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2422 2423 2424 2425 2426 2427 2428 2429 2430 2431 2432 2433 2434 2435 2436 2437 2438 2439 2440 2441 2442 2443 2444 2445 2446 2447 2448 2449 2450 2451 2452 2453 2454 2455 2456 2457 2458 2459 2460 2461 2462 2463 2464 2465 2466 2467 2468 2469 2470 2471 2472 2473 2474 2475 2476 2477 2478 2479 2480 2481 2482 2483 2484 2485 2486 2487 2488 2489 2490 2491 2492 2493 2494 2495 2496 2497 2498 2499 2500 2501 2502 2503 2504 2505 2506 2507 2508 | /* linux/net/inet/arp.c * * Copyright (C) 1994 by Florian La Roche * * This module implements the Address Resolution Protocol ARP (RFC 826), * which is used to convert IP addresses (or in the future maybe other * high-level addresses) into a low-level hardware address (like an Ethernet * address). * * FIXME: * Experiment with better retransmit timers * Clean up the timer deletions * If you create a proxy entry, set your interface address to the address * and then delete it, proxies may get out of sync with reality - * check this. * * This program is free software; you can redistribute it and/or * modify it under the terms of the GNU General Public License * as published by the Free Software Foundation; either version * 2 of the License, or (at your option) any later version. * * Fixes: * Alan Cox : Removed the ethernet assumptions in * Florian's code * Alan Cox : Fixed some small errors in the ARP * logic * Alan Cox : Allow >4K in /proc * Alan Cox : Make ARP add its own protocol entry * Ross Martin : Rewrote arp_rcv() and arp_get_info() * Stephen Henson : Add AX25 support to arp_get_info() * Alan Cox : Drop data when a device is downed. * Alan Cox : Use init_timer(). * Alan Cox : Double lock fixes. * Martin Seine : Move the arphdr structure * to if_arp.h for compatibility. * with BSD based programs. * Andrew Tridgell : Added ARP netmask code and * re-arranged proxy handling. * Alan Cox : Changed to use notifiers. * Niibe Yutaka : Reply for this device or proxies only. * Alan Cox : Don't proxy across hardware types! * Jonathan Naylor : Added support for NET/ROM. * Mike Shaver : RFC1122 checks. * Jonathan Naylor : Only lookup the hardware address for * the correct hardware type. * Germano Caronni : Assorted subtle races. * Craig Schlenter : Don't modify permanent entry * during arp_rcv. * Russ Nelson : Tidied up a few bits. * Alexey Kuznetsov: Major changes to caching and behaviour, * eg intelligent arp probing and * generation * of host down events. * Alan Cox : Missing unlock in device events. * Eckes : ARP ioctl control errors. * Alexey Kuznetsov: Arp free fix. * Manuel Rodriguez: Gratuitous ARP. * Jonathan Layes : Added arpd support through kerneld * message queue (960314) * Mike Shaver : /proc/sys/net/ipv4/arp_* support * Stuart Cheshire : Metricom and grat arp fixes * *** FOR 2.1 clean this up *** * Lawrence V. Stefani: (08/12/96) Added FDDI support. * David S. Miller : Fix skb leakage in arp_find. */ /* RFC1122 Status: 2.3.2.1 (ARP Cache Validation): MUST provide mechanism to flush stale cache entries (OK) SHOULD be able to configure cache timeout (OK) MUST throttle ARP retransmits (OK) 2.3.2.2 (ARP Packet Queue): SHOULD save at least one packet from each "conversation" with an unresolved IP address. (OK) 950727 -- MS */ #include <linux/types.h> #include <linux/string.h> #include <linux/kernel.h> #include <linux/sched.h> #include <linux/config.h> #include <linux/socket.h> #include <linux/sockios.h> #include <linux/errno.h> #include <linux/in.h> #include <linux/mm.h> #include <linux/inet.h> #include <linux/netdevice.h> #include <linux/etherdevice.h> #include <linux/fddidevice.h> #include <linux/if_arp.h> #include <linux/trdevice.h> #include <linux/skbuff.h> #include <linux/proc_fs.h> #include <linux/stat.h> #include <net/ip.h> #include <net/icmp.h> #include <net/route.h> #include <net/protocol.h> #include <net/tcp.h> #include <net/sock.h> #include <net/arp.h> #if defined(CONFIG_AX25) || defined(CONFIG_AX25_MODULE) #include <net/ax25.h> #if defined(CONFIG_NETROM) || defined(CONFIG_NETROM_MODULE) #include <net/netrom.h> #endif #endif #ifdef CONFIG_NET_ALIAS #include <linux/net_alias.h> #endif #ifdef CONFIG_ARPD #include <net/netlink.h> #endif #include <asm/system.h> #include <asm/segment.h> #include <stdarg.h> /* * Configurable Parameters */ /* * After that time, an unused entry is deleted from the arp table. * RFC1122 recommends set it to 60*HZ, if your site uses proxy arp * and dynamic routing. */ #define ARP_TIMEOUT (60*HZ) int sysctl_arp_timeout = ARP_TIMEOUT; /* * How often is ARP cache checked for expire. * It is useless to set ARP_CHECK_INTERVAL > ARP_TIMEOUT */ #define ARP_CHECK_INTERVAL (60*HZ) int sysctl_arp_check_interval = ARP_CHECK_INTERVAL; /* * Soft limit on ARP cache size. * Note that this number should be greater than * number of simultaneously opened sockets, or else * hardware header cache will not be efficient. */ #if RT_CACHE_DEBUG >= 2 #define ARP_MAXSIZE 4 #else #ifdef CONFIG_ARPD #define ARP_MAXSIZE 64 #else #define ARP_MAXSIZE 256 #endif /* CONFIG_ARPD */ #endif /* * If an arp request is send, ARP_RES_TIME is the timeout value until the * next request is send. * RFC1122: OK. Throttles ARPing, as per 2.3.2.1. (MUST) * The recommended minimum timeout is 1 second per destination. * */ #define ARP_RES_TIME (5*HZ) int sysctl_arp_res_time = ARP_RES_TIME; /* * The number of times an broadcast arp request is send, until * the host is considered temporarily unreachable. */ #define ARP_MAX_TRIES 3 int sysctl_arp_max_tries = ARP_MAX_TRIES; /* * The entry is reconfirmed by sending point-to-point ARP * request after ARP_CONFIRM_INTERVAL. * RFC1122 recommends 60*HZ. * * Warning: there exist nodes, that answer only broadcast * ARP requests (Cisco-4000 in hot standby mode?) * Now arp code should work with such nodes, but * it still will generate redundant broadcast requests, so that * this interval should be enough long. */ #define ARP_CONFIRM_INTERVAL (300*HZ) int sysctl_arp_confirm_interval = ARP_CONFIRM_INTERVAL; /* * We wait for answer to unicast request for ARP_CONFIRM_TIMEOUT. */ #define ARP_CONFIRM_TIMEOUT ARP_RES_TIME int sysctl_arp_confirm_timeout = ARP_CONFIRM_TIMEOUT; /* * The number of times an unicast arp request is retried, until * the cache entry is considered suspicious. * Value 0 means that no unicast pings will be sent. * RFC1122 recommends 2. */ #define ARP_MAX_PINGS 1 int sysctl_arp_max_pings = ARP_MAX_PINGS; /* * When a host is dead, but someone tries to connect it, * we do not remove corresponding cache entry (it would * be useless, it will be created again immediately) * Instead we prolongate interval between broadcasts * to ARP_DEAD_RES_TIME. * This interval should be not very long. * (When the host will be up again, we will notice it only * when ARP_DEAD_RES_TIME expires, or when the host will arp us. */ #define ARP_DEAD_RES_TIME (60*HZ) int sysctl_arp_dead_res_time = ARP_DEAD_RES_TIME; /* * This structure defines the ARP mapping cache. */ struct arp_table { struct arp_table *next; /* Linked entry list */ unsigned long last_used; /* For expiry */ unsigned long last_updated; /* For expiry */ unsigned int flags; /* Control status */ u32 ip; /* ip address of entry */ u32 mask; /* netmask - used for generalised proxy arps (tridge) */ unsigned char ha[MAX_ADDR_LEN]; /* Hardware address */ struct device *dev; /* Device the entry is tied to */ struct hh_cache *hh; /* Hardware headers chain */ /* * The following entries are only used for unresolved hw addresses. */ struct timer_list timer; /* expire timer */ int retries; /* remaining retries */ struct sk_buff_head skb; /* list of queued packets */ }; static atomic_t arp_size = 0; #ifdef CONFIG_ARPD static int arpd_not_running; static int arpd_stamp; #endif static unsigned int arp_bh_mask; #define ARP_BH_BACKLOG 1 /* * Backlog for ARP updates. */ static struct arp_table *arp_backlog; /* * Backlog for incomplete entries. */ static struct arp_table *arp_req_backlog; static void arp_run_bh(void); static void arp_check_expire (unsigned long); static int arp_update (u32 sip, char *sha, struct device * dev, unsigned long updated, struct arp_table *ientry, int grat); static struct timer_list arp_timer = { NULL, NULL, ARP_CHECK_INTERVAL, 0L, &arp_check_expire }; /* * The default arp netmask is just 255.255.255.255 which means it's * a single machine entry. Only proxy entries can have other netmasks */ #define DEF_ARP_NETMASK (~0) /* * The size of the hash table. Must be a power of two. */ #define ARP_TABLE_SIZE 16 #define FULL_ARP_TABLE_SIZE (ARP_TABLE_SIZE+1) struct arp_table *arp_tables[FULL_ARP_TABLE_SIZE] = { NULL, }; #define arp_proxy_list arp_tables[ARP_TABLE_SIZE] /* * The last bits in the IP address are used for the cache lookup. * A special entry is used for proxy arp entries */ #define HASH(paddr) (htonl(paddr) & (ARP_TABLE_SIZE - 1)) /* * ARP cache semaphore. * * Every time when someone wants to traverse arp table, * he MUST call arp_fast_lock. * It will guarantee that arp cache list will not change * by interrupts and the entry that you found will not * disappear unexpectedly. * * If you want to modify arp cache lists, you MUST * call arp_fast_lock, and check that you are the only * owner of semaphore (arp_lock == 1). If it is not the case * you can defer your operation or forgot it, * but DO NOT TOUCH lists. * * However, you are allowed to change arp entry contents. * * Assumptions: * -- interrupt code MUST have lock/unlock balanced, * you cannot lock cache on interrupt and defer unlocking * to callback. * In particular, it means that lock/unlock are allowed * to be non-atomic. They are made atomic, but it was not * necessary. * -- nobody is allowed to sleep while * it keeps arp locked. (route cache has similar locking * scheme, but allows sleeping) * */ static atomic_t arp_lock; #define ARP_LOCKED() (arp_lock != 1) static __inline__ void arp_fast_lock(void) { atomic_inc(&arp_lock); } static __inline__ void arp_unlock(void) { if (atomic_dec_and_test(&arp_lock) && arp_bh_mask) arp_run_bh(); } /* * Enqueue to FIFO list. */ static void arp_enqueue(struct arp_table **q, struct arp_table *entry) { unsigned long flags; struct arp_table * tail; save_flags(flags); cli(); tail = *q; if (!tail) entry->next = entry; else { entry->next = tail->next; tail->next = entry; } *q = entry; restore_flags(flags); return; } /* * Dequeue from FIFO list, * caller should mask interrupts. */ static struct arp_table * arp_dequeue(struct arp_table **q) { struct arp_table * entry; if (*q) { entry = (*q)->next; (*q)->next = entry->next; if (entry->next == entry) *q = NULL; entry->next = NULL; return entry; } return NULL; } /* * Purge all linked skb's of the entry. */ static void arp_purge_send_q(struct arp_table *entry) { struct sk_buff *skb; unsigned long flags; save_flags(flags); cli(); /* Release the list of `skb' pointers. */ while ((skb = skb_dequeue(&entry->skb)) != NULL) { skb_device_lock(skb); restore_flags(flags); dev_kfree_skb(skb, FREE_WRITE); cli(); } restore_flags(flags); return; } /* * Release the entry and all resources linked to it: skb's, hh's, timer * and certainly memory. * The entry should be already removed from lists. */ static void arp_free_entry(struct arp_table *entry) { unsigned long flags; struct hh_cache *hh, *next; del_timer(&entry->timer); arp_purge_send_q(entry); save_flags(flags); cli(); hh = entry->hh; entry->hh = NULL; restore_flags(flags); for ( ; hh; hh = next) { next = hh->hh_next; hh->hh_uptodate = 0; hh->hh_next = NULL; hh->hh_arp = NULL; if (atomic_dec_and_test(&hh->hh_refcnt)) kfree_s(hh, sizeof(struct(struct hh_cache))); } kfree_s(entry, sizeof(struct arp_table)); atomic_dec(&arp_size); return; } /* * Hardware header cache. * * BEWARE! Hardware header cache has no locking, so that * it requires especially careful handling. * It is the only part of arp+route, where a list * should be traversed with masked interrupts. * Luckily, this list contains one element 8), as rule. */ /* * How many users has this entry? * The answer is reliable only when interrupts are masked. */ static __inline__ int arp_count_hhs(struct arp_table * entry) { struct hh_cache *hh; int count = 0; for (hh = entry->hh; hh; hh = hh->hh_next) count += hh->hh_refcnt-1; return count; } /* * Signal to device layer, that hardware address may be changed. */ static __inline__ void arp_update_hhs(struct arp_table * entry) { struct hh_cache *hh; for (hh=entry->hh; hh; hh=hh->hh_next) entry->dev->header_cache_update(hh, entry->dev, entry->ha); } /* * Invalidate all hh's, so that higher level will not try to use it. */ static __inline__ void arp_invalidate_hhs(struct arp_table * entry) { struct hh_cache *hh; for (hh=entry->hh; hh; hh=hh->hh_next) hh->hh_uptodate = 0; } /* * Atomic attaching new hh entry. * Return 1, if entry has been freed, rather than attached. */ static int arp_set_hh(struct hh_cache **hhp, struct hh_cache *hh) { unsigned long flags; struct hh_cache *hh1; struct arp_table *entry; atomic_inc(&hh->hh_refcnt); save_flags(flags); cli(); if ((hh1 = *hhp) == NULL) { *hhp = hh; restore_flags(flags); return 0; } entry = (struct arp_table*)hh->hh_arp; /* * An hh1 entry is already attached to this point. * Is it not linked to arp entry? Link it! */ if (!hh1->hh_arp && entry) { atomic_inc(&hh1->hh_refcnt); hh1->hh_next = entry->hh; entry->hh = hh1; hh1->hh_arp = (void*)entry; restore_flags(flags); if (entry->flags & ATF_COM) entry->dev->header_cache_update(hh1, entry->dev, entry->ha); #if RT_CACHE_DEBUG >= 1 printk("arp_set_hh: %08x is reattached. Good!\n", entry->ip); #endif } #if RT_CACHE_DEBUG >= 1 else if (entry) printk("arp_set_hh: %08x rr1 ok!\n", entry->ip); #endif restore_flags(flags); if (atomic_dec_and_test(&hh->hh_refcnt)) kfree_s(hh, sizeof(struct hh_cache)); return 1; } static __inline__ struct hh_cache * arp_alloc_hh(int htype) { struct hh_cache *hh; hh = kmalloc(sizeof(struct hh_cache), GFP_ATOMIC); if (hh) { memset(hh, 0, sizeof(struct hh_cache)); hh->hh_type = htype; } return hh; } /* * Test if a hardware address is all zero */ static __inline__ int empty(unsigned char * addr, int len) { while (len > 0) { if (*addr) return 0; len--; addr++; } return 1; } #ifdef CONFIG_ARPD /* * Send ARPD message. */ static void arpd_send(int req, u32 addr, struct device * dev, char *ha, unsigned long updated) { int retval; struct sk_buff *skb; struct arpd_request *arpreq; if (arpd_not_running) return; skb = alloc_skb(sizeof(struct arpd_request), GFP_ATOMIC); if (skb == NULL) return; skb->free=1; arpreq=(struct arpd_request *)skb_put(skb, sizeof(struct arpd_request)); arpreq->req = req; arpreq->ip = addr; arpreq->dev = (unsigned long)dev; arpreq->stamp = arpd_stamp; arpreq->updated = updated; if (ha) memcpy(arpreq->ha, ha, sizeof(arpreq->ha)); retval = netlink_post(NETLINK_ARPD, skb); if (retval) { kfree_skb(skb, FREE_WRITE); if (retval == -EUNATCH) arpd_not_running = 1; } } /* * Send ARPD update message. */ static __inline__ void arpd_update(struct arp_table * entry) { if (arpd_not_running) return; arpd_send(ARPD_UPDATE, entry->ip, entry->dev, entry->ha, entry->last_updated); } /* * Send ARPD lookup request. */ static __inline__ void arpd_lookup(u32 addr, struct device * dev) { if (arpd_not_running) return; arpd_send(ARPD_LOOKUP, addr, dev, NULL, 0); } /* * Send ARPD flush message. */ static __inline__ void arpd_flush(struct device * dev) { if (arpd_not_running) return; arpd_send(ARPD_FLUSH, 0, dev, NULL, 0); } static int arpd_callback(struct sk_buff *skb) { struct device * dev; struct arpd_request *retreq; arpd_not_running = 0; if (skb->len != sizeof(struct arpd_request)) { kfree_skb(skb, FREE_READ); return -EINVAL; } retreq = (struct arpd_request *)skb->data; dev = (struct device*)retreq->dev; if (retreq->stamp != arpd_stamp || !dev) { kfree_skb(skb, FREE_READ); return -EINVAL; } if (!retreq->updated || empty(retreq->ha, sizeof(retreq->ha))) { /* * Invalid mapping: drop it and send ARP broadcast. */ arp_send(ARPOP_REQUEST, ETH_P_ARP, retreq->ip, dev, dev->pa_addr, NULL, dev->dev_addr, NULL); } else { arp_fast_lock(); arp_update(retreq->ip, retreq->ha, dev, retreq->updated, NULL, 0); arp_unlock(); } kfree_skb(skb, FREE_READ); return sizeof(struct arpd_request); } #else static __inline__ void arpd_update(struct arp_table * entry) { return; } #endif /* CONFIG_ARPD */ /* * ARP expiration routines. */ /* * Force the expiry of an entry in the internal cache so the memory * can be used for a new request. */ static int arp_force_expire(void) { int i; struct arp_table *entry, **pentry; struct arp_table **oldest_entry = NULL; unsigned long oldest_used = ~0; unsigned long flags; unsigned long now = jiffies; int result = 0; static int last_index; if (ARP_LOCKED()) return 0; save_flags(flags); if (last_index >= ARP_TABLE_SIZE) last_index = 0; for (i = 0; i < ARP_TABLE_SIZE; i++, last_index++) { pentry = &arp_tables[last_index & (ARP_TABLE_SIZE-1)]; while ((entry = *pentry) != NULL) { if (!(entry->flags & ATF_PERM)) { int users; cli(); users = arp_count_hhs(entry); if (!users && now - entry->last_used > sysctl_arp_timeout) { *pentry = entry->next; restore_flags(flags); #if RT_CACHE_DEBUG >= 2 printk("arp_force_expire: %08x expired\n", entry->ip); #endif arp_free_entry(entry); result++; if (arp_size < ARP_MAXSIZE) goto done; continue; } restore_flags(flags); if (!users && entry->last_used < oldest_used) { oldest_entry = pentry; oldest_used = entry->last_used; } } pentry = &entry->next; } } done: if (result || !oldest_entry) return result; entry = *oldest_entry; *oldest_entry = entry->next; #if RT_CACHE_DEBUG >= 2 printk("arp_force_expire: expiring %08x\n", entry->ip); #endif arp_free_entry(entry); return 1; } /* * Check if there are entries that are too old and remove them. If the * ATF_PERM flag is set, they are always left in the arp cache (permanent * entries). If an entry was not confirmed for ARP_CONFIRM_INTERVAL, * send point-to-point ARP request. * If it will not be confirmed for ARP_CONFIRM_TIMEOUT, * give it to shred by arp_expire_entry. */ static void arp_check_expire(unsigned long dummy) { int i; unsigned long now = jiffies; del_timer(&arp_timer); #ifdef CONFIG_ARPD arpd_not_running = 0; #endif ip_rt_check_expire(); arp_fast_lock(); if (!ARP_LOCKED()) { for (i = 0; i < ARP_TABLE_SIZE; i++) { struct arp_table *entry, **pentry; pentry = &arp_tables[i]; while ((entry = *pentry) != NULL) { if (entry->flags & ATF_PERM) { pentry = &entry->next; continue; } cli(); if (now - entry->last_used > sysctl_arp_timeout && !arp_count_hhs(entry)) { *pentry = entry->next; sti(); #if RT_CACHE_DEBUG >= 2 printk("arp_expire: %08x expired\n", entry->ip); #endif arp_free_entry(entry); continue; } sti(); if (entry->last_updated && now - entry->last_updated > sysctl_arp_confirm_interval && !(entry->flags & ATF_PERM)) { struct device * dev = entry->dev; entry->retries = sysctl_arp_max_tries+sysctl_arp_max_pings; del_timer(&entry->timer); entry->timer.expires = jiffies + ARP_CONFIRM_TIMEOUT; add_timer(&entry->timer); arp_send(ARPOP_REQUEST, ETH_P_ARP, entry->ip, dev, dev->pa_addr, entry->ha, dev->dev_addr, NULL); #if RT_CACHE_DEBUG >= 2 printk("arp_expire: %08x requires confirmation\n", entry->ip); #endif } pentry = &entry->next; /* go to next entry */ } } } arp_unlock(); /* * Set the timer again. */ arp_timer.expires = jiffies + sysctl_arp_check_interval; add_timer(&arp_timer); } /* * This function is called, if an entry is not resolved in ARP_RES_TIME. * When more than MAX_ARP_TRIES retries was done, release queued skb's, * but not discard entry itself if it is in use. */ static void arp_expire_request (unsigned long arg) { struct arp_table *entry = (struct arp_table *) arg; struct arp_table **pentry; unsigned long hash; unsigned long flags; arp_fast_lock(); save_flags(flags); cli(); del_timer(&entry->timer); /* * If arp table is locked, defer expire processing. */ if (ARP_LOCKED()) { #if RT_CACHE_DEBUG >= 1 printk(KERN_DEBUG "arp_expire_request: %08x deferred\n", entry->ip); #endif entry->timer.expires = jiffies + HZ/10; add_timer(&entry->timer); restore_flags(flags); arp_unlock(); return; } /* * Since all timeouts are handled with interrupts enabled, there is a * small chance, that this entry has just been resolved by an incoming * packet. This is the only race condition, but it is handled... * * One exception: if entry is COMPLETE but old, * it means that point-to-point ARP ping has been failed * (It really occurs with Cisco 4000 routers) * We should reconfirm it. */ if ((entry->flags & ATF_COM) && entry->last_updated && jiffies - entry->last_updated <= sysctl_arp_confirm_interval) { restore_flags(flags); arp_unlock(); return; } restore_flags(flags); if (entry->last_updated && --entry->retries > 0) { struct device *dev = entry->dev; #if RT_CACHE_DEBUG >= 2 printk("arp_expire_request: %08x timed out\n", entry->ip); #endif /* Set new timer. */ entry->timer.expires = jiffies + sysctl_arp_res_time; add_timer(&entry->timer); arp_send(ARPOP_REQUEST, ETH_P_ARP, entry->ip, dev, dev->pa_addr, entry->retries > sysctl_arp_max_tries ? entry->ha : NULL, dev->dev_addr, NULL); arp_unlock(); return; } /* * The host is really dead. */ arp_purge_send_q(entry); cli(); if (arp_count_hhs(entry)) { /* * The host is dead, but someone refers to it. * It is useless to drop this entry just now, * it will be born again, so that * we keep it, but slow down retransmitting * to ARP_DEAD_RES_TIME. */ struct device *dev = entry->dev; #if RT_CACHE_DEBUG >= 2 printk("arp_expire_request: %08x is dead\n", entry->ip); #endif entry->retries = sysctl_arp_max_tries; entry->flags &= ~ATF_COM; arp_invalidate_hhs(entry); restore_flags(flags); /* * Declare the entry dead. */ entry->last_updated = 0; arpd_update(entry); entry->timer.expires = jiffies + sysctl_arp_dead_res_time; add_timer(&entry->timer); arp_send(ARPOP_REQUEST, ETH_P_ARP, entry->ip, dev, dev->pa_addr, NULL, dev->dev_addr, NULL); arp_unlock(); return; } restore_flags(flags); entry->last_updated = 0; arpd_update(entry); hash = HASH(entry->ip); pentry = &arp_tables[hash]; while (*pentry != NULL) { if (*pentry != entry) { pentry = &(*pentry)->next; continue; } *pentry = entry->next; #if RT_CACHE_DEBUG >= 2 printk("arp_expire_request: %08x is killed\n", entry->ip); #endif arp_free_entry(entry); } arp_unlock(); } /* * Allocate memory for a new entry. If we are at the maximum limit * of the internal ARP cache, arp_force_expire() an entry. NOTE: * arp_force_expire() needs the cache to be locked, so therefore * arp_alloc_entry() should only be called with the cache locked too! */ static struct arp_table * arp_alloc_entry(void) { struct arp_table * entry; if (arp_size >= ARP_MAXSIZE) arp_force_expire(); entry = (struct arp_table *) kmalloc(sizeof(struct arp_table),GFP_ATOMIC); if (entry != NULL) { atomic_inc(&arp_size); memset(entry, 0, sizeof(struct arp_table)); entry->mask = DEF_ARP_NETMASK; init_timer(&entry->timer); entry->timer.function = arp_expire_request; entry->timer.data = (unsigned long)entry; entry->last_updated = entry->last_used = jiffies; skb_queue_head_init(&entry->skb); } return entry; } /* * Purge a device from the ARP queue */ int arp_device_event(struct notifier_block *this, unsigned long event, void *ptr) { struct device *dev=ptr; int i; if (event != NETDEV_DOWN) return NOTIFY_DONE; #ifdef CONFIG_ARPD arpd_flush(dev); arpd_stamp++; #endif arp_fast_lock(); #if RT_CACHE_DEBUG >= 1 if (ARP_LOCKED()) printk("arp_device_event: impossible\n"); #endif for (i = 0; i < FULL_ARP_TABLE_SIZE; i++) { struct arp_table *entry; struct arp_table **pentry = &arp_tables[i]; while ((entry = *pentry) != NULL) { if (entry->dev == dev) { *pentry = entry->next; /* remove from list */ arp_free_entry(entry); } else pentry = &entry->next; /* go to next entry */ } } arp_unlock(); return NOTIFY_DONE; } /* * This will try to retransmit everything on the queue. */ static void arp_send_q(struct arp_table *entry) { struct sk_buff *skb; unsigned long flags; /* * Empty the entire queue, building its data up ready to send */ if(!(entry->flags&ATF_COM)) { printk(KERN_ERR "arp_send_q: incomplete entry for %s\n", in_ntoa(entry->ip)); /* Can't flush the skb, because RFC1122 says to hang on to */ /* at least one from any unresolved entry. --MS */ /* What's happened is that someone has 'unresolved' the entry as we got to use it - this 'can't happen' -- AC */ return; } save_flags(flags); cli(); while((skb = skb_dequeue(&entry->skb)) != NULL) { IS_SKB(skb); skb_device_lock(skb); restore_flags(flags); if(!skb->dev->rebuild_header(skb->data,skb->dev,skb->raddr,skb)) { skb->arp = 1; if(skb->sk==NULL) dev_queue_xmit(skb, skb->dev, 0); else dev_queue_xmit(skb,skb->dev,skb->sk->priority); } cli(); } restore_flags(flags); } static int arp_update (u32 sip, char *sha, struct device * dev, unsigned long updated, struct arp_table *ientry, int grat) { struct arp_table * entry; unsigned long hash; int do_arpd = 0; if (updated == 0) { updated = jiffies; do_arpd = 1; } hash = HASH(sip); for (entry=arp_tables[hash]; entry; entry = entry->next) if (entry->ip == sip && entry->dev == dev) break; if (entry) { /* * Entry found; update it only if it is not a permanent entry. */ if (!(entry->flags & ATF_PERM)) { del_timer(&entry->timer); entry->last_updated = updated; if (memcmp(entry->ha, sha, dev->addr_len)!=0) { memcpy(entry->ha, sha, dev->addr_len); if (entry->flags & ATF_COM) arp_update_hhs(entry); } if (do_arpd) arpd_update(entry); } if (!(entry->flags & ATF_COM)) { /* * This entry was incomplete. Delete the retransmit timer * and switch to complete status. */ entry->flags |= ATF_COM; arp_update_hhs(entry); /* * Send out waiting packets. We might have problems, if someone is * manually removing entries right now -- entry might become invalid * underneath us. */ arp_send_q(entry); } return 1; } /* * No entry found. Need to add a new entry to the arp table. */ entry = ientry; if (grat && !entry) return 0; if (!entry) { entry = arp_alloc_entry(); if (!entry) return 0; entry->ip = sip; entry->flags = ATF_COM; memcpy(entry->ha, sha, dev->addr_len); entry->dev = dev; } entry->last_updated = updated; entry->last_used = jiffies; if (do_arpd) arpd_update(entry); if (!ARP_LOCKED()) { entry->next = arp_tables[hash]; arp_tables[hash] = entry; return 0; } #if RT_CACHE_DEBUG >= 2 printk("arp_update: %08x backlogged\n", entry->ip); #endif arp_enqueue(&arp_backlog, entry); arp_bh_mask |= ARP_BH_BACKLOG; return 0; } static __inline__ struct arp_table *arp_lookup(u32 paddr, struct device * dev) { struct arp_table *entry; for (entry = arp_tables[HASH(paddr)]; entry != NULL; entry = entry->next) if (entry->ip == paddr && (!dev || entry->dev == dev)) return entry; return NULL; } /* * Find an arp mapping in the cache. If not found, return false. */ int arp_query(unsigned char *haddr, u32 paddr, struct device * dev) { struct arp_table *entry; arp_fast_lock(); entry = arp_lookup(paddr, dev); if (entry != NULL) { entry->last_used = jiffies; if (entry->flags & ATF_COM) { memcpy(haddr, entry->ha, dev->addr_len); arp_unlock(); return 1; } } arp_unlock(); return 0; } static int arp_set_predefined(int addr_hint, unsigned char * haddr, u32 paddr, struct device * dev) { switch (addr_hint) { case IS_MYADDR: printk(KERN_DEBUG "ARP: arp called for own IP address\n"); memcpy(haddr, dev->dev_addr, dev->addr_len); return 1; #ifdef CONFIG_IP_MULTICAST case IS_MULTICAST: if(dev->type==ARPHRD_ETHER || dev->type==ARPHRD_IEEE802 || dev->type==ARPHRD_FDDI) { u32 taddr; haddr[0]=0x01; haddr[1]=0x00; haddr[2]=0x5e; taddr=ntohl(paddr); haddr[5]=taddr&0xff; taddr=taddr>>8; haddr[4]=taddr&0xff; taddr=taddr>>8; haddr[3]=taddr&0x7f; return 1; } /* * If a device does not support multicast broadcast the stuff (eg AX.25 for now) */ #endif case IS_BROADCAST: memcpy(haddr, dev->broadcast, dev->addr_len); return 1; } return 0; } /* * Create a new unresolved entry. */ struct arp_table * arp_new_entry(u32 paddr, struct device *dev, struct hh_cache *hh, struct sk_buff *skb) { struct arp_table *entry; entry = arp_alloc_entry(); if (entry != NULL) { entry->ip = paddr; entry->dev = dev; if (hh) { entry->hh = hh; atomic_inc(&hh->hh_refcnt); hh->hh_arp = (void*)entry; } entry->timer.expires = jiffies + sysctl_arp_res_time; if (skb != NULL) { skb_queue_tail(&entry->skb, skb); skb_device_unlock(skb); } if (!ARP_LOCKED()) { unsigned long hash = HASH(paddr); entry->next = arp_tables[hash]; arp_tables[hash] = entry; add_timer(&entry->timer); entry->retries = sysctl_arp_max_tries; #ifdef CONFIG_ARPD if (!arpd_not_running) arpd_lookup(paddr, dev); else #endif arp_send(ARPOP_REQUEST, ETH_P_ARP, paddr, dev, dev->pa_addr, NULL, dev->dev_addr, NULL); } else { #if RT_CACHE_DEBUG >= 2 printk("arp_new_entry: %08x backlogged\n", entry->ip); #endif arp_enqueue(&arp_req_backlog, entry); arp_bh_mask |= ARP_BH_BACKLOG; } } return entry; } /* * Find an arp mapping in the cache. If not found, post a request. */ int arp_find(unsigned char *haddr, u32 paddr, struct device *dev, u32 saddr, struct sk_buff *skb) { struct arp_table *entry; unsigned long hash; if (arp_set_predefined(ip_chk_addr(paddr), haddr, paddr, dev)) { if (skb) skb->arp = 1; return 0; } hash = HASH(paddr); arp_fast_lock(); /* * Find an entry */ entry = arp_lookup(paddr, dev); if (entry != NULL) /* It exists */ { if (entry->flags & ATF_COM) { entry->last_used = jiffies; memcpy(haddr, entry->ha, dev->addr_len); if (skb) skb->arp = 1; arp_unlock(); return 0; } /* * A request was already sent, but no reply yet. Thus * queue the packet with the previous attempt */ if (skb != NULL) { if (entry->last_updated) { skb_queue_tail(&entry->skb, skb); skb_device_unlock(skb); } /* * If last_updated==0 host is dead, so * drop skb's and set socket error. */ else { icmp_send(skb, ICMP_DEST_UNREACH, ICMP_HOST_UNREACH, 0, dev); skb_device_unlock(skb); /* else it is lost forever */ dev_kfree_skb(skb, FREE_WRITE); } } arp_unlock(); return 1; } entry = arp_new_entry(paddr, dev, NULL, skb); if (skb != NULL && !entry) { skb_device_unlock(skb); /* else it is lost forever */ dev_kfree_skb(skb, FREE_WRITE); } arp_unlock(); return 1; } /* * Binding hardware header cache entry. * It is the only really complicated part of arp code. * We have no locking for hh records, so that * all possible race conditions should be resolved by * cli()/sti() pairs. * * Important note: hhs never disappear from lists, if ARP_LOCKED, * this fact allows to scan hh lists with enabled interrupts, * but results in generating duplicate hh entries. * It is harmless. (and I've never seen such event) * * Returns 0, if hh has been just created, so that * caller should fill it. */ int arp_bind_cache(struct hh_cache ** hhp, struct device *dev, unsigned short htype, u32 paddr) { struct arp_table *entry; struct hh_cache *hh; int addr_hint; unsigned long flags; save_flags(flags); if ((addr_hint = ip_chk_addr(paddr)) != 0) { unsigned char haddr[MAX_ADDR_LEN]; if (*hhp) return 1; hh = arp_alloc_hh(htype); if (!hh) return 1; arp_set_predefined(addr_hint, haddr, paddr, dev); dev->header_cache_update(hh, dev, haddr); return arp_set_hh(hhp, hh); } arp_fast_lock(); entry = arp_lookup(paddr, dev); if (entry) { for (hh = entry->hh; hh; hh=hh->hh_next) if (hh->hh_type == htype) break; if (hh) { arp_set_hh(hhp, hh); arp_unlock(); return 1; } } hh = arp_alloc_hh(htype); if (!hh) { arp_unlock(); return 1; } if (entry) { cli(); hh->hh_arp = (void*)entry; hh->hh_next = entry->hh; entry->hh = hh; atomic_inc(&hh->hh_refcnt); restore_flags(flags); if (entry->flags & ATF_COM) dev->header_cache_update(hh, dev, entry->ha); if (arp_set_hh(hhp, hh)) { arp_unlock(); return 0; } entry->last_used = jiffies; arp_unlock(); return 0; } entry = arp_new_entry(paddr, dev, hh, NULL); if (entry == NULL) { kfree_s(hh, sizeof(struct hh_cache)); arp_unlock(); return 1; } if (!arp_set_hh(hhp, hh)) { arp_unlock(); return 0; } arp_unlock(); return 1; } static void arp_run_bh() { unsigned long flags; struct arp_table *entry, *entry1; struct device * dev; unsigned long hash; struct hh_cache *hh; u32 sip; save_flags(flags); cli(); arp_fast_lock(); while (arp_bh_mask) { arp_bh_mask &= ~ARP_BH_BACKLOG; while ((entry = arp_dequeue(&arp_backlog)) != NULL) { restore_flags(flags); if (arp_update(entry->ip, entry->ha, entry->dev, 0, entry, 0)) arp_free_entry(entry); cli(); } cli(); while ((entry = arp_dequeue(&arp_req_backlog)) != NULL) { restore_flags(flags); dev = entry->dev; sip = entry->ip; hash = HASH(sip); for (entry1 = arp_tables[hash]; entry1; entry1 = entry1->next) if (entry1->ip == sip && entry1->dev == dev) break; if (!entry1) { cli(); entry->next = arp_tables[hash]; arp_tables[hash] = entry; restore_flags(flags); entry->timer.expires = jiffies + sysctl_arp_res_time; entry->retries = sysctl_arp_max_tries; entry->last_used = jiffies; if (!(entry->flags & ATF_COM)) { add_timer(&entry->timer); #ifdef CONFIG_ARPD if (!arpd_not_running) arpd_lookup(sip, dev); else #endif arp_send(ARPOP_REQUEST, ETH_P_ARP, sip, dev, dev->pa_addr, NULL, dev->dev_addr, NULL); } #if RT_CACHE_DEBUG >= 1 printk(KERN_DEBUG "arp_run_bh: %08x reinstalled\n", sip); #endif } else { struct sk_buff * skb; struct hh_cache * next; /* Discard entry, but preserve its hh's and * skb's. */ cli(); for (hh=entry->hh; hh; hh=next) { next = hh->hh_next; hh->hh_next = entry1->hh; entry1->hh = hh; hh->hh_arp = (void*)entry1; } entry->hh = NULL; /* Prune skb list from entry * and graft it to entry1. */ while ((skb = skb_dequeue(&entry->skb)) != NULL) { skb_device_lock(skb); restore_flags(flags); skb_queue_tail(&entry1->skb, skb); skb_device_unlock(skb); cli(); } restore_flags(flags); arp_free_entry(entry); if (entry1->flags & ATF_COM) { arp_update_hhs(entry1); arp_send_q(entry1); } } cli(); } cli(); } arp_unlock(); restore_flags(flags); } /* * Interface to link layer: send routine and receive handler. */ /* * Create and send an arp packet. If (dest_hw == NULL), we create a broadcast * message. */ void arp_send(int type, int ptype, u32 dest_ip, struct device *dev, u32 src_ip, unsigned char *dest_hw, unsigned char *src_hw, unsigned char *target_hw) { struct sk_buff *skb; struct arphdr *arp; unsigned char *arp_ptr; /* * No arp on this interface. */ if (dev->flags&IFF_NOARP) return; /* * Allocate a buffer */ skb = alloc_skb(sizeof(struct arphdr)+ 2*(dev->addr_len+4) + dev->hard_header_len, GFP_ATOMIC); if (skb == NULL) { printk(KERN_DEBUG "ARP: no memory to send an arp packet\n"); return; } skb_reserve(skb, dev->hard_header_len); arp = (struct arphdr *) skb_put(skb,sizeof(struct arphdr) + 2*(dev->addr_len+4)); skb->arp = 1; skb->dev = dev; skb->free = 1; skb->protocol = htons (ETH_P_ARP); /* * Fill the device header for the ARP frame */ dev->hard_header(skb,dev,ptype,dest_hw?dest_hw:dev->broadcast,src_hw?src_hw:NULL,skb->len); /* * Fill out the arp protocol part. * * The arp hardware type should match the device type, except for FDDI, * which (according to RFC 1390) should always equal 1 (Ethernet). */ #ifdef CONFIG_FDDI arp->ar_hrd = (dev->type == ARPHRD_FDDI) ? htons(ARPHRD_ETHER) : htons(dev->type); #else arp->ar_hrd = htons(dev->type); #endif /* * Exceptions everywhere. AX.25 uses the AX.25 PID value not the * DIX code for the protocol. Make these device structure fields. */ #if defined(CONFIG_AX25) || defined(CONFIG_AX25_MODULE) #if defined(CONFIG_NETROM) || defined(CONFIG_NETROM_MODULE) arp->ar_pro = (dev->type == ARPHRD_AX25 || dev->type == ARPHRD_NETROM) ? htons(AX25_P_IP) : htons(ETH_P_IP); #else arp->ar_pro = (dev->type != ARPHRD_AX25) ? htons(ETH_P_IP) : htons(AX25_P_IP); #endif #else arp->ar_pro = htons(ETH_P_IP); #endif arp->ar_hln = dev->addr_len; arp->ar_pln = 4; arp->ar_op = htons(type); arp_ptr=(unsigned char *)(arp+1); memcpy(arp_ptr, src_hw, dev->addr_len); arp_ptr+=dev->addr_len; memcpy(arp_ptr, &src_ip,4); arp_ptr+=4; if (target_hw != NULL) memcpy(arp_ptr, target_hw, dev->addr_len); else memset(arp_ptr, 0, dev->addr_len); arp_ptr+=dev->addr_len; memcpy(arp_ptr, &dest_ip, 4); dev_queue_xmit(skb, dev, 0); } /* * Receive an arp request by the device layer. */ int arp_rcv(struct sk_buff *skb, struct device *dev, struct packet_type *pt) { /* * We shouldn't use this type conversion. Check later. */ struct arphdr *arp = (struct arphdr *)skb->h.raw; unsigned char *arp_ptr= (unsigned char *)(arp+1); unsigned char *sha,*tha; u32 sip,tip; if(skb->pkt_type == PACKET_OTHERHOST) { kfree_skb(skb, FREE_READ); return 0; } /* * The hardware length of the packet should match the hardware length * of the device. Similarly, the hardware types should match. The * device should be ARP-able. Also, if pln is not 4, then the lookup * is not from an IP number. We can't currently handle this, so toss * it. */ #ifdef CONFIG_FDDI if (dev->type == ARPHRD_FDDI) { /* * According to RFC 1390, FDDI devices should accept ARP hardware types * of 1 (Ethernet). However, to be more robust, we'll accept hardware * types of either 1 (Ethernet) or 6 (IEEE 802.2). */ if (arp->ar_hln != dev->addr_len || ((ntohs(arp->ar_hrd) != ARPHRD_ETHER) && (ntohs(arp->ar_hrd) != ARPHRD_IEEE802)) || dev->flags & IFF_NOARP || arp->ar_pln != 4) { kfree_skb(skb, FREE_READ); return 0; } } else { if (arp->ar_hln != dev->addr_len || dev->type != ntohs(arp->ar_hrd) || dev->flags & IFF_NOARP || arp->ar_pln != 4) { kfree_skb(skb, FREE_READ); return 0; } } #else if (arp->ar_hln != dev->addr_len || #if CONFIG_AP1000 /* * ARP from cafe-f was found to use ARPHDR_IEEE802 instead of * the expected ARPHDR_ETHER. */ (strcmp(dev->name,"fddi") == 0 && arp->ar_hrd != ARPHRD_ETHER && arp->ar_hrd != ARPHRD_IEEE802) || (strcmp(dev->name,"fddi") != 0 && dev->type != ntohs(arp->ar_hrd)) || #else dev->type != ntohs(arp->ar_hrd) || #endif dev->flags & IFF_NOARP || arp->ar_pln != 4) { kfree_skb(skb, FREE_READ); return 0; } #endif /* * Another test. * The logic here is that the protocol being looked up by arp should * match the protocol the device speaks. If it doesn't, there is a * problem, so toss the packet. */ switch (dev->type) { #if defined(CONFIG_AX25) || defined(CONFIG_AX25_MODULE) case ARPHRD_AX25: if(arp->ar_pro != htons(AX25_P_IP)) { kfree_skb(skb, FREE_READ); return 0; } break; #endif #if defined(CONFIG_NETROM) || defined(CONFIG_NETROM_MODULE) case ARPHRD_NETROM: if(arp->ar_pro != htons(AX25_P_IP)) { kfree_skb(skb, FREE_READ); return 0; } break; #endif case ARPHRD_ETHER: case ARPHRD_ARCNET: case ARPHRD_METRICOM: case ARPHRD_IEEE802: case ARPHRD_FDDI: if(arp->ar_pro != htons(ETH_P_IP)) { kfree_skb(skb, FREE_READ); return 0; } break; default: printk(KERN_ERR "ARP: dev->type mangled!\n"); kfree_skb(skb, FREE_READ); return 0; } /* * Extract fields */ sha=arp_ptr; arp_ptr += dev->addr_len; memcpy(&sip, arp_ptr, 4); arp_ptr += 4; tha=arp_ptr; arp_ptr += dev->addr_len; memcpy(&tip, arp_ptr, 4); /* * Check for bad requests for 127.x.x.x and requests for multicast * addresses. If this is one such, delete it. */ if (LOOPBACK(tip) || MULTICAST(tip)) { kfree_skb(skb, FREE_READ); return 0; } /* * Process entry. The idea here is we want to send a reply if it is a * request for us or if it is a request for someone else that we hold * a proxy for. We want to add an entry to our cache if it is a reply * to us or if it is a request for our address. * (The assumption for this last is that if someone is requesting our * address, they are probably intending to talk to us, so it saves time * if we cache their address. Their address is also probably not in * our cache, since ours is not in their cache.) * * Putting this another way, we only care about replies if they are to * us, in which case we add them to the cache. For requests, we care * about those for us and those for our proxies. We reply to both, * and in the case of requests for us we add the requester to the arp * cache. */ /* * try to switch to alias device whose addr is tip or closest to sip. */ #ifdef CONFIG_NET_ALIAS if (tip != dev->pa_addr && net_alias_has(skb->dev)) { /* * net_alias_dev_rx32 returns main dev if it fails to found other. * if successful, also incr. alias rx count. */ dev = net_alias_dev_rx32(dev, AF_INET, sip, tip); if (dev->type != ntohs(arp->ar_hrd) || dev->flags & IFF_NOARP) { kfree_skb(skb, FREE_READ); return 0; } } #endif if (arp->ar_op == htons(ARPOP_REQUEST)) { /* * Only reply for the real device address or when it's in our proxy tables */ if (tip != dev->pa_addr) { struct arp_table *proxy_entry; /* * To get in here, it is a request for someone else. We need to * check if that someone else is one of our proxies. If it isn't, * we can toss it. * * Make "longest match" lookup, a la routing. */ arp_fast_lock(); for (proxy_entry = arp_proxy_list; proxy_entry; proxy_entry = proxy_entry->next) { if (proxy_entry->dev == dev && !((proxy_entry->ip^tip)&proxy_entry->mask)) break; } if (proxy_entry && (proxy_entry->mask || ((dev->pa_addr^tip)&dev->pa_mask))) { char ha[MAX_ADDR_LEN]; struct rtable * rt; /* Unlock arp tables to make life for * ip_rt_route easy. Note, that we are obliged * to make local copy of hardware address. */ memcpy(ha, proxy_entry->ha, dev->addr_len); arp_unlock(); rt = ip_rt_route(tip, 0, NULL); if (rt && rt->rt_dev != dev) arp_send(ARPOP_REPLY,ETH_P_ARP,sip,dev,tip,sha,ha,sha); ip_rt_put(rt); } else arp_unlock(); } else arp_send(ARPOP_REPLY,ETH_P_ARP,sip,dev,tip,sha,dev->dev_addr,sha); } arp_fast_lock(); arp_update(sip, sha, dev, 0, NULL, ip_chk_addr(tip) != IS_MYADDR && dev->type != ARPHRD_METRICOM); arp_unlock(); kfree_skb(skb, FREE_READ); return 0; } /* * User level interface (ioctl, /proc) */ /* * Set (create) an ARP cache entry. */ static int arp_req_set(struct arpreq *r, struct device * dev) { struct arp_table *entry, **entryp; struct sockaddr_in *si; unsigned char *ha; u32 ip; u32 mask = DEF_ARP_NETMASK; unsigned long flags; /* * Extract netmask (if supplied). */ if (r->arp_flags&ATF_NETMASK) { si = (struct sockaddr_in *) &r->arp_netmask; mask = si->sin_addr.s_addr; } /* * Extract destination. */ si = (struct sockaddr_in *) &r->arp_pa; ip = si->sin_addr.s_addr; if (r->arp_flags&ATF_PUBL) { if (!mask && ip) return -EINVAL; if (!dev) { dev = dev_getbytype(r->arp_ha.sa_family); if (!dev) return -ENODEV; } } else { if (!dev) { struct rtable * rt; rt = ip_rt_route(ip, 0, NULL); if (!rt) return -ENETUNREACH; dev = rt->rt_dev; ip_rt_put(rt); if (!dev) return -ENODEV; } if (dev->type != ARPHRD_METRICOM && ip_chk_addr(ip)) return -EINVAL; } if (dev->flags & (IFF_LOOPBACK | IFF_NOARP)) return -ENODEV; if (r->arp_ha.sa_family != dev->type) return -EINVAL; arp_fast_lock(); #if RT_CACHE_DEBUG >= 1 if (ARP_LOCKED()) printk("arp_req_set: bug\n"); #endif if (!(r->arp_flags & ATF_PUBL)) entryp = &arp_tables[HASH(ip)]; else entryp = &arp_proxy_list; while ((entry = *entryp) != NULL) { /* User supplied arp entries are definitive - RHP 960603 */ if (entry->ip == ip && entry->mask == mask && entry->dev == dev) { *entryp=entry->next; arp_free_entry(entry); continue; } if ((entry->mask & mask) != mask) break; entryp = &entry->next; } entry = arp_alloc_entry(); if (entry == NULL) { arp_unlock(); return -ENOMEM; } entry->ip = ip; entry->dev = dev; entry->mask = mask; entry->flags = r->arp_flags; entry->next = *entryp; *entryp = entry; ha = r->arp_ha.sa_data; if (empty(ha, dev->addr_len)) ha = dev->dev_addr; save_flags(flags); cli(); memcpy(entry->ha, ha, dev->addr_len); entry->last_updated = entry->last_used = jiffies; entry->flags |= ATF_COM; restore_flags(flags); arpd_update(entry); arp_update_hhs(entry); arp_unlock(); return 0; } /* * Get an ARP cache entry. */ static int arp_req_get(struct arpreq *r, struct device *dev) { struct arp_table *entry; struct sockaddr_in *si; u32 mask = DEF_ARP_NETMASK; if (r->arp_flags&ATF_NETMASK) { si = (struct sockaddr_in *) &r->arp_netmask; mask = si->sin_addr.s_addr; } si = (struct sockaddr_in *) &r->arp_pa; arp_fast_lock(); #if RT_CACHE_DEBUG >= 1 if (ARP_LOCKED()) printk("arp_req_set: impossible\n"); #endif if (!(r->arp_flags & ATF_PUBL)) entry = arp_tables[HASH(si->sin_addr.s_addr)]; else entry = arp_proxy_list; for ( ; entry ;entry = entry->next) { if (entry->ip == si->sin_addr.s_addr && (!dev || entry->dev == dev) && (!(r->arp_flags&ATF_NETMASK) || entry->mask == mask)) { memcpy(r->arp_ha.sa_data, entry->ha, entry->dev->addr_len); r->arp_ha.sa_family = entry->dev->type; r->arp_flags = entry->flags; strncpy(r->arp_dev, entry->dev->name, sizeof(r->arp_dev)); arp_unlock(); return 0; } } arp_unlock(); return -ENXIO; } static int arp_req_delete(struct arpreq *r, struct device * dev) { struct sockaddr_in *si; struct arp_table *entry, **entryp; int retval = -ENXIO; u32 mask = DEF_ARP_NETMASK; if (r->arp_flags&ATF_NETMASK) { si = (struct sockaddr_in *) &r->arp_netmask; mask = si->sin_addr.s_addr; } si = (struct sockaddr_in *) &r->arp_pa; arp_fast_lock(); #if RT_CACHE_DEBUG >= 1 if (ARP_LOCKED()) printk("arp_req_delete: impossible\n"); #endif if (!(r->arp_flags & ATF_PUBL)) entryp = &arp_tables[HASH(si->sin_addr.s_addr)]; else entryp = &arp_proxy_list; while ((entry = *entryp) != NULL) { if (entry->ip == si->sin_addr.s_addr && (!dev || entry->dev == dev) && (!(r->arp_flags&ATF_NETMASK) || entry->mask == mask)) { *entryp = entry->next; arp_free_entry(entry); retval = 0; continue; } entryp = &entry->next; } arp_unlock(); return retval; } /* * Handle an ARP layer I/O control request. */ int arp_ioctl(unsigned int cmd, void *arg) { int err; struct arpreq r; struct device * dev = NULL; switch(cmd) { case SIOCDARP: case SIOCSARP: if (!suser()) return -EPERM; case SIOCGARP: err = verify_area(VERIFY_READ, arg, sizeof(struct arpreq)); if (err) return err; memcpy_fromfs(&r, arg, sizeof(struct arpreq)); break; case OLD_SIOCDARP: case OLD_SIOCSARP: if (!suser()) return -EPERM; case OLD_SIOCGARP: err = verify_area(VERIFY_READ, arg, sizeof(struct arpreq_old)); if (err) return err; memcpy_fromfs(&r, arg, sizeof(struct arpreq_old)); memset(&r.arp_dev, 0, sizeof(r.arp_dev)); break; default: return -EINVAL; } if (r.arp_pa.sa_family != AF_INET) return -EPFNOSUPPORT; if (!(r.arp_flags & ATF_PUBL)) r.arp_flags &= ~ATF_NETMASK; if (!(r.arp_flags & ATF_NETMASK)) ((struct sockaddr_in *)&r.arp_netmask)->sin_addr.s_addr=DEF_ARP_NETMASK; if (r.arp_dev[0]) { if ((dev = dev_get(r.arp_dev)) == NULL) return -ENODEV; if (!r.arp_ha.sa_family) r.arp_ha.sa_family = dev->type; else if (r.arp_ha.sa_family != dev->type) return -EINVAL; } switch(cmd) { case SIOCDARP: return arp_req_delete(&r, dev); case SIOCSARP: return arp_req_set(&r, dev); case OLD_SIOCDARP: /* old SIOCDARP destroys both * normal and proxy mappings */ r.arp_flags &= ~ATF_PUBL; err = arp_req_delete(&r, dev); r.arp_flags |= ATF_PUBL; if (!err) arp_req_delete(&r, dev); else err = arp_req_delete(&r, dev); return err; case OLD_SIOCSARP: err = arp_req_set(&r, dev); /* old SIOCSARP works so funny, * that its behaviour can be emulated * only approximately 8). * It should work. --ANK */ if (r.arp_flags & ATF_PUBL) { r.arp_flags &= ~ATF_PUBL; arp_req_delete(&r, dev); } return err; case SIOCGARP: err = verify_area(VERIFY_WRITE, arg, sizeof(struct arpreq)); if (err) return err; err = arp_req_get(&r, dev); if (!err) memcpy_tofs(arg, &r, sizeof(r)); return err; case OLD_SIOCGARP: err = verify_area(VERIFY_WRITE, arg, sizeof(struct arpreq_old)); if (err) return err; r.arp_flags &= ~ATF_PUBL; err = arp_req_get(&r, dev); if (err < 0) { r.arp_flags |= ATF_PUBL; err = arp_req_get(&r, dev); } if (!err) memcpy_tofs(arg, &r, sizeof(struct arpreq_old)); return err; } /*NOTREACHED*/ return 0; } /* * Write the contents of the ARP cache to a PROCfs file. */ #define HBUFFERLEN 30 int arp_get_info(char *buffer, char **start, off_t offset, int length, int dummy) { int len=0; off_t pos=0; int size; struct arp_table *entry; char hbuffer[HBUFFERLEN]; int i,j,k; const char hexbuf[] = "0123456789ABCDEF"; size = sprintf(buffer,"IP address HW type Flags HW address Mask Device\n"); pos+=size; len+=size; arp_fast_lock(); for(i=0; i<FULL_ARP_TABLE_SIZE; i++) { for(entry=arp_tables[i]; entry!=NULL; entry=entry->next) { /* * Convert hardware address to XX:XX:XX:XX ... form. */ #if defined(CONFIG_AX25) || defined(CONFIG_AX25_MODULE) #if defined(CONFIG_NETROM) || defined(CONFIG_NETROM_MODULE) if (entry->dev->type == ARPHRD_AX25 || entry->dev->type == ARPHRD_NETROM) strcpy(hbuffer,ax2asc((ax25_address *)entry->ha)); else { #else if(entry->dev->type==ARPHRD_AX25) strcpy(hbuffer,ax2asc((ax25_address *)entry->ha)); else { #endif #endif for(k=0,j=0;k<HBUFFERLEN-3 && j<entry->dev->addr_len;j++) { hbuffer[k++]=hexbuf[ (entry->ha[j]>>4)&15 ]; hbuffer[k++]=hexbuf[ entry->ha[j]&15 ]; hbuffer[k++]=':'; } hbuffer[--k]=0; #if defined(CONFIG_AX25) || defined(CONFIG_AX25_MODULE) } #endif size = sprintf(buffer+len, "%-17s0x%-10x0x%-10x%s", in_ntoa(entry->ip), (unsigned int)entry->dev->type, entry->flags, hbuffer); #if RT_CACHE_DEBUG < 2 size += sprintf(buffer+len+size, " %-17s %s\n", entry->mask==DEF_ARP_NETMASK ? "*" : in_ntoa(entry->mask), entry->dev->name); #else size += sprintf(buffer+len+size, " %-17s %s\t%d\t%1d\n", entry->mask==DEF_ARP_NETMASK ? "*" : in_ntoa(entry->mask), entry->dev->name, entry->hh ? entry->hh->hh_refcnt : -1, entry->hh ? entry->hh->hh_uptodate : 0); #endif len += size; pos += size; if (pos <= offset) len=0; if (pos >= offset+length) goto done; } } done: arp_unlock(); *start = buffer+len-(pos-offset); /* Start of wanted data */ len = pos-offset; /* Start slop */ if (len>length) len = length; /* Ending slop */ return len; } /* * Called once on startup. */ static struct packet_type arp_packet_type = { 0, /* Should be: __constant_htons(ETH_P_ARP) - but this _doesn't_ come out constant! */ NULL, /* All devices */ arp_rcv, NULL, NULL }; static struct notifier_block arp_dev_notifier={ arp_device_event, NULL, 0 }; void arp_init (void) { /* Register the packet type */ arp_packet_type.type=htons(ETH_P_ARP); dev_add_pack(&arp_packet_type); /* Start with the regular checks for expired arp entries. */ add_timer(&arp_timer); /* Register for device down reports */ register_netdevice_notifier(&arp_dev_notifier); #ifdef CONFIG_PROC_FS proc_net_register(&(struct proc_dir_entry) { PROC_NET_ARP, 3, "arp", S_IFREG | S_IRUGO, 1, 0, 0, 0, &proc_net_inode_operations, arp_get_info }); #endif #ifdef CONFIG_ARPD netlink_attach(NETLINK_ARPD, arpd_callback); #endif } #ifdef CONFIG_AX25_MODULE /* * ax25 -> ascii conversion */ char *ax2asc(ax25_address *a) { static char buf[11]; char c, *s; int n; for (n = 0, s = buf; n < 6; n++) { c = (a->ax25_call[n] >> 1) & 0x7F; if (c != ' ') *s++ = c; } *s++ = '-'; if ((n = ((a->ax25_call[6] >> 1) & 0x0F)) > 9) { *s++ = '1'; n -= 10; } *s++ = n + '0'; *s++ = '\0'; if (*buf == '\0' || *buf == '-') return "*"; return buf; } #endif |