1 /* 2 * ntp_request.c - respond to information requests 3 */ 4 5 #ifdef HAVE_CONFIG_H 6 # include <config.h> 7 #endif 8 9 #include "ntpd.h" 10 #include "ntp_io.h" 11 #include "ntp_request.h" 12 #include "ntp_control.h" 13 #include "ntp_refclock.h" 14 #include "ntp_if.h" 15 #include "ntp_stdlib.h" 16 #include "ntp_assert.h" 17 18 #include <stdio.h> 19 #include <stddef.h> 20 #include <signal.h> 21 #ifdef HAVE_NETINET_IN_H 22 #include <netinet/in.h> 23 #endif 24 #include <arpa/inet.h> 25 26 #include "recvbuff.h" 27 28 #ifdef KERNEL_PLL 29 #include "ntp_syscall.h" 30 #endif /* KERNEL_PLL */ 31 32 /* 33 * Structure to hold request procedure information 34 */ 35 #define NOAUTH 0 36 #define AUTH 1 37 38 #define NO_REQUEST (-1) 39 /* 40 * Because we now have v6 addresses in the messages, we need to compensate 41 * for the larger size. Therefore, we introduce the alternate size to 42 * keep us friendly with older implementations. A little ugly. 43 */ 44 static int client_v6_capable = 0; /* the client can handle longer messages */ 45 46 #define v6sizeof(type) (client_v6_capable ? sizeof(type) : v4sizeof(type)) 47 48 struct req_proc { 49 short request_code; /* defined request code */ 50 short needs_auth; /* true when authentication needed */ 51 short sizeofitem; /* size of request data item (older size)*/ 52 short v6_sizeofitem; /* size of request data item (new size)*/ 53 void (*handler) (sockaddr_u *, endpt *, 54 struct req_pkt *); /* routine to handle request */ 55 }; 56 57 /* 58 * Universal request codes 59 */ 60 static const struct req_proc univ_codes[] = { 61 { NO_REQUEST, NOAUTH, 0, 0, NULL } 62 }; 63 64 static void req_ack (sockaddr_u *, endpt *, struct req_pkt *, int); 65 static void * prepare_pkt (sockaddr_u *, endpt *, 66 struct req_pkt *, size_t); 67 static void * more_pkt (void); 68 static void flush_pkt (void); 69 static void list_peers (sockaddr_u *, endpt *, struct req_pkt *); 70 static void list_peers_sum (sockaddr_u *, endpt *, struct req_pkt *); 71 static void peer_info (sockaddr_u *, endpt *, struct req_pkt *); 72 static void peer_stats (sockaddr_u *, endpt *, struct req_pkt *); 73 static void sys_info (sockaddr_u *, endpt *, struct req_pkt *); 74 static void sys_stats (sockaddr_u *, endpt *, struct req_pkt *); 75 static void mem_stats (sockaddr_u *, endpt *, struct req_pkt *); 76 static void io_stats (sockaddr_u *, endpt *, struct req_pkt *); 77 static void timer_stats (sockaddr_u *, endpt *, struct req_pkt *); 78 static void loop_info (sockaddr_u *, endpt *, struct req_pkt *); 79 static void do_conf (sockaddr_u *, endpt *, struct req_pkt *); 80 static void do_unconf (sockaddr_u *, endpt *, struct req_pkt *); 81 static void set_sys_flag (sockaddr_u *, endpt *, struct req_pkt *); 82 static void clr_sys_flag (sockaddr_u *, endpt *, struct req_pkt *); 83 static void setclr_flags (sockaddr_u *, endpt *, struct req_pkt *, u_long); 84 static void list_restrict4 (const restrict_u *, struct info_restrict **); 85 static void list_restrict6 (const restrict_u *, struct info_restrict **); 86 static void list_restrict (sockaddr_u *, endpt *, struct req_pkt *); 87 static void do_resaddflags (sockaddr_u *, endpt *, struct req_pkt *); 88 static void do_ressubflags (sockaddr_u *, endpt *, struct req_pkt *); 89 static void do_unrestrict (sockaddr_u *, endpt *, struct req_pkt *); 90 static void do_restrict (sockaddr_u *, endpt *, struct req_pkt *, restrict_op); 91 static void mon_getlist (sockaddr_u *, endpt *, struct req_pkt *); 92 static void reset_stats (sockaddr_u *, endpt *, struct req_pkt *); 93 static void reset_peer (sockaddr_u *, endpt *, struct req_pkt *); 94 static void do_key_reread (sockaddr_u *, endpt *, struct req_pkt *); 95 static void trust_key (sockaddr_u *, endpt *, struct req_pkt *); 96 static void untrust_key (sockaddr_u *, endpt *, struct req_pkt *); 97 static void do_trustkey (sockaddr_u *, endpt *, struct req_pkt *, u_long); 98 static void get_auth_info (sockaddr_u *, endpt *, struct req_pkt *); 99 static void req_get_traps (sockaddr_u *, endpt *, struct req_pkt *); 100 static void req_set_trap (sockaddr_u *, endpt *, struct req_pkt *); 101 static void req_clr_trap (sockaddr_u *, endpt *, struct req_pkt *); 102 static void do_setclr_trap (sockaddr_u *, endpt *, struct req_pkt *, int); 103 static void set_request_keyid (sockaddr_u *, endpt *, struct req_pkt *); 104 static void set_control_keyid (sockaddr_u *, endpt *, struct req_pkt *); 105 static void get_ctl_stats (sockaddr_u *, endpt *, struct req_pkt *); 106 static void get_if_stats (sockaddr_u *, endpt *, struct req_pkt *); 107 static void do_if_reload (sockaddr_u *, endpt *, struct req_pkt *); 108 #ifdef KERNEL_PLL 109 static void get_kernel_info (sockaddr_u *, endpt *, struct req_pkt *); 110 #endif /* KERNEL_PLL */ 111 #ifdef REFCLOCK 112 static void get_clock_info (sockaddr_u *, endpt *, struct req_pkt *); 113 static void set_clock_fudge (sockaddr_u *, endpt *, struct req_pkt *); 114 #endif /* REFCLOCK */ 115 #ifdef REFCLOCK 116 static void get_clkbug_info (sockaddr_u *, endpt *, struct req_pkt *); 117 #endif /* REFCLOCK */ 118 119 /* 120 * ntpd request codes 121 */ 122 static const struct req_proc ntp_codes[] = { 123 { REQ_PEER_LIST, NOAUTH, 0, 0, list_peers }, 124 { REQ_PEER_LIST_SUM, NOAUTH, 0, 0, list_peers_sum }, 125 { REQ_PEER_INFO, NOAUTH, v4sizeof(struct info_peer_list), 126 sizeof(struct info_peer_list), peer_info}, 127 { REQ_PEER_STATS, NOAUTH, v4sizeof(struct info_peer_list), 128 sizeof(struct info_peer_list), peer_stats}, 129 { REQ_SYS_INFO, NOAUTH, 0, 0, sys_info }, 130 { REQ_SYS_STATS, NOAUTH, 0, 0, sys_stats }, 131 { REQ_IO_STATS, NOAUTH, 0, 0, io_stats }, 132 { REQ_MEM_STATS, NOAUTH, 0, 0, mem_stats }, 133 { REQ_LOOP_INFO, NOAUTH, 0, 0, loop_info }, 134 { REQ_TIMER_STATS, NOAUTH, 0, 0, timer_stats }, 135 { REQ_CONFIG, AUTH, v4sizeof(struct conf_peer), 136 sizeof(struct conf_peer), do_conf }, 137 { REQ_UNCONFIG, AUTH, v4sizeof(struct conf_unpeer), 138 sizeof(struct conf_unpeer), do_unconf }, 139 { REQ_SET_SYS_FLAG, AUTH, sizeof(struct conf_sys_flags), 140 sizeof(struct conf_sys_flags), set_sys_flag }, 141 { REQ_CLR_SYS_FLAG, AUTH, sizeof(struct conf_sys_flags), 142 sizeof(struct conf_sys_flags), clr_sys_flag }, 143 { REQ_GET_RESTRICT, NOAUTH, 0, 0, list_restrict }, 144 { REQ_RESADDFLAGS, AUTH, v4sizeof(struct conf_restrict), 145 sizeof(struct conf_restrict), do_resaddflags }, 146 { REQ_RESSUBFLAGS, AUTH, v4sizeof(struct conf_restrict), 147 sizeof(struct conf_restrict), do_ressubflags }, 148 { REQ_UNRESTRICT, AUTH, v4sizeof(struct conf_restrict), 149 sizeof(struct conf_restrict), do_unrestrict }, 150 { REQ_MON_GETLIST, NOAUTH, 0, 0, mon_getlist }, 151 { REQ_MON_GETLIST_1, NOAUTH, 0, 0, mon_getlist }, 152 { REQ_RESET_STATS, AUTH, sizeof(struct reset_flags), 0, reset_stats }, 153 { REQ_RESET_PEER, AUTH, v4sizeof(struct conf_unpeer), 154 sizeof(struct conf_unpeer), reset_peer }, 155 { REQ_REREAD_KEYS, AUTH, 0, 0, do_key_reread }, 156 { REQ_TRUSTKEY, AUTH, sizeof(u_long), sizeof(u_long), trust_key }, 157 { REQ_UNTRUSTKEY, AUTH, sizeof(u_long), sizeof(u_long), untrust_key }, 158 { REQ_AUTHINFO, NOAUTH, 0, 0, get_auth_info }, 159 { REQ_TRAPS, NOAUTH, 0, 0, req_get_traps }, 160 { REQ_ADD_TRAP, AUTH, v4sizeof(struct conf_trap), 161 sizeof(struct conf_trap), req_set_trap }, 162 { REQ_CLR_TRAP, AUTH, v4sizeof(struct conf_trap), 163 sizeof(struct conf_trap), req_clr_trap }, 164 { REQ_REQUEST_KEY, AUTH, sizeof(u_long), sizeof(u_long), 165 set_request_keyid }, 166 { REQ_CONTROL_KEY, AUTH, sizeof(u_long), sizeof(u_long), 167 set_control_keyid }, 168 { REQ_GET_CTLSTATS, NOAUTH, 0, 0, get_ctl_stats }, 169 #ifdef KERNEL_PLL 170 { REQ_GET_KERNEL, NOAUTH, 0, 0, get_kernel_info }, 171 #endif 172 #ifdef REFCLOCK 173 { REQ_GET_CLOCKINFO, NOAUTH, sizeof(u_int32), sizeof(u_int32), 174 get_clock_info }, 175 { REQ_SET_CLKFUDGE, AUTH, sizeof(struct conf_fudge), 176 sizeof(struct conf_fudge), set_clock_fudge }, 177 { REQ_GET_CLKBUGINFO, NOAUTH, sizeof(u_int32), sizeof(u_int32), 178 get_clkbug_info }, 179 #endif 180 { REQ_IF_STATS, AUTH, 0, 0, get_if_stats }, 181 { REQ_IF_RELOAD, AUTH, 0, 0, do_if_reload }, 182 183 { NO_REQUEST, NOAUTH, 0, 0, 0 } 184 }; 185 186 187 /* 188 * Authentication keyid used to authenticate requests. Zero means we 189 * don't allow writing anything. 190 */ 191 keyid_t info_auth_keyid; 192 193 /* 194 * Statistic counters to keep track of requests and responses. 195 */ 196 u_long numrequests; /* number of requests we've received */ 197 u_long numresppkts; /* number of resp packets sent with data */ 198 199 /* 200 * lazy way to count errors, indexed by the error code 201 */ 202 u_long errorcounter[MAX_INFO_ERR + 1]; 203 204 /* 205 * A hack. To keep the authentication module clear of ntp-ism's, we 206 * include a time reset variable for its stats here. 207 */ 208 u_long auth_timereset; 209 210 /* 211 * Response packet used by these routines. Also some state information 212 * so that we can handle packet formatting within a common set of 213 * subroutines. Note we try to enter data in place whenever possible, 214 * but the need to set the more bit correctly means we occasionally 215 * use the extra buffer and copy. 216 */ 217 static struct resp_pkt rpkt; 218 static int reqver; 219 static int seqno; 220 static int nitems; 221 static int itemsize; 222 static int databytes; 223 static char exbuf[RESP_DATA_SIZE]; 224 static int usingexbuf; 225 static sockaddr_u *toaddr; 226 static endpt *frominter; 227 228 /* 229 * init_request - initialize request data 230 */ 231 void 232 init_request (void) 233 { 234 size_t i; 235 236 numrequests = 0; 237 numresppkts = 0; 238 auth_timereset = 0; 239 info_auth_keyid = 0; /* by default, can't do this */ 240 241 for (i = 0; i < sizeof(errorcounter)/sizeof(errorcounter[0]); i++) 242 errorcounter[i] = 0; 243 } 244 245 246 /* 247 * req_ack - acknowledge request with no data 248 */ 249 static void 250 req_ack( 251 sockaddr_u *srcadr, 252 endpt *inter, 253 struct req_pkt *inpkt, 254 int errcode 255 ) 256 { 257 /* 258 * fill in the fields 259 */ 260 rpkt.rm_vn_mode = RM_VN_MODE(RESP_BIT, 0, reqver); 261 rpkt.auth_seq = AUTH_SEQ(0, 0); 262 rpkt.implementation = inpkt->implementation; 263 rpkt.request = inpkt->request; 264 rpkt.err_nitems = ERR_NITEMS(errcode, 0); 265 rpkt.mbz_itemsize = MBZ_ITEMSIZE(0); 266 267 /* 268 * send packet and bump counters 269 */ 270 sendpkt(srcadr, inter, -1, (struct pkt *)&rpkt, RESP_HEADER_SIZE); 271 errorcounter[errcode]++; 272 } 273 274 275 /* 276 * prepare_pkt - prepare response packet for transmission, return pointer 277 * to storage for data item. 278 */ 279 static void * 280 prepare_pkt( 281 sockaddr_u *srcadr, 282 endpt *inter, 283 struct req_pkt *pkt, 284 size_t structsize 285 ) 286 { 287 DPRINTF(4, ("request: preparing pkt\n")); 288 289 /* 290 * Fill in the implementation, request and itemsize fields 291 * since these won't change. 292 */ 293 rpkt.implementation = pkt->implementation; 294 rpkt.request = pkt->request; 295 rpkt.mbz_itemsize = MBZ_ITEMSIZE(structsize); 296 297 /* 298 * Compute the static data needed to carry on. 299 */ 300 toaddr = srcadr; 301 frominter = inter; 302 seqno = 0; 303 nitems = 0; 304 itemsize = structsize; 305 databytes = 0; 306 usingexbuf = 0; 307 308 /* 309 * return the beginning of the packet buffer. 310 */ 311 return &rpkt.u; 312 } 313 314 315 /* 316 * more_pkt - return a data pointer for a new item. 317 */ 318 static void * 319 more_pkt(void) 320 { 321 /* 322 * If we were using the extra buffer, send the packet. 323 */ 324 if (usingexbuf) { 325 DPRINTF(3, ("request: sending pkt\n")); 326 rpkt.rm_vn_mode = RM_VN_MODE(RESP_BIT, MORE_BIT, reqver); 327 rpkt.auth_seq = AUTH_SEQ(0, seqno); 328 rpkt.err_nitems = htons((u_short)nitems); 329 sendpkt(toaddr, frominter, -1, (struct pkt *)&rpkt, 330 RESP_HEADER_SIZE + databytes); 331 numresppkts++; 332 333 /* 334 * Copy data out of exbuf into the packet. 335 */ 336 memcpy(&rpkt.u.data[0], exbuf, (unsigned)itemsize); 337 seqno++; 338 databytes = 0; 339 nitems = 0; 340 usingexbuf = 0; 341 } 342 343 databytes += itemsize; 344 nitems++; 345 if (databytes + itemsize <= RESP_DATA_SIZE) { 346 DPRINTF(4, ("request: giving him more data\n")); 347 /* 348 * More room in packet. Give him the 349 * next address. 350 */ 351 return &rpkt.u.data[databytes]; 352 } else { 353 /* 354 * No room in packet. Give him the extra 355 * buffer unless this was the last in the sequence. 356 */ 357 DPRINTF(4, ("request: into extra buffer\n")); 358 if (seqno == MAXSEQ) 359 return NULL; 360 else { 361 usingexbuf = 1; 362 return exbuf; 363 } 364 } 365 } 366 367 368 /* 369 * flush_pkt - we're done, return remaining information. 370 */ 371 static void 372 flush_pkt(void) 373 { 374 DPRINTF(3, ("request: flushing packet, %d items\n", nitems)); 375 /* 376 * Must send the last packet. If nothing in here and nothing 377 * has been sent, send an error saying no data to be found. 378 */ 379 if (seqno == 0 && nitems == 0) 380 req_ack(toaddr, frominter, (struct req_pkt *)&rpkt, 381 INFO_ERR_NODATA); 382 else { 383 rpkt.rm_vn_mode = RM_VN_MODE(RESP_BIT, 0, reqver); 384 rpkt.auth_seq = AUTH_SEQ(0, seqno); 385 rpkt.err_nitems = htons((u_short)nitems); 386 sendpkt(toaddr, frominter, -1, (struct pkt *)&rpkt, 387 RESP_HEADER_SIZE+databytes); 388 numresppkts++; 389 } 390 } 391 392 393 394 /* 395 * Given a buffer, return the packet mode 396 */ 397 int 398 get_packet_mode(struct recvbuf *rbufp) 399 { 400 struct req_pkt *inpkt = (struct req_pkt *)&rbufp->recv_pkt; 401 return (INFO_MODE(inpkt->rm_vn_mode)); 402 } 403 404 405 /* 406 * process_private - process private mode (7) packets 407 */ 408 void 409 process_private( 410 struct recvbuf *rbufp, 411 int mod_okay 412 ) 413 { 414 static u_long quiet_until; 415 struct req_pkt *inpkt; 416 struct req_pkt_tail *tailinpkt; 417 sockaddr_u *srcadr; 418 endpt *inter; 419 const struct req_proc *proc; 420 int ec; 421 short temp_size; 422 l_fp ftmp; 423 double dtemp; 424 size_t recv_len; 425 size_t noslop_len; 426 size_t mac_len; 427 428 /* 429 * Initialize pointers, for convenience 430 */ 431 recv_len = rbufp->recv_length; 432 inpkt = (struct req_pkt *)&rbufp->recv_pkt; 433 srcadr = &rbufp->recv_srcadr; 434 inter = rbufp->dstadr; 435 436 DPRINTF(3, ("process_private: impl %d req %d\n", 437 inpkt->implementation, inpkt->request)); 438 439 /* 440 * Do some sanity checks on the packet. Return a format 441 * error if it fails. 442 */ 443 ec = 0; 444 if ( (++ec, ISRESPONSE(inpkt->rm_vn_mode)) 445 || (++ec, ISMORE(inpkt->rm_vn_mode)) 446 || (++ec, INFO_VERSION(inpkt->rm_vn_mode) > NTP_VERSION) 447 || (++ec, INFO_VERSION(inpkt->rm_vn_mode) < NTP_OLDVERSION) 448 || (++ec, INFO_SEQ(inpkt->auth_seq) != 0) 449 || (++ec, INFO_ERR(inpkt->err_nitems) != 0) 450 || (++ec, INFO_MBZ(inpkt->mbz_itemsize) != 0) 451 || (++ec, rbufp->recv_length < (int)REQ_LEN_HDR) 452 ) { 453 NLOG(NLOG_SYSEVENT) 454 if (current_time >= quiet_until) { 455 msyslog(LOG_ERR, 456 "process_private: drop test %d" 457 " failed, pkt from %s", 458 ec, stoa(srcadr)); 459 quiet_until = current_time + 60; 460 } 461 return; 462 } 463 464 reqver = INFO_VERSION(inpkt->rm_vn_mode); 465 466 /* 467 * Get the appropriate procedure list to search. 468 */ 469 if (inpkt->implementation == IMPL_UNIV) 470 proc = univ_codes; 471 else if ((inpkt->implementation == IMPL_XNTPD) || 472 (inpkt->implementation == IMPL_XNTPD_OLD)) 473 proc = ntp_codes; 474 else { 475 req_ack(srcadr, inter, inpkt, INFO_ERR_IMPL); 476 return; 477 } 478 479 /* 480 * Search the list for the request codes. If it isn't one 481 * we know, return an error. 482 */ 483 while (proc->request_code != NO_REQUEST) { 484 if (proc->request_code == (short) inpkt->request) 485 break; 486 proc++; 487 } 488 if (proc->request_code == NO_REQUEST) { 489 req_ack(srcadr, inter, inpkt, INFO_ERR_REQ); 490 return; 491 } 492 493 DPRINTF(4, ("found request in tables\n")); 494 495 /* 496 * If we need data, check to see if we have some. If we 497 * don't, check to see that there is none (picky, picky). 498 */ 499 500 /* This part is a bit tricky, we want to be sure that the size 501 * returned is either the old or the new size. We also can find 502 * out if the client can accept both types of messages this way. 503 * 504 * Handle the exception of REQ_CONFIG. It can have two data sizes. 505 */ 506 temp_size = INFO_ITEMSIZE(inpkt->mbz_itemsize); 507 if ((temp_size != proc->sizeofitem && 508 temp_size != proc->v6_sizeofitem) && 509 !(inpkt->implementation == IMPL_XNTPD && 510 inpkt->request == REQ_CONFIG && 511 temp_size == sizeof(struct old_conf_peer))) { 512 DPRINTF(3, ("process_private: wrong item size, received %d, should be %d or %d\n", 513 temp_size, proc->sizeofitem, proc->v6_sizeofitem)); 514 req_ack(srcadr, inter, inpkt, INFO_ERR_FMT); 515 return; 516 } 517 if ((proc->sizeofitem != 0) && 518 ((size_t)(temp_size * INFO_NITEMS(inpkt->err_nitems)) > 519 (recv_len - REQ_LEN_HDR))) { 520 DPRINTF(3, ("process_private: not enough data\n")); 521 req_ack(srcadr, inter, inpkt, INFO_ERR_FMT); 522 return; 523 } 524 525 switch (inpkt->implementation) { 526 case IMPL_XNTPD: 527 client_v6_capable = 1; 528 break; 529 case IMPL_XNTPD_OLD: 530 client_v6_capable = 0; 531 break; 532 default: 533 req_ack(srcadr, inter, inpkt, INFO_ERR_FMT); 534 return; 535 } 536 537 /* 538 * If we need to authenticate, do so. Note that an 539 * authenticatable packet must include a mac field, must 540 * have used key info_auth_keyid and must have included 541 * a time stamp in the appropriate field. The time stamp 542 * must be within INFO_TS_MAXSKEW of the receive 543 * time stamp. 544 */ 545 if (proc->needs_auth && sys_authenticate) { 546 547 if (recv_len < (REQ_LEN_HDR + 548 (INFO_ITEMSIZE(inpkt->mbz_itemsize) * 549 INFO_NITEMS(inpkt->err_nitems)) + 550 REQ_TAIL_MIN)) { 551 req_ack(srcadr, inter, inpkt, INFO_ERR_FMT); 552 return; 553 } 554 555 /* 556 * For 16-octet digests, regardless of itemsize and 557 * nitems, authenticated requests are a fixed size 558 * with the timestamp, key ID, and digest located 559 * at the end of the packet. Because the key ID 560 * determining the digest size precedes the digest, 561 * for larger digests the fixed size request scheme 562 * is abandoned and the timestamp, key ID, and digest 563 * are located relative to the start of the packet, 564 * with the digest size determined by the packet size. 565 */ 566 noslop_len = REQ_LEN_HDR 567 + INFO_ITEMSIZE(inpkt->mbz_itemsize) * 568 INFO_NITEMS(inpkt->err_nitems) 569 + sizeof(inpkt->tstamp); 570 /* 32-bit alignment */ 571 noslop_len = (noslop_len + 3) & ~3; 572 if (recv_len > (noslop_len + MAX_MAC_LEN)) 573 mac_len = 20; 574 else 575 mac_len = recv_len - noslop_len; 576 577 tailinpkt = (void *)((char *)inpkt + recv_len - 578 (mac_len + sizeof(inpkt->tstamp))); 579 580 /* 581 * If this guy is restricted from doing this, don't let 582 * him. If the wrong key was used, or packet doesn't 583 * have mac, return. 584 */ 585 /* XXX: Use authistrustedip(), or equivalent. */ 586 if (!INFO_IS_AUTH(inpkt->auth_seq) || !info_auth_keyid 587 || ntohl(tailinpkt->keyid) != info_auth_keyid) { 588 DPRINTF(5, ("failed auth %d info_auth_keyid %u pkt keyid %u maclen %lu\n", 589 INFO_IS_AUTH(inpkt->auth_seq), 590 info_auth_keyid, 591 ntohl(tailinpkt->keyid), (u_long)mac_len)); 592 #ifdef DEBUG 593 msyslog(LOG_DEBUG, 594 "process_private: failed auth %d info_auth_keyid %u pkt keyid %u maclen %lu\n", 595 INFO_IS_AUTH(inpkt->auth_seq), 596 info_auth_keyid, 597 ntohl(tailinpkt->keyid), (u_long)mac_len); 598 #endif 599 req_ack(srcadr, inter, inpkt, INFO_ERR_AUTH); 600 return; 601 } 602 if (recv_len > REQ_LEN_NOMAC + MAX_MAC_LEN) { 603 DPRINTF(5, ("bad pkt length %zu\n", recv_len)); 604 msyslog(LOG_ERR, 605 "process_private: bad pkt length %zu", 606 recv_len); 607 req_ack(srcadr, inter, inpkt, INFO_ERR_FMT); 608 return; 609 } 610 if (!mod_okay || !authhavekey(info_auth_keyid)) { 611 DPRINTF(5, ("failed auth mod_okay %d\n", 612 mod_okay)); 613 #ifdef DEBUG 614 msyslog(LOG_DEBUG, 615 "process_private: failed auth mod_okay %d\n", 616 mod_okay); 617 #endif 618 if (!mod_okay) { 619 sys_restricted++; 620 } 621 req_ack(srcadr, inter, inpkt, INFO_ERR_AUTH); 622 return; 623 } 624 625 /* 626 * calculate absolute time difference between xmit time stamp 627 * and receive time stamp. If too large, too bad. 628 */ 629 NTOHL_FP(&tailinpkt->tstamp, &ftmp); 630 L_SUB(&ftmp, &rbufp->recv_time); 631 LFPTOD(&ftmp, dtemp); 632 if (fabs(dtemp) > INFO_TS_MAXSKEW) { 633 /* 634 * He's a loser. Tell him. 635 */ 636 DPRINTF(5, ("xmit/rcv timestamp delta %g > INFO_TS_MAXSKEW %g\n", 637 dtemp, INFO_TS_MAXSKEW)); 638 req_ack(srcadr, inter, inpkt, INFO_ERR_AUTH); 639 return; 640 } 641 642 /* 643 * So far so good. See if decryption works out okay. 644 */ 645 if (!authdecrypt(info_auth_keyid, (u_int32 *)inpkt, 646 recv_len - mac_len, mac_len)) { 647 DPRINTF(5, ("authdecrypt failed\n")); 648 req_ack(srcadr, inter, inpkt, INFO_ERR_AUTH); 649 return; 650 } 651 } 652 653 DPRINTF(3, ("process_private: all okay, into handler\n")); 654 /* 655 * Packet is okay. Call the handler to send him data. 656 */ 657 (proc->handler)(srcadr, inter, inpkt); 658 } 659 660 661 /* 662 * list_peers - send a list of the peers 663 */ 664 static void 665 list_peers( 666 sockaddr_u *srcadr, 667 endpt *inter, 668 struct req_pkt *inpkt 669 ) 670 { 671 struct info_peer_list * ip; 672 const struct peer * pp; 673 674 ip = (struct info_peer_list *)prepare_pkt(srcadr, inter, inpkt, 675 v6sizeof(struct info_peer_list)); 676 for (pp = peer_list; pp != NULL && ip != NULL; pp = pp->p_link) { 677 if (IS_IPV6(&pp->srcadr)) { 678 if (!client_v6_capable) 679 continue; 680 ip->addr6 = SOCK_ADDR6(&pp->srcadr); 681 ip->v6_flag = 1; 682 } else { 683 ip->addr = NSRCADR(&pp->srcadr); 684 if (client_v6_capable) 685 ip->v6_flag = 0; 686 } 687 688 ip->port = NSRCPORT(&pp->srcadr); 689 ip->hmode = pp->hmode; 690 ip->flags = 0; 691 if (pp->flags & FLAG_CONFIG) 692 ip->flags |= INFO_FLAG_CONFIG; 693 if (pp == sys_peer) 694 ip->flags |= INFO_FLAG_SYSPEER; 695 if (pp->status == CTL_PST_SEL_SYNCCAND) 696 ip->flags |= INFO_FLAG_SEL_CANDIDATE; 697 if (pp->status >= CTL_PST_SEL_SYSPEER) 698 ip->flags |= INFO_FLAG_SHORTLIST; 699 ip = (struct info_peer_list *)more_pkt(); 700 } /* for pp */ 701 702 flush_pkt(); 703 } 704 705 706 /* 707 * list_peers_sum - return extended peer list 708 */ 709 static void 710 list_peers_sum( 711 sockaddr_u *srcadr, 712 endpt *inter, 713 struct req_pkt *inpkt 714 ) 715 { 716 struct info_peer_summary * ips; 717 const struct peer * pp; 718 l_fp ltmp; 719 720 DPRINTF(3, ("wants peer list summary\n")); 721 722 ips = (struct info_peer_summary *)prepare_pkt(srcadr, inter, inpkt, 723 v6sizeof(struct info_peer_summary)); 724 for (pp = peer_list; pp != NULL && ips != NULL; pp = pp->p_link) { 725 DPRINTF(4, ("sum: got one\n")); 726 /* 727 * Be careful here not to return v6 peers when we 728 * want only v4. 729 */ 730 if (IS_IPV6(&pp->srcadr)) { 731 if (!client_v6_capable) 732 continue; 733 ips->srcadr6 = SOCK_ADDR6(&pp->srcadr); 734 ips->v6_flag = 1; 735 if (pp->dstadr) 736 ips->dstadr6 = SOCK_ADDR6(&pp->dstadr->sin); 737 else 738 ZERO(ips->dstadr6); 739 } else { 740 ips->srcadr = NSRCADR(&pp->srcadr); 741 if (client_v6_capable) 742 ips->v6_flag = 0; 743 744 if (pp->dstadr) { 745 if (!pp->processed) 746 ips->dstadr = NSRCADR(&pp->dstadr->sin); 747 else { 748 if (MDF_BCAST == pp->cast_flags) 749 ips->dstadr = NSRCADR(&pp->dstadr->bcast); 750 else if (pp->cast_flags) { 751 ips->dstadr = NSRCADR(&pp->dstadr->sin); 752 if (!ips->dstadr) 753 ips->dstadr = NSRCADR(&pp->dstadr->bcast); 754 } 755 } 756 } else { 757 ips->dstadr = 0; 758 } 759 } 760 761 ips->srcport = NSRCPORT(&pp->srcadr); 762 ips->stratum = pp->stratum; 763 ips->hpoll = pp->hpoll; 764 ips->ppoll = pp->ppoll; 765 ips->reach = pp->reach; 766 ips->flags = 0; 767 if (pp == sys_peer) 768 ips->flags |= INFO_FLAG_SYSPEER; 769 if (pp->flags & FLAG_CONFIG) 770 ips->flags |= INFO_FLAG_CONFIG; 771 if (pp->flags & FLAG_REFCLOCK) 772 ips->flags |= INFO_FLAG_REFCLOCK; 773 if (pp->flags & FLAG_PREFER) 774 ips->flags |= INFO_FLAG_PREFER; 775 if (pp->flags & FLAG_BURST) 776 ips->flags |= INFO_FLAG_BURST; 777 if (pp->status == CTL_PST_SEL_SYNCCAND) 778 ips->flags |= INFO_FLAG_SEL_CANDIDATE; 779 if (pp->status >= CTL_PST_SEL_SYSPEER) 780 ips->flags |= INFO_FLAG_SHORTLIST; 781 ips->hmode = pp->hmode; 782 ips->delay = HTONS_FP(DTOFP(pp->delay)); 783 DTOLFP(pp->offset, <mp); 784 HTONL_FP(<mp, &ips->offset); 785 ips->dispersion = HTONS_FP(DTOUFP(SQRT(pp->disp))); 786 787 ips = (struct info_peer_summary *)more_pkt(); 788 } /* for pp */ 789 790 flush_pkt(); 791 } 792 793 794 /* 795 * peer_info - send information for one or more peers 796 */ 797 static void 798 peer_info ( 799 sockaddr_u *srcadr, 800 endpt *inter, 801 struct req_pkt *inpkt 802 ) 803 { 804 u_short items; 805 size_t item_sz; 806 char * datap; 807 struct info_peer_list ipl; 808 struct peer * pp; 809 struct info_peer * ip; 810 int i; 811 int j; 812 sockaddr_u addr; 813 l_fp ltmp; 814 815 items = INFO_NITEMS(inpkt->err_nitems); 816 item_sz = INFO_ITEMSIZE(inpkt->mbz_itemsize); 817 datap = inpkt->u.data; 818 if (item_sz != sizeof(ipl)) { 819 req_ack(srcadr, inter, inpkt, INFO_ERR_FMT); 820 return; 821 } 822 ip = prepare_pkt(srcadr, inter, inpkt, 823 v6sizeof(struct info_peer)); 824 while (items-- > 0 && ip != NULL) { 825 ZERO(ipl); 826 memcpy(&ipl, datap, item_sz); 827 ZERO_SOCK(&addr); 828 NSRCPORT(&addr) = ipl.port; 829 if (client_v6_capable && ipl.v6_flag) { 830 AF(&addr) = AF_INET6; 831 SOCK_ADDR6(&addr) = ipl.addr6; 832 } else { 833 AF(&addr) = AF_INET; 834 NSRCADR(&addr) = ipl.addr; 835 } 836 #ifdef ISC_PLATFORM_HAVESALEN 837 addr.sa.sa_len = SOCKLEN(&addr); 838 #endif 839 datap += item_sz; 840 841 pp = findexistingpeer(&addr, NULL, NULL, -1, 0, NULL); 842 if (NULL == pp) 843 continue; 844 if (IS_IPV6(&pp->srcadr)) { 845 if (pp->dstadr) 846 ip->dstadr6 = 847 (MDF_BCAST == pp->cast_flags) 848 ? SOCK_ADDR6(&pp->dstadr->bcast) 849 : SOCK_ADDR6(&pp->dstadr->sin); 850 else 851 ZERO(ip->dstadr6); 852 853 ip->srcadr6 = SOCK_ADDR6(&pp->srcadr); 854 ip->v6_flag = 1; 855 } else { 856 if (pp->dstadr) { 857 if (!pp->processed) 858 ip->dstadr = NSRCADR(&pp->dstadr->sin); 859 else { 860 if (MDF_BCAST == pp->cast_flags) 861 ip->dstadr = NSRCADR(&pp->dstadr->bcast); 862 else if (pp->cast_flags) { 863 ip->dstadr = NSRCADR(&pp->dstadr->sin); 864 if (!ip->dstadr) 865 ip->dstadr = NSRCADR(&pp->dstadr->bcast); 866 } 867 } 868 } else 869 ip->dstadr = 0; 870 871 ip->srcadr = NSRCADR(&pp->srcadr); 872 if (client_v6_capable) 873 ip->v6_flag = 0; 874 } 875 ip->srcport = NSRCPORT(&pp->srcadr); 876 ip->flags = 0; 877 if (pp == sys_peer) 878 ip->flags |= INFO_FLAG_SYSPEER; 879 if (pp->flags & FLAG_CONFIG) 880 ip->flags |= INFO_FLAG_CONFIG; 881 if (pp->flags & FLAG_REFCLOCK) 882 ip->flags |= INFO_FLAG_REFCLOCK; 883 if (pp->flags & FLAG_PREFER) 884 ip->flags |= INFO_FLAG_PREFER; 885 if (pp->flags & FLAG_BURST) 886 ip->flags |= INFO_FLAG_BURST; 887 if (pp->status == CTL_PST_SEL_SYNCCAND) 888 ip->flags |= INFO_FLAG_SEL_CANDIDATE; 889 if (pp->status >= CTL_PST_SEL_SYSPEER) 890 ip->flags |= INFO_FLAG_SHORTLIST; 891 ip->leap = pp->leap; 892 ip->hmode = pp->hmode; 893 ip->pmode = pp->pmode; 894 ip->keyid = pp->keyid; 895 ip->stratum = pp->stratum; 896 ip->ppoll = pp->ppoll; 897 ip->hpoll = pp->hpoll; 898 ip->precision = pp->precision; 899 ip->version = pp->version; 900 ip->reach = pp->reach; 901 ip->unreach = (u_char)pp->unreach; 902 ip->flash = (u_char)pp->flash; 903 ip->flash2 = (u_short)pp->flash; 904 ip->estbdelay = HTONS_FP(DTOFP(pp->delay)); 905 ip->ttl = (u_char)pp->ttl; 906 ip->associd = htons(pp->associd); 907 ip->rootdelay = HTONS_FP(DTOUFP(pp->rootdelay)); 908 ip->rootdispersion = HTONS_FP(DTOUFP(pp->rootdisp)); 909 ip->refid = pp->refid; 910 HTONL_FP(&pp->reftime, &ip->reftime); 911 HTONL_FP(&pp->aorg, &ip->org); 912 HTONL_FP(&pp->rec, &ip->rec); 913 HTONL_FP(&pp->xmt, &ip->xmt); 914 j = pp->filter_nextpt - 1; 915 for (i = 0; i < NTP_SHIFT; i++, j--) { 916 if (j < 0) 917 j = NTP_SHIFT-1; 918 ip->filtdelay[i] = HTONS_FP(DTOFP(pp->filter_delay[j])); 919 DTOLFP(pp->filter_offset[j], <mp); 920 HTONL_FP(<mp, &ip->filtoffset[i]); 921 ip->order[i] = (u_char)((pp->filter_nextpt + 922 NTP_SHIFT - 1) - 923 pp->filter_order[i]); 924 if (ip->order[i] >= NTP_SHIFT) 925 ip->order[i] -= NTP_SHIFT; 926 } 927 DTOLFP(pp->offset, <mp); 928 HTONL_FP(<mp, &ip->offset); 929 ip->delay = HTONS_FP(DTOFP(pp->delay)); 930 ip->dispersion = HTONS_FP(DTOUFP(SQRT(pp->disp))); 931 ip->selectdisp = HTONS_FP(DTOUFP(SQRT(pp->jitter))); 932 ip = more_pkt(); 933 } 934 flush_pkt(); 935 } 936 937 938 /* 939 * peer_stats - send statistics for one or more peers 940 */ 941 static void 942 peer_stats ( 943 sockaddr_u *srcadr, 944 endpt *inter, 945 struct req_pkt *inpkt 946 ) 947 { 948 u_short items; 949 size_t item_sz; 950 char * datap; 951 struct info_peer_list ipl; 952 struct peer * pp; 953 struct info_peer_stats *ip; 954 sockaddr_u addr; 955 956 DPRINTF(1, ("peer_stats: called\n")); 957 items = INFO_NITEMS(inpkt->err_nitems); 958 item_sz = INFO_ITEMSIZE(inpkt->mbz_itemsize); 959 datap = inpkt->u.data; 960 if (item_sz > sizeof(ipl)) { 961 req_ack(srcadr, inter, inpkt, INFO_ERR_FMT); 962 return; 963 } 964 ip = prepare_pkt(srcadr, inter, inpkt, 965 v6sizeof(struct info_peer_stats)); 966 while (items-- > 0 && ip != NULL) { 967 ZERO(ipl); 968 memcpy(&ipl, datap, item_sz); 969 ZERO(addr); 970 NSRCPORT(&addr) = ipl.port; 971 if (client_v6_capable && ipl.v6_flag) { 972 AF(&addr) = AF_INET6; 973 SOCK_ADDR6(&addr) = ipl.addr6; 974 } else { 975 AF(&addr) = AF_INET; 976 NSRCADR(&addr) = ipl.addr; 977 } 978 #ifdef ISC_PLATFORM_HAVESALEN 979 addr.sa.sa_len = SOCKLEN(&addr); 980 #endif 981 DPRINTF(1, ("peer_stats: looking for %s, %d, %d\n", 982 stoa(&addr), ipl.port, NSRCPORT(&addr))); 983 984 datap += item_sz; 985 986 pp = findexistingpeer(&addr, NULL, NULL, -1, 0, NULL); 987 if (NULL == pp) 988 continue; 989 990 DPRINTF(1, ("peer_stats: found %s\n", stoa(&addr))); 991 992 if (IS_IPV4(&pp->srcadr)) { 993 if (pp->dstadr) { 994 if (!pp->processed) 995 ip->dstadr = NSRCADR(&pp->dstadr->sin); 996 else { 997 if (MDF_BCAST == pp->cast_flags) 998 ip->dstadr = NSRCADR(&pp->dstadr->bcast); 999 else if (pp->cast_flags) { 1000 ip->dstadr = NSRCADR(&pp->dstadr->sin); 1001 if (!ip->dstadr) 1002 ip->dstadr = NSRCADR(&pp->dstadr->bcast); 1003 } 1004 } 1005 } else 1006 ip->dstadr = 0; 1007 1008 ip->srcadr = NSRCADR(&pp->srcadr); 1009 if (client_v6_capable) 1010 ip->v6_flag = 0; 1011 } else { 1012 if (pp->dstadr) 1013 ip->dstadr6 = 1014 (MDF_BCAST == pp->cast_flags) 1015 ? SOCK_ADDR6(&pp->dstadr->bcast) 1016 : SOCK_ADDR6(&pp->dstadr->sin); 1017 else 1018 ZERO(ip->dstadr6); 1019 1020 ip->srcadr6 = SOCK_ADDR6(&pp->srcadr); 1021 ip->v6_flag = 1; 1022 } 1023 ip->srcport = NSRCPORT(&pp->srcadr); 1024 ip->flags = 0; 1025 if (pp == sys_peer) 1026 ip->flags |= INFO_FLAG_SYSPEER; 1027 if (pp->flags & FLAG_CONFIG) 1028 ip->flags |= INFO_FLAG_CONFIG; 1029 if (pp->flags & FLAG_REFCLOCK) 1030 ip->flags |= INFO_FLAG_REFCLOCK; 1031 if (pp->flags & FLAG_PREFER) 1032 ip->flags |= INFO_FLAG_PREFER; 1033 if (pp->flags & FLAG_BURST) 1034 ip->flags |= INFO_FLAG_BURST; 1035 if (pp->flags & FLAG_IBURST) 1036 ip->flags |= INFO_FLAG_IBURST; 1037 if (pp->status == CTL_PST_SEL_SYNCCAND) 1038 ip->flags |= INFO_FLAG_SEL_CANDIDATE; 1039 if (pp->status >= CTL_PST_SEL_SYSPEER) 1040 ip->flags |= INFO_FLAG_SHORTLIST; 1041 ip->flags = htons(ip->flags); 1042 ip->timereceived = htonl((u_int32)(current_time - pp->timereceived)); 1043 ip->timetosend = htonl(pp->nextdate - current_time); 1044 ip->timereachable = htonl((u_int32)(current_time - pp->timereachable)); 1045 ip->sent = htonl((u_int32)(pp->sent)); 1046 ip->processed = htonl((u_int32)(pp->processed)); 1047 ip->badauth = htonl((u_int32)(pp->badauth)); 1048 ip->bogusorg = htonl((u_int32)(pp->bogusorg)); 1049 ip->oldpkt = htonl((u_int32)(pp->oldpkt)); 1050 ip->seldisp = htonl((u_int32)(pp->seldisptoolarge)); 1051 ip->selbroken = htonl((u_int32)(pp->selbroken)); 1052 ip->candidate = pp->status; 1053 ip = (struct info_peer_stats *)more_pkt(); 1054 } 1055 flush_pkt(); 1056 } 1057 1058 1059 /* 1060 * sys_info - return system info 1061 */ 1062 static void 1063 sys_info( 1064 sockaddr_u *srcadr, 1065 endpt *inter, 1066 struct req_pkt *inpkt 1067 ) 1068 { 1069 register struct info_sys *is; 1070 1071 is = (struct info_sys *)prepare_pkt(srcadr, inter, inpkt, 1072 v6sizeof(struct info_sys)); 1073 1074 if (sys_peer) { 1075 if (IS_IPV4(&sys_peer->srcadr)) { 1076 is->peer = NSRCADR(&sys_peer->srcadr); 1077 if (client_v6_capable) 1078 is->v6_flag = 0; 1079 } else if (client_v6_capable) { 1080 is->peer6 = SOCK_ADDR6(&sys_peer->srcadr); 1081 is->v6_flag = 1; 1082 } 1083 is->peer_mode = sys_peer->hmode; 1084 } else { 1085 is->peer = 0; 1086 if (client_v6_capable) { 1087 is->v6_flag = 0; 1088 } 1089 is->peer_mode = 0; 1090 } 1091 1092 is->leap = sys_leap; 1093 is->stratum = sys_stratum; 1094 is->precision = sys_precision; 1095 is->rootdelay = htonl(DTOFP(sys_rootdelay)); 1096 is->rootdispersion = htonl(DTOUFP(sys_rootdisp)); 1097 is->frequency = htonl(DTOFP(sys_jitter)); 1098 is->stability = htonl(DTOUFP(clock_stability * 1e6)); 1099 is->refid = sys_refid; 1100 HTONL_FP(&sys_reftime, &is->reftime); 1101 1102 is->poll = sys_poll; 1103 1104 is->flags = 0; 1105 if (sys_authenticate) 1106 is->flags |= INFO_FLAG_AUTHENTICATE; 1107 if (sys_bclient) 1108 is->flags |= INFO_FLAG_BCLIENT; 1109 #ifdef REFCLOCK 1110 if (cal_enable) 1111 is->flags |= INFO_FLAG_CAL; 1112 #endif /* REFCLOCK */ 1113 if (kern_enable) 1114 is->flags |= INFO_FLAG_KERNEL; 1115 if (mon_enabled != MON_OFF) 1116 is->flags |= INFO_FLAG_MONITOR; 1117 if (ntp_enable) 1118 is->flags |= INFO_FLAG_NTP; 1119 if (hardpps_enable) 1120 is->flags |= INFO_FLAG_PPS_SYNC; 1121 if (stats_control) 1122 is->flags |= INFO_FLAG_FILEGEN; 1123 is->bdelay = HTONS_FP(DTOFP(sys_bdelay)); 1124 HTONL_UF(sys_authdelay.l_uf, &is->authdelay); 1125 (void) more_pkt(); 1126 flush_pkt(); 1127 } 1128 1129 1130 /* 1131 * sys_stats - return system statistics 1132 */ 1133 static void 1134 sys_stats( 1135 sockaddr_u *srcadr, 1136 endpt *inter, 1137 struct req_pkt *inpkt 1138 ) 1139 { 1140 register struct info_sys_stats *ss; 1141 1142 ss = (struct info_sys_stats *)prepare_pkt(srcadr, inter, inpkt, 1143 sizeof(struct info_sys_stats)); 1144 ss->timeup = htonl((u_int32)current_time); 1145 ss->timereset = htonl((u_int32)(current_time - sys_stattime)); 1146 ss->denied = htonl((u_int32)sys_restricted); 1147 ss->oldversionpkt = htonl((u_int32)sys_oldversion); 1148 ss->newversionpkt = htonl((u_int32)sys_newversion); 1149 ss->unknownversion = htonl((u_int32)sys_declined); 1150 ss->badlength = htonl((u_int32)sys_badlength); 1151 ss->processed = htonl((u_int32)sys_processed); 1152 ss->badauth = htonl((u_int32)sys_badauth); 1153 ss->limitrejected = htonl((u_int32)sys_limitrejected); 1154 ss->received = htonl((u_int32)sys_received); 1155 ss->lamport = htonl((u_int32)sys_lamport); 1156 ss->tsrounding = htonl((u_int32)sys_tsrounding); 1157 (void) more_pkt(); 1158 flush_pkt(); 1159 } 1160 1161 1162 /* 1163 * mem_stats - return memory statistics 1164 */ 1165 static void 1166 mem_stats( 1167 sockaddr_u *srcadr, 1168 endpt *inter, 1169 struct req_pkt *inpkt 1170 ) 1171 { 1172 register struct info_mem_stats *ms; 1173 register int i; 1174 1175 ms = (struct info_mem_stats *)prepare_pkt(srcadr, inter, inpkt, 1176 sizeof(struct info_mem_stats)); 1177 1178 ms->timereset = htonl((u_int32)(current_time - peer_timereset)); 1179 ms->totalpeermem = htons((u_short)total_peer_structs); 1180 ms->freepeermem = htons((u_short)peer_free_count); 1181 ms->findpeer_calls = htonl((u_int32)findpeer_calls); 1182 ms->allocations = htonl((u_int32)peer_allocations); 1183 ms->demobilizations = htonl((u_int32)peer_demobilizations); 1184 1185 for (i = 0; i < NTP_HASH_SIZE; i++) 1186 ms->hashcount[i] = (u_char) 1187 min((u_int)peer_hash_count[i], UCHAR_MAX); 1188 1189 (void) more_pkt(); 1190 flush_pkt(); 1191 } 1192 1193 1194 /* 1195 * io_stats - return io statistics 1196 */ 1197 static void 1198 io_stats( 1199 sockaddr_u *srcadr, 1200 endpt *inter, 1201 struct req_pkt *inpkt 1202 ) 1203 { 1204 struct info_io_stats *io; 1205 1206 io = (struct info_io_stats *)prepare_pkt(srcadr, inter, inpkt, 1207 sizeof(struct info_io_stats)); 1208 1209 io->timereset = htonl((u_int32)(current_time - io_timereset)); 1210 io->totalrecvbufs = htons((u_short) total_recvbuffs()); 1211 io->freerecvbufs = htons((u_short) free_recvbuffs()); 1212 io->fullrecvbufs = htons((u_short) full_recvbuffs()); 1213 io->lowwater = htons((u_short) lowater_additions()); 1214 io->dropped = htonl((u_int32)packets_dropped); 1215 io->ignored = htonl((u_int32)packets_ignored); 1216 io->received = htonl((u_int32)packets_received); 1217 io->sent = htonl((u_int32)packets_sent); 1218 io->notsent = htonl((u_int32)packets_notsent); 1219 io->interrupts = htonl((u_int32)handler_calls); 1220 io->int_received = htonl((u_int32)handler_pkts); 1221 1222 (void) more_pkt(); 1223 flush_pkt(); 1224 } 1225 1226 1227 /* 1228 * timer_stats - return timer statistics 1229 */ 1230 static void 1231 timer_stats( 1232 sockaddr_u * srcadr, 1233 endpt * inter, 1234 struct req_pkt * inpkt 1235 ) 1236 { 1237 struct info_timer_stats * ts; 1238 u_long sincereset; 1239 1240 ts = (struct info_timer_stats *)prepare_pkt(srcadr, inter, 1241 inpkt, sizeof(*ts)); 1242 1243 sincereset = current_time - timer_timereset; 1244 ts->timereset = htonl((u_int32)sincereset); 1245 ts->alarms = ts->timereset; 1246 ts->overflows = htonl((u_int32)alarm_overflow); 1247 ts->xmtcalls = htonl((u_int32)timer_xmtcalls); 1248 1249 (void) more_pkt(); 1250 flush_pkt(); 1251 } 1252 1253 1254 /* 1255 * loop_info - return the current state of the loop filter 1256 */ 1257 static void 1258 loop_info( 1259 sockaddr_u *srcadr, 1260 endpt *inter, 1261 struct req_pkt *inpkt 1262 ) 1263 { 1264 struct info_loop *li; 1265 l_fp ltmp; 1266 1267 li = (struct info_loop *)prepare_pkt(srcadr, inter, inpkt, 1268 sizeof(struct info_loop)); 1269 1270 DTOLFP(last_offset, <mp); 1271 HTONL_FP(<mp, &li->last_offset); 1272 DTOLFP(drift_comp * 1e6, <mp); 1273 HTONL_FP(<mp, &li->drift_comp); 1274 li->compliance = htonl((u_int32)(tc_counter)); 1275 li->watchdog_timer = htonl((u_int32)(current_time - sys_epoch)); 1276 1277 (void) more_pkt(); 1278 flush_pkt(); 1279 } 1280 1281 1282 /* 1283 * do_conf - add a peer to the configuration list 1284 */ 1285 static void 1286 do_conf( 1287 sockaddr_u *srcadr, 1288 endpt *inter, 1289 struct req_pkt *inpkt 1290 ) 1291 { 1292 u_short items; 1293 size_t item_sz; 1294 u_int fl; 1295 char * datap; 1296 struct conf_peer temp_cp; 1297 sockaddr_u peeraddr; 1298 1299 /* 1300 * Do a check of everything to see that it looks 1301 * okay. If not, complain about it. Note we are 1302 * very picky here. 1303 */ 1304 items = INFO_NITEMS(inpkt->err_nitems); 1305 item_sz = INFO_ITEMSIZE(inpkt->mbz_itemsize); 1306 datap = inpkt->u.data; 1307 if (item_sz > sizeof(temp_cp)) { 1308 req_ack(srcadr, inter, inpkt, INFO_ERR_FMT); 1309 return; 1310 } 1311 1312 while (items-- > 0) { 1313 ZERO(temp_cp); 1314 memcpy(&temp_cp, datap, item_sz); 1315 ZERO_SOCK(&peeraddr); 1316 1317 fl = 0; 1318 if (temp_cp.flags & CONF_FLAG_PREFER) 1319 fl |= FLAG_PREFER; 1320 if (temp_cp.flags & CONF_FLAG_BURST) 1321 fl |= FLAG_BURST; 1322 if (temp_cp.flags & CONF_FLAG_IBURST) 1323 fl |= FLAG_IBURST; 1324 #ifdef AUTOKEY 1325 if (temp_cp.flags & CONF_FLAG_SKEY) 1326 fl |= FLAG_SKEY; 1327 #endif /* AUTOKEY */ 1328 if (client_v6_capable && temp_cp.v6_flag) { 1329 AF(&peeraddr) = AF_INET6; 1330 SOCK_ADDR6(&peeraddr) = temp_cp.peeraddr6; 1331 } else { 1332 AF(&peeraddr) = AF_INET; 1333 NSRCADR(&peeraddr) = temp_cp.peeraddr; 1334 /* 1335 * Make sure the address is valid 1336 */ 1337 if (!ISREFCLOCKADR(&peeraddr) && 1338 ISBADADR(&peeraddr)) { 1339 req_ack(srcadr, inter, inpkt, INFO_ERR_FMT); 1340 return; 1341 } 1342 1343 } 1344 NSRCPORT(&peeraddr) = htons(NTP_PORT); 1345 #ifdef ISC_PLATFORM_HAVESALEN 1346 peeraddr.sa.sa_len = SOCKLEN(&peeraddr); 1347 #endif 1348 1349 /* check mode value: 0 <= hmode <= 6 1350 * 1351 * There's no good global define for that limit, and 1352 * using a magic define is as good (or bad, actually) as 1353 * a magic number. So we use the highest possible peer 1354 * mode, and that is MODE_BCLIENT. 1355 * 1356 * [Bug 3009] claims that a problem occurs for hmode > 7, 1357 * but the code in ntp_peer.c indicates trouble for any 1358 * hmode > 6 ( --> MODE_BCLIENT). 1359 */ 1360 if (temp_cp.hmode > MODE_BCLIENT) { 1361 req_ack(srcadr, inter, inpkt, INFO_ERR_FMT); 1362 return; 1363 } 1364 1365 /* Any more checks on the values? Unchecked at this 1366 * point: 1367 * - version 1368 * - ttl 1369 * - keyid 1370 * 1371 * - minpoll/maxpoll, but they are treated properly 1372 * for all cases internally. Checking not necessary. 1373 * 1374 * Note that we ignore any previously-specified ippeerlimit. 1375 * If we're told to create the peer, we create the peer. 1376 */ 1377 1378 /* finally create the peer */ 1379 if (peer_config(&peeraddr, NULL, NULL, -1, 1380 temp_cp.hmode, temp_cp.version, temp_cp.minpoll, 1381 temp_cp.maxpoll, fl, temp_cp.ttl, temp_cp.keyid, 1382 NULL) == 0) 1383 { 1384 req_ack(srcadr, inter, inpkt, INFO_ERR_NODATA); 1385 return; 1386 } 1387 1388 datap += item_sz; 1389 } 1390 req_ack(srcadr, inter, inpkt, INFO_OKAY); 1391 } 1392 1393 1394 /* 1395 * do_unconf - remove a peer from the configuration list 1396 */ 1397 static void 1398 do_unconf( 1399 sockaddr_u * srcadr, 1400 endpt * inter, 1401 struct req_pkt *inpkt 1402 ) 1403 { 1404 u_short items; 1405 size_t item_sz; 1406 char * datap; 1407 struct conf_unpeer temp_cp; 1408 struct peer * p; 1409 sockaddr_u peeraddr; 1410 int loops; 1411 1412 /* 1413 * This is a bit unstructured, but I like to be careful. 1414 * We check to see that every peer exists and is actually 1415 * configured. If so, we remove them. If not, we return 1416 * an error. 1417 * 1418 * [Bug 3011] Even if we checked all peers given in the request 1419 * in a dry run, there's still a chance that the caller played 1420 * unfair and gave the same peer multiple times. So we still 1421 * have to be prepared for nasty surprises in the second run ;) 1422 */ 1423 1424 /* basic consistency checks */ 1425 item_sz = INFO_ITEMSIZE(inpkt->mbz_itemsize); 1426 if (item_sz > sizeof(temp_cp)) { 1427 req_ack(srcadr, inter, inpkt, INFO_ERR_FMT); 1428 return; 1429 } 1430 1431 /* now do two runs: first a dry run, then a busy one */ 1432 for (loops = 0; loops != 2; ++loops) { 1433 items = INFO_NITEMS(inpkt->err_nitems); 1434 datap = inpkt->u.data; 1435 while (items-- > 0) { 1436 /* copy from request to local */ 1437 ZERO(temp_cp); 1438 memcpy(&temp_cp, datap, item_sz); 1439 /* get address structure */ 1440 ZERO_SOCK(&peeraddr); 1441 if (client_v6_capable && temp_cp.v6_flag) { 1442 AF(&peeraddr) = AF_INET6; 1443 SOCK_ADDR6(&peeraddr) = temp_cp.peeraddr6; 1444 } else { 1445 AF(&peeraddr) = AF_INET; 1446 NSRCADR(&peeraddr) = temp_cp.peeraddr; 1447 } 1448 SET_PORT(&peeraddr, NTP_PORT); 1449 #ifdef ISC_PLATFORM_HAVESALEN 1450 peeraddr.sa.sa_len = SOCKLEN(&peeraddr); 1451 #endif 1452 DPRINTF(1, ("searching for %s\n", 1453 stoa(&peeraddr))); 1454 1455 /* search for matching configred(!) peer */ 1456 p = NULL; 1457 do { 1458 p = findexistingpeer( 1459 &peeraddr, NULL, p, -1, 0, NULL); 1460 } while (p && !(FLAG_CONFIG & p->flags)); 1461 1462 if (!loops && !p) { 1463 /* Item not found in dry run -- bail! */ 1464 req_ack(srcadr, inter, inpkt, 1465 INFO_ERR_NODATA); 1466 return; 1467 } else if (loops && p) { 1468 /* Item found in busy run -- remove! */ 1469 peer_clear(p, "GONE"); 1470 unpeer(p); 1471 } 1472 datap += item_sz; 1473 } 1474 } 1475 1476 /* report success */ 1477 req_ack(srcadr, inter, inpkt, INFO_OKAY); 1478 } 1479 1480 1481 /* 1482 * set_sys_flag - set system flags 1483 */ 1484 static void 1485 set_sys_flag( 1486 sockaddr_u *srcadr, 1487 endpt *inter, 1488 struct req_pkt *inpkt 1489 ) 1490 { 1491 setclr_flags(srcadr, inter, inpkt, 1); 1492 } 1493 1494 1495 /* 1496 * clr_sys_flag - clear system flags 1497 */ 1498 static void 1499 clr_sys_flag( 1500 sockaddr_u *srcadr, 1501 endpt *inter, 1502 struct req_pkt *inpkt 1503 ) 1504 { 1505 setclr_flags(srcadr, inter, inpkt, 0); 1506 } 1507 1508 1509 /* 1510 * setclr_flags - do the grunge work of flag setting/clearing 1511 */ 1512 static void 1513 setclr_flags( 1514 sockaddr_u *srcadr, 1515 endpt *inter, 1516 struct req_pkt *inpkt, 1517 u_long set 1518 ) 1519 { 1520 struct conf_sys_flags *sf; 1521 u_int32 flags; 1522 1523 if (INFO_NITEMS(inpkt->err_nitems) > 1) { 1524 msyslog(LOG_ERR, "setclr_flags: err_nitems > 1"); 1525 req_ack(srcadr, inter, inpkt, INFO_ERR_FMT); 1526 return; 1527 } 1528 1529 sf = (struct conf_sys_flags *)&inpkt->u; 1530 flags = ntohl(sf->flags); 1531 1532 if (flags & ~(SYS_FLAG_BCLIENT | SYS_FLAG_PPS | 1533 SYS_FLAG_NTP | SYS_FLAG_KERNEL | SYS_FLAG_MONITOR | 1534 SYS_FLAG_FILEGEN | SYS_FLAG_AUTH | SYS_FLAG_CAL)) { 1535 msyslog(LOG_ERR, "setclr_flags: extra flags: %#x", 1536 flags & ~(SYS_FLAG_BCLIENT | SYS_FLAG_PPS | 1537 SYS_FLAG_NTP | SYS_FLAG_KERNEL | 1538 SYS_FLAG_MONITOR | SYS_FLAG_FILEGEN | 1539 SYS_FLAG_AUTH | SYS_FLAG_CAL)); 1540 req_ack(srcadr, inter, inpkt, INFO_ERR_FMT); 1541 return; 1542 } 1543 1544 if (flags & SYS_FLAG_BCLIENT) 1545 proto_config(PROTO_BROADCLIENT, set, 0., NULL); 1546 if (flags & SYS_FLAG_PPS) 1547 proto_config(PROTO_PPS, set, 0., NULL); 1548 if (flags & SYS_FLAG_NTP) 1549 proto_config(PROTO_NTP, set, 0., NULL); 1550 if (flags & SYS_FLAG_KERNEL) 1551 proto_config(PROTO_KERNEL, set, 0., NULL); 1552 if (flags & SYS_FLAG_MONITOR) 1553 proto_config(PROTO_MONITOR, set, 0., NULL); 1554 if (flags & SYS_FLAG_FILEGEN) 1555 proto_config(PROTO_FILEGEN, set, 0., NULL); 1556 if (flags & SYS_FLAG_AUTH) 1557 proto_config(PROTO_AUTHENTICATE, set, 0., NULL); 1558 if (flags & SYS_FLAG_CAL) 1559 proto_config(PROTO_CAL, set, 0., NULL); 1560 req_ack(srcadr, inter, inpkt, INFO_OKAY); 1561 } 1562 1563 /* There have been some issues with the restrict list processing, 1564 * ranging from problems with deep recursion (resulting in stack 1565 * overflows) and overfull reply buffers. 1566 * 1567 * To avoid this trouble the list reversal is done iteratively using a 1568 * scratch pad. 1569 */ 1570 typedef struct RestrictStack RestrictStackT; 1571 struct RestrictStack { 1572 RestrictStackT *link; 1573 size_t fcnt; 1574 const restrict_u *pres[63]; 1575 }; 1576 1577 static size_t 1578 getStackSheetSize( 1579 RestrictStackT *sp 1580 ) 1581 { 1582 if (sp) 1583 return sizeof(sp->pres)/sizeof(sp->pres[0]); 1584 return 0u; 1585 } 1586 1587 static int/*BOOL*/ 1588 pushRestriction( 1589 RestrictStackT **spp, 1590 const restrict_u *ptr 1591 ) 1592 { 1593 RestrictStackT *sp; 1594 1595 if (NULL == (sp = *spp) || 0 == sp->fcnt) { 1596 /* need another sheet in the scratch pad */ 1597 sp = emalloc(sizeof(*sp)); 1598 sp->link = *spp; 1599 sp->fcnt = getStackSheetSize(sp); 1600 *spp = sp; 1601 } 1602 sp->pres[--sp->fcnt] = ptr; 1603 return TRUE; 1604 } 1605 1606 static int/*BOOL*/ 1607 popRestriction( 1608 RestrictStackT **spp, 1609 const restrict_u **opp 1610 ) 1611 { 1612 RestrictStackT *sp; 1613 1614 if (NULL == (sp = *spp) || sp->fcnt >= getStackSheetSize(sp)) 1615 return FALSE; 1616 1617 *opp = sp->pres[sp->fcnt++]; 1618 if (sp->fcnt >= getStackSheetSize(sp)) { 1619 /* discard sheet from scratch pad */ 1620 *spp = sp->link; 1621 free(sp); 1622 } 1623 return TRUE; 1624 } 1625 1626 static void 1627 flushRestrictionStack( 1628 RestrictStackT **spp 1629 ) 1630 { 1631 RestrictStackT *sp; 1632 1633 while (NULL != (sp = *spp)) { 1634 *spp = sp->link; 1635 free(sp); 1636 } 1637 } 1638 1639 /* 1640 * list_restrict4 - iterative helper for list_restrict dumps IPv4 1641 * restriction list in reverse order. 1642 */ 1643 static void 1644 list_restrict4( 1645 const restrict_u * res, 1646 struct info_restrict ** ppir 1647 ) 1648 { 1649 RestrictStackT * rpad; 1650 struct info_restrict * pir; 1651 1652 pir = *ppir; 1653 for (rpad = NULL; res; res = res->link) 1654 if (!pushRestriction(&rpad, res)) 1655 break; 1656 1657 while (pir && popRestriction(&rpad, &res)) { 1658 pir->addr = htonl(res->u.v4.addr); 1659 if (client_v6_capable) 1660 pir->v6_flag = 0; 1661 pir->mask = htonl(res->u.v4.mask); 1662 pir->count = htonl(res->count); 1663 pir->rflags = htons(res->rflags); 1664 pir->mflags = htons(res->mflags); 1665 pir = (struct info_restrict *)more_pkt(); 1666 } 1667 flushRestrictionStack(&rpad); 1668 *ppir = pir; 1669 } 1670 1671 /* 1672 * list_restrict6 - iterative helper for list_restrict dumps IPv6 1673 * restriction list in reverse order. 1674 */ 1675 static void 1676 list_restrict6( 1677 const restrict_u * res, 1678 struct info_restrict ** ppir 1679 ) 1680 { 1681 RestrictStackT * rpad; 1682 struct info_restrict * pir; 1683 1684 pir = *ppir; 1685 for (rpad = NULL; res; res = res->link) 1686 if (!pushRestriction(&rpad, res)) 1687 break; 1688 1689 while (pir && popRestriction(&rpad, &res)) { 1690 pir->addr6 = res->u.v6.addr; 1691 pir->mask6 = res->u.v6.mask; 1692 pir->v6_flag = 1; 1693 pir->count = htonl(res->count); 1694 pir->rflags = htons(res->rflags); 1695 pir->mflags = htons(res->mflags); 1696 pir = (struct info_restrict *)more_pkt(); 1697 } 1698 flushRestrictionStack(&rpad); 1699 *ppir = pir; 1700 } 1701 1702 1703 /* 1704 * list_restrict - return the restrict list 1705 */ 1706 static void 1707 list_restrict( 1708 sockaddr_u *srcadr, 1709 endpt *inter, 1710 struct req_pkt *inpkt 1711 ) 1712 { 1713 struct info_restrict *ir; 1714 1715 DPRINTF(3, ("wants restrict list summary\n")); 1716 1717 ir = (struct info_restrict *)prepare_pkt(srcadr, inter, inpkt, 1718 v6sizeof(struct info_restrict)); 1719 1720 /* 1721 * The restriction lists are kept sorted in the reverse order 1722 * than they were originally. To preserve the output semantics, 1723 * dump each list in reverse order. The workers take care of that. 1724 */ 1725 list_restrict4(restrictlist4, &ir); 1726 if (client_v6_capable) 1727 list_restrict6(restrictlist6, &ir); 1728 flush_pkt(); 1729 } 1730 1731 1732 /* 1733 * do_resaddflags - add flags to a restrict entry (or create one) 1734 */ 1735 static void 1736 do_resaddflags( 1737 sockaddr_u *srcadr, 1738 endpt *inter, 1739 struct req_pkt *inpkt 1740 ) 1741 { 1742 do_restrict(srcadr, inter, inpkt, RESTRICT_FLAGS); 1743 } 1744 1745 1746 1747 /* 1748 * do_ressubflags - remove flags from a restrict entry 1749 */ 1750 static void 1751 do_ressubflags( 1752 sockaddr_u *srcadr, 1753 endpt *inter, 1754 struct req_pkt *inpkt 1755 ) 1756 { 1757 do_restrict(srcadr, inter, inpkt, RESTRICT_UNFLAG); 1758 } 1759 1760 1761 /* 1762 * do_unrestrict - remove a restrict entry from the list 1763 */ 1764 static void 1765 do_unrestrict( 1766 sockaddr_u *srcadr, 1767 endpt *inter, 1768 struct req_pkt *inpkt 1769 ) 1770 { 1771 do_restrict(srcadr, inter, inpkt, RESTRICT_REMOVE); 1772 } 1773 1774 1775 /* 1776 * do_restrict - do the dirty stuff of dealing with restrictions 1777 */ 1778 static void 1779 do_restrict( 1780 sockaddr_u *srcadr, 1781 endpt *inter, 1782 struct req_pkt *inpkt, 1783 restrict_op op 1784 ) 1785 { 1786 char * datap; 1787 struct conf_restrict cr; 1788 u_short items; 1789 size_t item_sz; 1790 sockaddr_u matchaddr; 1791 sockaddr_u matchmask; 1792 int bad; 1793 1794 switch(op) { 1795 case RESTRICT_FLAGS: 1796 case RESTRICT_UNFLAG: 1797 case RESTRICT_REMOVE: 1798 case RESTRICT_REMOVEIF: 1799 break; 1800 1801 default: 1802 req_ack(srcadr, inter, inpkt, INFO_ERR_FMT); 1803 return; 1804 } 1805 1806 /* 1807 * Do a check of the flags to make sure that only 1808 * the NTPPORT flag is set, if any. If not, complain 1809 * about it. Note we are very picky here. 1810 */ 1811 items = INFO_NITEMS(inpkt->err_nitems); 1812 item_sz = INFO_ITEMSIZE(inpkt->mbz_itemsize); 1813 datap = inpkt->u.data; 1814 if (item_sz > sizeof(cr)) { 1815 req_ack(srcadr, inter, inpkt, INFO_ERR_FMT); 1816 return; 1817 } 1818 1819 bad = 0; 1820 while (items-- > 0 && !bad) { 1821 memcpy(&cr, datap, item_sz); 1822 cr.flags = ntohs(cr.flags); /* XXX */ 1823 cr.mflags = ntohs(cr.mflags); 1824 if (~RESM_NTPONLY & cr.mflags) 1825 bad |= 1; 1826 if (~RES_ALLFLAGS & cr.flags) 1827 bad |= 2; 1828 if (INADDR_ANY != cr.mask) { 1829 if (client_v6_capable && cr.v6_flag) { 1830 if (IN6_IS_ADDR_UNSPECIFIED(&cr.addr6)) 1831 bad |= 4; 1832 } else { 1833 if (INADDR_ANY == cr.addr) 1834 bad |= 8; 1835 } 1836 } 1837 datap += item_sz; 1838 } 1839 1840 if (bad) { 1841 msyslog(LOG_ERR, "do_restrict: bad = %#x", bad); 1842 req_ack(srcadr, inter, inpkt, INFO_ERR_FMT); 1843 return; 1844 } 1845 1846 /* 1847 * Looks okay, try it out. Needs to reload data pointer and 1848 * item counter. (Talos-CAN-0052) 1849 */ 1850 ZERO_SOCK(&matchaddr); 1851 ZERO_SOCK(&matchmask); 1852 items = INFO_NITEMS(inpkt->err_nitems); 1853 datap = inpkt->u.data; 1854 1855 while (items-- > 0) { 1856 memcpy(&cr, datap, item_sz); 1857 cr.flags = ntohs(cr.flags); /* XXX: size */ 1858 cr.mflags = ntohs(cr.mflags); 1859 cr.ippeerlimit = ntohs(cr.ippeerlimit); 1860 if (client_v6_capable && cr.v6_flag) { 1861 AF(&matchaddr) = AF_INET6; 1862 AF(&matchmask) = AF_INET6; 1863 SOCK_ADDR6(&matchaddr) = cr.addr6; 1864 SOCK_ADDR6(&matchmask) = cr.mask6; 1865 } else { 1866 AF(&matchaddr) = AF_INET; 1867 AF(&matchmask) = AF_INET; 1868 NSRCADR(&matchaddr) = cr.addr; 1869 NSRCADR(&matchmask) = cr.mask; 1870 } 1871 hack_restrict(op, &matchaddr, &matchmask, cr.mflags, 1872 cr.ippeerlimit, cr.flags, 0); 1873 datap += item_sz; 1874 } 1875 1876 req_ack(srcadr, inter, inpkt, INFO_OKAY); 1877 } 1878 1879 1880 /* 1881 * mon_getlist - return monitor data 1882 */ 1883 static void 1884 mon_getlist( 1885 sockaddr_u *srcadr, 1886 endpt *inter, 1887 struct req_pkt *inpkt 1888 ) 1889 { 1890 req_ack(srcadr, inter, inpkt, INFO_ERR_NODATA); 1891 } 1892 1893 1894 /* 1895 * Module entry points and the flags they correspond with 1896 */ 1897 struct reset_entry { 1898 int flag; /* flag this corresponds to */ 1899 void (*handler)(void); /* routine to handle request */ 1900 }; 1901 1902 struct reset_entry reset_entries[] = { 1903 { RESET_FLAG_ALLPEERS, peer_all_reset }, 1904 { RESET_FLAG_IO, io_clr_stats }, 1905 { RESET_FLAG_SYS, proto_clr_stats }, 1906 { RESET_FLAG_MEM, peer_clr_stats }, 1907 { RESET_FLAG_TIMER, timer_clr_stats }, 1908 { RESET_FLAG_AUTH, reset_auth_stats }, 1909 { RESET_FLAG_CTL, ctl_clr_stats }, 1910 { 0, 0 } 1911 }; 1912 1913 /* 1914 * reset_stats - reset statistic counters here and there 1915 */ 1916 static void 1917 reset_stats( 1918 sockaddr_u *srcadr, 1919 endpt *inter, 1920 struct req_pkt *inpkt 1921 ) 1922 { 1923 struct reset_flags *rflags; 1924 u_long flags; 1925 struct reset_entry *rent; 1926 1927 if (INFO_NITEMS(inpkt->err_nitems) > 1) { 1928 msyslog(LOG_ERR, "reset_stats: err_nitems > 1"); 1929 req_ack(srcadr, inter, inpkt, INFO_ERR_FMT); 1930 return; 1931 } 1932 1933 rflags = (struct reset_flags *)&inpkt->u; 1934 flags = ntohl(rflags->flags); 1935 1936 if (flags & ~RESET_ALLFLAGS) { 1937 msyslog(LOG_ERR, "reset_stats: reset leaves %#lx", 1938 flags & ~RESET_ALLFLAGS); 1939 req_ack(srcadr, inter, inpkt, INFO_ERR_FMT); 1940 return; 1941 } 1942 1943 for (rent = reset_entries; rent->flag != 0; rent++) { 1944 if (flags & rent->flag) 1945 (*rent->handler)(); 1946 } 1947 req_ack(srcadr, inter, inpkt, INFO_OKAY); 1948 } 1949 1950 1951 /* 1952 * reset_peer - clear a peer's statistics 1953 */ 1954 static void 1955 reset_peer( 1956 sockaddr_u *srcadr, 1957 endpt *inter, 1958 struct req_pkt *inpkt 1959 ) 1960 { 1961 u_short items; 1962 size_t item_sz; 1963 char * datap; 1964 struct conf_unpeer cp; 1965 struct peer * p; 1966 sockaddr_u peeraddr; 1967 int bad; 1968 1969 /* 1970 * We check first to see that every peer exists. If not, 1971 * we return an error. 1972 */ 1973 1974 items = INFO_NITEMS(inpkt->err_nitems); 1975 item_sz = INFO_ITEMSIZE(inpkt->mbz_itemsize); 1976 datap = inpkt->u.data; 1977 if (item_sz > sizeof(cp)) { 1978 req_ack(srcadr, inter, inpkt, INFO_ERR_FMT); 1979 return; 1980 } 1981 1982 bad = FALSE; 1983 while (items-- > 0 && !bad) { 1984 ZERO(cp); 1985 memcpy(&cp, datap, item_sz); 1986 ZERO_SOCK(&peeraddr); 1987 if (client_v6_capable && cp.v6_flag) { 1988 AF(&peeraddr) = AF_INET6; 1989 SOCK_ADDR6(&peeraddr) = cp.peeraddr6; 1990 } else { 1991 AF(&peeraddr) = AF_INET; 1992 NSRCADR(&peeraddr) = cp.peeraddr; 1993 } 1994 1995 #ifdef ISC_PLATFORM_HAVESALEN 1996 peeraddr.sa.sa_len = SOCKLEN(&peeraddr); 1997 #endif 1998 p = findexistingpeer(&peeraddr, NULL, NULL, -1, 0, NULL); 1999 if (NULL == p) 2000 bad++; 2001 datap += item_sz; 2002 } 2003 2004 if (bad) { 2005 req_ack(srcadr, inter, inpkt, INFO_ERR_NODATA); 2006 return; 2007 } 2008 2009 /* 2010 * Now do it in earnest. Needs to reload data pointer and item 2011 * counter. (Talos-CAN-0052) 2012 */ 2013 2014 items = INFO_NITEMS(inpkt->err_nitems); 2015 datap = inpkt->u.data; 2016 while (items-- > 0) { 2017 ZERO(cp); 2018 memcpy(&cp, datap, item_sz); 2019 ZERO_SOCK(&peeraddr); 2020 if (client_v6_capable && cp.v6_flag) { 2021 AF(&peeraddr) = AF_INET6; 2022 SOCK_ADDR6(&peeraddr) = cp.peeraddr6; 2023 } else { 2024 AF(&peeraddr) = AF_INET; 2025 NSRCADR(&peeraddr) = cp.peeraddr; 2026 } 2027 SET_PORT(&peeraddr, 123); 2028 #ifdef ISC_PLATFORM_HAVESALEN 2029 peeraddr.sa.sa_len = SOCKLEN(&peeraddr); 2030 #endif 2031 p = findexistingpeer(&peeraddr, NULL, NULL, -1, 0, NULL); 2032 while (p != NULL) { 2033 peer_reset(p); 2034 p = findexistingpeer(&peeraddr, NULL, p, -1, 0, NULL); 2035 } 2036 datap += item_sz; 2037 } 2038 2039 req_ack(srcadr, inter, inpkt, INFO_OKAY); 2040 } 2041 2042 2043 /* 2044 * do_key_reread - reread the encryption key file 2045 */ 2046 static void 2047 do_key_reread( 2048 sockaddr_u *srcadr, 2049 endpt *inter, 2050 struct req_pkt *inpkt 2051 ) 2052 { 2053 rereadkeys(); 2054 req_ack(srcadr, inter, inpkt, INFO_OKAY); 2055 } 2056 2057 2058 /* 2059 * trust_key - make one or more keys trusted 2060 */ 2061 static void 2062 trust_key( 2063 sockaddr_u *srcadr, 2064 endpt *inter, 2065 struct req_pkt *inpkt 2066 ) 2067 { 2068 do_trustkey(srcadr, inter, inpkt, 1); 2069 } 2070 2071 2072 /* 2073 * untrust_key - make one or more keys untrusted 2074 */ 2075 static void 2076 untrust_key( 2077 sockaddr_u *srcadr, 2078 endpt *inter, 2079 struct req_pkt *inpkt 2080 ) 2081 { 2082 do_trustkey(srcadr, inter, inpkt, 0); 2083 } 2084 2085 2086 /* 2087 * do_trustkey - make keys either trustable or untrustable 2088 */ 2089 static void 2090 do_trustkey( 2091 sockaddr_u *srcadr, 2092 endpt *inter, 2093 struct req_pkt *inpkt, 2094 u_long trust 2095 ) 2096 { 2097 register uint32_t *kp; 2098 register int items; 2099 2100 items = INFO_NITEMS(inpkt->err_nitems); 2101 kp = (uint32_t *)&inpkt->u; 2102 while (items-- > 0) { 2103 authtrust(*kp, trust); 2104 kp++; 2105 } 2106 2107 req_ack(srcadr, inter, inpkt, INFO_OKAY); 2108 } 2109 2110 2111 /* 2112 * get_auth_info - return some stats concerning the authentication module 2113 */ 2114 static void 2115 get_auth_info( 2116 sockaddr_u *srcadr, 2117 endpt *inter, 2118 struct req_pkt *inpkt 2119 ) 2120 { 2121 register struct info_auth *ia; 2122 2123 ia = (struct info_auth *)prepare_pkt(srcadr, inter, inpkt, 2124 sizeof(struct info_auth)); 2125 2126 ia->numkeys = htonl((u_int32)authnumkeys); 2127 ia->numfreekeys = htonl((u_int32)authnumfreekeys); 2128 ia->keylookups = htonl((u_int32)authkeylookups); 2129 ia->keynotfound = htonl((u_int32)authkeynotfound); 2130 ia->encryptions = htonl((u_int32)authencryptions); 2131 ia->decryptions = htonl((u_int32)authdecryptions); 2132 ia->keyuncached = htonl((u_int32)authkeyuncached); 2133 ia->expired = htonl((u_int32)authkeyexpired); 2134 ia->timereset = htonl((u_int32)(current_time - auth_timereset)); 2135 2136 (void) more_pkt(); 2137 flush_pkt(); 2138 } 2139 2140 2141 2142 /* 2143 * reset_auth_stats - reset the authentication stat counters. Done here 2144 * to keep ntp-isms out of the authentication module 2145 */ 2146 void 2147 reset_auth_stats(void) 2148 { 2149 authkeylookups = 0; 2150 authkeynotfound = 0; 2151 authencryptions = 0; 2152 authdecryptions = 0; 2153 authkeyuncached = 0; 2154 auth_timereset = current_time; 2155 } 2156 2157 2158 /* 2159 * req_get_traps - return information about current trap holders 2160 */ 2161 static void 2162 req_get_traps( 2163 sockaddr_u *srcadr, 2164 endpt *inter, 2165 struct req_pkt *inpkt 2166 ) 2167 { 2168 struct info_trap *it; 2169 struct ctl_trap *tr; 2170 size_t i; 2171 2172 if (num_ctl_traps == 0) { 2173 req_ack(srcadr, inter, inpkt, INFO_ERR_NODATA); 2174 return; 2175 } 2176 2177 it = (struct info_trap *)prepare_pkt(srcadr, inter, inpkt, 2178 v6sizeof(struct info_trap)); 2179 2180 for (i = 0, tr = ctl_traps; it && i < COUNTOF(ctl_traps); i++, tr++) { 2181 if (tr->tr_flags & TRAP_INUSE) { 2182 if (IS_IPV4(&tr->tr_addr)) { 2183 if (tr->tr_localaddr == any_interface) 2184 it->local_address = 0; 2185 else 2186 it->local_address 2187 = NSRCADR(&tr->tr_localaddr->sin); 2188 it->trap_address = NSRCADR(&tr->tr_addr); 2189 if (client_v6_capable) 2190 it->v6_flag = 0; 2191 } else { 2192 if (!client_v6_capable) 2193 continue; 2194 it->local_address6 2195 = SOCK_ADDR6(&tr->tr_localaddr->sin); 2196 it->trap_address6 = SOCK_ADDR6(&tr->tr_addr); 2197 it->v6_flag = 1; 2198 } 2199 it->trap_port = NSRCPORT(&tr->tr_addr); 2200 it->sequence = htons(tr->tr_sequence); 2201 it->settime = htonl((u_int32)(current_time - tr->tr_settime)); 2202 it->origtime = htonl((u_int32)(current_time - tr->tr_origtime)); 2203 it->resets = htonl((u_int32)tr->tr_resets); 2204 it->flags = htonl((u_int32)tr->tr_flags); 2205 it = (struct info_trap *)more_pkt(); 2206 } 2207 } 2208 flush_pkt(); 2209 } 2210 2211 2212 /* 2213 * req_set_trap - configure a trap 2214 */ 2215 static void 2216 req_set_trap( 2217 sockaddr_u *srcadr, 2218 endpt *inter, 2219 struct req_pkt *inpkt 2220 ) 2221 { 2222 do_setclr_trap(srcadr, inter, inpkt, 1); 2223 } 2224 2225 2226 2227 /* 2228 * req_clr_trap - unconfigure a trap 2229 */ 2230 static void 2231 req_clr_trap( 2232 sockaddr_u *srcadr, 2233 endpt *inter, 2234 struct req_pkt *inpkt 2235 ) 2236 { 2237 do_setclr_trap(srcadr, inter, inpkt, 0); 2238 } 2239 2240 2241 2242 /* 2243 * do_setclr_trap - do the grunge work of (un)configuring a trap 2244 */ 2245 static void 2246 do_setclr_trap( 2247 sockaddr_u *srcadr, 2248 endpt *inter, 2249 struct req_pkt *inpkt, 2250 int set 2251 ) 2252 { 2253 register struct conf_trap *ct; 2254 register endpt *linter; 2255 int res; 2256 sockaddr_u laddr; 2257 2258 /* 2259 * Prepare sockaddr 2260 */ 2261 ZERO_SOCK(&laddr); 2262 AF(&laddr) = AF(srcadr); 2263 SET_PORT(&laddr, NTP_PORT); 2264 2265 /* 2266 * Restrict ourselves to one item only. This eliminates 2267 * the error reporting problem. 2268 */ 2269 if (INFO_NITEMS(inpkt->err_nitems) > 1) { 2270 msyslog(LOG_ERR, "do_setclr_trap: err_nitems > 1"); 2271 req_ack(srcadr, inter, inpkt, INFO_ERR_FMT); 2272 return; 2273 } 2274 ct = (struct conf_trap *)&inpkt->u; 2275 2276 /* 2277 * Look for the local interface. If none, use the default. 2278 */ 2279 if (ct->local_address == 0) { 2280 linter = any_interface; 2281 } else { 2282 if (IS_IPV4(&laddr)) 2283 NSRCADR(&laddr) = ct->local_address; 2284 else 2285 SOCK_ADDR6(&laddr) = ct->local_address6; 2286 linter = findinterface(&laddr); 2287 if (NULL == linter) { 2288 req_ack(srcadr, inter, inpkt, INFO_ERR_NODATA); 2289 return; 2290 } 2291 } 2292 2293 if (IS_IPV4(&laddr)) 2294 NSRCADR(&laddr) = ct->trap_address; 2295 else 2296 SOCK_ADDR6(&laddr) = ct->trap_address6; 2297 if (ct->trap_port) 2298 NSRCPORT(&laddr) = ct->trap_port; 2299 else 2300 SET_PORT(&laddr, TRAPPORT); 2301 2302 if (set) { 2303 res = ctlsettrap(&laddr, linter, 0, 2304 INFO_VERSION(inpkt->rm_vn_mode)); 2305 } else { 2306 res = ctlclrtrap(&laddr, linter, 0); 2307 } 2308 2309 if (!res) { 2310 req_ack(srcadr, inter, inpkt, INFO_ERR_NODATA); 2311 } else { 2312 req_ack(srcadr, inter, inpkt, INFO_OKAY); 2313 } 2314 return; 2315 } 2316 2317 /* 2318 * Validate a request packet for a new request or control key: 2319 * - only one item allowed 2320 * - key must be valid (that is, known, and not in the autokey range) 2321 */ 2322 static void 2323 set_keyid_checked( 2324 keyid_t *into, 2325 const char *what, 2326 sockaddr_u *srcadr, 2327 endpt *inter, 2328 struct req_pkt *inpkt 2329 ) 2330 { 2331 keyid_t *pkeyid; 2332 keyid_t tmpkey; 2333 2334 /* restrict ourselves to one item only */ 2335 if (INFO_NITEMS(inpkt->err_nitems) > 1) { 2336 msyslog(LOG_ERR, "set_keyid_checked[%s]: err_nitems > 1", 2337 what); 2338 req_ack(srcadr, inter, inpkt, INFO_ERR_FMT); 2339 return; 2340 } 2341 2342 /* plug the new key from the packet */ 2343 pkeyid = (keyid_t *)&inpkt->u; 2344 tmpkey = ntohl(*pkeyid); 2345 2346 /* validate the new key id, claim data error on failure */ 2347 if (tmpkey < 1 || tmpkey > NTP_MAXKEY || !auth_havekey(tmpkey)) { 2348 msyslog(LOG_ERR, "set_keyid_checked[%s]: invalid key id: %ld", 2349 what, (long)tmpkey); 2350 req_ack(srcadr, inter, inpkt, INFO_ERR_NODATA); 2351 return; 2352 } 2353 2354 /* if we arrive here, the key is good -- use it */ 2355 *into = tmpkey; 2356 req_ack(srcadr, inter, inpkt, INFO_OKAY); 2357 } 2358 2359 /* 2360 * set_request_keyid - set the keyid used to authenticate requests 2361 */ 2362 static void 2363 set_request_keyid( 2364 sockaddr_u *srcadr, 2365 endpt *inter, 2366 struct req_pkt *inpkt 2367 ) 2368 { 2369 set_keyid_checked(&info_auth_keyid, "request", 2370 srcadr, inter, inpkt); 2371 } 2372 2373 2374 2375 /* 2376 * set_control_keyid - set the keyid used to authenticate requests 2377 */ 2378 static void 2379 set_control_keyid( 2380 sockaddr_u *srcadr, 2381 endpt *inter, 2382 struct req_pkt *inpkt 2383 ) 2384 { 2385 set_keyid_checked(&ctl_auth_keyid, "control", 2386 srcadr, inter, inpkt); 2387 } 2388 2389 2390 2391 /* 2392 * get_ctl_stats - return some stats concerning the control message module 2393 */ 2394 static void 2395 get_ctl_stats( 2396 sockaddr_u *srcadr, 2397 endpt *inter, 2398 struct req_pkt *inpkt 2399 ) 2400 { 2401 register struct info_control *ic; 2402 2403 ic = (struct info_control *)prepare_pkt(srcadr, inter, inpkt, 2404 sizeof(struct info_control)); 2405 2406 ic->ctltimereset = htonl((u_int32)(current_time - ctltimereset)); 2407 ic->numctlreq = htonl((u_int32)numctlreq); 2408 ic->numctlbadpkts = htonl((u_int32)numctlbadpkts); 2409 ic->numctlresponses = htonl((u_int32)numctlresponses); 2410 ic->numctlfrags = htonl((u_int32)numctlfrags); 2411 ic->numctlerrors = htonl((u_int32)numctlerrors); 2412 ic->numctltooshort = htonl((u_int32)numctltooshort); 2413 ic->numctlinputresp = htonl((u_int32)numctlinputresp); 2414 ic->numctlinputfrag = htonl((u_int32)numctlinputfrag); 2415 ic->numctlinputerr = htonl((u_int32)numctlinputerr); 2416 ic->numctlbadoffset = htonl((u_int32)numctlbadoffset); 2417 ic->numctlbadversion = htonl((u_int32)numctlbadversion); 2418 ic->numctldatatooshort = htonl((u_int32)numctldatatooshort); 2419 ic->numctlbadop = htonl((u_int32)numctlbadop); 2420 ic->numasyncmsgs = htonl((u_int32)numasyncmsgs); 2421 2422 (void) more_pkt(); 2423 flush_pkt(); 2424 } 2425 2426 2427 #ifdef KERNEL_PLL 2428 /* 2429 * get_kernel_info - get kernel pll/pps information 2430 */ 2431 static void 2432 get_kernel_info( 2433 sockaddr_u *srcadr, 2434 endpt *inter, 2435 struct req_pkt *inpkt 2436 ) 2437 { 2438 register struct info_kernel *ik; 2439 struct timex ntx; 2440 2441 if (!pll_control) { 2442 req_ack(srcadr, inter, inpkt, INFO_ERR_NODATA); 2443 return; 2444 } 2445 2446 ZERO(ntx); 2447 if (ntp_adjtime(&ntx) < 0) 2448 msyslog(LOG_ERR, "get_kernel_info: ntp_adjtime() failed: %m"); 2449 ik = (struct info_kernel *)prepare_pkt(srcadr, inter, inpkt, 2450 sizeof(struct info_kernel)); 2451 2452 /* 2453 * pll variables 2454 */ 2455 ik->offset = htonl((u_int32)ntx.offset); 2456 ik->freq = htonl((u_int32)ntx.freq); 2457 ik->maxerror = htonl((u_int32)ntx.maxerror); 2458 ik->esterror = htonl((u_int32)ntx.esterror); 2459 ik->status = htons(ntx.status); 2460 ik->constant = htonl((u_int32)ntx.constant); 2461 ik->precision = htonl((u_int32)ntx.precision); 2462 ik->tolerance = htonl((u_int32)ntx.tolerance); 2463 2464 /* 2465 * pps variables 2466 */ 2467 ik->ppsfreq = htonl((u_int32)ntx.ppsfreq); 2468 ik->jitter = htonl((u_int32)ntx.jitter); 2469 ik->shift = htons(ntx.shift); 2470 ik->stabil = htonl((u_int32)ntx.stabil); 2471 ik->jitcnt = htonl((u_int32)ntx.jitcnt); 2472 ik->calcnt = htonl((u_int32)ntx.calcnt); 2473 ik->errcnt = htonl((u_int32)ntx.errcnt); 2474 ik->stbcnt = htonl((u_int32)ntx.stbcnt); 2475 2476 (void) more_pkt(); 2477 flush_pkt(); 2478 } 2479 #endif /* KERNEL_PLL */ 2480 2481 2482 #ifdef REFCLOCK 2483 /* 2484 * get_clock_info - get info about a clock 2485 */ 2486 static void 2487 get_clock_info( 2488 sockaddr_u *srcadr, 2489 endpt *inter, 2490 struct req_pkt *inpkt 2491 ) 2492 { 2493 register struct info_clock *ic; 2494 register u_int32 *clkaddr; 2495 register int items; 2496 struct refclockstat clock_stat; 2497 sockaddr_u addr; 2498 l_fp ltmp; 2499 2500 ZERO_SOCK(&addr); 2501 AF(&addr) = AF_INET; 2502 #ifdef ISC_PLATFORM_HAVESALEN 2503 addr.sa.sa_len = SOCKLEN(&addr); 2504 #endif 2505 SET_PORT(&addr, NTP_PORT); 2506 items = INFO_NITEMS(inpkt->err_nitems); 2507 clkaddr = &inpkt->u.u32[0]; 2508 2509 ic = (struct info_clock *)prepare_pkt(srcadr, inter, inpkt, 2510 sizeof(struct info_clock)); 2511 2512 while (items-- > 0 && ic) { 2513 NSRCADR(&addr) = *clkaddr++; 2514 if (!ISREFCLOCKADR(&addr) || NULL == 2515 findexistingpeer(&addr, NULL, NULL, -1, 0, NULL)) { 2516 req_ack(srcadr, inter, inpkt, INFO_ERR_NODATA); 2517 return; 2518 } 2519 2520 clock_stat.kv_list = (struct ctl_var *)0; 2521 2522 refclock_control(&addr, NULL, &clock_stat); 2523 2524 ic->clockadr = NSRCADR(&addr); 2525 ic->type = clock_stat.type; 2526 ic->flags = clock_stat.flags; 2527 ic->lastevent = clock_stat.lastevent; 2528 ic->currentstatus = clock_stat.currentstatus; 2529 ic->polls = htonl((u_int32)clock_stat.polls); 2530 ic->noresponse = htonl((u_int32)clock_stat.noresponse); 2531 ic->badformat = htonl((u_int32)clock_stat.badformat); 2532 ic->baddata = htonl((u_int32)clock_stat.baddata); 2533 ic->timestarted = htonl((u_int32)clock_stat.timereset); 2534 DTOLFP(clock_stat.fudgetime1, <mp); 2535 HTONL_FP(<mp, &ic->fudgetime1); 2536 DTOLFP(clock_stat.fudgetime2, <mp); 2537 HTONL_FP(<mp, &ic->fudgetime2); 2538 ic->fudgeval1 = htonl((u_int32)clock_stat.fudgeval1); 2539 /* [Bug3527] Backward Incompatible: ic->fudgeval2 is 2540 * a string, instantiated via memcpy() so there is no 2541 * endian issue to correct. 2542 */ 2543 #ifdef DISABLE_BUG3527_FIX 2544 ic->fudgeval2 = htonl(clock_stat.fudgeval2); 2545 #else 2546 ic->fudgeval2 = clock_stat.fudgeval2; 2547 #endif 2548 2549 free_varlist(clock_stat.kv_list); 2550 2551 ic = (struct info_clock *)more_pkt(); 2552 } 2553 flush_pkt(); 2554 } 2555 2556 2557 2558 /* 2559 * set_clock_fudge - get a clock's fudge factors 2560 */ 2561 static void 2562 set_clock_fudge( 2563 sockaddr_u *srcadr, 2564 endpt *inter, 2565 struct req_pkt *inpkt 2566 ) 2567 { 2568 register struct conf_fudge *cf; 2569 register int items; 2570 struct refclockstat clock_stat; 2571 sockaddr_u addr; 2572 l_fp ltmp; 2573 2574 ZERO(addr); 2575 ZERO(clock_stat); 2576 items = INFO_NITEMS(inpkt->err_nitems); 2577 cf = (struct conf_fudge *)&inpkt->u; 2578 2579 while (items-- > 0) { 2580 AF(&addr) = AF_INET; 2581 NSRCADR(&addr) = cf->clockadr; 2582 #ifdef ISC_PLATFORM_HAVESALEN 2583 addr.sa.sa_len = SOCKLEN(&addr); 2584 #endif 2585 SET_PORT(&addr, NTP_PORT); 2586 if (!ISREFCLOCKADR(&addr) || NULL == 2587 findexistingpeer(&addr, NULL, NULL, -1, 0, NULL)) { 2588 req_ack(srcadr, inter, inpkt, INFO_ERR_NODATA); 2589 return; 2590 } 2591 2592 switch(ntohl(cf->which)) { 2593 case FUDGE_TIME1: 2594 NTOHL_FP(&cf->fudgetime, <mp); 2595 LFPTOD(<mp, clock_stat.fudgetime1); 2596 clock_stat.haveflags = CLK_HAVETIME1; 2597 break; 2598 case FUDGE_TIME2: 2599 NTOHL_FP(&cf->fudgetime, <mp); 2600 LFPTOD(<mp, clock_stat.fudgetime2); 2601 clock_stat.haveflags = CLK_HAVETIME2; 2602 break; 2603 case FUDGE_VAL1: 2604 clock_stat.fudgeval1 = ntohl(cf->fudgeval_flags); 2605 clock_stat.haveflags = CLK_HAVEVAL1; 2606 break; 2607 case FUDGE_VAL2: 2608 clock_stat.fudgeval2 = ntohl(cf->fudgeval_flags); 2609 clock_stat.haveflags = CLK_HAVEVAL2; 2610 break; 2611 case FUDGE_FLAGS: 2612 clock_stat.flags = (u_char) (ntohl(cf->fudgeval_flags) & 0xf); 2613 clock_stat.haveflags = 2614 (CLK_HAVEFLAG1|CLK_HAVEFLAG2|CLK_HAVEFLAG3|CLK_HAVEFLAG4); 2615 break; 2616 default: 2617 msyslog(LOG_ERR, "set_clock_fudge: default!"); 2618 req_ack(srcadr, inter, inpkt, INFO_ERR_FMT); 2619 return; 2620 } 2621 2622 refclock_control(&addr, &clock_stat, (struct refclockstat *)0); 2623 } 2624 2625 req_ack(srcadr, inter, inpkt, INFO_OKAY); 2626 } 2627 #endif 2628 2629 #ifdef REFCLOCK 2630 /* 2631 * get_clkbug_info - get debugging info about a clock 2632 */ 2633 static void 2634 get_clkbug_info( 2635 sockaddr_u *srcadr, 2636 endpt *inter, 2637 struct req_pkt *inpkt 2638 ) 2639 { 2640 register int i; 2641 register struct info_clkbug *ic; 2642 register u_int32 *clkaddr; 2643 register int items; 2644 struct refclockbug bug; 2645 sockaddr_u addr; 2646 2647 ZERO_SOCK(&addr); 2648 AF(&addr) = AF_INET; 2649 #ifdef ISC_PLATFORM_HAVESALEN 2650 addr.sa.sa_len = SOCKLEN(&addr); 2651 #endif 2652 SET_PORT(&addr, NTP_PORT); 2653 items = INFO_NITEMS(inpkt->err_nitems); 2654 clkaddr = (u_int32 *)&inpkt->u; 2655 2656 ic = (struct info_clkbug *)prepare_pkt(srcadr, inter, inpkt, 2657 sizeof(struct info_clkbug)); 2658 2659 while (items-- > 0 && ic) { 2660 NSRCADR(&addr) = *clkaddr++; 2661 if (!ISREFCLOCKADR(&addr) || NULL == 2662 findexistingpeer(&addr, NULL, NULL, -1, 0, NULL)) { 2663 req_ack(srcadr, inter, inpkt, INFO_ERR_NODATA); 2664 return; 2665 } 2666 2667 ZERO(bug); 2668 refclock_buginfo(&addr, &bug); 2669 if (bug.nvalues == 0 && bug.ntimes == 0) { 2670 req_ack(srcadr, inter, inpkt, INFO_ERR_NODATA); 2671 return; 2672 } 2673 2674 ic->clockadr = NSRCADR(&addr); 2675 i = bug.nvalues; 2676 if (i > NUMCBUGVALUES) 2677 i = NUMCBUGVALUES; 2678 ic->nvalues = (u_char)i; 2679 ic->svalues = htons((u_short) (bug.svalues & ((1<<i)-1))); 2680 while (--i >= 0) 2681 ic->values[i] = htonl(bug.values[i]); 2682 2683 i = bug.ntimes; 2684 if (i > NUMCBUGTIMES) 2685 i = NUMCBUGTIMES; 2686 ic->ntimes = (u_char)i; 2687 ic->stimes = htonl(bug.stimes); 2688 while (--i >= 0) { 2689 HTONL_FP(&bug.times[i], &ic->times[i]); 2690 } 2691 2692 ic = (struct info_clkbug *)more_pkt(); 2693 } 2694 flush_pkt(); 2695 } 2696 #endif 2697 2698 /* 2699 * receiver of interface structures 2700 */ 2701 static void 2702 fill_info_if_stats(void *data, interface_info_t *interface_info) 2703 { 2704 struct info_if_stats **ifsp = (struct info_if_stats **)data; 2705 struct info_if_stats *ifs = *ifsp; 2706 endpt *ep = interface_info->ep; 2707 2708 if (NULL == ifs) 2709 return; 2710 2711 ZERO(*ifs); 2712 2713 if (IS_IPV6(&ep->sin)) { 2714 if (!client_v6_capable) 2715 return; 2716 ifs->v6_flag = 1; 2717 ifs->unaddr.addr6 = SOCK_ADDR6(&ep->sin); 2718 ifs->unbcast.addr6 = SOCK_ADDR6(&ep->bcast); 2719 ifs->unmask.addr6 = SOCK_ADDR6(&ep->mask); 2720 } else { 2721 ifs->v6_flag = 0; 2722 ifs->unaddr.addr = SOCK_ADDR4(&ep->sin); 2723 ifs->unbcast.addr = SOCK_ADDR4(&ep->bcast); 2724 ifs->unmask.addr = SOCK_ADDR4(&ep->mask); 2725 } 2726 ifs->v6_flag = htonl(ifs->v6_flag); 2727 strlcpy(ifs->name, ep->name, sizeof(ifs->name)); 2728 ifs->family = htons(ep->family); 2729 ifs->flags = htonl(ep->flags); 2730 ifs->last_ttl = htonl(ep->last_ttl); 2731 ifs->num_mcast = htonl(ep->num_mcast); 2732 ifs->received = htonl(ep->received); 2733 ifs->sent = htonl(ep->sent); 2734 ifs->notsent = htonl(ep->notsent); 2735 ifs->ifindex = htonl(ep->ifindex); 2736 /* scope no longer in endpt, in in6_addr typically */ 2737 ifs->scopeid = ifs->ifindex; 2738 ifs->ifnum = htonl(ep->ifnum); 2739 ifs->uptime = htonl(current_time - ep->starttime); 2740 ifs->ignore_packets = ep->ignore_packets; 2741 ifs->peercnt = htonl(ep->peercnt); 2742 ifs->action = interface_info->action; 2743 2744 *ifsp = (struct info_if_stats *)more_pkt(); 2745 } 2746 2747 /* 2748 * get_if_stats - get interface statistics 2749 */ 2750 static void 2751 get_if_stats( 2752 sockaddr_u *srcadr, 2753 endpt *inter, 2754 struct req_pkt *inpkt 2755 ) 2756 { 2757 struct info_if_stats *ifs; 2758 2759 DPRINTF(3, ("wants interface statistics\n")); 2760 2761 ifs = (struct info_if_stats *)prepare_pkt(srcadr, inter, inpkt, 2762 v6sizeof(struct info_if_stats)); 2763 2764 interface_enumerate(fill_info_if_stats, &ifs); 2765 2766 flush_pkt(); 2767 } 2768 2769 static void 2770 do_if_reload( 2771 sockaddr_u *srcadr, 2772 endpt *inter, 2773 struct req_pkt *inpkt 2774 ) 2775 { 2776 struct info_if_stats *ifs; 2777 2778 DPRINTF(3, ("wants interface reload\n")); 2779 2780 ifs = (struct info_if_stats *)prepare_pkt(srcadr, inter, inpkt, 2781 v6sizeof(struct info_if_stats)); 2782 2783 interface_update(fill_info_if_stats, &ifs); 2784 2785 flush_pkt(); 2786 } 2787 2788