Commit | Line | Data |
---|---|---|
2fe58dfd SE |
1 | /* User-kernel network link */ |
2 | ||
ff05a229 | 3 | /* See RFCs 791, 792, 1123 and 1812 */ |
2fe58dfd | 4 | |
ff05a229 SE |
5 | /* The netlink device is actually a router. Tunnels are unnumbered |
6 | point-to-point lines (RFC1812 section 2.2.7); the router has a | |
7 | single address (the 'router-id'). */ | |
8 | ||
9 | /* This is where we currently have the anti-spoofing paranoia - before | |
10 | sending a packet to the kernel we check that the tunnel it came | |
11 | over could reasonably have produced it. */ | |
12 | ||
13 | ||
14 | /* Points to note from RFC1812 (which may require changes in this | |
15 | file): | |
16 | ||
17 | 3.3.4 Maximum Transmission Unit - MTU | |
18 | ||
19 | The MTU of each logical interface MUST be configurable within the | |
20 | range of legal MTUs for the interface. | |
21 | ||
22 | Many Link Layer protocols define a maximum frame size that may be | |
23 | sent. In such cases, a router MUST NOT allow an MTU to be set which | |
24 | would allow sending of frames larger than those allowed by the Link | |
25 | Layer protocol. However, a router SHOULD be willing to receive a | |
26 | packet as large as the maximum frame size even if that is larger than | |
27 | the MTU. | |
28 | ||
29 | 4.2.1 A router SHOULD count datagrams discarded. | |
30 | ||
31 | 4.2.2.1 Source route options - we probably should implement processing | |
32 | of source routes, even though mostly the security policy will prevent | |
33 | their use. | |
34 | ||
35 | 5.3.13.4 Source Route Options | |
36 | ||
37 | A router MUST implement support for source route options in forwarded | |
38 | packets. A router MAY implement a configuration option that, when | |
39 | enabled, causes all source-routed packets to be discarded. However, | |
40 | such an option MUST NOT be enabled by default. | |
41 | ||
42 | 5.3.13.5 Record Route Option | |
43 | ||
44 | Routers MUST support the Record Route option in forwarded packets. | |
45 | ||
46 | A router MAY provide a configuration option that, if enabled, will | |
47 | cause the router to ignore (i.e., pass through unchanged) Record | |
48 | Route options in forwarded packets. If provided, such an option MUST | |
49 | default to enabling the record-route. This option should not affect | |
50 | the processing of Record Route options in datagrams received by the | |
51 | router itself (in particular, Record Route options in ICMP echo | |
52 | requests will still be processed according to Section [4.3.3.6]). | |
53 | ||
54 | 5.3.13.6 Timestamp Option | |
55 | ||
56 | Routers MUST support the timestamp option in forwarded packets. A | |
57 | timestamp value MUST follow the rules given [INTRO:2]. | |
58 | ||
59 | If the flags field = 3 (timestamp and prespecified address), the | |
60 | router MUST add its timestamp if the next prespecified address | |
61 | matches any of the router's IP addresses. It is not necessary that | |
62 | the prespecified address be either the address of the interface on | |
63 | which the packet arrived or the address of the interface over which | |
64 | it will be sent. | |
65 | ||
66 | ||
67 | 4.2.2.7 Fragmentation: RFC 791 Section 3.2 | |
68 | ||
69 | Fragmentation, as described in [INTERNET:1], MUST be supported by a | |
70 | router. | |
71 | ||
72 | 4.2.2.8 Reassembly: RFC 791 Section 3.2 | |
73 | ||
74 | As specified in the corresponding section of [INTRO:2], a router MUST | |
75 | support reassembly of datagrams that it delivers to itself. | |
76 | ||
77 | 4.2.2.9 Time to Live: RFC 791 Section 3.2 | |
78 | ||
79 | Note in particular that a router MUST NOT check the TTL of a packet | |
80 | except when forwarding it. | |
81 | ||
82 | A router MUST NOT discard a datagram just because it was received | |
83 | with TTL equal to zero or one; if it is to the router and otherwise | |
84 | valid, the router MUST attempt to receive it. | |
85 | ||
86 | On messages the router originates, the IP layer MUST provide a means | |
87 | for the transport layer to set the TTL field of every datagram that | |
88 | is sent. When a fixed TTL value is used, it MUST be configurable. | |
89 | ||
90 | ||
91 | 8.1 The Simple Network Management Protocol - SNMP | |
92 | 8.1.1 SNMP Protocol Elements | |
93 | ||
94 | Routers MUST be manageable by SNMP [MGT:3]. The SNMP MUST operate | |
95 | using UDP/IP as its transport and network protocols. | |
96 | ||
97 | ||
98 | */ | |
2fe58dfd | 99 | |
3b83c932 | 100 | #include <string.h> |
59230b9b IJ |
101 | #include <assert.h> |
102 | #include <limits.h> | |
8689b3a9 | 103 | #include "secnet.h" |
2fe58dfd | 104 | #include "util.h" |
7138d0c5 | 105 | #include "ipaddr.h" |
9d3a4132 | 106 | #include "netlink.h" |
042a8da9 | 107 | #include "process.h" |
2fe58dfd | 108 | |
469fd1d9 SE |
109 | #define OPT_SOFTROUTE 1 |
110 | #define OPT_ALLOWROUTE 2 | |
111 | ||
ff05a229 SE |
112 | #define ICMP_TYPE_ECHO_REPLY 0 |
113 | ||
114 | #define ICMP_TYPE_UNREACHABLE 3 | |
115 | #define ICMP_CODE_NET_UNREACHABLE 0 | |
116 | #define ICMP_CODE_PROTOCOL_UNREACHABLE 2 | |
117 | #define ICMP_CODE_FRAGMENTATION_REQUIRED 4 | |
118 | #define ICMP_CODE_NET_PROHIBITED 13 | |
119 | ||
120 | #define ICMP_TYPE_ECHO_REQUEST 8 | |
121 | ||
122 | #define ICMP_TYPE_TIME_EXCEEDED 11 | |
123 | #define ICMP_CODE_TTL_EXCEEDED 0 | |
124 | ||
4efd681a | 125 | /* Generic IP checksum routine */ |
1caa23ff | 126 | static inline uint16_t ip_csum(uint8_t *iph,int32_t count) |
2fe58dfd | 127 | { |
4efd681a SE |
128 | register uint32_t sum=0; |
129 | ||
130 | while (count>1) { | |
131 | sum+=ntohs(*(uint16_t *)iph); | |
132 | iph+=2; | |
133 | count-=2; | |
134 | } | |
135 | if(count>0) | |
136 | sum+=*(uint8_t *)iph; | |
137 | while (sum>>16) | |
138 | sum=(sum&0xffff)+(sum>>16); | |
139 | return htons(~sum); | |
2fe58dfd SE |
140 | } |
141 | ||
4efd681a SE |
142 | #ifdef i386 |
143 | /* | |
144 | * This is a version of ip_compute_csum() optimized for IP headers, | |
145 | * which always checksum on 4 octet boundaries. | |
146 | * | |
147 | * By Jorge Cwik <jorge@laser.satlink.net>, adapted for linux by | |
148 | * Arnt Gulbrandsen. | |
149 | */ | |
1caa23ff | 150 | static inline uint16_t ip_fast_csum(uint8_t *iph, int32_t ihl) { |
4efd681a SE |
151 | uint32_t sum; |
152 | ||
20d324b6 SE |
153 | __asm__ __volatile__( |
154 | "movl (%1), %0 ;\n" | |
155 | "subl $4, %2 ;\n" | |
156 | "jbe 2f ;\n" | |
157 | "addl 4(%1), %0 ;\n" | |
158 | "adcl 8(%1), %0 ;\n" | |
159 | "adcl 12(%1), %0 ;\n" | |
160 | "1: adcl 16(%1), %0 ;\n" | |
161 | "lea 4(%1), %1 ;\n" | |
162 | "decl %2 ;\n" | |
163 | "jne 1b ;\n" | |
164 | "adcl $0, %0 ;\n" | |
165 | "movl %0, %2 ;\n" | |
166 | "shrl $16, %0 ;\n" | |
167 | "addw %w2, %w0 ;\n" | |
168 | "adcl $0, %0 ;\n" | |
169 | "notl %0 ;\n" | |
170 | "2: ;\n" | |
4efd681a SE |
171 | /* Since the input registers which are loaded with iph and ipl |
172 | are modified, we must also specify them as outputs, or gcc | |
173 | will assume they contain their original values. */ | |
174 | : "=r" (sum), "=r" (iph), "=r" (ihl) | |
20d324b6 SE |
175 | : "1" (iph), "2" (ihl) |
176 | : "memory"); | |
4efd681a SE |
177 | return sum; |
178 | } | |
179 | #else | |
1caa23ff | 180 | static inline uint16_t ip_fast_csum(uint8_t *iph, int32_t ihl) |
2fe58dfd | 181 | { |
1caa23ff | 182 | assert(ihl < INT_MAX/4); |
4efd681a SE |
183 | return ip_csum(iph,ihl*4); |
184 | } | |
185 | #endif | |
186 | ||
187 | struct iphdr { | |
188 | #if defined (WORDS_BIGENDIAN) | |
189 | uint8_t version:4, | |
190 | ihl:4; | |
191 | #else | |
192 | uint8_t ihl:4, | |
193 | version:4; | |
194 | #endif | |
195 | uint8_t tos; | |
196 | uint16_t tot_len; | |
197 | uint16_t id; | |
198 | uint16_t frag_off; | |
199 | uint8_t ttl; | |
200 | uint8_t protocol; | |
201 | uint16_t check; | |
202 | uint32_t saddr; | |
203 | uint32_t daddr; | |
204 | /* The options start here. */ | |
205 | }; | |
206 | ||
207 | struct icmphdr { | |
208 | struct iphdr iph; | |
209 | uint8_t type; | |
210 | uint8_t code; | |
211 | uint16_t check; | |
212 | union { | |
213 | uint32_t unused; | |
214 | struct { | |
215 | uint8_t pointer; | |
216 | uint8_t unused1; | |
217 | uint16_t unused2; | |
218 | } pprob; | |
219 | uint32_t gwaddr; | |
220 | struct { | |
221 | uint16_t id; | |
222 | uint16_t seq; | |
223 | } echo; | |
224 | } d; | |
225 | }; | |
226 | ||
70dc107b SE |
227 | static void netlink_packet_deliver(struct netlink *st, |
228 | struct netlink_client *client, | |
229 | struct buffer_if *buf); | |
4efd681a | 230 | |
ff05a229 SE |
231 | /* XXX RFC1812 4.3.2.5: |
232 | All other ICMP error messages (Destination Unreachable, | |
233 | Redirect, Time Exceeded, and Parameter Problem) SHOULD have their | |
234 | precedence value set to 6 (INTERNETWORK CONTROL) or 7 (NETWORK | |
235 | CONTROL). The IP Precedence value for these error messages MAY be | |
236 | settable. | |
237 | */ | |
4efd681a SE |
238 | static struct icmphdr *netlink_icmp_tmpl(struct netlink *st, |
239 | uint32_t dest,uint16_t len) | |
240 | { | |
241 | struct icmphdr *h; | |
242 | ||
243 | BUF_ALLOC(&st->icmp,"netlink_icmp_tmpl"); | |
244 | buffer_init(&st->icmp,st->max_start_pad); | |
245 | h=buf_append(&st->icmp,sizeof(*h)); | |
246 | ||
247 | h->iph.version=4; | |
248 | h->iph.ihl=5; | |
249 | h->iph.tos=0; | |
250 | h->iph.tot_len=htons(len+(h->iph.ihl*4)+8); | |
251 | h->iph.id=0; | |
252 | h->iph.frag_off=0; | |
ff05a229 | 253 | h->iph.ttl=255; /* XXX should be configurable */ |
4efd681a SE |
254 | h->iph.protocol=1; |
255 | h->iph.saddr=htonl(st->secnet_address); | |
256 | h->iph.daddr=htonl(dest); | |
257 | h->iph.check=0; | |
258 | h->iph.check=ip_fast_csum((uint8_t *)&h->iph,h->iph.ihl); | |
259 | h->check=0; | |
260 | h->d.unused=0; | |
261 | ||
262 | return h; | |
263 | } | |
264 | ||
265 | /* Fill in the ICMP checksum field correctly */ | |
266 | static void netlink_icmp_csum(struct icmphdr *h) | |
267 | { | |
1caa23ff | 268 | int32_t len; |
4efd681a SE |
269 | |
270 | len=ntohs(h->iph.tot_len)-(4*h->iph.ihl); | |
271 | h->check=0; | |
272 | h->check=ip_csum(&h->type,len); | |
273 | } | |
274 | ||
275 | /* RFC1122: | |
276 | * An ICMP error message MUST NOT be sent as the result of | |
277 | * receiving: | |
278 | * | |
279 | * * an ICMP error message, or | |
280 | * | |
281 | * * a datagram destined to an IP broadcast or IP multicast | |
282 | * address, or | |
283 | * | |
284 | * * a datagram sent as a link-layer broadcast, or | |
285 | * | |
286 | * * a non-initial fragment, or | |
287 | * | |
288 | * * a datagram whose source address does not define a single | |
289 | * host -- e.g., a zero address, a loopback address, a | |
290 | * broadcast address, a multicast address, or a Class E | |
291 | * address. | |
292 | */ | |
293 | static bool_t netlink_icmp_may_reply(struct buffer_if *buf) | |
294 | { | |
295 | struct iphdr *iph; | |
8dea8d37 | 296 | struct icmphdr *icmph; |
4efd681a SE |
297 | uint32_t source; |
298 | ||
299 | iph=(struct iphdr *)buf->start; | |
8dea8d37 SE |
300 | icmph=(struct icmphdr *)buf->start; |
301 | if (iph->protocol==1) { | |
302 | switch(icmph->type) { | |
303 | case 3: /* Destination unreachable */ | |
304 | case 11: /* Time Exceeded */ | |
305 | case 12: /* Parameter Problem */ | |
306 | return False; | |
307 | } | |
308 | } | |
4efd681a SE |
309 | /* How do we spot broadcast destination addresses? */ |
310 | if (ntohs(iph->frag_off)&0x1fff) return False; /* Non-initial fragment */ | |
311 | source=ntohl(iph->saddr); | |
312 | if (source==0) return False; | |
313 | if ((source&0xff000000)==0x7f000000) return False; | |
314 | /* How do we spot broadcast source addresses? */ | |
315 | if ((source&0xf0000000)==0xe0000000) return False; /* Multicast */ | |
316 | if ((source&0xf0000000)==0xf0000000) return False; /* Class E */ | |
317 | return True; | |
318 | } | |
319 | ||
320 | /* How much of the original IP packet do we include in its ICMP | |
321 | response? The header plus up to 64 bits. */ | |
ff05a229 SE |
322 | |
323 | /* XXX TODO RFC1812: | |
324 | 4.3.2.3 Original Message Header | |
325 | ||
326 | Historically, every ICMP error message has included the Internet | |
327 | header and at least the first 8 data bytes of the datagram that | |
328 | triggered the error. This is no longer adequate, due to the use of | |
329 | IP-in-IP tunneling and other technologies. Therefore, the ICMP | |
330 | datagram SHOULD contain as much of the original datagram as possible | |
331 | without the length of the ICMP datagram exceeding 576 bytes. The | |
332 | returned IP header (and user data) MUST be identical to that which | |
333 | was received, except that the router is not required to undo any | |
334 | modifications to the IP header that are normally performed in | |
335 | forwarding that were performed before the error was detected (e.g., | |
336 | decrementing the TTL, or updating options). Note that the | |
337 | requirements of Section [4.3.3.5] supersede this requirement in some | |
338 | cases (i.e., for a Parameter Problem message, if the problem is in a | |
339 | modified field, the router must undo the modification). See Section | |
340 | [4.3.3.5]). | |
341 | */ | |
4efd681a SE |
342 | static uint16_t netlink_icmp_reply_len(struct buffer_if *buf) |
343 | { | |
344 | struct iphdr *iph=(struct iphdr *)buf->start; | |
345 | uint16_t hlen,plen; | |
346 | ||
347 | hlen=iph->ihl*4; | |
348 | /* We include the first 8 bytes of the packet data, provided they exist */ | |
349 | hlen+=8; | |
350 | plen=ntohs(iph->tot_len); | |
351 | return (hlen>plen?plen:hlen); | |
352 | } | |
353 | ||
70dc107b SE |
354 | /* client indicates where the packet we're constructing a response to |
355 | comes from. NULL indicates the host. */ | |
4efd681a | 356 | static void netlink_icmp_simple(struct netlink *st, struct buffer_if *buf, |
70dc107b | 357 | struct netlink_client *client, |
4efd681a SE |
358 | uint8_t type, uint8_t code) |
359 | { | |
360 | struct iphdr *iph=(struct iphdr *)buf->start; | |
361 | struct icmphdr *h; | |
362 | uint16_t len; | |
363 | ||
364 | if (netlink_icmp_may_reply(buf)) { | |
365 | len=netlink_icmp_reply_len(buf); | |
366 | h=netlink_icmp_tmpl(st,ntohl(iph->saddr),len); | |
367 | h->type=type; h->code=code; | |
368 | memcpy(buf_append(&st->icmp,len),buf->start,len); | |
369 | netlink_icmp_csum(h); | |
70dc107b | 370 | netlink_packet_deliver(st,NULL,&st->icmp); |
4efd681a SE |
371 | BUF_ASSERT_FREE(&st->icmp); |
372 | } | |
373 | } | |
374 | ||
375 | /* | |
376 | * RFC1122: 3.1.2.2 MUST silently discard any IP frame that fails the | |
377 | * checksum. | |
ff05a229 | 378 | * RFC1812: 4.2.2.5 MUST discard messages containing invalid checksums. |
4efd681a SE |
379 | * |
380 | * Is the datagram acceptable? | |
381 | * | |
382 | * 1. Length at least the size of an ip header | |
383 | * 2. Version of 4 | |
384 | * 3. Checksums correctly. | |
385 | * 4. Doesn't have a bogus length | |
386 | */ | |
d714da29 IJ |
387 | static bool_t netlink_check(struct netlink *st, struct buffer_if *buf, |
388 | char *errmsgbuf, int errmsgbuflen) | |
4efd681a | 389 | { |
d714da29 IJ |
390 | #define BAD(...) do{ \ |
391 | snprintf(errmsgbuf,errmsgbuflen,__VA_ARGS__); \ | |
392 | return False; \ | |
393 | }while(0) | |
394 | ||
4efd681a | 395 | struct iphdr *iph=(struct iphdr *)buf->start; |
1caa23ff | 396 | int32_t len; |
4efd681a | 397 | |
d714da29 IJ |
398 | if (iph->ihl < 5) BAD("ihl %u",iph->ihl); |
399 | if (iph->version != 4) BAD("version %u",iph->version); | |
400 | if (buf->size < iph->ihl*4) BAD("size %"PRId32"<%u*4",buf->size,iph->ihl); | |
401 | if (ip_fast_csum((uint8_t *)iph, iph->ihl)!=0) BAD("csum"); | |
4efd681a SE |
402 | len=ntohs(iph->tot_len); |
403 | /* There should be no padding */ | |
d714da29 IJ |
404 | if (buf->size!=len) BAD("len %"PRId32"!=%"PRId32,buf->size,len); |
405 | if (len<(iph->ihl<<2)) BAD("len %"PRId32"<(%u<<2)",len,iph->ihl); | |
4efd681a SE |
406 | /* XXX check that there's no source route specified */ |
407 | return True; | |
d714da29 IJ |
408 | |
409 | #undef BAD | |
4efd681a SE |
410 | } |
411 | ||
469fd1d9 | 412 | /* Deliver a packet. "client" is the _origin_ of the packet, not its |
d3fe100d SE |
413 | destination, and is NULL for packets from the host and packets |
414 | generated internally in secnet. */ | |
70dc107b SE |
415 | static void netlink_packet_deliver(struct netlink *st, |
416 | struct netlink_client *client, | |
417 | struct buffer_if *buf) | |
4efd681a SE |
418 | { |
419 | struct iphdr *iph=(struct iphdr *)buf->start; | |
420 | uint32_t dest=ntohl(iph->daddr); | |
70dc107b SE |
421 | uint32_t source=ntohl(iph->saddr); |
422 | uint32_t best_quality; | |
469fd1d9 SE |
423 | bool_t allow_route=False; |
424 | bool_t found_allowed=False; | |
70dc107b SE |
425 | int best_match; |
426 | int i; | |
2fe58dfd | 427 | |
4efd681a | 428 | BUF_ASSERT_USED(buf); |
2fe58dfd | 429 | |
4efd681a | 430 | if (dest==st->secnet_address) { |
4f5e39ec | 431 | Message(M_ERR,"%s: trying to deliver a packet to myself!\n",st->name); |
4efd681a | 432 | BUF_FREE(buf); |
2fe58dfd SE |
433 | return; |
434 | } | |
4efd681a | 435 | |
d3fe100d | 436 | /* Packets from the host (client==NULL) may always be routed. Packets |
469fd1d9 SE |
437 | from clients with the allow_route option will also be routed. */ |
438 | if (!client || (client && (client->options & OPT_ALLOWROUTE))) | |
439 | allow_route=True; | |
440 | ||
441 | /* If !allow_route, we check the routing table anyway, and if | |
442 | there's a suitable route with OPT_ALLOWROUTE set we use it. If | |
443 | there's a suitable route, but none with OPT_ALLOWROUTE set then | |
444 | we generate ICMP 'communication with destination network | |
445 | administratively prohibited'. */ | |
446 | ||
447 | best_quality=0; | |
448 | best_match=-1; | |
d3fe100d SE |
449 | for (i=0; i<st->n_clients; i++) { |
450 | if (st->routes[i]->up && | |
451 | ipset_contains_addr(st->routes[i]->networks,dest)) { | |
469fd1d9 SE |
452 | /* It's an available route to the correct destination. But is |
453 | it better than the one we already have? */ | |
454 | ||
455 | /* If we have already found an allowed route then we don't | |
456 | bother looking at routes we're not allowed to use. If | |
457 | we don't yet have an allowed route we'll consider any. */ | |
458 | if (!allow_route && found_allowed) { | |
d3fe100d | 459 | if (!(st->routes[i]->options&OPT_ALLOWROUTE)) continue; |
70dc107b | 460 | } |
469fd1d9 | 461 | |
d3fe100d | 462 | if (st->routes[i]->link_quality>best_quality |
469fd1d9 | 463 | || best_quality==0) { |
d3fe100d | 464 | best_quality=st->routes[i]->link_quality; |
469fd1d9 | 465 | best_match=i; |
d3fe100d | 466 | if (st->routes[i]->options&OPT_ALLOWROUTE) |
469fd1d9 SE |
467 | found_allowed=True; |
468 | /* If quality isn't perfect we may wish to | |
469 | consider kicking the tunnel with a 0-length | |
470 | packet to prompt it to perform a key setup. | |
471 | Then it'll eventually decide it's up or | |
472 | down. */ | |
473 | /* If quality is perfect and we're allowed to use the | |
474 | route we don't need to search any more. */ | |
475 | if (best_quality>=MAXIMUM_LINK_QUALITY && | |
476 | (allow_route || found_allowed)) break; | |
4efd681a | 477 | } |
70dc107b | 478 | } |
469fd1d9 SE |
479 | } |
480 | if (best_match==-1) { | |
481 | /* The packet's not going down a tunnel. It might (ought to) | |
482 | be for the host. */ | |
794f2398 | 483 | if (ipset_contains_addr(st->networks,dest)) { |
469fd1d9 SE |
484 | st->deliver_to_host(st->dst,buf); |
485 | st->outcount++; | |
70dc107b SE |
486 | BUF_ASSERT_FREE(buf); |
487 | } else { | |
469fd1d9 SE |
488 | string_t s,d; |
489 | s=ipaddr_to_string(source); | |
490 | d=ipaddr_to_string(dest); | |
ff05a229 | 491 | Message(M_DEBUG,"%s: don't know where to deliver packet " |
469fd1d9 SE |
492 | "(s=%s, d=%s)\n", st->name, s, d); |
493 | free(s); free(d); | |
ff05a229 SE |
494 | netlink_icmp_simple(st,buf,client,ICMP_TYPE_UNREACHABLE, |
495 | ICMP_CODE_NET_UNREACHABLE); | |
70dc107b | 496 | BUF_FREE(buf); |
2fe58dfd | 497 | } |
469fd1d9 SE |
498 | } else { |
499 | if (!allow_route && | |
d3fe100d | 500 | !(st->routes[best_match]->options&OPT_ALLOWROUTE)) { |
469fd1d9 SE |
501 | string_t s,d; |
502 | s=ipaddr_to_string(source); | |
503 | d=ipaddr_to_string(dest); | |
504 | /* We have a usable route but aren't allowed to use it. | |
505 | Generate ICMP destination unreachable: communication | |
506 | with destination network administratively prohibited */ | |
507 | Message(M_NOTICE,"%s: denied forwarding for packet (s=%s, d=%s)\n", | |
508 | st->name,s,d); | |
509 | free(s); free(d); | |
510 | ||
ff05a229 SE |
511 | netlink_icmp_simple(st,buf,client,ICMP_TYPE_UNREACHABLE, |
512 | ICMP_CODE_NET_PROHIBITED); | |
469fd1d9 | 513 | BUF_FREE(buf); |
469fd1d9 | 514 | } else { |
ea7ec970 SE |
515 | if (best_quality>0) { |
516 | /* XXX Fragment if required */ | |
517 | st->routes[best_match]->deliver( | |
518 | st->routes[best_match]->dst, buf); | |
519 | st->routes[best_match]->outcount++; | |
520 | BUF_ASSERT_FREE(buf); | |
521 | } else { | |
522 | /* Generate ICMP destination unreachable */ | |
523 | netlink_icmp_simple(st,buf,client,ICMP_TYPE_UNREACHABLE, | |
524 | ICMP_CODE_NET_UNREACHABLE); /* client==NULL */ | |
525 | BUF_FREE(buf); | |
526 | } | |
469fd1d9 | 527 | } |
2fe58dfd | 528 | } |
70dc107b | 529 | BUF_ASSERT_FREE(buf); |
4efd681a SE |
530 | } |
531 | ||
70dc107b SE |
532 | static void netlink_packet_forward(struct netlink *st, |
533 | struct netlink_client *client, | |
534 | struct buffer_if *buf) | |
4efd681a SE |
535 | { |
536 | struct iphdr *iph=(struct iphdr *)buf->start; | |
537 | ||
538 | BUF_ASSERT_USED(buf); | |
539 | ||
540 | /* Packet has already been checked */ | |
541 | if (iph->ttl<=1) { | |
542 | /* Generate ICMP time exceeded */ | |
ff05a229 SE |
543 | netlink_icmp_simple(st,buf,client,ICMP_TYPE_TIME_EXCEEDED, |
544 | ICMP_CODE_TTL_EXCEEDED); | |
4efd681a SE |
545 | BUF_FREE(buf); |
546 | return; | |
547 | } | |
548 | iph->ttl--; | |
549 | iph->check=0; | |
550 | iph->check=ip_fast_csum((uint8_t *)iph,iph->ihl); | |
551 | ||
70dc107b | 552 | netlink_packet_deliver(st,client,buf); |
4efd681a SE |
553 | BUF_ASSERT_FREE(buf); |
554 | } | |
555 | ||
9d3a4132 | 556 | /* Deal with packets addressed explicitly to us */ |
70dc107b SE |
557 | static void netlink_packet_local(struct netlink *st, |
558 | struct netlink_client *client, | |
559 | struct buffer_if *buf) | |
4efd681a SE |
560 | { |
561 | struct icmphdr *h; | |
562 | ||
469fd1d9 SE |
563 | st->localcount++; |
564 | ||
4efd681a SE |
565 | h=(struct icmphdr *)buf->start; |
566 | ||
567 | if ((ntohs(h->iph.frag_off)&0xbfff)!=0) { | |
9d3a4132 SE |
568 | Message(M_WARNING,"%s: fragmented packet addressed to secnet; " |
569 | "ignoring it\n",st->name); | |
4efd681a SE |
570 | BUF_FREE(buf); |
571 | return; | |
572 | } | |
573 | ||
574 | if (h->iph.protocol==1) { | |
575 | /* It's ICMP */ | |
ff05a229 | 576 | if (h->type==ICMP_TYPE_ECHO_REQUEST && h->code==0) { |
4efd681a SE |
577 | /* ICMP echo-request. Special case: we re-use the buffer |
578 | to construct the reply. */ | |
ff05a229 | 579 | h->type=ICMP_TYPE_ECHO_REPLY; |
4efd681a SE |
580 | h->iph.daddr=h->iph.saddr; |
581 | h->iph.saddr=htonl(st->secnet_address); | |
ff05a229 | 582 | h->iph.ttl=255; |
4efd681a SE |
583 | h->iph.check=0; |
584 | h->iph.check=ip_fast_csum((uint8_t *)h,h->iph.ihl); | |
585 | netlink_icmp_csum(h); | |
70dc107b | 586 | netlink_packet_deliver(st,NULL,buf); |
4efd681a SE |
587 | return; |
588 | } | |
589 | Message(M_WARNING,"%s: unknown incoming ICMP\n",st->name); | |
590 | } else { | |
591 | /* Send ICMP protocol unreachable */ | |
ff05a229 SE |
592 | netlink_icmp_simple(st,buf,client,ICMP_TYPE_UNREACHABLE, |
593 | ICMP_CODE_PROTOCOL_UNREACHABLE); | |
4efd681a SE |
594 | BUF_FREE(buf); |
595 | return; | |
596 | } | |
597 | ||
598 | BUF_FREE(buf); | |
599 | } | |
600 | ||
9d3a4132 SE |
601 | /* If cid==NULL packet is from host, otherwise cid specifies which tunnel |
602 | it came from. */ | |
469fd1d9 SE |
603 | static void netlink_incoming(struct netlink *st, struct netlink_client *client, |
604 | struct buffer_if *buf) | |
4efd681a | 605 | { |
4efd681a SE |
606 | uint32_t source,dest; |
607 | struct iphdr *iph; | |
d714da29 | 608 | char errmsgbuf[50]; |
4efd681a SE |
609 | |
610 | BUF_ASSERT_USED(buf); | |
d714da29 IJ |
611 | if (!netlink_check(st,buf,errmsgbuf,sizeof(errmsgbuf))) { |
612 | Message(M_WARNING,"%s: bad IP packet from %s: %s\n", | |
613 | st->name,client?client->name:"host", | |
614 | errmsgbuf); | |
4efd681a SE |
615 | BUF_FREE(buf); |
616 | return; | |
617 | } | |
618 | iph=(struct iphdr *)buf->start; | |
619 | ||
620 | source=ntohl(iph->saddr); | |
621 | dest=ntohl(iph->daddr); | |
622 | ||
d3fe100d SE |
623 | /* Check source. If we don't like the source, there's no point |
624 | generating ICMP because we won't know how to get it to the | |
625 | source of the packet. */ | |
9d3a4132 | 626 | if (client) { |
c6f79b17 SE |
627 | /* Check that the packet source is appropriate for the tunnel |
628 | it came down */ | |
794f2398 | 629 | if (!ipset_contains_addr(client->networks,source)) { |
9d3a4132 SE |
630 | string_t s,d; |
631 | s=ipaddr_to_string(source); | |
632 | d=ipaddr_to_string(dest); | |
633 | Message(M_WARNING,"%s: packet from tunnel %s with bad " | |
634 | "source address (s=%s,d=%s)\n",st->name,client->name,s,d); | |
635 | free(s); free(d); | |
636 | BUF_FREE(buf); | |
637 | return; | |
638 | } | |
639 | } else { | |
c6f79b17 SE |
640 | /* Check that the packet originates in our configured local |
641 | network, and hasn't been forwarded from elsewhere or | |
642 | generated with the wrong source address */ | |
794f2398 | 643 | if (!ipset_contains_addr(st->networks,source)) { |
9d3a4132 SE |
644 | string_t s,d; |
645 | s=ipaddr_to_string(source); | |
646 | d=ipaddr_to_string(dest); | |
647 | Message(M_WARNING,"%s: outgoing packet with bad source address " | |
648 | "(s=%s,d=%s)\n",st->name,s,d); | |
649 | free(s); free(d); | |
650 | BUF_FREE(buf); | |
651 | return; | |
652 | } | |
4efd681a | 653 | } |
c6f79b17 | 654 | |
794f2398 SE |
655 | /* If this is a point-to-point device we don't examine the |
656 | destination address at all; we blindly send it down our | |
657 | one-and-only registered tunnel, or to the host, depending on | |
d3fe100d SE |
658 | where it came from. It's up to external software to check |
659 | address validity and generate ICMP, etc. */ | |
c6f79b17 SE |
660 | if (st->ptp) { |
661 | if (client) { | |
469fd1d9 | 662 | st->deliver_to_host(st->dst,buf); |
c6f79b17 | 663 | } else { |
469fd1d9 | 664 | st->clients->deliver(st->clients->dst,buf); |
c6f79b17 SE |
665 | } |
666 | BUF_ASSERT_FREE(buf); | |
667 | return; | |
668 | } | |
669 | ||
d3fe100d SE |
670 | /* st->secnet_address needs checking before matching destination |
671 | addresses */ | |
2fe58dfd | 672 | if (dest==st->secnet_address) { |
9d3a4132 | 673 | netlink_packet_local(st,client,buf); |
4efd681a | 674 | BUF_ASSERT_FREE(buf); |
2fe58dfd SE |
675 | return; |
676 | } | |
70dc107b | 677 | netlink_packet_forward(st,client,buf); |
4efd681a SE |
678 | BUF_ASSERT_FREE(buf); |
679 | } | |
680 | ||
469fd1d9 SE |
681 | static void netlink_inst_incoming(void *sst, struct buffer_if *buf) |
682 | { | |
683 | struct netlink_client *c=sst; | |
684 | struct netlink *st=c->nst; | |
685 | ||
686 | netlink_incoming(st,c,buf); | |
687 | } | |
688 | ||
689 | static void netlink_dev_incoming(void *sst, struct buffer_if *buf) | |
690 | { | |
691 | struct netlink *st=sst; | |
692 | ||
693 | netlink_incoming(st,NULL,buf); | |
694 | } | |
695 | ||
d3fe100d | 696 | static void netlink_set_quality(void *sst, uint32_t quality) |
4efd681a | 697 | { |
d3fe100d SE |
698 | struct netlink_client *c=sst; |
699 | struct netlink *st=c->nst; | |
4efd681a | 700 | |
d3fe100d SE |
701 | c->link_quality=quality; |
702 | c->up=(c->link_quality==LINK_QUALITY_DOWN)?False:True; | |
703 | if (c->options&OPT_SOFTROUTE) { | |
704 | st->set_routes(st->dst,c); | |
4efd681a | 705 | } |
4efd681a SE |
706 | } |
707 | ||
d3fe100d SE |
708 | static void netlink_output_subnets(struct netlink *st, uint32_t loglevel, |
709 | struct subnet_list *snets) | |
4efd681a | 710 | { |
1caa23ff | 711 | int32_t i; |
d3fe100d | 712 | string_t net; |
4efd681a | 713 | |
d3fe100d SE |
714 | for (i=0; i<snets->entries; i++) { |
715 | net=subnet_to_string(snets->list[i]); | |
716 | Message(loglevel,"%s ",net); | |
717 | free(net); | |
9d3a4132 | 718 | } |
4efd681a SE |
719 | } |
720 | ||
042a8da9 | 721 | static void netlink_dump_routes(struct netlink *st, bool_t requested) |
9d3a4132 SE |
722 | { |
723 | int i; | |
724 | string_t net; | |
042a8da9 | 725 | uint32_t c=M_INFO; |
9d3a4132 | 726 | |
042a8da9 | 727 | if (requested) c=M_WARNING; |
469fd1d9 SE |
728 | if (st->ptp) { |
729 | net=ipaddr_to_string(st->secnet_address); | |
730 | Message(c,"%s: point-to-point (remote end is %s); routes:\n", | |
731 | st->name, net); | |
9d3a4132 | 732 | free(net); |
d3fe100d | 733 | netlink_output_subnets(st,c,st->clients->subnets); |
469fd1d9 SE |
734 | Message(c,"\n"); |
735 | } else { | |
736 | Message(c,"%s: routing table:\n",st->name); | |
d3fe100d SE |
737 | for (i=0; i<st->n_clients; i++) { |
738 | netlink_output_subnets(st,c,st->routes[i]->subnets); | |
ff05a229 | 739 | Message(c,"-> tunnel %s (%s,mtu %d,%s routes,%s," |
ea7ec970 | 740 | "quality %d,use %d,pri %lu)\n", |
d3fe100d | 741 | st->routes[i]->name, |
ff05a229 SE |
742 | st->routes[i]->up?"up":"down", |
743 | st->routes[i]->mtu, | |
d3fe100d SE |
744 | st->routes[i]->options&OPT_SOFTROUTE?"soft":"hard", |
745 | st->routes[i]->options&OPT_ALLOWROUTE?"free":"restricted", | |
d3fe100d | 746 | st->routes[i]->link_quality, |
ea7ec970 SE |
747 | st->routes[i]->outcount, |
748 | (unsigned long)st->routes[i]->priority); | |
469fd1d9 SE |
749 | } |
750 | net=ipaddr_to_string(st->secnet_address); | |
751 | Message(c,"%s/32 -> netlink \"%s\" (use %d)\n", | |
752 | net,st->name,st->localcount); | |
9d3a4132 | 753 | free(net); |
794f2398 SE |
754 | for (i=0; i<st->subnets->entries; i++) { |
755 | net=subnet_to_string(st->subnets->list[i]); | |
756 | Message(c,"%s ",net); | |
469fd1d9 SE |
757 | free(net); |
758 | } | |
794f2398 SE |
759 | if (i>0) |
760 | Message(c,"-> host (use %d)\n",st->outcount); | |
9d3a4132 SE |
761 | } |
762 | } | |
763 | ||
d3fe100d SE |
764 | /* ap is a pointer to a member of the routes array */ |
765 | static int netlink_compare_client_priority(const void *ap, const void *bp) | |
70dc107b | 766 | { |
d3fe100d SE |
767 | const struct netlink_client *const*a=ap; |
768 | const struct netlink_client *const*b=bp; | |
70dc107b | 769 | |
d3fe100d SE |
770 | if ((*a)->priority==(*b)->priority) return 0; |
771 | if ((*a)->priority<(*b)->priority) return 1; | |
70dc107b SE |
772 | return -1; |
773 | } | |
774 | ||
775 | static void netlink_phase_hook(void *sst, uint32_t new_phase) | |
776 | { | |
777 | struct netlink *st=sst; | |
778 | struct netlink_client *c; | |
1caa23ff | 779 | int32_t i; |
70dc107b SE |
780 | |
781 | /* All the networks serviced by the various tunnels should now | |
782 | * have been registered. We build a routing table by sorting the | |
d3fe100d | 783 | * clients by priority. */ |
bb9d0561 IJ |
784 | st->routes=safe_malloc_ary(sizeof(*st->routes),st->n_clients, |
785 | "netlink_phase_hook"); | |
70dc107b SE |
786 | /* Fill the table */ |
787 | i=0; | |
59230b9b IJ |
788 | for (c=st->clients; c; c=c->next) { |
789 | assert(i<INT_MAX); | |
d3fe100d | 790 | st->routes[i++]=c; |
59230b9b | 791 | } |
d3fe100d SE |
792 | /* Sort the table in descending order of priority */ |
793 | qsort(st->routes,st->n_clients,sizeof(*st->routes), | |
794 | netlink_compare_client_priority); | |
9d3a4132 | 795 | |
042a8da9 SE |
796 | netlink_dump_routes(st,False); |
797 | } | |
798 | ||
799 | static void netlink_signal_handler(void *sst, int signum) | |
800 | { | |
801 | struct netlink *st=sst; | |
802 | Message(M_INFO,"%s: route dump requested by SIGUSR1\n",st->name); | |
803 | netlink_dump_routes(st,True); | |
70dc107b SE |
804 | } |
805 | ||
1caa23ff | 806 | static void netlink_inst_set_mtu(void *sst, int32_t new_mtu) |
d3fe100d SE |
807 | { |
808 | struct netlink_client *c=sst; | |
809 | ||
810 | c->mtu=new_mtu; | |
811 | } | |
812 | ||
469fd1d9 | 813 | static void netlink_inst_reg(void *sst, netlink_deliver_fn *deliver, |
1caa23ff IJ |
814 | void *dst, int32_t max_start_pad, |
815 | int32_t max_end_pad) | |
469fd1d9 SE |
816 | { |
817 | struct netlink_client *c=sst; | |
818 | struct netlink *st=c->nst; | |
819 | ||
820 | if (max_start_pad > st->max_start_pad) st->max_start_pad=max_start_pad; | |
821 | if (max_end_pad > st->max_end_pad) st->max_end_pad=max_end_pad; | |
822 | c->deliver=deliver; | |
823 | c->dst=dst; | |
824 | } | |
825 | ||
826 | static struct flagstr netlink_option_table[]={ | |
827 | { "soft", OPT_SOFTROUTE }, | |
828 | { "allow-route", OPT_ALLOWROUTE }, | |
829 | { NULL, 0} | |
830 | }; | |
831 | /* This is the routine that gets called when the closure that's | |
832 | returned by an invocation of a netlink device closure (eg. tun, | |
833 | userv-ipif) is invoked. It's used to create routes and pass in | |
834 | information about them; the closure it returns is used by site | |
835 | code. */ | |
836 | static closure_t *netlink_inst_create(struct netlink *st, | |
837 | struct cloc loc, dict_t *dict) | |
838 | { | |
839 | struct netlink_client *c; | |
840 | string_t name; | |
794f2398 | 841 | struct ipset *networks; |
1caa23ff IJ |
842 | uint32_t options,priority; |
843 | int32_t mtu; | |
794f2398 | 844 | list_t *l; |
469fd1d9 SE |
845 | |
846 | name=dict_read_string(dict, "name", True, st->name, loc); | |
847 | ||
794f2398 SE |
848 | l=dict_lookup(dict,"routes"); |
849 | if (!l) | |
850 | cfgfatal(loc,st->name,"required parameter \"routes\" not found\n"); | |
851 | networks=string_list_to_ipset(l,loc,st->name,"routes"); | |
469fd1d9 SE |
852 | options=string_list_to_word(dict_lookup(dict,"options"), |
853 | netlink_option_table,st->name); | |
854 | ||
d3fe100d SE |
855 | priority=dict_read_number(dict,"priority",False,st->name,loc,0); |
856 | mtu=dict_read_number(dict,"mtu",False,st->name,loc,0); | |
857 | ||
858 | if ((options&OPT_SOFTROUTE) && !st->set_routes) { | |
469fd1d9 SE |
859 | cfgfatal(loc,st->name,"this netlink device does not support " |
860 | "soft routes.\n"); | |
861 | return NULL; | |
862 | } | |
863 | ||
864 | if (options&OPT_SOFTROUTE) { | |
865 | /* XXX for now we assume that soft routes require root privilege; | |
866 | this may not always be true. The device driver can tell us. */ | |
867 | require_root_privileges=True; | |
868 | require_root_privileges_explanation="netlink: soft routes"; | |
869 | if (st->ptp) { | |
870 | cfgfatal(loc,st->name,"point-to-point netlinks do not support " | |
871 | "soft routes.\n"); | |
872 | return NULL; | |
873 | } | |
874 | } | |
875 | ||
794f2398 SE |
876 | /* Check that nets are a subset of st->remote_networks; |
877 | refuse to register if they are not. */ | |
878 | if (!ipset_is_subset(st->remote_networks,networks)) { | |
879 | cfgfatal(loc,st->name,"routes are not allowed\n"); | |
469fd1d9 SE |
880 | return NULL; |
881 | } | |
882 | ||
883 | c=safe_malloc(sizeof(*c),"netlink_inst_create"); | |
884 | c->cl.description=name; | |
885 | c->cl.type=CL_NETLINK; | |
886 | c->cl.apply=NULL; | |
887 | c->cl.interface=&c->ops; | |
888 | c->ops.st=c; | |
889 | c->ops.reg=netlink_inst_reg; | |
890 | c->ops.deliver=netlink_inst_incoming; | |
891 | c->ops.set_quality=netlink_set_quality; | |
d3fe100d | 892 | c->ops.set_mtu=netlink_inst_set_mtu; |
469fd1d9 SE |
893 | c->nst=st; |
894 | ||
895 | c->networks=networks; | |
794f2398 | 896 | c->subnets=ipset_to_subnet_list(networks); |
d3fe100d | 897 | c->priority=priority; |
469fd1d9 SE |
898 | c->deliver=NULL; |
899 | c->dst=NULL; | |
900 | c->name=name; | |
f208b9a9 | 901 | c->link_quality=LINK_QUALITY_UNUSED; |
d3fe100d SE |
902 | c->mtu=mtu?mtu:st->mtu; |
903 | c->options=options; | |
904 | c->outcount=0; | |
905 | c->up=False; | |
906 | c->kup=False; | |
469fd1d9 SE |
907 | c->next=st->clients; |
908 | st->clients=c; | |
59230b9b | 909 | assert(st->n_clients < INT_MAX); |
d3fe100d | 910 | st->n_clients++; |
469fd1d9 SE |
911 | |
912 | return &c->cl; | |
913 | } | |
914 | ||
915 | static list_t *netlink_inst_apply(closure_t *self, struct cloc loc, | |
916 | dict_t *context, list_t *args) | |
917 | { | |
918 | struct netlink *st=self->interface; | |
919 | ||
920 | dict_t *dict; | |
921 | item_t *item; | |
922 | closure_t *cl; | |
923 | ||
469fd1d9 SE |
924 | item=list_elem(args,0); |
925 | if (!item || item->type!=t_dict) { | |
926 | cfgfatal(loc,st->name,"must have a dictionary argument\n"); | |
927 | } | |
928 | dict=item->data.dict; | |
929 | ||
930 | cl=netlink_inst_create(st,loc,dict); | |
931 | ||
932 | return new_closure(cl); | |
933 | } | |
934 | ||
9d3a4132 SE |
935 | netlink_deliver_fn *netlink_init(struct netlink *st, |
936 | void *dst, struct cloc loc, | |
fe5e9cc4 | 937 | dict_t *dict, cstring_t description, |
d3fe100d | 938 | netlink_route_fn *set_routes, |
9d3a4132 | 939 | netlink_deliver_fn *to_host) |
4efd681a | 940 | { |
c6f79b17 | 941 | item_t *sa, *ptpa; |
794f2398 | 942 | list_t *l; |
c6f79b17 | 943 | |
4efd681a SE |
944 | st->dst=dst; |
945 | st->cl.description=description; | |
469fd1d9 SE |
946 | st->cl.type=CL_PURE; |
947 | st->cl.apply=netlink_inst_apply; | |
948 | st->cl.interface=st; | |
4efd681a SE |
949 | st->max_start_pad=0; |
950 | st->max_end_pad=0; | |
951 | st->clients=NULL; | |
d3fe100d SE |
952 | st->routes=NULL; |
953 | st->n_clients=0; | |
954 | st->set_routes=set_routes; | |
4efd681a SE |
955 | st->deliver_to_host=to_host; |
956 | ||
794f2398 | 957 | st->name=dict_read_string(dict,"name",False,description,loc); |
4efd681a | 958 | if (!st->name) st->name=description; |
794f2398 SE |
959 | l=dict_lookup(dict,"networks"); |
960 | if (l) | |
961 | st->networks=string_list_to_ipset(l,loc,st->name,"networks"); | |
962 | else { | |
4f5e39ec SE |
963 | struct ipset *empty; |
964 | empty=ipset_new(); | |
965 | st->networks=ipset_complement(empty); | |
966 | ipset_free(empty); | |
794f2398 SE |
967 | } |
968 | l=dict_lookup(dict,"remote-networks"); | |
969 | if (l) { | |
970 | st->remote_networks=string_list_to_ipset(l,loc,st->name, | |
971 | "remote-networks"); | |
972 | } else { | |
973 | struct ipset *empty; | |
974 | empty=ipset_new(); | |
975 | st->remote_networks=ipset_complement(empty); | |
976 | ipset_free(empty); | |
977 | } | |
978 | ||
c6f79b17 | 979 | sa=dict_find_item(dict,"secnet-address",False,"netlink",loc); |
469fd1d9 | 980 | ptpa=dict_find_item(dict,"ptp-address",False,"netlink",loc); |
c6f79b17 SE |
981 | if (sa && ptpa) { |
982 | cfgfatal(loc,st->name,"you may not specify secnet-address and " | |
983 | "ptp-address in the same netlink device\n"); | |
984 | } | |
985 | if (!(sa || ptpa)) { | |
986 | cfgfatal(loc,st->name,"you must specify secnet-address or " | |
987 | "ptp-address for this netlink device\n"); | |
988 | } | |
989 | if (sa) { | |
794f2398 | 990 | st->secnet_address=string_item_to_ipaddr(sa,"netlink"); |
c6f79b17 SE |
991 | st->ptp=False; |
992 | } else { | |
794f2398 | 993 | st->secnet_address=string_item_to_ipaddr(ptpa,"netlink"); |
c6f79b17 SE |
994 | st->ptp=True; |
995 | } | |
d3fe100d SE |
996 | /* To be strictly correct we could subtract secnet_address from |
997 | networks here. It shouldn't make any practical difference, | |
794f2398 SE |
998 | though, and will make the route dump look complicated... */ |
999 | st->subnets=ipset_to_subnet_list(st->networks); | |
4efd681a SE |
1000 | st->mtu=dict_read_number(dict, "mtu", False, "netlink", loc, DEFAULT_MTU); |
1001 | buffer_new(&st->icmp,ICMP_BUFSIZE); | |
469fd1d9 SE |
1002 | st->outcount=0; |
1003 | st->localcount=0; | |
70dc107b SE |
1004 | |
1005 | add_hook(PHASE_SETUP,netlink_phase_hook,st); | |
042a8da9 | 1006 | request_signal_notification(SIGUSR1, netlink_signal_handler, st); |
4efd681a | 1007 | |
469fd1d9 SE |
1008 | /* If we're point-to-point then we return a CL_NETLINK directly, |
1009 | rather than a CL_NETLINK_OLD or pure closure (depending on | |
1010 | compatibility). This CL_NETLINK is for our one and only | |
1011 | client. Our cl.apply function is NULL. */ | |
1012 | if (st->ptp) { | |
1013 | closure_t *cl; | |
1014 | cl=netlink_inst_create(st,loc,dict); | |
1015 | st->cl=*cl; | |
1016 | } | |
1017 | return netlink_dev_incoming; | |
2fe58dfd SE |
1018 | } |
1019 | ||
9d3a4132 | 1020 | /* No connection to the kernel at all... */ |
2fe58dfd | 1021 | |
9d3a4132 | 1022 | struct null { |
4efd681a | 1023 | struct netlink nl; |
4efd681a | 1024 | }; |
2fe58dfd | 1025 | |
d3fe100d | 1026 | static bool_t null_set_route(void *sst, struct netlink_client *routes) |
4efd681a | 1027 | { |
9d3a4132 | 1028 | struct null *st=sst; |
d3fe100d SE |
1029 | |
1030 | if (routes->up!=routes->kup) { | |
1031 | Message(M_INFO,"%s: setting routes for tunnel %s to state %s\n", | |
1032 | st->nl.name,routes->name, | |
1033 | routes->up?"up":"down"); | |
1034 | routes->kup=routes->up; | |
9d3a4132 | 1035 | return True; |
2fe58dfd | 1036 | } |
9d3a4132 | 1037 | return False; |
2fe58dfd | 1038 | } |
9d3a4132 | 1039 | |
469fd1d9 | 1040 | static void null_deliver(void *sst, struct buffer_if *buf) |
2fe58dfd SE |
1041 | { |
1042 | return; | |
1043 | } | |
1044 | ||
1045 | static list_t *null_apply(closure_t *self, struct cloc loc, dict_t *context, | |
1046 | list_t *args) | |
1047 | { | |
1048 | struct null *st; | |
4efd681a SE |
1049 | item_t *item; |
1050 | dict_t *dict; | |
2fe58dfd | 1051 | |
4efd681a | 1052 | st=safe_malloc(sizeof(*st),"null_apply"); |
2fe58dfd | 1053 | |
4efd681a SE |
1054 | item=list_elem(args,0); |
1055 | if (!item || item->type!=t_dict) | |
1056 | cfgfatal(loc,"null-netlink","parameter must be a dictionary\n"); | |
1057 | ||
1058 | dict=item->data.dict; | |
1059 | ||
9d3a4132 SE |
1060 | netlink_init(&st->nl,st,loc,dict,"null-netlink",null_set_route, |
1061 | null_deliver); | |
4efd681a SE |
1062 | |
1063 | return new_closure(&st->nl.cl); | |
2fe58dfd SE |
1064 | } |
1065 | ||
2fe58dfd SE |
1066 | void netlink_module(dict_t *dict) |
1067 | { | |
4efd681a | 1068 | add_closure(dict,"null-netlink",null_apply); |
2fe58dfd | 1069 | } |