}
/*********************************************************************
* Address Requests
*/
/*********************************************************************
* @fn ZDP_NwkAddrReq
*
* @brief This builds and send a NWK_addr_req message. This
* function sends a broadcast message looking for a 16
* bit address with a 64 bit address as bait.
*
* @param IEEEAddress - looking for this device
* @param SecurityEnable - Security Options
*
* @return afStatus_t
*/
afStatus_t ZDP_NwkAddrReq( uint8 *IEEEAddress, byte ReqType,
byte StartIndex, byte SecurityEnable )
{
uint8 *pBuf = ZDP_TmpBuf;
byte len = Z_EXTADDR_LEN + 1 + 1; // IEEEAddress + ReqType + StartIndex.
zAddrType_t dstAddr;
(void)SecurityEnable; // Intentionally unreferenced parameter
if ( osal_ExtAddrEqual( saveExtAddr, IEEEAddress ) == FALSE )
{
dstAddr.addrMode = AddrBroadcast;
dstAddr.addr.shortAddr = NWK_BROADCAST_SHORTADDR_DEVRXON;
}
else
{
dstAddr.addrMode = Addr16Bit;
dstAddr.addr.shortAddr = ZDAppNwkAddr.addr.shortAddr;
}
pBuf = osal_cpyExtAddr( pBuf, IEEEAddress );
*pBuf++ = ReqType;
*pBuf++ = StartIndex;
return fillAndSend( &ZDP_TransID, &dstAddr, NWK_addr_req, len );
}
/*********************************************************************
* @fn ZDP_IEEEAddrReq
*
* @brief This builds and send a IEEE_addr_req message. This
* function sends a unicast message looking for a 64
* bit IEEE address with a 16 bit address as bait.
*
* @param ReqType - ZDP_IEEEADDR_REQTYPE_SINGLE or
* ZDP_IEEEADDR_REQTYPE_EXTENDED
* @param SecurityEnable - Security Options
*
* @return afStatus_t
*/
afStatus_t ZDP_IEEEAddrReq( uint16 shortAddr, byte ReqType,
byte StartIndex, byte SecurityEnable )
{
uint8 *pBuf = ZDP_TmpBuf;
byte len = 2 + 1 + 1; // shortAddr + ReqType + StartIndex.
zAddrType_t dstAddr;
(void)SecurityEnable; // Intentionally unreferenced parameter
dstAddr.addrMode = (afAddrMode_t)Addr16Bit;
dstAddr.addr.shortAddr = shortAddr;
*pBuf++ = LO_UINT16( shortAddr );
*pBuf++ = HI_UINT16( shortAddr );
*pBuf++ = ReqType;
*pBuf++ = StartIndex;
return fillAndSend( &ZDP_TransID, &dstAddr, IEEE_addr_req, len );
}
/*********************************************************************
* @fn ZDP_MatchDescReq
*
* @brief This builds and send a Match_Desc_req message. This
* function sends a broadcast or unicast message
* requesting the list of endpoint/interfaces that
* match profile ID and cluster IDs.
*
* @param dstAddr - destination address
* @param nwkAddr - network address of interest
* @param ProfileID - Profile ID
* @param NumInClusters - number of input clusters
* @param InClusterList - input cluster ID list
* @param NumOutClusters - number of output clusters
* @param OutClusterList - output cluster ID list
* @param SecurityEnable - Security Options
*
* @return afStatus_t
*/
afStatus_t ZDP_MatchDescReq( zAddrType_t *dstAddr, uint16 nwkAddr,
uint16 ProfileID,
byte NumInClusters, cId_t *InClusterList,
byte NumOutClusters, cId_t *OutClusterList,
byte SecurityEnable )
{
uint8 *pBuf = ZDP_TmpBuf;
// nwkAddr+ProfileID+NumInClusters+NumOutClusters.
byte i, len = 2 + 2 + 1 + 1; // nwkAddr+ProfileID+NumInClusters+NumOutClusters.
(void)SecurityEnable; // Intentionally unreferenced parameter
len += (NumInClusters + NumOutClusters) * sizeof(uint16);
if ( len >= ZDP_BUF_SZ-1 )
{
return afStatus_MEM_FAIL;
}
// The spec changed in Zigbee 2007 (2.4.3.1.7.1) to not allow sending
// this command to 0xFFFF. So, here we will filter this and replace
// with 0xFFFD to only send to devices with RX ON. This includes the
// network address of interest.
if ( ((dstAddr->addrMode == AddrBroadcast) || (dstAddr->addrMode == Addr16Bit))
&& (dstAddr->addr.shortAddr == NWK_BROADCAST_SHORTADDR_DEVALL) )
{
dstAddr->addr.shortAddr = NWK_BROADCAST_SHORTADDR_DEVRXON;
}
if ( nwkAddr == NWK_BROADCAST_SHORTADDR_DEVALL )
{
nwkAddr = NWK_BROADCAST_SHORTADDR_DEVRXON;
}
*pBuf++ = LO_UINT16( nwkAddr ); // NWKAddrOfInterest
*pBuf++ = HI_UINT16( nwkAddr );
*pBuf++ = LO_UINT16( ProfileID ); // Profile ID
*pBuf++ = HI_UINT16( ProfileID );
*pBuf++ = NumInClusters; // Input cluster list
if ( NumInClusters )
{
for (i=0; i<NumInClusters; ++i) {
*pBuf++ = LO_UINT16( InClusterList[i] );
*pBuf++ = HI_UINT16( InClusterList[i] );
}
}
*pBuf++ = NumOutClusters; // Output cluster list
if ( NumOutClusters )
{
for (i=0; i<NumOutClusters; ++i) {
*pBuf++ = LO_UINT16( OutClusterList[i] );
*pBuf++ = HI_UINT16( OutClusterList[i] );
}
}
return fillAndSend( &ZDP_TransID, dstAddr, Match_Desc_req, len );
}
/*********************************************************************
* @fn ZDP_SimpleDescReq
*
* @brief This builds and send a NWK_Simple_Desc_req
* message. This function sends unicast message to the
* destination device.
*
* @param dstAddr - destination address
* @param nwkAddr - 16 bit address
* @param epIntf - endpoint/interface
* @param SecurityEnable - Security Options
*
* @return afStatus_t
*/
afStatus_t ZDP_SimpleDescReq( zAddrType_t *dstAddr, uint16 nwkAddr,
byte endPoint, byte SecurityEnable )
{
(void)SecurityEnable; // Intentionally unreferenced parameter
ZDP_TmpBuf[0] = LO_UINT16( nwkAddr );
ZDP_TmpBuf[1] = HI_UINT16( nwkAddr );
ZDP_TmpBuf[2] = endPoint;
return fillAndSend( &ZDP_TransID, dstAddr, Simple_Desc_req, 3 );
}
/*********************************************************************
* @fn ZDP_UserDescSet
*
* @brief This builds and send a User_Desc_set message to set
* the user descriptor. This function sends unicast
* message to the destination device.
*
* @param dstAddr - destination address
* @param nwkAddr - 16 bit address
* @param UserDescriptor - user descriptor
* @param SecurityEnable - Security Options
*
* @return afStatus_t
*/
afStatus_t ZDP_UserDescSet( zAddrType_t *dstAddr, uint16 nwkAddr,
UserDescriptorFormat_t *UserDescriptor,
byte SecurityEnable )
{
uint8 *pBuf = ZDP_TmpBuf;
byte len = (UserDescriptor->len < AF_MAX_USER_DESCRIPTOR_LEN) ?
UserDescriptor->len : AF_MAX_USER_DESCRIPTOR_LEN;
byte addrLen = 2;
(void)SecurityEnable; // Intentionally unreferenced parameter
*pBuf++ = LO_UINT16( nwkAddr );
*pBuf++ = HI_UINT16( nwkAddr );
*pBuf++ = len;
addrLen = 3;
pBuf = osal_memcpy( pBuf, UserDescriptor->desc, len );
osal_memset( pBuf, AF_USER_DESCRIPTOR_FILL, AF_MAX_USER_DESCRIPTOR_LEN-len );
return fillAndSend( &ZDP_TransID, dstAddr, User_Desc_set, (AF_MAX_USER_DESCRIPTOR_LEN + addrLen) );
}
/*********************************************************************
* @fn ZDP_ServerDiscReq
*
* @brief Build and send a Server_Discovery_req request message.
*
* @param serverMask - 16-bit bit-mask of server services being sought.
* @param SecurityEnable - Security Options
*
* @return afStatus_t
*/
afStatus_t ZDP_ServerDiscReq( uint16 serverMask, byte SecurityEnable )
{
uint8 *pBuf = ZDP_TmpBuf;
zAddrType_t dstAddr;
dstAddr.addrMode = AddrBroadcast;
dstAddr.addr.shortAddr = NWK_BROADCAST_SHORTADDR_DEVRXON;
*pBuf++ = LO_UINT16( serverMask );
*pBuf = HI_UINT16( serverMask );
FillAndSendTxOptions( &ZDP_TransID, &dstAddr, Server_Discovery_req, 2,
((SecurityEnable) ? AF_EN_SECURITY : AF_TX_OPTIONS_NONE) );
}
/*********************************************************************
* @fn ZDP_DeviceAnnce
*
* @brief This builds and send a Device_Annce message. This
* function sends a broadcast message.
*
* @param nwkAddr - 16 bit address of the device
* @param IEEEAddr - 64 bit address of the device
* @param capabilities - device capabilities. This field is only
* sent for v1.1 networks.
* @param SecurityEnable - Security Options
*
* @return afStatus_t
*/
afStatus_t ZDP_DeviceAnnce( uint16 nwkAddr, uint8 *IEEEAddr,
byte capabilities, byte SecurityEnable )
{
zAddrType_t dstAddr;
uint8 len;
(void)SecurityEnable; // Intentionally unreferenced parameter
dstAddr.addrMode = (afAddrMode_t)AddrBroadcast;
dstAddr.addr.shortAddr = NWK_BROADCAST_SHORTADDR_DEVRXON;
ZDP_TmpBuf[0] = LO_UINT16( nwkAddr );
ZDP_TmpBuf[1] = HI_UINT16( nwkAddr );
osal_cpyExtAddr( &ZDP_TmpBuf[2], IEEEAddr );
len = 2 + Z_EXTADDR_LEN;
ZDP_TmpBuf[10] = capabilities;
len++;
return fillAndSend( &ZDP_TransID, &dstAddr, Device_annce, len );
}
/*********************************************************************
* Address Responses
*/
/*********************************************************************
* @fn zdpProcessAddrReq
*
* @brief Process an incoming NWK_addr_req or IEEE_addr_req message and then
* build and send a corresponding NWK_addr_rsp or IEEE_addr_rsp msg.
*
* @param inMsg - incoming message
*
* @return none
*/
void zdpProcessAddrReq( zdoIncomingMsg_t *inMsg )
{
associated_devices_t *pAssoc;
uint8 reqType;
uint16 aoi = INVALID_NODE_ADDR;
uint8 *ieee = NULL;
reqType = inMsg->asdu[(inMsg->clusterID == NWK_addr_req) ? Z_EXTADDR_LEN : sizeof( uint16 ) ];
if ( inMsg->clusterID == NWK_addr_req )
{
ieee = inMsg->asdu;
if ( osal_ExtAddrEqual( saveExtAddr, ieee ) )
{
aoi = ZDAppNwkAddr.addr.shortAddr;
}
// Handle response for sleeping end devices
else if ( (ZSTACK_ROUTER_BUILD)
&& (((pAssoc = AssocGetWithExt( ieee )) != NULL)
&& (pAssoc->nodeRelation == CHILD_RFD)) )
{
aoi = pAssoc->shortAddr;
if ( reqType != ZDP_ADDR_REQTYPE_SINGLE )
reqType = 0xFF; // Force Invalid
}
}
else // if ( inMsg->clusterID == IEEE_addr_req )
{
aoi = BUILD_UINT16( inMsg->asdu[0], inMsg->asdu[1] );
if ( aoi == ZDAppNwkAddr.addr.shortAddr )
{
ieee = saveExtAddr;
}
else if ( (ZSTACK_ROUTER_BUILD)
&& (((pAssoc = AssocGetWithShort( aoi )) != NULL)
&& (pAssoc->nodeRelation == CHILD_RFD)) )
{
AddrMgrEntry_t addrEntry;
addrEntry.user = ADDRMGR_USER_DEFAULT;
addrEntry.index = pAssoc->addrIdx;
if ( AddrMgrEntryGet( &addrEntry ) )
{
ieee = addrEntry.extAddr;
}
if ( reqType != ZDP_ADDR_REQTYPE_SINGLE )
reqType = 0xFF; // Force Invalid
}
}
if ( ((aoi != INVALID_NODE_ADDR) && (ieee != NULL)) || (inMsg->wasBroadcast == FALSE) )
{
uint8 stat;
uint8 *pBuf = ZDP_TmpBuf;
// Status + IEEE-Addr + Nwk-Addr.
uint8 len = 1 + Z_EXTADDR_LEN + 2;
// If aoi and iee are both setup, we found results
if ( (aoi != INVALID_NODE_ADDR) && (ieee != NULL) )
{
stat = ((reqType == ZDP_ADDR_REQTYPE_SINGLE) || (reqType == ZDP_ADDR_REQTYPE_EXTENDED))
? ZDP_SUCCESS : ZDP_INVALID_REQTYPE;
}
else
{
// not found and the req was unicast to this device
stat = ZDP_DEVICE_NOT_FOUND;
// Fill in the missing field with this device's address
if ( inMsg->clusterID == NWK_addr_req )
{
aoi = ZDAppNwkAddr.addr.shortAddr;
}
else
{
ieee = saveExtAddr;
}
}
*pBuf++ = stat;
pBuf = osal_cpyExtAddr( pBuf, ieee );
*pBuf++ = LO_UINT16( aoi );
*pBuf++ = HI_UINT16( aoi );
if ( ZSTACK_ROUTER_BUILD )
{
if ( (reqType == ZDP_ADDR_REQTYPE_EXTENDED) && (aoi == ZDAppNwkAddr.addr.shortAddr)
&& (stat == ZDP_SUCCESS) )
{
uint8 cnt = 0;
uint16 *list = AssocMakeList( &cnt );
if ( list != NULL )
{
byte idx = inMsg->asdu[(((inMsg->clusterID == NWK_addr_req) ? Z_EXTADDR_LEN : sizeof( uint16 )) + 1)];
uint16 *pList = list + idx;
// NumAssocDev field is only present on success.
if ( cnt > idx )
{
cnt -= idx;
len += (cnt * sizeof( uint16 ));
}
else
{
cnt = 0;
}
*pBuf++ = cnt;
len++;
// StartIndex field is only present if NumAssocDev field is non-zero.
*pBuf++ = idx;
len++;
while ( cnt != 0 )
{
*pBuf++ = LO_UINT16( *pList );
*pBuf++ = HI_UINT16( *pList );
pList++;
cnt--;
}
osal_mem_free( (uint8 *)list );
}
else
{
// NumAssocDev field is only present on success.
*pBuf++ = 0;
len++;
}
}
}
ZDP_TxOptions = AF_MSG_ACK_REQUEST;
fillAndSend( &(inMsg->TransSeq), &(inMsg->srcAddr), (cId_t)(inMsg->clusterID | ZDO_RESPONSE_BIT), len );
ZDP_TxOptions = AF_TX_OPTIONS_NONE;
}
}
/*********************************************************************
* @fn ZDP_NodeDescMsg
*
* @brief Builds and sends a Node Descriptor message, unicast to the
* specified device.
*
* @param inMsg - incoming message
* @param nwkAddr - 16 bit network address for device
* @param pNodeDesc - pointer to the node descriptor
*
* @return afStatus_t
*/
afStatus_t ZDP_NodeDescMsg( zdoIncomingMsg_t *inMsg,
uint16 nwkAddr, NodeDescriptorFormat_t *pNodeDesc )
{
uint8 *pBuf = ZDP_TmpBuf;
byte len;
len = 1 + 2 + 13; // Status + nwkAddr + Node descriptor
*pBuf++ = ZDP_SUCCESS;
*pBuf++ = LO_UINT16( nwkAddr );
*pBuf++ = HI_UINT16( nwkAddr );
*pBuf++ = (byte)((pNodeDesc->ComplexDescAvail << 3) |
(pNodeDesc->UserDescAvail << 4) |
(pNodeDesc->LogicalType & 0x07));
*pBuf++ = (byte)((pNodeDesc->FrequencyBand << 3) | (pNodeDesc->APSFlags & 0x07));
*pBuf++ = pNodeDesc->CapabilityFlags;
*pBuf++ = pNodeDesc->ManufacturerCode[0];
*pBuf++ = pNodeDesc->ManufacturerCode[1];
*pBuf++ = pNodeDesc->MaxBufferSize;
*pBuf++ = pNodeDesc->MaxInTransferSize[0];
*pBuf++ = pNodeDesc->MaxInTransferSize[1];
*pBuf++ = LO_UINT16( pNodeDesc->ServerMask );
*pBuf++ = HI_UINT16( pNodeDesc->ServerMask );
*pBuf++ = pNodeDesc->MaxOutTransferSize[0];
*pBuf++ = pNodeDesc->MaxOutTransferSize[1];
*pBuf = pNodeDesc->DescriptorCapability;
return fillAndSend( &(inMsg->TransSeq), &(inMsg->srcAddr), Node_Desc_rsp, len );
}
/*********************************************************************
* @fn ZDP_PowerDescMsg
*
* @brief Builds and sends a Power Descriptor message, unicast to the
* specified device.
*
* @param inMsg - incoming message (request)
* @param nwkAddr - 16 bit network address for device
* @param pPowerDesc - pointer to the node descriptor
*
* @return afStatus_t
*/
afStatus_t ZDP_PowerDescMsg( zdoIncomingMsg_t *inMsg,
uint16 nwkAddr, NodePowerDescriptorFormat_t *pPowerDesc )
{
uint8 *pBuf = ZDP_TmpBuf;
byte len = 1 + 2 + 2; // Status + nwkAddr + Node Power descriptor.
*pBuf++ = ZDP_SUCCESS;
*pBuf++ = LO_UINT16( nwkAddr );
*pBuf++ = HI_UINT16( nwkAddr );
*pBuf++ = (byte)((pPowerDesc->AvailablePowerSources << 4)
| (pPowerDesc->PowerMode & 0x0F));
*pBuf++ = (byte)((pPowerDesc->CurrentPowerSourceLevel << 4)
| (pPowerDesc->CurrentPowerSource & 0x0F));
return fillAndSend( &(inMsg->TransSeq), &(inMsg->srcAddr), Power_Desc_rsp, len );
}
/*********************************************************************
* @fn ZDP_SimpleDescMsg
*
* @brief Builds and sends a Simple Descriptor message, unicast to the
* specified device.
*
* @param inMsg - incoming message (request)
* @param Status - message status (ZDP_SUCCESS or other)
* @param pSimpleDesc - pointer to the node descriptor
*
* @return afStatus_t
*/
afStatus_t ZDP_SimpleDescMsg( zdoIncomingMsg_t *inMsg, byte Status,
SimpleDescriptionFormat_t *pSimpleDesc )
{
uint8 *pBuf = ZDP_TmpBuf;
uint8 i, len;
if ( Status == ZDP_SUCCESS && pSimpleDesc )
{
// Status + NWKAddrOfInterest + desc length + empty simple descriptor.
len = 1 + 2 + 1 + 8;
len += (pSimpleDesc->AppNumInClusters + pSimpleDesc->AppNumOutClusters) * sizeof ( uint16 );
}
else
{
len = 1 + 2 + 1; // Status + desc length
}
if ( len >= ZDP_BUF_SZ-1 )
{
return afStatus_MEM_FAIL;
}
*pBuf++ = Status;
*pBuf++ = LO_UINT16( ZDAppNwkAddr.addr.shortAddr );
*pBuf++ = HI_UINT16( ZDAppNwkAddr.addr.shortAddr );
if ( len > 4 )
{
*pBuf++ = len - 4; // Simple descriptor length
*pBuf++ = pSimpleDesc->EndPoint;
*pBuf++ = LO_UINT16( pSimpleDesc->AppProfId );
*pBuf++ = HI_UINT16( pSimpleDesc->AppProfId );
*pBuf++ = LO_UINT16( pSimpleDesc->AppDeviceId );
*pBuf++ = HI_UINT16( pSimpleDesc->AppDeviceId );
*pBuf++ = (byte)(pSimpleDesc->AppDevVer << 4);
*pBuf++ = pSimpleDesc->AppNumInClusters;
if ( pSimpleDesc->AppNumInClusters )
{
for (i=0; i<pSimpleDesc->AppNumInClusters; ++i)
{
*pBuf++ = LO_UINT16( pSimpleDesc->pAppInClusterList[i] );
*pBuf++ = HI_UINT16( pSimpleDesc->pAppInClusterList[i] );
}
}
*pBuf++ = pSimpleDesc->AppNumOutClusters;
if ( pSimpleDesc->AppNumOutClusters )
{
for (i=0; i<pSimpleDesc->AppNumOutClusters; ++i)
{
*pBuf++ = LO_UINT16( pSimpleDesc->pAppOutClusterList[i] );
*pBuf++ = HI_UINT16( pSimpleDesc->pAppOutClusterList[i] );
}
}
}
else
{
*pBuf = 0; // Description Length = 0;
}
return fillAndSend( &(inMsg->TransSeq), &(inMsg->srcAddr), Simple_Desc_rsp, len );
}
/*********************************************************************
* @fn ZDP_EPRsp
*
* @brief This builds and send an endpoint list. Used in
* Active_EP_rsp and Match_Desc_Rsp
* message. This function sends unicast message to the
* requesting device.
*
* @param MsgType - either Active_EP_rsp or Match_Desc_Rsp
* @param dstAddr - destination address
* @param Status - message status (ZDP_SUCCESS or other)
* @param nwkAddr - Device's short address that this response describes
* @param Count - number of endpoint/interfaces in list
* @param pEPIntfList - Array of Endpoint/Interfaces
* @param SecurityEnable - Security Options
*
* @return afStatus_t
*/
afStatus_t ZDP_EPRsp( uint16 MsgType, byte TransSeq, zAddrType_t *dstAddr,
byte Status, uint16 nwkAddr, byte Count,
uint8 *pEPList,
byte SecurityEnable )
{
uint8 *pBuf = ZDP_TmpBuf;
byte len = 1 + 2 + 1; // Status + nwkAddr + endpoint/interface count.
byte txOptions;
(void)SecurityEnable; // Intentionally unreferenced parameter
if ( MsgType == Match_Desc_rsp )
txOptions = AF_MSG_ACK_REQUEST;
else
txOptions = 0;
*pBuf++ = Status;
*pBuf++ = LO_UINT16( nwkAddr );
*pBuf++ = HI_UINT16( nwkAddr );
*pBuf++ = Count; // Endpoint/Interface count
if ( Count )
{
len += Count;
osal_memcpy( pBuf, pEPList, Count );
}
FillAndSendTxOptions( &TransSeq, dstAddr, MsgType, len, txOptions );
}
/*********************************************************************
* @fn ZDP_UserDescRsp
*
* @brief Build and send the User Decriptor Response.
*
*
* @param dstAddr - destination address
* @param nwkAddrOfInterest -
* @param userDesc -
* @param SecurityEnable - Security Options
*
* @return ZStatus_t
*/
ZStatus_t ZDP_UserDescRsp( byte TransSeq, zAddrType_t *dstAddr,
uint16 nwkAddrOfInterest, UserDescriptorFormat_t *userDesc,
byte SecurityEnable )
{
uint8 *pBuf = ZDP_TmpBuf;
byte len = 1 + 2 + 1; // Status + nwkAddr + descriptor length.
(void)SecurityEnable; // Intentionally unreferenced parameter
len += userDesc->len;
*pBuf++ = ZSUCCESS;
*pBuf++ = LO_UINT16( nwkAddrOfInterest );
*pBuf++ = HI_UINT16( nwkAddrOfInterest );
*pBuf++ = userDesc->len;
osal_memcpy( pBuf, userDesc->desc, userDesc->len );
return (ZStatus_t)fillAndSend( &TransSeq, dstAddr, User_Desc_rsp, len );
}
/*********************************************************************
* @fn ZDP_ServerDiscRsp
*
* @brief Build and send the Server_Discovery_rsp response.
*
* @param transID - Transaction sequence number of request.
* @param dstAddr - Network Destination Address.
* @param status - Status of response to request.
* @param aoi - Network Address of Interest of request.
* @param serverMask - Bit map of service(s) being sought.
* @param SecurityEnable - Security Options
*
* @return ZStatus_t
*/
ZStatus_t ZDP_ServerDiscRsp( byte transID, zAddrType_t *dstAddr, byte status,
uint16 aoi, uint16 serverMask, byte SecurityEnable )
{
const byte len = 1 + 2; // status + aoi + mask.
uint8 *pBuf = ZDP_TmpBuf;
ZStatus_t stat;
// Intentionally unreferenced parameters
(void)aoi;
(void)SecurityEnable;
*pBuf++ = status;
*pBuf++ = LO_UINT16( serverMask );
*pBuf++ = HI_UINT16( serverMask );
ZDP_TxOptions = AF_MSG_ACK_REQUEST;
stat = fillAndSend( &transID, dstAddr, Server_Discovery_rsp, len );
ZDP_TxOptions = AF_TX_OPTIONS_NONE;
return ( stat );
}
/*********************************************************************
* @fn ZDP_GenericRsp
*
* @brief Sends a response message with only the parameter status
* byte and the addr of interest for data.
* This function sends unicast message to the
* requesting device.
*
* @param dstAddr - destination address
* @param status - generic status for response
* @param aoi - address of interest
* @param dstAddr - destination address
* @param rspId - response cluster ID
* @param SecurityEnable - Security Options
*
* @return afStatus_t
*/
afStatus_t ZDP_GenericRsp( byte TransSeq, zAddrType_t *dstAddr,
byte status, uint16 aoi, uint16 rspID, byte SecurityEnable )
{
uint8 len;
(void)SecurityEnable; // Intentionally unreferenced parameter
ZDP_TmpBuf[0] = status;
ZDP_TmpBuf[1] = LO_UINT16( aoi );
ZDP_TmpBuf[2] = HI_UINT16( aoi );
// Length byte
ZDP_TmpBuf[3] = 0;
len = 4;
return fillAndSend( &TransSeq, dstAddr, rspID, len );
}
/*********************************************************************
* Binding
*/
/*********************************************************************
* @fn ZDP_EndDeviceBindReq
*
* @brief This builds and sends a End_Device_Bind_req message.
* This function sends a unicast message.
*
* @param dstAddr - destination address
* @param LocalCoordinator - short address of local coordinator
* @param epIntf - Endpoint/Interface of Simple Desc
* @param ProfileID - Profile ID
*
* The Input cluster list is the opposite of what you would think.
* This is the output cluster list of this device
* @param NumInClusters - number of input clusters
* @param InClusterList - input cluster ID list
*
* The Output cluster list is the opposite of what you would think.
* This is the input cluster list of this device
* @param NumOutClusters - number of output clusters
* @param OutClusterList - output cluster ID list
*
* @param SecurityEnable - Security Options
*
* @return afStatus_t
*/
afStatus_t ZDP_EndDeviceBindReq( zAddrType_t *dstAddr,
uint16 LocalCoordinator,
byte endPoint,
uint16 ProfileID,
byte NumInClusters, cId_t *InClusterList,
byte NumOutClusters, cId_t *OutClusterList,
byte SecurityEnable )
{
uint8 *pBuf = ZDP_TmpBuf;
uint8 i, len;
uint8 *ieeeAddr;
(void)SecurityEnable; // Intentionally unreferenced parameter
// LocalCoordinator + SrcExtAddr + ep + ProfileID + NumInClusters + NumOutClusters.
len = 2 + Z_EXTADDR_LEN + 1 + 2 + 1 + 1;
len += (NumInClusters + NumOutClusters) * sizeof ( uint16 );
if ( len >= ZDP_BUF_SZ-1 )
{
return afStatus_MEM_FAIL;
}
if ( LocalCoordinator != NLME_GetShortAddr() )
{
return afStatus_INVALID_PARAMETER;
}
*pBuf++ = LO_UINT16( LocalCoordinator );
*pBuf++ = HI_UINT16( LocalCoordinator );
ieeeAddr = NLME_GetExtAddr();
pBuf = osal_cpyExtAddr( pBuf, ieeeAddr );
*pBuf++ = endPoint;
*pBuf++ = LO_UINT16( ProfileID ); // Profile ID
*pBuf++ = HI_UINT16( ProfileID );
*pBuf++ = NumInClusters; // Input cluster list
for ( i = 0; i < NumInClusters; ++i )
{
*pBuf++ = LO_UINT16(InClusterList[i]);
*pBuf++ = HI_UINT16(InClusterList[i]);
}
*pBuf++ = NumOutClusters; // Output cluster list
for ( i = 0; i < NumOutClusters; ++i )
{
*pBuf++ = LO_UINT16(OutClusterList[i]);
*pBuf++ = HI_UINT16(OutClusterList[i]);
}
return fillAndSend( &ZDP_TransID, dstAddr, End_Device_Bind_req, len );
}
/*********************************************************************
* @fn ZDP_BindUnbindReq
*
* @brief This builds and send a Bind_req or Unbind_req message
* Depending on the ClusterID. This function
* sends a unicast message to the local coordinator.
*
* @param BindOrUnbind - either Bind_req or Unbind_req
* @param dstAddr - destination address of the message
* @param SourceAddr - source 64 bit address of the binding
* @param SrcEPIntf - Source endpoint/interface
* @param ClusterID - Binding cluster ID
* @param DestinationAddr - destination 64 bit addr of binding
* @param DstEPIntf - destination endpoint/interface
* @param SecurityEnable - Security Options
*
* @return afStatus_t
*/
afStatus_t ZDP_BindUnbindReq( uint16 BindOrUnbind, zAddrType_t *dstAddr,
uint8 *SourceAddr, byte SrcEndPoint,
cId_t ClusterID,
zAddrType_t *destinationAddr, byte DstEndPoint,
byte SecurityEnable )
{
uint8 *pBuf = ZDP_TmpBuf;
byte len;
(void)SecurityEnable; // Intentionally unreferenced parameter
// SourceAddr + SrcEPIntf + ClusterID + addrMode.
len = Z_EXTADDR_LEN + 1 + sizeof( cId_t ) + sizeof( uint8 );
if ( destinationAddr->addrMode == Addr64Bit )
len += Z_EXTADDR_LEN + 1; // +1 for DstEPIntf
else if ( destinationAddr->addrMode == AddrGroup )
len += sizeof ( uint16 );
pBuf = osal_cpyExtAddr( pBuf, SourceAddr );
*pBuf++ = SrcEndPoint;
*pBuf++ = LO_UINT16( ClusterID );
*pBuf++ = HI_UINT16( ClusterID );
*pBuf++ = destinationAddr->addrMode;
if ( destinationAddr->addrMode == Addr64Bit )
{
pBuf = osal_cpyExtAddr( pBuf, destinationAddr->addr.extAddr );
*pBuf = DstEndPoint;
}
else if ( destinationAddr->addrMode == AddrGroup )
{
*pBuf++ = LO_UINT16( destinationAddr->addr.shortAddr );
*pBuf++ = HI_UINT16( destinationAddr->addr.shortAddr );
}
FillAndSendTxOptions( &ZDP_TransID, dstAddr, BindOrUnbind, len, AF_MSG_ACK_REQUEST );
}
/*********************************************************************
* Network Management
*/
/*********************************************************************
* @fn ZDP_MgmtNwkDiscReq
*
* @brief This builds and send a Mgmt_NWK_Disc_req message. This
* function sends a unicast message.
*
* @param dstAddr - destination address of the message
* @param ScanChannels - 32 bit address bit map
* @param StartIndex - Starting index within the reporting network
* list
* @param SecurityEnable - Security Options
*
* @return afStatus_t
*/
afStatus_t ZDP_MgmtNwkDiscReq( zAddrType_t *dstAddr,
uint32 ScanChannels,
byte ScanDuration,
byte StartIndex,
byte SecurityEnable )
{
uint8 *pBuf = ZDP_TmpBuf;
byte len = sizeof( uint32 )+1+1; // ScanChannels + ScanDuration + StartIndex.
(void)SecurityEnable; // Intentionally unreferenced parameter
pBuf = osal_buffer_uint32( pBuf, ScanChannels );
*pBuf++ = ScanDuration;
*pBuf = StartIndex;
return fillAndSend( &ZDP_TransID, dstAddr, Mgmt_NWK_Disc_req, len );
}
/*********************************************************************
* @fn ZDP_MgmtDirectJoinReq
*
* @brief This builds and send a Mgmt_Direct_Join_req message. This
* function sends a unicast message.
*
* @param dstAddr - destination address of the message
* @param deviceAddr - 64 bit IEEE Address
* @param SecurityEnable - Security Options
*
* @return afStatus_t
*/
afStatus_t ZDP_MgmtDirectJoinReq( zAddrType_t *dstAddr,
uint8 *deviceAddr,
byte capInfo,
byte SecurityEnable )
{
(void)SecurityEnable; // Intentionally unreferenced parameter
osal_cpyExtAddr( ZDP_TmpBuf, deviceAddr );
ZDP_TmpBuf[Z_EXTADDR_LEN] = capInfo;
return fillAndSend( &ZDP_TransID, dstAddr, Mgmt_Direct_Join_req, (Z_EXTADDR_LEN + 1) );
}
/*********************************************************************
* @fn ZDP_MgmtPermitJoinReq
*
* @brief This builds and send a Mgmt_Permit_Join_req message.
*
* @param dstAddr - destination address of the message
* @param duration - Permit duration
* @param TcSignificance - Trust Center Significance
*
* @return afStatus_t
*/
afStatus_t ZDP_MgmtPermitJoinReq( zAddrType_t *dstAddr, byte duration,
byte TcSignificance, byte SecurityEnable )
{
(void)SecurityEnable; // Intentionally unreferenced parameter
// Build buffer
ZDP_TmpBuf[ZDP_MGMT_PERMIT_JOIN_REQ_DURATION] = duration;
ZDP_TmpBuf[ZDP_MGMT_PERMIT_JOIN_REQ_TC_SIG] = TcSignificance;
// Send the message
return fillAndSend( &ZDP_TransID, dstAddr, Mgmt_Permit_Join_req,
ZDP_MGMT_PERMIT_JOIN_REQ_SIZE );
}
/*********************************************************************
* @fn ZDP_MgmtLeaveReq
*
* @brief This builds and send a Mgmt_Leave_req message.
*
* @param dstAddr - destination address of the message
* IEEEAddr - IEEE adddress of device that is removed
* RemoveChildren - set to 1 to remove the children of the
* device as well. 0 otherwise.
* Rejoin - set to 1 if the removed device should rejoin
afterwards. 0 otherwise.
*
* @return afStatus_t
*/
afStatus_t ZDP_MgmtLeaveReq( zAddrType_t *dstAddr, uint8 *IEEEAddr, uint8 RemoveChildren,
uint8 Rejoin, uint8 SecurityEnable )
{
(void)SecurityEnable; // Intentionally unreferenced parameter
osal_cpyExtAddr( ZDP_TmpBuf, IEEEAddr );
ZDP_TmpBuf[Z_EXTADDR_LEN] = 0;
if ( RemoveChildren == TRUE )
{
ZDP_TmpBuf[Z_EXTADDR_LEN] |= ZDP_MGMT_LEAVE_REQ_RC;
}
if ( Rejoin == TRUE )
{
ZDP_TmpBuf[Z_EXTADDR_LEN] |= ZDP_MGMT_LEAVE_REQ_REJOIN;
}
return fillAndSend( &ZDP_TransID, dstAddr, Mgmt_Leave_req, (Z_EXTADDR_LEN + 1) );
}
/*********************************************************************
* @fn ZDP_MgmtNwkUpdateReq
*
* @brief This builds and send a Mgmt_NWK_Update_req message. This
* function sends a unicast or broadcast message.
*
* @param dstAddr - destination address of the message
* @param ChannelMask - 32 bit address bit map
* @param ScanDuration - length of time to spend scanning each channel
* @param ScanCount - number of energy scans to be conducted
* @param NwkUpdateId - NWk Update Id value
* @param NwkManagerAddr - NWK address for device with Network Manager
* bit set in its Node Descriptor
*
* @return afStatus_t
*/
afStatus_t ZDP_MgmtNwkUpdateReq( zAddrType_t *dstAddr,
uint32 ChannelMask,
uint8 ScanDuration,
uint8 ScanCount,
uint8 NwkUpdateId,
uint16 NwkManagerAddr )
{
uint8 *pBuf = ZDP_TmpBuf;
byte len = sizeof( uint32 ) + 1; // ChannelMask + ScanDuration
pBuf = osal_buffer_uint32( pBuf, ChannelMask );
*pBuf++ = ScanDuration;
if ( ScanDuration <= 0x05 )
{
// Request is to scan over channelMask
len += sizeof( uint8 );
*pBuf++ = ScanCount;
}
else if ( ( ScanDuration == 0xFE ) || ( ScanDuration == 0xFF ) )
{
// Request is to change Channel (0xFE) or apsChannelMask and NwkManagerAddr (0xFF)
len += sizeof( uint8 );
*pBuf++ = NwkUpdateId;
if ( ScanDuration == 0xFF )
{
len += sizeof( uint16 );
*pBuf++ = LO_UINT16( NwkManagerAddr );
*pBuf++ = HI_UINT16( NwkManagerAddr );
}
}
return fillAndSend( &ZDP_TransID, dstAddr, Mgmt_NWK_Update_req, len );
}
/*********************************************************************
* Network Management Responses
*/
/*********************************************************************
* @fn ZDP_MgmtNwkDiscRsp
*
* @brief This builds and send a Mgmt_NWK_Disc_rsp message. This
* function sends a unicast message.
*
* @param dstAddr - destination address of the message
* @param Status - message status (ZDP_SUCCESS or other)
* @param NetworkCount - Total number of networks found
* @param StartIndex - Starting index within the reporting network
* list
* @param NetworkListCount - number of network lists included
* in this message
* @param NetworkList - List of network descriptors
* @param SecurityEnable - Security Options
*
* @return afStatus_t
*/
afStatus_t ZDP_MgmtNwkDiscRsp( byte TransSeq, zAddrType_t *dstAddr,
byte Status,
byte NetworkCount,
byte StartIndex,
byte NetworkListCount,
networkDesc_t *NetworkList,
byte SecurityEnable )
{
uint8 *buf;
uint8 *pBuf;
byte len = 1+1+1+1; // Status + NetworkCount + StartIndex + NetworkCountList.
byte idx;
(void)SecurityEnable; // Intentionally unreferenced parameter
len += (NetworkListCount * ( ZDP_NETWORK_EXTENDED_DISCRIPTOR_SIZE - 2 ));
buf = osal_mem_alloc( len+1 );
if ( buf == NULL )
{
return afStatus_MEM_FAIL;
}
pBuf = buf+1;
*pBuf++ = Status;
*pBuf++ = NetworkCount;
*pBuf++ = StartIndex;
*pBuf++ = NetworkListCount;
for ( idx = 0; idx < NetworkListCount; idx++ )
{
osal_cpyExtAddr( pBuf, NetworkList->extendedPANID);
pBuf += Z_EXTADDR_LEN;
*pBuf++ = NetworkList->logicalChannel; // LogicalChannel
*pBuf = NetworkList->stackProfile; // Stack profile
*pBuf++ |= (byte)(NetworkList->version << 4); // ZigBee Version
*pBuf = BEACON_ORDER_NO_BEACONS; // Beacon Order
*pBuf++ |= (uint8)(BEACON_ORDER_NO_BEACONS << 4); // Superframe Order
if ( NetworkList->chosenRouter != INVALID_NODE_ADDR )
{
*pBuf++ = TRUE; // Permit Joining
}
else
{
*pBuf++ = FALSE;
}
NetworkList = NetworkList->nextDesc; // Move to next list entry
}
FillAndSendBuffer( &TransSeq, dstAddr, Mgmt_NWK_Disc_rsp, len, buf );
}
/*********************************************************************
* @fn ZDP_MgmtLqiRsp
*
* @brief This builds and send a Mgmt_Lqi_rsp message. This
* function sends a unicast message.
*
* @param dstAddr - destination address of the message
* @param Status - message status (ZDP_SUCCESS or other)
* @param NeighborLqiEntries - Total number of entries found
* @param StartIndex - Starting index within the reporting list
* @param NeighborLqiCount - number of lists included
* in this message
* @param NeighborLqiList - List of NeighborLqiItems. This list
* is the list to be sent, not the entire list
* @param SecurityEnable - true if secure
*
* @return ZStatus_t
*/
ZStatus_t ZDP_MgmtLqiRsp( byte TransSeq, zAddrType_t *dstAddr,
byte Status,
byte NeighborLqiEntries,
byte StartIndex,
byte NeighborLqiCount,
ZDP_MgmtLqiItem_t* NeighborList,
byte SecurityEnable )
{
ZDP_MgmtLqiItem_t* list = NeighborList;
uint8 *buf, *pBuf;
byte len, x;
(void)SecurityEnable; // Intentionally unreferenced parameter
if ( ZSuccess != Status )
{
ZDP_TmpBuf[0] = Status;
return fillAndSend( &TransSeq, dstAddr, Mgmt_Lqi_rsp, 1 );
}
// (Status + NeighborLqiEntries + StartIndex + NeighborLqiCount) +
// neighbor LQI data.
len = (1 + 1 + 1 + 1) + (NeighborLqiCount * ZDP_MGMTLQI_EXTENDED_SIZE);
buf = osal_mem_alloc( len+1 );
if ( buf == NULL )
{
return afStatus_MEM_FAIL;
}
pBuf = buf+1;
*pBuf++ = Status;
*pBuf++ = NeighborLqiEntries;
*pBuf++ = StartIndex;
*pBuf++ = NeighborLqiCount;
for ( x = 0; x < NeighborLqiCount; x++ )
{
osal_cpyExtAddr( pBuf, list->extPanID); // Extended PanID
pBuf += Z_EXTADDR_LEN;
// EXTADDR
pBuf = osal_cpyExtAddr( pBuf, list->extAddr );
// NWKADDR
*pBuf++ = LO_UINT16( list->nwkAddr );
*pBuf++ = HI_UINT16( list->nwkAddr );
// DEVICETYPE
*pBuf = list->devType;
// RXONIDLE
*pBuf |= (uint8)(list->rxOnIdle << 2);
// RELATIONSHIP
*pBuf++ |= (uint8)(list->relation << 4);
// PERMITJOINING
*pBuf++ = (uint8)(list->permit);
// DEPTH
*pBuf++ = list->depth;
// LQI
*pBuf++ = list->lqi;
list++; // next list entry
}
FillAndSendBuffer( &TransSeq, dstAddr, Mgmt_Lqi_rsp, len, buf );
}
/*********************************************************************
* @fn ZDP_MgmtRtgRsp
*
* @brief This builds and send a Mgmt_Rtg_rsp message. This
* function sends a unicast message.
*
* @param dstAddr - destination address of the message
* @param Status - message status (ZDP_SUCCESS or other)
* @param RoutingTableEntries - Total number of entries
* @param StartIndex - Starting index within the reporting list
* @param RoutingTableListCount - number of entries included
* in this message
* @param RoutingTableList - List of Routing Table entries
* @param SecurityEnable - true to enable security for this message
*
* @return ZStatus_t
*/
ZStatus_t ZDP_MgmtRtgRsp( byte TransSeq, zAddrType_t *dstAddr,
byte Status,
byte RoutingTableEntries,
byte StartIndex,
byte RoutingListCount,
rtgItem_t *RoutingTableList,
byte SecurityEnable )
{
uint8 *buf;
uint8 *pBuf;
// Status + RoutingTableEntries + StartIndex + RoutingListCount.
byte len = 1 + 1 + 1 + 1;
byte x;
(void)SecurityEnable; // Intentionally unreferenced parameter
// Add an array for Routing List data
len += (RoutingListCount * ZDP_ROUTINGENTRY_SIZE);
buf = osal_mem_alloc( (short)(len+1) );
if ( buf == NULL )
{
return afStatus_MEM_FAIL;
}
pBuf = buf+1;
*pBuf++ = Status;
*pBuf++ = RoutingTableEntries;
*pBuf++ = StartIndex;
*pBuf++ = RoutingListCount;
for ( x = 0; x < RoutingListCount; x++ )
{
*pBuf++ = LO_UINT16( RoutingTableList->dstAddress ); // Destination Address
*pBuf++ = HI_UINT16( RoutingTableList->dstAddress );
*pBuf++ = RoutingTableList->status;
*pBuf++ = LO_UINT16( RoutingTableList->nextHopAddress ); // Next hop
*pBuf++ = HI_UINT16( RoutingTableList->nextHopAddress );
RoutingTableList++; // Move to next list entry
}
FillAndSendBuffer( &TransSeq, dstAddr, Mgmt_Rtg_rsp, len, buf );
}
/*********************************************************************
* @fn ZDP_MgmtBindRsp
*
* @brief This builds and send a Mgmt_Bind_rsp message. This
* function sends a unicast message.
*
* @param dstAddr - destination address of the message
* @param Status - message status (ZDP_SUCCESS or other)
* @param BindingTableEntries - Total number of entries
* @param StartIndex - Starting index within the reporting list
* @param BindingTableListCount - number of entries included
* in this message
* @param BindingTableList - List of Binding Table entries
* @param SecurityEnable - Security Options
*
* @return ZStatus_t
*/
ZStatus_t ZDP_MgmtBindRsp( byte TransSeq, zAddrType_t *dstAddr,
byte Status,
byte BindingTableEntries,
byte StartIndex,
byte BindingTableListCount,
apsBindingItem_t *BindingTableList,
byte SecurityEnable )
{
uint8 *buf;
uint8 *pBuf;
uint8 maxLen; // maxLen is the maximum packet length to allocate enough memory space
uint8 len; // Actual length varies due to different addrMode
uint8 x;
byte extZdpBindEntrySize = ZDP_BINDINGENTRY_SIZE + 1 + 1; // One more byte for cluserID and DstAddrMode
byte shortZdpBindEntrySize = ZDP_BINDINGENTRY_SIZE + 1 + 1 + 2 - 8 - 1; // clusterID + DstAddrMode + shortAddr - ExtAddr - DstEndpoint
(void)SecurityEnable; // Intentionally unreferenced parameter
// Status + BindingTableEntries + StartIndex + BindingTableListCount.
maxLen = 1 + 1 + 1 + 1;
maxLen += (BindingTableListCount * extZdpBindEntrySize ); //max length
buf = osal_mem_alloc( maxLen + 1 ); // +1 for transaction ID
if ( buf == NULL )
{
return afStatus_MEM_FAIL;
}
pBuf = buf+1;
*pBuf++ = Status;
*pBuf++ = BindingTableEntries;
*pBuf++ = StartIndex;
*pBuf++ = BindingTableListCount;
// Initial length = Status + BindingTableEntries + StartIndex + BindingTableListCount.
// length += ZDP_BINDINGENTRY_SIZE -- Version 1.0
// extZdpBindEntrySize -- Version 1.1 extended address mode
// shortZdpBindEntrySize -- Version 1.1 group address mode
len = 1 + 1 + 1 + 1;
for ( x = 0; x < BindingTableListCount; x++ )
{
pBuf = osal_cpyExtAddr( pBuf, BindingTableList->srcAddr );
*pBuf++ = BindingTableList->srcEP;
// Cluster ID
*pBuf++ = LO_UINT16( BindingTableList->clusterID );
*pBuf++ = HI_UINT16( BindingTableList->clusterID );
*pBuf++ = BindingTableList->dstAddr.addrMode;
if ( BindingTableList->dstAddr.addrMode == Addr64Bit )
{
len += extZdpBindEntrySize;
pBuf = osal_cpyExtAddr( pBuf, BindingTableList->dstAddr.addr.extAddr );
*pBuf++ = BindingTableList->dstEP;
}
else
{
len += shortZdpBindEntrySize;
*pBuf++ = LO_UINT16( BindingTableList->dstAddr.addr.shortAddr );
*pBuf++ = HI_UINT16( BindingTableList->dstAddr.addr.shortAddr );
}
BindingTableList++; // Move to next list entry
}
FillAndSendBuffer( &TransSeq, dstAddr, Mgmt_Bind_rsp, len, buf );
}
/*********************************************************************
* @fn ZDP_MgmtNwkUpdateNotify
*
* @brief This builds and send a Mgmt_NWK_Update_notify message. This
* function sends a unicast message.
*
* @param dstAddr - destination address of the message
* @param status - message status (ZDP_SUCCESS or other)
* @param scannedChannels - List of channels scanned by the request
* @param totalTransmissions - Total transmissions
* @param transmissionFailures - Sum of transmission failures
* @param listCount - Number of records contained in the energyValues list
* @param energyValues - List of descriptors, one for each of ListCount,
* of the enegry detect descriptors
* @param txOptions - Transmit options
* @param securityEnable - Security options
*
* @return afStatus_t
*/
afStatus_t ZDP_MgmtNwkUpdateNotify( uint8 TransSeq, zAddrType_t *dstAddr,
uint8 status, uint32 scannedChannels,
uint16 totalTransmissions, uint16 transmissionFailures,
uint8 listCount, uint8 *energyValues, uint8 txOptions,
uint8 securityEnable )
{
uint8 *buf;
uint8 *pBuf;
uint8 len;
(void)securityEnable; // Intentionally unreferenced parameter
// Status + ScannedChannels + totalTransmissions + transmissionFailures + ListCount + energyValues
len = 1 + 4 + 2 + 2 + 1 + listCount;
buf = osal_mem_alloc( len+1 ); // +1 for transaction ID
if ( buf == NULL )
{
return afStatus_MEM_FAIL;
}
pBuf = buf+1;
*pBuf++ = status;
pBuf = osal_buffer_uint32( pBuf, scannedChannels );
*pBuf++ = LO_UINT16( totalTransmissions );
*pBuf++ = HI_UINT16( totalTransmissions );
*pBuf++ = LO_UINT16( transmissionFailures );
*pBuf++ = HI_UINT16( transmissionFailures );
*pBuf++ = listCount;
if ( listCount > 0 )
osal_memcpy( pBuf, energyValues, listCount );
FillAndSendBufferTxOptions( &TransSeq, dstAddr, Mgmt_NWK_Update_notify, len, buf, txOptions );
}
/*********************************************************************
* Functions to register for ZDO Over-the-air messages
*/
/*********************************************************************
* @fn ZDO_RegisterForZDOMsg
*
* @brief Call this function to register of an incoming over
* the air ZDO message - probably a response message
* but requests can also be received.
* Messages are delivered to the task with ZDO_CB_MSG
* as the message ID.
*
* @param taskID - Where you would like the message delivered
* @param clusterID - What message?
*
* @return ZSuccess - successful, ZMemError if not
*/
ZStatus_t ZDO_RegisterForZDOMsg( uint8 taskID, uint16 clusterID )
{
ZDO_MsgCB_t *pList;
ZDO_MsgCB_t *pLast;
ZDO_MsgCB_t *pNew;
// Look for duplicate
pList = pLast = zdoMsgCBs;
while ( pList )
{
if ( pList->taskID == taskID && pList->clusterID == clusterID )
return ( ZSuccess );
pLast = pList;
pList = (ZDO_MsgCB_t *)pList->next;
}
// Add to the list
pNew = (ZDO_MsgCB_t *)osal_mem_alloc( sizeof ( ZDO_MsgCB_t ) );
if ( pNew )
{
pNew->taskID = taskID;
pNew->clusterID = clusterID;
pNew->next = NULL;
if ( zdoMsgCBs )
{
pLast->next = pNew;
}
else
zdoMsgCBs = pNew;
return ( ZSuccess );
}
else
return ( ZMemError );
}
/*********************************************************************
* @fn ZDO_RemoveRegisteredCB
*
* @brief Call this function if you don't want to receive the
* incoming message.
*
* @param taskID - Where the messages are being delivered.
* @param clusterID - What message?
*
* @return ZSuccess - successful, ZFailure if not found
*/
ZStatus_t ZDO_RemoveRegisteredCB( uint8 taskID, uint16 clusterID )
{
ZDO_MsgCB_t *pList;
ZDO_MsgCB_t *pLast = NULL;
pList = zdoMsgCBs;
while ( pList )
{
if ( pList->taskID == taskID && pList->clusterID == clusterID )
{
if ( pLast )
{
// remove this one from the linked list
pLast->next = pList->next;
}
else if ( pList->next )
{
// remove the first one from the linked list
zdoMsgCBs = pList->next;
}
else
{
// remove the only item from the list
zdoMsgCBs = (ZDO_MsgCB_t *)NULL;
}
osal_mem_free( pList );
return ( ZSuccess );
}
pLast = pList;
pList = pList->next;
}
return ( ZFailure );
}
/*********************************************************************
* @fn ZDO_SendMsgCBs
*
* @brief This function sends messages to registered tasks.
* Local to ZDO and shouldn't be called outside of ZDO.
*
* @param inMsg - incoming message
*
* @return TRUE if sent to at least 1 task, FALSE if not
*/
uint8 ZDO_SendMsgCBs( zdoIncomingMsg_t *inMsg )
{
uint8 ret = FALSE;
ZDO_MsgCB_t *pList = zdoMsgCBs;
while ( pList )
{
if ( pList->clusterID == inMsg->clusterID )
{
zdoIncomingMsg_t *msgPtr;
// Send the address to the task
msgPtr = (zdoIncomingMsg_t *)osal_msg_allocate( sizeof( zdoIncomingMsg_t ) + inMsg->asduLen );
if ( msgPtr )
{
// copy struct
osal_memcpy( msgPtr, inMsg, sizeof( zdoIncomingMsg_t ));
if ( inMsg->asduLen )
{
msgPtr->asdu = (byte*)(((byte*)msgPtr) + sizeof( zdoIncomingMsg_t ));
osal_memcpy( msgPtr->asdu, inMsg->asdu, inMsg->asduLen );
}
msgPtr->hdr.event = ZDO_CB_MSG;
osal_msg_send( pList->taskID, (uint8 *)msgPtr );
ret = TRUE;
}
}
pList = (ZDO_MsgCB_t *)pList->next;
}
return ( ret );
}
/*********************************************************************
* Incoming message processor
*/
/*********************************************************************
* @fn ZDP_IncomingData
*
* @brief This function indicates the transfer of a data PDU (ASDU)
* from the APS sub-layer to the ZDO.
*
* @param pData - Incoming Message
*
* @return none
*/
void ZDP_IncomingData( afIncomingMSGPacket_t *pData )
{
uint8 x = 0;
uint8 handled;
zdoIncomingMsg_t inMsg;
inMsg.srcAddr.addrMode = Addr16Bit;
inMsg.srcAddr.addr.shortAddr = pData->srcAddr.addr.shortAddr;
inMsg.wasBroadcast = pData->wasBroadcast;
inMsg.clusterID = pData->clusterId;
inMsg.SecurityUse = pData->SecurityUse;
inMsg.asduLen = pData->cmd.DataLength-1;
inMsg.asdu = pData->cmd.Data+1;
inMsg.TransSeq = pData->cmd.Data[0];
inMsg.macDestAddr = pData->macDestAddr;
handled = ZDO_SendMsgCBs( &inMsg );
#if (defined MT_ZDO_CB_FUNC)
#if !defined MT_TASK
if (zgZdoDirectCB)
#endif
{
MT_ZdoDirectCB( pData, &inMsg );
}
#endif
while ( zdpMsgProcs[x].clusterID != 0xFFFF )
{
if ( zdpMsgProcs[x].clusterID == inMsg.clusterID )
{
zdpMsgProcs[x].pFn( &inMsg );
return;
}
x++;
}
// Handle unhandled messages
if ( !handled )
ZDApp_InMsgCB( &inMsg );
}
/*********************************************************************
*********************************************************************/
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