1
// SPDX-License-Identifier: GPL-2.0-or-later
2
/*
3
 *	AARP:		An implementation of the AppleTalk AARP protocol for
4
 *			Ethernet 'ELAP'.
5
 *
6
 *		Alan Cox  <[email protected]>
7
 *
8
 *	This doesn't fit cleanly with the IP arp. Potentially we can use
9
 *	the generic neighbour discovery code to clean this up.
10
 *
11
 *	FIXME:
12
 *		We ought to handle the retransmits with a single list and a
13
 *	separate fast timer for when it is needed.
14
 *		Use neighbour discovery code.
15
 *		Token Ring Support.
16
 *
17
 *	References:
18
 *		Inside AppleTalk (2nd Ed).
19
 *	Fixes:
20
 *		Jaume Grau	-	flush caches on AARP_PROBE
21
 *		Rob Newberry	-	Added proxy AARP and AARP proc fs,
22
 *					moved probing from DDP module.
23
 *		Arnaldo C. Melo -	don't mangle rx packets
24
 */
25

26
#include <linux/if_arp.h>
27
#include <linux/slab.h>
28
#include <net/sock.h>
29
#include <net/datalink.h>
30
#include <net/psnap.h>
31
#include <linux/atalk.h>
32
#include <linux/delay.h>
33
#include <linux/init.h>
34
#include <linux/proc_fs.h>
35
#include <linux/seq_file.h>
36
#include <linux/export.h>
37
#include <linux/etherdevice.h>
38
#include <linux/refcount.h>
39

40
int sysctl_aarp_expiry_time = AARP_EXPIRY_TIME;
41
int sysctl_aarp_tick_time = AARP_TICK_TIME;
42
int sysctl_aarp_retransmit_limit = AARP_RETRANSMIT_LIMIT;
43
int sysctl_aarp_resolve_time = AARP_RESOLVE_TIME;
44

45
/* Lists of aarp entries */
46
/**
47
 *	struct aarp_entry - AARP entry
48
 *	@refcnt: Reference count
49
 *	@last_sent: Last time we xmitted the aarp request
50
 *	@packet_queue: Queue of frames wait for resolution
51
 *	@status: Used for proxy AARP
52
 *	@expires_at: Entry expiry time
53
 *	@target_addr: DDP Address
54
 *	@dev:  Device to use
55
 *	@hwaddr:  Physical i/f address of target/router
56
 *	@xmit_count:  When this hits 10 we give up
57
 *	@next: Next entry in chain
58
 */
59
struct aarp_entry {
60
	refcount_t			refcnt;
61
	/* These first two are only used for unresolved entries */
62
	unsigned long		last_sent;
63
	struct sk_buff_head	packet_queue;
64
	int			status;
65
	unsigned long		expires_at;
66
	struct atalk_addr	target_addr;
67
	struct net_device	*dev;
68
	char			hwaddr[ETH_ALEN];
69
	unsigned short		xmit_count;
70
	struct aarp_entry	*next;
71
};
72

73
/* Hashed list of resolved, unresolved and proxy entries */
74
static struct aarp_entry *resolved[AARP_HASH_SIZE];
75
static struct aarp_entry *unresolved[AARP_HASH_SIZE];
76
static struct aarp_entry *proxies[AARP_HASH_SIZE];
77
static int unresolved_count;
78

79
/* One lock protects it all. */
80
static DEFINE_RWLOCK(aarp_lock);
81

82
/* Used to walk the list and purge/kick entries.  */
83
static struct timer_list aarp_timer;
84

85
static inline void aarp_entry_get(struct aarp_entry *a)
86
{
87
	refcount_inc(&a->refcnt);
88
}
89

90
static inline void aarp_entry_put(struct aarp_entry *a)
91
{
92
	if (refcount_dec_and_test(&a->refcnt))
93
		kfree(a);
94
}
95

96
/*
97
 *	Delete an aarp queue
98
 *
99
 *	Must run under aarp_lock.
100
 */
101
static void __aarp_expire(struct aarp_entry *a)
102
{
103
	skb_queue_purge(&a->packet_queue);
104
	aarp_entry_put(a);
105
}
106

107
/*
108
 *	Send an aarp queue entry request
109
 *
110
 *	Must run under aarp_lock.
111
 */
112
static void __aarp_send_query(struct aarp_entry *a)
113
{
114
	static unsigned char aarp_eth_multicast[ETH_ALEN] =
115
					{ 0x09, 0x00, 0x07, 0xFF, 0xFF, 0xFF };
116
	struct net_device *dev = a->dev;
117
	struct elapaarp *eah;
118
	int len = dev->hard_header_len + sizeof(*eah) + aarp_dl->header_length;
119
	struct sk_buff *skb = alloc_skb(len, GFP_ATOMIC);
120
	struct atalk_addr *sat = atalk_find_dev_addr(dev);
121

122
	if (!skb)
123
		return;
124

125
	if (!sat) {
126
		kfree_skb(skb);
127
		return;
128
	}
129

130
	/* Set up the buffer */
131
	skb_reserve(skb, dev->hard_header_len + aarp_dl->header_length);
132
	skb_reset_network_header(skb);
133
	skb_reset_transport_header(skb);
134
	skb_put(skb, sizeof(*eah));
135
	skb->protocol    = htons(ETH_P_ATALK);
136
	skb->dev	 = dev;
137
	eah		 = aarp_hdr(skb);
138

139
	/* Set up the ARP */
140
	eah->hw_type	 = htons(AARP_HW_TYPE_ETHERNET);
141
	eah->pa_type	 = htons(ETH_P_ATALK);
142
	eah->hw_len	 = ETH_ALEN;
143
	eah->pa_len	 = AARP_PA_ALEN;
144
	eah->function	 = htons(AARP_REQUEST);
145

146
	ether_addr_copy(eah->hw_src, dev->dev_addr);
147

148
	eah->pa_src_zero = 0;
149
	eah->pa_src_net	 = sat->s_net;
150
	eah->pa_src_node = sat->s_node;
151

152
	eth_zero_addr(eah->hw_dst);
153

154
	eah->pa_dst_zero = 0;
155
	eah->pa_dst_net	 = a->target_addr.s_net;
156
	eah->pa_dst_node = a->target_addr.s_node;
157

158
	/* Send it */
159
	aarp_dl->request(aarp_dl, skb, aarp_eth_multicast);
160
	/* Update the sending count */
161
	a->xmit_count++;
162
	a->last_sent = jiffies;
163
}
164

165
/* This runs under aarp_lock and in softint context, so only atomic memory
166
 * allocations can be used. */
167
static void aarp_send_reply(struct net_device *dev, struct atalk_addr *us,
168
			    struct atalk_addr *them, unsigned char *sha)
169
{
170
	struct elapaarp *eah;
171
	int len = dev->hard_header_len + sizeof(*eah) + aarp_dl->header_length;
172
	struct sk_buff *skb = alloc_skb(len, GFP_ATOMIC);
173

174
	if (!skb)
175
		return;
176

177
	/* Set up the buffer */
178
	skb_reserve(skb, dev->hard_header_len + aarp_dl->header_length);
179
	skb_reset_network_header(skb);
180
	skb_reset_transport_header(skb);
181
	skb_put(skb, sizeof(*eah));
182
	skb->protocol    = htons(ETH_P_ATALK);
183
	skb->dev	 = dev;
184
	eah		 = aarp_hdr(skb);
185

186
	/* Set up the ARP */
187
	eah->hw_type	 = htons(AARP_HW_TYPE_ETHERNET);
188
	eah->pa_type	 = htons(ETH_P_ATALK);
189
	eah->hw_len	 = ETH_ALEN;
190
	eah->pa_len	 = AARP_PA_ALEN;
191
	eah->function	 = htons(AARP_REPLY);
192

193
	ether_addr_copy(eah->hw_src, dev->dev_addr);
194

195
	eah->pa_src_zero = 0;
196
	eah->pa_src_net	 = us->s_net;
197
	eah->pa_src_node = us->s_node;
198

199
	if (!sha)
200
		eth_zero_addr(eah->hw_dst);
201
	else
202
		ether_addr_copy(eah->hw_dst, sha);
203

204
	eah->pa_dst_zero = 0;
205
	eah->pa_dst_net	 = them->s_net;
206
	eah->pa_dst_node = them->s_node;
207

208
	/* Send it */
209
	aarp_dl->request(aarp_dl, skb, sha);
210
}
211

212
/*
213
 *	Send probe frames. Called from aarp_probe_network and
214
 *	aarp_proxy_probe_network.
215
 */
216

217
static void aarp_send_probe(struct net_device *dev, struct atalk_addr *us)
218
{
219
	struct elapaarp *eah;
220
	int len = dev->hard_header_len + sizeof(*eah) + aarp_dl->header_length;
221
	struct sk_buff *skb = alloc_skb(len, GFP_ATOMIC);
222
	static unsigned char aarp_eth_multicast[ETH_ALEN] =
223
					{ 0x09, 0x00, 0x07, 0xFF, 0xFF, 0xFF };
224

225
	if (!skb)
226
		return;
227

228
	/* Set up the buffer */
229
	skb_reserve(skb, dev->hard_header_len + aarp_dl->header_length);
230
	skb_reset_network_header(skb);
231
	skb_reset_transport_header(skb);
232
	skb_put(skb, sizeof(*eah));
233
	skb->protocol    = htons(ETH_P_ATALK);
234
	skb->dev	 = dev;
235
	eah		 = aarp_hdr(skb);
236

237
	/* Set up the ARP */
238
	eah->hw_type	 = htons(AARP_HW_TYPE_ETHERNET);
239
	eah->pa_type	 = htons(ETH_P_ATALK);
240
	eah->hw_len	 = ETH_ALEN;
241
	eah->pa_len	 = AARP_PA_ALEN;
242
	eah->function	 = htons(AARP_PROBE);
243

244
	ether_addr_copy(eah->hw_src, dev->dev_addr);
245

246
	eah->pa_src_zero = 0;
247
	eah->pa_src_net	 = us->s_net;
248
	eah->pa_src_node = us->s_node;
249

250
	eth_zero_addr(eah->hw_dst);
251

252
	eah->pa_dst_zero = 0;
253
	eah->pa_dst_net	 = us->s_net;
254
	eah->pa_dst_node = us->s_node;
255

256
	/* Send it */
257
	aarp_dl->request(aarp_dl, skb, aarp_eth_multicast);
258
}
259

260
/*
261
 *	Handle an aarp timer expire
262
 *
263
 *	Must run under the aarp_lock.
264
 */
265

266
static void __aarp_expire_timer(struct aarp_entry **n)
267
{
268
	struct aarp_entry *t;
269

270
	while (*n)
271
		/* Expired ? */
272
		if (time_after(jiffies, (*n)->expires_at)) {
273
			t = *n;
274
			*n = (*n)->next;
275
			__aarp_expire(t);
276
		} else
277
			n = &((*n)->next);
278
}
279

280
/*
281
 *	Kick all pending requests 5 times a second.
282
 *
283
 *	Must run under the aarp_lock.
284
 */
285
static void __aarp_kick(struct aarp_entry **n)
286
{
287
	struct aarp_entry *t;
288

289
	while (*n)
290
		/* Expired: if this will be the 11th tx, we delete instead. */
291
		if ((*n)->xmit_count >= sysctl_aarp_retransmit_limit) {
292
			t = *n;
293
			*n = (*n)->next;
294
			__aarp_expire(t);
295
		} else {
296
			__aarp_send_query(*n);
297
			n = &((*n)->next);
298
		}
299
}
300

301
/*
302
 *	A device has gone down. Take all entries referring to the device
303
 *	and remove them.
304
 *
305
 *	Must run under the aarp_lock.
306
 */
307
static void __aarp_expire_device(struct aarp_entry **n, struct net_device *dev)
308
{
309
	struct aarp_entry *t;
310

311
	while (*n)
312
		if ((*n)->dev == dev) {
313
			t = *n;
314
			*n = (*n)->next;
315
			__aarp_expire(t);
316
		} else
317
			n = &((*n)->next);
318
}
319

320
/* Handle the timer event */
321
static void aarp_expire_timeout(struct timer_list *unused)
322
{
323
	int ct;
324

325
	write_lock_bh(&aarp_lock);
326

327
	for (ct = 0; ct < AARP_HASH_SIZE; ct++) {
328
		__aarp_expire_timer(&resolved[ct]);
329
		__aarp_kick(&unresolved[ct]);
330
		__aarp_expire_timer(&unresolved[ct]);
331
		__aarp_expire_timer(&proxies[ct]);
332
	}
333

334
	write_unlock_bh(&aarp_lock);
335
	mod_timer(&aarp_timer, jiffies +
336
			       (unresolved_count ? sysctl_aarp_tick_time :
337
				sysctl_aarp_expiry_time));
338
}
339

340
/* Network device notifier chain handler. */
341
static int aarp_device_event(struct notifier_block *this, unsigned long event,
342
			     void *ptr)
343
{
344
	struct net_device *dev = netdev_notifier_info_to_dev(ptr);
345
	int ct;
346

347
	if (!net_eq(dev_net(dev), &init_net))
348
		return NOTIFY_DONE;
349

350
	if (event == NETDEV_DOWN) {
351
		write_lock_bh(&aarp_lock);
352

353
		for (ct = 0; ct < AARP_HASH_SIZE; ct++) {
354
			__aarp_expire_device(&resolved[ct], dev);
355
			__aarp_expire_device(&unresolved[ct], dev);
356
			__aarp_expire_device(&proxies[ct], dev);
357
		}
358

359
		write_unlock_bh(&aarp_lock);
360
	}
361
	return NOTIFY_DONE;
362
}
363

364
/* Expire all entries in a hash chain */
365
static void __aarp_expire_all(struct aarp_entry **n)
366
{
367
	struct aarp_entry *t;
368

369
	while (*n) {
370
		t = *n;
371
		*n = (*n)->next;
372
		__aarp_expire(t);
373
	}
374
}
375

376
/* Cleanup all hash chains -- module unloading */
377
static void aarp_purge(void)
378
{
379
	int ct;
380

381
	write_lock_bh(&aarp_lock);
382
	for (ct = 0; ct < AARP_HASH_SIZE; ct++) {
383
		__aarp_expire_all(&resolved[ct]);
384
		__aarp_expire_all(&unresolved[ct]);
385
		__aarp_expire_all(&proxies[ct]);
386
	}
387
	write_unlock_bh(&aarp_lock);
388
}
389

390
/*
391
 *	Create a new aarp entry.  This must use GFP_ATOMIC because it
392
 *	runs while holding spinlocks.
393
 */
394
static struct aarp_entry *aarp_alloc(void)
395
{
396
	struct aarp_entry *a = kmalloc(sizeof(*a), GFP_ATOMIC);
397
	if (!a)
398
		return NULL;
399

400
	refcount_set(&a->refcnt, 1);
401
	skb_queue_head_init(&a->packet_queue);
402
	return a;
403
}
404

405
/*
406
 * Find an entry. We might return an expired but not yet purged entry. We
407
 * don't care as it will do no harm.
408
 *
409
 * This must run under the aarp_lock.
410
 */
411
static struct aarp_entry *__aarp_find_entry(struct aarp_entry *list,
412
					    struct net_device *dev,
413
					    struct atalk_addr *sat)
414
{
415
	while (list) {
416
		if (list->target_addr.s_net == sat->s_net &&
417
		    list->target_addr.s_node == sat->s_node &&
418
		    list->dev == dev)
419
			break;
420
		list = list->next;
421
	}
422

423
	return list;
424
}
425

426
/* Called from the DDP code, and thus must be exported. */
427
void aarp_proxy_remove(struct net_device *dev, struct atalk_addr *sa)
428
{
429
	int hash = sa->s_node % (AARP_HASH_SIZE - 1);
430
	struct aarp_entry *a;
431

432
	write_lock_bh(&aarp_lock);
433

434
	a = __aarp_find_entry(proxies[hash], dev, sa);
435
	if (a)
436
		a->expires_at = jiffies - 1;
437

438
	write_unlock_bh(&aarp_lock);
439
}
440

441
/* This must run under aarp_lock. */
442
static struct atalk_addr *__aarp_proxy_find(struct net_device *dev,
443
					    struct atalk_addr *sa)
444
{
445
	int hash = sa->s_node % (AARP_HASH_SIZE - 1);
446
	struct aarp_entry *a = __aarp_find_entry(proxies[hash], dev, sa);
447

448
	return a ? sa : NULL;
449
}
450

451
void aarp_probe_network(struct atalk_iface *atif)
452
{
453
	unsigned int count;
454

455
	for (count = 0; count < AARP_RETRANSMIT_LIMIT; count++) {
456
		aarp_send_probe(atif->dev, &atif->address);
457

458
		/* Defer 1/10th */
459
		msleep(100);
460

461
		if (atif->status & ATIF_PROBE_FAIL)
462
			break;
463
	}
464
}
465

466
int aarp_proxy_probe_network(struct atalk_iface *atif, struct atalk_addr *sa)
467
{
468
	int hash, retval = -EPROTONOSUPPORT;
469
	struct aarp_entry *entry;
470
	unsigned int count;
471

472
	/*
473
	 * we don't currently support LocalTalk or PPP for proxy AARP;
474
	 * if someone wants to try and add it, have fun
475
	 */
476
	if (atif->dev->type == ARPHRD_LOCALTLK ||
477
	    atif->dev->type == ARPHRD_PPP)
478
		goto out;
479

480
	/*
481
	 * create a new AARP entry with the flags set to be published --
482
	 * we need this one to hang around even if it's in use
483
	 */
484
	entry = aarp_alloc();
485
	retval = -ENOMEM;
486
	if (!entry)
487
		goto out;
488

489
	entry->expires_at = -1;
490
	entry->status = ATIF_PROBE;
491
	entry->target_addr.s_node = sa->s_node;
492
	entry->target_addr.s_net = sa->s_net;
493
	entry->dev = atif->dev;
494

495
	write_lock_bh(&aarp_lock);
496
	aarp_entry_get(entry);
497

498
	hash = sa->s_node % (AARP_HASH_SIZE - 1);
499
	entry->next = proxies[hash];
500
	proxies[hash] = entry;
501

502
	for (count = 0; count < AARP_RETRANSMIT_LIMIT; count++) {
503
		aarp_send_probe(atif->dev, sa);
504

505
		/* Defer 1/10th */
506
		write_unlock_bh(&aarp_lock);
507
		msleep(100);
508
		write_lock_bh(&aarp_lock);
509

510
		if (entry->status & ATIF_PROBE_FAIL)
511
			break;
512
	}
513

514
	if (entry->status & ATIF_PROBE_FAIL) {
515
		entry->expires_at = jiffies - 1; /* free the entry */
516
		retval = -EADDRINUSE; /* return network full */
517
	} else { /* clear the probing flag */
518
		entry->status &= ~ATIF_PROBE;
519
		retval = 1;
520
	}
521

522
	aarp_entry_put(entry);
523
	write_unlock_bh(&aarp_lock);
524
out:
525
	return retval;
526
}
527

528
/* Send a DDP frame */
529
int aarp_send_ddp(struct net_device *dev, struct sk_buff *skb,
530
		  struct atalk_addr *sa, void *hwaddr)
531
{
532
	static char ddp_eth_multicast[ETH_ALEN] =
533
		{ 0x09, 0x00, 0x07, 0xFF, 0xFF, 0xFF };
534
	int hash;
535
	struct aarp_entry *a;
536

537
	skb_reset_network_header(skb);
538

539
	/* Check for LocalTalk first */
540
	if (dev->type == ARPHRD_LOCALTLK) {
541
		struct atalk_addr *at = atalk_find_dev_addr(dev);
542
		struct ddpehdr *ddp = (struct ddpehdr *)skb->data;
543
		int ft = 2;
544

545
		/*
546
		 * Compressible ?
547
		 *
548
		 * IFF: src_net == dest_net == device_net
549
		 * (zero matches anything)
550
		 */
551

552
		if ((!ddp->deh_snet || at->s_net == ddp->deh_snet) &&
553
		    (!ddp->deh_dnet || at->s_net == ddp->deh_dnet)) {
554
			skb_pull(skb, sizeof(*ddp) - 4);
555

556
			/*
557
			 *	The upper two remaining bytes are the port
558
			 *	numbers	we just happen to need. Now put the
559
			 *	length in the lower two.
560
			 */
561
			*((__be16 *)skb->data) = htons(skb->len);
562
			ft = 1;
563
		}
564
		/*
565
		 * Nice and easy. No AARP type protocols occur here so we can
566
		 * just shovel it out with a 3 byte LLAP header
567
		 */
568

569
		skb_push(skb, 3);
570
		skb->data[0] = sa->s_node;
571
		skb->data[1] = at->s_node;
572
		skb->data[2] = ft;
573
		skb->dev     = dev;
574
		goto sendit;
575
	}
576

577
	/* On a PPP link we neither compress nor aarp.  */
578
	if (dev->type == ARPHRD_PPP) {
579
		skb->protocol = htons(ETH_P_PPPTALK);
580
		skb->dev = dev;
581
		goto sendit;
582
	}
583

584
	/* Non ELAP we cannot do. */
585
	if (dev->type != ARPHRD_ETHER)
586
		goto free_it;
587

588
	skb->dev = dev;
589
	skb->protocol = htons(ETH_P_ATALK);
590
	hash = sa->s_node % (AARP_HASH_SIZE - 1);
591

592
	/* Do we have a resolved entry? */
593
	if (sa->s_node == ATADDR_BCAST) {
594
		/* Send it */
595
		ddp_dl->request(ddp_dl, skb, ddp_eth_multicast);
596
		goto sent;
597
	}
598

599
	write_lock_bh(&aarp_lock);
600
	a = __aarp_find_entry(resolved[hash], dev, sa);
601

602
	if (a) { /* Return 1 and fill in the address */
603
		a->expires_at = jiffies + (sysctl_aarp_expiry_time * 10);
604
		ddp_dl->request(ddp_dl, skb, a->hwaddr);
605
		write_unlock_bh(&aarp_lock);
606
		goto sent;
607
	}
608

609
	/* Do we have an unresolved entry: This is the less common path */
610
	a = __aarp_find_entry(unresolved[hash], dev, sa);
611
	if (a) { /* Queue onto the unresolved queue */
612
		skb_queue_tail(&a->packet_queue, skb);
613
		goto out_unlock;
614
	}
615

616
	/* Allocate a new entry */
617
	a = aarp_alloc();
618
	if (!a) {
619
		/* Whoops slipped... good job it's an unreliable protocol 8) */
620
		write_unlock_bh(&aarp_lock);
621
		goto free_it;
622
	}
623

624
	/* Set up the queue */
625
	skb_queue_tail(&a->packet_queue, skb);
626
	a->expires_at	 = jiffies + sysctl_aarp_resolve_time;
627
	a->dev		 = dev;
628
	a->next		 = unresolved[hash];
629
	a->target_addr	 = *sa;
630
	a->xmit_count	 = 0;
631
	unresolved[hash] = a;
632
	unresolved_count++;
633

634
	/* Send an initial request for the address */
635
	__aarp_send_query(a);
636

637
	/*
638
	 * Switch to fast timer if needed (That is if this is the first
639
	 * unresolved entry to get added)
640
	 */
641

642
	if (unresolved_count == 1)
643
		mod_timer(&aarp_timer, jiffies + sysctl_aarp_tick_time);
644

645
	/* Now finally, it is safe to drop the lock. */
646
out_unlock:
647
	write_unlock_bh(&aarp_lock);
648

649
	/* Tell the ddp layer we have taken over for this frame. */
650
	goto sent;
651

652
sendit:
653
	if (skb->sk)
654
		skb->priority = READ_ONCE(skb->sk->sk_priority);
655
	if (dev_queue_xmit(skb))
656
		goto drop;
657
sent:
658
	return NET_XMIT_SUCCESS;
659
free_it:
660
	kfree_skb(skb);
661
drop:
662
	return NET_XMIT_DROP;
663
}
664
EXPORT_SYMBOL(aarp_send_ddp);
665

666
/*
667
 *	An entry in the aarp unresolved queue has become resolved. Send
668
 *	all the frames queued under it.
669
 *
670
 *	Must run under aarp_lock.
671
 */
672
static void __aarp_resolved(struct aarp_entry **list, struct aarp_entry *a,
673
			    int hash)
674
{
675
	struct sk_buff *skb;
676

677
	while (*list)
678
		if (*list == a) {
679
			unresolved_count--;
680
			*list = a->next;
681

682
			/* Move into the resolved list */
683
			a->next = resolved[hash];
684
			resolved[hash] = a;
685

686
			/* Kick frames off */
687
			while ((skb = skb_dequeue(&a->packet_queue)) != NULL) {
688
				a->expires_at = jiffies +
689
						sysctl_aarp_expiry_time * 10;
690
				ddp_dl->request(ddp_dl, skb, a->hwaddr);
691
			}
692
		} else
693
			list = &((*list)->next);
694
}
695

696
/*
697
 *	This is called by the SNAP driver whenever we see an AARP SNAP
698
 *	frame. We currently only support Ethernet.
699
 */
700
static int aarp_rcv(struct sk_buff *skb, struct net_device *dev,
701
		    struct packet_type *pt, struct net_device *orig_dev)
702
{
703
	struct elapaarp *ea = aarp_hdr(skb);
704
	int hash, ret = 0;
705
	__u16 function;
706
	struct aarp_entry *a;
707
	struct atalk_addr sa, *ma, da;
708
	struct atalk_iface *ifa;
709

710
	if (!net_eq(dev_net(dev), &init_net))
711
		goto out0;
712

713
	/* We only do Ethernet SNAP AARP. */
714
	if (dev->type != ARPHRD_ETHER)
715
		goto out0;
716

717
	/* Frame size ok? */
718
	if (!skb_pull(skb, sizeof(*ea)))
719
		goto out0;
720

721
	function = ntohs(ea->function);
722

723
	/* Sanity check fields. */
724
	if (function < AARP_REQUEST || function > AARP_PROBE ||
725
	    ea->hw_len != ETH_ALEN || ea->pa_len != AARP_PA_ALEN ||
726
	    ea->pa_src_zero || ea->pa_dst_zero)
727
		goto out0;
728

729
	/* Looks good. */
730
	hash = ea->pa_src_node % (AARP_HASH_SIZE - 1);
731

732
	/* Build an address. */
733
	sa.s_node = ea->pa_src_node;
734
	sa.s_net = ea->pa_src_net;
735

736
	/* Process the packet. Check for replies of me. */
737
	ifa = atalk_find_dev(dev);
738
	if (!ifa)
739
		goto out1;
740

741
	if (ifa->status & ATIF_PROBE &&
742
	    ifa->address.s_node == ea->pa_dst_node &&
743
	    ifa->address.s_net == ea->pa_dst_net) {
744
		ifa->status |= ATIF_PROBE_FAIL; /* Fail the probe (in use) */
745
		goto out1;
746
	}
747

748
	/* Check for replies of proxy AARP entries */
749
	da.s_node = ea->pa_dst_node;
750
	da.s_net  = ea->pa_dst_net;
751

752
	write_lock_bh(&aarp_lock);
753
	a = __aarp_find_entry(proxies[hash], dev, &da);
754

755
	if (a && a->status & ATIF_PROBE) {
756
		a->status |= ATIF_PROBE_FAIL;
757
		/*
758
		 * we do not respond to probe or request packets of
759
		 * this address while we are probing this address
760
		 */
761
		goto unlock;
762
	}
763

764
	switch (function) {
765
	case AARP_REPLY:
766
		if (!unresolved_count)	/* Speed up */
767
			break;
768

769
		/* Find the entry.  */
770
		a = __aarp_find_entry(unresolved[hash], dev, &sa);
771
		if (!a || dev != a->dev)
772
			break;
773

774
		/* We can fill one in - this is good. */
775
		ether_addr_copy(a->hwaddr, ea->hw_src);
776
		__aarp_resolved(&unresolved[hash], a, hash);
777
		if (!unresolved_count)
778
			mod_timer(&aarp_timer,
779
				  jiffies + sysctl_aarp_expiry_time);
780
		break;
781

782
	case AARP_REQUEST:
783
	case AARP_PROBE:
784

785
		/*
786
		 * If it is my address set ma to my address and reply.
787
		 * We can treat probe and request the same.  Probe
788
		 * simply means we shouldn't cache the querying host,
789
		 * as in a probe they are proposing an address not
790
		 * using one.
791
		 *
792
		 * Support for proxy-AARP added. We check if the
793
		 * address is one of our proxies before we toss the
794
		 * packet out.
795
		 */
796

797
		sa.s_node = ea->pa_dst_node;
798
		sa.s_net  = ea->pa_dst_net;
799

800
		/* See if we have a matching proxy. */
801
		ma = __aarp_proxy_find(dev, &sa);
802
		if (!ma)
803
			ma = &ifa->address;
804
		else { /* We need to make a copy of the entry. */
805
			da.s_node = sa.s_node;
806
			da.s_net = sa.s_net;
807
			ma = &da;
808
		}
809

810
		if (function == AARP_PROBE) {
811
			/*
812
			 * A probe implies someone trying to get an
813
			 * address. So as a precaution flush any
814
			 * entries we have for this address.
815
			 */
816
			a = __aarp_find_entry(resolved[sa.s_node %
817
						       (AARP_HASH_SIZE - 1)],
818
					      skb->dev, &sa);
819

820
			/*
821
			 * Make it expire next tick - that avoids us
822
			 * getting into a probe/flush/learn/probe/
823
			 * flush/learn cycle during probing of a slow
824
			 * to respond host addr.
825
			 */
826
			if (a) {
827
				a->expires_at = jiffies - 1;
828
				mod_timer(&aarp_timer, jiffies +
829
					  sysctl_aarp_tick_time);
830
			}
831
		}
832

833
		if (sa.s_node != ma->s_node)
834
			break;
835

836
		if (sa.s_net && ma->s_net && sa.s_net != ma->s_net)
837
			break;
838

839
		sa.s_node = ea->pa_src_node;
840
		sa.s_net = ea->pa_src_net;
841

842
		/* aarp_my_address has found the address to use for us.
843
		 */
844
		aarp_send_reply(dev, ma, &sa, ea->hw_src);
845
		break;
846
	}
847

848
unlock:
849
	write_unlock_bh(&aarp_lock);
850
out1:
851
	ret = 1;
852
out0:
853
	kfree_skb(skb);
854
	return ret;
855
}
856

857
static struct notifier_block aarp_notifier = {
858
	.notifier_call = aarp_device_event,
859
};
860

861
static unsigned char aarp_snap_id[] = { 0x00, 0x00, 0x00, 0x80, 0xF3 };
862

863
int __init aarp_proto_init(void)
864
{
865
	int rc;
866

867
	aarp_dl = register_snap_client(aarp_snap_id, aarp_rcv);
868
	if (!aarp_dl) {
869
		printk(KERN_CRIT "Unable to register AARP with SNAP.\n");
870
		return -ENOMEM;
871
	}
872
	timer_setup(&aarp_timer, aarp_expire_timeout, 0);
873
	aarp_timer.expires  = jiffies + sysctl_aarp_expiry_time;
874
	add_timer(&aarp_timer);
875
	rc = register_netdevice_notifier(&aarp_notifier);
876
	if (rc) {
877
		timer_delete_sync(&aarp_timer);
878
		unregister_snap_client(aarp_dl);
879
	}
880
	return rc;
881
}
882

883
/* Remove the AARP entries associated with a device. */
884
void aarp_device_down(struct net_device *dev)
885
{
886
	int ct;
887

888
	write_lock_bh(&aarp_lock);
889

890
	for (ct = 0; ct < AARP_HASH_SIZE; ct++) {
891
		__aarp_expire_device(&resolved[ct], dev);
892
		__aarp_expire_device(&unresolved[ct], dev);
893
		__aarp_expire_device(&proxies[ct], dev);
894
	}
895

896
	write_unlock_bh(&aarp_lock);
897
}
898

899
#ifdef CONFIG_PROC_FS
900
/*
901
 * Get the aarp entry that is in the chain described
902
 * by the iterator.
903
 * If pos is set then skip till that index.
904
 * pos = 1 is the first entry
905
 */
906
static struct aarp_entry *iter_next(struct aarp_iter_state *iter, loff_t *pos)
907
{
908
	int ct = iter->bucket;
909
	struct aarp_entry **table = iter->table;
910
	loff_t off = 0;
911
	struct aarp_entry *entry;
912

913
 rescan:
914
	while (ct < AARP_HASH_SIZE) {
915
		for (entry = table[ct]; entry; entry = entry->next) {
916
			if (!pos || ++off == *pos) {
917
				iter->table = table;
918
				iter->bucket = ct;
919
				return entry;
920
			}
921
		}
922
		++ct;
923
	}
924

925
	if (table == resolved) {
926
		ct = 0;
927
		table = unresolved;
928
		goto rescan;
929
	}
930
	if (table == unresolved) {
931
		ct = 0;
932
		table = proxies;
933
		goto rescan;
934
	}
935
	return NULL;
936
}
937

938
static void *aarp_seq_start(struct seq_file *seq, loff_t *pos)
939
	__acquires(aarp_lock)
940
{
941
	struct aarp_iter_state *iter = seq->private;
942

943
	read_lock_bh(&aarp_lock);
944
	iter->table     = resolved;
945
	iter->bucket    = 0;
946

947
	return *pos ? iter_next(iter, pos) : SEQ_START_TOKEN;
948
}
949

950
static void *aarp_seq_next(struct seq_file *seq, void *v, loff_t *pos)
951
{
952
	struct aarp_entry *entry = v;
953
	struct aarp_iter_state *iter = seq->private;
954

955
	++*pos;
956

957
	/* first line after header */
958
	if (v == SEQ_START_TOKEN)
959
		entry = iter_next(iter, NULL);
960

961
	/* next entry in current bucket */
962
	else if (entry->next)
963
		entry = entry->next;
964

965
	/* next bucket or table */
966
	else {
967
		++iter->bucket;
968
		entry = iter_next(iter, NULL);
969
	}
970
	return entry;
971
}
972

973
static void aarp_seq_stop(struct seq_file *seq, void *v)
974
	__releases(aarp_lock)
975
{
976
	read_unlock_bh(&aarp_lock);
977
}
978

979
static const char *dt2str(unsigned long ticks)
980
{
981
	static char buf[32];
982

983
	sprintf(buf, "%ld.%02ld", ticks / HZ, ((ticks % HZ) * 100) / HZ);
984

985
	return buf;
986
}
987

988
static int aarp_seq_show(struct seq_file *seq, void *v)
989
{
990
	struct aarp_iter_state *iter = seq->private;
991
	struct aarp_entry *entry = v;
992
	unsigned long now = jiffies;
993

994
	if (v == SEQ_START_TOKEN)
995
		seq_puts(seq,
996
			 "Address  Interface   Hardware Address"
997
			 "   Expires LastSend  Retry Status\n");
998
	else {
999
		seq_printf(seq, "%04X:%02X  %-12s",
1000
			   ntohs(entry->target_addr.s_net),
1001
			   (unsigned int) entry->target_addr.s_node,
1002
			   entry->dev ? entry->dev->name : "????");
1003
		seq_printf(seq, "%pM", entry->hwaddr);
1004
		seq_printf(seq, " %8s",
1005
			   dt2str((long)entry->expires_at - (long)now));
1006
		if (iter->table == unresolved)
1007
			seq_printf(seq, " %8s %6hu",
1008
				   dt2str(now - entry->last_sent),
1009
				   entry->xmit_count);
1010
		else
1011
			seq_puts(seq, "                ");
1012
		seq_printf(seq, " %s\n",
1013
			   (iter->table == resolved) ? "resolved"
1014
			   : (iter->table == unresolved) ? "unresolved"
1015
			   : (iter->table == proxies) ? "proxies"
1016
			   : "unknown");
1017
	}
1018
	return 0;
1019
}
1020

1021
const struct seq_operations aarp_seq_ops = {
1022
	.start  = aarp_seq_start,
1023
	.next   = aarp_seq_next,
1024
	.stop   = aarp_seq_stop,
1025
	.show   = aarp_seq_show,
1026
};
1027
#endif
1028

1029
/* General module cleanup. Called from cleanup_module() in ddp.c. */
1030
void aarp_cleanup_module(void)
1031
{
1032
	timer_delete_sync(&aarp_timer);
1033
	unregister_netdevice_notifier(&aarp_notifier);
1034
	unregister_snap_client(aarp_dl);
1035
	aarp_purge();
1036
}
1037

1038