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noip.c (do_implicit_bind): Handle `SAME' impbind entries properly.
[preload-hacks] / noip.c
CommitLineData
1d1ccf4f
MW		 1/* -*-c-*-
2 *
3 * Make programs use Unix-domain sockets instead of IP
4 *
5 * (c) 2008 Straylight/Edgeware
6 */
7
8/*----- Licensing notice --------------------------------------------------*
9 *
10 * This file is part of the preload-hacks package.
11 *
12 * Preload-hacks are free software; you can redistribute it and/or modify
13 * them under the terms of the GNU General Public License as published by
14 * the Free Software Foundation; either version 2 of the License, or (at
15 * your option) any later version.
16 *
de6df72d
MW		 17 * Preload-hacks are distributed in the hope that it will be useful, but
18 * WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY
19 * or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
20 * for more details.
1d1ccf4f
MW		 21 *
22 * You should have received a copy of the GNU General Public License along
de6df72d
MW		 23 * with preload-hacks; if not, write to the Free Software Foundation, Inc.,
24 * 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA.
1d1ccf4f
MW		 25 */
26
e4976bb0 27#define _GNU_SOURCE
28#undef sun
29#undef SUN
30#define DEBUG
31
1d1ccf4f
MW		 32/*----- Header files ------------------------------------------------------*/
33
9314b85a 34#include <assert.h>
e4976bb0 35#include <ctype.h>
36#include <errno.h>
658c1774 37#include <stdarg.h>
9314b85a 38#include <stddef.h>
e4976bb0 39#include <stdio.h>
40#include <stdlib.h>
41
42#include <unistd.h>
43#include <dirent.h>
44#include <dlfcn.h>
45#include <fcntl.h>
46#include <pwd.h>
47
48#include <sys/ioctl.h>
49#include <sys/socket.h>
50#include <sys/stat.h>
51#include <sys/un.h>
52
53#include <netinet/in.h>
54#include <arpa/inet.h>
55#include <netinet/tcp.h>
56#include <netinet/udp.h>
9f1396d9 57#include <ifaddrs.h>
9314b85a 58#include <netdb.h>
e4976bb0 59
3fa60931
MW		 60#ifndef SUN_LEN
61# define SUN_LEN (sun) \
62 (strlen((sun)->sun_path) + offsetof(struct sockaddr_un, sun_path))
63#endif
64
1d1ccf4f
MW		 65/*----- Data structures ---------------------------------------------------*/
66
74eb4869
MW		 67/* Unix socket status values. */
68#define UNUSED 0u /* No sign of anyone using it */
69#define STALE 1u /* Socket exists, but is abandoned */
70#define USED 16u /* Socket is in active use */
97162e5b 71#define LISTEN 2u /* Socket has an active listener */
74eb4869 72
1d1ccf4f
MW		 73enum { DENY, ALLOW }; /* ACL verdicts */
74
2a06ea0b 75static int address_families[] = { AF_INET, AF_INET6, -1 };
9314b85a
MW		 76
77#define ADDRBUFSZ 64
78
79/* Address representations. */
80typedef union ipaddr {
81 struct in_addr v4;
2a06ea0b 82 struct in6_addr v6;
9314b85a
MW		 83} ipaddr;
84
85/* Convenient socket address hacking. */
86typedef union address {
87 struct sockaddr sa;
88 struct sockaddr_in sin;
2a06ea0b 89 struct sockaddr_in6 sin6;
9314b85a
MW		 90} address;
91
1d1ccf4f 92/* Access control list nodes */
e4976bb0 93typedef struct aclnode {
94 struct aclnode *next;
95 int act;
9314b85a
MW		 96 int af;
97 ipaddr minaddr, maxaddr;
e4976bb0 98 unsigned short minport, maxport;
99} aclnode;
100
7be80f86
MW		 101/* Implicit bind records */
102typedef struct impbind {
103 struct impbind *next;
104 int af, how;
105 ipaddr minaddr, maxaddr, bindaddr;
106} impbind;
107enum { EXPLICIT, SAME };
108
006dd63f
MW		 109/* A type for an address range */
110typedef struct addrrange {
111 int type;
112 union {
113 struct { int af; ipaddr min, max; } range;
114 } u;
115} addrrange;
116enum { EMPTY, ANY, LOCAL, RANGE };
117
1d1ccf4f 118/* Local address records */
9314b85a
MW		 119typedef struct full_ipaddr {
120 int af;
121 ipaddr addr;
122} full_ipaddr;
2a06ea0b 123#define MAX_LOCAL_IPADDRS 64
9314b85a 124static full_ipaddr local_ipaddrs[MAX_LOCAL_IPADDRS];
e4976bb0 125static int n_local_ipaddrs;
126
1d1ccf4f 127/* General configuration */
e4976bb0 128static uid_t uid;
129static char *sockdir = 0;
130static int debug = 0;
f6049fdd 131static unsigned minautoport = 16384, maxautoport = 65536;
e4976bb0 132
1d1ccf4f 133/* Access control lists */
e4976bb0 134static aclnode *bind_real, **bind_tail = &bind_real;
135static aclnode *connect_real, **connect_tail = &connect_real;
7be80f86 136static impbind *impbinds, **impbind_tail = &impbinds;
e4976bb0 137
1d1ccf4f 138/*----- Import the real versions of functions -----------------------------*/
e4976bb0 139
1d1ccf4f 140/* The list of functions to immport. */
e4976bb0 141#define IMPORTS(_) \
142 _(socket, int, (int, int, int)) \
143 _(socketpair, int, (int, int, int, int *)) \
144 _(connect, int, (int, const struct sockaddr *, socklen_t)) \
145 _(bind, int, (int, const struct sockaddr *, socklen_t)) \
146 _(accept, int, (int, struct sockaddr *, socklen_t *)) \
147 _(getsockname, int, (int, struct sockaddr *, socklen_t *)) \
148 _(getpeername, int, (int, struct sockaddr *, socklen_t *)) \
149 _(getsockopt, int, (int, int, int, void *, socklen_t *)) \
150 _(setsockopt, int, (int, int, int, const void *, socklen_t)) \
151 _(sendto, ssize_t, (int, const void *buf, size_t, int, \
152 const struct sockaddr *to, socklen_t tolen)) \
153 _(recvfrom, ssize_t, (int, void *buf, size_t, int, \
7d769c69 154 struct sockaddr *from, socklen_t *fromlen)) \
e4976bb0 155 _(sendmsg, ssize_t, (int, const struct msghdr *, int)) \
658c1774
MW		 156 _(recvmsg, ssize_t, (int, struct msghdr *, int)) \
157 _(ioctl, int, (int, unsigned long, ...))
e4976bb0 158
1d1ccf4f 159/* Function pointers to set up. */
e4976bb0 160#define DECL(imp, ret, args) static ret (*real_##imp) args;
161IMPORTS(DECL)
162#undef DECL
163
1d1ccf4f 164/* Import the system calls. */
e4976bb0 165static void import(void)
166{
167#define IMPORT(imp, ret, args) \
168 real_##imp = (ret (*)args)dlsym(RTLD_NEXT, #imp);
169 IMPORTS(IMPORT)
170#undef IMPORT
171}
172
1d1ccf4f 173/*----- Utilities ---------------------------------------------------------*/
e4976bb0 174
1d1ccf4f 175/* Socket address casts */
e4976bb0 176#define SA(sa) ((struct sockaddr *)(sa))
177#define SIN(sa) ((struct sockaddr_in *)(sa))
2a06ea0b 178#define SIN6(sa) ((struct sockaddr_in6 *)(sa))
e4976bb0 179#define SUN(sa) ((struct sockaddr_un *)(sa))
180
1d1ccf4f 181/* Raw bytes */
e4976bb0 182#define UC(ch) ((unsigned char)(ch))
183
1d1ccf4f 184/* Memory allocation */
e4976bb0 185#define NEW(x) ((x) = xmalloc(sizeof(*x)))
186#define NEWV(x, n) ((x) = xmalloc(sizeof(*x) * (n)))
187
1d1ccf4f 188/* Debugging */
e4976bb0 189#ifdef DEBUG
190# define D(body) { if (debug) { body } }
e397f0bd 191# define Dpid pid_t pid = debug ? getpid() : -1
e4976bb0 192#else
193# define D(body) ;
e397f0bd 194# define Dpid
e4976bb0 195#endif
196
1d1ccf4f 197/* Preservation of error status */
e4976bb0 198#define PRESERVING_ERRNO(body) do { \
199 int _err = errno; { body } errno = _err; \
200} while (0)
201
1d1ccf4f 202/* Allocate N bytes of memory; abort on failure. */
e4976bb0 203static void *xmalloc(size_t n)
204{
205 void *p;
206 if (!n) return (0);
3ef1fec9 207 if ((p = malloc(n)) == 0) { perror("malloc"); exit(127); }
e4976bb0 208 return (p);
209}
210
1d1ccf4f 211/* Allocate a copy of the null-terminated string P; abort on failure. */
e4976bb0 212static char *xstrdup(const char *p)
213{
214 size_t n = strlen(p) + 1;
215 char *q = xmalloc(n);
216 memcpy(q, p, n);
217 return (q);
218}
9314b85a
MW		 219
220/*----- Address-type hacking ----------------------------------------------*/
221
222/* If M is a simple mask, i.e., consists of a sequence of zero bits followed
223 * by a sequence of one bits, then return the length of the latter sequence
224 * (which may be zero); otherwise return -1.
225 */
226static int simple_mask_length(unsigned long m)
227{
228 int n = 0;
229
230 while (m & 1) { n++; m >>= 1; }
231 return (m ? -1 : n);
232}
233
234/* Answer whether AF is an interesting address family. */
235static int family_known_p(int af)
236{
237 switch (af) {
238 case AF_INET:
2a06ea0b 239 case AF_INET6:
9314b85a
MW		 240 return (1);
241 default:
242 return (0);
243 }
244}
245
246/* Return the socket address length for address family AF. */
247static socklen_t family_socklen(int af)
248{
249 switch (af) {
250 case AF_INET: return (sizeof(struct sockaddr_in));
2a06ea0b 251 case AF_INET6: return (sizeof(struct sockaddr_in6));
9314b85a
MW		 252 default: abort();
253 }
254}
255
256/* Return the width of addresses of kind AF. */
257static int address_width(int af)
258{
259 switch (af) {
260 case AF_INET: return 32;
2a06ea0b 261 case AF_INET6: return 128;
9314b85a
MW		 262 default: abort();
263 }
264}
265
266/* If addresses A and B share a common prefix then return its length;
267 * otherwise return -1.
268 */
269static int common_prefix_length(int af, const ipaddr *a, const ipaddr *b)
270{
271 switch (af) {
272 case AF_INET: {
273 unsigned long aa = ntohl(a->v4.s_addr), bb = ntohl(b->v4.s_addr);
274 unsigned long m = aa^bb;
275 if ((aa&m) == 0 && (bb&m) == m) return (32 - simple_mask_length(m));
276 else return (-1);
277 } break;
2a06ea0b
MW		 278 case AF_INET6: {
279 const uint8_t *aa = a->v6.s6_addr, *bb = b->v6.s6_addr;
280 unsigned m;
281 unsigned n;
282 int i;
283
284 for (i = 0; i < 16 && aa[i] == bb[i]; i++);
285 n = 8*i;
286 if (i < 16) {
287 m = aa[i]^bb[i];
288 if ((aa[i]&m) != 0 || (bb[i]&m) != m) return (-1);
289 n += 8 - simple_mask_length(m);
290 for (i++; i < 16; i++)
291 if (aa[i] || bb[i] != 0xff) return (-1);
292 }
293 return (n);
294 } break;
9314b85a
MW		 295 default:
296 abort();
297 }
298}
299
300/* Extract the port number (in host byte-order) from SA. */
301static int port_from_sockaddr(const struct sockaddr *sa)
302{
303 switch (sa->sa_family) {
304 case AF_INET: return (ntohs(SIN(sa)->sin_port));
2a06ea0b 305 case AF_INET6: return (ntohs(SIN6(sa)->sin6_port));
9314b85a
MW		 306 default: abort();
307 }
308}
309
310/* Store the port number PORT (in host byte-order) in SA. */
311static void port_to_sockaddr(struct sockaddr *sa, int port)
312{
313 switch (sa->sa_family) {
314 case AF_INET: SIN(sa)->sin_port = htons(port); break;
2a06ea0b 315 case AF_INET6: SIN6(sa)->sin6_port = htons(port); break;
9314b85a
MW		 316 default: abort();
317 }
318}
10cee633 319
9314b85a
MW		 320/* Extract the address part from SA and store it in A. */
321static void ipaddr_from_sockaddr(ipaddr *a, const struct sockaddr *sa)
322{
323 switch (sa->sa_family) {
324 case AF_INET: a->v4 = SIN(sa)->sin_addr; break;
2a06ea0b 325 case AF_INET6: a->v6 = SIN6(sa)->sin6_addr; break;
9314b85a
MW		 326 default: abort();
327 }
328}
329
7be80f86
MW		 330/* Store the address A in SA. */
331static void ipaddr_to_sockaddr(struct sockaddr *sa, const ipaddr *a)
332{
333 switch (sa->sa_family) {
334 case AF_INET:
335 SIN(sa)->sin_addr = a->v4;
336 break;
337 case AF_INET6:
338 SIN6(sa)->sin6_addr = a->v6;
339 SIN6(sa)->sin6_scope_id = 0;
340 SIN6(sa)->sin6_flowinfo = 0;
341 break;
342 default:
343 abort();
344 }
345}
346
9314b85a
MW		 347/* Copy a whole socket address about. */
348static void copy_sockaddr(struct sockaddr *sa_dst,
349 const struct sockaddr *sa_src)
350 { memcpy(sa_dst, sa_src, family_socklen(sa_src->sa_family)); }
351
a62e4ece
MW		 352/* Convert an AF_INET socket address into the equivalent IPv4-mapped AF_INET6
353 * address.
354 */
355static void map_ipv4_sockaddr(struct sockaddr_in6 *a6,
356 const struct sockaddr_in *a4)
357{
358 size_t i;
359 in_addr_t a = ntohl(a4->sin_addr.s_addr);
360
361 a6->sin6_family = AF_INET6;
362 a6->sin6_port = a4->sin_port;
363 a6->sin6_scope_id = 0;
364 a6->sin6_flowinfo = 0;
365 for (i = 0; i < 10; i++) a6->sin6_addr.s6_addr[i] = 0;
366 for (i = 10; i < 12; i++) a6->sin6_addr.s6_addr[i] = 0xff;
367 for (i = 0; i < 4; i++) a6->sin6_addr.s6_addr[15 - i] = (a >> 8*i)&0xff;
368}
369
370/* Convert an AF_INET6 socket address containing an IPv4-mapped IPv6 address
371 * into the equivalent AF_INET4 address. Return zero on success, or -1 if
372 * the address has the wrong form.
373 */
374static int unmap_ipv4_sockaddr(struct sockaddr_in *a4,
375 const struct sockaddr_in6 *a6)
376{
377 size_t i;
378 in_addr_t a;
379
380 for (i = 0; i < 10; i++) if (a6->sin6_addr.s6_addr[i] != 0) return (-1);
381 for (i = 10; i < 12; i++) if (a6->sin6_addr.s6_addr[i] != 0xff) return (-1);
382 for (i = 0, a = 0; i < 4; i++) a |= a6->sin6_addr.s6_addr[15 - i] << 8*i;
383 a4->sin_family = AF_INET;
384 a4->sin_port = a6->sin6_port;
385 a4->sin_addr.s_addr = htonl(a);
386 return (0);
387}
388
9314b85a
MW		 389/* Answer whether two addresses are equal. */
390static int ipaddr_equal_p(int af, const ipaddr *a, const ipaddr *b)
391{
392 switch (af) {
393 case AF_INET: return (a->v4.s_addr == b->v4.s_addr);
2a06ea0b 394 case AF_INET6: return (memcmp(a->v6.s6_addr, b->v6.s6_addr, 16) == 0);
9314b85a
MW		 395 default: abort();
396 }
397}
398
399/* Answer whether the address part of SA is between A and B (inclusive). We
400 * assume that SA has the correct address family.
401 */
402static int sockaddr_in_range_p(const struct sockaddr *sa,
403 const ipaddr *a, const ipaddr *b)
404{
405 switch (sa->sa_family) {
406 case AF_INET: {
407 unsigned long addr = ntohl(SIN(sa)->sin_addr.s_addr);
408 return (ntohl(a->v4.s_addr) <= addr &&
409 addr <= ntohl(b->v4.s_addr));
410 } break;
2a06ea0b
MW		 411 case AF_INET6: {
412 const uint8_t *ss = SIN6(sa)->sin6_addr.s6_addr;
413 const uint8_t *aa = a->v6.s6_addr, *bb = b->v6.s6_addr;
414 int h = 1, l = 1;
415 int i;
416
417 for (i = 0; h && l && i < 16; i++, ss++, aa++, bb++) {
418 if (*ss < *aa || *bb < *ss) return (0);
419 if (*aa < *ss) l = 0;
420 if (*ss < *bb) h = 0;
421 }
422 return (1);
423 } break;
9314b85a
MW		 424 default:
425 abort();
426 }
427}
428
429/* Fill in SA with the appropriate wildcard address. */
430static void wildcard_address(int af, struct sockaddr *sa)
431{
432 switch (af) {
433 case AF_INET: {
434 struct sockaddr_in *sin = SIN(sa);
435 memset(sin, 0, sizeof(*sin));
436 sin->sin_family = AF_INET;
437 sin->sin_port = 0;
438 sin->sin_addr.s_addr = INADDR_ANY;
439 } break;
2a06ea0b
MW		 440 case AF_INET6: {
441 struct sockaddr_in6 *sin6 = SIN6(sa);
dc2b0a44 442 memset(sin6, 0, sizeof(*sin6));
2a06ea0b
MW		 443 sin6->sin6_family = AF_INET6;
444 sin6->sin6_port = 0;
445 sin6->sin6_addr = in6addr_any;
446 sin6->sin6_scope_id = 0;
447 sin6->sin6_flowinfo = 0;
448 } break;
9314b85a
MW		 449 default:
450 abort();
451 }
452}
453
454/* Mask the address A, forcing all but the top PLEN bits to zero or one
455 * according to HIGHP.
456 */
457static void mask_address(int af, ipaddr *a, int plen, int highp)
458{
459 switch (af) {
460 case AF_INET: {
461 unsigned long addr = ntohl(a->v4.s_addr);
462 unsigned long mask = plen ? ~0ul << (32 - plen) : 0;
463 addr &= mask;
464 if (highp) addr |= ~mask;
465 a->v4.s_addr = htonl(addr & 0xffffffff);
466 } break;
2a06ea0b
MW		 467 case AF_INET6: {
468 int i = plen/8;
469 unsigned m = (0xff << (8 - plen%8)) & 0xff;
470 unsigned s = highp ? 0xff : 0;
471 if (m) {
472 a->v6.s6_addr[i] = (a->v6.s6_addr[i] & m) | (s & ~m);
473 i++;
474 }
475 for (; i < 16; i++) a->v6.s6_addr[i] = s;
476 } break;
9314b85a
MW		 477 default:
478 abort();
479 }
480}
481
482/* Write a presentation form of SA to BUF, a buffer of length SZ. LEN is the
483 * address length; if it's zero, look it up based on the address family.
484 * Return a pointer to the string (which might, in an emergency, be a static
485 * string rather than your buffer).
486 */
487static char *present_sockaddr(const struct sockaddr *sa, socklen_t len,
488 char *buf, size_t sz)
489{
490#define WANT(n_) do { if (sz < (n_)) goto nospace; } while (0)
491#define PUTC(c_) do { *buf++ = (c_); sz--; } while (0)
492
ad0f7002 493 if (!sa) return "<null-address>";
9314b85a
MW		 494 if (!sz) return "<no-space-in-buffer>";
495 if (!len) len = family_socklen(sa->sa_family);
496
497 switch (sa->sa_family) {
498 case AF_UNIX: {
499 struct sockaddr_un *sun = SUN(sa);
500 char *p = sun->sun_path;
501 size_t n = len - offsetof(struct sockaddr_un, sun_path);
502
503 assert(n);
504 if (*p == 0) {
505 WANT(1); PUTC('@');
506 p++; n--;
507 while (n) {
508 switch (*p) {
509 case 0: WANT(2); PUTC('\\'); PUTC('0'); break;
510 case '\a': WANT(2); PUTC('\\'); PUTC('a'); break;
511 case '\n': WANT(2); PUTC('\\'); PUTC('n'); break;
512 case '\r': WANT(2); PUTC('\\'); PUTC('r'); break;
513 case '\t': WANT(2); PUTC('\\'); PUTC('t'); break;
514 case '\v': WANT(2); PUTC('\\'); PUTC('v'); break;
515 case '\\': WANT(2); PUTC('\\'); PUTC('\\'); break;
516 default:
517 if (*p > ' ' && *p <= '~')
518 { WANT(1); PUTC(*p); }
519 else {
520 WANT(4); PUTC('\\'); PUTC('x');
521 PUTC((*p >> 4)&0xf); PUTC((*p >> 0)&0xf);
522 }
523 break;
524 }
525 p++; n--;
526 }
527 } else {
528 if (*p != '/') { WANT(2); PUTC('.'); PUTC('/'); }
529 while (n && *p) { WANT(1); PUTC(*p); p++; n--; }
530 }
531 WANT(1); PUTC(0);
532 } break;
2a06ea0b 533 case AF_INET: case AF_INET6: {
9314b85a
MW		 534 char addrbuf[NI_MAXHOST], portbuf[NI_MAXSERV];
535 int err = getnameinfo(sa, len,
536 addrbuf, sizeof(addrbuf),
537 portbuf, sizeof(portbuf),
538 NI_NUMERICHOST | NI_NUMERICSERV);
539 assert(!err);
540 snprintf(buf, sz, strchr(addrbuf, ':') ? "[%s]:%s" : "%s:%s",
541 addrbuf, portbuf);
542 } break;
543 default:
544 snprintf(buf, sz, "<unknown-address-family %d>", sa->sa_family);
545 break;
546 }
547 return (buf);
548
549nospace:
550 buf[sz - 1] = 0;
551 return (buf);
552}
553
554/* Guess the family of a textual socket address. */
555static int guess_address_family(const char *p)
2a06ea0b 556 { return (strchr(p, ':') ? AF_INET6 : AF_INET); }
9314b85a
MW		 557
558/* Parse a socket address P and write the result to SA. */
559static int parse_sockaddr(struct sockaddr *sa, const char *p)
560{
561 char buf[ADDRBUFSZ];
562 char *q;
563 struct addrinfo *ai, ai_hint = { 0 };
564
565 if (strlen(p) >= sizeof(buf) - 1) return (-1);
566 strcpy(buf, p); p = buf;
567 if (*p != '[') {
568 if ((q = strchr(p, ':')) == 0) return (-1);
569 *q++ = 0;
570 } else {
571 p++;
572 if ((q = strchr(p, ']')) == 0) return (-1);
573 *q++ = 0;
574 if (*q != ':') return (-1);
575 q++;
576 }
577
578 ai_hint.ai_family = AF_UNSPEC;
579 ai_hint.ai_socktype = SOCK_DGRAM;
580 ai_hint.ai_flags = AI_NUMERICHOST | AI_NUMERICSERV;
581 if (getaddrinfo(p, q, &ai_hint, &ai)) return (-1);
582 memcpy(sa, ai->ai_addr, ai->ai_addrlen);
583 freeaddrinfo(ai);
584 return (0);
585}
586
1d1ccf4f 587/*----- Access control lists ----------------------------------------------*/
e4976bb0 588
589#ifdef DEBUG
590
006dd63f 591static void dump_addrrange(int af, const ipaddr *min, const ipaddr *max)
e4976bb0 592{
9314b85a
MW		 593 char buf[ADDRBUFSZ];
594 const char *p;
595 int plen;
e4976bb0 596
006dd63f
MW		 597 plen = common_prefix_length(af, min, max);
598 p = inet_ntop(af, min, buf, sizeof(buf));
9314b85a
MW		 599 fprintf(stderr, strchr(p, ':') ? "[%s]" : "%s", p);
600 if (plen < 0) {
006dd63f 601 p = inet_ntop(af, &max, buf, sizeof(buf));
9314b85a 602 fprintf(stderr, strchr(p, ':') ? "-[%s]" : "-%s", p);
006dd63f 603 } else if (plen < address_width(af))
9314b85a 604 fprintf(stderr, "/%d", plen);
006dd63f
MW		 605}
606
607/* Write to standard error a description of the ACL node A. */
608static void dump_aclnode(const aclnode *a)
609{
610 fprintf(stderr, "noip(%d): %c ", getpid(), a->act ? '+' : '-');
611 dump_addrrange(a->af, &a->minaddr, &a->maxaddr);
e4976bb0 612 if (a->minport != 0 || a->maxport != 0xffff) {
613 fprintf(stderr, ":%u", (unsigned)a->minport);
614 if (a->minport != a->maxport)
615 fprintf(stderr, "-%u", (unsigned)a->maxport);
616 }
617 fputc('\n', stderr);
618}
619
bb182ccf 620static void dump_acl(const aclnode *a)
1d1ccf4f
MW		 621{
622 int act = ALLOW;
623
624 for (; a; a = a->next) {
625 dump_aclnode(a);
626 act = a->act;
627 }
e397f0bd 628 fprintf(stderr, "noip(%d): [default policy: %s]\n", getpid(),
1d1ccf4f
MW		 629 act == ALLOW ? "DENY" : "ALLOW");
630}
631
e4976bb0 632#endif
633
9314b85a 634/* Returns nonzero if the ACL A allows the socket address SA. */
bb182ccf 635static int acl_allows_p(const aclnode *a, const struct sockaddr *sa)
e4976bb0 636{
9314b85a 637 unsigned short port = port_from_sockaddr(sa);
e4976bb0 638 int act = ALLOW;
e397f0bd 639 Dpid;
e4976bb0 640
9314b85a 641 D({ char buf[ADDRBUFSZ];
e397f0bd 642 fprintf(stderr, "noip(%d): check %s\n", pid,
9314b85a 643 present_sockaddr(sa, 0, buf, sizeof(buf))); })
e4976bb0 644 for (; a; a = a->next) {
645 D( dump_aclnode(a); )
deedf22d
MW		 646 if (a->af == sa->sa_family &&
647 sockaddr_in_range_p(sa, &a->minaddr, &a->maxaddr) &&
e4976bb0 648 a->minport <= port && port <= a->maxport) {
e397f0bd
MW		 649 D( fprintf(stderr, "noip(%d): aha! %s\n", pid,
650 a->act ? "ALLOW" : "DENY"); )
e4976bb0 651 return (a->act);
652 }
653 act = a->act;
654 }
e397f0bd
MW		 655 D( fprintf(stderr, "noip(%d): nothing found: %s\n", pid,
656 act ? "DENY" : "ALLOW"); )
e4976bb0 657 return (!act);
658}
659
1d1ccf4f 660/*----- Socket address conversion -----------------------------------------*/
e4976bb0 661
1d1ccf4f 662/* Return a uniformly distributed integer between MIN and MAX inclusive. */
f6049fdd 663static unsigned randrange(unsigned min, unsigned max)
664{
665 unsigned mask, i;
666
667 /* It's so nice not to have to care about the quality of the generator
9314b85a
MW		 668 * much!
669 */
f6049fdd 670 max -= min;
671 for (mask = 1; mask < max; mask = (mask << 1) | 1)
672 ;
673 do i = rand() & mask; while (i > max);
674 return (i + min);
675}
676
1d1ccf4f
MW		 677/* Return the status of Unix-domain socket address SUN. Returns: UNUSED if
678 * the socket doesn't exist; USED if the path refers to an active socket, or
679 * isn't really a socket at all, or we can't tell without a careful search
680 * and QUICKP is set; or STALE if the file refers to a socket which isn't
681 * being used any more.
682 */
683static int unix_socket_status(struct sockaddr_un *sun, int quickp)
684{
685 struct stat st;
686 FILE *fp = 0;
687 size_t len, n;
688 int rc;
97162e5b 689 unsigned long f;
1d1ccf4f
MW		 690 char buf[256];
691
4b1a6174
MW		 692 /* If we can't find the socket node, then it's definitely not in use. If
693 * we get some other error, then this socket is weird.
694 */
1d1ccf4f
MW		 695 if (stat(sun->sun_path, &st))
696 return (errno == ENOENT ? UNUSED : USED);
4b1a6174
MW		 697
698 /* If it's not a socket, then something weird is going on. If we're just
699 * probing quickly to find a spare port, then existence is sufficient to
700 * discourage us now.
701 */
1d1ccf4f
MW		 702 if (!S_ISSOCK(st.st_mode) || quickp)
703 return (USED);
4b1a6174
MW		 704
705 /* The socket's definitely there, but is anyone actually still holding it
706 * open? The only way I know to discover this is to trundle through
707 * `/proc/net/unix'. If there's no entry, then the socket must be stale.
708 */
1d1ccf4f
MW		 709 rc = USED;
710 if ((fp = fopen("/proc/net/unix", "r")) == 0)
711 goto done;
72d85cdb 712 if (!fgets(buf, sizeof(buf), fp)) goto done; /* skip header */
1d1ccf4f 713 len = strlen(sun->sun_path);
61fbb4a5 714 rc = 0;
1d1ccf4f
MW		 715 while (fgets(buf, sizeof(buf), fp)) {
716 n = strlen(buf);
717 if (n >= len + 2 && buf[n - len - 2] == ' ' && buf[n - 1] == '\n' &&
61fbb4a5
MW		 718 memcmp(buf + n - len - 1, sun->sun_path, len) == 0) {
719 rc |= USED;
97162e5b
MW		 720 if (sscanf(buf, "%*s %*x %*x %lx", &f) < 0 || (f&0x00010000))
721 rc |= LISTEN;
61fbb4a5 722 }
1d1ccf4f
MW		 723 }
724 if (ferror(fp))
725 goto done;
61fbb4a5 726 if (!rc) rc = STALE;
1d1ccf4f
MW		 727done:
728 if (fp) fclose(fp);
4b1a6174
MW		 729
730 /* All done. */
1d1ccf4f
MW		 731 return (rc);
732}
733
81e3737d
MW		 734/* Encode SA as a Unix-domain address SUN, and return whether it's currently
735 * in use.
736 */
737static int encode_single_inet_addr(const struct sockaddr *sa,
738 struct sockaddr_un *sun,
739 int quickp)
740{
741 char buf[ADDRBUFSZ];
742 int rc;
743
744 snprintf(sun->sun_path, sizeof(sun->sun_path), "%s/%s", sockdir,
745 present_sockaddr(sa, 0, buf, sizeof(buf)));
c0ae47b3
MW		 746 rc = unix_socket_status(sun, quickp);
747 if (rc == STALE) unlink(sun->sun_path);
748 return (rc);
81e3737d
MW		 749}
750
f6e0ea86
MW		 751/* Convert the IP address SA to a Unix-domain address SUN. Fail if the
752 * address seems already taken. If DESPARATEP then try cleaning up stale old
753 * sockets.
754 */
755static int encode_unused_inet_addr(struct sockaddr *sa,
756 struct sockaddr_un *sun,
757 int desperatep)
758{
a62e4ece 759 address waddr, maddr;
f6e0ea86 760 struct sockaddr_un wsun;
d0e289af 761 int port = port_from_sockaddr(sa);
f6e0ea86 762
4b1a6174
MW		 763 /* First, look for an exact match. Only look quickly unless we're
764 * desperate. If the socket is in use, we fail here. (This could get
765 * racy. Let's not worry about that for now.)
766 */
74eb4869 767 if (encode_single_inet_addr(sa, sun, !desperatep)&USED)
81e3737d 768 return (-1);
f6e0ea86 769
4b1a6174
MW		 770 /* Next, check the corresponding wildcard address, so as to avoid
771 * inadvertant collisions with listeners. Do this in the same way.
772 */
f6e0ea86 773 wildcard_address(sa->sa_family, &waddr.sa);
d0e289af 774 port_to_sockaddr(&waddr.sa, port);
74eb4869 775 if (encode_single_inet_addr(&waddr.sa, &wsun, !desperatep)&USED)
81e3737d 776 return (-1);
f6e0ea86 777
a62e4ece
MW		 778 /* We're not done yet. If this is an IPv4 address, then /also/ check (a)
779 * the v6-mapped version, (b) the v6-mapped v4 wildcard, /and/ (c) the v6
780 * wildcard. Ugh!
781 */
782 if (sa->sa_family == AF_INET) {
783 map_ipv4_sockaddr(&maddr.sin6, SIN(&sa));
74eb4869 784 if (encode_single_inet_addr(&maddr.sa, &wsun, !desperatep)&USED)
a62e4ece
MW		 785 return (-1);
786
787 map_ipv4_sockaddr(&maddr.sin6, &waddr.sin);
74eb4869 788 if (encode_single_inet_addr(&maddr.sa, &wsun, !desperatep)&USED)
a62e4ece
MW		 789 return (-1);
790
791 wildcard_address(AF_INET6, &waddr.sa);
792 port_to_sockaddr(&waddr.sa, port);
74eb4869 793 if (encode_single_inet_addr(&waddr.sa, &wsun, !desperatep)&USED)
a62e4ece
MW		 794 return (-1);
795 }
796
4b1a6174 797 /* All is well. */
f6e0ea86
MW		 798 return (0);
799}
800
4b9d1fad
MW		 801/* Encode the Internet address SA as a Unix-domain address SUN. If the flag
802 * `ENCF_FRESH' is set, and SA's port number is zero, then we pick an
803 * arbitrary local port. Otherwise we pick the port given. There's an
804 * unpleasant hack to find servers bound to local wildcard addresses.
805 * Returns zero on success; -1 on failure.
1d1ccf4f 806 */
4b9d1fad 807#define ENCF_FRESH 1u
a59a964f 808#define ENCF_REUSEADDR 2u
e4976bb0 809static int encode_inet_addr(struct sockaddr_un *sun,
9314b85a 810 const struct sockaddr *sa,
4b9d1fad 811 unsigned f)
e4976bb0 812{
813 int i;
3ef1fec9 814 int desperatep = 0;
9314b85a 815 address addr;
a62e4ece 816 struct sockaddr_in6 sin6;
d0e289af 817 int port = port_from_sockaddr(sa);
74eb4869 818 int rc;
9314b85a 819 char buf[ADDRBUFSZ];
e4976bb0 820
e397f0bd 821 D( fprintf(stderr, "noip(%d): encode %s (%s)", getpid(),
9314b85a 822 present_sockaddr(sa, 0, buf, sizeof(buf)),
4b9d1fad 823 (f&ENCF_FRESH) ? "FRESH" : "EXISTING"); )
4b1a6174
MW		 824
825 /* Start making the Unix-domain address. */
e4976bb0 826 sun->sun_family = AF_UNIX;
4b1a6174 827
4b9d1fad 828 if (port || !(f&ENCF_FRESH)) {
4b1a6174
MW		 829
830 /* Try the address as given. If it's in use, or we don't necessarily
831 * want an existing socket, then we're done.
832 */
74eb4869 833 rc = encode_single_inet_addr(sa, sun, 0);
a59a964f 834 if ((f&ENCF_REUSEADDR) && !(rc&LISTEN)) unlink(sun->sun_path);
74eb4869 835 if ((rc&USED) || (f&ENCF_FRESH)) goto found;
4b1a6174 836
a62e4ece
MW		 837 /* We're looking for a socket which already exists. This is
838 * unfortunately difficult, because we must deal both with wildcards and
839 * v6-mapped IPv4 addresses.
840 *
841 * * We've just tried searching for a socket whose name is an exact
842 * match for our remote address. If the remote address is IPv4, then
843 * we should try again with the v6-mapped equivalent.
844 *
845 * * Failing that, we try again with the wildcard address for the
846 * appropriate address family.
847 *
848 * * Failing /that/, if the remote address is IPv4, then we try
849 * /again/, increasingly desperately, first with the v6-mapped IPv4
850 * wildcard address, and then with the IPv6 wildcard address. This
851 * will cause magic v6-mapping to occur when the connection is
852 * accepted, which we hope won't cause too much trouble.
4b1a6174 853 */
a62e4ece
MW		 854
855 if (sa->sa_family == AF_INET) {
856 map_ipv4_sockaddr(&addr.sin6, SIN(sa));
74eb4869 857 if (encode_single_inet_addr(&addr.sa, sun, 0)&USED) goto found;
a62e4ece
MW		 858 }
859
aed729d0
MW		 860 wildcard_address(sa->sa_family, &addr.sa);
861 port_to_sockaddr(&addr.sa, port);
74eb4869 862 if (encode_single_inet_addr(&addr.sa, sun, 0)&USED) goto found;
a62e4ece
MW		 863
864 if (sa->sa_family == AF_INET) {
865 map_ipv4_sockaddr(&sin6, &addr.sin);
74eb4869 866 if (encode_single_inet_addr(SA(&sin6), sun, 0)&USED) goto found;
a62e4ece
MW		 867 wildcard_address(AF_INET6, &addr.sa);
868 port_to_sockaddr(&addr.sa, port);
74eb4869 869 if (encode_single_inet_addr(&addr.sa, sun, 0)&USED) goto found;
a62e4ece
MW		 870 }
871
872 /* Well, this isn't going to work (unless a miraculous race is lost), but
873 * we might as well try.
874 */
875 encode_single_inet_addr(sa, sun, 1);
4b1a6174 876
e4976bb0 877 } else {
4b1a6174
MW		 878 /* We want a fresh new socket. */
879
880 /* Make a copy of the given address, because we're going to mangle it. */
9314b85a 881 copy_sockaddr(&addr.sa, sa);
4b1a6174
MW		 882
883 /* Try a few random-ish port numbers to see if any of them is spare. */
f6049fdd 884 for (i = 0; i < 10; i++) {
9314b85a 885 port_to_sockaddr(&addr.sa, randrange(minautoport, maxautoport));
f6e0ea86 886 if (!encode_unused_inet_addr(&addr.sa, sun, 0)) goto found;
f6049fdd 887 }
4b1a6174
MW		 888
889 /* Things must be getting tight. Work through all of the autoport range
890 * to see if we can find a spare one. The first time, just do it the
891 * quick way; if that doesn't work, then check harder for stale sockets.
892 */
3ef1fec9 893 for (desperatep = 0; desperatep < 2; desperatep++) {
f6049fdd 894 for (i = minautoport; i <= maxautoport; i++) {
9314b85a 895 port_to_sockaddr(&addr.sa, i);
f6e0ea86 896 if (!encode_unused_inet_addr(&addr.sa, sun, 0)) goto found;
e4976bb0 897 }
898 }
4b1a6174
MW		 899
900 /* We failed to find any free ports. */
e4976bb0 901 errno = EADDRINUSE;
902 D( fprintf(stderr, " -- can't resolve\n"); )
903 return (-1);
e4976bb0 904 }
4b1a6174
MW		 905
906 /* Success. */
5d8b1560 907found:
e4976bb0 908 D( fprintf(stderr, " -> `%s'\n", sun->sun_path); )
909 return (0);
910}
911
9314b85a 912/* Decode the Unix address SUN to an Internet address SIN. If AF_HINT is
c0876c8c
MW		 913 * nonzero, an empty address (indicative of an unbound Unix-domain socket) is
914 * translated to a wildcard Internet address of the appropriate family.
915 * Returns zero on success; -1 on failure (e.g., it wasn't one of our
916 * addresses).
00a98a8a 917 */
9314b85a 918static int decode_inet_addr(struct sockaddr *sa, int af_hint,
e4976bb0 919 const struct sockaddr_un *sun,
9314b85a 920 socklen_t len)
e4976bb0 921{
9314b85a 922 char buf[ADDRBUFSZ];
a2114371 923 size_t n = strlen(sockdir), nn;
9314b85a 924 address addr;
e4976bb0 925
9314b85a
MW		 926 if (!sa) sa = &addr.sa;
927 if (sun->sun_family != AF_UNIX) return (-1);
928 if (len > sizeof(*sun)) return (-1);
929 ((char *)sun)[len] = 0;
a2114371 930 nn = strlen(sun->sun_path);
e397f0bd 931 D( fprintf(stderr, "noip(%d): decode `%s'", getpid(), sun->sun_path); )
9314b85a
MW		 932 if (af_hint && !sun->sun_path[0]) {
933 wildcard_address(af_hint, sa);
e4976bb0 934 D( fprintf(stderr, " -- unbound socket\n"); )
935 return (0);
936 }
937 if (nn < n + 1 || nn - n >= sizeof(buf) || sun->sun_path[n] != '/' ||
938 memcmp(sun->sun_path, sockdir, n) != 0) {
939 D( fprintf(stderr, " -- not one of ours\n"); )
940 return (-1);
941 }
9314b85a
MW		 942 if (parse_sockaddr(sa, sun->sun_path + n + 1)) return (-1);
943 D( fprintf(stderr, " -> %s\n",
944 present_sockaddr(sa, 0, buf, sizeof(buf))); )
e4976bb0 945 return (0);
946}
947
1d1ccf4f
MW		 948/* SK is (or at least might be) a Unix-domain socket we created when an
949 * Internet socket was asked for. We've decided it should be an Internet
86134bfe
MW		 950 * socket after all, with family AF_HINT, so convert it. If TMP is not null,
951 * then don't replace the existing descriptor: store the new socket in *TMP
952 * and return zero.
1d1ccf4f 953 */
86134bfe 954static int fixup_real_ip_socket(int sk, int af_hint, int *tmp)
e4976bb0 955{
956 int nsk;
957 int type;
958 int f, fd;
959 struct sockaddr_un sun;
9314b85a 960 address addr;
e4976bb0 961 socklen_t len;
962
963#define OPTS(_) \
964 _(DEBUG, int) \
965 _(REUSEADDR, int) \
966 _(DONTROUTE, int) \
967 _(BROADCAST, int) \
968 _(SNDBUF, int) \
969 _(RCVBUF, int) \
970 _(OOBINLINE, int) \
971 _(NO_CHECK, int) \
972 _(LINGER, struct linger) \
973 _(BSDCOMPAT, int) \
974 _(RCVLOWAT, int) \
975 _(RCVTIMEO, struct timeval) \
976 _(SNDTIMEO, struct timeval)
977
978 len = sizeof(sun);
979 if (real_getsockname(sk, SA(&sun), &len))
980 return (-1);
9314b85a 981 if (decode_inet_addr(&addr.sa, af_hint, &sun, len))
e4976bb0 982 return (0); /* Not one of ours */
983 len = sizeof(type);
984 if (real_getsockopt(sk, SOL_SOCKET, SO_TYPE, &type, &len) < 0 ||
9314b85a 985 (nsk = real_socket(addr.sa.sa_family, type, 0)) < 0)
e4976bb0 986 return (-1);
987#define FIX(opt, ty) do { \
988 ty ov_; \
989 len = sizeof(ov_); \
990 if (real_getsockopt(sk, SOL_SOCKET, SO_##opt, &ov_, &len) < 0 || \
991 real_setsockopt(nsk, SOL_SOCKET, SO_##opt, &ov_, len)) { \
9fb8e5c9 992 close(nsk); \
e4976bb0 993 return (-1); \
994 } \
995} while (0);
996 OPTS(FIX)
997#undef FIX
86134bfe
MW		 998 if (tmp)
999 *tmp = nsk;
1000 else {
1001 if ((f = fcntl(sk, F_GETFL)) < 0 ||
1002 (fd = fcntl(sk, F_GETFD)) < 0 ||
1003 fcntl(nsk, F_SETFL, f) < 0 ||
1004 dup2(nsk, sk) < 0) {
1005 close(nsk);
1006 return (-1);
1007 }
1008 unlink(sun.sun_path);
9fb8e5c9 1009 close(nsk);
86134bfe
MW		 1010 if (fcntl(sk, F_SETFD, fd) < 0) {
1011 perror("noip: fixup_real_ip_socket F_SETFD");
1012 abort();
1013 }
e4976bb0 1014 }
1015 return (0);
1016}
1017
7be80f86
MW		 1018/* We found the real address SA, with length LEN; if it's a Unix-domain
1019 * address corresponding to a fake socket, convert it to cover up the
1020 * deception. Whatever happens, put the result at FAKE and store its length
1021 * at FAKELEN.
1022 */
a62e4ece 1023#define FNF_V6MAPPED 1u
7be80f86 1024static void return_fake_name(struct sockaddr *sa, socklen_t len,
a62e4ece
MW		 1025 struct sockaddr *fake, socklen_t *fakelen,
1026 unsigned f)
7be80f86
MW		 1027{
1028 address addr;
a62e4ece 1029 struct sockaddr_in6 sin6;
7be80f86
MW		 1030 socklen_t alen;
1031
1032 if (sa->sa_family == AF_UNIX &&
1033 !decode_inet_addr(&addr.sa, 0, SUN(sa), len)) {
a62e4ece
MW		 1034 if (addr.sa.sa_family != AF_INET || !(f&FNF_V6MAPPED)) {
1035 sa = &addr.sa;
1036 len = family_socklen(addr.sa.sa_family);
1037 } else {
1038 map_ipv4_sockaddr(&sin6, &addr.sin);
1039 sa = SA(&sin6);
1040 len = family_socklen(AF_INET6);
1041 }
7be80f86
MW		 1042 }
1043 alen = len;
1044 if (len > *fakelen) len = *fakelen;
1045 if (len > 0) memcpy(fake, sa, len);
1046 *fakelen = alen;
1047}
1048
a62e4ece
MW		 1049/* Variant of `return_fake_name' above, specifically handling the weirdness
1050 * of remote v6-mapped IPv4 addresses. If SK's fake local address is IPv6,
1051 * and the remote address is IPv4, then return a v6-mapped version of the
1052 * remote address.
1053 */
1054static void return_fake_peer(int sk, struct sockaddr *sa, socklen_t len,
1055 struct sockaddr *fake, socklen_t *fakelen)
1056{
1057 char sabuf[1024];
1058 socklen_t mylen = sizeof(sabuf);
1059 unsigned fnf = 0;
1060 address addr;
1061 int rc;
1062
1063 PRESERVING_ERRNO({
1064 rc = real_getsockname(sk, SA(sabuf), &mylen);
1065 if (!rc && sa->sa_family == AF_UNIX &&
1066 !decode_inet_addr(&addr.sa, 0, SUN(sabuf), mylen) &&
1067 addr.sa.sa_family == AF_INET6)
1068 fnf |= FNF_V6MAPPED;
1069 });
1070 return_fake_name(sa, len, fake, fakelen, fnf);
1071}
1072
7be80f86
MW		 1073/*----- Implicit binding --------------------------------------------------*/
1074
1075#ifdef DEBUG
1076
1077static void dump_impbind(const impbind *i)
1078{
1079 char buf[ADDRBUFSZ];
1080
1081 fprintf(stderr, "noip(%d): ", getpid());
1082 dump_addrrange(i->af, &i->minaddr, &i->maxaddr);
1083 switch (i->how) {
1084 case SAME: fprintf(stderr, " <self>"); break;
1085 case EXPLICIT:
1086 fprintf(stderr, " %s", inet_ntop(i->af, &i->bindaddr,
1087 buf, sizeof(buf)));
1088 break;
1089 default: abort();
1090 }
1091 fputc('\n', stderr);
1092}
1093
1094static void dump_impbind_list(void)
1095{
1096 const impbind *i;
1097
1098 for (i = impbinds; i; i = i->next) dump_impbind(i);
1099}
1100
1101#endif
1102
1d1ccf4f 1103/* The socket SK is about to be used to communicate with the remote address
9314b85a
MW		 1104 * SA. Assign it a local address so that getpeername(2) does something
1105 * useful.
a62e4ece
MW		 1106 *
1107 * If the flag `IBF_V6MAPPED' is set then, then SA must be an `AF_INET'
1108 * address; after deciding on the appropriate local address, convert it to be
1109 * an IPv4-mapped IPv6 address before final conversion to a Unix-domain
1110 * socket address and actually binding. Note that this could well mean that
1111 * the socket ends up bound to the v6-mapped v4 wildcard address
1112 * ::ffff:0.0.0.0, which looks very strange but is meaningful.
1d1ccf4f 1113 */
a62e4ece
MW		 1114#define IBF_V6MAPPED 1u
1115static int do_implicit_bind(int sk, const struct sockaddr *sa, unsigned f)
e4976bb0 1116{
9314b85a 1117 address addr;
a62e4ece 1118 struct sockaddr_in6 sin6;
6e1fe695 1119 struct sockaddr_un sun;
7be80f86
MW		 1120 const impbind *i;
1121 Dpid;
e4976bb0 1122
6e1fe695
MW		 1123 D( fprintf(stderr, "noip(%d): checking impbind list...\n", pid); )
1124 for (i = impbinds; i; i = i->next) {
1125 D( dump_impbind(i); )
1126 if (sa->sa_family == i->af &&
1127 sockaddr_in_range_p(sa, &i->minaddr, &i->maxaddr)) {
1128 D( fprintf(stderr, "noip(%d): match!\n", pid); )
1129 addr.sa.sa_family = sa->sa_family;
9111857c
MW		 1130 switch (i->how) {
1131 case EXPLICIT: ipaddr_to_sockaddr(&addr.sa, &i->bindaddr); break;
1132 case SAME: copy_sockaddr(&addr.sa, sa); break;
1133 }
662746a5 1134 port_to_sockaddr(&addr.sa, 0);
6e1fe695 1135 goto found;
e4976bb0 1136 }
1137 }
6e1fe695
MW		 1138 D( fprintf(stderr, "noip(%d): no match; using wildcard\n", pid); )
1139 wildcard_address(sa->sa_family, &addr.sa);
1140found:
a62e4ece
MW		 1141 if (addr.sa.sa_family != AF_INET || !(f&IBF_V6MAPPED)) sa = &addr.sa;
1142 else { map_ipv4_sockaddr(&sin6, &addr.sin); sa = SA(&sin6); }
1143 encode_inet_addr(&sun, sa, ENCF_FRESH);
43598265
MW		 1144 D( fprintf(stderr, "noip(%d): implicitly binding to %s\n",
1145 pid, sun.sun_path); )
6e1fe695
MW		 1146 if (real_bind(sk, SA(&sun), SUN_LEN(&sun))) return (-1);
1147 return (0);
1148}
1149
1150/* The socket SK is about to communicate with the remote address *SA. Ensure
1151 * that the socket has a local address, and adjust *SA to refer to the real
1152 * remote endpoint.
1153 *
1154 * If we need to translate the remote address, then the Unix-domain endpoint
1155 * address will end in *SUN, and *SA will be adjusted to point to it.
1156 */
1157static int fixup_client_socket(int sk, const struct sockaddr **sa_r,
1158 socklen_t *len_r, struct sockaddr_un *sun)
1159{
a62e4ece 1160 struct sockaddr_in sin;
6e1fe695
MW		 1161 socklen_t mylen = sizeof(*sun);
1162 const struct sockaddr *sa = *sa_r;
a62e4ece 1163 unsigned ibf = 0;
6e1fe695 1164
7d7cba35
MW		 1165 /* If this isn't a Unix-domain socket then there's nothing to do. */
1166 if (real_getsockname(sk, SA(sun), &mylen) < 0) return (-1);
1167 if (sun->sun_family != AF_UNIX) return (0);
1168 if (mylen < sizeof(*sun)) ((char *)sun)[mylen] = 0;
1169
a62e4ece
MW		 1170 /* If the remote address is v6-mapped IPv4, then unmap it so as to search
1171 * for IPv4 servers. Also remember to v6-map the local address when we
1172 * autobind.
1173 */
1174 if (sa->sa_family == AF_INET6 && !(unmap_ipv4_sockaddr(&sin, SIN6(sa)))) {
1175 sa = SA(&sin);
1176 ibf |= IBF_V6MAPPED;
1177 }
1178
6e1fe695
MW		 1179 /* If we're allowed to talk to a real remote endpoint, then fix things up
1180 * as necessary and proceed.
1181 */
1182 if (acl_allows_p(connect_real, sa)) {
1183 if (fixup_real_ip_socket(sk, (*sa_r)->sa_family, 0)) return (-1);
1184 return (0);
1185 }
1186
6e1fe695
MW		 1187 /* Speaking of which, if we don't have a local address, then we should
1188 * arrange one now.
1189 */
a62e4ece 1190 if (!sun->sun_path[0] && do_implicit_bind(sk, sa, ibf)) return (-1);
6e1fe695
MW		 1191
1192 /* And then come up with a remote address. */
1193 encode_inet_addr(sun, sa, 0);
1194 *sa_r = SA(sun);
1195 *len_r = SUN_LEN(sun);
e4976bb0 1196 return (0);
1197}
1198
1d1ccf4f 1199/*----- Configuration -----------------------------------------------------*/
e4976bb0 1200
1d1ccf4f 1201/* Return the process owner's home directory. */
e4976bb0 1202static char *home(void)
1203{
1204 char *p;
1205 struct passwd *pw;
1206
3ef1fec9 1207 if (getuid() == uid &&
1208 (p = getenv("HOME")) != 0)
1209 return (p);
1210 else if ((pw = getpwuid(uid)) != 0)
1211 return (pw->pw_dir);
1212 else
1213 return "/notexist";
e4976bb0 1214}
1215
1d1ccf4f 1216/* Return a good temporary directory to use. */
e4976bb0 1217static char *tmpdir(void)
1218{
1219 char *p;
1220
1221 if ((p = getenv("TMPDIR")) != 0) return (p);
1222 else if ((p = getenv("TMP")) != 0) return (p);
1223 else return ("/tmp");
1224}
1225
1d1ccf4f 1226/* Return the user's name, or at least something distinctive. */
e4976bb0 1227static char *user(void)
1228{
1229 static char buf[16];
1230 char *p;
1231 struct passwd *pw;
1232
1233 if ((p = getenv("USER")) != 0) return (p);
1234 else if ((p = getenv("LOGNAME")) != 0) return (p);
1235 else if ((pw = getpwuid(uid)) != 0) return (pw->pw_name);
1236 else {
1237 snprintf(buf, sizeof(buf), "uid-%lu", (unsigned long)uid);
1238 return (buf);
1239 }
1240}
1241
1d1ccf4f 1242/* Skip P over space characters. */
e4976bb0 1243#define SKIPSPC do { while (*p && isspace(UC(*p))) p++; } while (0)
1d1ccf4f
MW		 1244
1245/* Set Q to point to the next word following P, null-terminate it, and step P
1246 * past it. */
e4976bb0 1247#define NEXTWORD(q) do { \
1248 SKIPSPC; \
1249 q = p; \
1250 while (*p && !isspace(UC(*p))) p++; \
1251 if (*p) *p++ = 0; \
1252} while (0)
1d1ccf4f
MW		 1253
1254/* Set Q to point to the next dotted-quad address, store the ending delimiter
1255 * in DEL, null-terminate it, and step P past it. */
9314b85a
MW		 1256static void parse_nextaddr(char **pp, char **qq, int *del)
1257{
1258 char *p = *pp;
1259
1260 SKIPSPC;
1261 if (*p == '[') {
1262 p++; SKIPSPC;
1263 *qq = p;
1264 p += strcspn(p, "]");
1265 if (*p) *p++ = 0;
1266 *del = 0;
1267 } else {
1268 *qq = p;
1269 while (*p && (*p == '.' || isdigit(UC(*p)))) p++;
1270 *del = *p;
1271 if (*p) *p++ = 0;
1272 }
1273 *pp = p;
1274}
1d1ccf4f
MW		 1275
1276/* Set Q to point to the next decimal number, store the ending delimiter in
1277 * DEL, null-terminate it, and step P past it. */
e4976bb0 1278#define NEXTNUMBER(q, del) do { \
1279 SKIPSPC; \
1280 q = p; \
1281 while (*p && isdigit(UC(*p))) p++; \
1282 del = *p; \
1283 if (*p) *p++ = 0; \
1284} while (0)
1d1ccf4f
MW		 1285
1286/* Push the character DEL back so we scan it again, unless it's zero
1287 * (end-of-file). */
e4976bb0 1288#define RESCAN(del) do { if (del) *--p = del; } while (0)
1d1ccf4f
MW		 1289
1290/* Evaluate true if P is pointing to the word KW (and not some longer string
1291 * of which KW is a prefix). */
1292
e4976bb0 1293#define KWMATCHP(kw) (strncmp(p, kw, sizeof(kw) - 1) == 0 && \
1294 !isalnum(UC(p[sizeof(kw) - 1])) && \
1295 (p += sizeof(kw) - 1))
9f82ba1f 1296
1d1ccf4f
MW		 1297/* Parse a port list, starting at *PP. Port lists have the form
1298 * [:LOW[-HIGH]]: if omitted, all ports are included; if HIGH is omitted,
1299 * it's as if HIGH = LOW. Store LOW in *MIN, HIGH in *MAX and set *PP to the
1300 * rest of the string.
1301 */
e4976bb0 1302static void parse_ports(char **pp, unsigned short *min, unsigned short *max)
1303{
1304 char *p = *pp, *q;
1305 int del;
1306
1307 SKIPSPC;
f6049fdd 1308 if (*p != ':')
1309 { *min = 0; *max = 0xffff; }
1310 else {
e4976bb0 1311 p++;
f6049fdd 1312 NEXTNUMBER(q, del); *min = strtoul(q, 0, 0); RESCAN(del);
e4976bb0 1313 SKIPSPC;
f6049fdd 1314 if (*p == '-')
d83beb5c 1315 { p++; NEXTNUMBER(q, del); *max = strtoul(q, 0, 0); RESCAN(del); }
f6049fdd 1316 else
e4976bb0 1317 *max = *min;
1318 }
1319 *pp = p;
1320}
1321
006dd63f
MW		 1322/* Parse an address range designator starting at PP and store a
1323 * representation of it in R. An address range designator has the form:
1324 *
1325 * any | local | ADDR | ADDR - ADDR | ADDR/ADDR | ADDR/INT
1d1ccf4f 1326 */
006dd63f 1327static int parse_addrrange(char **pp, addrrange *r)
e4976bb0 1328{
006dd63f
MW		 1329 char *p = *pp, *q;
1330 int n;
e4976bb0 1331 int del;
006dd63f 1332 int af;
e4976bb0 1333
006dd63f
MW		 1334 SKIPSPC;
1335 if (KWMATCHP("any")) r->type = ANY;
1336 else if (KWMATCHP("local")) r->type = LOCAL;
1337 else {
1338 parse_nextaddr(&p, &q, &del);
1339 af = guess_address_family(q);
1340 if (inet_pton(af, q, &r->u.range.min) <= 0) goto bad;
1341 RESCAN(del);
a6d9626b 1342 SKIPSPC;
006dd63f
MW		 1343 if (*p == '-') {
1344 p++;
1345 parse_nextaddr(&p, &q, &del);
1346 if (inet_pton(af, q, &r->u.range.max) <= 0) goto bad;
1347 RESCAN(del);
1348 } else if (*p == '/') {
1349 p++;
1350 NEXTNUMBER(q, del);
1351 n = strtoul(q, 0, 0);
1352 r->u.range.max = r->u.range.min;
1353 mask_address(af, &r->u.range.min, n, 0);
1354 mask_address(af, &r->u.range.max, n, 1);
1355 RESCAN(del);
1356 } else
1357 r->u.range.max = r->u.range.min;
1358 r->type = RANGE;
1359 r->u.range.af = af;
1360 }
1361 *pp = p;
1362 return (0);
e4976bb0 1363
006dd63f
MW		 1364bad:
1365 return (-1);
1366}
1367
1368/* Call FUNC on each individual address range in R. */
1369static void foreach_addrrange(const addrrange *r,
1370 void (*func)(int af,
1371 const ipaddr *min,
1372 const ipaddr *max,
1373 void *p),
1374 void *p)
1375{
1376 ipaddr minaddr, maxaddr;
1377 int i, af;
1378
1379 switch (r->type) {
1380 case EMPTY:
1381 break;
1382 case ANY:
9314b85a
MW		 1383 for (i = 0; address_families[i] >= 0; i++) {
1384 af = address_families[i];
1385 memset(&minaddr, 0, sizeof(minaddr));
1386 maxaddr = minaddr; mask_address(af, &maxaddr, 0, 1);
006dd63f 1387 func(af, &minaddr, &maxaddr, p);
9314b85a 1388 }
006dd63f
MW		 1389 break;
1390 case LOCAL:
9314b85a
MW		 1391 for (i = 0; address_families[i] >= 0; i++) {
1392 af = address_families[i];
1393 memset(&minaddr, 0, sizeof(minaddr));
1394 maxaddr = minaddr; mask_address(af, &maxaddr, 0, 1);
006dd63f
MW		 1395 func(af, &minaddr, &minaddr, p);
1396 func(af, &maxaddr, &maxaddr, p);
9314b85a 1397 }
a6d9626b 1398 for (i = 0; i < n_local_ipaddrs; i++) {
006dd63f
MW		 1399 func(local_ipaddrs[i].af,
1400 &local_ipaddrs[i].addr, &local_ipaddrs[i].addr,
1401 p);
a6d9626b 1402 }
006dd63f
MW		 1403 break;
1404 case RANGE:
1405 func(r->u.range.af, &r->u.range.min, &r->u.range.max, p);
1406 break;
1407 default:
1408 abort();
1409 }
1410}
1411
1412struct add_aclnode_ctx {
1413 int act;
1414 unsigned short minport, maxport;
1415 aclnode ***tail;
1416};
1417
1418static void add_aclnode(int af, const ipaddr *min, const ipaddr *max,
1419 void *p)
1420{
1421 struct add_aclnode_ctx *ctx = p;
1422 aclnode *a;
1423
1424 NEW(a);
1425 a->act = ctx->act;
1426 a->af = af;
1427 a->minaddr = *min; a->maxaddr = *max;
1428 a->minport = ctx->minport; a->maxport = ctx->maxport;
1429 **ctx->tail = a; *ctx->tail = &a->next;
1430}
1431
1432/* Parse an ACL line. *PP points to the end of the line; *TAIL points to
1433 * the list tail (i.e., the final link in the list). An ACL entry has the
1434 * form +|- ADDR-RANGE PORTS
1435 * where PORTS is parsed by parse_ports above; an ACL line consists of a
1436 * comma-separated sequence of entries..
1437 */
1438static void parse_acl_line(char **pp, aclnode ***tail)
1439{
1440 struct add_aclnode_ctx ctx;
1441 addrrange r;
1442 char *p = *pp;
1443
1444 ctx.tail = tail;
1445 for (;;) {
1446 SKIPSPC;
1447 if (*p == '+') ctx.act = ALLOW;
1448 else if (*p == '-') ctx.act = DENY;
1449 else goto bad;
1450
1451 p++;
1452 if (parse_addrrange(&p, &r)) goto bad;
1453 parse_ports(&p, &ctx.minport, &ctx.maxport);
1454 foreach_addrrange(&r, add_aclnode, &ctx);
a6d9626b 1455 SKIPSPC;
1456 if (*p != ',') break;
1cce4a41 1457 if (*p) p++;
e4976bb0 1458 }
67fd355a 1459 if (*p) goto bad;
f797ea6d 1460 *pp = p;
e4976bb0 1461 return;
1462
1463bad:
e397f0bd 1464 D( fprintf(stderr, "noip(%d): bad acl spec (ignored)\n", getpid()); )
e4976bb0 1465 return;
1466}
1467
051fa2d8
MW		 1468/* Parse an ACL from an environment variable VAR, attaching it to the list
1469 * TAIL.
1470 */
1471static void parse_acl_env(const char *var, aclnode ***tail)
1472{
1473 char *p, *q;
1474
1475 if ((p = getenv(var)) != 0) {
1476 p = q = xstrdup(p);
1477 parse_acl_line(&q, tail);
1478 free(p);
1479 }
1480}
1481
7be80f86
MW		 1482struct add_impbind_ctx {
1483 int af, how;
1484 ipaddr addr;
1485};
1486
1487static void add_impbind(int af, const ipaddr *min, const ipaddr *max,
1488 void *p)
1489{
1490 struct add_impbind_ctx *ctx = p;
1491 impbind *i;
1492
1493 if (ctx->af && af != ctx->af) return;
1494 NEW(i);
1495 i->af = af;
1496 i->how = ctx->how;
1497 i->minaddr = *min; i->maxaddr = *max;
1498 switch (ctx->how) {
1499 case EXPLICIT: i->bindaddr = ctx->addr;
1500 case SAME: break;
1501 default: abort();
1502 }
1503 *impbind_tail = i; impbind_tail = &i->next;
1504}
1505
1506/* Parse an implicit-bind line. An implicit-bind entry has the form
1507 * ADDR-RANGE {ADDR | same}
1508 */
1509static void parse_impbind_line(char **pp)
1510{
1511 struct add_impbind_ctx ctx;
1512 char *p = *pp, *q;
1513 addrrange r;
1514 int del;
1515
1516 for (;;) {
1517 if (parse_addrrange(&p, &r)) goto bad;
1518 SKIPSPC;
1519 if (KWMATCHP("same")) {
1520 ctx.how = SAME;
1521 ctx.af = 0;
1522 } else {
1523 ctx.how = EXPLICIT;
1524 parse_nextaddr(&p, &q, &del);
1525 ctx.af = guess_address_family(q);
1526 if (inet_pton(ctx.af, q, &ctx.addr) < 0) goto bad;
1527 RESCAN(del);
1528 }
1529 foreach_addrrange(&r, add_impbind, &ctx);
1530 SKIPSPC;
1531 if (*p != ',') break;
1532 if (*p) p++;
1533 }
1534 if (*p) goto bad;
1535 *pp = p;
1536 return;
1537
1538bad:
1539 D( fprintf(stderr, "noip(%d): bad implicit-bind spec (ignored)\n",
1540 getpid()); )
1541 return;
1542}
1543
1544/* Parse implicit-bind instructions from an environment variable VAR,
1545 * attaching it to the list.
1546 */
1547static void parse_impbind_env(const char *var)
1548{
1549 char *p, *q;
1550
1551 if ((p = getenv(var)) != 0) {
1552 p = q = xstrdup(p);
1553 parse_impbind_line(&q);
1554 free(p);
1555 }
1556}
1557
1d1ccf4f 1558/* Parse the autoports configuration directive. Syntax is MIN - MAX. */
f6049fdd 1559static void parse_autoports(char **pp)
1560{
1561 char *p = *pp, *q;
1562 unsigned x, y;
1563 int del;
1564
1565 SKIPSPC;
1566 NEXTNUMBER(q, del); x = strtoul(q, 0, 0); RESCAN(del);
1567 SKIPSPC;
c6569cc9
MW		 1568 if (*p != '-') goto bad;
1569 p++;
f6049fdd 1570 NEXTNUMBER(q, del); y = strtoul(q, 0, 0); RESCAN(del);
1571 minautoport = x; maxautoport = y;
67fd355a 1572 SKIPSPC; if (*p) goto bad;
f797ea6d 1573 *pp = p;
f6049fdd 1574 return;
1575
1576bad:
e397f0bd 1577 D( fprintf(stderr, "noip(%d): bad port range (ignored)\n", getpid()); )
f6049fdd 1578 return;
1579}
1580
1d1ccf4f 1581/* Read the configuration from the config file and environment. */
e4976bb0 1582static void readconfig(void)
1583{
1584 FILE *fp;
1585 char buf[1024];
1586 size_t n;
f6049fdd 1587 char *p, *q, *cmd;
e397f0bd 1588 Dpid;
e4976bb0 1589
a6d9626b 1590 parse_acl_env("NOIP_REALBIND_BEFORE", &bind_tail);
1591 parse_acl_env("NOIP_REALCONNECT_BEFORE", &connect_tail);
7be80f86 1592 parse_impbind_env("NOIP_IMPBIND_BEFORE");
f6049fdd 1593 if ((p = getenv("NOIP_AUTOPORTS")) != 0) {
1594 p = q = xstrdup(p);
1595 parse_autoports(&q);
1596 free(p);
1597 }
4ab301de 1598 if ((p = getenv("NOIP_CONFIG")) == 0)
1599 snprintf(p = buf, sizeof(buf), "%s/.noip", home());
e397f0bd 1600 D( fprintf(stderr, "noip(%d): config file: %s\n", pid, p); )
4ab301de 1601
1602 if ((fp = fopen(p, "r")) == 0) {
e397f0bd
MW		 1603 D( fprintf(stderr, "noip(%d): couldn't read config: %s\n",
1604 pid, strerror(errno)); )
f6049fdd 1605 goto done;
4ab301de 1606 }
e4976bb0 1607 while (fgets(buf, sizeof(buf), fp)) {
1608 n = strlen(buf);
1609 p = buf;
1610
1611 SKIPSPC;
1612 if (!*p || *p == '#') continue;
1613 while (n && isspace(UC(buf[n - 1]))) n--;
1614 buf[n] = 0;
1615 NEXTWORD(cmd);
1616 SKIPSPC;
1617
1618 if (strcmp(cmd, "socketdir") == 0)
1619 sockdir = xstrdup(p);
1620 else if (strcmp(cmd, "realbind") == 0)
1621 parse_acl_line(&p, &bind_tail);
1622 else if (strcmp(cmd, "realconnect") == 0)
1623 parse_acl_line(&p, &connect_tail);
7be80f86
MW		 1624 else if (strcmp(cmd, "impbind") == 0)
1625 parse_impbind_line(&p);
f6049fdd 1626 else if (strcmp(cmd, "autoports") == 0)
1627 parse_autoports(&p);
e4976bb0 1628 else if (strcmp(cmd, "debug") == 0)
1629 debug = *p ? atoi(p) : 1;
1630 else
7be80f86 1631 D( fprintf(stderr, "noip(%d): bad config command %s\n", pid, cmd); )
e4976bb0 1632 }
1633 fclose(fp);
1634
1635done:
a6d9626b 1636 parse_acl_env("NOIP_REALBIND", &bind_tail);
1637 parse_acl_env("NOIP_REALCONNECT", &connect_tail);
7be80f86 1638 parse_impbind_env("NOIP_IMPBIND");
a6d9626b 1639 parse_acl_env("NOIP_REALBIND_AFTER", &bind_tail);
1640 parse_acl_env("NOIP_REALCONNECT_AFTER", &connect_tail);
7be80f86 1641 parse_impbind_env("NOIP_IMPBIND_AFTER");
e4976bb0 1642 *bind_tail = 0;
1643 *connect_tail = 0;
7be80f86 1644 *impbind_tail = 0;
a6d9626b 1645 if (!sockdir) sockdir = getenv("NOIP_SOCKETDIR");
e4976bb0 1646 if (!sockdir) {
1647 snprintf(buf, sizeof(buf), "%s/noip-%s", tmpdir(), user());
1648 sockdir = xstrdup(buf);
1649 }
e397f0bd
MW		 1650 D( fprintf(stderr, "noip(%d): socketdir: %s\n", pid, sockdir);
1651 fprintf(stderr, "noip(%d): autoports: %u-%u\n",
1652 pid, minautoport, maxautoport);
1653 fprintf(stderr, "noip(%d): realbind acl:\n", pid);
e4976bb0 1654 dump_acl(bind_real);
e397f0bd 1655 fprintf(stderr, "noip(%d): realconnect acl:\n", pid);
7be80f86
MW		 1656 dump_acl(connect_real);
1657 fprintf(stderr, "noip(%d): impbind list:\n", pid);
1658 dump_impbind_list(); )
e4976bb0 1659}
1660
1d1ccf4f 1661/*----- Overridden system calls -------------------------------------------*/
e4976bb0 1662
dc3956b3
MW		 1663static void dump_syserr(long rc)
1664 { fprintf(stderr, " => %ld (E%d)\n", rc, errno); }
1665
1666static void dump_sysresult(long rc)
1667{
1668 if (rc < 0) dump_syserr(rc);
1669 else fprintf(stderr, " => %ld\n", rc);
1670}
1671
1672static void dump_addrresult(long rc, const struct sockaddr *sa,
1673 socklen_t len)
1674{
1675 char addrbuf[ADDRBUFSZ];
1676
1677 if (rc < 0) dump_syserr(rc);
1678 else {
1679 fprintf(stderr, " => %ld [%s]\n", rc,
1680 present_sockaddr(sa, len, addrbuf, sizeof(addrbuf)));
1681 }
1682}
1683
e4976bb0 1684int socket(int pf, int ty, int proto)
1685{
dc3956b3
MW		 1686 int sk;
1687
1688 D( fprintf(stderr, "noip(%d): SOCKET pf=%d, type=%d, proto=%d",
1689 getpid(), pf, ty, proto); )
1690
8ce11853 1691 switch (pf) {
9314b85a
MW		 1692 default:
1693 if (!family_known_p(pf)) {
dc3956b3 1694 D( fprintf(stderr, " -> unknown; refuse\n"); )
9314b85a 1695 errno = EAFNOSUPPORT;
dc3956b3 1696 sk = -1;
9314b85a 1697 }
dc3956b3 1698 D( fprintf(stderr, " -> inet; substitute"); )
8ce11853
MW		 1699 pf = PF_UNIX;
1700 proto = 0;
dc3956b3 1701 break;
8ce11853 1702 case PF_UNIX:
41c50995
MW		 1703#ifdef PF_NETLINK
1704 case PF_NETLINK:
1705#endif
dc3956b3
MW		 1706 D( fprintf(stderr, " -> safe; permit"); )
1707 break;
e4976bb0 1708 }
dc3956b3
MW		 1709 sk = real_socket(pf, ty, proto);
1710 D( dump_sysresult(sk); )
1711 return (sk);
e4976bb0 1712}
1713
1714int socketpair(int pf, int ty, int proto, int *sk)
1715{
dc3956b3
MW		 1716 int rc;
1717
1718 D( fprintf(stderr, "noip(%d): SOCKETPAIR pf=%d, type=%d, proto=%d",
1719 getpid(), pf, ty, proto); )
1720 if (!family_known_p(pf))
1721 D( fprintf(stderr, " -> unknown; permit"); )
1722 else {
1723 D( fprintf(stderr, " -> inet; substitute"); )
e4976bb0 1724 pf = PF_UNIX;
1725 proto = 0;
1726 }
dc3956b3
MW		 1727 rc = real_socketpair(pf, ty, proto, sk);
1728 D( if (rc < 0) dump_syserr(rc);
1729 else fprintf(stderr, " => %d (%d, %d)\n", rc, sk[0], sk[1]); )
1730 return (rc);
e4976bb0 1731}
1732
1733int bind(int sk, const struct sockaddr *sa, socklen_t len)
1734{
1735 struct sockaddr_un sun;
dc3956b3 1736 int rc;
a59a964f
MW		 1737 unsigned f;
1738 int reusep;
1739 socklen_t n;
dc3956b3 1740 Dpid;
e4976bb0 1741
dc3956b3
MW		 1742 D({ char buf[ADDRBUFSZ];
1743 fprintf(stderr, "noip(%d): BIND sk=%d, sa[%d]=%s", pid,
1744 sk, len, present_sockaddr(sa, len, buf, sizeof(buf))); })
1745
1746 if (!family_known_p(sa->sa_family))
1747 D( fprintf(stderr, " -> unknown af; pass through"); )
1748 else {
1749 D( fprintf(stderr, " -> checking...\n"); )
e4976bb0 1750 PRESERVING_ERRNO({
9314b85a 1751 if (acl_allows_p(bind_real, sa)) {
86134bfe 1752 if (fixup_real_ip_socket(sk, sa->sa_family, 0))
e4976bb0 1753 return (-1);
1754 } else {
a59a964f
MW		 1755 f = ENCF_FRESH;
1756 n = sizeof(reusep);
1757 if (!getsockopt(sk, SOL_SOCKET, SO_REUSEADDR, &reusep, &n) && reusep)
1758 f |= ENCF_REUSEADDR;
1759 encode_inet_addr(&sun, sa, f);
e4976bb0 1760 sa = SA(&sun);
1761 len = SUN_LEN(&sun);
1762 }
1763 });
dc3956b3 1764 D( fprintf(stderr, "noip(%d): BIND ...", pid); )
e4976bb0 1765 }
dc3956b3
MW		 1766 rc = real_bind(sk, sa, len);
1767 D( dump_sysresult(rc); )
1768 return (rc);
e4976bb0 1769}
1770
1771int connect(int sk, const struct sockaddr *sa, socklen_t len)
1772{
1773 struct sockaddr_un sun;
53390eff 1774 int rc;
dc3956b3 1775 Dpid;
e4976bb0 1776
dc3956b3
MW		 1777 D({ char buf[ADDRBUFSZ];
1778 fprintf(stderr, "noip(%d): CONNECT sk=%d, sa[%d]=%s", pid,
1779 sk, len, present_sockaddr(sa, len, buf, sizeof(buf))); })
1780
1781 if (!family_known_p(sa->sa_family)) {
1782 D( fprintf(stderr, " -> unknown af; pass through"); )
9314b85a 1783 rc = real_connect(sk, sa, len);
dc3956b3
MW		 1784 } else {
1785 D( fprintf(stderr, " -> checking...\n"); )
9314b85a 1786 PRESERVING_ERRNO({
6e1fe695 1787 fixup_client_socket(sk, &sa, &len, &sun);
9314b85a 1788 });
dc3956b3 1789 D( fprintf(stderr, "noip(%d): CONNECT ...", pid); )
9314b85a
MW		 1790 rc = real_connect(sk, sa, len);
1791 if (rc < 0) {
1792 switch (errno) {
1793 case ENOENT: errno = ECONNREFUSED; break;
6df6f816 1794 }
9314b85a 1795 }
53390eff 1796 }
dc3956b3 1797 D( dump_sysresult(rc); )
9314b85a 1798 return (rc);
e4976bb0 1799}
1800
1801ssize_t sendto(int sk, const void *buf, size_t len, int flags,
1802 const struct sockaddr *to, socklen_t tolen)
1803{
1804 struct sockaddr_un sun;
dc3956b3
MW		 1805 ssize_t n;
1806 Dpid;
1807
1808 D({ char addrbuf[ADDRBUFSZ];
1809 fprintf(stderr, "noip(%d): SENDTO sk=%d, len=%lu, flags=%d, to[%d]=%s",
1810 pid, sk, (unsigned long)len, flags, tolen,
1811 present_sockaddr(to, tolen, addrbuf, sizeof(addrbuf))); })
e4976bb0 1812
dc3956b3
MW		 1813 if (!to)
1814 D( fprintf(stderr, " -> null address; leaving"); )
1815 else if (!family_known_p(to->sa_family))
1816 D( fprintf(stderr, " -> unknown af; pass through"); )
1817 else {
1818 D( fprintf(stderr, " -> checking...\n"); )
e4976bb0 1819 PRESERVING_ERRNO({
6e1fe695 1820 fixup_client_socket(sk, &to, &tolen, &sun);
e4976bb0 1821 });
dc3956b3 1822 D( fprintf(stderr, "noip(%d): SENDTO ...", pid); )
e4976bb0 1823 }
dc3956b3
MW		 1824 n = real_sendto(sk, buf, len, flags, to, tolen);
1825 D( dump_sysresult(n); )
1826 return (n);
e4976bb0 1827}
1828
1829ssize_t recvfrom(int sk, void *buf, size_t len, int flags,
1830 struct sockaddr *from, socklen_t *fromlen)
1831{
1832 char sabuf[1024];
1833 socklen_t mylen = sizeof(sabuf);
1834 ssize_t n;
dc3956b3 1835 Dpid;
e4976bb0 1836
dc3956b3
MW		 1837 D( fprintf(stderr, "noip(%d): RECVFROM sk=%d, len=%lu, flags=%d",
1838 pid, sk, (unsigned long)len, flags); )
1839
1840 if (!from) {
1841 D( fprintf(stderr, " -> null addr; pass through"); )
1842 n = real_recvfrom(sk, buf, len, flags, 0, 0);
1843 } else {
6ec34720
MW		 1844 n = real_recvfrom(sk, buf, len, flags, SA(sabuf), &mylen);
1845 if (n >= 0) {
1846 D( fprintf(stderr, " -> converting...\n"); )
1847 PRESERVING_ERRNO({
a62e4ece 1848 return_fake_peer(sk, SA(sabuf), mylen, from, fromlen);
6ec34720
MW		 1849 });
1850 D( fprintf(stderr, "noip(%d): ... RECVFROM", pid); )
1851 }
dc3956b3
MW		 1852 }
1853 D( dump_addrresult(n, from, fromlen ? *fromlen : 0); )
e4976bb0 1854 return (n);
1855}
1856
1857ssize_t sendmsg(int sk, const struct msghdr *msg, int flags)
1858{
1859 struct sockaddr_un sun;
dc3956b3 1860 const struct sockaddr *sa = SA(msg->msg_name);
e4976bb0 1861 struct msghdr mymsg;
dc3956b3
MW		 1862 ssize_t n;
1863 Dpid;
e4976bb0 1864
dc3956b3
MW		 1865 D({ char addrbuf[ADDRBUFSZ];
1866 fprintf(stderr, "noip(%d): SENDMSG sk=%d, "
1867 "msg_flags=%d, msg_name[%d]=%s, ...",
1868 pid, sk, msg->msg_flags, msg->msg_namelen,
1869 present_sockaddr(sa, msg->msg_namelen,
1870 addrbuf, sizeof(addrbuf))); })
1871
1872 if (!sa)
1873 D( fprintf(stderr, " -> null address; leaving"); )
1874 else if (!family_known_p(sa->sa_family))
1875 D( fprintf(stderr, " -> unknown af; pass through"); )
1876 else {
1877 D( fprintf(stderr, " -> checking...\n"); )
e4976bb0 1878 PRESERVING_ERRNO({
e4976bb0 1879 mymsg = *msg;
6e1fe695 1880 fixup_client_socket(sk, &sa, &mymsg.msg_namelen, &sun);
e4976bb0 1881 mymsg.msg_name = SA(sa);
1882 msg = &mymsg;
1883 });
dc3956b3 1884 D( fprintf(stderr, "noip(%d): SENDMSG ...", pid); )
e4976bb0 1885 }
dc3956b3
MW		 1886 n = real_sendmsg(sk, msg, flags);
1887 D( dump_sysresult(n); )
1888 return (n);
e4976bb0 1889}
1890
1891ssize_t recvmsg(int sk, struct msghdr *msg, int flags)
1892{
1893 char sabuf[1024];
dc3956b3
MW		 1894 struct sockaddr *sa = SA(msg->msg_name);
1895 socklen_t len = msg->msg_namelen;
e4976bb0 1896 ssize_t n;
dc3956b3 1897 Dpid;
e4976bb0 1898
dc3956b3
MW		 1899 D( fprintf(stderr, "noip(%d): RECVMSG sk=%d msg_flags=%d, ...",
1900 pid, sk, msg->msg_flags); )
1901
1902 if (!msg->msg_name) {
1903 D( fprintf(stderr, " -> null addr; pass through"); )
9314b85a 1904 return (real_recvmsg(sk, msg, flags));
dc3956b3 1905 } else {
6ec34720
MW		 1906 msg->msg_name = sabuf;
1907 msg->msg_namelen = sizeof(sabuf);
1908 n = real_recvmsg(sk, msg, flags);
1909 if (n >= 0) {
1910 D( fprintf(stderr, " -> converting...\n"); )
1911 PRESERVING_ERRNO({
a62e4ece 1912 return_fake_peer(sk, SA(sabuf), msg->msg_namelen, sa, &len);
6ec34720
MW		 1913 });
1914 }
1915 D( fprintf(stderr, "noip(%d): ... RECVMSG", pid); )
1916 msg->msg_name = sa;
1917 msg->msg_namelen = len;
dc3956b3
MW		 1918 }
1919 D( dump_addrresult(n, sa, len); )
e4976bb0 1920 return (n);
1921}
1922
1923int accept(int sk, struct sockaddr *sa, socklen_t *len)
1924{
1925 char sabuf[1024];
1926 socklen_t mylen = sizeof(sabuf);
dc3956b3
MW		 1927 int nsk;
1928 Dpid;
e4976bb0 1929
dc3956b3
MW		 1930 D( fprintf(stderr, "noip(%d): ACCEPT sk=%d", pid, sk); )
1931
1932 nsk = real_accept(sk, SA(sabuf), &mylen);
1933 if (nsk < 0) /* failed */;
1934 else if (!sa) D( fprintf(stderr, " -> address not wanted"); )
1935 else {
1936 D( fprintf(stderr, " -> converting...\n"); )
a62e4ece 1937 return_fake_peer(sk, SA(sabuf), mylen, sa, len);
dc3956b3
MW		 1938 D( fprintf(stderr, "noip(%d): ... ACCEPT", pid); )
1939 }
1940 D( dump_addrresult(nsk, sa, len ? *len : 0); )
e4976bb0 1941 return (nsk);
1942}
1943
1944int getsockname(int sk, struct sockaddr *sa, socklen_t *len)
1945{
0415c10e
MW		 1946 char sabuf[1024];
1947 socklen_t mylen = sizeof(sabuf);
dc3956b3
MW		 1948 int rc;
1949 Dpid;
1950
1951 D( fprintf(stderr, "noip(%d): GETSOCKNAME sk=%d", pid, sk); )
0415c10e
MW		 1952 rc = real_getsockname(sk, SA(sabuf), &mylen);
1953 if (rc >= 0) {
1954 D( fprintf(stderr, " -> converting...\n"); )
a62e4ece 1955 return_fake_name(SA(sabuf), mylen, sa, len, 0);
0415c10e
MW		 1956 D( fprintf(stderr, "noip(%d): ... GETSOCKNAME", pid); )
1957 }
dc3956b3
MW		 1958 D( dump_addrresult(rc, sa, *len); )
1959 return (rc);
e4976bb0 1960}
1961
1962int getpeername(int sk, struct sockaddr *sa, socklen_t *len)
1963{
0415c10e
MW		 1964 char sabuf[1024];
1965 socklen_t mylen = sizeof(sabuf);
dc3956b3
MW		 1966 int rc;
1967 Dpid;
1968
1969 D( fprintf(stderr, "noip(%d): GETPEERNAME sk=%d", pid, sk); )
0415c10e
MW		 1970 rc = real_getpeername(sk, SA(sabuf), &mylen);
1971 if (rc >= 0) {
1972 D( fprintf(stderr, " -> converting...\n"); )
a62e4ece 1973 return_fake_peer(sk, SA(sabuf), mylen, sa, len);
0415c10e
MW		 1974 D( fprintf(stderr, "noip(%d): ... GETPEERNAME", pid); )
1975 }
dc3956b3 1976 D( dump_addrresult(rc, sa, *len); )
6b6af30b 1977 return (rc);
e4976bb0 1978}
1979
1980int getsockopt(int sk, int lev, int opt, void *p, socklen_t *len)
1981{
1982 switch (lev) {
e32758ea 1983 case IPPROTO_IP:
f47a2b17 1984 case IPPROTO_IPV6:
e32758ea
MW		 1985 case IPPROTO_TCP:
1986 case IPPROTO_UDP:
e4976bb0 1987 if (*len > 0)
1988 memset(p, 0, *len);
1989 return (0);
1990 }
9314b85a 1991 return (real_getsockopt(sk, lev, opt, p, len));
e4976bb0 1992}
1993
1994int setsockopt(int sk, int lev, int opt, const void *p, socklen_t len)
1995{
1996 switch (lev) {
e32758ea 1997 case IPPROTO_IP:
f47a2b17 1998 case IPPROTO_IPV6:
e32758ea
MW		 1999 case IPPROTO_TCP:
2000 case IPPROTO_UDP:
e4976bb0 2001 return (0);
2002 }
2003 switch (opt) {
2004 case SO_BINDTODEVICE:
2005 case SO_ATTACH_FILTER:
2006 case SO_DETACH_FILTER:
2007 return (0);
2008 }
9314b85a 2009 return (real_setsockopt(sk, lev, opt, p, len));
e4976bb0 2010}
2011
658c1774
MW		 2012int ioctl(int fd, unsigned long op, ...)
2013{
2014 va_list ap;
2015 void *arg;
2016 int sk;
2017 int rc;
2018
2019 va_start(ap, op);
2020 arg = va_arg(ap, void *);
2021
2022 switch (op) {
2023 case SIOCGIFADDR:
2024 case SIOCGIFBRDADDR:
2025 case SIOCGIFDSTADDR:
2026 case SIOCGIFNETMASK:
2027 PRESERVING_ERRNO({
2028 if (fixup_real_ip_socket(fd, AF_INET, &sk)) goto real;
2029 });
2030 rc = real_ioctl(sk, op, arg);
2031 PRESERVING_ERRNO({ close(sk); });
2032 break;
2033 default:
2034 real:
2035 rc = real_ioctl(fd, op, arg);
2036 break;
2037 }
2038 va_end(ap);
2039 return (rc);
2040}
2041
1d1ccf4f 2042/*----- Initialization ----------------------------------------------------*/
e4976bb0 2043
1d1ccf4f 2044/* Clean up the socket directory, deleting stale sockets. */
e4976bb0 2045static void cleanup_sockdir(void)
2046{
2047 DIR *dir;
2048 struct dirent *d;
9314b85a 2049 address addr;
e4976bb0 2050 struct sockaddr_un sun;
3ef1fec9 2051 struct stat st;
e397f0bd 2052 Dpid;
e4976bb0 2053
9314b85a 2054 if ((dir = opendir(sockdir)) == 0) return;
4ab301de 2055 sun.sun_family = AF_UNIX;
e4976bb0 2056 while ((d = readdir(dir)) != 0) {
2057 if (d->d_name[0] == '.') continue;
2058 snprintf(sun.sun_path, sizeof(sun.sun_path),
2059 "%s/%s", sockdir, d->d_name);
9314b85a 2060 if (decode_inet_addr(&addr.sa, 0, &sun, SUN_LEN(&sun)) ||
3ef1fec9 2061 stat(sun.sun_path, &st) ||
4ab301de 2062 !S_ISSOCK(st.st_mode)) {
e397f0bd
MW		 2063 D( fprintf(stderr, "noip(%d): ignoring unknown socketdir entry `%s'\n",
2064 pid, sun.sun_path); )
3ef1fec9 2065 continue;
4ab301de 2066 }
e4976bb0 2067 if (unix_socket_status(&sun, 0) == STALE) {
e397f0bd
MW		 2068 D( fprintf(stderr, "noip(%d): clearing away stale socket %s\n",
2069 pid, d->d_name); )
e4976bb0 2070 unlink(sun.sun_path);
2071 }
2072 }
2073 closedir(dir);
2074}
2075
1d1ccf4f
MW		 2076/* Find the addresses attached to local network interfaces, and remember them
2077 * in a table.
2078 */
e4976bb0 2079static void get_local_ipaddrs(void)
2080{
9f1396d9 2081 struct ifaddrs *ifa_head, *ifa;
9314b85a 2082 ipaddr a;
e4976bb0 2083 int i;
e397f0bd 2084 Dpid;
e4976bb0 2085
e397f0bd 2086 D( fprintf(stderr, "noip(%d): fetching local addresses...\n", pid); )
9f1396d9
MW		 2087 if (getifaddrs(&ifa_head)) { perror("getifaddrs"); return; }
2088 for (n_local_ipaddrs = 0, ifa = ifa_head;
2089 n_local_ipaddrs < MAX_LOCAL_IPADDRS && ifa;
2090 ifa = ifa->ifa_next) {
9314b85a 2091 if (!ifa->ifa_addr || !family_known_p(ifa->ifa_addr->sa_family))
e4976bb0 2092 continue;
9314b85a
MW		 2093 ipaddr_from_sockaddr(&a, ifa->ifa_addr);
2094 D({ char buf[ADDRBUFSZ];
e397f0bd
MW		 2095 fprintf(stderr, "noip(%d): local addr %s = %s", pid,
2096 ifa->ifa_name,
9314b85a
MW		 2097 inet_ntop(ifa->ifa_addr->sa_family, &a,
2098 buf, sizeof(buf))); })
9f1396d9 2099 for (i = 0; i < n_local_ipaddrs; i++) {
9314b85a
MW		 2100 if (ifa->ifa_addr->sa_family == local_ipaddrs[i].af &&
2101 ipaddr_equal_p(local_ipaddrs[i].af, &a, &local_ipaddrs[i].addr)) {
9f1396d9
MW		 2102 D( fprintf(stderr, " (duplicate)\n"); )
2103 goto skip;
2104 }
2105 }
2106 D( fprintf(stderr, "\n"); )
9314b85a
MW		 2107 local_ipaddrs[n_local_ipaddrs].af = ifa->ifa_addr->sa_family;
2108 local_ipaddrs[n_local_ipaddrs].addr = a;
9f1396d9
MW		 2109 n_local_ipaddrs++;
2110 skip:;
e4976bb0 2111 }
9f1396d9 2112 freeifaddrs(ifa_head);
e4976bb0 2113}
2114
1d1ccf4f 2115/* Print the given message to standard error. Avoids stdio. */
72d85cdb 2116static void printerr(const char *p)
65f3786c 2117 { if (write(STDERR_FILENO, p, strlen(p))) ; }
3ef1fec9 2118
1d1ccf4f 2119/* Create the socket directory, being careful about permissions. */
3ef1fec9 2120static void create_sockdir(void)
2121{
2122 struct stat st;
2123
b514afdd 2124 if (lstat(sockdir, &st)) {
3ef1fec9 2125 if (errno == ENOENT) {
2126 if (mkdir(sockdir, 0700)) {
2127 perror("noip: creating socketdir");
2128 exit(127);
2129 }
b514afdd 2130 if (!lstat(sockdir, &st))
3ef1fec9 2131 goto check;
2132 }
2133 perror("noip: checking socketdir");
2134 exit(127);
2135 }
2136check:
2137 if (!S_ISDIR(st.st_mode)) {
2138 printerr("noip: bad socketdir: not a directory\n");
2139 exit(127);
2140 }
2141 if (st.st_uid != uid) {
2142 printerr("noip: bad socketdir: not owner\n");
2143 exit(127);
2144 }
2145 if (st.st_mode & 077) {
2146 printerr("noip: bad socketdir: not private\n");
2147 exit(127);
2148 }
2149}
2150
1d1ccf4f
MW		 2151/* Initialization function. */
2152static void setup(void) __attribute__((constructor));
e4976bb0 2153static void setup(void)
2154{
2155 PRESERVING_ERRNO({
2156 char *p;
2157
2158 import();
3ef1fec9 2159 uid = geteuid();
e4976bb0 2160 if ((p = getenv("NOIP_DEBUG")) && atoi(p))
2161 debug = 1;
2162 get_local_ipaddrs();
2163 readconfig();
3ef1fec9 2164 create_sockdir();
e4976bb0 2165 cleanup_sockdir();
2166 });
2167}
1d1ccf4f
MW		 2168
2169/*----- That's all, folks -------------------------------------------------*/
LD_PRELOAD hacks