Linux内核网络栈实现分析（三）驱动程序层+链路层（上）

本文分析基于Linux Kernel 1.2.13

原创作品，转载请标明http://blog.csdn.net/yming0221/article/details/7497260

更多请看专栏，地址http://blog.csdn.net/column/details/linux-kernel-net.html

作者：闫明

注：标题中的”（上）“，”（下）“表示分析过程基于数据包的传递方向：”（上）“表示分析是从底层向上分析、”（下）“表示分析是从上向下分析。

经过前面两篇博文的分析，已经对Linux的内核网络栈的结构有了一个模糊的认识，这里我们开始从底层开始详细分析Linux内核网络栈的实现。由于这是早期版本，代码的层次隔离做的还不是很好，这里说是从底层分析，但是不免会牵扯上层或下层的函数，许多关键代码都在驱动的文件夹下。

我们首先有第一篇博文中知道在网络栈初始化的时候在net/socket.c中的函数sock_init()函数中当proto_init()完成后会执行dev_init()来进行网络设备模块的初始化。

首先说明一下，在drivers/net/space.c中定义了设备首节点地址dev_base，其实际上是回环设备的地址。

struct device loopback_dev = {

    "lo",           /* Software Loopback interface      */

    0x0,            /* recv memory end          */

    0x0,            /* recv memory start            */

    0x0,            /* memory end               */

    0x0,            /* memory start             */

    0,          /* base I/O address         */

    0,          /* IRQ                  */

    0, 0, 0,        /* flags                */

    NEXT_DEV,       /* next device              */

    loopback_init       /* loopback_init should set up the rest */

};


struct device *dev_base = &loopback_dev;

而NEXT_DEV宏定义即定义了下一个网络设备的地址，这样可以把设备串成链。

附网络设备的定义(include/linux/netdevice.h)如下:

/*

 * The DEVICE structure.

 * Actually, this whole structure is a big mistake.  It mixes I/O

 * data with strictly "high-level" data, and it has to know about

 * almost every data structure used in the INET module.

 */

struct device

{


  /*

   * This is the first field of the "visible" part of this structure

   * (i.e. as seen by users in the "Space.c" file).  It is the name

   * the interface.

   */

  char            *name;


  /* I/O specific fields - FIXME: Merge these and struct ifmap into one */

  unsigned long       rmem_end;     /* shmem "recv" end */

  unsigned long       rmem_start;       /* shmem "recv" start   */

  unsigned long       mem_end;      /* sahared mem end  */

  unsigned long       mem_start;        /* shared mem start */

  unsigned long       base_addr;        /* device I/O address   */

  unsigned char       irq;          /* device IRQ number    */


  /* Low-level status flags. */

  volatile unsigned char  start,        /* start an operation   */

                          tbusy,        /* transmitter busy */

                          interrupt;        /* interrupt arrived    */


  struct device       *next;


  /* The device initialization function. Called only once. */

  int             (*init)(struct device *dev);


  /* Some hardware also needs these fields, but they are not part of the

     usual set specified in Space.c. */

  unsigned char       if_port;      /* Selectable AUI, TP,..*/

  unsigned char       dma;          /* DMA channel      */


  struct enet_statistics* (*get_stats)(struct device *dev);


  /*

   * This marks the end of the "visible" part of the structure. All

   * fields hereafter are internal to the system, and may change at

   * will (read: may be cleaned up at will).

   */


  /* These may be needed for future network-power-down code. */

  unsigned long       trans_start;  /* Time (in jiffies) of last Tx */

  unsigned long       last_rx;  /* Time of last Rx      */


  unsigned short      flags;    /* interface flags (a la BSD)   */

  unsigned short      family;   /* address family ID (AF_INET)  */

  unsigned short      metric;   /* routing metric (not used)    */

  unsigned short      mtu;      /* interface MTU value      */

  unsigned short      type;     /* interface hardware type  */

  unsigned short      hard_header_len;  /* hardware hdr length  */

  void            *priv;    /* pointer to private data  */


  /* Interface address info. */

  unsigned char       broadcast[MAX_ADDR_LEN];  /* hw bcast add */

  unsigned char       dev_addr[MAX_ADDR_LEN];   /* hw address   */

  unsigned char       addr_len; /* hardware address length  */

  unsigned long       pa_addr;  /* protocol address     */

  unsigned long       pa_brdaddr;   /* protocol broadcast addr  */

  unsigned long       pa_dstaddr;   /* protocol P-P other side addr */

  unsigned long       pa_mask;  /* protocol netmask     */

  unsigned short      pa_alen;  /* protocol address length  */


  struct dev_mc_list     *mc_list;  /* Multicast mac addresses  */

  int            mc_count;  /* Number of installed mcasts   */


  struct ip_mc_list  *ip_mc_list;   /* IP multicast filter chain    */


  /* For load balancing driver pair support */


  unsigned long        pkt_queue;   /* Packets queued */

  struct device       *slave;   /* Slave device */



  /* Pointer to the interface buffers. */

  struct sk_buff_head     buffs[DEV_NUMBUFFS];


  /* Pointers to interface service routines. */

  int             (*open)(struct device *dev);

  int             (*stop)(struct device *dev);

  int             (*hard_start_xmit) (struct sk_buff *skb,

                          struct device *dev);

  int             (*hard_header) (unsigned char *buff,

                      struct device *dev,

                      unsigned short type,

                      void *daddr,

                      void *saddr,

                      unsigned len,

                      struct sk_buff *skb);

  int             (*rebuild_header)(void *eth, struct device *dev,

                unsigned long raddr, struct sk_buff *skb);

  unsigned short      (*type_trans) (struct sk_buff *skb,

                     struct device *dev);

#define HAVE_MULTICAST

  void            (*set_multicast_list)(struct device *dev,

                     int num_addrs, void *addrs);

#define HAVE_SET_MAC_ADDR

  int             (*set_mac_address)(struct device *dev, void *addr);

#define HAVE_PRIVATE_IOCTL

  int             (*do_ioctl)(struct device *dev, struct ifreq *ifr, int cmd);

#define HAVE_SET_CONFIG

  int             (*set_config)(struct device *dev, struct ifmap *map);


};

dev_init()网络设备的初始化函数如下：

/*

 *  Initialize the DEV module. At boot time this walks the device list and

 *  unhooks any devices that fail to initialise (normally hardware not

 *  present) and leaves us with a valid list of present and active devices.

 *

 *  The PCMCIA code may need to change this a little, and add a pair

 *  of register_inet_device() unregister_inet_device() calls. This will be

 *  needed for ethernet as modules support.

 */


void dev_init(void)

{

    struct device *dev, *dev2;


    /*

     *  Add the devices.

     *  If the call to dev->init fails, the dev is removed

     *  from the chain disconnecting the device until the

     *  next reboot.

     */


    dev2 = NULL;

    for (dev = dev_base; dev != NULL; dev=dev->next) //循环移除设备由璞傅絛ev_base指向的网络设备链表

    {

        if (dev->init && dev->init(dev)) //如果设备有初始化函数并且初始化失败，则从链表摘除设备（init()函数成功返回0）

        {

            /*

             *  It failed to come up. Unhook it.这个函数还挺有技巧性的，从默认配置的设备中扫描不存在的设备，将其移除

             */


            if (dev2 == NULL)

                dev_base = dev->next;

            else

                dev2->next = dev->next;

        }

        else

        {

            dev2 = dev;

        }

    }

}

这里我们看一下dev_base这个队列是如何定义的，这里我们仅仅看eth网卡的定义方式即可

/* "eth0" defaults to autoprobe (== 0), other use a base of 0xffe0 (== -0x20),

   which means "don't probe".  These entries exist to only to provide empty

   slots which may be enabled at boot-time. */


static struct device eth3_dev = {

    "eth3", 0,0,0,0,0xffe0 /* I/O base*/, 0,0,0,0, NEXT_DEV, ethif_probe };

static struct device eth2_dev = {

    "eth2", 0,0,0,0,0xffe0 /* I/O base*/, 0,0,0,0, eth3_dev, ethif_probe };

static struct device eth1_dev = {

    "eth1", 0,0,0,0,0xffe0 /* I/O base*/, 0,0,0,0, eth2_dev, ethif_probe };


static struct device eth0_dev = {

    "eth0", 0, 0, 0, 0, ETH0_ADDR, ETH0_IRQ, 0, 0, 0, eth1_dev, ethif_probe };


#   undef NEXT_DEV

#   define NEXT_DEV (eth0_dev)

可以看出eth系列网卡设备的init函数定义为ethif_probe()，该函数会调用具体网卡的探测函数，我们还是以 NS8390 ethernet网卡为例来分析，该网卡的驱动实现文件为drivers/net/ne.c

ethif_probe()函数会调用函数ne_probe()探测函数，而该函数对设备地址进行检查后调用ne_probe1()函数，具体工作有ne_probe1()函数完成。

函数如下：

static int ne_probe1(struct device *dev, int ioaddr)

{

.....................//合法性检查

/* Fixup for users that don't know that IRQ 2 is really IRQ 9,

       or don't know which one to set. */

    dev->irq = 9;//设置中断类型号


    /* Snarf the interrupt now.  There's no point in waiting since we cannot

       share and the board will usually be enabled. */

    {

    int irqval = request_irq (dev->irq, ei_interrupt, 0, wordlength==2 ? "ne2000":"ne1000");//注册申请中断，中断处理函数为ei_interrupt

    if (irqval) {

        printk (" unable to get IRQ %d (irqval=%d).\n", dev->irq, irqval);

        return EAGAIN;

    }

    }


    dev->base_addr = ioaddr;


    request_region(ioaddr, NE_IO_EXTENT, wordlength==2 ? "ne2000":"ne1000");//申请内存空间


    for(i = 0; i < ETHER_ADDR_LEN; i++)

    dev->dev_addr[i] = SA_prom[i];


    ethdev_init(dev);//调用函数对dev设备结构体进行初始化

    printk("\n%s: %s found at %#x, using IRQ %d.\n",

       dev->name, name, ioaddr, dev->irq);


    if (ei_debug > 0)

    printk(version);


    ei_status.name = name;

    ei_status.tx_start_page = start_page;

    ei_status.stop_page = stop_page;

    ei_status.word16 = (wordlength == 2);


    ei_status.rx_start_page = start_page + TX_PAGES;

#ifdef PACKETBUF_MEMSIZE

    /* Allow the packet buffer size to be overridden by know-it-alls. */

    ei_status.stop_page = ei_status.tx_start_page + PACKETBUF_MEMSIZE;

#endif


    ei_status.reset_8390 = &ne_reset_8390;

    ei_status.block_input = &ne_block_input;

    ei_status.block_output = &ne_block_output;

    NS8390_init(dev, 0);//配置网卡中的寄存器等到默认状态

    return 0;

}

初始化函数ethdev_init()在文件drivers/net/8390.c中。如下：

/* Initialize the rest of the 8390 device structure. */

int ethdev_init(struct device *dev)

{

    if (ei_debug > 1)

        printk(version);


    if (dev->priv == NULL) {//申请私有空间存储具体网卡的结构体信息

        struct ei_device *ei_local;//8390网卡设备的结构体


        dev->priv = kmalloc(sizeof(struct ei_device), GFP_KERNEL);//申请内核内存空间

        memset(dev->priv, 0, sizeof(struct ei_device));

        ei_local = (struct ei_device *)dev->priv;

#ifndef NO_PINGPONG

        ei_local->pingpong = 1;

#endif

    }


    /* The open call may be overridden by the card-specific code. */

    if (dev->open == NULL)

        dev->open = &ei_open;//设备的打开函数

    /* We should have a dev->stop entry also. */

    dev->hard_start_xmit = &ei_start_xmit;//设备的发送函数，定义在8390.c中

    dev->get_stats   = get_stats;

#ifdef HAVE_MULTICAST

    dev->set_multicast_list = &set_multicast_list;

#endif


    ether_setup(dev);//进一步调用函数设置dev设备结构体


    return 0;

}

ether_setup()函数的实现如下：

void ether_setup(struct device *dev)

{

    int i;

    /* Fill in the fields of the device structure with ethernet-generic values.

       This should be in a common file instead of per-driver.  */

    for (i = 0; i < DEV_NUMBUFFS; i++)

        skb_queue_head_init(&dev->buffs[i]);//缓冲队列初始化


    /* register boot-defined "eth" devices */

    if (dev->name && (strncmp(dev->name, "eth", 3) == 0)) {//定义eth网卡的名称

        i = simple_strtoul(dev->name + 3, NULL, 0);

        if (ethdev_index[i] == NULL) {

            ethdev_index[i] = dev;

        }

        else if (dev != ethdev_index[i]) {

            /* Really shouldn't happen! */

            printk("ether_setup: Ouch! Someone else took %s\n",

                dev->name);

        }

    }


    dev->hard_header = eth_header;//该函数的作用是创建链路层首部，定义在eth.c中

    dev->rebuild_header = eth_rebuild_header;//该函数的作用是重建链路层首部，用于ARP协议

    dev->type_trans = eth_type_trans;


    dev->type        = ARPHRD_ETHER;

    dev->hard_header_len = ETH_HLEN;

    dev->mtu     = 1500; /* eth_mtu */

    dev->addr_len    = ETH_ALEN;

    for (i = 0; i < ETH_ALEN; i++) {

        dev->broadcast[i]=0xff;

    }


    /* New-style flags. */

    dev->flags       = IFF_BROADCAST|IFF_MULTICAST;

    dev->family      = AF_INET;

    dev->pa_addr = 0;

    dev->pa_brdaddr = 0;

    dev->pa_mask = 0;

    dev->pa_alen = sizeof(unsigned long);

}

这样，网络设备的初始化工作就完成了。

在drivers/net/8390.c中实现了该网卡的设备的基本操作函数，

设备的打开函数ei_open()比较简单，下面列出该设备的发送和接收函数，在这里不做具体的分析，如果想更多了解请点击前面分析过的DM9000网卡驱动，下面给出链接：

1. ARM-Linux驱动--DM9000网卡驱动分析（一）
   
2. ARM-Linux驱动--DM9000网卡驱动分析（二）
   
3. ARM-Linux驱动--DM9000网卡驱动分析（三）
   
4. ARM-Linux驱动--DM9000网卡驱动分析（四）

其基本结构是一致的。

ei_start_xmit()

static int ei_start_xmit(struct sk_buff *skb, struct device *dev)

{

    int e8390_base = dev->base_addr;

    struct ei_device *ei_local = (struct ei_device *) dev->priv;

    int length, send_length;

    unsigned long flags;


/*

 *  We normally shouldn't be called if dev->tbusy is set, but the

 *  existing code does anyway. If it has been too long since the

 *  last Tx, we assume the board has died and kick it.

 */


    if (dev->tbusy) {    /* Do timeouts, just like the 8003 driver. */

        int txsr = inb(e8390_base+EN0_TSR), isr;

        int tickssofar = jiffies - dev->trans_start;

        if (tickssofar < TX_TIMEOUT ||   (tickssofar < (TX_TIMEOUT+5) && ! (txsr & ENTSR_PTX))) {

            return 1;

        }

        isr = inb(e8390_base+EN0_ISR);

        if (dev->start == 0) {

            printk("%s: xmit on stopped card\n", dev->name);

            return 1;

        }

        printk(KERN_DEBUG "%s: transmit timed out, TX status %#2x, ISR %#2x.\n",

               dev->name, txsr, isr);

        /* Does the 8390 thinks it has posted an interrupt? */

        if (isr)

            printk(KERN_DEBUG "%s: Possible IRQ conflict on IRQ%d?\n", dev->name, dev->irq);

        else {

            /* The 8390 probably hasn't gotten on the cable yet. */

            printk(KERN_DEBUG "%s: Possible network cable problem?\n", dev->name);

            if(ei_local->stat.tx_packets==0)

                ei_local->interface_num ^= 1;    /* Try a different xcvr.  */

        }

        /* Try to restart the card.  Perhaps the user has fixed something. */

        ei_reset_8390(dev);

        NS8390_init(dev, 1);

        dev->trans_start = jiffies;

    }


    /* Sending a NULL skb means some higher layer thinks we've missed an

       tx-done interrupt. Caution: dev_tint() handles the cli()/sti()

       itself. */

    if (skb == NULL) {

        dev_tint(dev);

        return 0;

    }


    length = skb->len;

    if (skb->len <= 0)

        return 0;


    save_flags(flags);

    cli();


    /* Block a timer-based transmit from overlapping. */

    if ((set_bit(0, (void*)&dev->tbusy) != 0) || ei_local->irqlock) {

    printk("%s: Tx access conflict. irq=%d lock=%d tx1=%d tx2=%d last=%d\n",

        dev->name, dev->interrupt, ei_local->irqlock, ei_local->tx1,

        ei_local->tx2, ei_local->lasttx);

    restore_flags(flags);

    return 1;

    }


    /* Mask interrupts from the ethercard. */

    outb(0x00, e8390_base + EN0_IMR);

    ei_local->irqlock = 1;

    restore_flags(flags);


    send_length = ETH_ZLEN < length ? length : ETH_ZLEN;


    if (ei_local->pingpong) {

        int output_page;

        if (ei_local->tx1 == 0) {

            output_page = ei_local->tx_start_page;

            ei_local->tx1 = send_length;

            if (ei_debug  &&  ei_local->tx2 > 0)

                printk("%s: idle transmitter tx2=%d, lasttx=%d, txing=%d.\n",

                       dev->name, ei_local->tx2, ei_local->lasttx,

                       ei_local->txing);

        } else if (ei_local->tx2 == 0) {

            output_page = ei_local->tx_start_page + 6;

            ei_local->tx2 = send_length;

            if (ei_debug  &&  ei_local->tx1 > 0)

                printk("%s: idle transmitter, tx1=%d, lasttx=%d, txing=%d.\n",

                       dev->name, ei_local->tx1, ei_local->lasttx,

                       ei_local->txing);

        } else {    /* We should never get here. */

            if (ei_debug)

                printk("%s: No Tx buffers free. irq=%d tx1=%d tx2=%d last=%d\n",

                    dev->name, dev->interrupt, ei_local->tx1,

                    ei_local->tx2, ei_local->lasttx);

            ei_local->irqlock = 0;

            dev->tbusy = 1;

            outb_p(ENISR_ALL, e8390_base + EN0_IMR);

            return 1;

        }

        ei_block_output(dev, length, skb->data, output_page);

        if (! ei_local->txing) {

            ei_local->txing = 1;

            NS8390_trigger_send(dev, send_length, output_page);

            dev->trans_start = jiffies;

            if (output_page == ei_local->tx_start_page)

                ei_local->tx1 = -1, ei_local->lasttx = -1;

            else

                ei_local->tx2 = -1, ei_local->lasttx = -2;

        } else

            ei_local->txqueue++;


        dev->tbusy = (ei_local->tx1  &&  ei_local->tx2);

    } else {  /* No pingpong, just a single Tx buffer. */

        ei_block_output(dev, length, skb->data, ei_local->tx_start_page);

        ei_local->txing = 1;

        NS8390_trigger_send(dev, send_length, ei_local->tx_start_page);

        dev->trans_start = jiffies;

        dev->tbusy = 1;

    }


    /* Turn 8390 interrupts back on. */

    ei_local->irqlock = 0;

    outb_p(ENISR_ALL, e8390_base + EN0_IMR);


    dev_kfree_skb (skb, FREE_WRITE);


    return 0;

}

ei_receive()函数

static void ei_receive(struct device *dev)

{

    int e8390_base = dev->base_addr;

    struct ei_device *ei_local = (struct ei_device *) dev->priv;

    int rxing_page, this_frame, next_frame, current_offset;

    int rx_pkt_count = 0;

    struct e8390_pkt_hdr rx_frame;

    int num_rx_pages = ei_local->stop_page-ei_local->rx_start_page;


    while (++rx_pkt_count < 10) {

        int pkt_len;


        /* Get the rx page (incoming packet pointer). */

        outb_p(E8390_NODMA+E8390_PAGE1, e8390_base + E8390_CMD);

        rxing_page = inb_p(e8390_base + EN1_CURPAG);

        outb_p(E8390_NODMA+E8390_PAGE0, e8390_base + E8390_CMD);


        /* Remove one frame from the ring.  Boundary is always a page behind. */

        this_frame = inb_p(e8390_base + EN0_BOUNDARY) + 1;

        if (this_frame >= ei_local->stop_page)

            this_frame = ei_local->rx_start_page;


        /* Someday we'll omit the previous, iff we never get this message.

           (There is at least one clone claimed to have a problem.)  */

        if (ei_debug > 0  &&  this_frame != ei_local->current_page)

            printk("%s: mismatched read page pointers %2x vs %2x.\n",

                   dev->name, this_frame, ei_local->current_page);


        if (this_frame == rxing_page)   /* Read all the frames? */

            break;              /* Done for now */


        current_offset = this_frame << 8;

        ei_block_input(dev, sizeof(rx_frame), (char *)&rx_frame,

                       current_offset);


        pkt_len = rx_frame.count - sizeof(rx_frame);


        next_frame = this_frame + 1 + ((pkt_len+4)>>8);


        /* Check for bogosity warned by 3c503 book: the status byte is never

           written.  This happened a lot during testing! This code should be

           cleaned up someday. */

        if (rx_frame.next != next_frame

            && rx_frame.next != next_frame + 1

            && rx_frame.next != next_frame - num_rx_pages

            && rx_frame.next != next_frame + 1 - num_rx_pages) {

            ei_local->current_page = rxing_page;

            outb(ei_local->current_page-1, e8390_base+EN0_BOUNDARY);

            ei_local->stat.rx_errors++;

            continue;

        }


        if (pkt_len < 60  ||  pkt_len > 1518) {

            if (ei_debug)

                printk("%s: bogus packet size: %d, status=%#2x nxpg=%#2x.\n",

                       dev->name, rx_frame.count, rx_frame.status,

                       rx_frame.next);

            ei_local->stat.rx_errors++;

        } else if ((rx_frame.status & 0x0F) == ENRSR_RXOK) {

            struct sk_buff *skb;


            skb = alloc_skb(pkt_len, GFP_ATOMIC);

            if (skb == NULL) {

                if (ei_debug > 1)

                    printk("%s: Couldn't allocate a sk_buff of size %d.\n",

                           dev->name, pkt_len);

                ei_local->stat.rx_dropped++;

                break;

            } else {

                skb->len = pkt_len;

                skb->dev = dev;


                ei_block_input(dev, pkt_len, (char *) skb->data,

                               current_offset + sizeof(rx_frame));

                netif_rx(skb);

                ei_local->stat.rx_packets++;

            }

        } else {

            int errs = rx_frame.status;

            if (ei_debug)

                printk("%s: bogus packet: status=%#2x nxpg=%#2x size=%d\n",

                       dev->name, rx_frame.status, rx_frame.next,

                       rx_frame.count);

            if (errs & ENRSR_FO)

                ei_local->stat.rx_fifo_errors++;

        }

        next_frame = rx_frame.next;


        /* This _should_ never happen: it's here for avoiding bad clones. */

        if (next_frame >= ei_local->stop_page) {

            printk("%s: next frame inconsistency, %#2x\n", dev->name,

                   next_frame);

            next_frame = ei_local->rx_start_page;

        }

        ei_local->current_page = next_frame;

        outb_p(next_frame-1, e8390_base+EN0_BOUNDARY);

    }

    /* If any worth-while packets have been received, dev_rint()

       has done a mark_bh(NET_BH) for us and will work on them

       when we get to the bottom-half routine. */


    /* Record the maximum Rx packet queue. */

    if (rx_pkt_count > high_water_mark)

        high_water_mark = rx_pkt_count;


    /* Bug alert!  Reset ENISR_OVER to avoid spurious overruns! */

    outb_p(ENISR_RX+ENISR_RX_ERR+ENISR_OVER, e8390_base+EN0_ISR);

    return;

}