WAN: convert HD64572-based drivers to NAPI.

[safe/jmp/linux-2.6] / drivers / net / wan / hd64572.c

/*
 * Hitachi (now Renesas) SCA-II HD64572 driver for Linux
 *
 * Copyright (C) 1998-2008 Krzysztof Halasa <khc@pm.waw.pl>
 *
 * This program is free software; you can redistribute it and/or modify it
 * under the terms of version 2 of the GNU General Public License
 * as published by the Free Software Foundation.
 *
 * Source of information: HD64572 SCA-II User's Manual
 *
 * We use the following SCA memory map:
 *
 * Packet buffer descriptor rings - starting from winbase or win0base:
 * rx_ring_buffers * sizeof(pkt_desc) = logical channel #0 RX ring
 * tx_ring_buffers * sizeof(pkt_desc) = logical channel #0 TX ring
 * rx_ring_buffers * sizeof(pkt_desc) = logical channel #1 RX ring (if used)
 * tx_ring_buffers * sizeof(pkt_desc) = logical channel #1 TX ring (if used)
 *
 * Packet data buffers - starting from winbase + buff_offset:
 * rx_ring_buffers * HDLC_MAX_MRU     = logical channel #0 RX buffers
 * tx_ring_buffers * HDLC_MAX_MRU     = logical channel #0 TX buffers
 * rx_ring_buffers * HDLC_MAX_MRU     = logical channel #0 RX buffers (if used)
 * tx_ring_buffers * HDLC_MAX_MRU     = logical channel #0 TX buffers (if used)
 */

#include <linux/bitops.h>
#include <linux/errno.h>
#include <linux/fcntl.h>
#include <linux/hdlc.h>
#include <linux/in.h>
#include <linux/init.h>
#include <linux/interrupt.h>
#include <linux/ioport.h>
#include <linux/jiffies.h>
#include <linux/kernel.h>
#include <linux/module.h>
#include <linux/netdevice.h>
#include <linux/skbuff.h>
#include <linux/slab.h>
#include <linux/string.h>
#include <linux/types.h>
#include <asm/io.h>
#include <asm/system.h>
#include <asm/uaccess.h>
#include "hd64572.h"

#define NAPI_WEIGHT             16

#define get_msci(port)    (phy_node(port) ?   MSCI1_OFFSET :   MSCI0_OFFSET)
#define get_dmac_rx(port) (phy_node(port) ? DMAC1RX_OFFSET : DMAC0RX_OFFSET)
#define get_dmac_tx(port) (phy_node(port) ? DMAC1TX_OFFSET : DMAC0TX_OFFSET)

#define SCA_INTR_MSCI(node)    (node ? 0x10 : 0x01)
#define SCA_INTR_DMAC_RX(node) (node ? 0x20 : 0x02)
#define SCA_INTR_DMAC_TX(node) (node ? 0x40 : 0x04)

static int sca_poll(struct napi_struct *napi, int budget);

static inline struct net_device *port_to_dev(port_t *port)
{
        return port->dev;
}

static inline int sca_intr_status(card_t *card)
{
        u8 result = 0;
        u32 isr0 = sca_inl(ISR0, card);

        if (isr0 & 0x0000000F) result |= SCA_INTR_DMAC_RX(0);
        if (isr0 & 0x000000F0) result |= SCA_INTR_DMAC_TX(0);
        if (isr0 & 0x00000F00) result |= SCA_INTR_DMAC_RX(1);
        if (isr0 & 0x0000F000) result |= SCA_INTR_DMAC_TX(1);
        if (isr0 & 0x003E0000) result |= SCA_INTR_MSCI(0);
        if (isr0 & 0x3E000000) result |= SCA_INTR_MSCI(1);

        if (!(result & SCA_INTR_DMAC_TX(0)))
                if (sca_in(DSR_TX(0), card) & DSR_EOM)
                        result |= SCA_INTR_DMAC_TX(0);
        if (!(result & SCA_INTR_DMAC_TX(1)))
                if (sca_in(DSR_TX(1), card) & DSR_EOM)
                        result |= SCA_INTR_DMAC_TX(1);

        return result;
}

static inline port_t* dev_to_port(struct net_device *dev)
{
        return dev_to_hdlc(dev)->priv;
}

static inline void enable_intr(port_t *port)
{
        /* DMA & MSCI IRQ enable */
        /* IR0_TXINT | IR0_RXINTA | IR0_DMIB* | IR0_DMIA* */
        sca_outl(sca_inl(IER0, port->card) |
                 (phy_node(port) ? 0x0A006600 : 0x000A0066), IER0, port->card);
}

static inline void disable_intr(port_t *port)
{
        sca_outl(sca_inl(IER0, port->card) &
                 (phy_node(port) ? 0x00FF00FF : 0xFF00FF00), IER0, port->card);
}

static inline u16 next_desc(port_t *port, u16 desc, int transmit)
{
        return (desc + 1) % (transmit ? port_to_card(port)->tx_ring_buffers
                             : port_to_card(port)->rx_ring_buffers);
}


static inline u16 desc_abs_number(port_t *port, u16 desc, int transmit)
{
        u16 rx_buffs = port_to_card(port)->rx_ring_buffers;
        u16 tx_buffs = port_to_card(port)->tx_ring_buffers;

        desc %= (transmit ? tx_buffs : rx_buffs); // called with "X + 1" etc.
        return log_node(port) * (rx_buffs + tx_buffs) +
                transmit * rx_buffs + desc;
}


static inline u16 desc_offset(port_t *port, u16 desc, int transmit)
{
        /* Descriptor offset always fits in 16 bytes */
        return desc_abs_number(port, desc, transmit) * sizeof(pkt_desc);
}


static inline pkt_desc __iomem *desc_address(port_t *port, u16 desc,
                                             int transmit)
{
        return (pkt_desc __iomem *)(winbase(port_to_card(port))
                                    + desc_offset(port, desc, transmit));
}


static inline u32 buffer_offset(port_t *port, u16 desc, int transmit)
{
        return port_to_card(port)->buff_offset +
                desc_abs_number(port, desc, transmit) * (u32)HDLC_MAX_MRU;
}


static inline void sca_set_carrier(port_t *port)
{
        if (!(sca_in(get_msci(port) + ST3, port_to_card(port)) & ST3_DCD)) {
#ifdef DEBUG_LINK
                printk(KERN_DEBUG "%s: sca_set_carrier on\n",
                       port_to_dev(port)->name);
#endif
                netif_carrier_on(port_to_dev(port));
        } else {
#ifdef DEBUG_LINK
                printk(KERN_DEBUG "%s: sca_set_carrier off\n",
                       port_to_dev(port)->name);
#endif
                netif_carrier_off(port_to_dev(port));
        }
}


static void sca_init_port(port_t *port)
{
        card_t *card = port_to_card(port);
        int transmit, i;

        port->rxin = 0;
        port->txin = 0;
        port->txlast = 0;

        for (transmit = 0; transmit < 2; transmit++) {
                u16 dmac = transmit ? get_dmac_tx(port) : get_dmac_rx(port);
                u16 buffs = transmit ? card->tx_ring_buffers
                        : card->rx_ring_buffers;

                for (i = 0; i < buffs; i++) {
                        pkt_desc __iomem *desc = desc_address(port, i, transmit);
                        u16 chain_off = desc_offset(port, i + 1, transmit);
                        u32 buff_off = buffer_offset(port, i, transmit);

                        writel(chain_off, &desc->cp);
                        writel(buff_off, &desc->bp);
                        writew(0, &desc->len);
                        writeb(0, &desc->stat);
                }

                /* DMA disable - to halt state */
                sca_out(0, transmit ? DSR_TX(phy_node(port)) :
                        DSR_RX(phy_node(port)), card);
                /* software ABORT - to initial state */
                sca_out(DCR_ABORT, transmit ? DCR_TX(phy_node(port)) :
                        DCR_RX(phy_node(port)), card);

                /* current desc addr */
                sca_outl(desc_offset(port, 0, transmit), dmac + CDAL, card);
                if (!transmit)
                        sca_outl(desc_offset(port, buffs - 1, transmit),
                                 dmac + EDAL, card);
                else
                        sca_outl(desc_offset(port, 0, transmit), dmac + EDAL,
                                 card);

                /* clear frame end interrupt counter */
                sca_out(DCR_CLEAR_EOF, transmit ? DCR_TX(phy_node(port)) :
                        DCR_RX(phy_node(port)), card);

                if (!transmit) { /* Receive */
                        /* set buffer length */
                        sca_outw(HDLC_MAX_MRU, dmac + BFLL, card);
                        /* Chain mode, Multi-frame */
                        sca_out(0x14, DMR_RX(phy_node(port)), card);
                        sca_out(DIR_EOME | DIR_BOFE, DIR_RX(phy_node(port)),
                                card);
                        /* DMA enable */
                        sca_out(DSR_DE, DSR_RX(phy_node(port)), card);
                } else {        /* Transmit */
                        /* Chain mode, Multi-frame */
                        sca_out(0x14, DMR_TX(phy_node(port)), card);
                        /* enable underflow interrupts */
                        sca_out(DIR_BOFE, DIR_TX(phy_node(port)), card);
                }
        }
        sca_set_carrier(port);
        netif_napi_add(port_to_dev(port), &port->napi, sca_poll, NAPI_WEIGHT);
}


/* MSCI interrupt service */
static inline void sca_msci_intr(port_t *port)
{
        u16 msci = get_msci(port);
        card_t* card = port_to_card(port);
        u8 stat = sca_in(msci + ST1, card); /* read MSCI ST1 status */

        /* Reset MSCI TX underrun and CDCD status bit */
        sca_out(stat & (ST1_UDRN | ST1_CDCD), msci + ST1, card);

        if (stat & ST1_UDRN) {
                /* TX Underrun error detected */
                port_to_dev(port)->stats.tx_errors++;
                port_to_dev(port)->stats.tx_fifo_errors++;
        }

        if (stat & ST1_CDCD)
                sca_set_carrier(port);
}


static inline void sca_rx(card_t *card, port_t *port, pkt_desc __iomem *desc,
                          u16 rxin)
{
        struct net_device *dev = port_to_dev(port);
        struct sk_buff *skb;
        u16 len;
        u32 buff;

        len = readw(&desc->len);
        skb = dev_alloc_skb(len);
        if (!skb) {
                dev->stats.rx_dropped++;
                return;
        }

        buff = buffer_offset(port, rxin, 0);
        memcpy_fromio(skb->data, winbase(card) + buff, len);

        skb_put(skb, len);
#ifdef DEBUG_PKT
        printk(KERN_DEBUG "%s RX(%i):", dev->name, skb->len);
        debug_frame(skb);
#endif
        dev->stats.rx_packets++;
        dev->stats.rx_bytes += skb->len;
        skb->protocol = hdlc_type_trans(skb, dev);
        netif_receive_skb(skb);
}


/* Receive DMA service */
static inline int sca_rx_done(port_t *port, int budget)
{
        struct net_device *dev = port_to_dev(port);
        u16 dmac = get_dmac_rx(port);
        card_t *card = port_to_card(port);
        u8 stat = sca_in(DSR_RX(phy_node(port)), card); /* read DMA Status */
        int received = 0;

        /* Reset DSR status bits */
        sca_out((stat & (DSR_EOT | DSR_EOM | DSR_BOF | DSR_COF)) | DSR_DWE,
                DSR_RX(phy_node(port)), card);

        if (stat & DSR_BOF)
                /* Dropped one or more frames */
                dev->stats.rx_over_errors++;

        while (received < budget) {
                u32 desc_off = desc_offset(port, port->rxin, 0);
                pkt_desc __iomem *desc;
                u32 cda = sca_inl(dmac + CDAL, card);

                if ((cda >= desc_off) && (cda < desc_off + sizeof(pkt_desc)))
                        break;  /* No frame received */

                desc = desc_address(port, port->rxin, 0);
                stat = readb(&desc->stat);
                if (!(stat & ST_RX_EOM))
                        port->rxpart = 1; /* partial frame received */
                else if ((stat & ST_ERROR_MASK) || port->rxpart) {
                        dev->stats.rx_errors++;
                        if (stat & ST_RX_OVERRUN)
                                dev->stats.rx_fifo_errors++;
                        else if ((stat & (ST_RX_SHORT | ST_RX_ABORT |
                                          ST_RX_RESBIT)) || port->rxpart)
                                dev->stats.rx_frame_errors++;
                        else if (stat & ST_RX_CRC)
                                dev->stats.rx_crc_errors++;
                        if (stat & ST_RX_EOM)
                                port->rxpart = 0; /* received last fragment */
                } else {
                        sca_rx(card, port, desc, port->rxin);
                        received++;
                }

                /* Set new error descriptor address */
                sca_outl(desc_off, dmac + EDAL, card);
                port->rxin = next_desc(port, port->rxin, 0);
        }

        /* make sure RX DMA is enabled */
        sca_out(DSR_DE, DSR_RX(phy_node(port)), card);
        return received;
}


/* Transmit DMA service */
static inline void sca_tx_done(port_t *port)
{
        struct net_device *dev = port_to_dev(port);
        u16 dmac = get_dmac_tx(port);
        card_t* card = port_to_card(port);
        u8 stat;

        spin_lock(&port->lock);

        stat = sca_in(DSR_TX(phy_node(port)), card); /* read DMA Status */

        /* Reset DSR status bits */
        sca_out((stat & (DSR_EOT | DSR_EOM | DSR_BOF | DSR_COF)) | DSR_DWE,
                DSR_TX(phy_node(port)), card);

        while (1) {
                pkt_desc __iomem *desc;

                u32 desc_off = desc_offset(port, port->txlast, 1);
                u32 cda = sca_inl(dmac + CDAL, card);
                if ((cda >= desc_off) && (cda < desc_off + sizeof(pkt_desc)))
                        break;  /* Transmitter is/will_be sending this frame */

                desc = desc_address(port, port->txlast, 1);
                dev->stats.tx_packets++;
                dev->stats.tx_bytes += readw(&desc->len);
                writeb(0, &desc->stat); /* Free descriptor */
                port->txlast = next_desc(port, port->txlast, 1);
        }

        netif_wake_queue(dev);
        spin_unlock(&port->lock);
}


static int sca_poll(struct napi_struct *napi, int budget)
{
        port_t *port = container_of(napi, port_t, napi);
        u8 stat = sca_intr_status(port->card);
        int received = 0;

        if (stat & SCA_INTR_MSCI(port->phy_node))
                sca_msci_intr(port);

        if (stat & SCA_INTR_DMAC_TX(port->phy_node))
                sca_tx_done(port);

        if (stat & SCA_INTR_DMAC_RX(port->phy_node))
                received = sca_rx_done(port, budget);

        if (received < budget) {
                netif_rx_complete(port->dev, napi);
                enable_intr(port);
        }

        return received;
}

static irqreturn_t sca_intr(int irq, void* dev_id)
{
        card_t *card = dev_id;
        int i;
        u8 stat = sca_intr_status(card);
        int handled = 0;

        for (i = 0; i < 2; i++) {
                port_t *port = get_port(card, i);
                if (port && (stat & (SCA_INTR_MSCI(i) | SCA_INTR_DMAC_RX(i) |
                                     SCA_INTR_DMAC_TX(i)))) {
                        handled = 1;
                        disable_intr(port);
                        netif_rx_schedule(port->dev, &port->napi);
                }
        }

        return IRQ_RETVAL(handled);
}


static void sca_set_port(port_t *port)
{
        card_t* card = port_to_card(port);
        u16 msci = get_msci(port);
        u8 md2 = sca_in(msci + MD2, card);
        unsigned int tmc, br = 10, brv = 1024;


        if (port->settings.clock_rate > 0) {
                /* Try lower br for better accuracy*/
                do {
                        br--;
                        brv >>= 1; /* brv = 2^9 = 512 max in specs */

                        /* Baud Rate = CLOCK_BASE / TMC / 2^BR */
                        tmc = CLOCK_BASE / brv / port->settings.clock_rate;
                }while (br > 1 && tmc <= 128);

                if (tmc < 1) {
                        tmc = 1;
                        br = 0; /* For baud=CLOCK_BASE we use tmc=1 br=0 */
                        brv = 1;
                } else if (tmc > 255)
                        tmc = 256; /* tmc=0 means 256 - low baud rates */

                port->settings.clock_rate = CLOCK_BASE / brv / tmc;
        } else {
                br = 9; /* Minimum clock rate */
                tmc = 256;      /* 8bit = 0 */
                port->settings.clock_rate = CLOCK_BASE / (256 * 512);
        }

        port->rxs = (port->rxs & ~CLK_BRG_MASK) | br;
        port->txs = (port->txs & ~CLK_BRG_MASK) | br;
        port->tmc = tmc;

        /* baud divisor - time constant*/
        sca_out(port->tmc, msci + TMCR, card);
        sca_out(port->tmc, msci + TMCT, card);

        /* Set BRG bits */
        sca_out(port->rxs, msci + RXS, card);
        sca_out(port->txs, msci + TXS, card);

        if (port->settings.loopback)
                md2 |= MD2_LOOPBACK;
        else
                md2 &= ~MD2_LOOPBACK;

        sca_out(md2, msci + MD2, card);

}


static void sca_open(struct net_device *dev)
{
        port_t *port = dev_to_port(dev);
        card_t* card = port_to_card(port);
        u16 msci = get_msci(port);
        u8 md0, md2;

        switch(port->encoding) {
        case ENCODING_NRZ:      md2 = MD2_NRZ;          break;
        case ENCODING_NRZI:     md2 = MD2_NRZI;         break;
        case ENCODING_FM_MARK:  md2 = MD2_FM_MARK;      break;
        case ENCODING_FM_SPACE: md2 = MD2_FM_SPACE;     break;
        default:                md2 = MD2_MANCHESTER;
        }

        if (port->settings.loopback)
                md2 |= MD2_LOOPBACK;

        switch(port->parity) {
        case PARITY_CRC16_PR0:       md0 = MD0_HDLC | MD0_CRC_16_0;  break;
        case PARITY_CRC16_PR1:       md0 = MD0_HDLC | MD0_CRC_16;    break;
        case PARITY_CRC32_PR1_CCITT: md0 = MD0_HDLC | MD0_CRC_ITU32; break;
        case PARITY_CRC16_PR1_CCITT: md0 = MD0_HDLC | MD0_CRC_ITU;   break;
        default:                     md0 = MD0_HDLC | MD0_CRC_NONE;
        }

        sca_out(CMD_RESET, msci + CMD, card);
        sca_out(md0, msci + MD0, card);
        sca_out(0x00, msci + MD1, card); /* no address field check */
        sca_out(md2, msci + MD2, card);
        sca_out(0x7E, msci + IDL, card); /* flag character 0x7E */
        /* Skip the rest of underrun frame */
        sca_out(CTL_IDLE | CTL_URCT | CTL_URSKP, msci + CTL, card);
        sca_out(0x0F, msci + RNR, card); /* +1=RX DMA activation condition */
        sca_out(0x3C, msci + TFS, card); /* +1 = TX start */
        sca_out(0x38, msci + TCR, card); /* =Critical TX DMA activ condition */
        sca_out(0x38, msci + TNR0, card); /* =TX DMA activation condition */
        sca_out(0x3F, msci + TNR1, card); /* +1=TX DMA deactivation condition*/

/* We're using the following interrupts:
   - TXINT (DMAC completed all transmissions, underrun or DCD change)
   - all DMA interrupts
*/
        /* MSCI TXINT and RXINTA interrupt enable */
        sca_outl(IE0_TXINT | IE0_RXINTA | IE0_UDRN | IE0_CDCD, msci + IE0,
                 card);

        sca_out(port->tmc, msci + TMCR, card);
        sca_out(port->tmc, msci + TMCT, card);
        sca_out(port->rxs, msci + RXS, card);
        sca_out(port->txs, msci + TXS, card);
        sca_out(CMD_TX_ENABLE, msci + CMD, card);
        sca_out(CMD_RX_ENABLE, msci + CMD, card);

        sca_set_carrier(port);
        enable_intr(port);
        napi_enable(&port->napi);
        netif_start_queue(dev);
}


static void sca_close(struct net_device *dev)
{
        port_t *port = dev_to_port(dev);

        /* reset channel */
        sca_out(CMD_RESET, get_msci(port) + CMD, port_to_card(port));
        disable_intr(port);
        napi_disable(&port->napi);
        netif_stop_queue(dev);
}


static int sca_attach(struct net_device *dev, unsigned short encoding,
                      unsigned short parity)
{
        if (encoding != ENCODING_NRZ &&
            encoding != ENCODING_NRZI &&
            encoding != ENCODING_FM_MARK &&
            encoding != ENCODING_FM_SPACE &&
            encoding != ENCODING_MANCHESTER)
                return -EINVAL;

        if (parity != PARITY_NONE &&
            parity != PARITY_CRC16_PR0 &&
            parity != PARITY_CRC16_PR1 &&
            parity != PARITY_CRC32_PR1_CCITT &&
            parity != PARITY_CRC16_PR1_CCITT)
                return -EINVAL;

        dev_to_port(dev)->encoding = encoding;
        dev_to_port(dev)->parity = parity;
        return 0;
}


#ifdef DEBUG_RINGS
static void sca_dump_rings(struct net_device *dev)
{
        port_t *port = dev_to_port(dev);
        card_t *card = port_to_card(port);
        u16 cnt;

        printk(KERN_DEBUG "RX ring: CDA=%u EDA=%u DSR=%02X in=%u %sactive",
               sca_inl(get_dmac_rx(port) + CDAL, card),
               sca_inl(get_dmac_rx(port) + EDAL, card),
               sca_in(DSR_RX(phy_node(port)), card), port->rxin,
               sca_in(DSR_RX(phy_node(port)), card) & DSR_DE ? "" : "in");
        for (cnt = 0; cnt < port_to_card(port)->rx_ring_buffers; cnt++)
                printk(" %02X", readb(&(desc_address(port, cnt, 0)->stat)));

        printk("\n" KERN_DEBUG "TX ring: CDA=%u EDA=%u DSR=%02X in=%u "
               "last=%u %sactive",
               sca_inl(get_dmac_tx(port) + CDAL, card),
               sca_inl(get_dmac_tx(port) + EDAL, card),
               sca_in(DSR_TX(phy_node(port)), card), port->txin, port->txlast,
               sca_in(DSR_TX(phy_node(port)), card) & DSR_DE ? "" : "in");

        for (cnt = 0; cnt < port_to_card(port)->tx_ring_buffers; cnt++)
                printk(" %02X", readb(&(desc_address(port, cnt, 1)->stat)));
        printk("\n");

        printk(KERN_DEBUG "MSCI: MD: %02x %02x %02x,"
               " ST: %02x %02x %02x %02x %02x, FST: %02x CST: %02x %02x\n",
               sca_in(get_msci(port) + MD0, card),
               sca_in(get_msci(port) + MD1, card),
               sca_in(get_msci(port) + MD2, card),
               sca_in(get_msci(port) + ST0, card),
               sca_in(get_msci(port) + ST1, card),
               sca_in(get_msci(port) + ST2, card),
               sca_in(get_msci(port) + ST3, card),
               sca_in(get_msci(port) + ST4, card),
               sca_in(get_msci(port) + FST, card),
               sca_in(get_msci(port) + CST0, card),
               sca_in(get_msci(port) + CST1, card));

        printk(KERN_DEBUG "ILAR: %02x ISR: %08x %08x\n", sca_in(ILAR, card),
               sca_inl(ISR0, card), sca_inl(ISR1, card));
}
#endif /* DEBUG_RINGS */


static int sca_xmit(struct sk_buff *skb, struct net_device *dev)
{
        port_t *port = dev_to_port(dev);
        card_t *card = port_to_card(port);
        pkt_desc __iomem *desc;
        u32 buff, len;

        spin_lock_irq(&port->lock);

        desc = desc_address(port, port->txin + 1, 1);
        BUG_ON(readb(&desc->stat)); /* previous xmit should stop queue */

#ifdef DEBUG_PKT
        printk(KERN_DEBUG "%s TX(%i):", dev->name, skb->len);
        debug_frame(skb);
#endif

        desc = desc_address(port, port->txin, 1);
        buff = buffer_offset(port, port->txin, 1);
        len = skb->len;
        memcpy_toio(winbase(card) + buff, skb->data, len);

        writew(len, &desc->len);
        writeb(ST_TX_EOM, &desc->stat);
        dev->trans_start = jiffies;

        port->txin = next_desc(port, port->txin, 1);
        sca_outl(desc_offset(port, port->txin, 1),
                 get_dmac_tx(port) + EDAL, card);

        sca_out(DSR_DE, DSR_TX(phy_node(port)), card); /* Enable TX DMA */

        desc = desc_address(port, port->txin + 1, 1);
        if (readb(&desc->stat)) /* allow 1 packet gap */
                netif_stop_queue(dev);

        spin_unlock_irq(&port->lock);

        dev_kfree_skb(skb);
        return 0;
}


static u32 __devinit sca_detect_ram(card_t *card, u8 __iomem *rambase,
                                    u32 ramsize)
{
        /* Round RAM size to 32 bits, fill from end to start */
        u32 i = ramsize &= ~3;

        do {
                i -= 4;
                writel(i ^ 0x12345678, rambase + i);
        } while (i > 0);

        for (i = 0; i < ramsize ; i += 4) {
                if (readl(rambase + i) != (i ^ 0x12345678))
                        break;
        }

        return i;
}


static void __devinit sca_init(card_t *card, int wait_states)
{
        sca_out(wait_states, WCRL, card); /* Wait Control */
        sca_out(wait_states, WCRM, card);
        sca_out(wait_states, WCRH, card);

        sca_out(0, DMER, card); /* DMA Master disable */
        sca_out(0x03, PCR, card); /* DMA priority */
        sca_out(0, DSR_RX(0), card); /* DMA disable - to halt state */
        sca_out(0, DSR_TX(0), card);
        sca_out(0, DSR_RX(1), card);
        sca_out(0, DSR_TX(1), card);
        sca_out(DMER_DME, DMER, card); /* DMA Master enable */
}