/**
* This function resets the device but preserves the options set by the user.
*
* The descriptor list could be reinitialized with the same calls to
* XLlTemac_SgSetSpace() as used in main(). Doing this is a matter of preference.
* In many cases, an OS may have resources tied up in the descriptors.
* Reinitializing in this case may bad for the OS since its resources may be
* permamently lost.
*
* @param    TemacInstancePtr is a pointer to the instance of the Temac
*           component.
*
* @return   XST_SUCCESS if successful, else XST_FAILURE.
*
* @note     None.
*
******************************************************************************/
static int TemacResetDevice(XLlTemac * TemacInstancePtr,
				XLlDma * DmaInstancePtr)
{
	int Status;
	u8 MacSave[6];
	u32 Options;
	//u32 RxThreshold = 1;
	//u32 TxThreshold = 1;
	//u32 RxWaitbound = 0;
	//u32 TxWaitbound = 0;
	//XLlDma_BdRing * RxRingPtr = &XLlDma_GetRxRing(DmaInstancePtr);
	//XLlDma_BdRing * TxRingPtr = &XLlDma_GetTxRing(DmaInstancePtr);

	/*
	 * Stop LLTEMAC device
	 */
	XLlTemac_Stop(TemacInstancePtr);

	/*
	 * Save the device state
	 */
	XLlTemac_GetMacAddress(TemacInstancePtr, MacSave);
	Options = XLlTemac_GetOptions(TemacInstancePtr);

	/*
	 * Stop and reset the device
	 */
	XLlTemac_Reset(TemacInstancePtr, XTE_NORESET_HARD);

	/*
	 * Restore the state
	 */
	Status = XLlTemac_SetMacAddress(TemacInstancePtr, MacSave);
	Status |= XLlTemac_SetOptions(TemacInstancePtr, Options);
	Status |= XLlTemac_ClearOptions(TemacInstancePtr, ~Options);
	if (Status != XST_SUCCESS) {
		TemacUtilErrorTrap("Error restoring state after reset");
		return XST_FAILURE;
	}

	/*
	 * Restart the device
	 */
	XLlTemac_Start(TemacInstancePtr);
	return XST_SUCCESS;
}
Exemplo n.º 2
0
void
init_lltemac(xlltemacif_s *xlltemacif, struct netif *netif)
{
	int rdy;
	unsigned mac_address = (unsigned)(netif->state);
	unsigned link_speed = 1000;
	unsigned options;
        unsigned lock_message_printed = 0;

	/* obtain config of this emac */
	XLlTemac_Config *mac_config = lookup_config(mac_address);

	XLlTemac *xlltemacp = &xlltemacif->lltemac;

	XLlTemac_CfgInitialize(xlltemacp, mac_config, mac_config->BaseAddress);

	options = XLlTemac_GetOptions(xlltemacp);
	options |= XTE_FLOW_CONTROL_OPTION;
	options |= XTE_JUMBO_OPTION;
	options |= XTE_TRANSMITTER_ENABLE_OPTION;
	options |= XTE_RECEIVER_ENABLE_OPTION;
	options |= XTE_FCS_STRIP_OPTION;
	options |= XTE_MULTICAST_OPTION;
	XLlTemac_SetOptions(xlltemacp, options);
	XLlTemac_ClearOptions(xlltemacp, ~options);

	/* set mac address */
	XLlTemac_SetMacAddress(xlltemacp, (Xuint8*)(netif->hwaddr));

	/* make sure the hard TEMAC is ready */
	rdy = XLlTemac_ReadReg(xlltemacp->Config.BaseAddress,
			XTE_RDY_OFFSET);
	while ((rdy & XTE_RDY_HARD_ACS_RDY_MASK) == 0) {
		rdy = XLlTemac_ReadReg(xlltemacp->Config.BaseAddress,
				XTE_RDY_OFFSET);
	}

	link_speed = Phy_Setup(xlltemacp);
    	XLlTemac_SetOperatingSpeed(xlltemacp, link_speed);

	/* Setting the operating speed of the MAC needs a delay. */
	{
		volatile int wait;
		for (wait=0; wait < 100000; wait++);
		for (wait=0; wait < 100000; wait++);
	}

        /* in a soft temac implementation, we need to explicitly make sure that
         * the RX DCM has been locked. See xps_ll_temac manual for details.
         * This bit is guaranteed to be 1 for hard temac's
         */
        lock_message_printed = 0;
        while (!(XLlTemac_ReadReg(xlltemacp->Config.BaseAddress, XTE_IS_OFFSET)
                    & XTE_INT_RXDCM_LOCK_MASK)) {
                int first = 1;
                if (first) {
                        print("Waiting for RX DCM to lock..");
                        first = 0;
                        lock_message_printed = 1;
                }
        }

        if (lock_message_printed)
                print("RX DCM locked.\r\n");

	/* start the temac */
    	XLlTemac_Start(xlltemacp);

	/* enable TEMAC interrupts */
	XLlTemac_IntEnable(xlltemacp, XTE_INT_RECV_ERROR_MASK);
}
/**
*
* This function demonstrates the usage of the TEMAC by sending and receiving
* a single frame in SGDMA interrupt mode.
* The source packet will be described by two descriptors. It will be received
* into a buffer described by a single descriptor.
*
* @param    TemacInstancePtr is a pointer to the instance of the Temac
*           component.
*
* @return   XST_SUCCESS to indicate success, otherwise XST_FAILURE.
*
* @note     None.
*
******************************************************************************/
int TemacSgDmaIntrSingleFrameExample(XLlTemac * TemacInstancePtr,
				     XLlDma * DmaInstancePtr)
{
	int Status;
	u32 TxFrameLength;
	int PayloadSize = 1000;
	XLlDma_BdRing *RxRingPtr = &XLlDma_GetRxRing(DmaInstancePtr);
	XLlDma_BdRing *TxRingPtr = &XLlDma_GetTxRing(DmaInstancePtr);
	XLlDma_Bd *Bd1Ptr;
	XLlDma_Bd *Bd2Ptr;

	/*
	 * Clear variables shared with callbacks
	 */
	FramesRx = 0;
	FramesTx = 0;
	DeviceErrors = 0;

	/*
	 * Calculate the frame length (not including FCS)
	 */
	TxFrameLength = XTE_HDR_SIZE + PayloadSize;

	/*
	 * Setup packet to be transmitted
	 */
	TemacUtilFrameHdrFormatMAC(&TxFrame, TemacMAC);
	TemacUtilFrameHdrFormatType(&TxFrame, PayloadSize);
	TemacUtilFrameSetPayloadData(&TxFrame, PayloadSize);

        /*
         * Flush the TX frame before giving it to DMA TX channel to transmit,
         * in case D-Caching is turned on.
         */
	XCACHE_FLUSH_DCACHE_RANGE(&TxFrame, TxFrameLength);

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

        /*
         * Invalidate the RX frame before giving it to DMA RX channel to
         * receive data, in case D-Caching is turned on.
         */
	XCACHE_INVALIDATE_DCACHE_RANGE(&RxFrame, TxFrameLength);

	/*
	 * Start the LLTEMAC device and enable the ERROR interrupt
	 */
	XLlTemac_Start(TemacInstancePtr);
	XLlTemac_IntEnable(TemacInstancePtr, XTE_INT_RECV_ERROR_MASK);

	/*
	 * Allocate 1 RxBD. Note that TEMAC utilizes an in-place allocation
	 * scheme. The returned Bd1Ptr will point to a free BD in the memory
	 * segment setup with the call to XLlTemac_SgSetSpace()
	 */
	Status = XLlDma_BdRingAlloc(RxRingPtr, 1, &Bd1Ptr);
	if (Status != XST_SUCCESS) {
		TemacUtilErrorTrap("Error allocating RxBD");
		return XST_FAILURE;
	}

	/*
	 * Setup the BD. The BD template used in the call to XLlTemac_SgSetSpace()
	 * set the "last" field of all RxBDs. Therefore we are not required to
	 * issue a XLlDma_Bd_mSetLast(Bd1Ptr) here.
	 */
	XLlDma_BdSetBufAddr(Bd1Ptr, &RxFrame);
	XLlDma_BdSetLength(Bd1Ptr, sizeof(RxFrame));
	XLlDma_BdSetStsCtrl(Bd1Ptr, XLLDMA_BD_STSCTRL_SOP_MASK | XLLDMA_BD_STSCTRL_EOP_MASK);

	/*
	 * Enqueue to HW
	 */
	Status = XLlDma_BdRingToHw(RxRingPtr, 1, Bd1Ptr);
	if (Status != XST_SUCCESS) {
		TemacUtilErrorTrap("Error committing RxBD to HW");
		return XST_FAILURE;
	}

	/*
	 * Enable DMA RX interrupt.
	 *
	 * Interrupt coalescing parameters are left at their default settings
	 * which is to interrupt the processor after every frame has been
	 * processed by the DMA engine.
	 */
	XLlDma_BdRingIntEnable(RxRingPtr, XLLDMA_CR_IRQ_ALL_EN_MASK);

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

	/*
	 * Allocate, setup, and enqueue 2 TxBDs. The first BD will describe
	 * the first 32 bytes of TxFrame and the second BD will describe the
	 * rest of the frame.
	 *
	 * The function below will allocate two adjacent BDs with Bd1Ptr being
	 * set as the lead BD.
	 */
	Status = XLlDma_BdRingAlloc(TxRingPtr, 2, &Bd1Ptr);
	if (Status != XST_SUCCESS) {
		TemacUtilErrorTrap("Error allocating TxBD");
		return XST_FAILURE;
	}

	/*
	 * Setup TxBD #1
	 */
	XLlDma_BdSetBufAddr(Bd1Ptr, &TxFrame);
	XLlDma_BdSetLength(Bd1Ptr, 32);
	XLlDma_BdSetStsCtrl(Bd1Ptr, XLLDMA_BD_STSCTRL_SOP_MASK);

	/*
	 * Setup TxBD #2
	 */
	Bd2Ptr = XLlDma_BdRingNext(TxRingPtr, Bd1Ptr);
	XLlDma_BdSetBufAddr(Bd2Ptr, (u32) (&TxFrame) + 32);
	XLlDma_BdSetLength(Bd2Ptr, TxFrameLength - 32);
	XLlDma_BdSetStsCtrl(Bd2Ptr, XLLDMA_BD_STSCTRL_EOP_MASK);

	/*
	 * Enqueue to HW
	 */
	Status = XLlDma_BdRingToHw(TxRingPtr, 2, Bd1Ptr);
	if (Status != XST_SUCCESS) {
		/*
		 * Undo BD allocation and exit
		 */
		XLlDma_BdRingUnAlloc(TxRingPtr, 2, Bd1Ptr);
		TemacUtilErrorTrap("Error committing TxBD to HW");
		return XST_FAILURE;
	}

	/*
	 * Enable DMA transmit interrupts
	 */
	XLlDma_BdRingIntEnable(TxRingPtr, XLLDMA_CR_IRQ_ALL_EN_MASK);

	/*
	 * Start DMA TX channel. Transmission starts at once.
	 */
	Status = XLlDma_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 (XLlDma_BdRingFromHw(TxRingPtr, 2, &Bd1Ptr) == 0) {
		TemacUtilErrorTrap("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 = XLlDma_BdRingFree(TxRingPtr, 2, Bd1Ptr);
	if (Status != XST_SUCCESS) {
		TemacUtilErrorTrap("Error freeing up TxBDs");
		return XST_FAILURE;
	}


	/*
	 * Wait for Rx indication
	 */
	while (!FramesRx);

    printf("Transmitted Packet!\r\n");
    printf("\r\n");

	/*
	 * 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 (XLlDma_BdRingFromHw(RxRingPtr, 1, &Bd1Ptr) == 0) {
		TemacUtilErrorTrap("RxBD was not ready for post processing");
		return XST_FAILURE;
	}

	/*
	 * There is no device status to check. If there was a DMA error, it
	 * should have been reported to the error handler. Check the receive
	 * length against the transmitted length, then verify the data.
	 *
	 * Note in LLTEMAC case, USR4_OFFSET word in the RX BD is used to store
	 * the real length of the received packet
	 */
        if ((XLlDma_BdRead(Bd1Ptr, XLLDMA_BD_USR4_OFFSET) & 0x3FFF)

                != TxFrameLength) {

                TemacUtilErrorTrap("Length mismatch");

                return XST_FAILURE;

        }



        if (TemacUtilFrameVerify(&TxFrame, &RxFrame) != 0) {

                TemacUtilErrorTrap("Data mismatch");

                return XST_FAILURE;

        }


	/*
	 * Return the RxBD back to the channel for later allocation. Free the
	 * exact number we just post processed.
	 */
	Status = XLlDma_BdRingFree(RxRingPtr, 1, Bd1Ptr);
	if (Status != XST_SUCCESS) {
		TemacUtilErrorTrap("Error freeing up TxBDs");
		return XST_FAILURE;
	}

	/*
	 * Finished this example. If everything worked correctly, all TxBDs and
	 * RxBDs should be free for allocation. Stop the device.
	 */
	XLlTemac_Stop(TemacInstancePtr);

	return XST_SUCCESS;
}
Exemplo n.º 4
0
static err_t
xlltemacif_mac_filter_update (struct netif *netif, struct ip_addr *group,
								u8_t action)
{
	err_t return_val = ERR_OK;
	u8_t multicast_mac_addr[6];
	u8_t multicast_mac_addr_to_clr[6];
	u8_t temp_mask;
	int entry;
	int i;
	u8_t * ip_addr_temp  = (u8_t *)group;
	struct xemac_s *xemac = (struct xemac_s *)(netif->state);
	xlltemacif_s *xlltemacif = (xlltemacif_s *)(xemac->state);

	if (action == IGMP_ADD_MAC_FILTER) {
		if ((ip_addr_temp[0] >= 224) && (ip_addr_temp[0] <= 239)) {
			if (xlltemac_mcast_entry_mask >= 0x0F) {
				LWIP_DEBUGF(NETIF_DEBUG,
				("xlltemacif_mac_filter_update: No multicast address registers left.\r\n"));
				LWIP_DEBUGF(NETIF_DEBUG,
				("				 Multicast MAC address add operation failure !!\r\n"));

				return_val = ERR_MEM;
			} else {
				for (i = 0; i < 4; i++) {
					temp_mask = (0x01) << i;
					if ((xlltemac_mcast_entry_mask &
						temp_mask) == temp_mask) {

						continue;

					} else {
						entry = i;
						xlltemac_mcast_entry_mask |=
								temp_mask;
						multicast_mac_addr[0] = 0x01;
						multicast_mac_addr[1] = 0x00;
						multicast_mac_addr[2] = 0x5E;

						multicast_mac_addr[3] =
						ip_addr_temp[1] & 0x7F;
						multicast_mac_addr[4] =
						ip_addr_temp[2];
						multicast_mac_addr[5] =
						ip_addr_temp[3];

						XLlTemac_Stop
						(&xlltemacif->lltemac);

						XLlTemac_MulticastAdd
						(&xlltemacif->lltemac,
						multicast_mac_addr,entry);

						XLlTemac_Start
						(&xlltemacif->lltemac);

						LWIP_DEBUGF(NETIF_DEBUG,
						("xlltemacif_mac_filter_update: Muticast MAC address successfully added.\r\n"));

						return_val = ERR_OK;
						break;
					}
				}
				if (i == 4) {
					LWIP_DEBUGF(NETIF_DEBUG,
					("xlltemacif_mac_filter_update: No multicast address registers left.\r\n"));
					LWIP_DEBUGF(NETIF_DEBUG,
					("				Multicast MAC address add operation failure !!\r\n"));

					return_val = ERR_MEM;
				}
			}
		} else {
			LWIP_DEBUGF(NETIF_DEBUG,
			("xlltemacif_mac_filter_update: The requested MAC address is not a multicast address.\r\n"));
			LWIP_DEBUGF(NETIF_DEBUG,
			("				Multicast address add operation failure !!\r\n"));

			return_val = ERR_ARG;
		}
	} else if (action == IGMP_DEL_MAC_FILTER) {
		if ((ip_addr_temp[0] < 224) || (ip_addr_temp[0] > 239)) {
			LWIP_DEBUGF(NETIF_DEBUG,
			("xlltemacif_mac_filter_update: The requested MAC address is not a multicast address.\r\n"));
			LWIP_DEBUGF(NETIF_DEBUG,
			("				Multicast address add operation failure !!\r\n"));

			return_val = ERR_ARG;
		} else {
			for (i = 0; i < 4; i++) {
				temp_mask = (0x01) << i;
				if ((xlltemac_mcast_entry_mask & temp_mask)
								== temp_mask) {
					XLlTemac_MulticastGet
					(&xlltemacif->lltemac,
					multicast_mac_addr_to_clr, i);

					if ((ip_addr_temp[3] ==
					multicast_mac_addr_to_clr[5]) &&
					(ip_addr_temp[2] ==
					multicast_mac_addr_to_clr[4]) &&
					((ip_addr_temp[1] & 0x7f) ==
					multicast_mac_addr_to_clr[3])) {

						XLlTemac_Stop
						(&xlltemacif->lltemac);

						XLlTemac_MulticastClear
						(&xlltemacif->lltemac, i);

						XLlTemac_Start
						(&xlltemacif->lltemac);

						return_val = ERR_OK;
						xlltemac_mcast_entry_mask
						&= (~temp_mask);
						break;
					} else {
						continue;
					}
				} else {
					continue;
				}
			}
			if (i == 4) {
				LWIP_DEBUGF(NETIF_DEBUG,
				("xlltemacif_mac_filter_update: No multicast address registers present with\r\n"));
				LWIP_DEBUGF(NETIF_DEBUG,
				("				the requested Multicast MAC address.\r\n"));
				LWIP_DEBUGF(NETIF_DEBUG,
				("				Multicast MAC address removal failure!!.\r\n"));

				return_val = ERR_MEM;
			}
		}
	}
	return return_val;
}
/**
*
* This example sends and receives a single packet in loopback mode with checksum
* offloading support.
*
* The transmit frame will be checksummed over the entire Ethernet payload
* and inserted into the last 2 bytes of the frame.
*
* On receive, HW should calculate the Ethernet payload checksum and return a
* value of 0xFFFF which means the payload data was likely not corrupted.
*
* @param    TemacInstancePtr is a pointer to the instance of the Temac
*           component.
*
* @return   XST_SUCCESS to indicate success, otherwise XST_FAILURE.
*
* @note     None.
*
******************************************************************************/
int TemacSgDmaChecksumOffloadExample(XLlTemac * TemacInstancePtr,
				     XLlDma * DmaInstancePtr)
{
	int Status;
	u32 TxFrameLength;
	int PayloadSize = 1000;
	XLlDma_BdRing *RxRingPtr = &XLlDma_mGetRxRing(DmaInstancePtr);
	XLlDma_BdRing *TxRingPtr = &XLlDma_mGetTxRing(DmaInstancePtr);
	XLlDma_Bd *BdPtr;

	/*
	 * Cannot run this example if checksum offloading support is not available
	 */
	if (!(XLlTemac_IsRxCsum(TemacInstancePtr) &&
	      XLlTemac_IsTxCsum(TemacInstancePtr))) {
		TemacUtilErrorTrap("Checksum offloading not available");
		return XST_FAILURE;
	}

	/*
	 * Clear variables shared with callbacks
	 */
	FramesRx = 0;
	FramesTx = 0;
	DeviceErrors = 0;

	/*
	 * Calculate frame length (not including FCS)
	 */
	TxFrameLength = XTE_HDR_SIZE + PayloadSize;

	/*
	 * Setup the packet to be transmitted,
	 * Last 2 bytes are reserved for checksum
	 */
	TemacUtilFrameMemClear(&TxFrame);
	TemacUtilFrameHdrFormatMAC(&TxFrame, TemacMAC);
	TemacUtilFrameHdrFormatType(&TxFrame, PayloadSize);
	TemacUtilFrameSetPayloadData(&TxFrame, PayloadSize - 2);

        /*
         * Flush the TX frame before giving it to DMA TX channel to transmit,
         * in case D-Caching is turned on.
         */
	XCACHE_FLUSH_DCACHE_RANGE(&TxFrame, TxFrameLength);

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

        /*
         * Invalidate the RX frame before giving it to DMA RX channel to
         * receive data, in case D-Caching is turned on.
         */
	XCACHE_INVALIDATE_DCACHE_RANGE(&RxFrame, TxFrameLength);

	/*
	 * 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 = XLlDma_BdRingSetCoalesce(TxRingPtr, 1, 1);
	if (Status != XST_SUCCESS) {
		TemacUtilErrorTrap("Error setting coalescing for transmit");
		return XST_FAILURE;
	}

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

	/*
	 * Make sure Tx and Rx are enabled
	 */
	Status = XLlTemac_SetOptions(TemacInstancePtr,
				     XTE_RECEIVER_ENABLE_OPTION |
				     XTE_TRANSMITTER_ENABLE_OPTION);
	if (Status != XST_SUCCESS) {
		TemacUtilErrorTrap("Error setting options");
		return XST_FAILURE;
	}

	/*
	 * Start the LLTEMAC and enable its ERROR interrupts
	 */
	XLlTemac_Start(TemacInstancePtr);
	XLlTemac_IntEnable(TemacInstancePtr, XTE_INT_RECV_ERROR_MASK);

	/*
	 * Allocate 1 RxBD. Note that TEMAC utilizes an in-place allocation
	 * scheme. The returned BdPtr will point to a free BD in the memory
	 * segment setup with the call to XLlTemac_SgSetSpace()
	 */
	Status = XLlDma_BdRingAlloc(RxRingPtr, 1, &BdPtr);
	if (Status != XST_SUCCESS) {
		TemacUtilErrorTrap("Error allocating RxBD");
		return XST_FAILURE;
	}

	/*
	 * Setup the BD. The BD template used in the call to XLlTemac_SgSetSpace()
	 * set the SOP and EOP fields of all RxBDs.
	 */
	XLlDma_mBdSetBufAddr(BdPtr, &RxFrame);
	XLlDma_mBdSetLength(BdPtr, sizeof(RxFrame));
	XLlDma_mBdSetStsCtrl(BdPtr, XLLDMA_BD_STSCTRL_SOP_MASK |
			     XLLDMA_BD_STSCTRL_EOP_MASK);


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

	/*
	 * Enable DMA receive related interrupts
	 */
	XLlDma_mBdRingIntEnable(RxRingPtr, XLLDMA_CR_IRQ_ALL_EN_MASK);

	/*
	 * As DMA RX channel has been started in
	 * TemacSgDmaIntrSingleFrameExample() above, there is no need to start
	 * it again here
	 */

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

	/*
	 * Setup the TxBD
	 */
	XLlDma_mBdSetBufAddr(BdPtr, &TxFrame);
	XLlDma_mBdSetLength(BdPtr, TxFrameLength);
	XLlDma_mBdSetStsCtrl(BdPtr, XLLDMA_BD_STSCTRL_SOP_MASK |
			     XLLDMA_BD_STSCTRL_EOP_MASK);

	/*
	 * Setup TxBd checksum offload attributes.
	 * Note that the checksum offload values can be set globally for all TxBds
	 * when XLlDma_BdRingClone() is called to setup Tx BD space. This would
	 * eliminate the need to set them here.
	 */

	/* Enable hardware checksum computation for the buffer descriptor */
	XLlDma_mBdWrite((BdPtr), XLLDMA_BD_STSCTRL_USR0_OFFSET,
			(XLlDma_mBdRead((BdPtr), XLLDMA_BD_STSCTRL_USR0_OFFSET)
			 | CSUM_ENABLE));
	/* Write Start Offset and Insert Offset into BD */
	XLlDma_mBdWrite(BdPtr, XLLDMA_BD_USR1_OFFSET,
					XTE_HDR_SIZE << 16 | TxFrameLength - 2);
	/* Write 0, as the seed value, to the BD */
	XLlDma_mBdWrite(BdPtr, XLLDMA_BD_USR2_OFFSET, 0);
	/*
	 * Enqueue to HW
	 */
	Status = XLlDma_BdRingToHw(TxRingPtr, 1, BdPtr);
	if (Status != XST_SUCCESS) {
		TemacUtilErrorTrap("Error committing TxBD to HW");
		return XST_FAILURE;
	}

	/*
	 * Enable DMA transmit related interrupts
	 */
	XLlDma_mBdRingIntEnable(TxRingPtr, XLLDMA_CR_IRQ_ALL_EN_MASK);

	/*
	 * As DMA TX channel has been started in
	 * TemacSgDmaIntrSingleFrameExample() above, there is no need to start
	 * it again here
	 */

	/*
	 * 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 (XLlDma_BdRingFromHw(TxRingPtr, 1, &BdPtr) == 0) {
		TemacUtilErrorTrap("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 = XLlDma_BdRingFree(TxRingPtr, 1, BdPtr);
	if (Status != XST_SUCCESS) {
		TemacUtilErrorTrap("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 (XLlDma_BdRingFromHw(RxRingPtr, 1, &BdPtr) == 0) {
		TemacUtilErrorTrap("RxBD was not ready for post processing");
		return XST_FAILURE;
	}

	/*
	 * There is no device status to check. If there was a DMA error, it should
	 * have been reported to the error handler. Check the receive length against
	 * the transmitted length, then verify the data.
	 *
	 * Note in LLTEMAC case, USR4_OFFSET word in the RX BD is used to store
	 * the real length of the received packet
	 */
	if (XLlDma_mBdRead(BdPtr, XLLDMA_BD_USR4_OFFSET) != TxFrameLength) {
		TemacUtilErrorTrap("Length mismatch");
	}

	/*
	 * Verify the checksum as computed by HW. It should add up to 0xFFFF
	 * if frame was uncorrupted
	 */
	if ((u16) (XLlDma_mBdRead(BdPtr, XLLDMA_BD_USR3_OFFSET))
		!= 0xFFFF) {
		TemacUtilErrorTrap("Rx checksum incorrect");
		return XST_FAILURE;
	}

	/*
	 * Return the RxBD back to the channel for later allocation. Free the
	 * exact number we just post processed.
	 */
	Status = XLlDma_BdRingFree(RxRingPtr, 1, BdPtr);
	if (Status != XST_SUCCESS) {
		TemacUtilErrorTrap("Error freeing up TxBDs");
		return XST_FAILURE;
	}

	/*
	 * Finished this example. If everything worked correctly, all TxBDs and
	 * RxBDs should be free for allocation. Stop the device.
	 */
	XLlTemac_Stop(TemacInstancePtr);
	return XST_SUCCESS;
}
/**
*
* This example sends frames with the interrupt coalescing settings altered
* from their defaults.
*
* The default settings will interrupt the processor after every frame has been
* sent. This example will increase the threshold resulting in lower CPU
* utilization since it spends less time servicing interrupts.
*
* @param    TemacInstancePtr is a pointer to the instance of the Temac
*           component.
*
* @return   XST_SUCCESS to indicate success, otherwise XST_FAILURE.
*
* @note     None.
*
******************************************************************************/
int TemacSgDmaIntrCoalescingExample(XLlTemac * TemacInstancePtr,
				    XLlDma * DmaInstancePtr)
{
	int Status;
	u32 TxFrameLength;
	int TxFramesToSend = 1000;
	int TxFramesSent = 0;
	int PayloadSize = XTE_MTU;
	u32 Index;
	u32 NumBd;
	u16 Threshold = 64;
	XLlDma_BdRing *RxRingPtr = &XLlDma_mGetRxRing(DmaInstancePtr);
	XLlDma_BdRing *TxRingPtr = &XLlDma_mGetTxRing(DmaInstancePtr);
	XLlDma_Bd *BdPtr, *BdCurPtr;

	/*
	 * Clear variables shared with callbacks
	 */
	FramesRx = 0;
	FramesTx = 0;
	DeviceErrors = 0;

	/*
	 * Calculate the frame length (not including FCS)
	 */
	TxFrameLength = XTE_HDR_SIZE + PayloadSize;

	/*
	 * Setup packet to be transmitted. The same packet will be transmitted
	 * over and over
	 */
	TemacUtilFrameHdrFormatMAC(&TxFrame, TemacMAC);
	TemacUtilFrameHdrFormatType(&TxFrame, PayloadSize);
	TemacUtilFrameSetPayloadData(&TxFrame, PayloadSize);

        /*
         * Flush the TX frame before giving it to DMA TX channel to transmit,
         * in case D-Caching is turned on.
         */
	XCACHE_FLUSH_DCACHE_RANGE(&TxFrame, TxFrameLength);

	/*
	 * We don't care about the receive channel for this example, so turn it off
	 */
	Status = XLlTemac_ClearOptions(TemacInstancePtr,
				       XTE_RECEIVER_ENABLE_OPTION);
	if (Status != XST_SUCCESS) {
		TemacUtilErrorTrap("Error clearing option");
		return XST_FAILURE;
	}

	/*
	 * Set the interrupt coalescing parameters for the test. The waitbound timer
	 * is set to 1 (ms) to catch the last few frames.
	 *
	 * If you set variable Threshold to some value larger than TXBD_CNT, then
	 * there can never be enough frames sent to meet the threshold. In this case
	 * the waitbound timer will always cause the interrupt to occur.
	 */
	Status = XLlDma_BdRingSetCoalesce(TxRingPtr, Threshold, 1);
	if (Status != XST_SUCCESS) {
		TemacUtilErrorTrap("Error setting coalescing settings");
		return XST_FAILURE;
	}

	/*
	 * Prime the engine, allocate all BDs and assign them to the same buffer
	 */
	Status = XLlDma_BdRingAlloc(TxRingPtr, TXBD_CNT, &BdPtr);
	if (Status != XST_SUCCESS) {
		TemacUtilErrorTrap("Error allocating TxBDs prior to starting");
		return XST_FAILURE;
	}

	/*
	 * Setup the TxBDs
	 */
	BdCurPtr = BdPtr;

	for (Index = 0; Index < TXBD_CNT; Index++) {
		XLlDma_mBdSetBufAddr(BdCurPtr, &TxFrame);
		XLlDma_mBdSetLength(BdCurPtr, TxFrameLength);
		XLlDma_mBdSetStsCtrl(BdCurPtr, XLLDMA_BD_STSCTRL_SOP_MASK |
				     XLLDMA_BD_STSCTRL_EOP_MASK);
		BdCurPtr = XLlDma_mBdRingNext(TxRingPtr, BdCurPtr);
	}

	/*
	 *  Enqueue all TxBDs to HW
	 */
	Status = XLlDma_BdRingToHw(TxRingPtr, TXBD_CNT, BdPtr);

	TxFramesSent += TXBD_CNT;
	if (Status != XST_SUCCESS) {
		TemacUtilErrorTrap("Error committing TxBDs prior to starting");
		return XST_FAILURE;
	}

	/*
	 * Enable the send interrupts. Nothing should be transmitted yet as the
	 * device has not been started
	 */
	XLlDma_mBdRingIntEnable(TxRingPtr, XLLDMA_CR_IRQ_ALL_EN_MASK);
	/* Enable temac interrupts to capture errors */
	XLlTemac_IntEnable(TemacInstancePtr, XTE_INT_RECV_ERROR_MASK);

	/*
	 * Start the device. Transmission commences now!
	 */
	XLlTemac_Start(TemacInstancePtr);

	/*
	 * As DMA TX channel has been started in
	 * TemacSgDmaIntrSingleFrameExample() above, there is no need to start
	 * it again here
	 */

	while (TxFramesSent < TxFramesToSend) {
		/*
		 * Wait for the interrupt
		 */
		while (!FramesTx);

		/*
		 * Some TxBDs are ready for post processing. Get all that are available
		 * at the moment, free them, then allocate the same number and
		 * re-enqueue back to HW. At the same time this all occurs here,
		 * the DMA engine should be processing other TxBDs. If we can stay ahead
		 * of the transmitter like this, then throughput should be at or near
		 * line-rate.
		 *
		 * Note that this retrieves up to TXBD_CNT outstanding packets,
		 * so we may be processing more packets here than the threshold
		 * value, which may result in a seemingly spurious interrupt
		 * next time if we grab twice (or more) of the threshold value
		 * this time around (clear as mud, eh!).  Bottom line is that we
		 * ignore if NumBd returns as zero.
		 */
		NumBd = XLlDma_BdRingFromHw(TxRingPtr, TXBD_CNT, &BdPtr);
		if (NumBd > 0) {
			TxFramesSent += NumBd;

			/*
			 * Don't bother to check the BDs status, just free them
			 */
			Status = XLlDma_BdRingFree(TxRingPtr, NumBd, BdPtr);
			if (Status != XST_SUCCESS) {
				TemacUtilErrorTrap("Error freeing TxBDs");
			}

			/*
			 * Allocate the same number of BDs just freed
			 */
			Status = XLlDma_BdRingAlloc(TxRingPtr, NumBd, &BdPtr);
			if (Status != XST_SUCCESS) {
				TemacUtilErrorTrap("Error allocating TxBDs");
				return XST_FAILURE;
			}

			/*
			 * Setup the TxBDs
			 */
			BdCurPtr = BdPtr;
			for (Index = 0; Index < NumBd; Index++) {
				XLlDma_mBdSetBufAddr(BdCurPtr, &TxFrame);
				XLlDma_mBdSetLength(BdCurPtr, TxFrameLength);
				XLlDma_mBdSetStsCtrl(BdCurPtr,
						     XLLDMA_BD_STSCTRL_SOP_MASK
						     |
						     XLLDMA_BD_STSCTRL_EOP_MASK);
				BdCurPtr =
					XLlDma_mBdRingNext(TxRingPtr, BdCurPtr);
			}

			/*
			 * Enqueue TxBDs to HW
			 */
			Status = XLlDma_BdRingToHw(TxRingPtr, NumBd, BdPtr);
			if (Status != XST_SUCCESS) {
				TemacUtilErrorTrap
					("Error committing TxBDs prior to starting");
				return XST_FAILURE;
			}
		}

		/*
		 * Re-enable the interrupts
		 */
		FramesTx = 0;
		XLlDma_mBdRingIntEnable(TxRingPtr, XLLDMA_CR_IRQ_ALL_EN_MASK);
	}

	/*
	 * Wait a second and collect any remaining frames that had been
	 * queued up but not post processed
	 */
#ifndef __MICROBLAZE__
	usleep(1000000);
#else
	/*
	 * Not sure if we should depend on there being a timer core in a
	 * microblaze system
	 */
	TemacUtilPhyDelay(1);
#endif

	NumBd = XLlDma_BdRingFromHw(TxRingPtr, 0xFFFFFFFF, &BdPtr);

	if (NumBd > 0) {
		Status = XLlDma_BdRingFree(TxRingPtr, NumBd, BdPtr);
		if (Status != XST_SUCCESS) {
			TemacUtilErrorTrap("Error freeing TxBDs");
		}
	}

	/*
	 * Done sending frames. Stop the device
	 */
	XLlTemac_Stop(TemacInstancePtr);

	return XST_SUCCESS;
}
/**
*
* This example uses polled mode to queue up multiple frames in the packet
* FIFOs before sending them in a single burst. Receive packets are handled in
* a similar way.
*
* @param    None.
*
* @return   XST_SUCCESS to indicate success, otherwise XST_FAILURE.
*
* @note     None.
*
******************************************************************************/
int TemacMultipleFramesPolledExample(void)
{
	u32 FramesToLoopback;
	u32 PayloadSize;
	u32 TxFrameLength;
	u32 RxFrameLength;
	u32 FifoFreeBytes;
	u32 Index;

	/*
	 * Start the TEMAC device
	 */
	XLlTemac_Start(&TemacInstance);

	/*
	 * Setup the number of frames to loopback (FramesToLoopback) and the size
	 * of the frame (PayloadSize) to loopback. The default settings should
	 * work for every case. Modifying the settings can cause problems, see
	 * discussion below:
	 *
	 * If PayloadSize is set small and FramesToLoopback high, then it is
	 * possible to cause the transmit status FIFO to overflow.
	 *
	 * If PayloadSize is set large and FramesToLoopback high, then it is
	 * possible to cause the transmit packet FIFO to overflow.
	 *
	 * Either of these scenarios may be worth trying out to observe how the
	 * driver reacts. The exact values to cause these types of errors
	 * will vary due to the sizes of the FIFOs selected at hardware build
	 * time. But the following settings should create problems for all
	 * FIFO sizes:
	 *
	 * Transmit status FIFO overflow
	 *    PayloadSize = 1
	 *    FramesToLoopback = 1000
	 *
	 * Transmit packet FIFO overflow
	 *    PayloadSize = 1500
	 *    FramesToLoopback = 16
	 *
	 * These values should always work without error
	 *    PayloadSize = 100
	 *    FramesToLoopback = 5
	 */
	PayloadSize = 100;
	FramesToLoopback = 5;

	/*
	 * Calculate Tx frame length (not including FCS)
	 */
	TxFrameLength = XTE_HDR_SIZE + PayloadSize;

	/*
	 * Setup the packet to be transmitted
	 */
	TemacUtilFrameHdrFormatMAC(&TxFrame, TemacMAC);
	TemacUtilFrameHdrFormatType(&TxFrame, PayloadSize);
	TemacUtilFrameSetPayloadData(&TxFrame, PayloadSize);

	/****************/
	/* Send packets */
	/****************/

	/*
	 * Since we may be interested to see what happens when FIFOs overflow, don't
	 * check for room in the transmit packet FIFO prior to writing to it.
	 */

	/*
	 * Write frame data to FIFO
	 * Fifo core only allows loading and sending one frame at a time.
	 */
	for (Index = 0; Index < FramesToLoopback; Index++) {
		/* Make sure there is room in the FIFO */
		do {
			FifoFreeBytes = XLlFifo_TxVacancy(&FifoInstance);
		} while (FifoFreeBytes < TxFrameLength);

		XLlFifo_Write(&FifoInstance, TxFrame, TxFrameLength);
		XLlFifo_TxSetLen(&FifoInstance, TxFrameLength);

		switch (TemacPollForTxStatus()) {
		case XST_SUCCESS:	/* Got a sucessfull transmit status */
			break;

		case XST_NO_DATA:	/* Timed out */
			TemacUtilErrorTrap("Tx timeout");
			return XST_FAILURE;
			break;

		default:	/* Some other error */
			TemacResetDevice();
			return XST_FAILURE;
		}
	}

	/**********************/
	/* Receive the packet */
	/**********************/

	/*
	 * Wait for the packets to arrive
	 * The Fifo core only allows us to pull out one frame at a time.
	 */
	for (Index = 0; Index < FramesToLoopback; Index++) {
		/*
		 * Wait for packet Rx
		 */
		switch (TemacPollForRxStatus()) {
		case XST_SUCCESS:	/* Got a successfull receive status */
			break;

		case XST_NO_DATA:	/* Timed out */
			TemacUtilErrorTrap("Rx timeout");
			return XST_FAILURE;
			break;

		default:	/* Some other error */
			TemacResetDevice();
			return XST_FAILURE;
		}

		while(XLlFifo_RxOccupancy(&FifoInstance)) {
			/*
			 * A packet has arrived, get its length
			 */
			RxFrameLength = XLlFifo_RxGetLen(&FifoInstance);
	
			/*
			 * Verify the received frame length
			 */
			if ((RxFrameLength) != TxFrameLength) {
				TemacUtilErrorTrap("Receive length incorrect");
				return XST_FAILURE;
			}
			/*
			 * Read the received packet data
			 */
			XLlFifo_Read(&FifoInstance, &RxFrame, RxFrameLength);

			if (TemacUtilFrameVerify(&TxFrame, &RxFrame) != 0) {
				TemacUtilErrorTrap("Receive Data Mismatch");
				return XST_FAILURE;
			}
		}
	}

	/*
	 * Stop device
	 */
	XLlTemac_Stop(&TemacInstance);

	return XST_SUCCESS;
}
/**
*
* This function demonstrates the usage of the TEMAC by sending and receiving
* a single frame in polled mode.
*
* @param    None.
*
* @return   XST_SUCCESS to indicate success, otherwise XST_FAILURE.
*
* @note     None.
*
******************************************************************************/
int TemacSingleFramePolledExample(void)
{
	u32 FifoFreeBytes;
	int PayloadSize = 100;
	u32 TxFrameLength;
	u32 RxFrameLength;

	/*
	 * Start the TEMAC device
	 */
	XLlTemac_Start(&TemacInstance);

	/*
	 * Setup the packet to be transmitted
	 */
	TemacUtilFrameHdrFormatMAC(&TxFrame, TemacMAC);
	TemacUtilFrameHdrFormatType(&TxFrame, PayloadSize);
	TemacUtilFrameSetPayloadData(&TxFrame, PayloadSize);

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

	/*
	 * Calculate frame length (not including FCS)
	 */
	TxFrameLength = XTE_HDR_SIZE + PayloadSize;

	/*******************/
	/* Send the packet */
	/*******************/

	/*
	 * Wait for enough room in FIFO to become available
	 */
	do {
		FifoFreeBytes = XLlFifo_TxVacancy(&FifoInstance);
	} while (FifoFreeBytes < TxFrameLength);

	/*
	 * Write the frame data to FIFO
	 */
	XLlFifo_Write(&FifoInstance, TxFrame, TxFrameLength);

	/*
	 * Initiate transmit
	 */
	XLlFifo_TxSetLen(&FifoInstance, TxFrameLength);

	/*
	 * Wait for status of the transmitted packet
	 */
	switch (TemacPollForTxStatus()) {
	case XST_SUCCESS:	/* Got a sucessfull transmit status */
		break;

	case XST_NO_DATA:	/* Timed out */
		TemacUtilErrorTrap("Tx timeout");
		return XST_FAILURE;

	default:		/* Some other error */
		return XST_FAILURE;
	}

	/**********************/
	/* Receive the packet */
	/**********************/

	/*
	 * Wait for packet Rx
	 */
	switch (TemacPollForRxStatus()) {
	case XST_SUCCESS:	/* Got a sucessfull receive status */
		break;

	case XST_NO_DATA:	/* Timed out */
		TemacUtilErrorTrap("Rx timeout");
		return XST_FAILURE;

	default:		/* Some other error */
		return XST_FAILURE;
	}

	while(XLlFifo_RxOccupancy(&FifoInstance)) {
		/*
		 * A packet as arrived, get its length
		 */
		RxFrameLength = XLlFifo_RxGetLen(&FifoInstance);

		/*
		 * Read the received packet data
		 */
		XLlFifo_Read(&FifoInstance, &RxFrame, RxFrameLength);
	
		/*
		 * Verify the received frame length
		 */
		if ((RxFrameLength) != TxFrameLength) {
			TemacUtilErrorTrap("Receive length incorrect");
			return XST_FAILURE;
		}

		/*
		 * Validate frame data
		 */
		if (TemacUtilFrameVerify(&TxFrame, &RxFrame) != 0) {
			TemacUtilErrorTrap("Receive Data mismatch");
			return XST_FAILURE;
		}
	}

	/*
	 * Stop device
	 */
	XLlTemac_Stop(&TemacInstance);

	return XST_SUCCESS;
}