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[/] [or1k_old/] [trunk/] [rc203soc/] [sw/] [uClinux/] [fs/] [nfs/] [nfsroot.c] - Rev 1782
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/* * linux/fs/nfs/nfsroot.c -- version 2.3 * * Copyright (C) 1995, 1996 Gero Kuhlmann <gero@gkminix.han.de> * * For parts of this file: * Copyright (C) 1996 Martin Mares <mj@k332.feld.cvut.cz> * * Allow an NFS filesystem to be mounted as root. The way this works is: * (1) Determine the local IP address via RARP or BOOTP or from the * kernel command line. * (2) Handle RPC negotiation with the system which replied to RARP or * was reported as a boot server by BOOTP or manually. * (3) The actual mounting is done later, when init() is running. * * * Changes: * * R. Drahtmueller : Set IFF_MULTICAST in dev->flags if applicable. * Alan Cox : Removed get_address name clash with FPU. * Alan Cox : Reformatted a bit. * Gero Kuhlmann : Code cleanup * Michael Rausch : Fixed recognition of an incoming RARP answer. * Martin Mares : (2.0) Auto-configuration via BOOTP supported. * Martin Mares : Manual selection of interface & BOOTP/RARP. * Martin Mares : Using network routes instead of host routes, * allowing the default configuration to be used * for normal operation of the host. * Martin Mares : Randomized timer with exponential backoff * installed to minimize network congestion. * Martin Mares : Code cleanup. * Martin Mares : (2.1) BOOTP and RARP made configuration options. * Martin Mares : Server hostname generation fixed. * Gerd Knorr : Fixed wired inode handling * Martin Mares : (2.2) "0.0.0.0" addresses from command line ignored. * Martin Mares : RARP replies not tested for server address. * Gero Kuhlmann : (2.3) Some bug fixes and code cleanup again (please * send me your new patches _before_ bothering * Linus so that I don' always have to cleanup * _afterwards_ - thanks) * Gero Kuhlmann : Last changes of Martin Mares undone. * Gero Kuhlmann : RARP replies are tested for specified server * again. However, it's now possible to have * different RARP and NFS servers. * Gero Kuhlmann : "0.0.0.0" addresses from command line are * now mapped to INADDR_NONE. * Gero Kuhlmann : Fixed a bug which prevented BOOTP path name * from being used (thanks to Leo Spiekman) * Andy Walker : Allow to specify the NFS server in nfs_root * without giving a path name * Swen Th=FCmmler : Allow to specify the NFS options in nfs_root * without giving a path name. Fix BOOTP request * for domainname (domainname is NIS domain, not * DNS domain!). Skip dummy devices for BOOTP. * Jacek Zapala : Fixed a bug which prevented server-ip address * from nfsroot parameter from being used. * */ /* Define this to allow debugging output */ #undef NFSROOT_DEBUG #undef NFSROOT_BOOTP_DEBUG #include <linux/config.h> #include <linux/types.h> #include <linux/string.h> #include <linux/kernel.h> #include <linux/sched.h> #include <linux/fs.h> #include <linux/random.h> #include <linux/fcntl.h> #include <asm/param.h> #include <linux/utsname.h> #include <linux/in.h> #include <linux/if.h> #include <linux/inet.h> #include <linux/net.h> #include <linux/netdevice.h> #include <linux/if_arp.h> #if defined(CONFIG_AX25) || defined(CONFIG_AX25_MODULE) #include <net/ax25.h> /* For AX25_P_IP */ #endif #include <linux/skbuff.h> #include <linux/socket.h> #include <linux/route.h> #include <linux/nfs.h> #include <linux/nfs_fs.h> #include <linux/nfs_mount.h> #include <linux/in.h> #include <net/route.h> #include <net/sock.h> #include <asm/segment.h> /* Range of privileged ports */ #define STARTPORT 600 #define ENDPORT 1023 #define NPORTS (ENDPORT - STARTPORT + 1) /* Define the timeout for waiting for a RARP/BOOTP reply */ #define CONF_BASE_TIMEOUT (HZ*5) /* Initial timeout: 5 seconds */ #define CONF_RETRIES 10 /* 10 retries */ #define CONF_TIMEOUT_RANDOM (HZ) /* Maximum amount of randomization */ #define CONF_TIMEOUT_MULT *5/4 /* Speed of timeout growth */ #define CONF_TIMEOUT_MAX (HZ*30) /* Maximum allowed timeout */ /* List of open devices */ struct open_dev { struct device *dev; unsigned short old_flags; struct open_dev *next; }; static struct open_dev *open_base = NULL; /* IP configuration */ static struct device *root_dev = NULL; /* Device selected for booting */ static char user_dev_name[IFNAMSIZ]; /* Name of user-selected boot device */ static struct sockaddr_in myaddr; /* My IP address */ static struct sockaddr_in server; /* Server IP address */ static struct sockaddr_in gateway; /* Gateway IP address */ static struct sockaddr_in netmask; /* Netmask for local subnet */ /* BOOTP/RARP variables */ static int bootp_flag; /* User said: Use BOOTP! */ static int rarp_flag; /* User said: Use RARP! */ static int bootp_dev_count = 0; /* Number of devices allowing BOOTP */ static int rarp_dev_count = 0; /* Number of devices allowing RARP */ static struct sockaddr_in rarp_serv; /* IP address of RARP server */ #if defined(CONFIG_RNFS_BOOTP) || defined(CONFIG_RNFS_RARP) #define CONFIG_RNFS_DYNAMIC /* Enable dynamic IP config */ static volatile int pkt_arrived; /* BOOTP/RARP packet detected */ #define ARRIVED_BOOTP 1 #define ARRIVED_RARP 2 #endif /* NFS-related data */ static struct nfs_mount_data nfs_data; /* NFS mount info */ static char nfs_path[NFS_MAXPATHLEN] = ""; /* Name of directory to mount */ static int nfs_port; /* Port to connect to for NFS */ /* Yes, we use sys_socket, but there's no include file for it */ extern asmlinkage int sys_socket(int family, int type, int protocol); /*************************************************************************** Device Handling Subroutines ***************************************************************************/ /* * Setup and initialize all network devices. If there is a user-preferred * interface, ignore all other interfaces. */ static int root_dev_open(void) { struct open_dev *openp, **last; struct device *dev; unsigned short old_flags; last = &open_base; for (dev = dev_base; dev != NULL; dev = dev->next) { if (dev->type < ARPHRD_SLIP && dev->family == AF_INET && !(dev->flags & (IFF_LOOPBACK | IFF_POINTOPOINT)) && (0 != strncmp(dev->name, "dummy", 5)) && (!user_dev_name[0] || !strcmp(dev->name, user_dev_name))) { /* First up the interface */ old_flags = dev->flags; #ifdef CONFIG_IP_MULTICAST dev->flags = IFF_UP | IFF_BROADCAST | IFF_RUNNING | IFF_MULTICAST; #else dev->flags = IFF_UP | IFF_BROADCAST | IFF_RUNNING; #endif if (!(old_flags & IFF_UP) && dev_open(dev)) { dev->flags = old_flags; continue; } openp = (struct open_dev *) kmalloc(sizeof(struct open_dev), GFP_ATOMIC); if (openp == NULL) continue; openp->dev = dev; openp->old_flags = old_flags; *last = openp; last = &openp->next; bootp_dev_count++; if (!(dev->flags & IFF_NOARP)) rarp_dev_count++; #ifdef NFSROOT_DEBUG printk(KERN_NOTICE "Root-NFS: Opened %s\n", dev->name); #endif } } *last = NULL; if (!bootp_dev_count && !rarp_dev_count) { printk(KERN_ERR "Root-NFS: Unable to open at least one network device\n"); return -1; } return 0; } /* * Restore the state of all devices. However, keep the root device open * for the upcoming mount. */ static void root_dev_close(void) { struct open_dev *openp; struct open_dev *nextp; openp = open_base; while (openp != NULL) { nextp = openp->next; openp->next = NULL; if (openp->dev != root_dev) { if (!(openp->old_flags & IFF_UP)) dev_close(openp->dev); openp->dev->flags = openp->old_flags; } kfree_s(openp, sizeof(struct open_dev)); openp = nextp; } } /*************************************************************************** RARP Subroutines ***************************************************************************/ #ifdef CONFIG_RNFS_RARP extern void arp_send(int type, int ptype, unsigned long target_ip, struct device *dev, unsigned long src_ip, unsigned char *dest_hw, unsigned char *src_hw, unsigned char *target_hw); static int root_rarp_recv(struct sk_buff *skb, struct device *dev, struct packet_type *pt); static struct packet_type rarp_packet_type = { 0, /* Should be: __constant_htons(ETH_P_RARP) * - but this _doesn't_ come out constant! */ NULL, /* Listen to all devices */ root_rarp_recv, NULL, NULL }; /* * Register the packet type for RARP */ static void root_rarp_open(void) { rarp_packet_type.type = htons(ETH_P_RARP); dev_add_pack(&rarp_packet_type); } /* * Deregister the RARP packet type */ static void root_rarp_close(void) { rarp_packet_type.type = htons(ETH_P_RARP); dev_remove_pack(&rarp_packet_type); } /* * Receive RARP packets. */ static int root_rarp_recv(struct sk_buff *skb, struct device *dev, struct packet_type *pt) { struct arphdr *rarp = (struct arphdr *)skb->h.raw; unsigned char *rarp_ptr = (unsigned char *) (rarp + 1); unsigned long sip, tip; unsigned char *sha, *tha; /* s for "source", t for "target" */ /* If this test doesn't pass, it's not IP, or we should ignore it anyway */ if (rarp->ar_hln != dev->addr_len || dev->type != ntohs(rarp->ar_hrd)) { kfree_skb(skb, FREE_READ); return 0; } /* If it's not a RARP reply, delete it. */ if (rarp->ar_op != htons(ARPOP_RREPLY)) { kfree_skb(skb, FREE_READ); return 0; } /* If it's not ethernet or AX25, delete it. */ if ((rarp->ar_pro != htons(ETH_P_IP) && dev->type != ARPHRD_AX25) || #if defined(CONFIG_AX25) || defined(CONFIG_AX25_MODULE) (rarp->ar_pro != htons(AX25_P_IP) && dev->type == ARPHRD_AX25) || #endif rarp->ar_pln != 4) { kfree_skb(skb, FREE_READ); return 0; } /* Extract variable width fields */ sha = rarp_ptr; rarp_ptr += dev->addr_len; memcpy(&sip, rarp_ptr, 4); rarp_ptr += 4; tha = rarp_ptr; rarp_ptr += dev->addr_len; memcpy(&tip, rarp_ptr, 4); /* Discard packets which are not meant for us. */ if (memcmp(tha, dev->dev_addr, dev->addr_len)) { kfree_skb(skb, FREE_READ); return 0; } /* Discard packets which are not from specified server. */ if (rarp_flag && !bootp_flag && rarp_serv.sin_addr.s_addr != INADDR_NONE && rarp_serv.sin_addr.s_addr != sip) { kfree_skb(skb, FREE_READ); return 0; } /* * The packet is what we were looking for. Setup the global * variables. */ cli(); if (pkt_arrived) { sti(); kfree_skb(skb, FREE_READ); return 0; } pkt_arrived = ARRIVED_RARP; sti(); root_dev = dev; if (myaddr.sin_addr.s_addr == INADDR_NONE) { myaddr.sin_family = dev->family; myaddr.sin_addr.s_addr = tip; } if (server.sin_addr.s_addr == INADDR_NONE) { server.sin_family = dev->family; server.sin_addr.s_addr = sip; } kfree_skb(skb, FREE_READ); return 0; } /* * Send RARP request packet over all devices which allow RARP. */ static void root_rarp_send(void) { struct open_dev *openp; struct device *dev; int num = 0; for (openp = open_base; openp != NULL; openp = openp->next) { dev = openp->dev; if (!(dev->flags & IFF_NOARP)) { arp_send(ARPOP_RREQUEST, ETH_P_RARP, 0, dev, 0, NULL, dev->dev_addr, dev->dev_addr); num++; } } } #endif /*************************************************************************** BOOTP Subroutines ***************************************************************************/ #ifdef CONFIG_RNFS_BOOTP static struct device *bootp_dev = NULL; /* Device selected as best BOOTP target */ static int bootp_xmit_fd = -1; /* Socket descriptor for transmit */ static struct socket *bootp_xmit_sock; /* The socket itself */ static int bootp_recv_fd = -1; /* Socket descriptor for receive */ static struct socket *bootp_recv_sock; /* The socket itself */ struct bootp_pkt { /* BOOTP packet format */ u8 op; /* 1=request, 2=reply */ u8 htype; /* HW address type */ u8 hlen; /* HW address length */ u8 hops; /* Used only by gateways */ u32 xid; /* Transaction ID */ u16 secs; /* Seconds since we started */ u16 flags; /* Just what is says */ u32 client_ip; /* Client's IP address if known */ u32 your_ip; /* Assigned IP address */ u32 server_ip; /* Server's IP address */ u32 relay_ip; /* IP address of BOOTP relay */ u8 hw_addr[16]; /* Client's HW address */ u8 serv_name[64]; /* Server host name */ u8 boot_file[128]; /* Name of boot file */ u8 vendor_area[128]; /* Area for extensions */ }; #define BOOTP_REQUEST 1 #define BOOTP_REPLY 2 static struct bootp_pkt *xmit_bootp; /* Packet being transmitted */ static struct bootp_pkt *recv_bootp; /* Packet being received */ static int bootp_have_route = 0; /* BOOTP route installed */ /* * Free BOOTP packet buffers */ static void root_free_bootp(void) { if (xmit_bootp) { kfree_s(xmit_bootp, sizeof(struct bootp_pkt)); xmit_bootp = NULL; } if (recv_bootp) { kfree_s(recv_bootp, sizeof(struct bootp_pkt)); recv_bootp = NULL; } } /* * Allocate memory for BOOTP packet buffers */ static inline int root_alloc_bootp(void) { if (!(xmit_bootp = kmalloc(sizeof(struct bootp_pkt), GFP_KERNEL)) || !(recv_bootp = kmalloc(sizeof(struct bootp_pkt), GFP_KERNEL))) { printk("BOOTP: Out of memory!"); return -1; } return 0; } /* * Create default route for BOOTP sending */ static int root_add_bootp_route(void) { struct rtentry route; memset(&route, 0, sizeof(route)); route.rt_dev = bootp_dev->name; route.rt_mss = bootp_dev->mtu; route.rt_flags = RTF_UP; ((struct sockaddr_in *) &(route.rt_dst)) -> sin_addr.s_addr = 0; ((struct sockaddr_in *) &(route.rt_dst)) -> sin_family = AF_INET; ((struct sockaddr_in *) &(route.rt_genmask)) -> sin_addr.s_addr = 0; ((struct sockaddr_in *) &(route.rt_genmask)) -> sin_family = AF_INET; if (ip_rt_new(&route)) { printk(KERN_ERR "BOOTP: Adding of route failed!\n"); return -1; } bootp_have_route = 1; return 0; } /* * Delete default route for BOOTP sending */ static int root_del_bootp_route(void) { struct rtentry route; if (!bootp_have_route) return 0; memset(&route, 0, sizeof(route)); ((struct sockaddr_in *) &(route.rt_dst)) -> sin_addr.s_addr = 0; ((struct sockaddr_in *) &(route.rt_genmask)) -> sin_addr.s_addr = 0; if (ip_rt_kill(&route)) { printk(KERN_ERR "BOOTP: Deleting of route failed!\n"); return -1; } bootp_have_route = 0; return 0; } /* * Open UDP socket. */ static int root_open_udp_sock(int *fd, struct socket **sock) { struct file *file; struct inode *inode; *fd = sys_socket(AF_INET, SOCK_DGRAM, IPPROTO_UDP); if (*fd >= 0) { file = current->files->fd[*fd]; inode = file->f_inode; *sock = &inode->u.socket_i; return 0; } printk(KERN_ERR "BOOTP: Cannot open UDP socket!\n"); return -1; } /* * Connect UDP socket. */ static int root_connect_udp_sock(struct socket *sock, u32 addr, u16 port) { struct sockaddr_in sa; int result; sa.sin_family = AF_INET; sa.sin_addr.s_addr = htonl(addr); sa.sin_port = htons(port); result = sock->ops->connect(sock, (struct sockaddr *) &sa, sizeof(sa), 0); if (result < 0) { printk(KERN_ERR "BOOTP: connect() failed\n"); return -1; } return 0; } /* * Bind UDP socket. */ static int root_bind_udp_sock(struct socket *sock, u32 addr, u16 port) { struct sockaddr_in sa; int result; sa.sin_family = AF_INET; sa.sin_addr.s_addr = htonl(addr); sa.sin_port = htons(port); result = sock->ops->bind(sock, (struct sockaddr *) &sa, sizeof(sa)); if (result < 0) { printk(KERN_ERR "BOOTP: bind() failed\n"); return -1; } return 0; } /* * Send UDP packet. */ static inline int root_send_udp(struct socket *sock, void *buf, int size) { u32 oldfs; int result; struct msghdr msg; struct iovec iov; oldfs = get_fs(); set_fs(get_ds()); iov.iov_base = buf; iov.iov_len = size; msg.msg_name = NULL; msg.msg_iov = &iov; msg.msg_iovlen = 1; msg.msg_control = NULL; result = sock->ops->sendmsg(sock, &msg, size, 0, 0); set_fs(oldfs); return (result != size); } /* * Try to receive UDP packet. */ static inline int root_recv_udp(struct socket *sock, void *buf, int size) { u32 oldfs; int result; struct msghdr msg; struct iovec iov; oldfs = get_fs(); set_fs(get_ds()); iov.iov_base = buf; iov.iov_len = size; msg.msg_name = NULL; msg.msg_iov = &iov; msg.msg_iovlen = 1; msg.msg_control = NULL; msg.msg_namelen = 0; result = sock->ops->recvmsg(sock, &msg, size, O_NONBLOCK, 0, &msg.msg_namelen); set_fs(oldfs); return result; } /* * Initialize BOOTP extension fields in the request. */ static void root_bootp_init_ext(u8 *e) { *e++ = 99; /* RFC1048 Magic Cookie */ *e++ = 130; *e++ = 83; *e++ = 99; *e++ = 1; /* Subnet mask request */ *e++ = 4; e += 4; *e++ = 3; /* Default gateway request */ *e++ = 4; e += 4; *e++ = 12; /* Host name request */ *e++ = 32; e += 32; *e++ = 40; /* NIS Domain name request */ *e++ = 32; e += 32; *e++ = 17; /* Boot path */ *e++ = 32; e += 32; *e = 255; /* End of the list */ } /* * Deinitialize the BOOTP mechanism. */ static void root_bootp_close(void) { if (bootp_xmit_fd != -1) sys_close(bootp_xmit_fd); if (bootp_recv_fd != -1) sys_close(bootp_recv_fd); root_del_bootp_route(); root_free_bootp(); } /* * Initialize the BOOTP mechanism. */ static int root_bootp_open(void) { struct open_dev *openp; struct device *dev, *best_dev; /* * Select the best interface for BOOTP. We try to select a first * Ethernet-like interface. It's shame I know no simple way how to send * BOOTP's to all interfaces, but it doesn't apply to usual diskless * stations as they don't have multiple interfaces. */ best_dev = NULL; for (openp = open_base; openp != NULL; openp = openp->next) { dev = openp->dev; if (dev->flags & IFF_BROADCAST) { if (!best_dev || ((best_dev->flags & IFF_NOARP) && !(dev->flags & IFF_NOARP))) best_dev = dev; } } if (!best_dev) { printk(KERN_ERR "BOOTP: This cannot happen!\n"); return -1; } bootp_dev = best_dev; /* Allocate memory for BOOTP packets */ if (root_alloc_bootp()) return -1; /* Construct BOOTP request */ memset(xmit_bootp, 0, sizeof(struct bootp_pkt)); xmit_bootp->op = BOOTP_REQUEST; get_random_bytes(&xmit_bootp->xid, sizeof(xmit_bootp->xid)); xmit_bootp->htype = best_dev->type; xmit_bootp->hlen = best_dev->addr_len; memcpy(xmit_bootp->hw_addr, best_dev->dev_addr, best_dev->addr_len); root_bootp_init_ext(xmit_bootp->vendor_area); #ifdef NFSROOT_BOOTP_DEBUG { int x; printk(KERN_NOTICE "BOOTP: XID=%08x, DE=%s, HT=%02x, HL=%02x, HA=", xmit_bootp->xid, best_dev->name, xmit_bootp->htype, xmit_bootp->hlen); for(x=0; x<xmit_bootp->hlen; x++) printk("%02x", xmit_bootp->hw_addr[x]); printk("\n"); } #endif /* Create default route to that interface */ if (root_add_bootp_route()) return -1; /* Open the sockets */ if (root_open_udp_sock(&bootp_xmit_fd, &bootp_xmit_sock) || root_open_udp_sock(&bootp_recv_fd, &bootp_recv_sock)) return -1; /* Bind/connect the sockets */ ((struct sock *) bootp_xmit_sock->data) -> broadcast = 1; ((struct sock *) bootp_xmit_sock->data) -> reuse = 1; ((struct sock *) bootp_recv_sock->data) -> reuse = 1; if (root_bind_udp_sock(bootp_recv_sock, INADDR_ANY, 68) || root_bind_udp_sock(bootp_xmit_sock, INADDR_ANY, 68) || root_connect_udp_sock(bootp_xmit_sock, INADDR_BROADCAST, 67)) return -1; return 0; } /* * Send BOOTP request. */ static int root_bootp_send(u32 jiffies) { xmit_bootp->secs = htons(jiffies / HZ); return root_send_udp(bootp_xmit_sock, xmit_bootp, sizeof(struct bootp_pkt)); } /* * Copy BOOTP-supplied string if not already set. */ static int root_bootp_string(char *dest, char *src, int len, int max) { if (*dest || !len) return 0; if (len > max-1) len = max-1; strncpy(dest, src, len); dest[len] = '\0'; return 1; } /* * Process BOOTP extension. */ static void root_do_bootp_ext(u8 *ext) { #ifdef NFSROOT_BOOTP_DEBUG u8 *c; printk("BOOTP: Got extension %02x",*ext); for(c=ext+2; c<ext+2+ext[1]; c++) printk(" %02x", *c); printk("\n"); #endif switch (*ext++) { case 1: /* Subnet mask */ if (netmask.sin_addr.s_addr == INADDR_NONE) memcpy(&netmask.sin_addr.s_addr, ext+1, 4); break; case 3: /* Default gateway */ if (gateway.sin_addr.s_addr == INADDR_NONE) memcpy(&gateway.sin_addr.s_addr, ext+1, 4); break; case 12: /* Host name */ root_bootp_string(system_utsname.nodename, ext+1, *ext, __NEW_UTS_LEN); break; case 40: /* NIS Domain name */ root_bootp_string(system_utsname.domainname, ext+1, *ext, __NEW_UTS_LEN); break; case 17: /* Root path */ root_bootp_string(nfs_path, ext+1, *ext, NFS_MAXPATHLEN); break; } } /* * Receive BOOTP request. */ static void root_bootp_recv(void) { int len; u8 *ext, *end, *opt; len = root_recv_udp(bootp_recv_sock, recv_bootp, sizeof(struct bootp_pkt)); if (len < 0) return; /* Check consistency of incoming packet */ if (len < 300 || /* See RFC 1542:2.1 */ recv_bootp->op != BOOTP_REPLY || recv_bootp->htype != xmit_bootp->htype || recv_bootp->hlen != xmit_bootp->hlen || recv_bootp->xid != xmit_bootp->xid) { #ifdef NFSROOT_BOOTP_DEBUG printk("?"); #endif return; } /* Record BOOTP packet arrival in the global variables */ cli(); if (pkt_arrived) { sti(); return; } pkt_arrived = ARRIVED_BOOTP; sti(); root_dev = bootp_dev; /* Extract basic fields */ myaddr.sin_addr.s_addr = recv_bootp->your_ip; if (server.sin_addr.s_addr==INADDR_NONE) server.sin_addr.s_addr = recv_bootp->server_ip; /* Parse extensions */ if (recv_bootp->vendor_area[0] == 99 && /* Check magic cookie */ recv_bootp->vendor_area[1] == 130 && recv_bootp->vendor_area[2] == 83 && recv_bootp->vendor_area[3] == 99) { ext = &recv_bootp->vendor_area[4]; end = (u8 *) recv_bootp + len; while (ext < end && *ext != 255) { if (*ext == 0) /* Padding */ ext++; else { opt = ext; ext += ext[1] + 2; if (ext <= end) root_do_bootp_ext(opt); } } } } #endif /*************************************************************************** Dynamic configuration of IP. ***************************************************************************/ #ifdef CONFIG_RNFS_DYNAMIC /* * Determine client and server IP numbers and appropriate device by using * the RARP and BOOTP protocols. */ static int root_auto_config(void) { int retries; unsigned long timeout, jiff; unsigned long start_jiffies; /* * If neither BOOTP nor RARP was selected, return with an error. This * routine gets only called when some pieces of information are mis- * sing, and without BOOTP and RARP we are not able to get that in- * formation. */ if (!bootp_flag && !rarp_flag) { printk(KERN_ERR "Root-NFS: Neither RARP nor BOOTP selected.\n"); return -1; } #ifdef CONFIG_RNFS_BOOTP if (bootp_flag && !bootp_dev_count) { printk(KERN_ERR "Root-NFS: No suitable device for BOOTP found.\n"); bootp_flag = 0; } #else bootp_flag = 0; #endif #ifdef CONFIG_RNFS_RARP if (rarp_flag && !rarp_dev_count) { printk(KERN_ERR "Root-NFS: No suitable device for RARP found.\n"); rarp_flag = 0; } #else rarp_flag = 0; #endif if (!bootp_flag && !rarp_flag) /* Error message already printed */ return -1; /* * Setup RARP and BOOTP protocols */ #ifdef CONFIG_RNFS_RARP if (rarp_flag) root_rarp_open(); #endif #ifdef CONFIG_RNFS_BOOTP if (bootp_flag && root_bootp_open() < 0) { root_bootp_close(); return -1; } #endif /* * Send requests and wait, until we get an answer. This loop * seems to be a terrible waste of CPU time, but actually there is * only one process running at all, so we don't need to use any * scheduler functions. * [Actually we could now, but the nothing else running note still * applies.. - AC] */ printk(KERN_NOTICE "Sending %s%s%s requests...", bootp_flag ? "BOOTP" : "", bootp_flag && rarp_flag ? " and " : "", rarp_flag ? "RARP" : ""); start_jiffies = jiffies; retries = CONF_RETRIES; get_random_bytes(&timeout, sizeof(timeout)); timeout = CONF_BASE_TIMEOUT + (timeout % (unsigned) CONF_TIMEOUT_RANDOM); for(;;) { #ifdef CONFIG_RNFS_BOOTP if (bootp_flag && root_bootp_send(jiffies - start_jiffies) < 0) { printk(" BOOTP failed!\n"); root_bootp_close(); bootp_flag = 0; if (!rarp_flag) break; } #endif #ifdef CONFIG_RNFS_RARP if (rarp_flag) root_rarp_send(); #endif printk("."); jiff = jiffies + timeout; while (jiffies < jiff && !pkt_arrived) #ifdef CONFIG_RNFS_BOOTP root_bootp_recv(); #else ; #endif if (pkt_arrived) break; if (! --retries) { printk(" timed out!\n"); break; } timeout = timeout CONF_TIMEOUT_MULT; if (timeout > CONF_TIMEOUT_MAX) timeout = CONF_TIMEOUT_MAX; } #ifdef CONFIG_RNFS_RARP if (rarp_flag) root_rarp_close(); #endif #ifdef CONFIG_RNFS_BOOTP if (bootp_flag) root_bootp_close(); #endif if (!pkt_arrived) return -1; printk(" OK\n"); printk(KERN_NOTICE "Root-NFS: Got %s answer from %s, ", (pkt_arrived == ARRIVED_BOOTP) ? "BOOTP" : "RARP", in_ntoa(server.sin_addr.s_addr)); printk("my address is %s\n", in_ntoa(myaddr.sin_addr.s_addr)); return 0; } #endif /*************************************************************************** Parsing of options ***************************************************************************/ /* * The following integer options are recognized */ static struct nfs_int_opts { char *name; int *val; } root_int_opts[] = { { "port", &nfs_port }, { "rsize", &nfs_data.rsize }, { "wsize", &nfs_data.wsize }, { "timeo", &nfs_data.timeo }, { "retrans", &nfs_data.retrans }, { "acregmin", &nfs_data.acregmin }, { "acregmax", &nfs_data.acregmax }, { "acdirmin", &nfs_data.acdirmin }, { "acdirmax", &nfs_data.acdirmax }, { NULL, NULL } }; /* * And now the flag options */ static struct nfs_bool_opts { char *name; int and_mask; int or_mask; } root_bool_opts[] = { { "soft", ~NFS_MOUNT_SOFT, NFS_MOUNT_SOFT }, { "hard", ~NFS_MOUNT_SOFT, 0 }, { "intr", ~NFS_MOUNT_INTR, NFS_MOUNT_INTR }, { "nointr", ~NFS_MOUNT_INTR, 0 }, { "posix", ~NFS_MOUNT_POSIX, NFS_MOUNT_POSIX }, { "noposix", ~NFS_MOUNT_POSIX, 0 }, { "cto", ~NFS_MOUNT_NOCTO, 0 }, { "nocto", ~NFS_MOUNT_NOCTO, NFS_MOUNT_NOCTO }, { "ac", ~NFS_MOUNT_NOAC, 0 }, { "noac", ~NFS_MOUNT_NOAC, NFS_MOUNT_NOAC }, { NULL, 0, 0 } }; /* * Prepare the NFS data structure and parse any options. This tries to * set as many values in the nfs_data structure as known right now. */ static int root_nfs_name(char *name) { char buf[NFS_MAXPATHLEN]; char *cp, *cq, *options, *val; int octets = 0; /* It is possible to override the server IP number here */ cp = cq = name; while (octets < 4) { while (*cp >= '0' && *cp <= '9') cp++; if (cp == cq || cp - cq > 3) break; if (*cp == '.' || octets == 3) octets++; if (octets < 4) cp++; cq = cp; } if (octets == 4 && (*cp == ':' || *cp == '\0')) { if (*cp == ':') *cp++ = '\0'; server.sin_addr.s_addr = in_aton(name); name = cp; } /* Clear the nfs_data structure and setup the server hostname */ memset(&nfs_data, 0, sizeof(nfs_data)); strncpy(nfs_data.hostname, in_ntoa(server.sin_addr.s_addr), sizeof(nfs_data.hostname)-1); /* Set the name of the directory to mount */ if (nfs_path[0] == '\0' || strncmp(name, "default", 7)) strncpy(buf, name, NFS_MAXPATHLEN); else strncpy(buf, nfs_path, NFS_MAXPATHLEN); if ((options = strchr(buf, ','))) *options++ = '\0'; if (!strcmp(buf, "default")) strcpy(buf, NFS_ROOT); cp = in_ntoa(myaddr.sin_addr.s_addr); if (strlen(buf) + strlen(cp) > NFS_MAXPATHLEN) { printk(KERN_ERR "Root-NFS: Pathname for remote directory too long.\n"); return -1; } /* update nfs_path with path from nfsroot=... command line parameter */ if (*buf) sprintf(nfs_path, buf, cp); /* Set some default values */ nfs_port = -1; nfs_data.version = NFS_MOUNT_VERSION; nfs_data.flags = 0; nfs_data.rsize = NFS_DEF_FILE_IO_BUFFER_SIZE; nfs_data.wsize = NFS_DEF_FILE_IO_BUFFER_SIZE; nfs_data.timeo = 7; nfs_data.retrans = 3; nfs_data.acregmin = 3; nfs_data.acregmax = 60; nfs_data.acdirmin = 30; nfs_data.acdirmax = 60; /* Process any options */ if (options) { cp = strtok(options, ","); while (cp) { if ((val = strchr(cp, '='))) { struct nfs_int_opts *opts = root_int_opts; *val++ = '\0'; while (opts->name && strcmp(opts->name, cp)) opts++; if (opts->name) *(opts->val) = (int) simple_strtoul(val, NULL, 10); } else { struct nfs_bool_opts *opts = root_bool_opts; while (opts->name && strcmp(opts->name, cp)) opts++; if (opts->name) { nfs_data.flags &= opts->and_mask; nfs_data.flags |= opts->or_mask; } } cp = strtok(NULL, ","); } } return 0; } /* * Tell the user what's going on. */ #ifdef NFSROOT_DEBUG static void root_nfs_print(void) { #define IN_NTOA(x) (((x) == INADDR_NONE) ? "none" : in_ntoa(x)) printk(KERN_NOTICE "Root-NFS: IP config: dev=%s, ", root_dev ? root_dev->name : "none"); printk("local=%s, ", IN_NTOA(myaddr.sin_addr.s_addr)); printk("server=%s, ", IN_NTOA(server.sin_addr.s_addr)); printk("gw=%s, ", IN_NTOA(gateway.sin_addr.s_addr)); printk("mask=%s, ", IN_NTOA(netmask.sin_addr.s_addr)); printk("host=%s, domain=%s\n", system_utsname.nodename[0] ? system_utsname.nodename : "none", system_utsname.domainname[0] ? system_utsname.domainname : "none"); printk(KERN_NOTICE "Root-NFS: Mounting %s on server %s as root\n", nfs_path, nfs_data.hostname); printk(KERN_NOTICE "Root-NFS: rsize = %d, wsize = %d, timeo = %d, retrans = %d\n", nfs_data.rsize, nfs_data.wsize, nfs_data.timeo, nfs_data.retrans); printk(KERN_NOTICE "Root-NFS: acreg (min,max) = (%d,%d), acdir (min,max) = (%d,%d)\n", nfs_data.acregmin, nfs_data.acregmax, nfs_data.acdirmin, nfs_data.acdirmax); printk(KERN_NOTICE "Root-NFS: port = %d, flags = %08x\n", nfs_port, nfs_data.flags); #undef IN_NTOA } #endif /* * Decode any IP configuration options in the "nfsaddrs" kernel command * line parameter. It consists of option fields separated by colons in * the following order: * * <client-ip>:<server-ip>:<gw-ip>:<netmask>:<host name>:<device>:<bootp|rarp> * * Any of the fields can be empty which means to use a default value: * <client-ip> - address given by BOOTP or RARP * <server-ip> - address of host returning BOOTP or RARP packet * <gw-ip> - none, or the address returned by BOOTP * <netmask> - automatically determined from <client-ip>, or the * one returned by BOOTP * <host name> - <client-ip> in ASCII notation, or the name returned * by BOOTP * <device> - use all available devices for RARP and the first * one for BOOTP * <bootp|rarp> - use both protocols to determine my own address */ static void root_nfs_addrs(char *addrs) { char *cp, *ip, *dp; int num = 0; /* Clear all addresses and strings */ myaddr.sin_family = server.sin_family = rarp_serv.sin_family = gateway.sin_family = netmask.sin_family = AF_INET; myaddr.sin_addr.s_addr = server.sin_addr.s_addr = rarp_serv.sin_addr.s_addr = gateway.sin_addr.s_addr = netmask.sin_addr.s_addr = INADDR_NONE; system_utsname.nodename[0] = '\0'; system_utsname.domainname[0] = '\0'; user_dev_name[0] = '\0'; bootp_flag = rarp_flag = 1; /* The following is just a shortcut for automatic IP configuration */ if (!strcmp(addrs, "bootp")) { rarp_flag = 0; return; } else if (!strcmp(addrs, "rarp")) { bootp_flag = 0; return; } else if (!strcmp(addrs, "both")) { return; } /* Parse the whole string */ ip = addrs; while (ip && *ip) { if ((cp = strchr(ip, ':'))) *cp++ = '\0'; if (strlen(ip) > 0) { #ifdef NFSROOT_DEBUG printk(KERN_NOTICE "Root-NFS: Config string num %d is \"%s\"\n", num, ip); #endif switch (num) { case 0: if ((myaddr.sin_addr.s_addr = in_aton(ip)) == INADDR_ANY) myaddr.sin_addr.s_addr = INADDR_NONE; break; case 1: if ((server.sin_addr.s_addr = in_aton(ip)) == INADDR_ANY) server.sin_addr.s_addr = INADDR_NONE; break; case 2: if ((gateway.sin_addr.s_addr = in_aton(ip)) == INADDR_ANY) gateway.sin_addr.s_addr = INADDR_NONE; break; case 3: if ((netmask.sin_addr.s_addr = in_aton(ip)) == INADDR_ANY) netmask.sin_addr.s_addr = INADDR_NONE; break; case 4: if ((dp = strchr(ip, '.'))) { *dp++ = '\0'; strncpy(system_utsname.domainname, dp, __NEW_UTS_LEN); system_utsname.domainname[__NEW_UTS_LEN] = '\0'; } strncpy(system_utsname.nodename, ip, __NEW_UTS_LEN); system_utsname.nodename[__NEW_UTS_LEN] = '\0'; break; case 5: strncpy(user_dev_name, ip, IFNAMSIZ); user_dev_name[IFNAMSIZ-1] = '\0'; break; case 6: if (!strcmp(ip, "rarp")) bootp_flag = 0; else if (!strcmp(ip, "bootp")) rarp_flag = 0; else if (strcmp(ip, "both")) bootp_flag = rarp_flag = 0; break; default: break; } } ip = cp; num++; } rarp_serv = server; } /* * Set the interface address and configure a route to the server. */ static int root_nfs_setup(void) { struct rtentry route; /* Set the default system name in case none was previously found */ if (!system_utsname.nodename[0]) { strncpy(system_utsname.nodename, in_ntoa(myaddr.sin_addr.s_addr), __NEW_UTS_LEN); system_utsname.nodename[__NEW_UTS_LEN] = '\0'; } /* Set the correct netmask */ if (netmask.sin_addr.s_addr == INADDR_NONE) netmask.sin_addr.s_addr = ip_get_mask(myaddr.sin_addr.s_addr); /* Setup the device correctly */ root_dev->family = myaddr.sin_family; root_dev->pa_addr = myaddr.sin_addr.s_addr; root_dev->pa_mask = netmask.sin_addr.s_addr; root_dev->pa_brdaddr = root_dev->pa_addr | ~root_dev->pa_mask; root_dev->pa_dstaddr = 0; /* * Now add a route to the server. If there is no gateway given, * the server is on the same subnet, so we establish only a route to * the local network. Otherwise we create a route to the gateway (the * same local network router as in the former case) and then setup a * gatewayed default route. Note that this gives sufficient network * setup even for full system operation in all common cases. */ memset(&route, 0, sizeof(route)); /* Local subnet route */ route.rt_dev = root_dev->name; route.rt_mss = root_dev->mtu; route.rt_flags = RTF_UP; *((struct sockaddr_in *) &(route.rt_dst)) = myaddr; (((struct sockaddr_in *) &(route.rt_dst)))->sin_addr.s_addr &= netmask.sin_addr.s_addr; *((struct sockaddr_in *) &(route.rt_genmask)) = netmask; if (ip_rt_new(&route)) { printk(KERN_ERR "Root-NFS: Adding of local route failed!\n"); return -1; } if (gateway.sin_addr.s_addr != INADDR_NONE) { /* Default route */ (((struct sockaddr_in *) &(route.rt_dst)))->sin_addr.s_addr = INADDR_ANY; (((struct sockaddr_in *) &(route.rt_genmask)))->sin_addr.s_addr = INADDR_ANY; *((struct sockaddr_in *) &(route.rt_gateway)) = gateway; route.rt_flags |= RTF_GATEWAY; if ((gateway.sin_addr.s_addr ^ myaddr.sin_addr.s_addr) & netmask.sin_addr.s_addr) { printk(KERN_ERR "Root-NFS: Gateway not on local network!\n"); return -1; } if (ip_rt_new(&route)) { printk(KERN_ERR "Root-NFS: Adding of default route failed!\n"); return -1; } } else if ((server.sin_addr.s_addr ^ myaddr.sin_addr.s_addr) & netmask.sin_addr.s_addr) { printk(KERN_ERR "Root-NFS: Boot server not on local network and no default gateway configured!\n"); return -1; } return 0; } /* * Get the necessary IP addresses and prepare for mounting the required * NFS filesystem. */ int nfs_root_init(char *nfsname, char *nfsaddrs) { /* * Decode IP addresses and other configuration info contained * in the nfsaddrs string (which came from the kernel command * line). */ root_nfs_addrs(nfsaddrs); /* * Setup all network devices */ if (root_dev_open() < 0) return -1; /* * If the config information is insufficient (e.g., our IP address or * IP address of the boot server is missing or we have multiple network * interfaces and no default was set), use BOOTP or RARP to get the * missing values. * * Note that we don't try to set up correct routes for multiple * interfaces (could be solved by trying icmp echo requests), because * it's only necessary in the rare case of multiple ethernet devices * in the (diskless) system and if the server is on another subnet. * If only one interface is installed, the routing is obvious. */ if ((myaddr.sin_addr.s_addr == INADDR_NONE || server.sin_addr.s_addr == INADDR_NONE || (open_base != NULL && open_base->next != NULL)) #ifdef CONFIG_RNFS_DYNAMIC && root_auto_config() < 0 #endif ) { root_dev_close(); return -1; } if (root_dev == NULL) { if (open_base != NULL && open_base->next == NULL) { root_dev = open_base->dev; } else { printk(KERN_ERR "Root-NFS: Multiple devices and no server\n"); root_dev_close(); return -1; } } /* * Close all network devices except the device which connects to * server */ root_dev_close(); /* * Decode the root directory path name and NFS options from * the kernel command line. This has to go here in order to * be able to use the client IP address for the remote root * directory (necessary for pure RARP booting). */ if (root_nfs_name(nfsname) < 0) return -1; /* * Setup devices and routes. The server directory is actually * mounted after init() has been started. */ if (root_nfs_setup() < 0) return -1; #ifdef NFSROOT_DEBUG root_nfs_print(); #endif return 0; } /*************************************************************************** Routines to actually mount the root directory ***************************************************************************/ static struct file *nfs_file; /* File descriptor pointing to inode */ static struct inode *nfs_sock_inode; /* Inode containing socket */ static int *rpc_packet = NULL; /* RPC packet */ /* * Open a UDP socket. */ static int root_nfs_open(void) { /* Open the socket */ if ((nfs_data.fd = sys_socket(AF_INET, SOCK_DGRAM, IPPROTO_UDP)) < 0) { printk(KERN_ERR "Root-NFS: Cannot open UDP socket for NFS!\n"); return -1; } nfs_file = current->files->fd[nfs_data.fd]; nfs_sock_inode = nfs_file->f_inode; return 0; } /* * Close the UDP file descriptor. If nfs_read_super is successful, it * increases the reference count, so we can simply close the file, and * the socket keeps open. */ static void root_nfs_close(void) { /* * The following close doesn't touch the server structure, which * now contains a file pointer pointing into nowhere. The system * _should_ crash as soon as someone tries to select on the root * filesystem. Haven't tried it yet - we can still change it back * to the old way of keeping a static copy of all important data * structures, including their pointers. At least this should be * checked out _carefully_ before going into a public release * kernel. - GK */ sys_close(nfs_data.fd); } /* * Find a suitable listening port and bind to it */ static int root_nfs_bind(void) { int res = -1; short port = STARTPORT; struct sockaddr_in *sin = &myaddr; int i; if (nfs_sock_inode->u.socket_i.ops->bind) { for (i = 0; i < NPORTS && res < 0; i++) { sin->sin_port = htons(port++); if (port > ENDPORT) { port = STARTPORT; } res = nfs_sock_inode->u.socket_i.ops->bind(&nfs_sock_inode->u.socket_i, (struct sockaddr *)sin, sizeof(struct sockaddr_in)); } } if (res < 0) { printk(KERN_ERR "Root-NFS: Cannot find a suitable listening port\n"); root_nfs_close(); return -1; } #ifdef NFSROOT_DEBUG printk(KERN_NOTICE "Root-NFS: Binding to listening port %d\n", port); #endif return 0; } /* * Send an RPC request and wait for the answer */ static int *root_nfs_call(int *end) { struct socket *sock; int dummylen; static struct nfs_server s = { 0, /* struct file * */ 0, /* struct rsock * */ { 0, "", }, /* toaddr */ 0, /* lock */ NULL, /* wait queue */ NFS_MOUNT_SOFT, /* flags */ 0, 0, /* rsize, wsize */ 0, /* timeo */ 0, /* retrans */ 3 * HZ, 60 * HZ, 30 * HZ, 60 * HZ, "\0" }; s.file = nfs_file; sock = &((nfs_file->f_inode)->u.socket_i); /* Extract the other end of the socket into s->toaddr */ sock->ops->getname(sock, &(s.toaddr), &dummylen, 1); ((struct sockaddr_in *) &s.toaddr)->sin_port = server.sin_port; ((struct sockaddr_in *) &s.toaddr)->sin_family = server.sin_family; ((struct sockaddr_in *) &s.toaddr)->sin_addr.s_addr = server.sin_addr.s_addr; s.rsock = rpc_makesock(nfs_file); s.flags = nfs_data.flags; s.rsize = nfs_data.rsize; s.wsize = nfs_data.wsize; s.timeo = nfs_data.timeo * HZ / 10; s.retrans = nfs_data.retrans; strcpy(s.hostname, nfs_data.hostname); /* * First connect the UDP socket to a server port, then send the * packet out, and finally check whether the answer is OK. */ if (nfs_sock_inode->u.socket_i.ops->connect && nfs_sock_inode->u.socket_i.ops->connect(&nfs_sock_inode->u.socket_i, (struct sockaddr *) &server, sizeof(struct sockaddr_in), nfs_file->f_flags) < 0) return NULL; if (nfs_rpc_call(&s, rpc_packet, end, nfs_data.wsize) < 0) return NULL; return rpc_verify(rpc_packet); } /* * Create an RPC packet header */ static int *root_nfs_header(int proc, int program, int version) { int groups[] = { 0, NOGROUP }; if (rpc_packet == NULL) { if (!(rpc_packet = kmalloc(nfs_data.wsize + 1024, GFP_NFS))) { printk(KERN_ERR "Root-NFS: Cannot allocate UDP buffer\n"); return NULL; } } return rpc_header(rpc_packet, proc, program, version, 0, 0, groups); } /* * Query server portmapper for the port of a daemon program */ static int root_nfs_get_port(int program, int version) { int *p; /* Prepare header for portmap request */ server.sin_port = htons(NFS_PMAP_PORT); p = root_nfs_header(NFS_PMAP_PROC, NFS_PMAP_PROGRAM, NFS_PMAP_VERSION); if (!p) return -1; /* Set arguments for portmapper */ *p++ = htonl(program); *p++ = htonl(version); *p++ = htonl(IPPROTO_UDP); *p++ = 0; /* Send request to server portmapper */ if ((p = root_nfs_call(p)) == NULL) return -1; return ntohl(*p); } /* * Get portnumbers for mountd and nfsd from server */ static int root_nfs_ports(void) { int port; if (nfs_port < 0) { if ((port = root_nfs_get_port(NFS_NFS_PROGRAM, NFS_NFS_VERSION)) < 0) { printk(KERN_ERR "Root-NFS: Unable to get nfsd port number from server, using default\n"); port = NFS_NFS_PORT; } nfs_port = port; #ifdef NFSROOT_DEBUG printk(KERN_NOTICE "Root-NFS: Portmapper on server returned %d as nfsd port\n", port); #endif } if ((port = root_nfs_get_port(NFS_MOUNT_PROGRAM, NFS_MOUNT_VERSION)) < 0) { printk(KERN_ERR "Root-NFS: Unable to get mountd port number from server, using default\n"); port = NFS_MOUNT_PORT; } server.sin_port = htons(port); #ifdef NFSROOT_DEBUG printk(KERN_NOTICE "Root-NFS: Portmapper on server returned %d as mountd port\n", port); #endif return 0; } /* * Get a file handle from the server for the directory which is to be * mounted */ static int root_nfs_get_handle(void) { int len, status, *p; /* Prepare header for mountd request */ p = root_nfs_header(NFS_MOUNT_PROC, NFS_MOUNT_PROGRAM, NFS_MOUNT_VERSION); if (!p) { root_nfs_close(); return -1; } /* Set arguments for mountd */ len = strlen(nfs_path); *p++ = htonl(len); memcpy(p, nfs_path, len); len = (len + 3) >> 2; p[len] = 0; p += len; /* Send request to server mountd */ if ((p = root_nfs_call(p)) == NULL) { root_nfs_close(); return -1; } status = ntohl(*p++); if (status == 0) { nfs_data.root = *((struct nfs_fh *) p); printk(KERN_NOTICE "Root-NFS: Got file handle for %s via RPC\n", nfs_path); } else { printk(KERN_ERR "Root-NFS: Server returned error %d while mounting %s\n", status, nfs_path); root_nfs_close(); return -1; } return 0; } /* * Now actually mount the given directory */ static int root_nfs_do_mount(struct super_block *sb) { /* First connect to the nfsd port on the server */ server.sin_port = htons(nfs_port); nfs_data.addr = server; if (nfs_sock_inode->u.socket_i.ops->connect && nfs_sock_inode->u.socket_i.ops->connect(&nfs_sock_inode->u.socket_i, (struct sockaddr *) &server, sizeof(struct sockaddr_in), nfs_file->f_flags) < 0) { root_nfs_close(); return -1; } /* Now (finally ;-)) read the super block for mounting */ if (nfs_read_super(sb, &nfs_data, 1) == NULL) { root_nfs_close(); return -1; } return 0; } /* * Get the NFS port numbers and file handle, and then read the super- * block for mounting. */ int nfs_root_mount(struct super_block *sb) { if (root_nfs_open() < 0) return -1; if (root_nfs_bind() < 0) return -1; if (root_nfs_ports() < 0) return -1; if (root_nfs_get_handle() < 0) return -1; if (root_nfs_do_mount(sb) < 0) return -1; root_nfs_close(); return 0; }