drivers/net/xilinx_emac.c - uboot/prism - Git at Google

 /******************************************************************************
  *
  * XILINX IS PROVIDING THIS DESIGN, CODE, OR INFORMATION "AS IS"
  * AS A COURTESY TO YOU, SOLELY FOR USE IN DEVELOPING PROGRAMS AND
  * SOLUTIONS FOR XILINX DEVICES. BY PROVIDING THIS DESIGN, CODE,
  * OR INFORMATION AS ONE POSSIBLE IMPLEMENTATION OF THIS FEATURE,
  * APPLICATION OR STANDARD, XILINX IS MAKING NO REPRESENTATION
  * THAT THIS IMPLEMENTATION IS FREE FROM ANY CLAIMS OF INFRINGEMENT,
  * AND YOU ARE RESPONSIBLE FOR OBTAINING ANY RIGHTS YOU MAY REQUIRE
  * FOR YOUR IMPLEMENTATION. XILINX EXPRESSLY DISCLAIMS ANY
  * WARRANTY WHATSOEVER WITH RESPECT TO THE ADEQUACY OF THE
  * IMPLEMENTATION, INCLUDING BUT NOT LIMITED TO ANY WARRANTIES OR
  * REPRESENTATIONS THAT THIS IMPLEMENTATION IS FREE FROM CLAIMS OF
  * INFRINGEMENT, IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS
  * FOR A PARTICULAR PURPOSE.
  *
  * (C) Copyright 2007-2008 Michal Simek
  * Michal SIMEK <monstr@monstr.eu>
  *
  * (c) Copyright 2003 Xilinx Inc.
  * All rights reserved.
  *
  ******************************************************************************/

 #include <config.h>
 #include <common.h>
 #include <net.h>
 #include <asm/io.h>

 #include <asm/asm.h>

 #undef DEBUG

 typedef struct {
 	u32 regbaseaddress;	/* Base address of registers */
 	u32 databaseaddress;	/* Base address of data for FIFOs */
 } xpacketfifov100b;

 typedef struct {
 	u32 baseaddress;	/* Base address (of IPIF) */
 	u32 isstarted;		/* Device is currently started 0-no, 1-yes */
 	xpacketfifov100b recvfifo;	/* FIFO used to receive frames */
 	xpacketfifov100b sendfifo;	/* FIFO used to send frames */
 } xemac;

 #define XIIF_V123B_IISR_OFFSET	32UL /* IP interrupt status register */
 #define XIIF_V123B_RESET_MASK		0xAUL
 #define XIIF_V123B_RESETR_OFFSET	64UL /* reset register */

 /* This constant is used with the Reset Register */
 #define XPF_RESET_FIFO_MASK		0x0000000A
 #define XPF_COUNT_STATUS_REG_OFFSET	4UL

 /* These constants are used with the Occupancy/Vacancy Count Register. This
  * register also contains FIFO status */
 #define XPF_COUNT_MASK			0x0000FFFF
 #define XPF_DEADLOCK_MASK		0x20000000

 /* Offset of the MAC registers from the IPIF base address */
 #define XEM_REG_OFFSET		0x1100UL

 /*
  * Register offsets for the Ethernet MAC. Each register is 32 bits.
  */
 #define XEM_ECR_OFFSET	(XEM_REG_OFFSET + 0x4)	/* MAC Control */
 #define XEM_SAH_OFFSET	(XEM_REG_OFFSET + 0xC)	/* Station addr, high */
 #define XEM_SAL_OFFSET	(XEM_REG_OFFSET + 0x10)	/* Station addr, low */
 #define XEM_RPLR_OFFSET	(XEM_REG_OFFSET + 0x1C)	/* Rx packet length */
 #define XEM_TPLR_OFFSET	(XEM_REG_OFFSET + 0x20)	/* Tx packet length */
 #define XEM_TSR_OFFSET	(XEM_REG_OFFSET + 0x24)	/* Tx status */

 #define XEM_PFIFO_OFFSET	0x2000UL
 /* Tx registers */
 #define XEM_PFIFO_TXREG_OFFSET	(XEM_PFIFO_OFFSET + 0x0)
 /* Rx registers */
 #define XEM_PFIFO_RXREG_OFFSET	(XEM_PFIFO_OFFSET + 0x10)
 /* Tx keyhole */
 #define XEM_PFIFO_TXDATA_OFFSET	(XEM_PFIFO_OFFSET + 0x100)
 /* Rx keyhole */
 #define XEM_PFIFO_RXDATA_OFFSET	(XEM_PFIFO_OFFSET + 0x200)

 /*
  * EMAC Interrupt Registers (Status and Enable) masks. These registers are
  * part of the IPIF IP Interrupt registers
  */
 /* A mask for all transmit interrupts, used in polled mode */
 #define XEM_EIR_XMIT_ALL_MASK	(XEM_EIR_XMIT_DONE_MASK |\
 				XEM_EIR_XMIT_ERROR_MASK | \
 				XEM_EIR_XMIT_SFIFO_EMPTY_MASK |\
 				XEM_EIR_XMIT_LFIFO_FULL_MASK)

 /* Xmit complete */
 #define XEM_EIR_XMIT_DONE_MASK		0x00000001UL
 /* Recv complete */
 #define XEM_EIR_RECV_DONE_MASK		0x00000002UL
 /* Xmit error */
 #define XEM_EIR_XMIT_ERROR_MASK		0x00000004UL
 /* Recv error */
 #define XEM_EIR_RECV_ERROR_MASK		0x00000008UL
 /* Xmit status fifo empty */
 #define XEM_EIR_XMIT_SFIFO_EMPTY_MASK	0x00000010UL
 /* Recv length fifo empty */
 #define XEM_EIR_RECV_LFIFO_EMPTY_MASK	0x00000020UL
 /* Xmit length fifo full */
 #define XEM_EIR_XMIT_LFIFO_FULL_MASK	0x00000040UL
 /* Recv length fifo overrun */
 #define XEM_EIR_RECV_LFIFO_OVER_MASK	0x00000080UL
 /* Recv length fifo underrun */
 #define XEM_EIR_RECV_LFIFO_UNDER_MASK	0x00000100UL
 /* Xmit status fifo overrun */
 #define XEM_EIR_XMIT_SFIFO_OVER_MASK	0x00000200UL
 /* Transmit status fifo underrun */
 #define XEM_EIR_XMIT_SFIFO_UNDER_MASK	0x00000400UL
 /* Transmit length fifo overrun */
 #define XEM_EIR_XMIT_LFIFO_OVER_MASK	0x00000800UL
 /* Transmit length fifo underrun */
 #define XEM_EIR_XMIT_LFIFO_UNDER_MASK	0x00001000UL
 /* Transmit pause pkt received */
 #define XEM_EIR_XMIT_PAUSE_MASK		0x00002000UL

 /*
  * EMAC Control Register (ECR)
  */
 /* Full duplex mode */
 #define XEM_ECR_FULL_DUPLEX_MASK	0x80000000UL
 /* Reset transmitter */
 #define XEM_ECR_XMIT_RESET_MASK		0x40000000UL
 /* Enable transmitter */
 #define XEM_ECR_XMIT_ENABLE_MASK	0x20000000UL
 /* Reset receiver */
 #define XEM_ECR_RECV_RESET_MASK		0x10000000UL
 /* Enable receiver */
 #define XEM_ECR_RECV_ENABLE_MASK	0x08000000UL
 /* Enable PHY */
 #define XEM_ECR_PHY_ENABLE_MASK		0x04000000UL
 /* Enable xmit pad insert */
 #define XEM_ECR_XMIT_PAD_ENABLE_MASK	0x02000000UL
 /* Enable xmit FCS insert */
 #define XEM_ECR_XMIT_FCS_ENABLE_MASK	0x01000000UL
 /* Enable unicast addr */
 #define XEM_ECR_UNICAST_ENABLE_MASK	0x00020000UL
 /* Enable broadcast addr */
 #define XEM_ECR_BROAD_ENABLE_MASK	0x00008000UL

 /*
  * Transmit Status Register (TSR)
  */
 /* Transmit excess deferral */
 #define XEM_TSR_EXCESS_DEFERRAL_MASK	0x80000000UL
 /* Transmit late collision */
 #define XEM_TSR_LATE_COLLISION_MASK	0x01000000UL

 #define ENET_MAX_MTU		PKTSIZE
 #define ENET_ADDR_LENGTH	6

 static unsigned int etherrxbuff[PKTSIZE_ALIGN/4]; /* Receive buffer */

 static u8 emacaddr[ENET_ADDR_LENGTH] = { 0x00, 0x0a, 0x35, 0x00, 0x22, 0x01 };

 static xemac emac;

 void eth_halt(void)
 {
 	debug ("eth_halt\n");
 }

 int eth_init(bd_t * bis)
 {
 	uchar enetaddr[6];
 	u32 helpreg;
 	debug ("EMAC Initialization Started\n\r");

 	if (emac.isstarted) {
 		puts("Emac is started\n");
 		return 0;
 	}

 	memset (&emac, 0, sizeof (xemac));

 	emac.baseaddress = XILINX_EMAC_BASEADDR;

 	/* Setting up FIFOs */
 	emac.recvfifo.regbaseaddress = emac.baseaddress +
 					XEM_PFIFO_RXREG_OFFSET;
 	emac.recvfifo.databaseaddress = emac.baseaddress +
 					XEM_PFIFO_RXDATA_OFFSET;
 	out_be32 (emac.recvfifo.regbaseaddress, XPF_RESET_FIFO_MASK);

 	emac.sendfifo.regbaseaddress = emac.baseaddress +
 					XEM_PFIFO_TXREG_OFFSET;
 	emac.sendfifo.databaseaddress = emac.baseaddress +
 					XEM_PFIFO_TXDATA_OFFSET;
 	out_be32 (emac.sendfifo.regbaseaddress, XPF_RESET_FIFO_MASK);

 	/* Reset the entire IPIF */
 	out_be32 (emac.baseaddress + XIIF_V123B_RESETR_OFFSET,
 					XIIF_V123B_RESET_MASK);

 	/* Stopping EMAC for setting up MAC */
 	helpreg = in_be32 (emac.baseaddress + XEM_ECR_OFFSET);
 	helpreg &= ~(XEM_ECR_XMIT_ENABLE_MASK | XEM_ECR_RECV_ENABLE_MASK);
 	out_be32 (emac.baseaddress + XEM_ECR_OFFSET, helpreg);

 	if (!eth_getenv_enetaddr("ethaddr", enetaddr)) {
 		memcpy(enetaddr, emacaddr, ENET_ADDR_LENGTH);
 		eth_setenv_enetaddr("ethaddr", enetaddr);
 	}

 	/* Set the device station address high and low registers */
 	helpreg = (enetaddr[0] << 8) | enetaddr[1];
 	out_be32 (emac.baseaddress + XEM_SAH_OFFSET, helpreg);
 	helpreg = (enetaddr[2] << 24) | (enetaddr[3] << 16) |
 			(enetaddr[4] << 8) | enetaddr[5];
 	out_be32 (emac.baseaddress + XEM_SAL_OFFSET, helpreg);

 	helpreg = XEM_ECR_UNICAST_ENABLE_MASK | XEM_ECR_BROAD_ENABLE_MASK |
 		XEM_ECR_FULL_DUPLEX_MASK | XEM_ECR_XMIT_FCS_ENABLE_MASK |
 		XEM_ECR_XMIT_PAD_ENABLE_MASK | XEM_ECR_PHY_ENABLE_MASK;
 	out_be32 (emac.baseaddress + XEM_ECR_OFFSET, helpreg);

 	emac.isstarted = 1;

 	/* Enable the transmitter, and receiver */
 	helpreg = in_be32 (emac.baseaddress + XEM_ECR_OFFSET);
 	helpreg &= ~(XEM_ECR_XMIT_RESET_MASK | XEM_ECR_RECV_RESET_MASK);
 	helpreg |= (XEM_ECR_XMIT_ENABLE_MASK | XEM_ECR_RECV_ENABLE_MASK);
 	out_be32 (emac.baseaddress + XEM_ECR_OFFSET, helpreg);

 	printf("EMAC Initialization complete\n\r");
 	return 0;
 }

 int eth_send(volatile void *ptr, int len)
 {
 	u32 intrstatus;
 	u32 xmitstatus;
 	u32 fifocount;
 	u32 wordcount;
 	u32 extrabytecount;
 	u32 *wordbuffer = (u32 *) ptr;

 	if (len > ENET_MAX_MTU)
 		len = ENET_MAX_MTU;

 	/*
 	 * Check for overruns and underruns for the transmit status and length
 	 * FIFOs and make sure the send packet FIFO is not deadlocked.
 	 * Any of these conditions is bad enough that we do not want to
 	 * continue. The upper layer software should reset the device to resolve
 	 * the error.
 	 */
 	intrstatus = in_be32 ((emac.baseaddress) + XIIF_V123B_IISR_OFFSET);
 	if (intrstatus & (XEM_EIR_XMIT_SFIFO_OVER_MASK |
 			XEM_EIR_XMIT_LFIFO_OVER_MASK)) {
 		debug ("Transmitting overrun error\n");
 		return 0;
 	} else if (intrstatus & (XEM_EIR_XMIT_SFIFO_UNDER_MASK |
 			XEM_EIR_XMIT_LFIFO_UNDER_MASK)) {
 		debug ("Transmitting underrun error\n");
 		return 0;
 	} else if (in_be32 (emac.sendfifo.regbaseaddress +
 			XPF_COUNT_STATUS_REG_OFFSET) & XPF_DEADLOCK_MASK) {
 		debug ("Transmitting fifo error\n");
 		return 0;
 	}

 	/*
 	 * Before writing to the data FIFO, make sure the length FIFO is not
 	 * full. The data FIFO might not be full yet even though the length FIFO
 	 * is. This avoids an overrun condition on the length FIFO and keeps the
 	 * FIFOs in sync.
 	 *
 	 * Clear the latched LFIFO_FULL bit so next time around the most
 	 * current status is represented
 	 */
 	if (intrstatus & XEM_EIR_XMIT_LFIFO_FULL_MASK) {
 		out_be32 ((emac.baseaddress) + XIIF_V123B_IISR_OFFSET,
 			intrstatus & XEM_EIR_XMIT_LFIFO_FULL_MASK);
 		debug ("Fifo is full\n");
 		return 0;
 	}

 	/* get the count of how many words may be inserted into the FIFO */
 	fifocount = in_be32 (emac.sendfifo.regbaseaddress +
 				XPF_COUNT_STATUS_REG_OFFSET) & XPF_COUNT_MASK;
 	wordcount = len >> 2;
 	extrabytecount = len & 0x3;

 	if (fifocount < wordcount) {
 		debug ("Sending packet is larger then size of FIFO\n");
 		return 0;
 	}

 	for (fifocount = 0; fifocount < wordcount; fifocount++) {
 		out_be32 (emac.sendfifo.databaseaddress, wordbuffer[fifocount]);
 	}
 	if (extrabytecount > 0) {
 		u32 lastword = 0;
 		u8 *extrabytesbuffer = (u8 *) (wordbuffer + wordcount);

 		if (extrabytecount == 1) {
 			lastword = extrabytesbuffer[0] << 24;
 		} else if (extrabytecount == 2) {
 			lastword = extrabytesbuffer[0] << 24 |
 				extrabytesbuffer[1] << 16;
 		} else if (extrabytecount == 3) {
 			lastword = extrabytesbuffer[0] << 24 |
 				extrabytesbuffer[1] << 16 |
 				extrabytesbuffer[2] << 8;
 		}
 		out_be32 (emac.sendfifo.databaseaddress, lastword);
 	}

 	/* Loop on the MAC's status to wait for any pause to complete */
 	intrstatus = in_be32 ((emac.baseaddress) + XIIF_V123B_IISR_OFFSET);
 	while ((intrstatus & XEM_EIR_XMIT_PAUSE_MASK) != 0) {
 		intrstatus = in_be32 ((emac.baseaddress) +
 					XIIF_V123B_IISR_OFFSET);
 		/* Clear the pause status from the transmit status register */
 		out_be32 ((emac.baseaddress) + XIIF_V123B_IISR_OFFSET,
 				intrstatus & XEM_EIR_XMIT_PAUSE_MASK);
 	}

 	/*
 	 * Set the MAC's transmit packet length register to tell it to transmit
 	 */
 	out_be32 (emac.baseaddress + XEM_TPLR_OFFSET, len);

 	/*
 	 * Loop on the MAC's status to wait for the transmit to complete.
 	 * The transmit status is in the FIFO when the XMIT_DONE bit is set.
 	 */
 	do {
 		intrstatus = in_be32 ((emac.baseaddress) +
 						XIIF_V123B_IISR_OFFSET);
 	}
 	while ((intrstatus & XEM_EIR_XMIT_DONE_MASK) == 0);

 	xmitstatus = in_be32 (emac.baseaddress + XEM_TSR_OFFSET);

 	if (intrstatus & (XEM_EIR_XMIT_SFIFO_OVER_MASK |
 					XEM_EIR_XMIT_LFIFO_OVER_MASK)) {
 		debug ("Transmitting overrun error\n");
 		return 0;
 	} else if (intrstatus & (XEM_EIR_XMIT_SFIFO_UNDER_MASK |
 					XEM_EIR_XMIT_LFIFO_UNDER_MASK)) {
 		debug ("Transmitting underrun error\n");
 		return 0;
 	}

 	/* Clear the interrupt status register of transmit statuses */
 	out_be32 ((emac.baseaddress) + XIIF_V123B_IISR_OFFSET,
 				intrstatus & XEM_EIR_XMIT_ALL_MASK);

 	/*
 	 * Collision errors are stored in the transmit status register
 	 * instead of the interrupt status register
 	 */
 	if ((xmitstatus & XEM_TSR_EXCESS_DEFERRAL_MASK) ||
 				(xmitstatus & XEM_TSR_LATE_COLLISION_MASK)) {
 		debug ("Transmitting collision error\n");
 		return 0;
 	}
 	return 1;
 }

 int eth_rx(void)
 {
 	u32 pktlength;
 	u32 intrstatus;
 	u32 fifocount;
 	u32 wordcount;
 	u32 extrabytecount;
 	u32 lastword;
 	u8 *extrabytesbuffer;

 	if (in_be32 (emac.recvfifo.regbaseaddress + XPF_COUNT_STATUS_REG_OFFSET)
 			& XPF_DEADLOCK_MASK) {
 		out_be32 (emac.recvfifo.regbaseaddress, XPF_RESET_FIFO_MASK);
 		debug ("Receiving FIFO deadlock\n");
 		return 0;
 	}

 	/*
 	 * Get the interrupt status to know what happened (whether an error
 	 * occurred and/or whether frames have been received successfully).
 	 * When clearing the intr status register, clear only statuses that
 	 * pertain to receive.
 	 */
 	intrstatus = in_be32 ((emac.baseaddress) + XIIF_V123B_IISR_OFFSET);
 	/*
 	 * Before reading from the length FIFO, make sure the length FIFO is not
 	 * empty. We could cause an underrun error if we try to read from an
 	 * empty FIFO.
 	 */
 	if (!(intrstatus & XEM_EIR_RECV_DONE_MASK)) {
 		/* debug ("Receiving FIFO is empty\n"); */
 		return 0;
 	}

 	/*
 	 * Determine, from the MAC, the length of the next packet available
 	 * in the data FIFO (there should be a non-zero length here)
 	 */
 	pktlength = in_be32 (emac.baseaddress + XEM_RPLR_OFFSET);
 	if (!pktlength) {
 		return 0;
 	}

 	/*
 	 * Write the RECV_DONE bit in the status register to clear it. This bit
 	 * indicates the RPLR is non-empty, and we know it's set at this point.
 	 * We clear it so that subsequent entry into this routine will reflect
 	 * the current status. This is done because the non-empty bit is latched
 	 * in the IPIF, which means it may indicate a non-empty condition even
 	 * though there is something in the FIFO.
 	 */
 	out_be32 ((emac.baseaddress) + XIIF_V123B_IISR_OFFSET,
 						XEM_EIR_RECV_DONE_MASK);

 	fifocount = in_be32 (emac.recvfifo.regbaseaddress +
 				XPF_COUNT_STATUS_REG_OFFSET) & XPF_COUNT_MASK;

 	if ((fifocount * 4) < pktlength) {
 		debug ("Receiving FIFO is smaller than packet size.\n");
 		return 0;
 	}

 	wordcount = pktlength >> 2;
 	extrabytecount = pktlength & 0x3;

 	for (fifocount = 0; fifocount < wordcount; fifocount++) {
 		etherrxbuff[fifocount] =
 				in_be32 (emac.recvfifo.databaseaddress);
 	}

 	/*
 	 * if there are extra bytes to handle, read the last word from the FIFO
 	 * and insert the extra bytes into the buffer
 	 */
 	if (extrabytecount > 0) {
 		extrabytesbuffer = (u8 *) (etherrxbuff + wordcount);

 		lastword = in_be32 (emac.recvfifo.databaseaddress);

 		/*
 		 * one extra byte in the last word, put the byte into the next
 		 * location of the buffer, bytes in a word of the FIFO are
 		 * ordered from most significant byte to least
 		 */
 		if (extrabytecount == 1) {
 			extrabytesbuffer[0] = (u8) (lastword >> 24);
 		} else if (extrabytecount == 2) {
 			extrabytesbuffer[0] = (u8) (lastword >> 24);
 			extrabytesbuffer[1] = (u8) (lastword >> 16);
 		} else if (extrabytecount == 3) {
 			extrabytesbuffer[0] = (u8) (lastword >> 24);
 			extrabytesbuffer[1] = (u8) (lastword >> 16);
 			extrabytesbuffer[2] = (u8) (lastword >> 8);
 		}
 	}
 	NetReceive((uchar *)etherrxbuff, pktlength);
 	return 1;
 }
	/******************************************************************************
	*
	* XILINX IS PROVIDING THIS DESIGN, CODE, OR INFORMATION "AS IS"
	* AS A COURTESY TO YOU, SOLELY FOR USE IN DEVELOPING PROGRAMS AND
	* SOLUTIONS FOR XILINX DEVICES. BY PROVIDING THIS DESIGN, CODE,
	* OR INFORMATION AS ONE POSSIBLE IMPLEMENTATION OF THIS FEATURE,
	* APPLICATION OR STANDARD, XILINX IS MAKING NO REPRESENTATION
	* THAT THIS IMPLEMENTATION IS FREE FROM ANY CLAIMS OF INFRINGEMENT,
	* AND YOU ARE RESPONSIBLE FOR OBTAINING ANY RIGHTS YOU MAY REQUIRE
	* FOR YOUR IMPLEMENTATION. XILINX EXPRESSLY DISCLAIMS ANY
	* WARRANTY WHATSOEVER WITH RESPECT TO THE ADEQUACY OF THE
	* IMPLEMENTATION, INCLUDING BUT NOT LIMITED TO ANY WARRANTIES OR
	* REPRESENTATIONS THAT THIS IMPLEMENTATION IS FREE FROM CLAIMS OF
	* INFRINGEMENT, IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS
	* FOR A PARTICULAR PURPOSE.
	*
	* (C) Copyright 2007-2008 Michal Simek
	* Michal SIMEK <monstr@monstr.eu>
	*
	* (c) Copyright 2003 Xilinx Inc.
	* All rights reserved.
	*
	******************************************************************************/

	#include <config.h>
	#include <common.h>
	#include <net.h>
	#include <asm/io.h>

	#include <asm/asm.h>

	#undef DEBUG

	typedef struct {
	u32 regbaseaddress; /* Base address of registers */
	u32 databaseaddress; /* Base address of data for FIFOs */
	} xpacketfifov100b;

	typedef struct {
	u32 baseaddress; /* Base address (of IPIF) */
	u32 isstarted; /* Device is currently started 0-no, 1-yes */
	xpacketfifov100b recvfifo; /* FIFO used to receive frames */
	xpacketfifov100b sendfifo; /* FIFO used to send frames */
	} xemac;

	#define XIIF_V123B_IISR_OFFSET 32UL /* IP interrupt status register */
	#define XIIF_V123B_RESET_MASK 0xAUL
	#define XIIF_V123B_RESETR_OFFSET 64UL /* reset register */

	/* This constant is used with the Reset Register */
	#define XPF_RESET_FIFO_MASK 0x0000000A
	#define XPF_COUNT_STATUS_REG_OFFSET 4UL

	/* These constants are used with the Occupancy/Vacancy Count Register. This
	* register also contains FIFO status */
	#define XPF_COUNT_MASK 0x0000FFFF
	#define XPF_DEADLOCK_MASK 0x20000000

	/* Offset of the MAC registers from the IPIF base address */
	#define XEM_REG_OFFSET 0x1100UL

	/*
	* Register offsets for the Ethernet MAC. Each register is 32 bits.
	*/
	#define XEM_ECR_OFFSET (XEM_REG_OFFSET + 0x4) /* MAC Control */
	#define XEM_SAH_OFFSET (XEM_REG_OFFSET + 0xC) /* Station addr, high */
	#define XEM_SAL_OFFSET (XEM_REG_OFFSET + 0x10) /* Station addr, low */
	#define XEM_RPLR_OFFSET (XEM_REG_OFFSET + 0x1C) /* Rx packet length */
	#define XEM_TPLR_OFFSET (XEM_REG_OFFSET + 0x20) /* Tx packet length */
	#define XEM_TSR_OFFSET (XEM_REG_OFFSET + 0x24) /* Tx status */

	#define XEM_PFIFO_OFFSET 0x2000UL
	/* Tx registers */
	#define XEM_PFIFO_TXREG_OFFSET (XEM_PFIFO_OFFSET + 0x0)
	/* Rx registers */
	#define XEM_PFIFO_RXREG_OFFSET (XEM_PFIFO_OFFSET + 0x10)
	/* Tx keyhole */
	#define XEM_PFIFO_TXDATA_OFFSET (XEM_PFIFO_OFFSET + 0x100)
	/* Rx keyhole */
	#define XEM_PFIFO_RXDATA_OFFSET (XEM_PFIFO_OFFSET + 0x200)

	/*
	* EMAC Interrupt Registers (Status and Enable) masks. These registers are
	* part of the IPIF IP Interrupt registers
	*/
	/* A mask for all transmit interrupts, used in polled mode */
	#define XEM_EIR_XMIT_ALL_MASK (XEM_EIR_XMIT_DONE_MASK \|\
	XEM_EIR_XMIT_ERROR_MASK \| \
	XEM_EIR_XMIT_SFIFO_EMPTY_MASK \|\
	XEM_EIR_XMIT_LFIFO_FULL_MASK)

	/* Xmit complete */
	#define XEM_EIR_XMIT_DONE_MASK 0x00000001UL
	/* Recv complete */
	#define XEM_EIR_RECV_DONE_MASK 0x00000002UL
	/* Xmit error */
	#define XEM_EIR_XMIT_ERROR_MASK 0x00000004UL
	/* Recv error */
	#define XEM_EIR_RECV_ERROR_MASK 0x00000008UL
	/* Xmit status fifo empty */
	#define XEM_EIR_XMIT_SFIFO_EMPTY_MASK 0x00000010UL
	/* Recv length fifo empty */
	#define XEM_EIR_RECV_LFIFO_EMPTY_MASK 0x00000020UL
	/* Xmit length fifo full */
	#define XEM_EIR_XMIT_LFIFO_FULL_MASK 0x00000040UL
	/* Recv length fifo overrun */
	#define XEM_EIR_RECV_LFIFO_OVER_MASK 0x00000080UL
	/* Recv length fifo underrun */
	#define XEM_EIR_RECV_LFIFO_UNDER_MASK 0x00000100UL
	/* Xmit status fifo overrun */
	#define XEM_EIR_XMIT_SFIFO_OVER_MASK 0x00000200UL
	/* Transmit status fifo underrun */
	#define XEM_EIR_XMIT_SFIFO_UNDER_MASK 0x00000400UL
	/* Transmit length fifo overrun */
	#define XEM_EIR_XMIT_LFIFO_OVER_MASK 0x00000800UL
	/* Transmit length fifo underrun */
	#define XEM_EIR_XMIT_LFIFO_UNDER_MASK 0x00001000UL
	/* Transmit pause pkt received */
	#define XEM_EIR_XMIT_PAUSE_MASK 0x00002000UL

	/*
	* EMAC Control Register (ECR)
	*/
	/* Full duplex mode */
	#define XEM_ECR_FULL_DUPLEX_MASK 0x80000000UL
	/* Reset transmitter */
	#define XEM_ECR_XMIT_RESET_MASK 0x40000000UL
	/* Enable transmitter */
	#define XEM_ECR_XMIT_ENABLE_MASK 0x20000000UL
	/* Reset receiver */
	#define XEM_ECR_RECV_RESET_MASK 0x10000000UL
	/* Enable receiver */
	#define XEM_ECR_RECV_ENABLE_MASK 0x08000000UL
	/* Enable PHY */
	#define XEM_ECR_PHY_ENABLE_MASK 0x04000000UL
	/* Enable xmit pad insert */
	#define XEM_ECR_XMIT_PAD_ENABLE_MASK 0x02000000UL
	/* Enable xmit FCS insert */
	#define XEM_ECR_XMIT_FCS_ENABLE_MASK 0x01000000UL
	/* Enable unicast addr */
	#define XEM_ECR_UNICAST_ENABLE_MASK 0x00020000UL
	/* Enable broadcast addr */
	#define XEM_ECR_BROAD_ENABLE_MASK 0x00008000UL

	/*
	* Transmit Status Register (TSR)
	*/
	/* Transmit excess deferral */
	#define XEM_TSR_EXCESS_DEFERRAL_MASK 0x80000000UL
	/* Transmit late collision */
	#define XEM_TSR_LATE_COLLISION_MASK 0x01000000UL

	#define ENET_MAX_MTU PKTSIZE
	#define ENET_ADDR_LENGTH 6

	static unsigned int etherrxbuff[PKTSIZE_ALIGN/4]; /* Receive buffer */

	static u8 emacaddr[ENET_ADDR_LENGTH] = { 0x00, 0x0a, 0x35, 0x00, 0x22, 0x01 };

	static xemac emac;

	void eth_halt(void)
	{
	debug ("eth_halt\n");
	}

	int eth_init(bd_t * bis)
	{
	uchar enetaddr[6];
	u32 helpreg;
	debug ("EMAC Initialization Started\n\r");

	if (emac.isstarted) {
	puts("Emac is started\n");
	return 0;
	}

	memset (&emac, 0, sizeof (xemac));

	emac.baseaddress = XILINX_EMAC_BASEADDR;

	/* Setting up FIFOs */
	emac.recvfifo.regbaseaddress = emac.baseaddress +
	XEM_PFIFO_RXREG_OFFSET;
	emac.recvfifo.databaseaddress = emac.baseaddress +
	XEM_PFIFO_RXDATA_OFFSET;
	out_be32 (emac.recvfifo.regbaseaddress, XPF_RESET_FIFO_MASK);

	emac.sendfifo.regbaseaddress = emac.baseaddress +
	XEM_PFIFO_TXREG_OFFSET;
	emac.sendfifo.databaseaddress = emac.baseaddress +
	XEM_PFIFO_TXDATA_OFFSET;
	out_be32 (emac.sendfifo.regbaseaddress, XPF_RESET_FIFO_MASK);

	/* Reset the entire IPIF */
	out_be32 (emac.baseaddress + XIIF_V123B_RESETR_OFFSET,
	XIIF_V123B_RESET_MASK);

	/* Stopping EMAC for setting up MAC */
	helpreg = in_be32 (emac.baseaddress + XEM_ECR_OFFSET);
	helpreg &= ~(XEM_ECR_XMIT_ENABLE_MASK \| XEM_ECR_RECV_ENABLE_MASK);
	out_be32 (emac.baseaddress + XEM_ECR_OFFSET, helpreg);

	if (!eth_getenv_enetaddr("ethaddr", enetaddr)) {
	memcpy(enetaddr, emacaddr, ENET_ADDR_LENGTH);
	eth_setenv_enetaddr("ethaddr", enetaddr);
	}

	/* Set the device station address high and low registers */
	helpreg = (enetaddr[0] << 8) \| enetaddr[1];
	out_be32 (emac.baseaddress + XEM_SAH_OFFSET, helpreg);
	helpreg = (enetaddr[2] << 24) \| (enetaddr[3] << 16) \|
	(enetaddr[4] << 8) \| enetaddr[5];
	out_be32 (emac.baseaddress + XEM_SAL_OFFSET, helpreg);

	helpreg = XEM_ECR_UNICAST_ENABLE_MASK \| XEM_ECR_BROAD_ENABLE_MASK \|
	XEM_ECR_FULL_DUPLEX_MASK \| XEM_ECR_XMIT_FCS_ENABLE_MASK \|
	XEM_ECR_XMIT_PAD_ENABLE_MASK \| XEM_ECR_PHY_ENABLE_MASK;
	out_be32 (emac.baseaddress + XEM_ECR_OFFSET, helpreg);

	emac.isstarted = 1;

	/* Enable the transmitter, and receiver */
	helpreg = in_be32 (emac.baseaddress + XEM_ECR_OFFSET);
	helpreg &= ~(XEM_ECR_XMIT_RESET_MASK \| XEM_ECR_RECV_RESET_MASK);
	helpreg \|= (XEM_ECR_XMIT_ENABLE_MASK \| XEM_ECR_RECV_ENABLE_MASK);
	out_be32 (emac.baseaddress + XEM_ECR_OFFSET, helpreg);

	printf("EMAC Initialization complete\n\r");
	return 0;
	}

	int eth_send(volatile void *ptr, int len)
	{
	u32 intrstatus;
	u32 xmitstatus;
	u32 fifocount;
	u32 wordcount;
	u32 extrabytecount;
	u32 wordbuffer = (u32 ) ptr;

	if (len > ENET_MAX_MTU)
	len = ENET_MAX_MTU;

	/*
	* Check for overruns and underruns for the transmit status and length
	* FIFOs and make sure the send packet FIFO is not deadlocked.
	* Any of these conditions is bad enough that we do not want to
	* continue. The upper layer software should reset the device to resolve
	* the error.
	*/
	intrstatus = in_be32 ((emac.baseaddress) + XIIF_V123B_IISR_OFFSET);
	if (intrstatus & (XEM_EIR_XMIT_SFIFO_OVER_MASK \|
	XEM_EIR_XMIT_LFIFO_OVER_MASK)) {
	debug ("Transmitting overrun error\n");
	return 0;
	} else if (intrstatus & (XEM_EIR_XMIT_SFIFO_UNDER_MASK \|
	XEM_EIR_XMIT_LFIFO_UNDER_MASK)) {
	debug ("Transmitting underrun error\n");
	return 0;
	} else if (in_be32 (emac.sendfifo.regbaseaddress +
	XPF_COUNT_STATUS_REG_OFFSET) & XPF_DEADLOCK_MASK) {
	debug ("Transmitting fifo error\n");
	return 0;
	}

	/*
	* Before writing to the data FIFO, make sure the length FIFO is not
	* full. The data FIFO might not be full yet even though the length FIFO
	* is. This avoids an overrun condition on the length FIFO and keeps the
	* FIFOs in sync.
	*
	* Clear the latched LFIFO_FULL bit so next time around the most
	* current status is represented
	*/
	if (intrstatus & XEM_EIR_XMIT_LFIFO_FULL_MASK) {
	out_be32 ((emac.baseaddress) + XIIF_V123B_IISR_OFFSET,
	intrstatus & XEM_EIR_XMIT_LFIFO_FULL_MASK);
	debug ("Fifo is full\n");
	return 0;
	}

	/* get the count of how many words may be inserted into the FIFO */
	fifocount = in_be32 (emac.sendfifo.regbaseaddress +
	XPF_COUNT_STATUS_REG_OFFSET) & XPF_COUNT_MASK;
	wordcount = len >> 2;
	extrabytecount = len & 0x3;

	if (fifocount < wordcount) {
	debug ("Sending packet is larger then size of FIFO\n");
	return 0;
	}

	for (fifocount = 0; fifocount < wordcount; fifocount++) {
	out_be32 (emac.sendfifo.databaseaddress, wordbuffer[fifocount]);
	}
	if (extrabytecount > 0) {
	u32 lastword = 0;
	u8 extrabytesbuffer = (u8 ) (wordbuffer + wordcount);

	if (extrabytecount == 1) {
	lastword = extrabytesbuffer[0] << 24;
	} else if (extrabytecount == 2) {
	lastword = extrabytesbuffer[0] << 24 \|
	extrabytesbuffer[1] << 16;
	} else if (extrabytecount == 3) {
	lastword = extrabytesbuffer[0] << 24 \|
	extrabytesbuffer[1] << 16 \|
	extrabytesbuffer[2] << 8;
	}
	out_be32 (emac.sendfifo.databaseaddress, lastword);
	}

	/* Loop on the MAC's status to wait for any pause to complete */
	intrstatus = in_be32 ((emac.baseaddress) + XIIF_V123B_IISR_OFFSET);
	while ((intrstatus & XEM_EIR_XMIT_PAUSE_MASK) != 0) {
	intrstatus = in_be32 ((emac.baseaddress) +
	XIIF_V123B_IISR_OFFSET);
	/* Clear the pause status from the transmit status register */
	out_be32 ((emac.baseaddress) + XIIF_V123B_IISR_OFFSET,
	intrstatus & XEM_EIR_XMIT_PAUSE_MASK);
	}

	/*
	* Set the MAC's transmit packet length register to tell it to transmit
	*/
	out_be32 (emac.baseaddress + XEM_TPLR_OFFSET, len);

	/*
	* Loop on the MAC's status to wait for the transmit to complete.
	* The transmit status is in the FIFO when the XMIT_DONE bit is set.
	*/
	do {
	intrstatus = in_be32 ((emac.baseaddress) +
	XIIF_V123B_IISR_OFFSET);
	}
	while ((intrstatus & XEM_EIR_XMIT_DONE_MASK) == 0);

	xmitstatus = in_be32 (emac.baseaddress + XEM_TSR_OFFSET);

	if (intrstatus & (XEM_EIR_XMIT_SFIFO_OVER_MASK \|
	XEM_EIR_XMIT_LFIFO_OVER_MASK)) {
	debug ("Transmitting overrun error\n");
	return 0;
	} else if (intrstatus & (XEM_EIR_XMIT_SFIFO_UNDER_MASK \|
	XEM_EIR_XMIT_LFIFO_UNDER_MASK)) {
	debug ("Transmitting underrun error\n");
	return 0;
	}

	/* Clear the interrupt status register of transmit statuses */
	out_be32 ((emac.baseaddress) + XIIF_V123B_IISR_OFFSET,
	intrstatus & XEM_EIR_XMIT_ALL_MASK);

	/*
	* Collision errors are stored in the transmit status register
	* instead of the interrupt status register
	*/
	if ((xmitstatus & XEM_TSR_EXCESS_DEFERRAL_MASK) \|\|
	(xmitstatus & XEM_TSR_LATE_COLLISION_MASK)) {
	debug ("Transmitting collision error\n");
	return 0;
	}
	return 1;
	}

	int eth_rx(void)
	{
	u32 pktlength;
	u32 intrstatus;
	u32 fifocount;
	u32 wordcount;
	u32 extrabytecount;
	u32 lastword;
	u8 *extrabytesbuffer;

	if (in_be32 (emac.recvfifo.regbaseaddress + XPF_COUNT_STATUS_REG_OFFSET)
	& XPF_DEADLOCK_MASK) {
	out_be32 (emac.recvfifo.regbaseaddress, XPF_RESET_FIFO_MASK);
	debug ("Receiving FIFO deadlock\n");
	return 0;
	}

	/*
	* Get the interrupt status to know what happened (whether an error
	* occurred and/or whether frames have been received successfully).
	* When clearing the intr status register, clear only statuses that
	* pertain to receive.
	*/
	intrstatus = in_be32 ((emac.baseaddress) + XIIF_V123B_IISR_OFFSET);
	/*
	* Before reading from the length FIFO, make sure the length FIFO is not
	* empty. We could cause an underrun error if we try to read from an
	* empty FIFO.
	*/
	if (!(intrstatus & XEM_EIR_RECV_DONE_MASK)) {
	/* debug ("Receiving FIFO is empty\n"); */
	return 0;
	}

	/*
	* Determine, from the MAC, the length of the next packet available
	* in the data FIFO (there should be a non-zero length here)
	*/
	pktlength = in_be32 (emac.baseaddress + XEM_RPLR_OFFSET);
	if (!pktlength) {
	return 0;
	}

	/*
	* Write the RECV_DONE bit in the status register to clear it. This bit
	* indicates the RPLR is non-empty, and we know it's set at this point.
	* We clear it so that subsequent entry into this routine will reflect
	* the current status. This is done because the non-empty bit is latched
	* in the IPIF, which means it may indicate a non-empty condition even
	* though there is something in the FIFO.
	*/
	out_be32 ((emac.baseaddress) + XIIF_V123B_IISR_OFFSET,
	XEM_EIR_RECV_DONE_MASK);

	fifocount = in_be32 (emac.recvfifo.regbaseaddress +
	XPF_COUNT_STATUS_REG_OFFSET) & XPF_COUNT_MASK;

	if ((fifocount * 4) < pktlength) {
	debug ("Receiving FIFO is smaller than packet size.\n");
	return 0;
	}

	wordcount = pktlength >> 2;
	extrabytecount = pktlength & 0x3;

	for (fifocount = 0; fifocount < wordcount; fifocount++) {
	etherrxbuff[fifocount] =
	in_be32 (emac.recvfifo.databaseaddress);
	}

	/*
	* if there are extra bytes to handle, read the last word from the FIFO
	* and insert the extra bytes into the buffer
	*/
	if (extrabytecount > 0) {
	extrabytesbuffer = (u8 *) (etherrxbuff + wordcount);

	lastword = in_be32 (emac.recvfifo.databaseaddress);

	/*
	* one extra byte in the last word, put the byte into the next
	* location of the buffer, bytes in a word of the FIFO are
	* ordered from most significant byte to least
	*/
	if (extrabytecount == 1) {
	extrabytesbuffer[0] = (u8) (lastword >> 24);
	} else if (extrabytecount == 2) {
	extrabytesbuffer[0] = (u8) (lastword >> 24);
	extrabytesbuffer[1] = (u8) (lastword >> 16);
	} else if (extrabytecount == 3) {
	extrabytesbuffer[0] = (u8) (lastword >> 24);
	extrabytesbuffer[1] = (u8) (lastword >> 16);
	extrabytesbuffer[2] = (u8) (lastword >> 8);
	}
	}
	NetReceive((uchar *)etherrxbuff, pktlength);
	return 1;
	}