int wlan_eth_setup_interrupt(XIntc* intc){
	Intc_ptr = intc;
	XAxiDma_BdRing *RxRingPtr = XAxiDma_GetRxRing(&ETH_A_DMA_Instance);
	int Status;

	Status = XIntc_Connect(Intc_ptr, RX_INTR_ID,(XInterruptHandler) RxIntrHandler, RxRingPtr);
	if (Status != XST_SUCCESS) {

		xil_printf("Failed tx connect intc\r\n");
		return XST_FAILURE;
	}

	XIntc_Enable(Intc_ptr, RX_INTR_ID);



	return 0;
}
void wlan_poll_eth() {
	XAxiDma_BdRing *rxRing_ptr;
	XAxiDma_Bd *cur_bd_ptr;
	XAxiDma_Bd *first_bd_ptr;
	u8* mpdu_start_ptr;
	u8* eth_start_ptr;
	u8* eth_mid_ptr;
	packet_bd* tx_queue;
	u32 eth_rx_len, eth_rx_buf;
	u32 mpdu_tx_len;
	packet_bd_list tx_queue_list;
	u32 i;
	u8 continue_loop;

	int bd_count;
	int status;
	int packet_is_queued;

	ethernet_header* eth_hdr;
	ipv4_header* ip_hdr;
	arp_packet* arp;
	udp_header* udp;
	dhcp_packet* dhcp;

	llc_header* llc_hdr;
	u8 eth_dest[6];
	u8 eth_src[6];

	static u32 max_bd_count = 0;

	rxRing_ptr = XAxiDma_GetRxRing(&ETH_A_DMA_Instance);

	//Check if any Rx BDs have been executed
	//TODO: process XAXIDMA_ALL_BDS instead of 1 at a time
	//bd_count = XAxiDma_BdRingFromHw(rxRing_ptr, 1, &cur_bd_ptr);
	bd_count = XAxiDma_BdRingFromHw(rxRing_ptr, XAXIDMA_ALL_BDS, &first_bd_ptr);
	cur_bd_ptr = first_bd_ptr;

	if(bd_count > max_bd_count){
		max_bd_count = bd_count;
		//xil_printf("max_bd_count = %d\n",max_bd_count);
	}

	if(bd_count == 0) {
		//No Rx BDs have been processed - no new Eth receptions waiting
		return;
	}

	for(i=0;i<bd_count;i++){

		//A packet has been received and transferred by DMA
		tx_queue = (packet_bd*)XAxiDma_BdGetId(cur_bd_ptr);

		//xil_printf("DMA has filled in packet_bd at 0x%08x\n", tx_queue);

		eth_rx_len = XAxiDma_BdGetActualLength(cur_bd_ptr, rxRing_ptr->MaxTransferLen);
		eth_rx_buf = XAxiDma_BdGetBufAddr(cur_bd_ptr);

		//After encapsulation, byte[0] of the MPDU will be at byte[0] of the queue entry frame buffer
		mpdu_start_ptr = (void*)((tx_packet_buffer*)(tx_queue->buf_ptr))->frame;

		eth_start_ptr = (u8*)eth_rx_buf;

		//Calculate actual wireless Tx len (eth payload - eth header + wireless header)
		mpdu_tx_len = eth_rx_len - sizeof(ethernet_header) + sizeof(llc_header) + sizeof(mac_header_80211);

		//Helper pointers to interpret/fill fields in the new MPDU
		eth_hdr = (ethernet_header*)eth_start_ptr;
		llc_hdr = (llc_header*)(mpdu_start_ptr + sizeof(mac_header_80211));

		//Copy the src/dest addresses from the received Eth packet to temp space
		memcpy(eth_src, eth_hdr->address_source, 6);
		memcpy(eth_dest, eth_hdr->address_destination, 6);

		//Prepare the MPDU LLC header
		llc_hdr->dsap = LLC_SNAP;
		llc_hdr->ssap = LLC_SNAP;
		llc_hdr->control_field = LLC_CNTRL_UNNUMBERED;
		bzero((void *)(llc_hdr->org_code), 3); //Org Code 0x000000: Encapsulated Ethernet

		packet_is_queued = 0;
		packet_bd_list tx_queue_list;
		packet_bd_list_init(&tx_queue_list);
		packet_bd_insertEnd(&tx_queue_list, tx_queue);

		switch(eth_encap_mode){
			case ENCAP_MODE_AP:

				switch(eth_hdr->type) {
					case ETH_TYPE_ARP:
						llc_hdr->type = LLC_TYPE_ARP;
						packet_is_queued = eth_rx_callback(&tx_queue_list, eth_dest, eth_src, mpdu_tx_len);
					break;
					case ETH_TYPE_IP:
						llc_hdr->type = LLC_TYPE_IP;
						packet_is_queued = eth_rx_callback(&tx_queue_list, eth_dest, eth_src, mpdu_tx_len);
					break;

					/* WMP_START */
					case WMP4WARP_ETHER_TYPE:
						wmp_high_util_handle_wmp_cmd_from_ethernet(eth_hdr);
					break;
					/* WMP_END */
					default:
						//Unknown/unsupported EtherType; don't process the Eth frame
					break;
				}

			break;

			case ENCAP_MODE_STA:

				//Save this ethernet src address for d
				memcpy(eth_sta_mac_addr, eth_src, 6);
				memcpy(eth_src, hw_info.hw_addr_wlan, 6);

				switch(eth_hdr->type) {
					case ETH_TYPE_ARP:
						arp = (arp_packet*)((void*)eth_hdr + sizeof(ethernet_header));

						//Here we hijack ARP messages and overwrite their source MAC address field with
						//the station's wireless MAC address.
						memcpy(arp->eth_src, hw_info.hw_addr_wlan, 6);

						llc_hdr->type = LLC_TYPE_ARP;
						packet_is_queued = eth_rx_callback(&tx_queue_list, eth_dest, eth_src, mpdu_tx_len);


					break;
					case ETH_TYPE_IP:
						llc_hdr->type = LLC_TYPE_IP;
						ip_hdr = (ipv4_header*)((void*)eth_hdr + sizeof(ethernet_header));

						if(ip_hdr->prot == IPV4_PROT_UDP){
							udp = (udp_header*)((void*)ip_hdr + 4*((u8)(ip_hdr->ver_ihl) & 0xF));
							udp->checksum = 0; //Disable the checksum since we are about to mess with the bytes in the packet

							if(Xil_Ntohs(udp->src_port) == UDP_SRC_PORT_BOOTPC || Xil_Ntohs(udp->src_port) == UDP_SRC_PORT_BOOTPS){
								//This is a DHCP Discover packet, which contains the source hardware address
								//deep inside the packet (in addition to its usual location in the Eth header).
								//For STA encapsulation, we need to overwrite this address with the MAC addr
								//of the wireless station.

								dhcp = (dhcp_packet*)((void*)udp + sizeof(udp_header));

								if(Xil_Ntohl(dhcp->magic_cookie) == DHCP_MAGIC_COOKIE){
									eth_mid_ptr = (u8*)((void*)dhcp + sizeof(dhcp_packet));

									dhcp->flags = Xil_Htons(DHCP_BOOTP_FLAGS_BROADCAST);

									//Tagged DHCP Options
									continue_loop = 1;

									while(continue_loop){
										switch(eth_mid_ptr[0]){

											case DHCP_OPTION_TAG_TYPE:
												switch(eth_mid_ptr[2]){
													case DHCP_OPTION_TYPE_DISCOVER:
													case DHCP_OPTION_TYPE_REQUEST:
														//memcpy(dhcp->chaddr,hw_info.hw_addr_wlan,6);
													break;

												}

											break;

											case DHCP_OPTION_TAG_IDENTIFIER:
												//memcpy(&(eth_mid_ptr[3]),hw_info.hw_addr_wlan,6);

											break;

											case DHCP_OPTION_END:
												continue_loop = 0;
											break;
										}
										eth_mid_ptr += (2+eth_mid_ptr[1]);
									}
								}
							}
						}
						packet_is_queued = eth_rx_callback(&tx_queue_list, eth_dest, eth_src, mpdu_tx_len);

					break;

					/* WMP_START */
					case WMP4WARP_ETHER_TYPE:{
						wmp_high_util_handle_wmp_cmd_from_ethernet(eth_hdr);
					break;}
					/* WMP_END */
					default:
						//Unknown/unsupported EtherType; don't process the Eth frame
					break;
			}

			break;

		}

		if(packet_is_queued == 0){
			//xil_printf("   ...checking in\n");
			queue_checkin(&tx_queue_list);
		}

		//TODO: Option A: We free this single BD and run the routine to checkout as many queues as we can and hook them up to BDs
		//Results: pretty good TCP performance
		//Free this bd
		status = XAxiDma_BdRingFree(rxRing_ptr, 1, cur_bd_ptr);
		if(status != XST_SUCCESS) {xil_printf("Error in XAxiDma_BdRingFree of Rx BD! Err = %d\n", status); return;}
		wlan_eth_dma_update();

		//Update cur_bd_ptr to the next BD in the chain for the next iteration
		cur_bd_ptr = XAxiDma_BdRingNext(rxRing_ptr, cur_bd_ptr);

	}
	//TODO: Option B: We free all BDs at once and run the routine to checkout as many queues as we can and hook them up to BDs
	//Results: pretty lackluster TCP performance. needs further investigation
	//Free this bd
	//status = XAxiDma_BdRingFree(rxRing_ptr, bd_count, first_bd_ptr);
	//if(status != XST_SUCCESS) {xil_printf("Error in XAxiDma_BdRingFree of Rx BD! Err = %d\n", status); return;}
	//wlan_eth_dma_update();

	return;
}
void wlan_eth_dma_update(){
	//Used to submit new BDs to the DMA hardware if space is available
	int bd_count;
	int status;
	XAxiDma_BdRing *ETH_A_RxRing_ptr;
	XAxiDma_Bd *first_bd_ptr;
	XAxiDma_Bd *cur_bd_ptr;
	packet_bd_list checkout;
	packet_bd*	tx_queue;
	u32 i;
	u32 buf_addr;
	u32 num_available_packet_bd;

	ETH_A_RxRing_ptr = XAxiDma_GetRxRing(&ETH_A_DMA_Instance);
	bd_count = XAxiDma_BdRingGetFreeCnt(ETH_A_RxRing_ptr);

	num_available_packet_bd = queue_num_free();

	if(min(num_available_packet_bd,bd_count)>0){
//		xil_printf("%d BDs are free\n",bd_count);
//		xil_printf("%d packet_bds are free\n", num_available_packet_bd);
//		xil_printf("Attaching %d BDs to packet_bds\n",min(bd_count,num_available_packet_bd));

		//Checkout ETH_A_NUM_RX_BD packet_bds
		queue_checkout(&checkout, min(bd_count,num_available_packet_bd));

		status = XAxiDma_BdRingAlloc(ETH_A_RxRing_ptr, min(bd_count,checkout.length), &first_bd_ptr);
		if(status != XST_SUCCESS) {xil_printf("Error in XAxiDma_BdRingAlloc()! Err = %d\n", status); return;}

		tx_queue = checkout.first;

		//Iterate over each Rx buffer descriptor
		cur_bd_ptr = first_bd_ptr;
		for(i = 0; i < min(bd_count,checkout.length); i++) {
			//Set the memory address for this BD's buffer
			buf_addr = (u32)((void*)((tx_packet_buffer*)(tx_queue->buf_ptr))->frame + sizeof(mac_header_80211) + sizeof(llc_header) - sizeof(ethernet_header));

			status = XAxiDma_BdSetBufAddr(cur_bd_ptr, buf_addr);
			if(status != XST_SUCCESS) {xil_printf("XAxiDma_BdSetBufAddr failed (bd %d, addr 0x08x)! Err = %d\n", i, buf_addr, status); return;}

			//Set every Rx BD to max length (this assures 1 BD per Rx pkt)
			status = XAxiDma_BdSetLength(cur_bd_ptr, ETH_A_PKT_BUF_SIZE, ETH_A_RxRing_ptr->MaxTransferLen);
			if(status != XST_SUCCESS) {xil_printf("XAxiDma_BdSetLength failed (bd %d, addr 0x08x)! Err = %d\n", i, buf_addr, status); return;}

			//Rx BD's don't need control flags before use; DMA populates these post-Rx
			XAxiDma_BdSetCtrl(cur_bd_ptr, 0);

			//BD ID is arbitrary; use pointer to the packet_bd associated with this BD
			XAxiDma_BdSetId(cur_bd_ptr, (u32)tx_queue);

			//Update cur_bd_ptr to the next BD in the chain for the next iteration
			cur_bd_ptr = XAxiDma_BdRingNext(ETH_A_RxRing_ptr, cur_bd_ptr);

			//Remove this tx_queue from the checkout list
			//packet_bd_remove(&checkout,tx_queue);

			//Traverse forward in the checked-out packet_bd list
			tx_queue = tx_queue->next;
		}

		//Push the Rx BD ring to hardware and start receiving
		status = XAxiDma_BdRingToHw(ETH_A_RxRing_ptr, min(num_available_packet_bd,bd_count), first_bd_ptr);

		//Check any remaining unused entries from the checkout list back in
		//queue_checkin(&checkout);

	}
	return;
}
/**
*
* This function waits until the DMA transaction is finished, checks data,
* and cleans up.
*
* @return   - XST_SUCCESS if DMA transfer is successful and data is correct,
*           - XST_FAILURE otherwise.
*
* @note     None.
*
******************************************************************************/
static int CheckDmaResult(XAxiDma * AxiDmaInstPtr)
{
	XAxiDma_BdRing *TxRingPtr;
	XAxiDma_BdRing *RxRingPtr;
	XAxiDma_Bd *BdPtr;
	int ProcessedBdCount;
	int FreeBdCount;
	int Status;

	TxRingPtr = XAxiDma_GetTxRing(AxiDmaInstPtr);
	RxRingPtr = XAxiDma_GetRxRing(AxiDmaInstPtr);

	/* Wait until the one BD TX transaction is done */
	while ((ProcessedBdCount = XAxiDma_BdRingFromHw(TxRingPtr,
						       XAXIDMA_ALL_BDS,
						       &BdPtr)) == 0) {
	}

	/* Free all processed TX BDs for future transmission */
	Status = XAxiDma_BdRingFree(TxRingPtr, ProcessedBdCount, BdPtr);
	if (Status != XST_SUCCESS) {
		xdbg_printf(XDBG_DEBUG_ERROR,
		    "Failed to free %d tx BDs %d\r\n",
		    ProcessedBdCount, Status);
		return XST_FAILURE;
	}

	/* Wait until the data has been received by the Rx channel */
	while ((ProcessedBdCount = XAxiDma_BdRingFromHw(RxRingPtr,
						       XAXIDMA_ALL_BDS,
						       &BdPtr)) == 0) {
	}

	/* Check received data */
	if (CheckData() != XST_SUCCESS) {

		return XST_FAILURE;
	}

	/* Free all processed RX BDs for future transmission */
	Status = XAxiDma_BdRingFree(RxRingPtr, ProcessedBdCount, BdPtr);
	if (Status != XST_SUCCESS) {
		xdbg_printf(XDBG_DEBUG_ERROR,
		    "Failed to free %d rx BDs %d\r\n",
		    ProcessedBdCount, Status);
		return XST_FAILURE;
	}

	/* Return processed BDs to RX channel so we are ready to receive new
	 * packets:
	 *    - Allocate all free RX BDs
	 *    - Pass the BDs to RX channel
	 */
	FreeBdCount = XAxiDma_BdRingGetFreeCnt(RxRingPtr);
	Status = XAxiDma_BdRingAlloc(RxRingPtr, FreeBdCount, &BdPtr);
	if (Status != XST_SUCCESS) {
		xdbg_printf(XDBG_DEBUG_ERROR, "bd alloc failed\r\n");
		return XST_FAILURE;
	}

	Status = XAxiDma_BdRingToHw(RxRingPtr, FreeBdCount, BdPtr);
	if (Status != XST_SUCCESS) {
		xdbg_printf(XDBG_DEBUG_ERROR,
		    "Submit %d rx BDs failed %d\r\n", FreeBdCount, Status);
		return XST_FAILURE;
	}

	return XST_SUCCESS;
}
int wlan_eth_dma_init() {
	int status;
	int bd_count;
	int i;
	u32 buf_addr;

	XAxiDma_Config *ETH_A_DMA_CFG_ptr;

	XAxiDma_Bd ETH_DMA_BD_Template;
	XAxiDma_BdRing *ETH_A_TxRing_ptr;
	XAxiDma_BdRing *ETH_A_RxRing_ptr;

	XAxiDma_Bd *first_bd_ptr;
	XAxiDma_Bd *cur_bd_ptr;

	packet_bd_list checkout;
	packet_bd*	tx_queue;

	ETH_A_DMA_CFG_ptr = XAxiDma_LookupConfig(ETH_A_DMA_DEV_ID);
	status = XAxiDma_CfgInitialize(&ETH_A_DMA_Instance, ETH_A_DMA_CFG_ptr);
	if(status != XST_SUCCESS) {xil_printf("Error in XAxiDma_CfgInitialize! Err = %d\n", status); return -1;}

	//Zero-out the template buffer descriptor
	XAxiDma_BdClear(&ETH_DMA_BD_Template);

	//Fetch handles to the Tx and Rx BD rings
	ETH_A_TxRing_ptr = XAxiDma_GetTxRing(&ETH_A_DMA_Instance);
	ETH_A_RxRing_ptr = XAxiDma_GetRxRing(&ETH_A_DMA_Instance);

	//Disable all Tx/Rx DMA interrupts
	XAxiDma_BdRingIntDisable(ETH_A_TxRing_ptr, XAXIDMA_IRQ_ALL_MASK);
	XAxiDma_BdRingIntDisable(ETH_A_RxRing_ptr, XAXIDMA_IRQ_ALL_MASK);

	//Disable delays and coalescing (for now - these will be useful when we transition to interrupts)
	XAxiDma_BdRingSetCoalesce(ETH_A_TxRing_ptr, 1, 0);
	XAxiDma_BdRingSetCoalesce(ETH_A_RxRing_ptr, 1, 0);

	//Setup Tx/Rx buffer descriptor rings in memory
	status =  XAxiDma_BdRingCreate(ETH_A_TxRing_ptr, ETH_A_TX_BD_SPACE_BASE, ETH_A_TX_BD_SPACE_BASE, XAXIDMA_BD_MINIMUM_ALIGNMENT, ETH_A_NUM_TX_BD);
	status |= XAxiDma_BdRingCreate(ETH_A_RxRing_ptr, ETH_A_RX_BD_SPACE_BASE, ETH_A_RX_BD_SPACE_BASE, XAXIDMA_BD_MINIMUM_ALIGNMENT, ETH_A_NUM_RX_BD);
	if(status != XST_SUCCESS) {xil_printf("Error creating DMA BD Rings! Err = %d\n", status); return -1;}

	//Populate each ring with empty buffer descriptors
	status =  XAxiDma_BdRingClone(ETH_A_TxRing_ptr, &ETH_DMA_BD_Template);
	status |= XAxiDma_BdRingClone(ETH_A_RxRing_ptr, &ETH_DMA_BD_Template);
	if(status != XST_SUCCESS) {xil_printf("Error in XAxiDma_BdRingClone()! Err = %d\n", status); return -1;}

	//Start the DMA Tx channel
	// No Eth packets are transmitted until actual Tx BD's are pushed to the DMA hardware
	status = XAxiDma_BdRingStart(ETH_A_TxRing_ptr);

	//Initialize the Rx buffer descriptors
	bd_count = XAxiDma_BdRingGetFreeCnt(ETH_A_RxRing_ptr);
	if(bd_count != ETH_A_NUM_RX_BD) {xil_printf("Error in Eth Rx DMA init - not all Rx BDs were free at boot\n");}

	status = XAxiDma_BdRingAlloc(ETH_A_RxRing_ptr, bd_count, &first_bd_ptr);
	if(status != XST_SUCCESS) {xil_printf("Error in XAxiDma_BdRingAlloc()! Err = %d\n", status); return -1;}

	//Checkout ETH_A_NUM_RX_BD packet_bds
	queue_checkout(&checkout, ETH_A_NUM_RX_BD);

	if(checkout.length == ETH_A_NUM_RX_BD){
		tx_queue = checkout.first;
	} else {
		xil_printf("Error during wlan_eth_dma_init: able to check out %d of %d packet_bds\n", checkout.length, ETH_A_NUM_RX_BD);
		return -1;
	}

	//Iterate over each Rx buffer descriptor
	cur_bd_ptr = first_bd_ptr;
	for(i = 0; i < bd_count; i++) {
		//Set the memory address for this BD's buffer
		buf_addr = (u32)((void*)((tx_packet_buffer*)(tx_queue->buf_ptr))->frame + sizeof(mac_header_80211) + sizeof(llc_header) - sizeof(ethernet_header));

		status = XAxiDma_BdSetBufAddr(cur_bd_ptr, buf_addr);
		if(status != XST_SUCCESS) {xil_printf("XAxiDma_BdSetBufAddr failed (bd %d, addr 0x08x)! Err = %d\n", i, buf_addr, status); return -1;}

		//Set every Rx BD to max length (this assures 1 BD per Rx pkt)
		status = XAxiDma_BdSetLength(cur_bd_ptr, ETH_A_PKT_BUF_SIZE, ETH_A_RxRing_ptr->MaxTransferLen);
		if(status != XST_SUCCESS) {xil_printf("XAxiDma_BdSetLength failed (bd %d, addr 0x08x)! Err = %d\n", i, buf_addr, status); return -1;}

		//Rx BD's don't need control flags before use; DMA populates these post-Rx
		XAxiDma_BdSetCtrl(cur_bd_ptr, 0);

		//BD ID is arbitrary; use pointer to the packet_bd associated with this BD
		XAxiDma_BdSetId(cur_bd_ptr, (u32)tx_queue);

		//Update cur_bd_ptr to the next BD in the chain for the next iteration
		cur_bd_ptr = XAxiDma_BdRingNext(ETH_A_RxRing_ptr, cur_bd_ptr);

		//Traverse forward in the checked-out packet_bd list
		tx_queue = tx_queue->next;
	}

	//Push the Rx BD ring to hardware and start receiving
	status = XAxiDma_BdRingToHw(ETH_A_RxRing_ptr, bd_count, first_bd_ptr);

	//Enable Interrupts
	XAxiDma_BdRingIntEnable(ETH_A_RxRing_ptr, XAXIDMA_IRQ_ALL_MASK);

	status |= XAxiDma_BdRingStart(ETH_A_RxRing_ptr);
	if(status != XST_SUCCESS) {xil_printf("Error in XAxiDma_BdRingToHw/XAxiDma_BdRingStart(ETH_A_RxRing_ptr)! Err = %d\n", status); return -1;}

	return 0;
}
/**
*
* This function sets up RX channel of the DMA engine to be ready for packet
* reception
*
* @param    AxiDmaInstPtr is the pointer to the instance of the DMA engine.
*
* @return   XST_SUCCESS if the setup is successful, XST_FAILURE otherwise.
*
* @note     None.
*
******************************************************************************/
static int RxSetup(XAxiDma * AxiDmaInstPtr)
{
	XAxiDma_BdRing *RxRingPtr;
	int Delay = 0;
	int Coalesce = 1;
	int Status;
	XAxiDma_Bd BdTemplate;
	XAxiDma_Bd *BdPtr;
	XAxiDma_Bd *BdCurPtr;
	u32 BdCount;
	u32 FreeBdCount;
	u32 RxBufferPtr;
	int i;

	RxRingPtr = XAxiDma_GetRxRing(&AxiDma);

	/* Disable all RX interrupts before RxBD space setup */

	XAxiDma_BdRingIntDisable(RxRingPtr, XAXIDMA_IRQ_ALL_MASK);

	/* Set delay and coalescing */
	XAxiDma_BdRingSetCoalesce(RxRingPtr, Coalesce, Delay);

	/* Setup Rx BD space */
	BdCount = XAxiDma_BdRingCntCalc(XAXIDMA_BD_MINIMUM_ALIGNMENT,
					RX_BD_SPACE_HIGH - RX_BD_SPACE_BASE + 1);

	Status = XAxiDma_BdRingCreate(RxRingPtr, RX_BD_SPACE_BASE,
				     RX_BD_SPACE_BASE,
				     XAXIDMA_BD_MINIMUM_ALIGNMENT, BdCount);

	if (Status != XST_SUCCESS) {
		xdbg_printf(XDBG_DEBUG_ERROR,
		    "RX create BD ring failed %d\r\n", Status);

		return XST_FAILURE;
	}

	/*
	 * Setup an all-zero BD as the template for the Rx channel.
	 */
	XAxiDma_BdClear(&BdTemplate);

	Status = XAxiDma_BdRingClone(RxRingPtr, &BdTemplate);
	if (Status != XST_SUCCESS) {
		xdbg_printf(XDBG_DEBUG_ERROR,
		    "RX clone BD failed %d\r\n", Status);

		return XST_FAILURE;
	}

	/* Attach buffers to RxBD ring so we are ready to receive packets */

	FreeBdCount = XAxiDma_BdRingGetFreeCnt(RxRingPtr);

	Status = XAxiDma_BdRingAlloc(RxRingPtr, FreeBdCount, &BdPtr);
	if (Status != XST_SUCCESS) {
		xdbg_printf(XDBG_DEBUG_ERROR,
		    "RX alloc BD failed %d\r\n", Status);

		return XST_FAILURE;
	}

	BdCurPtr = BdPtr;
	RxBufferPtr = RX_BUFFER_BASE;
	for (i = 0; i < FreeBdCount; i++) {
		Status = XAxiDma_BdSetBufAddr(BdCurPtr, RxBufferPtr);

		if (Status != XST_SUCCESS) {
			xdbg_printf(XDBG_DEBUG_ERROR,
			    "Set buffer addr %x on BD %x failed %d\r\n",
			    (unsigned int)RxBufferPtr,
			    (unsigned int)BdCurPtr, Status);

			return XST_FAILURE;
		}

		Status = XAxiDma_BdSetLength(BdCurPtr, MAX_PKT_LEN);
		if (Status != XST_SUCCESS) {
			xdbg_printf(XDBG_DEBUG_ERROR,
			    "Rx set length %d on BD %x failed %d\r\n",
			    MAX_PKT_LEN, (unsigned int)BdCurPtr, Status);

			return XST_FAILURE;
		}

		/* Receive BDs do not need to set anything for the control
		 * The hardware will set the SOF/EOF bits per stream status 
		 */
		XAxiDma_BdSetCtrl(BdCurPtr, 0);
		XAxiDma_BdSetId(BdCurPtr, RxBufferPtr);
	
		RxBufferPtr += MAX_PKT_LEN;
		BdCurPtr = XAxiDma_BdRingNext(RxRingPtr, BdCurPtr);
	}

	/* Clear the receive buffer, so we can verify data
	 */
	memset((void *)RX_BUFFER_BASE, 0, MAX_PKT_LEN); 

	Status = XAxiDma_BdRingToHw(RxRingPtr, FreeBdCount, BdPtr);
	if (Status != XST_SUCCESS) {
		xdbg_printf(XDBG_DEBUG_ERROR,
		    "RX submit hw failed %d\r\n", Status);

		return XST_FAILURE;
	}

	/* Start RX DMA channel */
	Status = XAxiDma_BdRingStart(RxRingPtr);
	if (Status != XST_SUCCESS) {
		xdbg_printf(XDBG_DEBUG_ERROR,
		    "RX start hw failed %d\r\n", Status);

		return XST_FAILURE;
	}

	return XST_SUCCESS;
}
/*
*
* This function sets up RX channel of the DMA engine to be ready for packet
* reception
*
* @param	AxiDmaInstPtr is the pointer to the instance of the DMA engine.
*
* @return	- XST_SUCCESS if the setup is successful.
*		- XST_FAILURE if fails.
*
* @note		None.
*
******************************************************************************/
static int RxSetup(XAxiDma * AxiDmaInstPtr)
{
	XAxiDma_BdRing *RxRingPtr;
	int Status;
	XAxiDma_Bd BdTemplate;
	XAxiDma_Bd *BdPtr;
	XAxiDma_Bd *BdCurPtr;
	int BdCount;
	int FreeBdCount;
	u32 RxBufferPtr;
	int Index;

	RxRingPtr = XAxiDma_GetRxRing(&AxiDma);

	/* Disable all RX interrupts before RxBD space setup */
	XAxiDma_BdRingIntDisable(RxRingPtr, XAXIDMA_IRQ_ALL_MASK);

	/* Setup Rx BD space */
	BdCount = XAxiDma_BdRingCntCalc(XAXIDMA_BD_MINIMUM_ALIGNMENT,
				RX_BD_SPACE_HIGH - RX_BD_SPACE_BASE + 1);

	Status = XAxiDma_BdRingCreate(RxRingPtr, RX_BD_SPACE_BASE,
					RX_BD_SPACE_BASE,
					XAXIDMA_BD_MINIMUM_ALIGNMENT, BdCount);
	if (Status != XST_SUCCESS) {
		xil_printf("Rx bd create failed with %d\r\n", Status);
		return XST_FAILURE;
	}

	/*
	 * Setup a BD template for the Rx channel. Then copy it to every RX BD.
	 */
	XAxiDma_BdClear(&BdTemplate);
	Status = XAxiDma_BdRingClone(RxRingPtr, &BdTemplate);
	if (Status != XST_SUCCESS) {
		xil_printf("Rx bd clone failed with %d\r\n", Status);
		return XST_FAILURE;
	}

	/* Attach buffers to RxBD ring so we are ready to receive packets */
	FreeBdCount = XAxiDma_BdRingGetFreeCnt(RxRingPtr);

	Status = XAxiDma_BdRingAlloc(RxRingPtr, FreeBdCount, &BdPtr);
	if (Status != XST_SUCCESS) {
		xil_printf("Rx bd alloc failed with %d\r\n", Status);
		return XST_FAILURE;
	}

	BdCurPtr = BdPtr;
	RxBufferPtr = RX_BUFFER_BASE;

	for (Index = 0; Index < FreeBdCount; Index++) {

		Status = XAxiDma_BdSetBufAddr(BdCurPtr, RxBufferPtr);
		if (Status != XST_SUCCESS) {
			xil_printf("Rx set buffer addr %x on BD %x failed %d\r\n",
			(unsigned int)RxBufferPtr,
			(unsigned int)BdCurPtr, Status);

			return XST_FAILURE;
		}

		Status = XAxiDma_BdSetLength(BdCurPtr, MAX_PKT_LEN,
					RxRingPtr->MaxTransferLen);
		if (Status != XST_SUCCESS) {
			xil_printf("Rx set length %d on BD %x failed %d\r\n",
			    MAX_PKT_LEN, (unsigned int)BdCurPtr, Status);

			return XST_FAILURE;
		}

		/* Receive BDs do not need to set anything for the control
		 * The hardware will set the SOF/EOF bits per stream status
		 */
		XAxiDma_BdSetCtrl(BdCurPtr, 0);

		XAxiDma_BdSetId(BdCurPtr, RxBufferPtr);

		RxBufferPtr += MAX_PKT_LEN;
		BdCurPtr = XAxiDma_BdRingNext(RxRingPtr, BdCurPtr);
	}

	/*
	 * Set the coalescing threshold, so only one receive interrupt
	 * occurs for this example
	 *
	 * If you would like to have multiple interrupts to happen, change
	 * the COALESCING_COUNT to be a smaller value
	 */
	Status = XAxiDma_BdRingSetCoalesce(RxRingPtr, COALESCING_COUNT,
			DELAY_TIMER_COUNT);
	if (Status != XST_SUCCESS) {
		xil_printf("Rx set coalesce failed with %d\r\n", Status);
		return XST_FAILURE;
	}

	Status = XAxiDma_BdRingToHw(RxRingPtr, FreeBdCount, BdPtr);
	if (Status != XST_SUCCESS) {
		xil_printf("Rx ToHw failed with %d\r\n", Status);
		return XST_FAILURE;
	}

	/* Enable all RX interrupts */
	XAxiDma_BdRingIntEnable(RxRingPtr, XAXIDMA_IRQ_ALL_MASK);

	/* Start RX DMA channel */
	Status = XAxiDma_BdRingStart(RxRingPtr);
	if (Status != XST_SUCCESS) {
		xil_printf("Rx start BD ring failed with %d\r\n", Status);
		return XST_FAILURE;
	}

	return XST_SUCCESS;
}
static int SetupIntrSystem(INTC * IntcInstancePtr,
			   XAxiDma * AxiDmaPtr, u16 TxIntrId, u16 RxIntrId)
{
	XAxiDma_BdRing *TxRingPtr = XAxiDma_GetTxRing(AxiDmaPtr);
	XAxiDma_BdRing *RxRingPtr = XAxiDma_GetRxRing(AxiDmaPtr);
	int Status;

#ifdef XPAR_INTC_0_DEVICE_ID

	/* Initialize the interrupt controller and connect the ISRs */
	Status = XIntc_Initialize(IntcInstancePtr, INTC_DEVICE_ID);
	if (Status != XST_SUCCESS) {

		xil_printf("Failed init intc\r\n");
		return XST_FAILURE;
	}

	Status = XIntc_Connect(IntcInstancePtr, TxIntrId,
			       (XInterruptHandler) TxIntrHandler, TxRingPtr);
	if (Status != XST_SUCCESS) {

		xil_printf("Failed tx connect intc\r\n");
		return XST_FAILURE;
	}

	Status = XIntc_Connect(IntcInstancePtr, RxIntrId,
			       (XInterruptHandler) RxIntrHandler, RxRingPtr);
	if (Status != XST_SUCCESS) {

		xil_printf("Failed rx connect intc\r\n");
		return XST_FAILURE;
	}

	/* Start the interrupt controller */
	Status = XIntc_Start(IntcInstancePtr, XIN_REAL_MODE);
	if (Status != XST_SUCCESS) {

		xil_printf("Failed to start intc\r\n");
		return XST_FAILURE;
	}

	XIntc_Enable(IntcInstancePtr, TxIntrId);
	XIntc_Enable(IntcInstancePtr, RxIntrId);

#else

	XScuGic_Config *IntcConfig;


	/*
	 * Initialize the interrupt controller driver so that it is ready to
	 * use.
	 */
	IntcConfig = XScuGic_LookupConfig(INTC_DEVICE_ID);
	if (NULL == IntcConfig) {
		return XST_FAILURE;
	}

	Status = XScuGic_CfgInitialize(IntcInstancePtr, IntcConfig,
					IntcConfig->CpuBaseAddress);
	if (Status != XST_SUCCESS) {
		return XST_FAILURE;
	}


	XScuGic_SetPriorityTriggerType(IntcInstancePtr, TxIntrId, 0xA0, 0x3);

	XScuGic_SetPriorityTriggerType(IntcInstancePtr, RxIntrId, 0xA0, 0x3);
	/*
	 * Connect the device driver handler that will be called when an
	 * interrupt for the device occurs, the handler defined above performs
	 * the specific interrupt processing for the device.
	 */
	Status = XScuGic_Connect(IntcInstancePtr, TxIntrId,
				(Xil_InterruptHandler)TxIntrHandler,
				TxRingPtr);
	if (Status != XST_SUCCESS) {
		return Status;
	}

	Status = XScuGic_Connect(IntcInstancePtr, RxIntrId,
				(Xil_InterruptHandler)RxIntrHandler,
				RxRingPtr);
	if (Status != XST_SUCCESS) {
		return Status;
	}

	XScuGic_Enable(IntcInstancePtr, TxIntrId);
	XScuGic_Enable(IntcInstancePtr, RxIntrId);
#endif

	/* Enable interrupts from the hardware */

	Xil_ExceptionInit();
	Xil_ExceptionRegisterHandler(XIL_EXCEPTION_ID_INT,
			(Xil_ExceptionHandler)INTC_HANDLER,
			(void *)IntcInstancePtr);

	Xil_ExceptionEnable();

	return XST_SUCCESS;
}
/**
*
* This example sends and receives a single packet in loopback mode with
* extended VLAN support.
*
* The transmit frame will have VLAN field populated.
*
* On receive, HW should pass the VLAN field to receive BDs.
*
* @param	AxiEthernetInstancePtr is a pointer to the instance of the
*		AxiEthernet component.
* @param	DmaInstancePtr   is a pointer to the instance of the Dma
*		component.
*
* @return	-XST_SUCCESS to indicate success.
*		-XST_FAILURE to indicate failure.
*
* @note		Summary of VLAN tags handling in this example
*
* Frame setup with Tpid1+Cfi1+TxPid => 0x88A83111
* Frame translated to TxTransVid => 0x88A83222
* Frame tagged to Tpid2+Cfi2+TxTagVid => 0x9100C333 + 0x88A83222
* Frame sent and loopbacked.
*
* Frame stripped with RxStrpVid(0x333) => 0x88A83222
* Frame translated (key:RxVid:0x222) RxTransVid => 0x88A83444
*
******************************************************************************/
int AxiEthernetSgDmaIntrExtVlanExample(XAxiEthernet *AxiEthernetInstancePtr,
				XAxiDma *DmaInstancePtr)
{
	int Status;
	u32 TxFrameLength;
	u32 RxFrameLength;
	int PayloadSize = PAYLOAD_SIZE;
	u16 Tpid1 = 0x88A8;
	u16 Tpid2 = 0x9100;
	u8  Cfi1  = 0x03;
	u8  Cfi2  = 0x0C;
	u16 TxVid      = 0x0111;
	u16 TxTransVid = 0x0222;
	u16 TxTagVid   = 0x0333;
	u16 RxVid      = 0x0222;
	u16 RxTransVid = 0x0444;
	u16 RxStrpVid  = 0x0333;
	u32 VTagCfiVid;
	u16 RxCfiVid;
	u16 RxTpid;
	u32 RxStatusControlWord;
	int Valid;


	XAxiDma_BdRing *RxRingPtr = XAxiDma_GetRxRing(DmaInstancePtr);
	XAxiDma_BdRing *TxRingPtr = XAxiDma_GetTxRing(DmaInstancePtr);
	XAxiDma_Bd *BdPtr;
	XAxiDma_Bd *BdCurPtr;
	u32 BdSts;

	/*
	 * Cannot run this example if extended features support is not enabled
	 */
	if (!(XAxiEthernet_IsTxVlanTran(AxiEthernetInstancePtr) &&
		XAxiEthernet_IsTxVlanStrp(AxiEthernetInstancePtr) &&
		XAxiEthernet_IsTxVlanTag(AxiEthernetInstancePtr)  &&
		XAxiEthernet_IsRxVlanTran(AxiEthernetInstancePtr) &&
		XAxiEthernet_IsRxVlanStrp(AxiEthernetInstancePtr) &&
		XAxiEthernet_IsRxVlanTag(AxiEthernetInstancePtr))) {
		AxiEthernetUtilErrorTrap("Extended VLAN not available");
		return XST_FAILURE;
	}

	/*
	 * Clear variables shared with callbacks
	 */
	FramesRx = 0;
	FramesTx = 0;
	DeviceErrors = 0;
	memset(RxFrame,0,sizeof(RxFrame));
	memset(TxFrame,0,sizeof(TxFrame));

	/*
	 * Calculate frame length (not including FCS) plus one VLAN tag
	 */
	TxFrameLength = XAE_HDR_VLAN_SIZE + PayloadSize;

	/*
	 * Setup the packet with one VALN tag = VtagCfiVid to be transmitted
	 * initially.
	 */
	VTagCfiVid = (((u32)Tpid1 << 16) | ((u32)Cfi1 << 12) | TxVid);
	AxiEthernetUtilFrameMemClear(&TxFrame);
	AxiEthernetUtilFrameHdrFormatMAC(&TxFrame, AxiEthernetMAC);
	AxiEthernetUtilFrameHdrVlanFormatVid(&TxFrame, 0, VTagCfiVid);
	AxiEthernetUtilFrameHdrVlanFormatType(&TxFrame, PayloadSize, 1);
	AxiEthernetUtilFrameSetVlanPayloadData(&TxFrame, PayloadSize, 1);

	/* Intended VLAN setup:
	 * TX translation and tagging. RX stripping and translation.
	 *
	 * Frame setup with Tpid1+Cfi1+TxPid => 0x88A83111
	 * Frame translated to TxTransVid => 0x88A83222
	 * Frame tagged to Tpid2+Cfi2+TxTagVid => 0x9100C333 + 0x88A83222
	 * Frame sent and loopbacked.
	 *
	 * Frame stripped with RxStrpVid(0x333) => 0x88A83222
	 * Frame translated (key:RxVid:0x222) RxTransVid => 0x88A83444
	 */

	/* Extended VLAN transmit side. Stripping->Translation->Tagging */
	/*
	 * Configure VLAN TX tag mode, set to XAE_VTAG_SELECT.
	 */
	Status  = XAxiEthernet_SetOptions(AxiEthernetInstancePtr,
						XAE_EXT_TXVLAN_TAG_OPTION);
	Status |= XAxiEthernet_SetVTagMode(AxiEthernetInstancePtr,
						XAE_VTAG_SELECT, XAE_TX);

	/*
	 * TX VLAN translation from TxVid to TxTransVid and enable tagging.
	 */
	Status |= XAxiEthernet_SetOptions(AxiEthernetInstancePtr,
						XAE_EXT_TXVLAN_TRAN_OPTION);
	Status |= XAxiEthernet_SetVidTable(AxiEthernetInstancePtr, TxVid,
						TxTransVid,0, 1, XAE_TX);

	/*
	 * TX VLAN tagging is keyed on TxVid to add one additional tag based
	 * on register XAE_TTAG_OFFSET value.
	 */
	VTagCfiVid = (((u32)Tpid2 << 16) | ((u32)Cfi2 << 12) | TxTagVid);
	Status |= XAxiEthernet_SetVTagValue(AxiEthernetInstancePtr,
							VTagCfiVid, XAE_TX);
	if (Status != XST_SUCCESS) {
		AxiEthernetUtilErrorTrap("Error setting TX VLAN");
		return XST_FAILURE;
	}

	/* Extended VLAN receive side. Stripping->Translation->Tagging */
	/*
	 * Configure VLAN RX strip mode, set to XAE_VSTRP_SELECT.
	 */
	Status = XAxiEthernet_SetOptions(AxiEthernetInstancePtr,
						XAE_EXT_RXVLAN_STRP_OPTION);
	Status |= XAxiEthernet_SetVStripMode(AxiEthernetInstancePtr,
						XAE_VSTRP_SELECT, XAE_RX);

	/*
	 * RX VLAN strips based on RxStrpVid and enable stripping.
	 */
	Status |= XAxiEthernet_SetVidTable(AxiEthernetInstancePtr, RxStrpVid,
						RxStrpVid, 1, 0, XAE_RX);

	/*
	 * RX VLAN translation from RxVid to RxTransVid only.
	 */
	Status |= XAxiEthernet_SetOptions(AxiEthernetInstancePtr,
						XAE_EXT_RXVLAN_TRAN_OPTION);
	Status |= XAxiEthernet_SetVidTable(AxiEthernetInstancePtr, RxVid,
						RxTransVid, 0, 0, XAE_RX);

	if (Status != XST_SUCCESS) {
		AxiEthernetUtilErrorTrap("Error setting RX VLAN");
		return XST_FAILURE;
	}

	/* Configure VLAN TPIDs for HW to recognize. */
	Status  = XAxiEthernet_SetTpid(AxiEthernetInstancePtr, Tpid1, 0);
	Status |= XAxiEthernet_SetTpid(AxiEthernetInstancePtr, Tpid2, 1);
	if (Status != XST_SUCCESS) {
		AxiEthernetUtilErrorTrap("Error setting TPIDs");
		return XST_FAILURE;
	}

	/*
	 * Flush the TX frame before giving it to DMA TX channel to transmit.
	 */
	Xil_DCacheFlushRange((u32)&TxFrame, TxFrameLength);

	/*
	 * Clear out receive packet memory area
	 */
	AxiEthernetUtilFrameMemClear(&RxFrame);

	/*
	 * Invalidate the RX frame before giving it to DMA RX channel to
	 * receive data.
 	 */
	Xil_DCacheInvalidateRange((u32)&RxFrame, TxFrameLength + 4);

	/*
	 * Interrupt coalescing parameters are set to their default settings
	 * which is to interrupt the processor after every frame has been
	 * processed by the DMA engine.
	 */

	Status = XAxiDma_BdRingSetCoalesce(TxRingPtr, 1, 1);
	if (Status != XST_SUCCESS) {
		AxiEthernetUtilErrorTrap("Error setting coalescing for transmit");
		return XST_FAILURE;
	}

	Status = XAxiDma_BdRingSetCoalesce(RxRingPtr, 1, 1);
	if (Status != XST_SUCCESS) {
		AxiEthernetUtilErrorTrap("Error setting coalescing for recv");
		return XST_FAILURE;
	}

	/*
	 * Make sure Tx and Rx are enabled
	 */
	Status = XAxiEthernet_SetOptions(AxiEthernetInstancePtr,
					XAE_RECEIVER_ENABLE_OPTION |
					XAE_TRANSMITTER_ENABLE_OPTION );
	if (Status != XST_SUCCESS) {
		AxiEthernetUtilErrorTrap("Error setting options");
		return XST_FAILURE;
	}

	Status = XAxiEthernet_SetOptions(AxiEthernetInstancePtr,
					XAE_JUMBO_OPTION);
	if (Status != XST_SUCCESS) {
		AxiEthernetUtilErrorTrap("Error setting options");
		return XST_FAILURE;
	}

	/*
	 * Start the AxiEthernet and enable its ERROR interrupts
	 */
	XAxiEthernet_Start(AxiEthernetInstancePtr);
	XAxiEthernet_IntEnable(&AxiEthernetInstance,
					XAE_INT_RECV_ERROR_MASK);

	/*
	 * Enable DMA receive related interrupts
	 */
	XAxiDma_BdRingIntEnable(RxRingPtr, XAXIDMA_IRQ_ALL_MASK);

	/*
	 * Allocate 1 RxBD.
	 */
	Status = XAxiDma_BdRingAlloc(RxRingPtr, 1, &BdPtr);
	if (Status != XST_SUCCESS) {
		AxiEthernetUtilErrorTrap("Error allocating RxBD");
		return XST_FAILURE;
	}

	/*
	 * Setup the BD.
	 */
	XAxiDma_BdSetBufAddr(BdPtr, (u32)&RxFrame);
#ifndef XPAR_AXIDMA_0_ENABLE_MULTI_CHANNEL
	XAxiDma_BdSetLength(BdPtr, sizeof(RxFrame));
#else
	XAxiDma_BdSetLength(BdPtr, sizeof(RxFrame),
				RxRingPtr->MaxTransferLen);
#endif
	XAxiDma_BdSetCtrl(BdPtr, 0);

	/*
	 * Enqueue to HW
	 */
	Status = XAxiDma_BdRingToHw(RxRingPtr, 1, BdPtr);
	if (Status != XST_SUCCESS) {
		AxiEthernetUtilErrorTrap("Error committing RxBD to HW");
		return XST_FAILURE;
	}

	/*
	 * Start DMA RX channel. Now it's ready to receive data.
	 */
	Status = XAxiDma_BdRingStart(RxRingPtr);
	if (Status != XST_SUCCESS) {
		return XST_FAILURE;
	}

	/*
	 * Enable DMA transmit related interrupts
	 */
	XAxiDma_BdRingIntEnable(TxRingPtr, XAXIDMA_IRQ_ALL_MASK);

	/*
	 * Allocate 1 TxBD
	 */
	Status = XAxiDma_BdRingAlloc(TxRingPtr, 1, &BdPtr);
	if (Status != XST_SUCCESS) {
		AxiEthernetUtilErrorTrap("Error allocating TxBD");
		return XST_FAILURE;
	}

	/*
	 * Setup the TxBD
	 */
	XAxiDma_BdSetBufAddr(BdPtr, (u32)&TxFrame);
#ifndef XPAR_AXIDMA_0_ENABLE_MULTI_CHANNEL
	XAxiDma_BdSetLength(BdPtr, TxFrameLength);
#else
	XAxiDma_BdSetLength(BdPtr, TxFrameLength,
				TxRingPtr->MaxTransferLen);
#endif
	XAxiDma_BdSetCtrl(BdPtr, XAXIDMA_BD_CTRL_TXSOF_MASK |
						XAXIDMA_BD_CTRL_TXEOF_MASK);

	/*
	 * Enqueue to HW
	 */
	Status = XAxiDma_BdRingToHw(TxRingPtr, 1, BdPtr);
	if (Status != XST_SUCCESS) {
		AxiEthernetUtilErrorTrap("Error committing TxBD to HW");
		return XST_FAILURE;
	}

	/*
	 * Start DMA TX channel. Transmission starts at once.
	 */
	Status = XAxiDma_BdRingStart(TxRingPtr);
	if (Status != XST_SUCCESS) {
		return XST_FAILURE;
	}

	/*
	 * Wait for transmission to complete
	 */
	while (!FramesTx);

	/*
	 * Now that the frame has been sent, post process our TxBDs.
	 * Since we have only submitted 2 to HW, then there should be only 2
	 * ready for post processing.
	 */
	if (XAxiDma_BdRingFromHw(TxRingPtr, 1, &BdPtr) == 0) {
		AxiEthernetUtilErrorTrap("TxBDs were not ready for post processing");
		return XST_FAILURE;
	}

	/*
	 * Examine the TxBDs.
	 *
	 * There isn't much to do. The only thing to check would be DMA
	 * exception bits. But this would also be caught in the error handler.
	 * So we just return these BDs to the free list
	 */
	Status = XAxiDma_BdRingFree(TxRingPtr, 1, BdPtr);
	if (Status != XST_SUCCESS) {
		AxiEthernetUtilErrorTrap("Error freeing up TxBDs");
		return XST_FAILURE;
	}

	/*
	 * Wait for Rx indication
	 */
	while (!FramesRx);
	/*
	 * Now that the frame has been received, post process our RxBD.
	 * Since we have only submitted 1 to HW, then there should be only 1
	 * ready for post processing.
	 */
	if (XAxiDma_BdRingFromHw(RxRingPtr, 1, &BdPtr) == 0) {
		AxiEthernetUtilErrorTrap("RxBD was not ready for post processing");
		return XST_FAILURE;
	}

	BdCurPtr = BdPtr;
	BdSts = XAxiDma_BdGetSts(BdCurPtr);

	if ((BdSts & XAXIDMA_BD_STS_ALL_ERR_MASK) ||
		(!(BdSts & XAXIDMA_BD_STS_COMPLETE_MASK))) {
			AxiEthernetUtilErrorTrap("Rx Error");
			return XST_FAILURE;
	}
	else {

		RxFrameLength =
		(XAxiDma_BdRead(BdCurPtr,XAXIDMA_BD_USR4_OFFSET)) & 0x0000FFFF;
	}

	/* Expected RX TPID+CFI+VID !!! */
	VTagCfiVid = (((u32)Tpid2 << 16) | ((u32)Cfi2 << 12) | RxStrpVid);

	/* Check on the VLAN CFI and VID */
	RxStatusControlWord = XAxiDma_BdGetAppWord(BdPtr,
						BD_VLAN_VID_OFFSET, &Valid);
	if(Valid) {
		RxCfiVid = RxStatusControlWord >> 16;
		RxCfiVid = Xil_Ntohs(RxCfiVid);
		if(RxCfiVid != (VTagCfiVid & 0x0000FFFF)) {
			AxiEthernetUtilErrorTrap("VLAN CFI and VID mismatch\n");
			return XST_FAILURE;
		}
	}
	else {
/**
*
* This function demonstrates the usage usage of the Axi Ethernet by sending
* and receiving frames in interrupt driven SGDMA mode.
*
*
* @param	IntcInstancePtr is a pointer to the instance of the Intc
*		component.
* @param	AxiEthernetInstancePtr is a pointer to the instance of the
*		AxiEthernet component.
* @param	DmaInstancePtr is a pointer to the instance of the AXIDMA
*		component.
* @param	AxiEthernetDeviceId is Device ID of the Axi Ethernet Device ,
*		typically XPAR_<AXIETHERNET_instance>_DEVICE_ID value from
*		xparameters.h.
* @param	AxiDmaDeviceId is Device ID of the Axi DMAA Device ,
*		typically XPAR_<AXIDMA_instance>_DEVICE_ID value from
*		xparameters.h.
* @param	AxiEthernetIntrId is the Interrupt ID and is typically
*		XPAR_<INTC_instance>_<AXIETHERNET_instance>_VEC_ID
*		value from xparameters.h.
* @param	DmaRxIntrId is the interrupt id for DMA Rx and is typically
*		taken from XPAR_<AXIETHERNET_instance>_CONNECTED_DMARX_INTR
* @param	DmaTxIntrId is the interrupt id for DMA Tx and is typically
*		taken from XPAR_<AXIETHERNET_instance>_CONNECTED_DMATX_INTR
*
* @return	-XST_SUCCESS to indicate success.
*		-XST_FAILURE to indicate failure.
*
* @note		AxiDma hardware must be initialized before initializing
*		AxiEthernet. Since AxiDma reset line is connected to the
*		AxiEthernet reset line, a reset of AxiDma hardware during its
*		initialization would reset AxiEthernet.
*
******************************************************************************/
int AxiEthernetExtVlanExample(INTC *IntcInstancePtr,
			  	XAxiEthernet *AxiEthernetInstancePtr,
			  	XAxiDma *DmaInstancePtr,
			  	u16 AxiEthernetDeviceId,
			  	u16 AxiDmaDeviceId,
			  	u16 AxiEthernetIntrId,
			  	u16 DmaRxIntrId,
			  	u16 DmaTxIntrId)
{
	int Status;
	int LoopbackSpeed;
	XAxiEthernet_Config *MacCfgPtr;
	XAxiDma_BdRing *RxRingPtr = XAxiDma_GetRxRing(DmaInstancePtr);
	XAxiDma_BdRing *TxRingPtr = XAxiDma_GetTxRing(DmaInstancePtr);
	XAxiDma_Bd BdTemplate;
	XAxiDma_Config* DmaConfig;

	/*************************************/
	/* Setup device for first-time usage */
	/*************************************/

	/*
	 *  Get the configuration of AxiEthernet hardware.
	 */
	MacCfgPtr = XAxiEthernet_LookupConfig(AxiEthernetDeviceId);

	/*
	 * Check if DMA is present or not.
	 */
	if(MacCfgPtr->AxiDevType != XPAR_AXI_DMA) {
		AxiEthernetUtilErrorTrap
			("Device HW not configured for SGDMA mode\r\n");
		return XST_FAILURE;
	}

	DmaConfig = XAxiDma_LookupConfig(AxiDmaDeviceId);

	/*
	 * Initialize AXIDMA engine. AXIDMA engine must be initialized before
	 * AxiEthernet. During AXIDMA engine initialization, AXIDMA hardware is
	 * reset, and since AXIDMA reset line is connected to AxiEthernet, this
	 * would ensure a reset of AxiEthernet.
	 */
	Status = XAxiDma_CfgInitialize(DmaInstancePtr, DmaConfig);
	if(Status != XST_SUCCESS) {
		AxiEthernetUtilErrorTrap("Error initializing DMA\r\n");
		return XST_FAILURE;
	}

	/*
	 * Initialize AxiEthernet hardware.
	 */
	Status = XAxiEthernet_CfgInitialize(AxiEthernetInstancePtr, MacCfgPtr,
					MacCfgPtr->BaseAddress);
	if (Status != XST_SUCCESS) {
		AxiEthernetUtilErrorTrap("Error in initialize");
		return XST_FAILURE;
	}

	/*
	 * Set the MAC address
	 */
	Status = XAxiEthernet_SetMacAddress(AxiEthernetInstancePtr,
							AxiEthernetMAC);
	if (Status != XST_SUCCESS) {
		AxiEthernetUtilErrorTrap("Error setting MAC address");
		return XST_FAILURE;
	}

	/*
	 * Setup RxBD space.
	 *
	 * We have already defined a properly aligned area of memory to store
	 * RxBDs at the beginning of this source code file so just pass its
	 * address into the function. No MMU is being used so the physical and
	 * virtual addresses are the same.
	 *
	 * Setup a BD template for the Rx channel. This template will be copied
	 * to every RxBD. We will not have to explicitly set these again.
	 */

	/*
	 * Create the RxBD ring
	 */
	Status = XAxiDma_BdRingCreate(RxRingPtr, (u32) &RxBdSpace,
				     (u32) &RxBdSpace, BD_ALIGNMENT, RXBD_CNT);
	if (Status != XST_SUCCESS) {
		AxiEthernetUtilErrorTrap("Error setting up RxBD space");
		return XST_FAILURE;
	}
	XAxiDma_BdClear(&BdTemplate);
	Status = XAxiDma_BdRingClone(RxRingPtr, &BdTemplate);
	if (Status != XST_SUCCESS) {
		AxiEthernetUtilErrorTrap("Error initializing RxBD space");
		return XST_FAILURE;
	}

	/*
	 * Setup TxBD space.
	 *
	 * Like RxBD space, we have already defined a properly aligned area of
	 * memory to use.
	 */

	/*
	 * Create the TxBD ring
	 */
	Status = XAxiDma_BdRingCreate(TxRingPtr, (u32) &TxBdSpace,
				     (u32) &TxBdSpace, BD_ALIGNMENT, TXBD_CNT);
	if (Status != XST_SUCCESS) {
		AxiEthernetUtilErrorTrap("Error setting up TxBD space");
		return XST_FAILURE;
	}

	/*
	 * We reuse the bd template, as the same one will work for both rx and
	 * tx.
	 */
	Status = XAxiDma_BdRingClone(TxRingPtr, &BdTemplate);
	if (Status != XST_SUCCESS) {
		AxiEthernetUtilErrorTrap("Error initializing TxBD space");
		return XST_FAILURE;
	}

	/*
	 * Set PHY to loopback, speed depends on phy type.
	 * MII is 100 and all others are 1000.
	 */
	if (XAxiEthernet_GetPhysicalInterface(AxiEthernetInstancePtr)
						== XAE_PHY_TYPE_MII){
		LoopbackSpeed = AXIETHERNET_LOOPBACK_SPEED;
	} else {
		LoopbackSpeed = AXIETHERNET_LOOPBACK_SPEED_1G;
	}
	AxiEthernetUtilEnterLoopback(AxiEthernetInstancePtr, LoopbackSpeed);

	/*
	 * Set PHY<-->MAC data clock
	 */
	Status =  XAxiEthernet_SetOperatingSpeed(AxiEthernetInstancePtr,
						(u16)LoopbackSpeed);
	if (Status != XST_SUCCESS) {
		return XST_FAILURE;
	}

	/*
	 * Setting the operating speed of the MAC needs a delay.  There
	 * doesn't seem to be register to poll, so please consider this
	 * during your application design.
	 */
	AxiEthernetUtilPhyDelay(2);

	/*
	 * Connect to the interrupt controller and enable interrupts
	 */
	Status = AxiEthernetSetupIntrSystem(IntcInstancePtr,
					AxiEthernetInstancePtr,
					DmaInstancePtr,
					AxiEthernetIntrId, DmaRxIntrId,
					DmaTxIntrId);

	/****************************/
	/* Run the example */
	/****************************/

	/* Run the new VLAN feature. Make sure HW has the capability */
	if (XAxiEthernet_IsTxVlanTran(AxiEthernetInstancePtr) &&
		XAxiEthernet_IsTxVlanStrp(AxiEthernetInstancePtr) &&
		XAxiEthernet_IsTxVlanTag(AxiEthernetInstancePtr)  &&
		XAxiEthernet_IsRxVlanTran(AxiEthernetInstancePtr) &&
		XAxiEthernet_IsRxVlanStrp(AxiEthernetInstancePtr) &&
		XAxiEthernet_IsRxVlanTag(AxiEthernetInstancePtr)) {
		Status = AxiEthernetSgDmaIntrExtVlanExample
		(AxiEthernetInstancePtr,DmaInstancePtr);
		if (Status != XST_SUCCESS) {
			return XST_FAILURE;
		}
	}

	/*
	 * Disable the interrupts for the AxiEthernet device
	 */
	AxiEthernetDisableIntrSystem(IntcInstancePtr, AxiEthernetIntrId,
						DmaRxIntrId, DmaTxIntrId);

	/*
	 * Stop the device
	 */
	XAxiEthernet_Stop(AxiEthernetInstancePtr);

	return XST_SUCCESS;
}