drivers/net/xilinx_ll_temac_sdma.c - u-boot - Git at Google

 /*
  * Xilinx xps_ll_temac ethernet driver for u-boot
  *
  * SDMA sub-controller
  *
  * Copyright (C) 2011 - 2012 Stephan Linz <linz@li-pro.net>
  * Copyright (C) 2008 - 2011 Michal Simek <monstr@monstr.eu>
  * Copyright (C) 2008 - 2011 PetaLogix
  *
  * Based on Yoshio Kashiwagi kashiwagi@co-nss.co.jp driver
  * Copyright (C) 2008 Nissin Systems Co.,Ltd.
  * March 2008 created
  *
  * CREDITS: tsec driver
  *
  * SPDX-License-Identifier:	GPL-2.0+
  *
  * [0]: http://www.xilinx.com/support/documentation
  *
  * [M]:	[0]/ip_documentation/mpmc.pdf
  * [S]:	[0]/ip_documentation/xps_ll_temac.pdf
  * [A]:	[0]/application_notes/xapp1041.pdf
  */

 #include <config.h>
 #include <common.h>
 #include <net.h>

 #include <asm/types.h>
 #include <asm/io.h>

 #include "xilinx_ll_temac.h"
 #include "xilinx_ll_temac_sdma.h"

 #define TX_BUF_CNT		2

 static unsigned int rx_idx;	/* index of the current RX buffer */
 static unsigned int tx_idx;	/* index of the current TX buffer */

 struct rtx_cdmac_bd {
 	struct cdmac_bd rx[PKTBUFSRX];
 	struct cdmac_bd tx[TX_BUF_CNT];
 };

 /*
  * DMA Buffer Descriptor alignment
  *
  * If the address contained in the Next Descriptor Pointer register is not
  * 8-word aligned or reaches beyond the range of available memory, the SDMA
  * halts processing and sets the CDMAC_BD_STCTRL_ERROR bit in the respective
  * status register (tx_chnl_sts or rx_chnl_sts).
  *
  * [1]: [0]/ip_documentation/mpmc.pdf
  *      page 161, Next Descriptor Pointer
  */
 static struct rtx_cdmac_bd cdmac_bd __aligned(32);

 #if defined(CONFIG_XILINX_440) || defined(CONFIG_XILINX_405)

 /*
  * Indirect DCR access operations mi{ft}dcr_xilinx() espacialy
  * for Xilinx PowerPC implementations on FPGA.
  *
  * FIXME: This part should go up to arch/powerpc -- but where?
  */
 #include <asm/processor.h>
 #define XILINX_INDIRECT_DCR_ADDRESS_REG	0
 #define XILINX_INDIRECT_DCR_ACCESS_REG	1
 inline unsigned mifdcr_xilinx(const unsigned dcrn)
 {
 	mtdcr(XILINX_INDIRECT_DCR_ADDRESS_REG, dcrn);
 	return mfdcr(XILINX_INDIRECT_DCR_ACCESS_REG);
 }
 inline void mitdcr_xilinx(const unsigned dcrn, int val)
 {
 	mtdcr(XILINX_INDIRECT_DCR_ADDRESS_REG, dcrn);
 	mtdcr(XILINX_INDIRECT_DCR_ACCESS_REG, val);
 }

 /* Xilinx Device Control Register (DCR) in/out accessors */
 inline unsigned ll_temac_xldcr_in32(phys_addr_t addr)
 {
 	return mifdcr_xilinx((const unsigned)addr);
 }
 inline void ll_temac_xldcr_out32(phys_addr_t addr, unsigned value)
 {
 	mitdcr_xilinx((const unsigned)addr, value);
 }

 void ll_temac_collect_xldcr_sdma_reg_addr(struct eth_device *dev)
 {
 	struct ll_temac *ll_temac = dev->priv;
 	phys_addr_t dmac_ctrl = ll_temac->ctrladdr;
 	phys_addr_t *ra = ll_temac->sdma_reg_addr;

 	ra[TX_NXTDESC_PTR]   = dmac_ctrl + TX_NXTDESC_PTR;
 	ra[TX_CURBUF_ADDR]   = dmac_ctrl + TX_CURBUF_ADDR;
 	ra[TX_CURBUF_LENGTH] = dmac_ctrl + TX_CURBUF_LENGTH;
 	ra[TX_CURDESC_PTR]   = dmac_ctrl + TX_CURDESC_PTR;
 	ra[TX_TAILDESC_PTR]  = dmac_ctrl + TX_TAILDESC_PTR;
 	ra[TX_CHNL_CTRL]     = dmac_ctrl + TX_CHNL_CTRL;
 	ra[TX_IRQ_REG]       = dmac_ctrl + TX_IRQ_REG;
 	ra[TX_CHNL_STS]      = dmac_ctrl + TX_CHNL_STS;
 	ra[RX_NXTDESC_PTR]   = dmac_ctrl + RX_NXTDESC_PTR;
 	ra[RX_CURBUF_ADDR]   = dmac_ctrl + RX_CURBUF_ADDR;
 	ra[RX_CURBUF_LENGTH] = dmac_ctrl + RX_CURBUF_LENGTH;
 	ra[RX_CURDESC_PTR]   = dmac_ctrl + RX_CURDESC_PTR;
 	ra[RX_TAILDESC_PTR]  = dmac_ctrl + RX_TAILDESC_PTR;
 	ra[RX_CHNL_CTRL]     = dmac_ctrl + RX_CHNL_CTRL;
 	ra[RX_IRQ_REG]       = dmac_ctrl + RX_IRQ_REG;
 	ra[RX_CHNL_STS]      = dmac_ctrl + RX_CHNL_STS;
 	ra[DMA_CONTROL_REG]  = dmac_ctrl + DMA_CONTROL_REG;
 }

 #endif /* CONFIG_XILINX_440 || ONFIG_XILINX_405 */

 /* Xilinx Processor Local Bus (PLB) in/out accessors */
 inline unsigned ll_temac_xlplb_in32(phys_addr_t addr)
 {
 	return in_be32((void *)addr);
 }
 inline void ll_temac_xlplb_out32(phys_addr_t addr, unsigned value)
 {
 	out_be32((void *)addr, value);
 }

 /* collect all register addresses for Xilinx PLB in/out accessors */
 void ll_temac_collect_xlplb_sdma_reg_addr(struct eth_device *dev)
 {
 	struct ll_temac *ll_temac = dev->priv;
 	struct sdma_ctrl *sdma_ctrl = (void *)ll_temac->ctrladdr;
 	phys_addr_t *ra = ll_temac->sdma_reg_addr;

 	ra[TX_NXTDESC_PTR]   = (phys_addr_t)&sdma_ctrl->tx_nxtdesc_ptr;
 	ra[TX_CURBUF_ADDR]   = (phys_addr_t)&sdma_ctrl->tx_curbuf_addr;
 	ra[TX_CURBUF_LENGTH] = (phys_addr_t)&sdma_ctrl->tx_curbuf_length;
 	ra[TX_CURDESC_PTR]   = (phys_addr_t)&sdma_ctrl->tx_curdesc_ptr;
 	ra[TX_TAILDESC_PTR]  = (phys_addr_t)&sdma_ctrl->tx_taildesc_ptr;
 	ra[TX_CHNL_CTRL]     = (phys_addr_t)&sdma_ctrl->tx_chnl_ctrl;
 	ra[TX_IRQ_REG]       = (phys_addr_t)&sdma_ctrl->tx_irq_reg;
 	ra[TX_CHNL_STS]      = (phys_addr_t)&sdma_ctrl->tx_chnl_sts;
 	ra[RX_NXTDESC_PTR]   = (phys_addr_t)&sdma_ctrl->rx_nxtdesc_ptr;
 	ra[RX_CURBUF_ADDR]   = (phys_addr_t)&sdma_ctrl->rx_curbuf_addr;
 	ra[RX_CURBUF_LENGTH] = (phys_addr_t)&sdma_ctrl->rx_curbuf_length;
 	ra[RX_CURDESC_PTR]   = (phys_addr_t)&sdma_ctrl->rx_curdesc_ptr;
 	ra[RX_TAILDESC_PTR]  = (phys_addr_t)&sdma_ctrl->rx_taildesc_ptr;
 	ra[RX_CHNL_CTRL]     = (phys_addr_t)&sdma_ctrl->rx_chnl_ctrl;
 	ra[RX_IRQ_REG]       = (phys_addr_t)&sdma_ctrl->rx_irq_reg;
 	ra[RX_CHNL_STS]      = (phys_addr_t)&sdma_ctrl->rx_chnl_sts;
 	ra[DMA_CONTROL_REG]  = (phys_addr_t)&sdma_ctrl->dma_control_reg;
 }

 /* Check for TX and RX channel errors. */
 static inline int ll_temac_sdma_error(struct eth_device *dev)
 {
 	int err;
 	struct ll_temac *ll_temac = dev->priv;
 	phys_addr_t *ra = ll_temac->sdma_reg_addr;

 	err = ll_temac->in32(ra[TX_CHNL_STS]) & CHNL_STS_ERROR;
 	err |= ll_temac->in32(ra[RX_CHNL_STS]) & CHNL_STS_ERROR;

 	return err;
 }

 int ll_temac_init_sdma(struct eth_device *dev)
 {
 	struct ll_temac *ll_temac = dev->priv;
 	struct cdmac_bd *rx_dp;
 	struct cdmac_bd *tx_dp;
 	phys_addr_t *ra = ll_temac->sdma_reg_addr;
 	int i;

 	printf("%s: SDMA: %d Rx buffers, %d Tx buffers\n",
 			dev->name, PKTBUFSRX, TX_BUF_CNT);

 	/* Initialize the Rx Buffer descriptors */
 	for (i = 0; i < PKTBUFSRX; i++) {
 		rx_dp = &cdmac_bd.rx[i];
 		memset(rx_dp, 0, sizeof(*rx_dp));
 		rx_dp->next_p = rx_dp;
 		rx_dp->buf_len = PKTSIZE_ALIGN;
 		rx_dp->phys_buf_p = (u8 *)NetRxPackets[i];
 		flush_cache((u32)rx_dp->phys_buf_p, PKTSIZE_ALIGN);
 	}
 	flush_cache((u32)cdmac_bd.rx, sizeof(cdmac_bd.rx));

 	/* Initialize the TX Buffer Descriptors */
 	for (i = 0; i < TX_BUF_CNT; i++) {
 		tx_dp = &cdmac_bd.tx[i];
 		memset(tx_dp, 0, sizeof(*tx_dp));
 		tx_dp->next_p = tx_dp;
 	}
 	flush_cache((u32)cdmac_bd.tx, sizeof(cdmac_bd.tx));

 	/* Reset index counter to the Rx and Tx Buffer descriptors */
 	rx_idx = tx_idx = 0;

 	/* initial Rx DMA start by writing to respective TAILDESC_PTR */
 	ll_temac->out32(ra[RX_CURDESC_PTR], (int)&cdmac_bd.rx[rx_idx]);
 	ll_temac->out32(ra[RX_TAILDESC_PTR], (int)&cdmac_bd.rx[rx_idx]);

 	return 0;
 }

 int ll_temac_halt_sdma(struct eth_device *dev)
 {
 	unsigned timeout = 50;	/* 1usec * 50 = 50usec */
 	struct ll_temac *ll_temac = dev->priv;
 	phys_addr_t *ra = ll_temac->sdma_reg_addr;

 	/*
 	 * Soft reset the DMA
 	 *
 	 * Quote from MPMC documentation: Writing a 1 to this field
 	 * forces the DMA engine to shutdown and reset itself. After
 	 * setting this bit, software must poll it until the bit is
 	 * cleared by the DMA. This indicates that the reset process
 	 * is done and the pipeline has been flushed.
 	 */
 	ll_temac->out32(ra[DMA_CONTROL_REG], DMA_CONTROL_RESET);
 	while (timeout && (ll_temac->in32(ra[DMA_CONTROL_REG])
 					& DMA_CONTROL_RESET)) {
 		timeout--;
 		udelay(1);
 	}

 	if (!timeout) {
 		printf("%s: Timeout\n", __func__);
 		return -1;
 	}

 	return 0;
 }

 int ll_temac_reset_sdma(struct eth_device *dev)
 {
 	u32 r;
 	struct ll_temac *ll_temac = dev->priv;
 	phys_addr_t *ra = ll_temac->sdma_reg_addr;

 	/* Soft reset the DMA.  */
 	if (ll_temac_halt_sdma(dev))
 		return -1;

 	/* Now clear the interrupts.  */
 	r = ll_temac->in32(ra[TX_CHNL_CTRL]);
 	r &= ~CHNL_CTRL_IRQ_MASK;
 	ll_temac->out32(ra[TX_CHNL_CTRL], r);

 	r = ll_temac->in32(ra[RX_CHNL_CTRL]);
 	r &= ~CHNL_CTRL_IRQ_MASK;
 	ll_temac->out32(ra[RX_CHNL_CTRL], r);

 	/* Now ACK pending IRQs.  */
 	ll_temac->out32(ra[TX_IRQ_REG], IRQ_REG_IRQ_MASK);
 	ll_temac->out32(ra[RX_IRQ_REG], IRQ_REG_IRQ_MASK);

 	/* Set tail-ptr mode, disable errors for both channels.  */
 	ll_temac->out32(ra[DMA_CONTROL_REG],
 			/* Enable use of tail pointer register */
 			DMA_CONTROL_TPE |
 			/* Disable error when 2 or 4 bit coalesce cnt overfl */
 			DMA_CONTROL_RXOCEID |
 			/* Disable error when 2 or 4 bit coalesce cnt overfl */
 			DMA_CONTROL_TXOCEID);

 	return 0;
 }

 int ll_temac_recv_sdma(struct eth_device *dev)
 {
 	int length, pb_idx;
 	struct cdmac_bd *rx_dp = &cdmac_bd.rx[rx_idx];
 	struct ll_temac *ll_temac = dev->priv;
 	phys_addr_t *ra = ll_temac->sdma_reg_addr;

 	if (ll_temac_sdma_error(dev)) {

 		if (ll_temac_reset_sdma(dev))
 			return -1;

 		ll_temac_init_sdma(dev);
 	}

 	flush_cache((u32)rx_dp, sizeof(*rx_dp));

 	if (!(rx_dp->sca.stctrl & CDMAC_BD_STCTRL_COMPLETED))
 		return 0;

 	if (rx_dp->sca.stctrl & (CDMAC_BD_STCTRL_SOP | CDMAC_BD_STCTRL_EOP)) {
 		pb_idx = rx_idx;
 		length = rx_dp->sca.app[4] & CDMAC_BD_APP4_RXBYTECNT_MASK;
 	} else {
 		pb_idx = -1;
 		length = 0;
 		printf("%s: Got part of package, unsupported (%x)\n",
 				__func__, rx_dp->sca.stctrl);
 	}

 	/* flip the buffer */
 	flush_cache((u32)rx_dp->phys_buf_p, length);

 	/* reset the current descriptor */
 	rx_dp->sca.stctrl = 0;
 	rx_dp->sca.app[4] = 0;
 	flush_cache((u32)rx_dp, sizeof(*rx_dp));

 	/* Find next empty buffer descriptor, preparation for next iteration */
 	rx_idx = (rx_idx + 1) % PKTBUFSRX;
 	rx_dp = &cdmac_bd.rx[rx_idx];
 	flush_cache((u32)rx_dp, sizeof(*rx_dp));

 	/* DMA start by writing to respective TAILDESC_PTR */
 	ll_temac->out32(ra[RX_CURDESC_PTR], (int)&cdmac_bd.rx[rx_idx]);
 	ll_temac->out32(ra[RX_TAILDESC_PTR], (int)&cdmac_bd.rx[rx_idx]);

 	if (length > 0 && pb_idx != -1)
 		NetReceive(NetRxPackets[pb_idx], length);

 	return 0;
 }

 int ll_temac_send_sdma(struct eth_device *dev, void *packet, int length)
 {
 	unsigned timeout = 50;	/* 1usec * 50 = 50usec */
 	struct cdmac_bd *tx_dp = &cdmac_bd.tx[tx_idx];
 	struct ll_temac *ll_temac = dev->priv;
 	phys_addr_t *ra = ll_temac->sdma_reg_addr;

 	if (ll_temac_sdma_error(dev)) {

 		if (ll_temac_reset_sdma(dev))
 			return -1;

 		ll_temac_init_sdma(dev);
 	}

 	tx_dp->phys_buf_p = (u8 *)packet;
 	tx_dp->buf_len = length;
 	tx_dp->sca.stctrl = CDMAC_BD_STCTRL_SOP | CDMAC_BD_STCTRL_EOP |
 			CDMAC_BD_STCTRL_STOP_ON_END;

 	flush_cache((u32)packet, length);
 	flush_cache((u32)tx_dp, sizeof(*tx_dp));

 	/* DMA start by writing to respective TAILDESC_PTR */
 	ll_temac->out32(ra[TX_CURDESC_PTR], (int)tx_dp);
 	ll_temac->out32(ra[TX_TAILDESC_PTR], (int)tx_dp);

 	/* Find next empty buffer descriptor, preparation for next iteration */
 	tx_idx = (tx_idx + 1) % TX_BUF_CNT;
 	tx_dp = &cdmac_bd.tx[tx_idx];

 	do {
 		flush_cache((u32)tx_dp, sizeof(*tx_dp));
 		udelay(1);
 	} while (timeout-- && !(tx_dp->sca.stctrl & CDMAC_BD_STCTRL_COMPLETED));

 	if (!timeout) {
 		printf("%s: Timeout\n", __func__);
 		return -1;
 	}

 	return 0;
 }
	/*
	* Xilinx xps_ll_temac ethernet driver for u-boot
	*
	* SDMA sub-controller
	*
	* Copyright (C) 2011 - 2012 Stephan Linz <linz@li-pro.net>
	* Copyright (C) 2008 - 2011 Michal Simek <monstr@monstr.eu>
	* Copyright (C) 2008 - 2011 PetaLogix
	*
	* Based on Yoshio Kashiwagi kashiwagi@co-nss.co.jp driver
	* Copyright (C) 2008 Nissin Systems Co.,Ltd.
	* March 2008 created
	*
	* CREDITS: tsec driver
	*
	* SPDX-License-Identifier: GPL-2.0+
	*
	* [0]: http://www.xilinx.com/support/documentation
	*
	* [M]: [0]/ip_documentation/mpmc.pdf
	* [S]: [0]/ip_documentation/xps_ll_temac.pdf
	* [A]: [0]/application_notes/xapp1041.pdf
	*/

	#include <config.h>
	#include <common.h>
	#include <net.h>

	#include <asm/types.h>
	#include <asm/io.h>

	#include "xilinx_ll_temac.h"
	#include "xilinx_ll_temac_sdma.h"

	#define TX_BUF_CNT 2

	static unsigned int rx_idx; /* index of the current RX buffer */
	static unsigned int tx_idx; /* index of the current TX buffer */

	struct rtx_cdmac_bd {
	struct cdmac_bd rx[PKTBUFSRX];
	struct cdmac_bd tx[TX_BUF_CNT];
	};

	/*
	* DMA Buffer Descriptor alignment
	*
	* If the address contained in the Next Descriptor Pointer register is not
	* 8-word aligned or reaches beyond the range of available memory, the SDMA
	* halts processing and sets the CDMAC_BD_STCTRL_ERROR bit in the respective
	* status register (tx_chnl_sts or rx_chnl_sts).
	*
	* [1]: [0]/ip_documentation/mpmc.pdf
	* page 161, Next Descriptor Pointer
	*/
	static struct rtx_cdmac_bd cdmac_bd __aligned(32);

	#if defined(CONFIG_XILINX_440) \|\| defined(CONFIG_XILINX_405)

	/*
	* Indirect DCR access operations mi{ft}dcr_xilinx() espacialy
	* for Xilinx PowerPC implementations on FPGA.
	*
	* FIXME: This part should go up to arch/powerpc -- but where?
	*/
	#include <asm/processor.h>
	#define XILINX_INDIRECT_DCR_ADDRESS_REG 0
	#define XILINX_INDIRECT_DCR_ACCESS_REG 1
	inline unsigned mifdcr_xilinx(const unsigned dcrn)
	{
	mtdcr(XILINX_INDIRECT_DCR_ADDRESS_REG, dcrn);
	return mfdcr(XILINX_INDIRECT_DCR_ACCESS_REG);
	}
	inline void mitdcr_xilinx(const unsigned dcrn, int val)
	{
	mtdcr(XILINX_INDIRECT_DCR_ADDRESS_REG, dcrn);
	mtdcr(XILINX_INDIRECT_DCR_ACCESS_REG, val);
	}

	/* Xilinx Device Control Register (DCR) in/out accessors */
	inline unsigned ll_temac_xldcr_in32(phys_addr_t addr)
	{
	return mifdcr_xilinx((const unsigned)addr);
	}
	inline void ll_temac_xldcr_out32(phys_addr_t addr, unsigned value)
	{
	mitdcr_xilinx((const unsigned)addr, value);
	}

	void ll_temac_collect_xldcr_sdma_reg_addr(struct eth_device *dev)
	{
	struct ll_temac *ll_temac = dev->priv;
	phys_addr_t dmac_ctrl = ll_temac->ctrladdr;
	phys_addr_t *ra = ll_temac->sdma_reg_addr;

	ra[TX_NXTDESC_PTR] = dmac_ctrl + TX_NXTDESC_PTR;
	ra[TX_CURBUF_ADDR] = dmac_ctrl + TX_CURBUF_ADDR;
	ra[TX_CURBUF_LENGTH] = dmac_ctrl + TX_CURBUF_LENGTH;
	ra[TX_CURDESC_PTR] = dmac_ctrl + TX_CURDESC_PTR;
	ra[TX_TAILDESC_PTR] = dmac_ctrl + TX_TAILDESC_PTR;
	ra[TX_CHNL_CTRL] = dmac_ctrl + TX_CHNL_CTRL;
	ra[TX_IRQ_REG] = dmac_ctrl + TX_IRQ_REG;
	ra[TX_CHNL_STS] = dmac_ctrl + TX_CHNL_STS;
	ra[RX_NXTDESC_PTR] = dmac_ctrl + RX_NXTDESC_PTR;
	ra[RX_CURBUF_ADDR] = dmac_ctrl + RX_CURBUF_ADDR;
	ra[RX_CURBUF_LENGTH] = dmac_ctrl + RX_CURBUF_LENGTH;
	ra[RX_CURDESC_PTR] = dmac_ctrl + RX_CURDESC_PTR;
	ra[RX_TAILDESC_PTR] = dmac_ctrl + RX_TAILDESC_PTR;
	ra[RX_CHNL_CTRL] = dmac_ctrl + RX_CHNL_CTRL;
	ra[RX_IRQ_REG] = dmac_ctrl + RX_IRQ_REG;
	ra[RX_CHNL_STS] = dmac_ctrl + RX_CHNL_STS;
	ra[DMA_CONTROL_REG] = dmac_ctrl + DMA_CONTROL_REG;
	}

	#endif /* CONFIG_XILINX_440 \|\| ONFIG_XILINX_405 */

	/* Xilinx Processor Local Bus (PLB) in/out accessors */
	inline unsigned ll_temac_xlplb_in32(phys_addr_t addr)
	{
	return in_be32((void *)addr);
	}
	inline void ll_temac_xlplb_out32(phys_addr_t addr, unsigned value)
	{
	out_be32((void *)addr, value);
	}

	/* collect all register addresses for Xilinx PLB in/out accessors */
	void ll_temac_collect_xlplb_sdma_reg_addr(struct eth_device *dev)
	{
	struct ll_temac *ll_temac = dev->priv;
	struct sdma_ctrl sdma_ctrl = (void )ll_temac->ctrladdr;
	phys_addr_t *ra = ll_temac->sdma_reg_addr;

	ra[TX_NXTDESC_PTR] = (phys_addr_t)&sdma_ctrl->tx_nxtdesc_ptr;
	ra[TX_CURBUF_ADDR] = (phys_addr_t)&sdma_ctrl->tx_curbuf_addr;
	ra[TX_CURBUF_LENGTH] = (phys_addr_t)&sdma_ctrl->tx_curbuf_length;
	ra[TX_CURDESC_PTR] = (phys_addr_t)&sdma_ctrl->tx_curdesc_ptr;
	ra[TX_TAILDESC_PTR] = (phys_addr_t)&sdma_ctrl->tx_taildesc_ptr;
	ra[TX_CHNL_CTRL] = (phys_addr_t)&sdma_ctrl->tx_chnl_ctrl;
	ra[TX_IRQ_REG] = (phys_addr_t)&sdma_ctrl->tx_irq_reg;
	ra[TX_CHNL_STS] = (phys_addr_t)&sdma_ctrl->tx_chnl_sts;
	ra[RX_NXTDESC_PTR] = (phys_addr_t)&sdma_ctrl->rx_nxtdesc_ptr;
	ra[RX_CURBUF_ADDR] = (phys_addr_t)&sdma_ctrl->rx_curbuf_addr;
	ra[RX_CURBUF_LENGTH] = (phys_addr_t)&sdma_ctrl->rx_curbuf_length;
	ra[RX_CURDESC_PTR] = (phys_addr_t)&sdma_ctrl->rx_curdesc_ptr;
	ra[RX_TAILDESC_PTR] = (phys_addr_t)&sdma_ctrl->rx_taildesc_ptr;
	ra[RX_CHNL_CTRL] = (phys_addr_t)&sdma_ctrl->rx_chnl_ctrl;
	ra[RX_IRQ_REG] = (phys_addr_t)&sdma_ctrl->rx_irq_reg;
	ra[RX_CHNL_STS] = (phys_addr_t)&sdma_ctrl->rx_chnl_sts;
	ra[DMA_CONTROL_REG] = (phys_addr_t)&sdma_ctrl->dma_control_reg;
	}

	/* Check for TX and RX channel errors. */
	static inline int ll_temac_sdma_error(struct eth_device *dev)
	{
	int err;
	struct ll_temac *ll_temac = dev->priv;
	phys_addr_t *ra = ll_temac->sdma_reg_addr;

	err = ll_temac->in32(ra[TX_CHNL_STS]) & CHNL_STS_ERROR;
	err \|= ll_temac->in32(ra[RX_CHNL_STS]) & CHNL_STS_ERROR;

	return err;
	}

	int ll_temac_init_sdma(struct eth_device *dev)
	{
	struct ll_temac *ll_temac = dev->priv;
	struct cdmac_bd *rx_dp;
	struct cdmac_bd *tx_dp;
	phys_addr_t *ra = ll_temac->sdma_reg_addr;
	int i;

	printf("%s: SDMA: %d Rx buffers, %d Tx buffers\n",
	dev->name, PKTBUFSRX, TX_BUF_CNT);

	/* Initialize the Rx Buffer descriptors */
	for (i = 0; i < PKTBUFSRX; i++) {
	rx_dp = &cdmac_bd.rx[i];
	memset(rx_dp, 0, sizeof(*rx_dp));
	rx_dp->next_p = rx_dp;
	rx_dp->buf_len = PKTSIZE_ALIGN;
	rx_dp->phys_buf_p = (u8 *)NetRxPackets[i];
	flush_cache((u32)rx_dp->phys_buf_p, PKTSIZE_ALIGN);
	}
	flush_cache((u32)cdmac_bd.rx, sizeof(cdmac_bd.rx));

	/* Initialize the TX Buffer Descriptors */
	for (i = 0; i < TX_BUF_CNT; i++) {
	tx_dp = &cdmac_bd.tx[i];
	memset(tx_dp, 0, sizeof(*tx_dp));
	tx_dp->next_p = tx_dp;
	}
	flush_cache((u32)cdmac_bd.tx, sizeof(cdmac_bd.tx));

	/* Reset index counter to the Rx and Tx Buffer descriptors */
	rx_idx = tx_idx = 0;

	/* initial Rx DMA start by writing to respective TAILDESC_PTR */
	ll_temac->out32(ra[RX_CURDESC_PTR], (int)&cdmac_bd.rx[rx_idx]);
	ll_temac->out32(ra[RX_TAILDESC_PTR], (int)&cdmac_bd.rx[rx_idx]);

	return 0;
	}

	int ll_temac_halt_sdma(struct eth_device *dev)
	{
	unsigned timeout = 50; /* 1usec * 50 = 50usec */
	struct ll_temac *ll_temac = dev->priv;
	phys_addr_t *ra = ll_temac->sdma_reg_addr;

	/*
	* Soft reset the DMA
	*
	* Quote from MPMC documentation: Writing a 1 to this field
	* forces the DMA engine to shutdown and reset itself. After
	* setting this bit, software must poll it until the bit is
	* cleared by the DMA. This indicates that the reset process
	* is done and the pipeline has been flushed.
	*/
	ll_temac->out32(ra[DMA_CONTROL_REG], DMA_CONTROL_RESET);
	while (timeout && (ll_temac->in32(ra[DMA_CONTROL_REG])
	& DMA_CONTROL_RESET)) {
	timeout--;
	udelay(1);
	}

	if (!timeout) {
	printf("%s: Timeout\n", __func__);
	return -1;
	}

	return 0;
	}

	int ll_temac_reset_sdma(struct eth_device *dev)
	{
	u32 r;
	struct ll_temac *ll_temac = dev->priv;
	phys_addr_t *ra = ll_temac->sdma_reg_addr;

	/* Soft reset the DMA. */
	if (ll_temac_halt_sdma(dev))
	return -1;

	/* Now clear the interrupts. */
	r = ll_temac->in32(ra[TX_CHNL_CTRL]);
	r &= ~CHNL_CTRL_IRQ_MASK;
	ll_temac->out32(ra[TX_CHNL_CTRL], r);

	r = ll_temac->in32(ra[RX_CHNL_CTRL]);
	r &= ~CHNL_CTRL_IRQ_MASK;
	ll_temac->out32(ra[RX_CHNL_CTRL], r);

	/* Now ACK pending IRQs. */
	ll_temac->out32(ra[TX_IRQ_REG], IRQ_REG_IRQ_MASK);
	ll_temac->out32(ra[RX_IRQ_REG], IRQ_REG_IRQ_MASK);

	/* Set tail-ptr mode, disable errors for both channels. */
	ll_temac->out32(ra[DMA_CONTROL_REG],
	/* Enable use of tail pointer register */
	DMA_CONTROL_TPE \|
	/* Disable error when 2 or 4 bit coalesce cnt overfl */
	DMA_CONTROL_RXOCEID \|
	/* Disable error when 2 or 4 bit coalesce cnt overfl */
	DMA_CONTROL_TXOCEID);

	return 0;
	}

	int ll_temac_recv_sdma(struct eth_device *dev)
	{
	int length, pb_idx;
	struct cdmac_bd *rx_dp = &cdmac_bd.rx[rx_idx];
	struct ll_temac *ll_temac = dev->priv;
	phys_addr_t *ra = ll_temac->sdma_reg_addr;

	if (ll_temac_sdma_error(dev)) {

	if (ll_temac_reset_sdma(dev))
	return -1;

	ll_temac_init_sdma(dev);
	}

	flush_cache((u32)rx_dp, sizeof(*rx_dp));

	if (!(rx_dp->sca.stctrl & CDMAC_BD_STCTRL_COMPLETED))
	return 0;

	if (rx_dp->sca.stctrl & (CDMAC_BD_STCTRL_SOP \| CDMAC_BD_STCTRL_EOP)) {
	pb_idx = rx_idx;
	length = rx_dp->sca.app[4] & CDMAC_BD_APP4_RXBYTECNT_MASK;
	} else {
	pb_idx = -1;
	length = 0;
	printf("%s: Got part of package, unsupported (%x)\n",
	__func__, rx_dp->sca.stctrl);
	}

	/* flip the buffer */
	flush_cache((u32)rx_dp->phys_buf_p, length);

	/* reset the current descriptor */
	rx_dp->sca.stctrl = 0;
	rx_dp->sca.app[4] = 0;
	flush_cache((u32)rx_dp, sizeof(*rx_dp));

	/* Find next empty buffer descriptor, preparation for next iteration */
	rx_idx = (rx_idx + 1) % PKTBUFSRX;
	rx_dp = &cdmac_bd.rx[rx_idx];
	flush_cache((u32)rx_dp, sizeof(*rx_dp));

	/* DMA start by writing to respective TAILDESC_PTR */
	ll_temac->out32(ra[RX_CURDESC_PTR], (int)&cdmac_bd.rx[rx_idx]);
	ll_temac->out32(ra[RX_TAILDESC_PTR], (int)&cdmac_bd.rx[rx_idx]);

	if (length > 0 && pb_idx != -1)
	NetReceive(NetRxPackets[pb_idx], length);

	return 0;
	}

	int ll_temac_send_sdma(struct eth_device dev, void packet, int length)
	{
	unsigned timeout = 50; /* 1usec * 50 = 50usec */
	struct cdmac_bd *tx_dp = &cdmac_bd.tx[tx_idx];
	struct ll_temac *ll_temac = dev->priv;
	phys_addr_t *ra = ll_temac->sdma_reg_addr;

	if (ll_temac_sdma_error(dev)) {

	if (ll_temac_reset_sdma(dev))
	return -1;

	ll_temac_init_sdma(dev);
	}

	tx_dp->phys_buf_p = (u8 *)packet;
	tx_dp->buf_len = length;
	tx_dp->sca.stctrl = CDMAC_BD_STCTRL_SOP \| CDMAC_BD_STCTRL_EOP \|
	CDMAC_BD_STCTRL_STOP_ON_END;

	flush_cache((u32)packet, length);
	flush_cache((u32)tx_dp, sizeof(*tx_dp));

	/* DMA start by writing to respective TAILDESC_PTR */
	ll_temac->out32(ra[TX_CURDESC_PTR], (int)tx_dp);
	ll_temac->out32(ra[TX_TAILDESC_PTR], (int)tx_dp);

	/* Find next empty buffer descriptor, preparation for next iteration */
	tx_idx = (tx_idx + 1) % TX_BUF_CNT;
	tx_dp = &cdmac_bd.tx[tx_idx];

	do {
	flush_cache((u32)tx_dp, sizeof(*tx_dp));
	udelay(1);
	} while (timeout-- && !(tx_dp->sca.stctrl & CDMAC_BD_STCTRL_COMPLETED));

	if (!timeout) {
	printf("%s: Timeout\n", __func__);
	return -1;
	}

	return 0;
	}