[ViewVC] Diff of: cvs/gvpe/src/vpn

Comparing gvpe/src/vpn_dns.C (file contents):
Revision 1.19 by pcg, Sun Mar 6 18:34:46 2005 UTC vs.
Revision 1.51 by root, Sun Mar 6 19:40:28 2011 UTC

…		…
1	/*	1	/*
2	vpn_dns.C -- handle the dns tunnel part of the protocol.	2	vpn_dns.C -- handle the dns tunnel part of the protocol.
3	Copyright (C) 2003-2005 Marc Lehmann <gvpe@schmorp.de>	3	Copyright (C) 2003-2011 Marc Lehmann <gvpe@schmorp.de>
4		4
5	This file is part of GVPE.	5	This file is part of GVPE.
6		6
7	GVPE is free software; you can redistribute it and/or modify	7	GVPE is free software; you can redistribute it and/or modify it
8	it under the terms of the GNU General Public License as published by	8	under the terms of the GNU General Public License as published by the
9	the Free Software Foundation; either version 2 of the License, or	9	Free Software Foundation; either version 3 of the License, or (at your
10	(at your option) any later version.	10	option) any later version.
11		11
12	This program is distributed in the hope that it will be useful,	12	This program is distributed in the hope that it will be useful, but
13	but WITHOUT ANY WARRANTY; without even the implied warranty of	13	WITHOUT ANY WARRANTY; without even the implied warranty of
14	MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the	14	MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General
15	GNU General Public License for more details.	15	Public License for more details.
16		16
17	You should have received a copy of the GNU General Public License	17	You should have received a copy of the GNU General Public License along
18	along with gvpe; if not, write to the Free Software	18	with this program; if not, see <http://www.gnu.org/licenses/>.
19	Foundation, Inc. 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA	19
		20	Additional permission under GNU GPL version 3 section 7
		21
		22	If you modify this Program, or any covered work, by linking or
		23	combining it with the OpenSSL project's OpenSSL library (or a modified
		24	version of that library), containing parts covered by the terms of the
		25	OpenSSL or SSLeay licenses, the licensors of this Program grant you
		26	additional permission to convey the resulting work. Corresponding
		27	Source for a non-source form of such a combination shall include the
		28	source code for the parts of OpenSSL used as well as that of the
		29	covered work.
20	*/	30	*/
		31
		32	// TODO: EDNS0 option to increase dns mtu?
		33	// TODO: re-write dns packet parsing/creation using a safe mem-buffer
		34	// to ensure no buffer overflows or similar problems.
21		35
22	#include "config.h"	36	#include "config.h"
23		37
24	#if ENABLE_DNS	38	#if ENABLE_DNS
25		39
26	// dns processing is EXTREMELY ugly. For obvious(?) reasons.	40	// dns processing is EXTREMELY ugly. For obvious(?) reasons.
27	// it's a hack, use only in emergency situations please.	41	// it's a hack, use only in emergency situations please.
28		42
29	#include <cstring>	43	#include <cstring>
		44	#include <cassert>
30		45
31	#include <sys/types.h>	46	#include <sys/types.h>
32	#include <sys/socket.h>	47	#include <sys/socket.h>
33	#include <sys/wait.h>	48	#include <sys/wait.h>
34	#include <sys/uio.h>	49	#include <sys/uio.h>
37	#include <unistd.h>	52	#include <unistd.h>
38	#include <fcntl.h>	53	#include <fcntl.h>
39		54
40	#include <map>	55	#include <map>
41		56
		57	#include <cstdio> /* bug in libgmp: gmp.h relies on cstdio being included */
42	#include <gmp.h>	58	#include <gmp.h>
43		59
44	#include "netcompat.h"	60	#include "netcompat.h"
45		61
46	#include "vpn.h"	62	#include "vpn.h"
47		63
48	#define MIN_POLL_INTERVAL .02 // how often to poll minimally when the server has data	64	#define MIN_POLL_INTERVAL 0.1 // poll at most this often when no data received
49	#define MAX_POLL_INTERVAL 6. // how often to poll minimally when the server has no data	65	#define MAX_POLL_INTERVAL 1. // how often to poll minimally when the server has no data
50	#define ACTIVITY_INTERVAL 5.
51		66
52	#define INITIAL_TIMEOUT 0.1 // retry timeouts	67	#define INITIAL_TIMEOUT 0.1 // retry timeouts
53	#define INITIAL_SYN_TIMEOUT 10. // retry timeout for initial syn	68	#define INITIAL_SYN_TIMEOUT 2. // retry timeout for initial syn
54		69
55	#define MIN_SEND_INTERVAL 0.01 // wait at least this time between sending requests
56	#define MAX_SEND_INTERVAL 0.5 // optimistic?	70	#define MAX_SEND_INTERVAL 2. // optimistic?
57		71
58	#define MAX_OUTSTANDING 10 // max. outstanding requests
59	#define MAX_WINDOW 1000 // max. for MAX_OUTSTANDING, and backlog	72	#define MAX_WINDOW 1000 // max. for MAX_OUTSTANDING, and backlog
60	#define MAX_BACKLOG (100*1024) // size of gvpe protocol backlog (bytes), must be > MAXSIZE	73	#define MAX_BACKLOG (64*1024) // size of gvpe protocol backlog (bytes), must be > MAXSIZE
61		74
62	#define MAX_DOMAIN_SIZE 220 // 255 is legal limit, but bind doesn't compress well	75	#define MAX_DOMAIN_SIZE 240 // 255 is legal limit, but bind doesn't compress well
63	// 240 leaves about 4 bytes of server reply data	76	// 240 leaves about 4 bytes of server reply data
64	// every two request bytes less give room for one reply byte	77	// every request byte less give room for two reply bytes
65		78
66	#define SEQNO_MASK 0x3fff	79	#define SEQNO_MASK 0x3fff
67	#define SEQNO_EQ(a,b) ( 0 == ( ((a) ^ (b)) & SEQNO_MASK) )	80	#define SEQNO_EQ(a,b) ( 0 == ( ((a) ^ (b)) & SEQNO_MASK) )
68		81
69	#define MAX_LBL_SIZE 63	82	#define MAX_LBL_SIZE 63
70	#define MAX_PKT_SIZE 512	83	#define MAX_PKT_SIZE 512
71		84
72	#define RR_TYPE_A 1	85	#define RR_TYPE_A 1
73	#define RR_TYPE_NULL 10	86	#define RR_TYPE_NULL 10
74	#define RR_TYPE_TXT 16	87	#define RR_TYPE_TXT 16
		88	#define RR_TYPE_AAAA 28
75	#define RR_TYPE_ANY 255	89	#define RR_TYPE_ANY 255
76		90
77	#define RR_CLASS_IN 1	91	#define RR_CLASS_IN 1
78		92
79	#define CMD_IP_1 207	93	#define CMD_IP_1 207
80	#define CMD_IP_2 46	94	#define CMD_IP_2 46
81	#define CMD_IP_3 236	95	#define CMD_IP_3 236
82	#define CMD_IP_RST 29	96
83	#define CMD_IP_SYN 113	97	#define CMD_IP_RST 29 // some error, reset and retry
84	#define CMD_IP_REJ 32	98	#define CMD_IP_REJ 32 // do not want you
		99	#define CMD_IP_SYN 113 // connection established
		100	#define CMD_IP_CSE 213 // connection established, but likely case mismatch
		101
		102	static bool
		103	is_uc (char c)
		104	{
		105	return 'A' <= c && c <= 'Z';
		106	}
		107
		108	static bool
		109	is_lc (char c)
		110	{
		111	return 'a' <= c && c <= 'z';
		112	}
85		113
86	// works for cmaps up to 255 (not 256!)	114	// works for cmaps up to 255 (not 256!)
87	struct charmap	115	struct charmap
88	{	116	{
89	enum { INVALID = (u8)255 };	117	enum { INVALID = (u8)255 };
…		…
103	memset (enc, (char) 0, 256);	131	memset (enc, (char) 0, 256);
104	memset (dec, (char)INVALID, 256);	132	memset (dec, (char)INVALID, 256);
105		133
106	for (size = 0; cmap [size]; size++)	134	for (size = 0; cmap [size]; size++)
107	{	135	{
		136	char c = cmap [size];
		137
108	enc [size] = cmap [size];	138	enc [size] = c;
109	dec [(u8)enc [size]] = size;	139	dec [(u8)c] = size;
		140
		141	// allow lowercase/uppercase aliases if possible
		142	if (is_uc (c) && dec [c + ('a' - 'A')] == INVALID) dec [c + ('a' - 'A')] = size;
		143	if (is_lc (c) && dec [c - ('a' - 'A')] == INVALID) dec [c - ('a' - 'A')] = size;
110	}	144	}
111		145
112	assert (size < 256);	146	assert (size < 256);
113	}	147	}
114		148
…		…
121	{	155	{
122	charmap cmap;	156	charmap cmap;
123	unsigned int enc_len [MAX_DEC_LEN];	157	unsigned int enc_len [MAX_DEC_LEN];
124	unsigned int dec_len [MAX_ENC_LEN];	158	unsigned int dec_len [MAX_ENC_LEN];
125		159
126	unsigned int encode_len (unsigned int len);	160	unsigned int encode_len (unsigned int len) const;
127	unsigned int decode_len (unsigned int len);	161	unsigned int decode_len (unsigned int len) const;
128		162
129	unsigned int encode (char dst, u8 src, unsigned int len);	163	unsigned int encode (char dst, u8 src, unsigned int len) const;
130	unsigned int decode (u8 dst, char src, unsigned int len);	164	unsigned int decode (u8 dst, char src, unsigned int len) const;
131		165
132	basecoder (const char *cmap);	166	basecoder (const char *cmap);
133	};	167	};
134		168
135	basecoder::basecoder (const char *cmap)	169	basecoder::basecoder (const char *cmap)
…		…
154	enc_len [len] = n;	188	enc_len [len] = n;
155	dec_len [n] = len;	189	dec_len [n] = len;
156	}	190	}
157	}	191	}
158		192
		193	unsigned int
159	unsigned int basecoder::encode_len (unsigned int len)	194	basecoder::encode_len (unsigned int len) const
160	{	195	{
161	return enc_len [len];	196	return enc_len [len];
162	}	197	}
163		198
		199	unsigned int
164	unsigned int basecoder::decode_len (unsigned int len)	200	basecoder::decode_len (unsigned int len) const
165	{	201	{
166	while (len && !dec_len [len])	202	while (len && !dec_len [len])
167	--len;	203	--len;
168		204
169	return dec_len [len];	205	return dec_len [len];
170	}	206	}
171		207
		208	unsigned int
172	unsigned int basecoder::encode (char dst, u8 src, unsigned int len)	209	basecoder::encode (char dst, u8 src, unsigned int len) const
173	{	210	{
174	if (!len \|\| len > MAX_DEC_LEN)	211	if (!len \|\| len > MAX_DEC_LEN)
175	return 0;	212	return 0;
176		213
177	int elen = encode_len (len);	214	int elen = encode_len (len);
…		…
196	*dst++ = cmap.encode [dst_ [i]];	233	*dst++ = cmap.encode [dst_ [i]];
197		234
198	return elen;	235	return elen;
199	}	236	}
200		237
		238	unsigned int
201	unsigned int basecoder::decode (u8 dst, char src, unsigned int len)	239	basecoder::decode (u8 dst, char src, unsigned int len) const
202	{	240	{
203	if (!len \|\| len > MAX_ENC_LEN)	241	if (!len \|\| len > MAX_ENC_LEN)
204	return 0;	242	return 0;
205		243
206	u8 src_ [MAX_ENC_LEN];	244	u8 src_ [MAX_ENC_LEN];
…		…
255	}	293	}
256	abort ();	294	abort ();
257	}	295	}
258	#endif	296	#endif
259		297
260	//static basecoder cdc64 ("_dDpPhHzZrR06QqMmjJkKBb34TtSsvVlL81xXaAeEFf92WwGgYyoO57UucCNniI-");
261	//static basecoder cdc63 ("_dDpPhHzZrR06QqMmjJkKBb34TtSsvVlL81xXaAeEFf92WwGgYyoO57UucCNniI");
262	static basecoder cdc62 ("dDpPhHzZrR06QqMmjJkKBb34TtSsvVlL81xXaAeEFf92WwGgYyoO57UucCNniI");	298	static basecoder cdc62 ("dDpPhHzZrR06QqMmjJkKBb34TtSsvVlL81xXaAeEFf92WwGgYyoO57UucCNniI"); // a-zA-Z0-9
263	//static basecoder cdc36 ("dphzr06qmjkb34tsvl81xaef92wgyo57ucni"); // unused as of yet	299	static basecoder cdc36 ("dPhZr06QmJkB34tSvL81xAeF92wGyO57uCnI"); // a-z0-9 for case-changers
264	static basecoder cdc26 ("dPhZrQmJkBtSvLxAeFwGyO");	300	static basecoder cdc26 ("dPhZrQmJkBtSvLxAeFwGyOuCnI"); // a-z
265		301
266	/////////////////////////////////////////////////////////////////////////////	302	/////////////////////////////////////////////////////////////////////////////
267		303
268	#define HDRSIZE 6	304	#define HDRSIZE 5
269		305
		306	inline void
270	inline void encode_header (char *data, int clientid, int seqno, int retry = 0)	307	encode_header (char *data, int clientid, int seqno, int retry = 0)
271	{	308	{
		309	assert (clientid < 256);
		310
272	seqno &= SEQNO_MASK;	311	seqno &= SEQNO_MASK;
273		312
274	u8 hdr[3] = {	313	u8 hdr[3] = {
		314	seqno,
		315	(seqno >> 8) \| (retry << 6),
275	clientid,	316	clientid,
276	(seqno >> 8) \| (retry << 6),
277	seqno,
278	};	317	};
279		318
280	assert (clientid < 256);
281
282	cdc26.encode (data, hdr, 3);	319	cdc36.encode (data, hdr, 3);
283	}	320	}
284		321
		322	inline void
285	inline void decode_header (char *data, int &clientid, int &seqno)	323	decode_header (char *data, int &clientid, int &seqno)
286	{	324	{
287	u8 hdr[3];	325	u8 hdr[3];
288		326
289	cdc26.decode (hdr, data, HDRSIZE);	327	cdc36.decode (hdr, data, HDRSIZE);
290		328
291	clientid = hdr[0];	329	clientid = hdr[2];
292	seqno = ((hdr[1] << 8) \| hdr[2]) & SEQNO_MASK;	330	seqno = ((hdr[1] << 8) \| hdr[0]) & SEQNO_MASK;
293	}	331	}
294		332
295	/////////////////////////////////////////////////////////////////////////////	333	/////////////////////////////////////////////////////////////////////////////
296		334
297	struct byte_stream	335	struct byte_stream
…		…
323	byte_stream::~byte_stream ()	361	byte_stream::~byte_stream ()
324	{	362	{
325	delete data;	363	delete data;
326	}	364	}
327		365
		366	void
328	void byte_stream::remove (int count)	367	byte_stream::remove (int count)
329	{	368	{
330	if (count > fill)	369	if (count > fill)
331	assert (count <= fill);	370	assert (count <= fill);
332		371
333	memmove (data, data + count, fill -= count);	372	memmove (data, data + count, fill -= count);
334	}	373	}
335		374
		375	bool
336	bool byte_stream::put (u8 *data, unsigned int datalen)	376	byte_stream::put (u8 *data, unsigned int datalen)
337	{	377	{
338	if (maxsize - fill < datalen)	378	if (maxsize - fill < datalen)
339	return false;	379	return false;
340		380
341	memcpy (this->data + fill, data, datalen); fill += datalen;	381	memcpy (this->data + fill, data, datalen); fill += datalen;
342		382
343	return true;	383	return true;
344	}	384	}
345		385
		386	bool
346	bool byte_stream::put (vpn_packet *pkt)	387	byte_stream::put (vpn_packet *pkt)
347	{	388	{
348	if (maxsize - fill < pkt->len + 2)	389	if (maxsize - fill < pkt->len + 2)
349	return false;	390	return false;
350		391
351	data [fill++] = pkt->len >> 8;	392	data [fill++] = pkt->len >> 8;
…		…
407		448
408	struct dns_cfg	449	struct dns_cfg
409	{	450	{
410	static int next_uid;	451	static int next_uid;
411		452
		453	u8 chksum;
		454	u8 rrtype;
		455	u16 uid; // to make request unique
		456
		457	u8 version;
		458	u8 flags;
		459	u16 max_size;
		460
412	u8 id1, id2, id3, id4;	461	u8 id1, id2, id3, id4;
413	u8 version;	462
414	u8 rrtype;	463	u16 client;
415	u8 flags;
416	u8 def_ttl;	464	u8 def_ttl;
417	u8 rcv_cdc;	465	u8 r0;
418	u8 snd_cdc;
419	u16 max_size;
420	u16 client;
421	u16 uid; // to make request unique
422		466
423	u8 reserved[8];	467	u8 syn_cdc; // cdc en/decoder for syn (A?) requests
		468	u8 hdr_cdc; // cdc en/decoder for regular request headers
		469	u8 req_cdc; // cdc en/decoder for regular (ANY?) request data
		470	u8 rep_cdc; // cdc en/decoder for regular (TXT) replies, 0 == 8 bit encoding
		471
		472	u8 r1, r2, r3, r4;
424		473
425	void reset (int clientid);	474	void reset (int clientid);
426	bool valid ();	475	bool valid ();
		476	u8 get_chksum ();
427	};	477	};
428		478
429	int dns_cfg::next_uid;	479	int dns_cfg::next_uid;
430		480
		481	void
431	void dns_cfg::reset (int clientid)	482	dns_cfg::reset (int clientid)
432	{	483	{
		484	// this ID must result in some mixed-case characters in cdc26-encoding
433	id1 = 'G';	485	id1 = 'G';
434	id2 = 'V';	486	id2 = 'V';
435	id3 = 'P';	487	id3 = 'P';
436	id4 = 'E';	488	id4 = 'E';
437		489
438	version = 1;	490	version = 2;
439		491
440	rrtype = RR_TYPE_TXT;	492	rrtype = RR_TYPE_TXT;
441	flags = 0;	493	flags = 0;
442	def_ttl = 1;	494	def_ttl = 0;
443	rcv_cdc = 0;
444	snd_cdc = 62;	495	syn_cdc = 26;
		496	hdr_cdc = 36;
		497	req_cdc = conf.dns_case_preserving ? 62 : 36;
		498	rep_cdc = 0;
445	max_size = ntohs (MAX_PKT_SIZE);	499	max_size = htons (MAX_PKT_SIZE);
446	client = ntohs (clientid);	500	client = htons (clientid);
447	uid = next_uid++;	501	uid = ++next_uid;
448		502
449	memset (reserved, 0, 8);	503	r0 = r1 = r2 = r3 = r4 = 0;
450	}
451		504
		505	chksum = get_chksum ();
		506	}
		507
		508	// simple but not trivial chksum
		509	u8
		510	dns_cfg::get_chksum ()
		511	{
		512	unsigned int sum = 0xff00; // only 16 bits required
		513
		514	u8 old_chksum = chksum;
		515	chksum = 0;
		516
		517	for (unsigned int i = 0; i < sizeof (*this); ++i)
		518	sum += ((u8 )this)[i] (i + 1);
		519
		520	chksum = old_chksum;
		521
		522	return sum + (sum >> 8);
		523	}
		524
		525	bool
452	bool dns_cfg::valid ()	526	dns_cfg::valid ()
453	{	527	{
		528	// although the protocol itself allows for some configurability,
		529	// only the following encoding/decoding settings are implemented.
454	return id1 == 'G'	530	return id1 == 'G'
455	&& id2 == 'V'	531	&& id2 == 'V'
456	&& id3 == 'P'	532	&& id3 == 'P'
457	&& id4 == 'E'	533	&& id4 == 'E'
458	&& version == 1	534	&& version == 2
459	&& flags == 0
460	&& rcv_cdc == 0
461	&& snd_cdc == 62	535	&& syn_cdc == 26
462	&& max_size == ntohs (MAX_PKT_SIZE);	536	&& hdr_cdc == 36
		537	&& (req_cdc == 36 \|\| req_cdc == 62)
		538	&& rep_cdc == 0
		539	&& chksum == get_chksum ();
463	}	540	}
464		541
465	struct dns_packet : net_packet	542	struct dns_packet : net_packet
466	{	543	{
467	u16 id;	544	u16 id;
468	u16 flags; // QR:1 Opcode:4 AA:1 TC:1 RD:1 RA:1 Z:3 RCODE:4	545	u16 flags; // QR:1 Opcode:4 AA:1 TC:1 RD:1 RA:1 Z:3 RCODE:4
469	u16 qdcount, ancount, nscount, arcount;	546	u16 qdcount, ancount, nscount, arcount;
470		547
471	u8 data[MAXSIZE - 6 * 2];	548	u8 data [MAXSIZE - 6 * 2];
472		549
473	int decode_label (char *data, int size, int &offs);	550	int decode_label (char *data, int size, int &offs);
474	};	551	};
475		552
		553	int
476	int dns_packet::decode_label (char *data, int size, int &offs)	554	dns_packet::decode_label (char *data, int size, int &offs)
477	{	555	{
478	char *orig = data;	556	char *orig = data;
479		557
480	memset (data, 0, size);	558	memset (data, 0, size);
481		559
…		…
507	return data - orig;	585	return data - orig;
508	}	586	}
509		587
510	/////////////////////////////////////////////////////////////////////////////	588	/////////////////////////////////////////////////////////////////////////////
511		589
		590	static
		591	u16 next_id ()
		592	{
512	static u16 dns_id = 0; // TODO: should be per-vpn	593	static u16 dns_id = 0; // TODO: should be per-vpn
513		594
514	static u16 next_id ()
515	{
516	if (!dns_id)	595	if (!dns_id)
517	dns_id = time (0);	596	dns_id = time (0);
518		597
519	// the simplest lsfr with periodicity 65535 i could find	598	// the simplest lsfr with periodicity 65535 i could find
520	dns_id = (dns_id << 1)	599	dns_id = (dns_id << 1)
…		…
535	struct vpn *vpn;	614	struct vpn *vpn;
536		615
537	dns_cfg cfg;	616	dns_cfg cfg;
538		617
539	bool established;	618	bool established;
		619	const basecoder *cdc;
540		620
541	tstamp last_received;	621	tstamp last_received;
542	tstamp last_sent;	622	tstamp last_sent;
543	double last_latency;	623	double min_latency;
544	double poll_interval, send_interval;	624	double poll_interval, send_interval;
545		625
546	vector<dns_rcv *> rcvpq;	626	vector<dns_rcv *> rcvpq;
547		627
548	byte_stream rcvdq; int rcvseq;	628	byte_stream rcvdq; int rcvseq; int repseq;
549	byte_stream snddq; int sndseq;	629	byte_stream snddq; int sndseq;
550		630
551	void time_cb (time_watcher &w); time_watcher tw;	631	inline void time_cb (ev::timer &w, int revents); ev::timer tw;
552	void receive_rep (dns_rcv *r);	632	void receive_rep (dns_rcv *r);
		633
		634	void reset (); // quite like tcp RST
		635	void set_cfg (); // to be called after any cfg changes
553		636
554	dns_connection (connection *c);	637	dns_connection (connection *c);
555	~dns_connection ();	638	~dns_connection ();
556	};	639	};
557		640
…		…
575	: dns (dns)	658	: dns (dns)
576	{	659	{
577	timeout = 0;	660	timeout = 0;
578	retry = 0;	661	retry = 0;
579	seqno = 0;	662	seqno = 0;
580	sent = NOW;	663	sent = ev_now ();
581	stdhdr = false;	664	stdhdr = false;
582		665
583	pkt = new dns_packet;	666	pkt = new dns_packet;
584		667
585	pkt->id = next_id ();	668	pkt->id = next_id ();
…		…
588	dns_snd::~dns_snd ()	671	dns_snd::~dns_snd ()
589	{	672	{
590	delete pkt;	673	delete pkt;
591	}	674	}
592		675
		676	static void
593	static void append_domain (dns_packet &pkt, int &offs, const char *domain)	677	append_domain (dns_packet &pkt, int &offs, const char *domain)
594	{	678	{
595	// add tunnel domain	679	// add tunnel domain
596	for (;;)	680	for (;;)
597	{	681	{
598	const char *end = strchr (domain, '.');	682	const char *end = strchr (domain, '.');
…		…
611		695
612	domain = end + 1;	696	domain = end + 1;
613	}	697	}
614	}	698	}
615		699
		700	void
616	void dns_snd::gen_stream_req (int seqno, byte_stream &stream)	701	dns_snd::gen_stream_req (int seqno, byte_stream &stream)
617	{	702	{
618	stdhdr = true;	703	stdhdr = true;
619	this->seqno = seqno;	704	this->seqno = seqno;
620		705
621	timeout = NOW + INITIAL_TIMEOUT;	706	timeout = ev_now () + INITIAL_TIMEOUT;
622		707
623	pkt->flags = htons (DEFAULT_CLIENT_FLAGS);	708	pkt->flags = htons (DEFAULT_CLIENT_FLAGS);
624	pkt->qdcount = htons (1);	709	pkt->qdcount = htons (1);
625		710
626	int offs = 6*2;	711	int offs = 6*2;
…		…
629	// so we need to have space for 2*MAX_DOMAIN_SIZE + header + extra	714	// so we need to have space for 2*MAX_DOMAIN_SIZE + header + extra
630		715
631	char enc[256], *encp = enc;	716	char enc[256], *encp = enc;
632	encode_header (enc, THISNODE->id, seqno);	717	encode_header (enc, THISNODE->id, seqno);
633		718
634	int datalen = cdc62.decode_len (dlen - (dlen + MAX_LBL_SIZE - 1) / MAX_LBL_SIZE - HDRSIZE);	719	int datalen = dns->cdc->decode_len (dlen - (dlen + MAX_LBL_SIZE - 1) / MAX_LBL_SIZE - HDRSIZE);
635		720
636	if (datalen > stream.size ())	721	if (datalen > stream.size ())
637	datalen = stream.size ();	722	datalen = stream.size ();
638		723
639	int enclen = cdc62.encode (enc + HDRSIZE, stream.begin (), datalen) + HDRSIZE;	724	int enclen = dns->cdc->encode (enc + HDRSIZE, stream.begin (), datalen) + HDRSIZE;
640	stream.remove (datalen);	725	stream.remove (datalen);
641		726
642	while (enclen)	727	while (enclen)
643	{	728	{
644	int lbllen = enclen < MAX_LBL_SIZE ? enclen : MAX_LBL_SIZE;	729	int lbllen = enclen < MAX_LBL_SIZE ? enclen : MAX_LBL_SIZE;
…		…
659	(pkt)[offs++] = RR_CLASS_IN >> 8; (pkt)[offs++] = RR_CLASS_IN;	744	(pkt)[offs++] = RR_CLASS_IN >> 8; (pkt)[offs++] = RR_CLASS_IN;
660		745
661	pkt->len = offs;	746	pkt->len = offs;
662	}	747	}
663		748
		749	void
664	void dns_snd::gen_syn_req ()	750	dns_snd::gen_syn_req ()
665	{	751	{
666	timeout = NOW + INITIAL_SYN_TIMEOUT;	752	timeout = ev_now () + INITIAL_SYN_TIMEOUT;
667
668	printf ("send syn\n");//D
669		753
670	pkt->flags = htons (DEFAULT_CLIENT_FLAGS);	754	pkt->flags = htons (DEFAULT_CLIENT_FLAGS);
671	pkt->qdcount = htons (1);	755	pkt->qdcount = htons (1);
672		756
673	int offs = 6 * 2;	757	int offs = 6 * 2;
…		…
712	/////////////////////////////////////////////////////////////////////////////	796	/////////////////////////////////////////////////////////////////////////////
713		797
714	dns_connection::dns_connection (connection *c)	798	dns_connection::dns_connection (connection *c)
715	: c (c)	799	: c (c)
716	, rcvdq (MAX_BACKLOG * 2)	800	, rcvdq (MAX_BACKLOG * 2)
717	, snddq (MAX_BACKLOG * 2)	801	, snddq (MAX_BACKLOG)
718	, tw (this, &dns_connection::time_cb)
719	{	802	{
		803	tw.set<dns_connection, &dns_connection::time_cb> (this);
		804
720	vpn = c->vpn;	805	vpn = c->vpn;
721		806
		807	reset ();
		808	}
		809
		810	dns_connection::~dns_connection ()
		811	{
		812	reset ();
		813	}
		814
		815	void
		816	dns_connection::reset ()
		817	{
		818	while (!rcvpq.empty ())
		819	{
		820	delete rcvpq.back ();
		821	rcvpq.pop_back ();
		822	}
		823
		824	for (int i = vpn->dns_sndpq.size (); i--; )
		825	if (vpn->dns_sndpq [i]->dns == this)
		826	{
		827	vpn->dns_sndpq [i] = vpn->dns_sndpq.back ();
		828	vpn->dns_sndpq.pop_back ();
		829	}
		830
722	established = false;	831	established = false;
723		832
724	rcvseq = sndseq = 0;	833	rcvseq = repseq = sndseq = 0;
725		834
726	last_sent = last_received = 0;	835	last_sent = last_received = 0;
727	poll_interval = MIN_POLL_INTERVAL;	836	poll_interval = 0.5; // starting here
728	send_interval = 0.5; // starting rate	837	send_interval = 0.5; // starting rate
729	last_latency = INITIAL_TIMEOUT;	838	min_latency = INITIAL_TIMEOUT;
730	}	839	}
731		840
732	dns_connection::~dns_connection ()	841	void
		842	dns_connection::set_cfg ()
733	{	843	{
734	for (vector<dns_rcv *>::iterator i = rcvpq.begin ();	844	cdc = cfg.req_cdc == 36 ? &cdc36 : &cdc62;
735	i != rcvpq.end ();
736	++i)
737	delete *i;
738	}	845	}
739		846
		847	void
740	void dns_connection::receive_rep (dns_rcv *r)	848	dns_connection::receive_rep (dns_rcv *r)
741	{	849	{
742	if (r->datalen)	850	if (r->datalen)
743	{	851	{
744	last_received = NOW;	852	last_received = ev_now ();
745	tw.trigger ();	853	tw ();
746		854
747	poll_interval = send_interval;	855	poll_interval = send_interval;
748	}	856	}
749	else	857	else
750	{	858	{
751	poll_interval *= 1.5;	859	poll_interval *= 1.5;
		860
752	if (poll_interval > MAX_POLL_INTERVAL)	861	if (poll_interval > MAX_POLL_INTERVAL)
753	poll_interval = MAX_POLL_INTERVAL;	862	poll_interval = MAX_POLL_INTERVAL;
754	}	863	}
755		864
756	rcvpq.push_back (r);	865	rcvpq.push_back (r);
…		…
759		868
760	// find next packet	869	// find next packet
761	for (vector<dns_rcv *>::iterator i = rcvpq.end (); i-- != rcvpq.begin (); )	870	for (vector<dns_rcv *>::iterator i = rcvpq.end (); i-- != rcvpq.begin (); )
762	if (SEQNO_EQ (rcvseq, (*i)->seqno))	871	if (SEQNO_EQ (rcvseq, (*i)->seqno))
763	{	872	{
		873	//printf ("seqno eq %x %x\n", rcvseq, (*i)->seqno);//D
764	// enter the packet into our input stream	874	// enter the packet into our input stream
765	r = *i;	875	r = *i;
766		876
767	// remove the oldest packet, look forward, as it's oldest first	877	// remove the oldest packet, look forward, as it's oldest first
768	for (vector<dns_rcv *>::iterator j = rcvpq.begin (); j != rcvpq.end (); ++j)	878	for (vector<dns_rcv *>::iterator j = rcvpq.begin (); j != rcvpq.end (); ++j)
769	if (SEQNO_EQ ((*j)->seqno, rcvseq - MAX_WINDOW))	879	if (SEQNO_EQ ((*j)->seqno, rcvseq - MAX_WINDOW))
770	{	880	{
		881	//printf ("seqno RR %x %x\n", (*j)->seqno, rcvseq - MAX_WINDOW);//D
771	delete *j;	882	delete *j;
772	rcvpq.erase (j);	883	rcvpq.erase (j);
773	break;	884	break;
774	}	885	}
775		886
776	rcvseq = (rcvseq + 1) & SEQNO_MASK;	887	rcvseq = (rcvseq + 1) & SEQNO_MASK;
777		888
778	if (!rcvdq.put (r->data, r->datalen))	889	if (!rcvdq.put (r->data, r->datalen))
779	{	890	{
		891	// MUST never overflow, can be caused by data corruption, TODO
780	slog (L_ERR, "DNS: !rcvdq.put (r->data, r->datalen)");	892	slog (L_CRIT, "DNS: !rcvdq.put (r->data, r->datalen)");
781	abort (); // MUST never overflow, can be caused by data corruption, TODO	893	reset ();
		894	return;
782	}	895	}
783		896
784	while (vpn_packet *pkt = rcvdq.get ())	897	while (vpn_packet *pkt = rcvdq.get ())
785	{	898	{
786	sockinfo si;	899	sockinfo si;
787	si.host = 0x01010101; si.port = htons (c->conf->id); si.prot = PROT_DNSv4;	900	si.host = htonl (c->conf->id); si.port = 0; si.prot = PROT_DNSv4;
788		901
789	vpn->recv_vpn_packet (pkt, si);	902	vpn->recv_vpn_packet (pkt, si);
790
791	delete pkt;	903	delete pkt;
792	}	904	}
793		905
794	// check for further packets	906	// check for further packets
795	goto redo;	907	goto redo;
…		…
806	pkt.flags = htons (DEFAULT_SERVER_FLAGS \| FLAG_RCODE_FORMERR);	918	pkt.flags = htons (DEFAULT_SERVER_FLAGS \| FLAG_RCODE_FORMERR);
807		919
808	if (0 == (flags & (FLAG_RESPONSE \| FLAG_OP_MASK))	920	if (0 == (flags & (FLAG_RESPONSE \| FLAG_OP_MASK))
809	&& pkt.qdcount == htons (1))	921	&& pkt.qdcount == htons (1))
810	{	922	{
811	char qname[MAXSIZE];	923	char qname [MAXSIZE];
812	int qlen = pkt.decode_label ((char *)qname, MAXSIZE - offs, offs);	924	int qlen = pkt.decode_label ((char *)qname, MAXSIZE - offs, offs);
813		925
814	u16 qtype = pkt [offs++] << 8; qtype \|= pkt [offs++];	926	u16 qtype = pkt [offs++] << 8; qtype \|= pkt [offs++];
815	u16 qclass = pkt [offs++] << 8; qclass \|= pkt [offs++];	927	u16 qclass = pkt [offs++] << 8; qclass \|= pkt [offs++];
816		928
…		…
823		935
824	int dlen = strlen (THISNODE->domain);	936	int dlen = strlen (THISNODE->domain);
825		937
826	if (qclass == RR_CLASS_IN	938	if (qclass == RR_CLASS_IN
827	&& qlen > dlen + 1	939	&& qlen > dlen + 1
828	&& !memcmp (qname + qlen - dlen - 1, THISNODE->domain, dlen))	940	&& !memcmp (qname + qlen - (dlen + 1), THISNODE->domain, dlen))
829	{	941	{
830	// now generate reply	942	// now generate reply
831	pkt.ancount = htons (1); // one answer RR	943	pkt.ancount = htons (1); // one answer RR
832	pkt.flags = htons (DEFAULT_SERVER_FLAGS \| FLAG_RCODE_OK);	944	pkt.flags = htons (DEFAULT_SERVER_FLAGS \| FLAG_RCODE_OK);
833		945
…		…
838	{	950	{
839	// correct class, domain: parse	951	// correct class, domain: parse
840	int client, seqno;	952	int client, seqno;
841	decode_header (qname, client, seqno);	953	decode_header (qname, client, seqno);
842		954
843	u8 data[MAXSIZE];
844	int datalen = cdc62.decode (data, qname + HDRSIZE, qlen - (dlen + 1 + HDRSIZE));
845
846	if (0 < client && client <= conns.size ())	955	if (0 < client && client <= conns.size ())
847	{	956	{
848	connection *c = conns [client - 1];	957	connection *c = conns [client - 1];
849	dns_connection *dns = c->dns;	958	dns_connection *dns = c->dns;
850	dns_rcv *rcv;	959	dns_rcv *rcv;
851	bool in_seq;
852		960
853	if (dns)	961	if (dns)
854	{	962	{
		963	u8 data[MAXSIZE];
		964	int datalen = dns->cdc->decode (data, qname + HDRSIZE, qlen - (dlen + 1 + HDRSIZE));
		965
855	for (vector<dns_rcv *>::iterator i = dns->rcvpq.end (); i-- != dns->rcvpq.begin (); )	966	for (vector<dns_rcv *>::iterator i = dns->rcvpq.end (); i-- != dns->rcvpq.begin (); )
856	if (SEQNO_EQ ((*i)->seqno, seqno))	967	if (SEQNO_EQ ((*i)->seqno, seqno))
857	{	968	{
858	// already seen that request: simply reply with the cached reply	969	// already seen that request: simply reply with the cached reply
859	dns_rcv r = i;	970	dns_rcv r = i;
…		…
867	memcpy (pkt.at (0), r->pkt->at (0), offs = r->pkt->len);	978	memcpy (pkt.at (0), r->pkt->at (0), offs = r->pkt->len);
868		979
869	goto duplicate_request;	980	goto duplicate_request;
870	}	981	}
871		982
872	in_seq = dns->rcvseq == seqno;
873
874	// new packet, queue	983	// new packet, queue
875	rcv = new dns_rcv (seqno, data, datalen);	984	rcv = new dns_rcv (seqno, data, datalen);
876	dns->receive_rep (rcv);	985	dns->receive_rep (rcv);
877	}	986	}
878		987
		988	{
879	pkt [offs++] = 0xc0; pkt [offs++] = 6 * 2; // refer to name in query section	989	pkt [offs++] = 0xc0; pkt [offs++] = 6 * 2; // refer to name in query section
880		990
881	int rtype = dns ? dns->cfg.rrtype : RR_TYPE_A;	991	int rtype = dns ? dns->cfg.rrtype : RR_TYPE_A;
882	pkt [offs++] = rtype >> 8; pkt [offs++] = rtype; // type	992	pkt [offs++] = rtype >> 8; pkt [offs++] = rtype; // type
883	pkt [offs++] = RR_CLASS_IN >> 8; pkt [offs++] = RR_CLASS_IN; // class	993	pkt [offs++] = RR_CLASS_IN >> 8; pkt [offs++] = RR_CLASS_IN; // class
884	pkt [offs++] = 0; pkt [offs++] = 0;	994	pkt [offs++] = 0; pkt [offs++] = 0;
885	pkt [offs++] = 0; pkt [offs++] = dns ? dns->cfg.def_ttl : 0; // TTL	995	pkt [offs++] = 0; pkt [offs++] = dns ? dns->cfg.def_ttl : 0; // TTL
886		996
887	int rdlen_offs = offs += 2;	997	int rdlen_offs = offs += 2;
888		998
		999	if (dns)
		1000	{
889	int dlen = (dns ? ntohs (dns->cfg.max_size) : MAX_PKT_SIZE) - offs;	1001	int dlen = ntohs (dns->cfg.max_size) - offs;
		1002
890	// bind doesn't compress well, so reduce further by one label length	1003	// bind doesn't compress well, so reduce further by one label length
891	dlen -= qlen;	1004	dlen -= qlen;
892		1005
893	if (dns)
894	{
895	// only put data into in-order sequence packets, if	1006	// only put data into in-order sequence packets, if
896	// we receive out-of-order packets we generate empty	1007	// we receive out-of-order packets we generate empty
897	// replies	1008	// replies
898	while (dlen > 1 && !dns->snddq.empty () && in_seq)	1009	//printf ("%d - %d & %x (=%d) < %d\n", seqno, dns->repseq, SEQNO_MASK, (seqno - dns->repseq) & SEQNO_MASK, MAX_WINDOW);//D
		1010	if (((seqno - dns->repseq) & SEQNO_MASK) <= MAX_WINDOW)
899	{	1011	{
		1012	dns->repseq = seqno;
		1013
		1014	while (dlen > 1 && !dns->snddq.empty ())
		1015	{
900	int txtlen = dlen <= 255 ? dlen - 1 : 255;	1016	int txtlen = dlen <= 255 ? dlen - 1 : 255;
901		1017
902	if (txtlen > dns->snddq.size ())	1018	if (txtlen > dns->snddq.size ())
903	txtlen = dns->snddq.size ();	1019	txtlen = dns->snddq.size ();
904		1020
905	pkt[offs++] = txtlen;	1021	pkt[offs++] = txtlen;
906	memcpy (pkt.at (offs), dns->snddq.begin (), txtlen);	1022	memcpy (pkt.at (offs), dns->snddq.begin (), txtlen);
907	offs += txtlen;	1023	offs += txtlen;
908	dns->snddq.remove (txtlen);	1024	dns->snddq.remove (txtlen);
909		1025
910	dlen -= txtlen + 1;	1026	dlen -= txtlen + 1;
		1027	}
911	}	1028	}
912		1029
913	// avoid empty TXT rdata	1030	// avoid completely empty TXT rdata
914	if (offs == rdlen_offs)	1031	if (offs == rdlen_offs)
915	pkt[offs++] = 0;	1032	pkt[offs++] = 0;
916		1033
917	slog (L_NOISE, "DNS: snddq %d", dns->snddq.size ());	1034	slog (L_NOISE, "DNS: snddq %d", dns->snddq.size ());
918	}	1035	}
919	else	1036	else
920	{	1037	{
921	// send RST	1038	// send RST
922	pkt [offs++] = CMD_IP_1; pkt [offs++] = CMD_IP_2; pkt [offs++] = CMD_IP_3;	1039	pkt [offs++] = CMD_IP_1; pkt [offs++] = CMD_IP_2; pkt [offs++] = CMD_IP_3;
923	pkt [offs++] = CMD_IP_RST;	1040	pkt [offs++] = CMD_IP_RST;
924	}	1041	}
925		1042
926	int rdlen = offs - rdlen_offs;	1043	int rdlen = offs - rdlen_offs;
927		1044
928	pkt [rdlen_offs - 2] = rdlen >> 8;	1045	pkt [rdlen_offs - 2] = rdlen >> 8;
929	pkt [rdlen_offs - 1] = rdlen;	1046	pkt [rdlen_offs - 1] = rdlen;
930		1047
931	if (dns)	1048	if (dns)
932	{	1049	{
933	// now update dns_rcv copy	1050	// now update dns_rcv copy
934	rcv->pkt->len = offs;	1051	rcv->pkt->len = offs;
935	memcpy (rcv->pkt->at (0), pkt.at (0), offs);	1052	memcpy (rcv->pkt->at (0), pkt.at (0), offs);
936	}	1053	}
		1054	}
937		1055
938	duplicate_request: ;	1056	duplicate_request: ;
939	}	1057	}
940	else	1058	else
941	pkt.flags = htons (DEFAULT_SERVER_FLAGS \| FLAG_RCODE_FORMERR);	1059	pkt.flags = htons (DEFAULT_SERVER_FLAGS \| FLAG_RCODE_FORMERR);
…		…
953	pkt [offs++] = RR_CLASS_IN >> 8; pkt [offs++] = RR_CLASS_IN; // class	1071	pkt [offs++] = RR_CLASS_IN >> 8; pkt [offs++] = RR_CLASS_IN; // class
954	pkt [offs++] = 0; pkt [offs++] = 0;	1072	pkt [offs++] = 0; pkt [offs++] = 0;
955	pkt [offs++] = 0; pkt [offs++] = cfg.def_ttl; // TTL	1073	pkt [offs++] = 0; pkt [offs++] = cfg.def_ttl; // TTL
956	pkt [offs++] = 0; pkt [offs++] = 4; // rdlength	1074	pkt [offs++] = 0; pkt [offs++] = 4; // rdlength
957		1075
958	slog (L_INFO, _("DNS: client %d tries to connect"), client);
959
960	pkt [offs++] = CMD_IP_1; pkt [offs++] = CMD_IP_2; pkt [offs++] = CMD_IP_3;	1076	pkt [offs++] = CMD_IP_1; pkt [offs++] = CMD_IP_2; pkt [offs++] = CMD_IP_3;
961	pkt [offs++] = CMD_IP_REJ;	1077	pkt [offs++] = CMD_IP_REJ;
962		1078
963	if (0 < client && client <= conns.size ())	1079	if (0 < client && client <= conns.size ())
964	{	1080	{
965	connection *c = conns [client - 1];	1081	connection *c = conns [client - 1];
966		1082
967	if (cfg.valid ())	1083	if (cfg.valid ())
968	{	1084	{
969	pkt [offs - 1] = CMD_IP_SYN;	1085	slog (L_INFO, _("DNS: client %d connects (version %d, req_cdc %d)"), client, cfg.version, cfg.req_cdc);
		1086
		1087	// check for any encoding mismatches - hints at a case problem
		1088	char qname2 [MAX_ENC_LEN];
		1089	cdc26.encode (qname2, (u8 *)&cfg, sizeof (dns_cfg));
970		1090
971	delete c->dns;	1091	delete c->dns;
		1092
		1093	pkt [offs - 1] = memcmp (qname, qname2, cdc26.encode_len (sizeof (dns_cfg)))
		1094	? CMD_IP_CSE : CMD_IP_SYN;
		1095
972	c->dns = new dns_connection (c);	1096	c->dns = new dns_connection (c);
973	c->dns->cfg = cfg;	1097	c->dns->cfg = cfg;
		1098	c->dns->set_cfg ();
974	}	1099	}
975	}	1100	}
976	}	1101	}
977	}	1102	}
978		1103
…		…
997	{	1122	{
998	dns_connection dns = (i)->dns;	1123	dns_connection dns = (i)->dns;
999	connection *c = dns->c;	1124	connection *c = dns->c;
1000	int seqno = (*i)->seqno;	1125	int seqno = (*i)->seqno;
1001	u8 data[MAXSIZE], *datap = data;	1126	u8 data[MAXSIZE], *datap = data;
		1127	//printf ("rcv pkt %x\n", seqno);//D
		1128	bool back_off = (*i)->retry;
1002		1129
1003	if ((*i)->retry)	1130	if (back_off)
1004	{	1131	{
1005	dns->send_interval *= 1.01;	1132	dns->send_interval *= 1.01;
1006	if (dns->send_interval > MAX_SEND_INTERVAL)	1133	if (dns->send_interval > MAX_SEND_INTERVAL)
1007	dns->send_interval = MAX_SEND_INTERVAL;	1134	dns->send_interval = MAX_SEND_INTERVAL;
1008	}	1135	}
1009	else	1136	else
1010	{	1137	{
1011	#if 1	1138	#if 0
1012	dns->send_interval *= 0.999;	1139	dns->send_interval *= 0.999;
1013	#endif	1140	#endif
1014	if (dns->send_interval < MIN_SEND_INTERVAL)
1015	dns->send_interval = MIN_SEND_INTERVAL;
1016
1017	// the latency surely puts an upper bound on	1141	// the latency surely puts an upper bound on
1018	// the minimum send interval	1142	// the minimum send interval
1019	double latency = NOW - (*i)->sent;	1143	double latency = ev_now () - (*i)->sent;
		1144
		1145	if (latency < dns->min_latency)
1020	dns->last_latency = latency;	1146	dns->min_latency = latency;
1021		1147
1022	if (dns->send_interval > latency)	1148	if (dns->send_interval > dns->min_latency * conf.dns_overlap_factor)
		1149	dns->send_interval = dns->min_latency * conf.dns_overlap_factor;
		1150
		1151	if (dns->send_interval < conf.dns_send_interval)
1023	dns->send_interval = latency;	1152	dns->send_interval = conf.dns_send_interval;
1024	}	1153	}
1025		1154
1026	delete *i;	1155	delete *i;
1027	dns_sndpq.erase (i);	1156	dns_sndpq.erase (i);
1028		1157
…		…
1046	ttl \|= pkt [offs++] << 16;	1175	ttl \|= pkt [offs++] << 16;
1047	ttl \|= pkt [offs++] << 8;	1176	ttl \|= pkt [offs++] << 8;
1048	ttl \|= pkt [offs++];	1177	ttl \|= pkt [offs++];
1049	u16 rdlen = pkt [offs++] << 8; rdlen \|= pkt [offs++];	1178	u16 rdlen = pkt [offs++] << 8; rdlen \|= pkt [offs++];
1050		1179
1051	if (qtype == RR_TYPE_NULL \|\| qtype == RR_TYPE_TXT)	1180	if (qtype == RR_TYPE_NULL \|\| qtype == RR_TYPE_TXT \|\| qtype == dns->cfg.rrtype)
1052	{	1181	{
1053	if (rdlen <= MAXSIZE - offs)	1182	if (rdlen <= MAXSIZE - offs)
1054	{	1183	{
1055	// decode bytes, finally	1184	// decode bytes, finally
1056		1185
…		…
1082	{	1211	{
1083	slog (L_TRACE, _("DNS: got tunnel meta command %02x"), ip [3]);	1212	slog (L_TRACE, _("DNS: got tunnel meta command %02x"), ip [3]);
1084		1213
1085	if (ip [3] == CMD_IP_RST)	1214	if (ip [3] == CMD_IP_RST)
1086	{	1215	{
1087	slog (L_DEBUG, _("DNS: got tunnel RST request"));	1216	slog (L_DEBUG, _("DNS: got tunnel RST request."));
1088		1217
1089	delete dns; c->dns = 0;	1218	dns->reset ();
1090
1091	return;	1219	return;
1092	}	1220	}
1093	else if (ip [3] == CMD_IP_SYN)	1221	else if (ip [3] == CMD_IP_SYN)
1094	{	1222	{
1095	slog (L_DEBUG, _("DNS: got tunnel SYN reply, server likes us."));	1223	slog (L_DEBUG, _("DNS: got tunnel SYN reply, server likes us."));
1096	dns->established = true;	1224	dns->established = true;
1097	}	1225	}
		1226	else if (ip [3] == CMD_IP_CSE)
		1227	{
		1228	if (conf.dns_case_preserving)
		1229	{
		1230	slog (L_INFO, _("DNS: got tunnel CSE reply, globally downgrading to case-insensitive protocol."));
		1231	conf.dns_case_preserving = false;
		1232	dns->reset ();
		1233	return;
		1234	}
		1235	else
		1236	{
		1237	slog (L_DEBUG, _("DNS: got tunnel CSE reply, server likes us."));
		1238	dns->established = true;
		1239	}
		1240	}
1098	else if (ip [3] == CMD_IP_REJ)	1241	else if (ip [3] == CMD_IP_REJ)
1099	{	1242	{
1100	slog (L_DEBUG, _("DNS: got tunnel REJ reply, server does not like us, aborting."));	1243	slog (L_ERR, _("DNS: got tunnel REJ reply, server does not like us."));
1101	abort ();	1244	dns->tw.start (60.);
1102	}	1245	}
1103	else	1246	else
		1247	{
1104	slog (L_INFO, _("DNS: got unknown meta command %02x"), ip [3]);	1248	slog (L_INFO, _("DNS: got unknown meta command %02x"), ip [3]);
		1249	dns->tw.start (60.);
		1250	}
1105	}	1251	}
1106	else	1252	else
1107	slog (L_INFO, _("DNS: got spurious a record %d.%d.%d.%d"),	1253	slog (L_INFO, _("DNS: got spurious a record %d.%d.%d.%d"),
1108	ip [0], ip [1], ip [2], ip [3]);	1254	ip [0], ip [1], ip [2], ip [3]);
1109		1255
…		…
1127	}	1273	}
1128		1274
1129	// todo: pkt now used	1275	// todo: pkt now used
1130	if (datap)	1276	if (datap)
1131	dns->receive_rep (new dns_rcv (seqno, data, datap - data));	1277	dns->receive_rep (new dns_rcv (seqno, data, datap - data));
		1278	else if (dns_sndpq.empty ()) // no data received, and nothing to send - idle
		1279	{
		1280	dns->send_interval *= 1.1;
		1281
		1282	if (dns->send_interval < MIN_POLL_INTERVAL)
		1283	dns->send_interval = MIN_POLL_INTERVAL;
		1284
		1285	if (dns->send_interval > MAX_POLL_INTERVAL && !back_off)
		1286	dns->send_interval = MAX_POLL_INTERVAL;
		1287	}
1132		1288
1133	break;	1289	break;
1134	}	1290	}
1135	}	1291	}
1136		1292
1137	void	1293	void
1138	vpn::dnsv4_ev (io_watcher &w, short revents)	1294	vpn::dnsv4_ev (ev::io &w, int revents)
1139	{	1295	{
1140	if (revents & EVENT_READ)	1296	if (revents & EV_READ)
1141	{	1297	{
1142	dns_packet *pkt = new dns_packet;	1298	dns_packet *pkt = new dns_packet;
1143	struct sockaddr_in sa;	1299	struct sockaddr_in sa;
1144	socklen_t sa_len = sizeof (sa);	1300	socklen_t sa_len = sizeof (sa);
1145		1301
1146	pkt->len = recvfrom (w.fd, pkt->at (0), MAXSIZE, 0, (sockaddr *)&sa, &sa_len);	1302	pkt->len = recvfrom (w.fd, pkt->at (0), MAXSIZE, 0, (sockaddr *)&sa, &sa_len);
1147		1303
1148	if (pkt->len > 0)	1304	if (pkt->len > 0)
1149	{	1305	{
1150	if (THISNODE->dns_port)	1306	if (ntohs (pkt->flags) & FLAG_RESPONSE)
		1307	dnsv4_client (*pkt);
		1308	else
1151	{	1309	{
1152	dnsv4_server (*pkt);	1310	dnsv4_server (*pkt);
1153	sendto (w.fd, pkt->at (0), pkt->len, 0, (sockaddr *)&sa, sa_len);	1311	sendto (w.fd, pkt->at (0), pkt->len, 0, (sockaddr *)&sa, sa_len);
1154	}	1312	}
1155	else
1156	dnsv4_client (*pkt);
1157		1313
1158	delete pkt;	1314	delete pkt;
1159	}	1315	}
1160	}	1316	}
1161	}	1317	}
1162		1318
1163	bool	1319	bool
1164	vpn::send_dnsv4_packet (vpn_packet *pkt, const sockinfo &si, int tos)	1320	vpn::send_dnsv4_packet (vpn_packet *pkt, const sockinfo &si, int tos)
1165	{	1321	{
1166	int client = ntohs (si.port);	1322	int client = ntohl (si.host);
1167		1323
1168	assert (0 < client && client <= conns.size ());	1324	assert (0 < client && client <= conns.size ());
1169		1325
1170	connection *c = conns [client - 1];	1326	connection *c = conns [client - 1];
1171		1327
1172	if (!c->dns)	1328	if (!c->dns)
1173	c->dns = new dns_connection (c);	1329	c->dns = new dns_connection (c);
1174		1330
1175	if (!c->dns->snddq.put (pkt))	1331	if (c->dns->snddq.put (pkt))
1176	return false;
1177
1178	c->dns->tw.trigger ();	1332	c->dns->tw ();
1179		1333
		1334	// always return true even if the buffer overflows
1180	return true;	1335	return true;
1181	}	1336	}
1182		1337
		1338	#define NEXT(w) do { if (next > (w)) next = w; } while (0)
		1339
1183	void	1340	void
1184	connection::dnsv4_reset_connection ()	1341	dns_connection::time_cb (ev::timer &w, int revents)
1185	{
1186	//delete dns; dns = 0; //TODO
1187	}
1188
1189	#define NEXT(w) do { if (next > (w)) next = w; } while (0)
1190
1191	void
1192	dns_connection::time_cb (time_watcher &w)
1193	{	1342	{
1194	// servers have to be polled	1343	// servers have to be polled
1195	if (THISNODE->dns_port)	1344	if (THISNODE->dns_port)
1196	return;	1345	return;
1197		1346
1198	// check for timeouts and (re)transmit	1347	// check for timeouts and (re)transmit
1199	tstamp next = NOW + poll_interval;	1348	tstamp next = ev::now () + poll_interval;
1200	dns_snd *send = 0;	1349	dns_snd *send = 0;
1201		1350
1202	for (vector<dns_snd *>::iterator i = vpn->dns_sndpq.begin ();	1351	for (vector<dns_snd *>::iterator i = vpn->dns_sndpq.begin ();
1203	i != vpn->dns_sndpq.end ();	1352	i != vpn->dns_sndpq.end ();
1204	++i)	1353	++i)
1205	{	1354	{
1206	dns_snd r = i;	1355	dns_snd r = i;
1207		1356
1208	if (r->timeout <= NOW)	1357	if (r->timeout <= ev_now ())
1209	{	1358	{
1210	if (!send)	1359	if (!send)
1211	{	1360	{
1212	send = r;	1361	send = r;
1213		1362
1214	r->retry++;	1363	r->retry++;
1215	r->timeout = NOW + (r->retry * last_latency * 8.);	1364	r->timeout = ev_now () + (r->retry * min_latency * conf.dns_timeout_factor);
		1365	//printf ("RETRY %x (%d, %f)\n", r->seqno, r->retry, r->timeout - ev_now ());//D
1216		1366
1217	// the following code changes the query section a bit, forcing	1367	// the following code changes the query section a bit, forcing
1218	// the forwarder to generate a new request	1368	// the forwarder to generate a new request
1219	if (r->stdhdr)	1369	if (r->stdhdr)
1220	{
1221	//printf ("reencoded header for ID %d retry %d:%d:%d\n", htons (r->pkt->id), THISNODE->id, r->seqno, r->retry);printf ("reencoded header for ID %d retry %d:%d:%d\n", htons (r->pkt->id), THISNODE->id, r->seqno, r->retry);
1222	//encode_header ((char )r->pkt->at (6 2 + 1), THISNODE->id, r->seqno, r->retry);	1370	encode_header ((char )r->pkt->at (6 2 + 1), THISNODE->id, r->seqno, r->retry);
1223	}
1224	}	1371	}
1225	}	1372	}
1226	else	1373	else
1227	NEXT (r->timeout);	1374	NEXT (r->timeout);
1228	}	1375	}
1229		1376
1230	if (last_sent + send_interval <= NOW)
1231	{
1232	if (!send)	1377	if (!send)
		1378	{
		1379	// generate a new packet, if wise
		1380
		1381	if (!established)
1233	{	1382	{
1234	// generate a new packet, if wise	1383	if (vpn->dns_sndpq.empty ())
1235
1236	if (!established)
1237	{	1384	{
1238	if (vpn->dns_sndpq.empty ())
1239	{
1240	send = new dns_snd (this);	1385	send = new dns_snd (this);
1241		1386
1242	printf ("new conn %p %d\n", this, c->conf->id);//D
1243	cfg.reset (THISNODE->id);	1387	cfg.reset (THISNODE->id);
		1388	set_cfg ();
1244	send->gen_syn_req ();	1389	send->gen_syn_req ();
1245	}
1246	}	1390	}
1247	else if (vpn->dns_sndpq.size () < MAX_OUTSTANDING	1391	}
		1392	else if (vpn->dns_sndpq.size () < conf.dns_max_outstanding
1248	&& !SEQNO_EQ (rcvseq, sndseq - (MAX_WINDOW - 1)))	1393	&& !SEQNO_EQ (rcvseq, sndseq - (MAX_WINDOW - 1)))
		1394	{
		1395	if (last_sent + send_interval <= ev_now ())
1249	{	1396	{
1250	//printf ("sending data request etc.\n"); //D	1397	//printf ("sending data request etc.\n"); //D
1251	if (!snddq.empty ())	1398	if (!snddq.empty () \|\| last_received + 1. > ev_now ())
1252	{	1399	{
1253	poll_interval = send_interval;	1400	poll_interval = send_interval;
1254	NEXT (NOW + send_interval);	1401	NEXT (ev_now () + send_interval);
1255	}	1402	}
1256		1403
1257	send = new dns_snd (this);	1404	send = new dns_snd (this);
1258	send->gen_stream_req (sndseq, snddq);	1405	send->gen_stream_req (sndseq, snddq);
1259	send->timeout = NOW + last_latency * 8.;	1406	send->timeout = ev_now () + min_latency * conf.dns_timeout_factor;
		1407	//printf ("SEND %x (%f)\n", send->seqno, send->timeout - ev_now (), min_latency, conf.dns_timeout_factor);//D
1260		1408
1261	sndseq = (sndseq + 1) & SEQNO_MASK;	1409	sndseq = (sndseq + 1) & SEQNO_MASK;
1262	}	1410	}
1263		1411	else
1264	if (send)	1412	NEXT (last_sent + send_interval);
1265	vpn->dns_sndpq.push_back (send);
1266	}	1413	}
1267		1414
1268	if (send)	1415	if (send)
1269	{	1416	vpn->dns_sndpq.push_back (send);
1270	last_sent = NOW;	1417	}
		1418
		1419	if (send)
		1420	{
		1421	last_sent = ev_now ();
1271	sendto (vpn->dnsv4_fd,	1422	sendto (vpn->dnsv4_fd,
1272	send->pkt->at (0), send->pkt->len, 0,	1423	send->pkt->at (0), send->pkt->len, 0,
1273	vpn->dns_forwarder.sav4 (), vpn->dns_forwarder.salenv4 ());	1424	vpn->dns_forwarder.sav4 (), vpn->dns_forwarder.salenv4 ());
1274	}
1275	}	1425	}
1276	else
1277	NEXT (last_sent + send_interval);
1278		1426
1279	slog (L_NOISE, "DNS: pi %f si %f N %f (%d:%d)",	1427	slog (L_NOISE, "DNS: pi %f si %f N %f (%d:%d %d)",
1280	poll_interval, send_interval, next - NOW,	1428	poll_interval, send_interval, next - ev_now (),
1281	vpn->dns_sndpq.size (), snddq.size ());	1429	vpn->dns_sndpq.size (), snddq.size (),
		1430	rcvpq.size ());
1282		1431
1283	// TODO: no idea when this happens, but when next < NOW, we have a problem	1432	// TODO: no idea when this happens, but when next < ev_now (), we have a problem
		1433	// doesn't seem to happen anymore
1284	if (next < NOW + 0.0001)	1434	if (next < ev_now () + 0.001)
1285	next = NOW + 0.1;	1435	next = ev_now () + 0.1;
1286		1436
1287	w.start (next);	1437	w.start (next - ev_now ());
1288	}	1438	}
1289		1439
1290	#endif	1440	#endif
1291		1441

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Comparing gvpe/src/vpn_dns.C (file contents): Revision 1.19 by pcg, Sun Mar 6 18:34:46 2005 UTC vs. Revision 1.51 by root, Sun Mar 6 19:40:28 2011 UTC

Diff Legend

Comparing gvpe/src/vpn_dns.C (file contents):
Revision 1.19 by pcg, Sun Mar 6 18:34:46 2005 UTC vs.
Revision 1.51 by root, Sun Mar 6 19:40:28 2011 UTC