DM9000网卡驱动分析（转）

s3c6410自带的DM9000网卡驱动也是基于platform设备模型。

其定义的设备资源在arch/arm/mach-s3c64xx/mach-smdk6410中。有网卡的resource resource dm9000_resources[]，还有一些板级信息，dm9000_plat_data dm9000_setup。

 

1.宏及参数  //板级、系统定义

#define DM9000_PHY        0x40    /* PHY address 0x01 */

#define CARDNAME    "dm9000"
#define DRV_VERSION    "1.31"
/*
 * Transmit timeout, default 5 seconds.
 */
static int watchdog = 5000; //5s的延时时间
module_param(watchdog, int, 0400);
MODULE_PARM_DESC(watchdog, "transmit timeout in milliseconds");
enum dm9000_type {  //开发板定义了三个DM9000类型
    TYPE_DM9000E,    /* original DM9000 */
    TYPE_DM9000A,
    TYPE_DM9000B
};

2.模块注册

此处因为基于platform模型，采用platform_driver_register函数注册内核模块，当设备驱动与设备匹配真确后，转入执行dm9000_probe()函数，该函数包含真正的dm9000网卡驱动注册函数是register_netdev()函数。

static int __init dm9000_init(void)
{
    printk(KERN_INFO "%s Ethernet Driver, V%s
", CARDNAME, DRV_VERSION);

    return platform_driver_register(&dm9000_driver); //platform设备模型注册驱动
}

dm9000的platform设备驱动函数如下：

static struct platform_driver dm9000_driver = {
    .driver    = {
        .name = "dm9000",
        .owner     = THIS_MODULE,
        .pm     = &dm9000_drv_pm_ops,
    },
    .probe = dm9000_probe,
    .remove = __devexit_p(dm9000_drv_remove),
};

3.dm9000_probe函数

主要完成网络设备的初始化，以及网卡驱动的注册register_netdev（）

static int __devinit  dm9000_probe(struct platform_device *pdev)
{
    struct dm9000_plat_data *pdata = pdev->dev.platform_data;//驱动程序中获得系统定义的网卡板级信息
                                            //定义在/arch/arm/mach-s3c64xx/mach-smdk6410.c中。
    struct board_info *db;    /* Point a board information structure */
    struct net_device *ndev; //定义设备结构体
    const unsigned char *mac_src;
    int ret = 0;
    int iosize;
    int i;
    u32 id_val;

    /* Init network device */
//分配生成net_device结构体  alloc_etherdev是alloc_netdev()针对以太网的快捷操作函数
    ndev = alloc_etherdev(sizeof(struct board_info)); 

//判断是否分配正确
    if (!ndev) {
        dev_err(&pdev->dev, "could not allocate device.
");
        return -ENOMEM;
    }
//建立net_device到device的连接
    SET_NETDEV_DEV(ndev, &pdev->dev); 
//内核输出信息
    dev_dbg(&pdev->dev, "dm9000_probe()
");
//函数netdev_priv直接返回了net_device结构末端地址，也就是网卡私有数据结构的起始地址。
    /* setup board info structure */
    db = netdev_priv(ndev);

    db->dev = &pdev->dev;
    db->ndev = ndev;

    spin_lock_init(&db->lock);//初始化自旋锁
    mutex_init(&db->addr_lock);

    INIT_DELAYED_WORK(&db->phy_poll, dm9000_poll_work); //??
//获取平台设备资源 resource 地址空间、数据空间、中断信号 7号中断
    db->addr_res = platform_get_resource(pdev, IORESOURCE_MEM, 0);
    db->data_res = platform_get_resource(pdev, IORESOURCE_MEM, 1);
    db->irq_res = platform_get_resource(pdev, IORESOURCE_IRQ, 0);
//判断资源是否获取成功
    if (db->addr_res == NULL || db->data_res == NULL ||
     db->irq_res == NULL) {
        dev_err(db->dev, "insufficient resources
");
        ret = -ENOENT;
        goto out;
    }
//platform_get_resource的变体 同  platform_get_resource(pdev, IORESOURCE_IRQ, 1)
    db->irq_wake = platform_get_irq(pdev, 1); 
    if (db->irq_wake >= 0) {
        dev_dbg(db->dev, "wakeup irq %d
", db->irq_wake);
                                                                                                         //前面获得中断号  申请中断
        ret = request_irq(db->irq_wake, dm9000_wol_interrupt,
                 IRQF_SHARED, dev_name(db->dev), ndev);
        if (ret) {
            dev_err(db->dev, "cannot get wakeup irq (%d)
", ret);
        } else {
            /* test to see if irq is really wakeup capable */
            ret = set_irq_wake(db->irq_wake, 1);
            if (ret) {
                dev_err(db->dev, "irq %d cannot set wakeup (%d)
",
                    db->irq_wake, ret);
                ret = 0;
            } else {
                set_irq_wake(db->irq_wake, 0);
                db->wake_supported = 1;
            }
        }
    }
//IO资源分配大小  地址  为resource分配内存
    iosize = resource_size(db->addr_res);
    db->addr_req = request_mem_region(db->addr_res->start, iosize,
                     pdev->name); //内存申请

    if (db->addr_req == NULL) {
        dev_err(db->dev, "cannot claim address reg area
");
        ret = -EIO;
        goto out;
    }

    db->io_addr = ioremap(db->addr_res->start, iosize);

    if (db->io_addr == NULL) {
        dev_err(db->dev, "failed to ioremap address reg
");
        ret = -EINVAL;
        goto out;
    }

    iosize = resource_size(db->data_res);
    db->data_req = request_mem_region(db->data_res->start, iosize,
                     pdev->name);

    if (db->data_req == NULL) {
        dev_err(db->dev, "cannot claim data reg area
");
        ret = -EIO;
        goto out;
    }

    db->io_data = ioremap(db->data_res->start, iosize);

    if (db->io_data == NULL) {
        dev_err(db->dev, "failed to ioremap data reg
");
        ret = -EINVAL;
        goto out;
    }
//初始化net_device中的成员
    /* fill in parameters for net-dev structure */
    ndev->base_addr = (unsigned long)db->io_addr; //网络接口的IO基地址
    ndev->irq    = db->irq_res->start;//中断号  ifconfig时会打印出这个值  也可通过这个修改

    /* ensure at least we have a default set of IO routines */
    dm9000_set_io(db, iosize); 

    /* check to see if anything is being over-ridden */
    if (pdata != NULL) {
        /* check to see if the driver wants to over-ride the
         * default IO width */
//检测与板级信息是否相同
        if (pdata->flags & DM9000_PLATF_8BITONLY)
            dm9000_set_io(db, 1);

        if (pdata->flags & DM9000_PLATF_16BITONLY)
            dm9000_set_io(db, 2);

        if (pdata->flags & DM9000_PLATF_32BITONLY)
            dm9000_set_io(db, 4);

        /* check to see if there are any IO routine
         * over-rides */

        if (pdata->inblk != NULL)
            db->inblk = pdata->inblk;

        if (pdata->outblk != NULL)
            db->outblk = pdata->outblk;

        if (pdata->dumpblk != NULL)
            db->dumpblk = pdata->dumpblk;

        db->flags = pdata->flags;
    }

#ifdef CONFIG_DM9000_FORCE_SIMPLE_PHY_POLL
    db->flags |= DM9000_PLATF_SIMPLE_PHY;
#endif

    dm9000_reset(db);

    /* try multiple times, DM9000 sometimes gets the read wrong */
    for (i = 0; i < 8; i++) {  //宏定义在dm9000.h中
        id_val = ior(db, DM9000_VIDL);
        id_val |= (u32)ior(db, DM9000_VIDH) << 8;
        id_val |= (u32)ior(db, DM9000_PIDL) << 16;
        id_val |= (u32)ior(db, DM9000_PIDH) << 24;

        if (id_val == DM9000_ID)
            break;
        dev_err(db->dev, "read wrong id 0x%08x
", id_val);
    }

    if (id_val != DM9000_ID) {
        dev_err(db->dev, "wrong id: 0x%08x
", id_val);
        ret = -ENODEV;
        goto out;
    }

    /* Identify what type of DM9000 we are working on */

    id_val = ior(db, DM9000_CHIPR);
    dev_dbg(db->dev, "dm9000 revision 0x%02x
", id_val);

    switch (id_val) {
    case CHIPR_DM9000A:
        db->type = TYPE_DM9000A;
        break;
    case CHIPR_DM9000B:
        db->type = TYPE_DM9000B;
        break;
    default:
        dev_dbg(db->dev, "ID %02x => defaulting to DM9000E
", id_val);
        db->type = TYPE_DM9000E;
    }

    /* dm9000a/b are capable of hardware checksum offload */
    if (db->type == TYPE_DM9000A || db->type == TYPE_DM9000B) {
        db->can_csum = 1;
        db->rx_csum = 1;
        ndev->features |= NETIF_F_IP_CSUM;
    }

    /* from this point we assume that we have found a DM9000 */

    /* driver system function */ //初始化以太网设备的公有成员
    ether_setup(ndev);//在调用register_netdev之前必须初始化完全。该函数中为net_device设置了很多默认值

    ndev->netdev_ops    = &dm9000_netdev_ops;
    ndev->watchdog_timeo    = msecs_to_jiffies(watchdog);
    ndev->ethtool_ops    = &dm9000_ethtool_ops;

    db->msg_enable = NETIF_MSG_LINK;
    db->mii.phy_id_mask = 0x1f;
    db->mii.reg_num_mask = 0x1f;
    db->mii.force_media = 0;
    db->mii.full_duplex = 0;
    db->mii.dev     = ndev;
    db->mii.mdio_read = dm9000_phy_read;
    db->mii.mdio_write = dm9000_phy_write;

    mac_src = "eeprom";

    /* try reading the node address from the attached EEPROM */
    for (i = 0; i < 6; i += 2)
        dm9000_read_eeprom(db, i / 2, ndev->dev_addr+i);

    if (!is_valid_ether_addr(ndev->dev_addr) && pdata != NULL) {
        mac_src = "platform data";
        memcpy(ndev->dev_addr, pdata->dev_addr, 6);
    }

    if (!is_valid_ether_addr(ndev->dev_addr)) {
        /* try reading from mac */
        
        mac_src = "chip";
        for (i = 0; i < 6; i++)
            ndev->dev_addr[i] = ior(db, i+DM9000_PAR);
    }

    if (!is_valid_ether_addr(ndev->dev_addr))
        dev_warn(db->dev, "%s: Invalid ethernet MAC address. Please "
             "set using ifconfig
", ndev->name);

    platform_set_drvdata(pdev, ndev);
    ret = register_netdev(ndev); //注册net_device结构体

    if (ret == 0)
        printk(KERN_INFO "%s: dm9000%c at %p,%p IRQ %d MAC: %pM (%s)
",
         ndev->name, dm9000_type_to_char(db->type),
         db->io_addr, db->io_data, ndev->irq,
         ndev->dev_addr, mac_src);
    return 0;

out:
    dev_err(db->dev, "not found (%d).
", ret);

    dm9000_release_board(pdev, db);
    free_netdev(ndev); //分配错误则释放net_device结构

    return ret;
}

模块加载后转入probe中执行，在probe中完成了分配net_device、网络设备的初始化，设备驱动的加载。

先是分配获得了net_device结构体等。

网络设备初始化包括:

进行硬件上的准备工作，检查网络设备是否存在，检测所使用的硬件资源。主要是resource

获得软件接口上的准备工作。

获得私有数据指针，初始化以太网设备公有成员、初始化成员，初始化自旋锁或并发同步机制、申请设备所需的硬件资源 request_region等。

 

在网络设备驱动程序完成模块注册时，会调用dm9000_probe()函数进行初始化，分配并初始化net_device结构体。其中有些成员在dm9000_probe()中已经完成初始化，还有一些函数指针例如（*open）（）、（*release）（）等函数，也是在驱动程序中进行定义。

 

4.dm9000_open（）

open函数在执行ifconfig命令时会被激活。主要作用是打开网络设备，获得设备所需的IO地址，IRQ、DMA通道等。注册中断、设置寄存器、启动发送队列。

在字符设备驱动中是把中断注册放在模块初始化函数中，而网卡驱动则放在open函数中。原因是网卡有禁用操作，当被禁用的时候，要把占用的中断号释放。

m9000_open(struct net_device *dev)
{
    board_info_t *db = netdev_priv(dev);//获取设备私有数据 返回board_info_t的地址
    unsigned long irqflags = db->irq_res->flags & IRQF_TRIGGER_MASK;

    if (netif_msg_ifup(db))
        dev_dbg(db->dev, "enabling %s
", dev->name);

    /* If there is no IRQ type specified, default to something that
     * may work, and tell the user that this is a problem */

    if (irqflags == IRQF_TRIGGER_NONE)
        dev_warn(db->dev, "WARNING: no IRQ resource flags set.
");

    irqflags |= IRQF_SHARED;
//注册中断
    if (request_irq(dev->irq, dm9000_interrupt, irqflags, dev->name, dev))
        return -EAGAIN;

    /* Initialize DM9000 board */
    dm9000_reset(db); //复位DM9000
    dm9000_init_dm9000(dev); //初始化dm9000中net_device结构中的成员

    /* Init driver variable */
    db->dbug_cnt = 0;

    mii_check_media(&db->mii, netif_msg_link(db), 1);//检测mii接口状态
    netif_start_queue(dev); //启动发送队列  协议栈向网卡发送
    
    dm9000_schedule_poll(db);

    return 0;
}

5.stop（）

设备关闭函数

tatic int dm9000_stop(struct net_device *ndev)
{
    board_info_t *db = netdev_priv(ndev);

    if (netif_msg_ifdown(db))
        dev_dbg(db->dev, "shutting down %s
", ndev->name);

    cancel_delayed_work_sync(&db->phy_poll); /* 终止phy_poll队列中被延迟的任务 */

    netif_stop_queue(ndev); /* 关闭发送队列 */
    netif_carrier_off(ndev); 

    /* free interrupt */
    free_irq(ndev->irq, ndev);   /* 释放中断 */

    dm9000_shutdown(ndev);  /* 关闭DM9000网卡 */ 

    return 0;
}

6.dm9000_shutdown()

下面是调用的dm9000_shutdown(ndev)函数，该函数的功能是复位phy，配置寄存器GPR位0为1，关闭dm9000电源，配置寄存器IMR位7为1，disable中断，配置寄存器RCR，disable接收.

static void dm9000_shutdown(struct net_device *dev)
{
    board_info_t *db = netdev_priv(dev);

    /* RESET device */
    dm9000_phy_write(dev, 0, MII_BMCR, BMCR_RESET);   /* PHY RESET ,复位PHY*/ 
    iow(db, DM9000_GPR, 0x01);    /* Power-Down PHY */
    iow(db, DM9000_IMR, IMR_PAR);  /* Disable all interrupt ，关闭所有的中断*/
    iow(db, DM9000_RCR, 0x00);   /* Disable RX ,不再接受数据*/
}

7.数据发送函数

数据包发送流程:

1)设备驱动程序从上层协议传递过来的sk_buff参数获得数据包的有效数据和长度，将有效数据放入临时缓冲区中。

2)设置硬件寄存器，驱动网络设备进行数据发送操作。

static int dm9000_start_xmit(struct sk_buff *skb, struct net_device *dev)
{
    unsigned long flags;
    board_info_t *db = netdev_priv(dev);

    dm9000_dbg(db, 3, "%s:
", __func__);

    if (db->tx_pkt_cnt > 1)
        return NETDEV_TX_BUSY;

    spin_lock_irqsave(&db->lock, flags); //获得自旋锁

    /* Move data to DM9000 TX RAM */
    writeb(DM9000_MWCMD, db->io_addr); //根据 IO 操作模式(8-bit or 16-bit)来增加写指针 1 或 2

    (db->outblk)(db->io_data, skb->data, skb->len); //将数据从sk_buff中copy到网卡的TX SRAM中
    dev->stats.tx_bytes += skb->len; //统计发送的字节数

    db->tx_pkt_cnt++; //待发送计数 
    /* TX control: First packet immediately send, second packet queue */
    if (db->tx_pkt_cnt == 1) {  //如果计数为1，直接发送
        dm9000_send_packet(dev, skb->ip_summed, skb->len);
    } else {
        /* Second packet */
        db->queue_pkt_len = skb->len;
        db->queue_ip_summed = skb->ip_summed;
        netif_stop_queue(dev); //告诉上层停止发送
    }

    spin_unlock_irqrestore(&db->lock, flags);//解锁

    /* free this SKB */
    dev_kfree_skb(skb); //释放SKB

    return NETDEV_TX_OK;
}

dm9000_start_xmit通过调用dm9000_send_packet来发送数据。

8.发送数据

dm9000_start_xmit函数中获得要发送的数据字节数，并调用dm9000_send_packet来发送数据。

static void dm9000_send_packet(struct net_device *dev,
             int ip_summed,
             u16 pkt_len)
{
    board_info_t *dm = to_dm9000_board(dev);

    /* The DM9000 is not smart enough to leave fragmented packets alone. */
    if (dm->ip_summed != ip_summed) {
        if (ip_summed == CHECKSUM_NONE)
            iow(dm, DM9000_TCCR, 0);
        else
            iow(dm, DM9000_TCCR, TCCR_IP | TCCR_UDP | TCCR_TCP);
        dm->ip_summed = ip_summed;
    }

    /* Set TX length to DM9000 *///设置发送数据的长度到TXPLLTXPLH中
    iow(dm, DM9000_TXPLL, pkt_len);
    iow(dm, DM9000_TXPLH, pkt_len >> 8);

    /* Issue TX polling command *///设置发送寄存器的发送控制位，启动发送数据
    iow(dm, DM9000_TCR, TCR_TXREQ);    /* Cleared after TX complete */
}

9.发送超时函数

发送数据时并不一定会成功，系统会调用dm9000_timeout函数。当传输数据超时时，意味发送操作失败或硬件进入未知状态。在超时函数中会调用netif_wake_queue()函数来重新启动设备发送队列。

static void dm9000_timeout(struct net_device *dev)
{
    board_info_t *db = netdev_priv(dev);
    u8 reg_save;
    unsigned long flags;

    /* Save previous register address */
    reg_save = readb(db->io_addr);
    spin_lock_irqsave(&db->lock, flags);

    netif_stop_queue(dev);
    dm9000_reset(db);
    dm9000_init_dm9000(dev);
    /* We can accept TX packets again */
    dev->trans_start = jiffies; /* prevent tx timeout */
    netif_wake_queue(dev); //重启发送队列

    /* Restore previous register address */
    writeb(reg_save, db->io_addr);
    spin_unlock_irqrestore(&db->lock, flags);
}

由此，netif_wake_queue()函数与netif_stop_queue()是数据发送流程中要调用的两个重要的函数，分别用于唤醒和阻止上层向下层传送数据包。原型定义于include/linux/netdevice.h中。

 

10.发送中断处理函数

当一个数据包发送完成后会产生一个中断，进入中断处理函数。

static void dm9000_tx_done(struct net_device *dev, board_info_t *db)
{
    int tx_status = ior(db, DM9000_NSR);    /* Got TX status */

    if (tx_status & (NSR_TX2END | NSR_TX1END)) { //检测一个数据包发送完毕
        /* One packet sent complete */
        db->tx_pkt_cnt--;  //待发送的数据包数减1
        dev->stats.tx_packets++;//已发送数据包加1

        if (netif_msg_tx_done(db))
            dev_dbg(db->dev, "tx done, NSR %02x
", tx_status);

        /* Queue packet check & send */
        if (db->tx_pkt_cnt > 0) //如果还有数据包，则继续发送
            dm9000_send_packet(dev, db->queue_ip_summed,
                     db->queue_pkt_len);
        netif_wake_queue(dev); //启动发送队列
    }
}

11.中断处理函数

网络设备接收数据的主要方法是有中断引发设备的中断处理函数，中断处理函数判断中断的类型，如果为接收中断，则读取接收到的数据，分配sk_buff数据结构和数据缓冲区，将接收到的数据复制到数据缓冲区中，并调用netif_rx()函数将sk_buff传递给上层协议。

static irqreturn_t dm9000_interrupt(int irq, void *dev_id)
{
    struct net_device *dev = dev_id;
    board_info_t *db = netdev_priv(dev);
    int int_status;
    unsigned long flags;
    u8 reg_save;

    dm9000_dbg(db, 3, "entering %s
", __func__);

    /* A real interrupt coming */

    /* holders of db->lock must always block IRQs */
    spin_lock_irqsave(&db->lock, flags);

    /* Save previous register address */
    reg_save = readb(db->io_addr);

    /* Disable all interrupts */
    iow(db, DM9000_IMR, IMR_PAR);

    /* Got DM9000 interrupt status */ //获取中断类型
    int_status = ior(db, DM9000_ISR);    /* Got ISR */
    iow(db, DM9000_ISR, int_status);    /* Clear ISR status */

    if (netif_msg_intr(db))
        dev_dbg(db->dev, "interrupt status %02x
", int_status);

    /* Received the coming packet */ //接收到一个数据包
    if (int_status & ISR_PRS)
        dm9000_rx(dev); //调用数据接收函数

    /* Trnasmit Interrupt check */ //发送一个数据包
    if (int_status & ISR_PTS)
        dm9000_tx_done(dev, db); //调用数据发送函数

    if (db->type != TYPE_DM9000E) {
        if (int_status & ISR_LNKCHNG) {
            /* fire a link-change request */
            schedule_delayed_work(&db->phy_poll, 1);
        }
    }

    /* Re-enable interrupt mask */
    iow(db, DM9000_IMR, db->imr_all);

    /* Restore previous register address */
    writeb(reg_save, db->io_addr);

    spin_unlock_irqrestore(&db->lock, flags);

    return IRQ_HANDLED;
}

12.接收数据

接收数据函数主要将接收到的数据包传递给上层。

dm9000_rx(struct net_device *dev)
{
    board_info_t *db = netdev_priv(dev); //获得网卡私有数据首地址
    struct dm9000_rxhdr rxhdr;
    struct sk_buff *skb;
    u8 rxbyte, *rdptr;
    bool GoodPacket;
    int RxLen;

    /* Check packet ready or not */
    do {//存储器地址不变的读数据
        ior(db, DM9000_MRCMDX);    /* Dummy read */ //MRCMDX是内存数据预取读命令
 
        /* Get most updated data */
        rxbyte = readb(db->io_data);

        /* Status check: this byte must be 0 or 1 */ //0、1为正确，2表示接收出错
        if (rxbyte & DM9000_PKT_ERR) {
            dev_warn(db->dev, "status check fail: %d
", rxbyte);
            iow(db, DM9000_RCR, 0x00);    /* Stop Device */ //关闭设备 并停止中断请求
            iow(db, DM9000_ISR, IMR_PAR);    /* Stop INT request */
            return;
        }

        if (!(rxbyte & DM9000_PKT_RDY)) // 0x01没准备好，直接返回
            return;

        /* A packet ready now & Get status/length */
        GoodPacket = true;
        writeb(DM9000_MRCMD, db->io_addr);
      //读取数据，从RX_SRAM读取到rxhdr中
        (db->inblk)(db->io_data, &rxhdr, sizeof(rxhdr)); 

        RxLen = le16_to_cpu(rxhdr.RxLen);

        if (netif_msg_rx_status(db))
            dev_dbg(db->dev, "RX: status %02x, length %04x
",
                rxhdr.RxStatus, RxLen);

        /* Packet Status check */ //检查包得完整性
        if (RxLen < 0x40) {
            GoodPacket = false;
            if (netif_msg_rx_err(db))
                dev_dbg(db->dev, "RX: Bad Packet (runt)
");
        }

        if (RxLen > DM9000_PKT_MAX) {
            dev_dbg(db->dev, "RST: RX Len:%x
", RxLen);
        }

        /* rxhdr.RxStatus is identical to RSR register. */
        if (rxhdr.RxStatus & (RSR_FOE | RSR_CE | RSR_AE |
                 RSR_PLE | RSR_RWTO |
                 RSR_LCS | RSR_RF)) {
            GoodPacket = false;
            if (rxhdr.RxStatus & RSR_FOE) {
                if (netif_msg_rx_err(db))
                    dev_dbg(db->dev, "fifo error
");
                dev->stats.rx_fifo_errors++;
            }
            if (rxhdr.RxStatus & RSR_CE) {
                if (netif_msg_rx_err(db))
                    dev_dbg(db->dev, "crc error
");
                dev->stats.rx_crc_errors++;
            }
            if (rxhdr.RxStatus & RSR_RF) {
                if (netif_msg_rx_err(db))
                    dev_dbg(db->dev, "length error
");
                dev->stats.rx_length_errors++;
            }
        }

        /* Move data from DM9000 */ //从DM9000获取数据
        if (GoodPacket && //分配SKB
         ((skb = dev_alloc_skb(RxLen + 4)) != NULL)) {  //+4是因为除了数据包前面还有空读一字节、读状态一字节、读长度低位和高位各一个字节
            skb_reserve(skb, 2);  //定位data指针 DA(6)+SA(6)+type(2)+IP包+CFS(校验码4字节)  IP包要求四字节对齐
            rdptr = (u8 *) skb_put(skb, RxLen - 4);  //定位tail指针  -4是减去校验码

            /* Read received packet from RX SRAM */
       //读取数据 从RX SRAM 到sk_buff中
            (db->inblk)(db->io_data, rdptr, RxLen);
            dev->stats.rx_bytes += RxLen;

            /* Pass to upper layer */ //获取上层协议类型
            skb->protocol = eth_type_trans(skb, dev);
            if (db->rx_csum) {
                if ((((rxbyte & 0x1c) << 3) & rxbyte) == 0)
                    skb->ip_summed = CHECKSUM_UNNECESSARY;
                else
                    skb->ip_summed = CHECKSUM_NONE;
            }
            netif_rx(skb); //把数据包交给上层
            dev->stats.rx_packets++;

        } else {
            /* need to dump the packet's data */

            (db->dumpblk)(db->io_data, RxLen);
        }
    } while (rxbyte & DM9000_PKT_RDY);
}

可以看出接收数据主要包括:

判断为接收数据中断----dm9000_rx()完成更深入的数据包接收工作[获取数据包长度，分配sk_buff和数据段缓冲区，读取硬件接收的数据放入缓冲区中，解析上层协议类型，将数据包交给上层]