/* * remote.c - remote control for the NSD daemon. * * Copyright (c) 2008, NLnet Labs. All rights reserved. * * This software is open source. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * * Redistributions of source code must retain the above copyright notice, * this list of conditions and the following disclaimer. * * Redistributions in binary form must reproduce the above copyright notice, * this list of conditions and the following disclaimer in the documentation * and/or other materials provided with the distribution. * * Neither the name of the NLNET LABS nor the names of its contributors may * be used to endorse or promote products derived from this software without * specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS * "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT * LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR * A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT * HOLDER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, * SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED * TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR * PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF * LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING * NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS * SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. */ /** * \file * * This file contains the remote control functionality for the daemon. * The remote control can be performed using either the commandline * nsd-control tool, or a TLS capable web browser. * The channel is secured using TLSv1, and certificates. * Both the server and the client(control tool) have their own keys. */ #include "config.h" #ifdef HAVE_SSL #ifdef HAVE_OPENSSL_SSL_H #include "openssl/ssl.h" #endif #ifdef HAVE_OPENSSL_ERR_H #include #endif #ifdef HAVE_OPENSSL_RAND_H #include #endif #include #include #include #include #ifndef USE_MINI_EVENT # ifdef HAVE_EVENT_H # include # else # include # include "event2/event_struct.h" # include "event2/event_compat.h" # endif #else # include "mini_event.h" #endif #include "remote.h" #include "util.h" #include "xfrd.h" #include "xfrd-notify.h" #include "xfrd-tcp.h" #include "nsd.h" #include "options.h" #include "difffile.h" #include "ipc.h" #ifdef HAVE_SYS_TYPES_H # include #endif #ifdef HAVE_SYS_STAT_H # include #endif #ifdef HAVE_NETDB_H # include #endif #ifdef HAVE_SYS_UN_H # include #endif /** number of seconds timeout on incoming remote control handshake */ #define REMOTE_CONTROL_TCP_TIMEOUT 120 /** repattern to master or slave */ #define REPAT_SLAVE 1 #define REPAT_MASTER 2 /** if you want zero to be inhibited in stats output. * it omits zeroes for types that have no acronym and unused-rcodes */ const int inhibit_zero = 1; /** * a busy control command connection, SSL state * Defined here to keep the definition private, and keep SSL out of the .h */ struct rc_state { /** the next item in list */ struct rc_state* next, *prev; /* if the event was added to the event_base */ int event_added; /** the commpoint */ struct event c; /** timeout for this state */ struct timeval tval; /** in the handshake part */ enum { rc_none, rc_hs_read, rc_hs_write } shake_state; /** the ssl state */ SSL* ssl; /** file descriptor */ int fd; /** the rc this is part of */ struct daemon_remote* rc; /** stats list next item */ struct rc_state* stats_next; /** stats list indicator (0 is not part of stats list, 1 is stats, * 2 is stats_noreset. */ int in_stats_list; }; /** * list of events for accepting connections */ struct acceptlist { struct acceptlist* next; int event_added; struct event c; char* ident; struct daemon_remote* rc; }; /** * The remote control state. */ struct daemon_remote { /** the master process for this remote control */ struct xfrd_state* xfrd; /** commpoints for accepting remote control connections */ struct acceptlist* accept_list; /* if certificates are used */ int use_cert; /** number of active commpoints that are handling remote control */ int active; /** max active commpoints */ int max_active; /** current commpoints busy; double linked, malloced */ struct rc_state* busy_list; /** commpoints waiting for stats to complete (also in busy_list) */ struct rc_state* stats_list; /** last time stats was reported */ struct timeval stats_time, boot_time; /** the SSL context for creating new SSL streams */ SSL_CTX* ctx; }; /** * Connection to print to, either SSL or plain over fd */ struct remote_stream { /** SSL structure, nonNULL if using SSL */ SSL* ssl; /** file descriptor for plain transfer */ int fd; }; typedef struct remote_stream RES; /** * Print fixed line of text over ssl connection in blocking mode * @param res: print to * @param text: the text. * @return false on connection failure. */ static int ssl_print_text(RES* res, const char* text); /** * printf style printing to the ssl connection * @param res: the RES connection to print to. Blocking. * @param format: printf style format string. * @return success or false on a network failure. */ static int ssl_printf(RES* res, const char* format, ...) ATTR_FORMAT(printf, 2, 3); /** * Read until \n is encountered * If stream signals EOF, the string up to then is returned (without \n). * @param res: the RES connection to read from. blocking. * @param buf: buffer to read to. * @param max: size of buffer. * @return false on connection failure. */ static int ssl_read_line(RES* res, char* buf, size_t max); /** perform the accept of a new remote control connection */ static void remote_accept_callback(int fd, short event, void* arg); /** perform remote control */ static void remote_control_callback(int fd, short event, void* arg); /** ---- end of private defines ---- **/ /** log ssl crypto err */ static void log_crypto_err(const char* str) { /* error:[error code]:[library name]:[function name]:[reason string] */ char buf[128]; unsigned long e; ERR_error_string_n(ERR_get_error(), buf, sizeof(buf)); log_msg(LOG_ERR, "%s crypto %s", str, buf); while( (e=ERR_get_error()) ) { ERR_error_string_n(e, buf, sizeof(buf)); log_msg(LOG_ERR, "and additionally crypto %s", buf); } } #ifdef BIND8_STATS /** subtract timers and the values do not overflow or become negative */ static void timeval_subtract(struct timeval* d, const struct timeval* end, const struct timeval* start) { #ifndef S_SPLINT_S time_t end_usec = end->tv_usec; d->tv_sec = end->tv_sec - start->tv_sec; if(end_usec < start->tv_usec) { end_usec += 1000000; d->tv_sec--; } d->tv_usec = end_usec - start->tv_usec; #endif } #endif /* BIND8_STATS */ static int remote_setup_ctx(struct daemon_remote* rc, struct nsd_options* cfg) { char* s_cert = cfg->server_cert_file; char* s_key = cfg->server_key_file; rc->ctx = server_tls_ctx_setup(s_key, s_cert, s_cert); if(!rc->ctx) { log_msg(LOG_ERR, "could not setup remote control TLS context"); return 0; } return 1; } struct daemon_remote* daemon_remote_create(struct nsd_options* cfg) { struct daemon_remote* rc = (struct daemon_remote*)xalloc_zero( sizeof(*rc)); rc->max_active = 10; assert(cfg->control_enable); if(options_remote_is_address(cfg)) { if(!remote_setup_ctx(rc, cfg)) { daemon_remote_delete(rc); return NULL; } rc->use_cert = 1; } else { struct ip_address_option* o; rc->ctx = NULL; rc->use_cert = 0; for(o = cfg->control_interface; o; o = o->next) { if(o->address && o->address[0] != '/') log_msg(LOG_WARNING, "control-interface %s is not using TLS, but plain transfer, because first control-interface in config file is a local socket (starts with a /).", o->address); } } /* and try to open the ports */ if(!daemon_remote_open_ports(rc, cfg)) { log_msg(LOG_ERR, "could not open remote control port"); daemon_remote_delete(rc); return NULL; } if(gettimeofday(&rc->boot_time, NULL) == -1) log_msg(LOG_ERR, "gettimeofday: %s", strerror(errno)); rc->stats_time = rc->boot_time; return rc; } void daemon_remote_close(struct daemon_remote* rc) { struct rc_state* p, *np; struct acceptlist* h, *nh; if(!rc) return; /* close listen sockets */ h = rc->accept_list; while(h) { nh = h->next; if(h->event_added) event_del(&h->c); close(h->c.ev_fd); free(h->ident); free(h); h = nh; } rc->accept_list = NULL; /* close busy connection sockets */ p = rc->busy_list; while(p) { np = p->next; if(p->event_added) event_del(&p->c); if(p->ssl) SSL_free(p->ssl); close(p->c.ev_fd); free(p); p = np; } rc->busy_list = NULL; rc->active = 0; } void daemon_remote_delete(struct daemon_remote* rc) { if(!rc) return; daemon_remote_close(rc); if(rc->ctx) { SSL_CTX_free(rc->ctx); } free(rc); } static int create_tcp_accept_sock(struct addrinfo* addr, int* noproto) { #if defined(SO_REUSEADDR) || (defined(INET6) && (defined(IPV6_V6ONLY) || defined(IPV6_USE_MIN_MTU) || defined(IPV6_MTU))) int on = 1; #endif int s; *noproto = 0; if ((s = socket(addr->ai_family, addr->ai_socktype, 0)) == -1) { #if defined(INET6) if (addr->ai_family == AF_INET6 && errno == EAFNOSUPPORT) { *noproto = 1; log_msg(LOG_WARNING, "fallback to TCP4, no IPv6: not supported"); return -1; } #endif /* INET6 */ log_msg(LOG_ERR, "can't create a socket: %s", strerror(errno)); return -1; } #ifdef SO_REUSEADDR if (setsockopt(s, SOL_SOCKET, SO_REUSEADDR, &on, sizeof(on)) < 0) { log_msg(LOG_ERR, "setsockopt(..., SO_REUSEADDR, ...) failed: %s", strerror(errno)); } #endif /* SO_REUSEADDR */ #if defined(INET6) && defined(IPV6_V6ONLY) if (addr->ai_family == AF_INET6 && setsockopt(s, IPPROTO_IPV6, IPV6_V6ONLY, &on, sizeof(on)) < 0) { log_msg(LOG_ERR, "setsockopt(..., IPV6_V6ONLY, ...) failed: %s", strerror(errno)); return -1; } #endif /* set it nonblocking */ /* (StevensUNP p463), if tcp listening socket is blocking, then it may block in accept, even if select() says readable. */ if (fcntl(s, F_SETFL, O_NONBLOCK) == -1) { log_msg(LOG_ERR, "cannot fcntl tcp: %s", strerror(errno)); } /* Bind it... */ if (bind(s, (struct sockaddr *)addr->ai_addr, addr->ai_addrlen) != 0) { log_msg(LOG_ERR, "can't bind tcp socket: %s", strerror(errno)); return -1; } /* Listen to it... */ if (listen(s, TCP_BACKLOG_REMOTE) == -1) { log_msg(LOG_ERR, "can't listen: %s", strerror(errno)); return -1; } return s; } /** * Add and open a new control port * @param rc: rc with result list. * @param ip: ip str * @param nr: port nr * @param noproto_is_err: if lack of protocol support is an error. * @return false on failure. */ static int add_open(struct daemon_remote* rc, struct nsd_options* cfg, const char* ip, int nr, int noproto_is_err) { struct addrinfo hints; struct addrinfo* res; struct acceptlist* hl; int noproto = 0; int fd, r; char port[15]; snprintf(port, sizeof(port), "%d", nr); port[sizeof(port)-1]=0; memset(&hints, 0, sizeof(hints)); assert(ip); if(ip[0] == '/') { /* This looks like a local socket */ fd = create_local_accept_sock(ip, &noproto); /* * Change socket ownership and permissions so users other * than root can access it provided they are in the same * group as the user we run as. */ if(fd != -1) { #ifdef HAVE_CHOWN if (cfg->username && cfg->username[0] && nsd.uid != (uid_t)-1) { if(chown(ip, nsd.uid, nsd.gid) == -1) VERBOSITY(2, (LOG_INFO, "cannot chown %u.%u %s: %s", (unsigned)nsd.uid, (unsigned)nsd.gid, ip, strerror(errno))); } chmod(ip, (mode_t)(S_IRUSR | S_IWUSR | S_IRGRP | S_IWGRP)); #else (void)cfg; #endif } } else { hints.ai_socktype = SOCK_STREAM; hints.ai_flags = AI_PASSIVE | AI_NUMERICHOST; if((r = getaddrinfo(ip, port, &hints, &res)) != 0 || !res) { log_msg(LOG_ERR, "control interface %s:%s getaddrinfo: %s %s", ip?ip:"default", port, gai_strerror(r), #ifdef EAI_SYSTEM r==EAI_SYSTEM?(char*)strerror(errno):"" #else "" #endif ); return 0; } /* open fd */ fd = create_tcp_accept_sock(res, &noproto); freeaddrinfo(res); } if(fd == -1 && noproto) { if(!noproto_is_err) return 1; /* return success, but do nothing */ log_msg(LOG_ERR, "cannot open control interface %s %d : " "protocol not supported", ip, nr); return 0; } if(fd == -1) { log_msg(LOG_ERR, "cannot open control interface %s %d", ip, nr); return 0; } /* alloc */ hl = (struct acceptlist*)xalloc_zero(sizeof(*hl)); hl->rc = rc; hl->ident = strdup(ip); if(!hl->ident) { log_msg(LOG_ERR, "malloc failure"); close(fd); free(hl); return 0; } hl->next = rc->accept_list; rc->accept_list = hl; hl->c.ev_fd = fd; hl->event_added = 0; return 1; } int daemon_remote_open_ports(struct daemon_remote* rc, struct nsd_options* cfg) { assert(cfg->control_enable && cfg->control_port); if(cfg->control_interface) { ip_address_option_type* p; for(p = cfg->control_interface; p; p = p->next) { if(!add_open(rc, cfg, p->address, cfg->control_port, 1)) { return 0; } } } else { /* defaults */ if(cfg->do_ip6 && !add_open(rc, cfg, "::1", cfg->control_port, 0)) { return 0; } if(cfg->do_ip4 && !add_open(rc, cfg, "127.0.0.1", cfg->control_port, 1)) { return 0; } } return 1; } void daemon_remote_attach(struct daemon_remote* rc, struct xfrd_state* xfrd) { int fd; struct acceptlist* p; if(!rc) return; rc->xfrd = xfrd; for(p = rc->accept_list; p; p = p->next) { /* add event */ fd = p->c.ev_fd; memset(&p->c, 0, sizeof(p->c)); event_set(&p->c, fd, EV_PERSIST|EV_READ, remote_accept_callback, p); if(event_base_set(xfrd->event_base, &p->c) != 0) log_msg(LOG_ERR, "remote: cannot set event_base"); if(event_add(&p->c, NULL) != 0) log_msg(LOG_ERR, "remote: cannot add event"); p->event_added = 1; } } static void remote_accept_callback(int fd, short event, void* arg) { struct acceptlist *hl = (struct acceptlist*)arg; struct daemon_remote *rc = hl->rc; #ifdef INET6 struct sockaddr_storage addr; #else struct sockaddr_in addr; #endif socklen_t addrlen; int newfd; struct rc_state* n; if (!(event & EV_READ)) { return; } /* perform the accept */ addrlen = sizeof(addr); #ifndef HAVE_ACCEPT4 newfd = accept(fd, (struct sockaddr*)&addr, &addrlen); #else newfd = accept4(fd, (struct sockaddr*)&addr, &addrlen, SOCK_NONBLOCK); #endif if(newfd == -1) { if ( errno != EINTR && errno != EWOULDBLOCK #ifdef ECONNABORTED && errno != ECONNABORTED #endif /* ECONNABORTED */ #ifdef EPROTO && errno != EPROTO #endif /* EPROTO */ ) { log_msg(LOG_ERR, "accept failed: %s", strerror(errno)); } return; } /* create new commpoint unless we are servicing already */ if(rc->active >= rc->max_active) { log_msg(LOG_WARNING, "drop incoming remote control: " "too many connections"); close_exit: close(newfd); return; } #ifndef HAVE_ACCEPT4 if (fcntl(newfd, F_SETFL, O_NONBLOCK) == -1) { log_msg(LOG_ERR, "fcntl failed: %s", strerror(errno)); goto close_exit; } #endif /* setup state to service the remote control command */ n = (struct rc_state*)calloc(1, sizeof(*n)); if(!n) { log_msg(LOG_ERR, "out of memory"); goto close_exit; } n->tval.tv_sec = REMOTE_CONTROL_TCP_TIMEOUT; n->tval.tv_usec = 0L; n->fd = newfd; memset(&n->c, 0, sizeof(n->c)); event_set(&n->c, newfd, EV_PERSIST|EV_TIMEOUT|EV_READ, remote_control_callback, n); if(event_base_set(xfrd->event_base, &n->c) != 0) { log_msg(LOG_ERR, "remote_accept: cannot set event_base"); free(n); goto close_exit; } if(event_add(&n->c, &n->tval) != 0) { log_msg(LOG_ERR, "remote_accept: cannot add event"); free(n); goto close_exit; } n->event_added = 1; if(2 <= verbosity) { if(hl->ident && hl->ident[0] == '/') { VERBOSITY(2, (LOG_INFO, "new control connection from %s", hl->ident)); } else { char s[128]; addr2str(&addr, s, sizeof(s)); VERBOSITY(2, (LOG_INFO, "new control connection from %s", s)); } } if(rc->ctx) { n->shake_state = rc_hs_read; n->ssl = SSL_new(rc->ctx); if(!n->ssl) { log_crypto_err("could not SSL_new"); event_del(&n->c); free(n); goto close_exit; } SSL_set_accept_state(n->ssl); (void)SSL_set_mode(n->ssl, SSL_MODE_AUTO_RETRY); if(!SSL_set_fd(n->ssl, newfd)) { log_crypto_err("could not SSL_set_fd"); event_del(&n->c); SSL_free(n->ssl); free(n); goto close_exit; } } else { n->ssl = NULL; } n->rc = rc; n->stats_next = NULL; n->in_stats_list = 0; n->prev = NULL; n->next = rc->busy_list; if(n->next) n->next->prev = n; rc->busy_list = n; rc->active ++; /* perform the first nonblocking read already, for windows, * so it can return wouldblock. could be faster too. */ remote_control_callback(newfd, EV_READ, n); } /** delete from list */ static void state_list_remove_elem(struct rc_state** list, struct rc_state* todel) { if(todel->prev) todel->prev->next = todel->next; else *list = todel->next; if(todel->next) todel->next->prev = todel->prev; } /** delete from stats list */ static void stats_list_remove_elem(struct rc_state** list, struct rc_state* todel) { struct rc_state* prev = NULL; struct rc_state* n = *list; while(n) { /* delete this one? */ if(n == todel) { if(prev) prev->next = n->next; else (*list) = n->next; /* go on and delete further elements */ /* prev = prev; */ n = n->next; continue; } /* go to the next element */ prev = n; n = n->next; } } /** decrease active count and remove commpoint from busy list */ static void clean_point(struct daemon_remote* rc, struct rc_state* s) { if(s->in_stats_list) stats_list_remove_elem(&rc->stats_list, s); state_list_remove_elem(&rc->busy_list, s); rc->active --; if(s->event_added) event_del(&s->c); if(s->ssl) { SSL_shutdown(s->ssl); SSL_free(s->ssl); } close(s->c.ev_fd); free(s); } static int ssl_print_text(RES* res, const char* text) { int r; if(!res) return 0; if(res->ssl) { ERR_clear_error(); if((r=SSL_write(res->ssl, text, (int)strlen(text))) <= 0) { if(SSL_get_error(res->ssl, r) == SSL_ERROR_ZERO_RETURN) { VERBOSITY(2, (LOG_WARNING, "in SSL_write, peer " "closed connection")); return 0; } log_crypto_err("could not SSL_write"); return 0; } } else { if(write_socket(res->fd, text, strlen(text)) <= 0) { log_msg(LOG_ERR, "could not write: %s", strerror(errno)); return 0; } } return 1; } /** print text over the ssl connection */ static int ssl_print_vmsg(RES* ssl, const char* format, va_list args) { char msg[1024]; vsnprintf(msg, sizeof(msg), format, args); return ssl_print_text(ssl, msg); } /** printf style printing to the ssl connection */ static int ssl_printf(RES* ssl, const char* format, ...) { va_list args; int ret; va_start(args, format); ret = ssl_print_vmsg(ssl, format, args); va_end(args); return ret; } static int ssl_read_line(RES* res, char* buf, size_t max) { int r; size_t len = 0; if(!res) return 0; while(len < max) { if(res->ssl) { ERR_clear_error(); if((r=SSL_read(res->ssl, buf+len, 1)) <= 0) { if(SSL_get_error(res->ssl, r) == SSL_ERROR_ZERO_RETURN) { buf[len] = 0; return 1; } log_crypto_err("could not SSL_read"); return 0; } } else { while(1) { ssize_t rr = read(res->fd, buf+len, 1); if(rr <= 0) { if(rr == 0) { buf[len] = 0; return 1; } if(errno == EINTR || errno == EAGAIN) continue; log_msg(LOG_ERR, "could not read: %s", strerror(errno)); return 0; } break; } } if(buf[len] == '\n') { /* return string without \n */ buf[len] = 0; return 1; } len++; } buf[max-1] = 0; log_msg(LOG_ERR, "control line too long (%d): %s", (int)max, buf); return 0; } /** skip whitespace, return new pointer into string */ static char* skipwhite(char* str) { /* EOS \0 is not a space */ while( isspace((unsigned char)*str) ) str++; return str; } /** send the OK to the control client */ static void send_ok(RES* ssl) { (void)ssl_printf(ssl, "ok\n"); } /** get zone argument (if any) or NULL, false on error */ static int get_zone_arg(RES* ssl, xfrd_state_type* xfrd, char* arg, struct zone_options** zo) { const dname_type* dname; if(!arg[0]) { /* no argument present, return NULL */ *zo = NULL; return 1; } dname = dname_parse(xfrd->region, arg); if(!dname) { ssl_printf(ssl, "error cannot parse zone name '%s'\n", arg); *zo = NULL; return 0; } *zo = zone_options_find(xfrd->nsd->options, dname); region_recycle(xfrd->region, (void*)dname, dname_total_size(dname)); if(!*zo) { ssl_printf(ssl, "error zone %s not configured\n", arg); return 0; } return 1; } /** do the stop command */ static void do_stop(RES* ssl, xfrd_state_type* xfrd) { xfrd->need_to_send_shutdown = 1; if(!(xfrd->ipc_handler_flags&EV_WRITE)) { ipc_xfrd_set_listening(xfrd, EV_PERSIST|EV_READ|EV_WRITE); } send_ok(ssl); } /** do the log_reopen command, it only needs reload_now */ static void do_log_reopen(RES* ssl, xfrd_state_type* xfrd) { xfrd_set_reload_now(xfrd); send_ok(ssl); } /** do the reload command */ static void do_reload(RES* ssl, xfrd_state_type* xfrd, char* arg) { struct zone_options* zo; if(!get_zone_arg(ssl, xfrd, arg, &zo)) return; task_new_check_zonefiles(xfrd->nsd->task[xfrd->nsd->mytask], xfrd->last_task, zo?(const dname_type*)zo->node.key:NULL); xfrd_set_reload_now(xfrd); send_ok(ssl); } /** do the write command */ static void do_write(RES* ssl, xfrd_state_type* xfrd, char* arg) { struct zone_options* zo; if(!get_zone_arg(ssl, xfrd, arg, &zo)) return; task_new_write_zonefiles(xfrd->nsd->task[xfrd->nsd->mytask], xfrd->last_task, zo?(const dname_type*)zo->node.key:NULL); xfrd_set_reload_now(xfrd); send_ok(ssl); } /** do the notify command */ static void do_notify(RES* ssl, xfrd_state_type* xfrd, char* arg) { struct zone_options* zo; if(!get_zone_arg(ssl, xfrd, arg, &zo)) return; if(zo) { struct notify_zone* n = (struct notify_zone*)rbtree_search( xfrd->notify_zones, (const dname_type*)zo->node.key); if(n) { xfrd_notify_start(n, xfrd); send_ok(ssl); } else { ssl_printf(ssl, "error zone does not have notify\n"); } } else { struct notify_zone* n; RBTREE_FOR(n, struct notify_zone*, xfrd->notify_zones) { xfrd_notify_start(n, xfrd); } send_ok(ssl); } } /** do the transfer command */ static void do_transfer(RES* ssl, xfrd_state_type* xfrd, char* arg) { struct zone_options* zo; xfrd_zone_type* zone; if(!get_zone_arg(ssl, xfrd, arg, &zo)) return; if(zo) { zone = (xfrd_zone_type*)rbtree_search(xfrd->zones, (const dname_type*)zo->node.key); if(zone) { xfrd_handle_notify_and_start_xfr(zone, NULL); send_ok(ssl); } else { ssl_printf(ssl, "error zone not slave\n"); } } else { RBTREE_FOR(zone, xfrd_zone_type*, xfrd->zones) { xfrd_handle_notify_and_start_xfr(zone, NULL); } ssl_printf(ssl, "ok, %lu zones\n", (unsigned long)xfrd->zones->count); } } /** force transfer a zone */ static void force_transfer_zone(xfrd_zone_type* zone) { /* if in TCP transaction, stop it immediately. */ if(zone->tcp_conn != -1) xfrd_tcp_release(xfrd->tcp_set, zone); else if(zone->zone_handler.ev_fd != -1) xfrd_udp_release(zone); /* pretend we not longer have it and force any * zone to be downloaded (even same serial, w AXFR) */ zone->soa_disk_acquired = 0; zone->soa_nsd_acquired = 0; xfrd_handle_notify_and_start_xfr(zone, NULL); } /** do the force transfer command */ static void do_force_transfer(RES* ssl, xfrd_state_type* xfrd, char* arg) { struct zone_options* zo; xfrd_zone_type* zone; if(!get_zone_arg(ssl, xfrd, arg, &zo)) return; if(zo) { zone = (xfrd_zone_type*)rbtree_search(xfrd->zones, (const dname_type*)zo->node.key); if(zone) { force_transfer_zone(zone); send_ok(ssl); } else { ssl_printf(ssl, "error zone not slave\n"); } } else { RBTREE_FOR(zone, xfrd_zone_type*, xfrd->zones) { force_transfer_zone(zone); } ssl_printf(ssl, "ok, %lu zones\n", (unsigned long)xfrd->zones->count); } } static int print_soa_status(RES* ssl, const char* str, xfrd_soa_type* soa, time_t acq) { if(acq) { if(!ssl_printf(ssl, " %s: \"%u since %s\"\n", str, (unsigned)ntohl(soa->serial), xfrd_pretty_time(acq))) return 0; } else { if(!ssl_printf(ssl, " %s: none\n", str)) return 0; } return 1; } /** print zonestatus for one domain */ static int print_zonestatus(RES* ssl, xfrd_state_type* xfrd, struct zone_options* zo) { xfrd_zone_type* xz = (xfrd_zone_type*)rbtree_search(xfrd->zones, (const dname_type*)zo->node.key); struct notify_zone* nz = (struct notify_zone*)rbtree_search( xfrd->notify_zones, (const dname_type*)zo->node.key); if(!ssl_printf(ssl, "zone: %s\n", zo->name)) return 0; if(!zo->part_of_config) { if(!ssl_printf(ssl, " pattern: %s\n", zo->pattern->pname)) return 0; } if(nz) { if(nz->is_waiting) { if(!ssl_printf(ssl, " notify: \"waiting-for-fd\"\n")) return 0; } else if(nz->notify_send_enable || nz->notify_send6_enable) { int i; if(!ssl_printf(ssl, " notify: \"send")) return 0; for(i=0; ipkts[i].dest) continue; if(!ssl_printf(ssl, " %s", nz->pkts[i].dest->ip_address_spec)) return 0; } if(!ssl_printf(ssl, " with serial %u\"\n", (unsigned)ntohl(nz->current_soa->serial))) return 0; } } if(!xz) { if(!ssl_printf(ssl, " state: master\n")) return 0; return 1; } if(!ssl_printf(ssl, " state: %s\n", (xz->state == xfrd_zone_ok)?"ok":( (xz->state == xfrd_zone_expired)?"expired":"refreshing"))) return 0; if(!print_soa_status(ssl, "served-serial", &xz->soa_nsd, xz->soa_nsd_acquired)) return 0; if(!print_soa_status(ssl, "commit-serial", &xz->soa_disk, xz->soa_disk_acquired)) return 0; if(xz->round_num != -1) { if(!print_soa_status(ssl, "notified-serial", &xz->soa_notified, xz->soa_notified_acquired)) return 0; } else if(xz->event_added) { if(!ssl_printf(ssl, "\twait: \"%lu sec between attempts\"\n", (unsigned long)xz->timeout.tv_sec)) return 0; } /* UDP */ if(xz->udp_waiting) { if(!ssl_printf(ssl, " transfer: \"waiting-for-UDP-fd\"\n")) return 0; } else if(xz->zone_handler.ev_fd != -1 && xz->tcp_conn == -1) { if(!ssl_printf(ssl, " transfer: \"sent UDP to %s\"\n", xz->master->ip_address_spec)) return 0; } /* TCP */ if(xz->tcp_waiting) { if(!ssl_printf(ssl, " transfer: \"waiting-for-TCP-fd\"\n")) return 0; } else if(xz->tcp_conn != -1) { if(!ssl_printf(ssl, " transfer: \"TCP connected to %s\"\n", xz->master->ip_address_spec)) return 0; } return 1; } /** do the zonestatus command */ static void do_zonestatus(RES* ssl, xfrd_state_type* xfrd, char* arg) { struct zone_options* zo; if(!get_zone_arg(ssl, xfrd, arg, &zo)) return; if(zo) (void)print_zonestatus(ssl, xfrd, zo); else { RBTREE_FOR(zo, struct zone_options*, xfrd->nsd->options->zone_options) { if(!print_zonestatus(ssl, xfrd, zo)) return; } } } /** do the verbosity command */ static void do_verbosity(RES* ssl, char* str) { int val = atoi(str); if(strcmp(str, "") == 0) { ssl_printf(ssl, "verbosity %d\n", verbosity); return; } if(val == 0 && strcmp(str, "0") != 0) { ssl_printf(ssl, "error in verbosity number syntax: %s\n", str); return; } verbosity = val; task_new_set_verbosity(xfrd->nsd->task[xfrd->nsd->mytask], xfrd->last_task, val); xfrd_set_reload_now(xfrd); send_ok(ssl); } /** find second argument, modifies string */ static int find_arg2(RES* ssl, char* arg, char** arg2) { char* as = strrchr(arg, ' '); if(as) { as[0]=0; *arg2 = as+1; while(isspace((unsigned char)*as) && as > arg) as--; as[0]=0; return 1; } *arg2 = NULL; ssl_printf(ssl, "error could not find next argument " "after %s\n", arg); return 0; } /** find second and third arguments, modifies string, * does not print error for missing arg3 so that if it does not find an * arg3, the caller can use two arguments. */ static int find_arg3(RES* ssl, char* arg, char** arg2, char** arg3) { if(find_arg2(ssl, arg, arg2)) { char* as; *arg3 = *arg2; as = strrchr(arg, ' '); if(as) { as[0]=0; *arg2 = as+1; while(isspace((unsigned char)*as) && as > arg) as--; as[0]=0; return 1; } } *arg3 = NULL; return 0; } /** do the status command */ static void do_status(RES* ssl, xfrd_state_type* xfrd) { if(!ssl_printf(ssl, "version: %s\n", PACKAGE_VERSION)) return; if(!ssl_printf(ssl, "verbosity: %d\n", verbosity)) return; #ifdef RATELIMIT if(!ssl_printf(ssl, "ratelimit: %d\n", (int)xfrd->nsd->options->rrl_ratelimit)) return; #else (void)xfrd; #endif } /** do the stats command */ static void do_stats(struct daemon_remote* rc, int peek, struct rc_state* rs) { #ifdef BIND8_STATS /* queue up to get stats after a reload is done (to gather statistics * from the servers) */ assert(!rs->in_stats_list); if(peek) rs->in_stats_list = 2; else rs->in_stats_list = 1; rs->stats_next = rc->stats_list; rc->stats_list = rs; /* block the tcp waiting for the reload */ event_del(&rs->c); rs->event_added = 0; /* force a reload */ xfrd_set_reload_now(xfrd); #else (void)rc; (void)peek; (void)ssl_printf(rs->ssl, "error no stats enabled at compile time\n"); #endif /* BIND8_STATS */ } /** see if we have more zonestatistics entries and it has to be incremented */ static void zonestat_inc_ifneeded(xfrd_state_type* xfrd) { #ifdef USE_ZONE_STATS if(xfrd->nsd->options->zonestatnames->count != xfrd->zonestat_safe) task_new_zonestat_inc(xfrd->nsd->task[xfrd->nsd->mytask], xfrd->last_task, xfrd->nsd->options->zonestatnames->count); #else (void)xfrd; #endif /* USE_ZONE_STATS */ } /** perform the changezone command for one zone */ static int perform_changezone(RES* ssl, xfrd_state_type* xfrd, char* arg) { const dname_type* dname; struct zone_options* zopt; char* arg2 = NULL; if(!find_arg2(ssl, arg, &arg2)) return 0; /* if we add it to the xfrd now, then xfrd could download AXFR and * store it and the NSD-reload would see it in the difffile before * it sees the add-config task. */ /* thus: AXFRs and IXFRs must store the pattern name in the * difffile, so that it can be added when the AXFR or IXFR is seen. */ /* check that the pattern exists */ if(!rbtree_search(xfrd->nsd->options->patterns, arg2)) { (void)ssl_printf(ssl, "error pattern %s does not exist\n", arg2); return 0; } dname = dname_parse(xfrd->region, arg); if(!dname) { (void)ssl_printf(ssl, "error cannot parse zone name\n"); return 0; } /* see if zone is a duplicate */ if( (zopt=zone_options_find(xfrd->nsd->options, dname)) ) { if(zopt->part_of_config) { (void)ssl_printf(ssl, "error zone defined in nsd.conf, " "cannot delete it in this manner: remove it from " "nsd.conf yourself and repattern\n"); region_recycle(xfrd->region, (void*)dname, dname_total_size(dname)); dname = NULL; return 0; } /* found the zone, now delete it */ /* create deletion task */ /* this deletion task is processed before the addition task, * that is created below, in the same reload process, causing * a seamless change from one to the other, with no downtime * for the zone. */ task_new_del_zone(xfrd->nsd->task[xfrd->nsd->mytask], xfrd->last_task, dname); xfrd_set_reload_now(xfrd); /* delete it in xfrd */ if(zone_is_slave(zopt)) { xfrd_del_slave_zone(xfrd, dname); } xfrd_del_notify(xfrd, dname); /* delete from config */ zone_list_del(xfrd->nsd->options, zopt); } else { (void)ssl_printf(ssl, "zone %s did not exist, creating", arg); } region_recycle(xfrd->region, (void*)dname, dname_total_size(dname)); dname = NULL; /* add to zonelist and adds to config in memory */ zopt = zone_list_add(xfrd->nsd->options, arg, arg2); if(!zopt) { /* also dname parse error here */ (void)ssl_printf(ssl, "error could not add zonelist entry\n"); return 0; } /* make addzone task and schedule reload */ task_new_add_zone(xfrd->nsd->task[xfrd->nsd->mytask], xfrd->last_task, arg, arg2, getzonestatid(xfrd->nsd->options, zopt)); zonestat_inc_ifneeded(xfrd); xfrd_set_reload_now(xfrd); /* add to xfrd - notify (for master and slaves) */ init_notify_send(xfrd->notify_zones, xfrd->region, zopt); /* add to xfrd - slave */ if(zone_is_slave(zopt)) { xfrd_init_slave_zone(xfrd, zopt); } return 1; } /** perform the addzone command for one zone */ static int perform_addzone(RES* ssl, xfrd_state_type* xfrd, char* arg) { const dname_type* dname; struct zone_options* zopt; char* arg2 = NULL; if(!find_arg2(ssl, arg, &arg2)) return 0; /* if we add it to the xfrd now, then xfrd could download AXFR and * store it and the NSD-reload would see it in the difffile before * it sees the add-config task. */ /* thus: AXFRs and IXFRs must store the pattern name in the * difffile, so that it can be added when the AXFR or IXFR is seen. */ /* check that the pattern exists */ if(!rbtree_search(xfrd->nsd->options->patterns, arg2)) { (void)ssl_printf(ssl, "error pattern %s does not exist\n", arg2); return 0; } dname = dname_parse(xfrd->region, arg); if(!dname) { (void)ssl_printf(ssl, "error cannot parse zone name\n"); return 0; } /* see if zone is a duplicate */ if( (zopt=zone_options_find(xfrd->nsd->options, dname)) ) { region_recycle(xfrd->region, (void*)dname, dname_total_size(dname)); (void)ssl_printf(ssl, "zone %s already exists\n", arg); return 1; } region_recycle(xfrd->region, (void*)dname, dname_total_size(dname)); dname = NULL; /* add to zonelist and adds to config in memory */ zopt = zone_list_add(xfrd->nsd->options, arg, arg2); if(!zopt) { /* also dname parse error here */ (void)ssl_printf(ssl, "error could not add zonelist entry\n"); return 0; } /* make addzone task and schedule reload */ task_new_add_zone(xfrd->nsd->task[xfrd->nsd->mytask], xfrd->last_task, arg, arg2, getzonestatid(xfrd->nsd->options, zopt)); zonestat_inc_ifneeded(xfrd); xfrd_set_reload_now(xfrd); /* add to xfrd - notify (for master and slaves) */ init_notify_send(xfrd->notify_zones, xfrd->region, zopt); /* add to xfrd - slave */ if(zone_is_slave(zopt)) { xfrd_init_slave_zone(xfrd, zopt); } return 1; } /** perform the delzone command for one zone */ static int perform_delzone(RES* ssl, xfrd_state_type* xfrd, char* arg) { const dname_type* dname; struct zone_options* zopt; dname = dname_parse(xfrd->region, arg); if(!dname) { (void)ssl_printf(ssl, "error cannot parse zone name\n"); return 0; } /* see if we have the zone in question */ zopt = zone_options_find(xfrd->nsd->options, dname); if(!zopt) { region_recycle(xfrd->region, (void*)dname, dname_total_size(dname)); /* nothing to do */ if(!ssl_printf(ssl, "warning zone %s not present\n", arg)) return 0; return 0; } /* see if it can be deleted */ if(zopt->part_of_config) { region_recycle(xfrd->region, (void*)dname, dname_total_size(dname)); (void)ssl_printf(ssl, "error zone defined in nsd.conf, " "cannot delete it in this manner: remove it from " "nsd.conf yourself and repattern\n"); return 0; } /* create deletion task */ task_new_del_zone(xfrd->nsd->task[xfrd->nsd->mytask], xfrd->last_task, dname); xfrd_set_reload_now(xfrd); /* delete it in xfrd */ if(zone_is_slave(zopt)) { xfrd_del_slave_zone(xfrd, dname); } xfrd_del_notify(xfrd, dname); /* delete from config */ zone_list_del(xfrd->nsd->options, zopt); region_recycle(xfrd->region, (void*)dname, dname_total_size(dname)); return 1; } /** do the addzone command */ static void do_addzone(RES* ssl, xfrd_state_type* xfrd, char* arg) { if(!perform_addzone(ssl, xfrd, arg)) return; send_ok(ssl); } /** do the delzone command */ static void do_delzone(RES* ssl, xfrd_state_type* xfrd, char* arg) { if(!perform_delzone(ssl, xfrd, arg)) return; send_ok(ssl); } /** do the changezone command */ static void do_changezone(RES* ssl, xfrd_state_type* xfrd, char* arg) { if(!perform_changezone(ssl, xfrd, arg)) return; send_ok(ssl); } /** do the addzones command */ static void do_addzones(RES* ssl, xfrd_state_type* xfrd) { char buf[2048]; int num = 0; while(ssl_read_line(ssl, buf, sizeof(buf))) { if(buf[0] == 0x04 && buf[1] == 0) break; /* end of transmission */ if(!perform_addzone(ssl, xfrd, buf)) { if(!ssl_printf(ssl, "error for input line '%s'\n", buf)) return; } else { if(!ssl_printf(ssl, "added: %s\n", buf)) return; num++; } } (void)ssl_printf(ssl, "added %d zones\n", num); } /** do the delzones command */ static void do_delzones(RES* ssl, xfrd_state_type* xfrd) { char buf[2048]; int num = 0; while(ssl_read_line(ssl, buf, sizeof(buf))) { if(buf[0] == 0x04 && buf[1] == 0) break; /* end of transmission */ if(!perform_delzone(ssl, xfrd, buf)) { if(!ssl_printf(ssl, "error for input line '%s'\n", buf)) return; } else { if(!ssl_printf(ssl, "removed: %s\n", buf)) return; num++; } } (void)ssl_printf(ssl, "deleted %d zones\n", num); } /** remove TSIG key from config and add task so that reload does too */ static void remove_key(xfrd_state_type* xfrd, const char* kname) { /* add task before deletion because the name string could be deleted */ task_new_del_key(xfrd->nsd->task[xfrd->nsd->mytask], xfrd->last_task, kname); key_options_remove(xfrd->nsd->options, kname); xfrd_set_reload_now(xfrd); /* this is executed when the current control command ends, thus the entire config changes are bunched up */ } /** add TSIG key to config and add task so that reload does too */ static void add_key(xfrd_state_type* xfrd, struct key_options* k) { key_options_add_modify(xfrd->nsd->options, k); task_new_add_key(xfrd->nsd->task[xfrd->nsd->mytask], xfrd->last_task, k); xfrd_set_reload_now(xfrd); } /** check if keys have changed */ static void repat_keys(xfrd_state_type* xfrd, struct nsd_options* newopt) { struct nsd_options* oldopt = xfrd->nsd->options; struct key_options* k; /* find deleted keys */ k = (struct key_options*)rbtree_first(oldopt->keys); while((rbnode_type*)k != RBTREE_NULL) { struct key_options* next = (struct key_options*)rbtree_next( (rbnode_type*)k); if(!key_options_find(newopt, k->name)) remove_key(xfrd, k->name); k = next; } /* find added or changed keys */ RBTREE_FOR(k, struct key_options*, newopt->keys) { struct key_options* origk = key_options_find(oldopt, k->name); if(!origk) add_key(xfrd, k); else if(!key_options_equal(k, origk)) add_key(xfrd, k); } } /** find zone given the implicit pattern */ static const dname_type* parse_implicit_name(xfrd_state_type* xfrd,const char* pname) { if(strncmp(pname, PATTERN_IMPLICIT_MARKER, strlen(PATTERN_IMPLICIT_MARKER)) != 0) return NULL; return dname_parse(xfrd->region, pname + strlen(PATTERN_IMPLICIT_MARKER)); } /** remove cfgzone and add task so that reload does too */ static void remove_cfgzone(xfrd_state_type* xfrd, const char* pname) { /* dname and find the zone for the implicit pattern */ struct zone_options* zopt = NULL; const dname_type* dname = parse_implicit_name(xfrd, pname); if(!dname) { /* should have a parseable name, but it did not */ return; } /* find the zone entry for the implicit pattern */ zopt = zone_options_find(xfrd->nsd->options, dname); if(!zopt) { /* this should not happen; implicit pattern has zone entry */ region_recycle(xfrd->region, (void*)dname, dname_total_size(dname)); return; } /* create deletion task */ task_new_del_zone(xfrd->nsd->task[xfrd->nsd->mytask], xfrd->last_task, dname); xfrd_set_reload_now(xfrd); /* delete it in xfrd */ if(zone_is_slave(zopt)) { xfrd_del_slave_zone(xfrd, dname); } xfrd_del_notify(xfrd, dname); /* delete from zoneoptions */ zone_options_delete(xfrd->nsd->options, zopt); /* recycle parsed dname */ region_recycle(xfrd->region, (void*)dname, dname_total_size(dname)); } /** add cfgzone and add task so that reload does too */ static void add_cfgzone(xfrd_state_type* xfrd, const char* pname) { /* add to our zonelist */ struct zone_options* zopt = zone_options_create( xfrd->nsd->options->region); if(!zopt) return; zopt->part_of_config = 1; zopt->name = region_strdup(xfrd->nsd->options->region, pname + strlen(PATTERN_IMPLICIT_MARKER)); zopt->pattern = pattern_options_find(xfrd->nsd->options, pname); if(!zopt->name || !zopt->pattern) return; if(!nsd_options_insert_zone(xfrd->nsd->options, zopt)) { log_msg(LOG_ERR, "bad domain name or duplicate zone '%s' " "pattern %s", zopt->name, pname); } /* make addzone task and schedule reload */ task_new_add_zone(xfrd->nsd->task[xfrd->nsd->mytask], xfrd->last_task, zopt->name, pname, getzonestatid(xfrd->nsd->options, zopt)); /* zonestat_inc is done after the entire config file has been done */ xfrd_set_reload_now(xfrd); /* add to xfrd - notify (for master and slaves) */ init_notify_send(xfrd->notify_zones, xfrd->region, zopt); /* add to xfrd - slave */ if(zone_is_slave(zopt)) { xfrd_init_slave_zone(xfrd, zopt); } } /** remove pattern and add task so that reload does too */ static void remove_pat(xfrd_state_type* xfrd, const char* name) { /* add task before deletion, because name-string could be deleted */ task_new_del_pattern(xfrd->nsd->task[xfrd->nsd->mytask], xfrd->last_task, name); pattern_options_remove(xfrd->nsd->options, name); xfrd_set_reload_now(xfrd); } /** add pattern and add task so that reload does too */ static void add_pat(xfrd_state_type* xfrd, struct pattern_options* p) { pattern_options_add_modify(xfrd->nsd->options, p); task_new_add_pattern(xfrd->nsd->task[xfrd->nsd->mytask], xfrd->last_task, p); xfrd_set_reload_now(xfrd); } /** interrupt zones that are using changed or removed patterns */ static void repat_interrupt_zones(xfrd_state_type* xfrd, struct nsd_options* newopt) { /* if masterlist changed: * interrupt slave zone (UDP or TCP) transfers. * slave zones reset master to start of list. */ xfrd_zone_type* xz; struct notify_zone* nz; RBTREE_FOR(xz, xfrd_zone_type*, xfrd->zones) { struct pattern_options* oldp = xz->zone_options->pattern; struct pattern_options* newp = pattern_options_find(newopt, oldp->pname); if(!newp || !acl_list_equal(oldp->request_xfr, newp->request_xfr)) { /* interrupt transfer */ if(xz->tcp_conn != -1) { xfrd_tcp_release(xfrd->tcp_set, xz); xfrd_set_refresh_now(xz); } else if(xz->zone_handler.ev_fd != -1) { xfrd_udp_release(xz); xfrd_set_refresh_now(xz); } xz->master = 0; xz->master_num = 0; xz->next_master = -1; xz->round_num = -1; /* fresh set of retries */ } } /* if notify list changed: * interrupt notify that is busy. * reset notify to start of list. (clear all other reset_notify) */ RBTREE_FOR(nz, struct notify_zone*, xfrd->notify_zones) { struct pattern_options* oldp = nz->options->pattern; struct pattern_options* newp = pattern_options_find(newopt, oldp->pname); if(!newp || !acl_list_equal(oldp->notify, newp->notify)) { /* interrupt notify */ if(nz->notify_send_enable) { notify_disable(nz); /* set to restart the notify after the * pattern has been changed. */ nz->notify_restart = 2; } else { nz->notify_restart = 1; } } else { nz->notify_restart = 0; } } } /** for notify, after the pattern changes, restart the affected notifies */ static void repat_interrupt_notify_start(xfrd_state_type* xfrd) { struct notify_zone* nz; RBTREE_FOR(nz, struct notify_zone*, xfrd->notify_zones) { if(nz->notify_restart) { if(nz->notify_current) nz->notify_current = nz->options->pattern->notify; if(nz->notify_restart == 2) { if(nz->notify_restart) xfrd_notify_start(nz, xfrd); } } } } /** check if patterns have changed */ static void repat_patterns(xfrd_state_type* xfrd, struct nsd_options* newopt) { /* zones that use changed patterns must have: * - their AXFR/IXFR interrupted: try again, acl may have changed. * if the old master/key still exists, OK, fix master-numptrs and * keep going. Otherwise, stop xfer and reset TSIG. * - send NOTIFY reset to start of NOTIFY list (and TSIG reset). */ struct nsd_options* oldopt = xfrd->nsd->options; struct pattern_options* p; int search_zones = 0; repat_interrupt_zones(xfrd, newopt); /* find deleted patterns */ p = (struct pattern_options*)rbtree_first(oldopt->patterns); while((rbnode_type*)p != RBTREE_NULL) { struct pattern_options* next = (struct pattern_options*) rbtree_next((rbnode_type*)p); if(!pattern_options_find(newopt, p->pname)) { if(p->implicit) { /* first remove its zone */ VERBOSITY(1, (LOG_INFO, "zone removed from config: %s", p->pname + strlen(PATTERN_IMPLICIT_MARKER))); remove_cfgzone(xfrd, p->pname); } remove_pat(xfrd, p->pname); } p = next; } /* find added or changed patterns */ RBTREE_FOR(p, struct pattern_options*, newopt->patterns) { struct pattern_options* origp = pattern_options_find(oldopt, p->pname); if(!origp) { /* no zones can use it, no zone_interrupt needed */ add_pat(xfrd, p); if(p->implicit) { VERBOSITY(1, (LOG_INFO, "zone added to config: %s", p->pname + strlen(PATTERN_IMPLICIT_MARKER))); add_cfgzone(xfrd, p->pname); } } else if(!pattern_options_equal(p, origp)) { uint8_t newstate = 0; if (p->request_xfr && !origp->request_xfr) { newstate = REPAT_SLAVE; } else if (!p->request_xfr && origp->request_xfr) { newstate = REPAT_MASTER; } add_pat(xfrd, p); if (p->implicit && newstate) { const dname_type* dname = parse_implicit_name(xfrd, p->pname); if (dname) { if (newstate == REPAT_SLAVE) { struct zone_options* zopt = zone_options_find( oldopt, dname); if (zopt) { xfrd_init_slave_zone( xfrd, zopt); } } else if (newstate == REPAT_MASTER) { xfrd_del_slave_zone(xfrd, dname); } region_recycle(xfrd->region, (void*)dname, dname_total_size(dname)); } } else if(!p->implicit && newstate) { /* search all zones with this pattern */ search_zones = 1; origp->xfrd_flags = newstate; } } } if (search_zones) { struct zone_options* zone_opt; /* search in oldopt because 1) it contains zonelist zones, * and 2) you need oldopt(existing) to call xfrd_init */ RBTREE_FOR(zone_opt, struct zone_options*, oldopt->zone_options) { struct pattern_options* oldp = zone_opt->pattern; if (!oldp->implicit) { if (oldp->xfrd_flags == REPAT_SLAVE) { /* xfrd needs stable reference so get * it from the oldopt(modified) tree */ xfrd_init_slave_zone(xfrd, zone_opt); } else if (oldp->xfrd_flags == REPAT_MASTER) { xfrd_del_slave_zone(xfrd, (const dname_type*) zone_opt->node.key); } oldp->xfrd_flags = 0; } } } repat_interrupt_notify_start(xfrd); } /** true if options are different that can be set via repat. */ static int repat_options_changed(xfrd_state_type* xfrd, struct nsd_options* newopt) { #ifdef RATELIMIT if(xfrd->nsd->options->rrl_ratelimit != newopt->rrl_ratelimit) return 1; if(xfrd->nsd->options->rrl_whitelist_ratelimit != newopt->rrl_whitelist_ratelimit) return 1; if(xfrd->nsd->options->rrl_slip != newopt->rrl_slip) return 1; #else (void)xfrd; (void)newopt; #endif return 0; } /** check if global options have changed */ static void repat_options(xfrd_state_type* xfrd, struct nsd_options* newopt) { if(repat_options_changed(xfrd, newopt)) { /* update our options */ #ifdef RATELIMIT xfrd->nsd->options->rrl_ratelimit = newopt->rrl_ratelimit; xfrd->nsd->options->rrl_whitelist_ratelimit = newopt->rrl_whitelist_ratelimit; xfrd->nsd->options->rrl_slip = newopt->rrl_slip; #endif task_new_opt_change(xfrd->nsd->task[xfrd->nsd->mytask], xfrd->last_task, newopt); xfrd_set_reload_now(xfrd); } } /** print errors over ssl, gets pointer-to-pointer to ssl, so it can set * the pointer to NULL on failure and stop printing */ static void print_ssl_cfg_err(void* arg, const char* str) { RES** ssl = (RES**)arg; if(!*ssl) return; if(!ssl_printf(*ssl, "%s", str)) *ssl = NULL; /* failed, stop printing */ } /** do the repattern command: reread config file and apply keys, patterns */ static void do_repattern(RES* ssl, xfrd_state_type* xfrd) { region_type* region = region_create(xalloc, free); struct nsd_options* opt; const char* cfgfile = xfrd->nsd->options->configfile; /* check chroot and configfile, if possible to reread */ if(xfrd->nsd->chrootdir) { size_t l = strlen(xfrd->nsd->chrootdir); while(l>0 && xfrd->nsd->chrootdir[l-1] == '/') --l; if(strncmp(xfrd->nsd->chrootdir, cfgfile, l) != 0) { ssl_printf(ssl, "error %s is not relative to %s: " "chroot prevents reread of config\n", cfgfile, xfrd->nsd->chrootdir); region_destroy(region); return; } cfgfile += l; } ssl_printf(ssl, "reconfig start, read %s\n", cfgfile); opt = nsd_options_create(region); if(!parse_options_file(opt, cfgfile, &print_ssl_cfg_err, &ssl)) { /* error already printed */ region_destroy(region); return; } /* check for differences in TSIG keys and patterns, and apply, * first the keys, so that pattern->keyptr can be set right. */ repat_keys(xfrd, opt); repat_patterns(xfrd, opt); repat_options(xfrd, opt); zonestat_inc_ifneeded(xfrd); send_ok(ssl); region_destroy(region); } /** do the serverpid command: printout pid of server process */ static void do_serverpid(RES* ssl, xfrd_state_type* xfrd) { (void)ssl_printf(ssl, "%u\n", (unsigned)xfrd->reload_pid); } /** do the print_tsig command: printout tsig info */ static void do_print_tsig(RES* ssl, xfrd_state_type* xfrd, char* arg) { if(*arg == '\0') { struct key_options* key; RBTREE_FOR(key, struct key_options*, xfrd->nsd->options->keys) { if(!ssl_printf(ssl, "key: name: \"%s\" secret: \"%s\" algorithm: %s\n", key->name, key->secret, key->algorithm)) return; } return; } else { struct key_options* key_opts = key_options_find(xfrd->nsd->options, arg); if(!key_opts) { if(!ssl_printf(ssl, "error: no such key with name: %s\n", arg)) return; return; } else { if(!ssl_printf(ssl, "key: name: \"%s\" secret: \"%s\" algorithm: %s\n", arg, key_opts->secret, key_opts->algorithm)) return; } } } /** do the update_tsig command: change existing tsig to new secret */ static void do_update_tsig(RES* ssl, xfrd_state_type* xfrd, char* arg) { struct region* region = xfrd->nsd->options->region; char* arg2 = NULL; uint8_t data[65536]; /* 64K */ struct key_options* key_opt; if(*arg == '\0') { if(!ssl_printf(ssl, "error: missing argument (keyname)\n")) return; return; } if(!find_arg2(ssl, arg, &arg2)) { if(!ssl_printf(ssl, "error: missing argument (secret)\n")) return; return; } key_opt = key_options_find(xfrd->nsd->options, arg); if(!key_opt) { if(!ssl_printf(ssl, "error: no such key with name: %s\n", arg)) return; memset(arg2, 0xdd, strlen(arg2)); return; } if(__b64_pton(arg2, data, sizeof(data)) == -1) { if(!ssl_printf(ssl, "error: the secret: %s is not in b64 format\n", arg2)) return; memset(data, 0xdd, sizeof(data)); /* wipe secret */ memset(arg2, 0xdd, strlen(arg2)); return; } log_msg(LOG_INFO, "changing secret provided with the key: %s with old secret %s and algo: %s\n", arg, key_opt->secret, key_opt->algorithm); if(key_opt->secret) { /* wipe old secret */ memset(key_opt->secret, 0xdd, strlen(key_opt->secret)); region_recycle(region, key_opt->secret, strlen(key_opt->secret)+1); } key_opt->secret = region_strdup(region, arg2); log_msg(LOG_INFO, "the key: %s has new secret %s and algorithm: %s\n", arg, key_opt->secret, key_opt->algorithm); /* wipe secret from temp parse buffer */ memset(arg2, 0xdd, strlen(arg2)); memset(data, 0xdd, sizeof(data)); key_options_desetup(region, key_opt); key_options_setup(region, key_opt); task_new_add_key(xfrd->nsd->task[xfrd->nsd->mytask], xfrd->last_task, key_opt); xfrd_set_reload_now(xfrd); send_ok(ssl); } /** do the add tsig command, add new key with name, secret and algo given */ static void do_add_tsig(RES* ssl, xfrd_state_type* xfrd, char* arg) { char* arg2 = NULL; char* arg3 = NULL; uint8_t data[65536]; /* 64KB */ uint8_t dname[MAXDOMAINLEN+1]; char algo[256]; region_type* region = xfrd->nsd->options->region; struct key_options* new_key_opt; if(*arg == '\0') { if(!ssl_printf(ssl, "error: missing argument (keyname)\n")) return; return; } if(!find_arg3(ssl, arg, &arg2, &arg3)) { strlcpy(algo, "hmac-sha256", sizeof(algo)); } else { strlcpy(algo, arg3, sizeof(algo)); } if(!arg2) { if(!ssl_printf(ssl, "error: missing argument (secret)\n")) return; return; } if(key_options_find(xfrd->nsd->options, arg)) { if(!ssl_printf(ssl, "error: key %s already exists\n", arg)) return; memset(arg2, 0xdd, strlen(arg2)); return; } if(__b64_pton(arg2, data, sizeof(data)) == -1) { if(!ssl_printf(ssl, "error: the secret: %s is not in b64 format\n", arg2)) return; memset(data, 0xdd, sizeof(data)); /* wipe secret */ memset(arg2, 0xdd, strlen(arg2)); return; } memset(data, 0xdd, sizeof(data)); /* wipe secret from temp buffer */ if(!dname_parse_wire(dname, arg)) { if(!ssl_printf(ssl, "error: could not parse key name: %s\n", arg)) return; memset(arg2, 0xdd, strlen(arg2)); return; } if(tsig_get_algorithm_by_name(algo) == NULL) { if(!ssl_printf(ssl, "error: unknown algorithm: %s\n", algo)) return; memset(arg2, 0xdd, strlen(arg2)); return; } log_msg(LOG_INFO, "adding key with name: %s and secret: %s with algo: %s\n", arg, arg2, algo); new_key_opt = key_options_create(region); new_key_opt->name = region_strdup(region, arg); new_key_opt->secret = region_strdup(region, arg2); new_key_opt->algorithm = region_strdup(region, algo); add_key(xfrd, new_key_opt); /* wipe secret from temp buffer */ memset(arg2, 0xdd, strlen(arg2)); send_ok(ssl); } /** set acl entries to use the given TSIG key */ static void zopt_set_acl_to_tsig(struct acl_options* acl, struct region* region, const char* key_name, struct key_options* key_opt) { while(acl) { if(acl->blocked) { acl = acl->next; continue; } acl->nokey = 0; if(acl->key_name) region_recycle(region, (void*)acl->key_name, strlen(acl->key_name)+1); acl->key_name = region_strdup(region, key_name); acl->key_options = key_opt; acl = acl->next; } } /** do the assoc_tsig command: associate the zone to use the tsig name */ static void do_assoc_tsig(RES* ssl, xfrd_state_type* xfrd, char* arg) { region_type* region = xfrd->nsd->options->region; char* arg2 = NULL; struct zone_options* zone; struct key_options* key_opt; if(*arg == '\0') { if(!ssl_printf(ssl, "error: missing argument (zonename)\n")) return; return; } if(!find_arg2(ssl, arg, &arg2)) { if(!ssl_printf(ssl, "error: missing argument (keyname)\n")) return; return; } if(!get_zone_arg(ssl, xfrd, arg, &zone)) return; if(!zone) { if(!ssl_printf(ssl, "error: missing argument (zone)\n")) return; return; } key_opt = key_options_find(xfrd->nsd->options, arg2); if(!key_opt) { if(!ssl_printf(ssl, "error: key: %s does not exist\n", arg2)) return; return; } zopt_set_acl_to_tsig(zone->pattern->allow_notify, region, arg2, key_opt); zopt_set_acl_to_tsig(zone->pattern->notify, region, arg2, key_opt); zopt_set_acl_to_tsig(zone->pattern->request_xfr, region, arg2, key_opt); zopt_set_acl_to_tsig(zone->pattern->provide_xfr, region, arg2, key_opt); task_new_add_pattern(xfrd->nsd->task[xfrd->nsd->mytask], xfrd->last_task, zone->pattern); xfrd_set_reload_now(xfrd); send_ok(ssl); } /** see if TSIG key is used in the acl */ static int acl_contains_tsig_key(struct acl_options* acl, const char* name) { while(acl) { if(acl->key_name && strcmp(acl->key_name, name) == 0) return 1; acl = acl->next; } return 0; } /** do the del_tsig command, remove an (unused) tsig */ static void do_del_tsig(RES* ssl, xfrd_state_type* xfrd, char* arg) { int used_key = 0; struct zone_options* zone; struct key_options* key_opt; if(*arg == '\0') { if(!ssl_printf(ssl, "error: missing argument (keyname)\n")) return; return; } key_opt = key_options_find(xfrd->nsd->options, arg); if(!key_opt) { if(!ssl_printf(ssl, "key %s does not exist, nothing to be deleted\n", arg)) return; return; } RBTREE_FOR(zone, struct zone_options*, xfrd->nsd->options->zone_options) { if(acl_contains_tsig_key(zone->pattern->allow_notify, arg) || acl_contains_tsig_key(zone->pattern->notify, arg) || acl_contains_tsig_key(zone->pattern->request_xfr, arg) || acl_contains_tsig_key(zone->pattern->provide_xfr, arg)) { if(!ssl_printf(ssl, "zone %s uses key %s\n", zone->name, arg)) return; used_key = 1; break; } } if(used_key) { if(!ssl_printf(ssl, "error: key: %s is in use and cannot be deleted\n", arg)) return; return; } else { remove_key(xfrd, arg); log_msg(LOG_INFO, "key: %s is successfully deleted\n", arg); } send_ok(ssl); } /** check for name with end-of-string, space or tab after it */ static int cmdcmp(char* p, const char* cmd, size_t len) { return strncmp(p,cmd,len)==0 && (p[len]==0||p[len]==' '||p[len]=='\t'); } /** execute a remote control command */ static void execute_cmd(struct daemon_remote* rc, RES* ssl, char* cmd, struct rc_state* rs) { char* p = skipwhite(cmd); /* compare command */ if(cmdcmp(p, "stop", 4)) { do_stop(ssl, rc->xfrd); } else if(cmdcmp(p, "reload", 6)) { do_reload(ssl, rc->xfrd, skipwhite(p+6)); } else if(cmdcmp(p, "write", 5)) { do_write(ssl, rc->xfrd, skipwhite(p+5)); } else if(cmdcmp(p, "status", 6)) { do_status(ssl, rc->xfrd); } else if(cmdcmp(p, "stats_noreset", 13)) { do_stats(rc, 1, rs); } else if(cmdcmp(p, "stats", 5)) { do_stats(rc, 0, rs); } else if(cmdcmp(p, "log_reopen", 10)) { do_log_reopen(ssl, rc->xfrd); } else if(cmdcmp(p, "addzone", 7)) { do_addzone(ssl, rc->xfrd, skipwhite(p+7)); } else if(cmdcmp(p, "delzone", 7)) { do_delzone(ssl, rc->xfrd, skipwhite(p+7)); } else if(cmdcmp(p, "changezone", 10)) { do_changezone(ssl, rc->xfrd, skipwhite(p+10)); } else if(cmdcmp(p, "addzones", 8)) { do_addzones(ssl, rc->xfrd); } else if(cmdcmp(p, "delzones", 8)) { do_delzones(ssl, rc->xfrd); } else if(cmdcmp(p, "notify", 6)) { do_notify(ssl, rc->xfrd, skipwhite(p+6)); } else if(cmdcmp(p, "transfer", 8)) { do_transfer(ssl, rc->xfrd, skipwhite(p+8)); } else if(cmdcmp(p, "force_transfer", 14)) { do_force_transfer(ssl, rc->xfrd, skipwhite(p+14)); } else if(cmdcmp(p, "zonestatus", 10)) { do_zonestatus(ssl, rc->xfrd, skipwhite(p+10)); } else if(cmdcmp(p, "verbosity", 9)) { do_verbosity(ssl, skipwhite(p+9)); } else if(cmdcmp(p, "repattern", 9)) { do_repattern(ssl, rc->xfrd); } else if(cmdcmp(p, "reconfig", 8)) { do_repattern(ssl, rc->xfrd); } else if(cmdcmp(p, "serverpid", 9)) { do_serverpid(ssl, rc->xfrd); } else if(cmdcmp(p, "print_tsig", 10)) { do_print_tsig(ssl, rc->xfrd, skipwhite(p+10)); } else if(cmdcmp(p, "update_tsig", 11)) { do_update_tsig(ssl, rc->xfrd, skipwhite(p+11)); } else if(cmdcmp(p, "add_tsig", 8)) { do_add_tsig(ssl, rc->xfrd, skipwhite(p+8)); } else if(cmdcmp(p, "assoc_tsig", 10)) { do_assoc_tsig(ssl, rc->xfrd, skipwhite(p+10)); } else if(cmdcmp(p, "del_tsig", 8)) { do_del_tsig(ssl, rc->xfrd, skipwhite(p+8)); } else { (void)ssl_printf(ssl, "error unknown command '%s'\n", p); } } /** handle remote control request */ static void handle_req(struct daemon_remote* rc, struct rc_state* s, RES* res) { int r; char pre[10]; char magic[8]; char buf[1024]; if (fcntl(s->c.ev_fd, F_SETFL, 0) == -1) { /* set blocking */ log_msg(LOG_ERR, "cannot fcntl rc: %s", strerror(errno)); } /* try to read magic UBCT[version]_space_ string */ if(res->ssl) { ERR_clear_error(); if((r=SSL_read(res->ssl, magic, (int)sizeof(magic)-1)) <= 0) { if(SSL_get_error(res->ssl, r) == SSL_ERROR_ZERO_RETURN) return; log_crypto_err("could not SSL_read"); return; } } else { while(1) { ssize_t rr = read(res->fd, magic, sizeof(magic)-1); if(rr <= 0) { if(rr == 0) return; if(errno == EINTR || errno == EAGAIN) continue; log_msg(LOG_ERR, "could not read: %s", strerror(errno)); return; } r = (int)rr; break; } } magic[7] = 0; if( r != 7 || strncmp(magic, "NSDCT", 5) != 0) { VERBOSITY(2, (LOG_INFO, "control connection has bad header")); /* probably wrong tool connected, ignore it completely */ return; } /* read the command line */ if(!ssl_read_line(res, buf, sizeof(buf))) { return; } snprintf(pre, sizeof(pre), "NSDCT%d ", NSD_CONTROL_VERSION); if(strcmp(magic, pre) != 0) { VERBOSITY(2, (LOG_INFO, "control connection had bad " "version %s, cmd: %s", magic, buf)); ssl_printf(res, "error version mismatch\n"); return; } VERBOSITY(2, (LOG_INFO, "control cmd: %s", buf)); /* figure out what to do */ execute_cmd(rc, res, buf, s); } /** handle SSL_do_handshake changes to the file descriptor to wait for later */ static void remote_handshake_later(struct daemon_remote* rc, struct rc_state* s, int fd, int r, int r2) { if(r2 == SSL_ERROR_WANT_READ) { if(s->shake_state == rc_hs_read) { /* try again later */ return; } s->shake_state = rc_hs_read; event_del(&s->c); memset(&s->c, 0, sizeof(s->c)); event_set(&s->c, fd, EV_PERSIST|EV_TIMEOUT|EV_READ, remote_control_callback, s); if(event_base_set(xfrd->event_base, &s->c) != 0) log_msg(LOG_ERR, "remote_accept: cannot set event_base"); if(event_add(&s->c, &s->tval) != 0) log_msg(LOG_ERR, "remote_accept: cannot add event"); return; } else if(r2 == SSL_ERROR_WANT_WRITE) { if(s->shake_state == rc_hs_write) { /* try again later */ return; } s->shake_state = rc_hs_write; event_del(&s->c); memset(&s->c, 0, sizeof(s->c)); event_set(&s->c, fd, EV_PERSIST|EV_TIMEOUT|EV_WRITE, remote_control_callback, s); if(event_base_set(xfrd->event_base, &s->c) != 0) log_msg(LOG_ERR, "remote_accept: cannot set event_base"); if(event_add(&s->c, &s->tval) != 0) log_msg(LOG_ERR, "remote_accept: cannot add event"); return; } else { if(r == 0) log_msg(LOG_ERR, "remote control connection closed prematurely"); log_crypto_err("remote control failed ssl"); clean_point(rc, s); } } static void remote_control_callback(int fd, short event, void* arg) { RES res; struct rc_state* s = (struct rc_state*)arg; struct daemon_remote* rc = s->rc; int r; if( (event&EV_TIMEOUT) ) { log_msg(LOG_ERR, "remote control timed out"); clean_point(rc, s); return; } if(s->ssl) { /* (continue to) setup the SSL connection */ ERR_clear_error(); r = SSL_do_handshake(s->ssl); if(r != 1) { int r2 = SSL_get_error(s->ssl, r); remote_handshake_later(rc, s, fd, r, r2); return; } s->shake_state = rc_none; } /* once handshake has completed, check authentication */ if (!rc->use_cert) { VERBOSITY(3, (LOG_INFO, "unauthenticated remote control connection")); } else if(SSL_get_verify_result(s->ssl) == X509_V_OK) { X509* x = SSL_get_peer_certificate(s->ssl); if(!x) { VERBOSITY(2, (LOG_INFO, "remote control connection " "provided no client certificate")); clean_point(rc, s); return; } VERBOSITY(3, (LOG_INFO, "remote control connection authenticated")); X509_free(x); } else { VERBOSITY(2, (LOG_INFO, "remote control connection failed to " "authenticate with client certificate")); clean_point(rc, s); return; } /* if OK start to actually handle the request */ res.ssl = s->ssl; res.fd = fd; handle_req(rc, s, &res); if(!s->in_stats_list) { VERBOSITY(3, (LOG_INFO, "remote control operation completed")); clean_point(rc, s); } } #ifdef BIND8_STATS static const char* opcode2str(int o) { switch(o) { case OPCODE_QUERY: return "QUERY"; case OPCODE_IQUERY: return "IQUERY"; case OPCODE_STATUS: return "STATUS"; case OPCODE_NOTIFY: return "NOTIFY"; case OPCODE_UPDATE: return "UPDATE"; default: return "OTHER"; } } /** print long number */ static int print_longnum(RES* ssl, char* desc, uint64_t x) { if(x > (uint64_t)1024*1024*1024) { /* more than a Gb */ size_t front = (size_t)(x / (uint64_t)1000000); size_t back = (size_t)(x % (uint64_t)1000000); return ssl_printf(ssl, "%s%lu%6.6lu\n", desc, (unsigned long)front, (unsigned long)back); } else { return ssl_printf(ssl, "%s%lu\n", desc, (unsigned long)x); } } /* print one block of statistics. n is name and d is delimiter */ static void print_stat_block(RES* ssl, char* n, char* d, struct nsdst* st) { const char* rcstr[] = {"NOERROR", "FORMERR", "SERVFAIL", "NXDOMAIN", "NOTIMP", "REFUSED", "YXDOMAIN", "YXRRSET", "NXRRSET", "NOTAUTH", "NOTZONE", "RCODE11", "RCODE12", "RCODE13", "RCODE14", "RCODE15", "BADVERS" }; size_t i; for(i=0; i<= 255; i++) { if(inhibit_zero && st->qtype[i] == 0 && strncmp(rrtype_to_string(i), "TYPE", 4) == 0) continue; if(!ssl_printf(ssl, "%s%snum.type.%s=%lu\n", n, d, rrtype_to_string(i), (unsigned long)st->qtype[i])) return; } /* opcode */ for(i=0; i<6; i++) { if(inhibit_zero && st->opcode[i] == 0 && i != OPCODE_QUERY) continue; if(!ssl_printf(ssl, "%s%snum.opcode.%s=%lu\n", n, d, opcode2str(i), (unsigned long)st->opcode[i])) return; } /* qclass */ for(i=0; i<4; i++) { if(inhibit_zero && st->qclass[i] == 0 && i != CLASS_IN) continue; if(!ssl_printf(ssl, "%s%snum.class.%s=%lu\n", n, d, rrclass_to_string(i), (unsigned long)st->qclass[i])) return; } /* rcode */ for(i=0; i<17; i++) { if(inhibit_zero && st->rcode[i] == 0 && i > RCODE_YXDOMAIN) /* NSD does not use larger */ continue; if(!ssl_printf(ssl, "%s%snum.rcode.%s=%lu\n", n, d, rcstr[i], (unsigned long)st->rcode[i])) return; } /* edns */ if(!ssl_printf(ssl, "%s%snum.edns=%lu\n", n, d, (unsigned long)st->edns)) return; /* ednserr */ if(!ssl_printf(ssl, "%s%snum.ednserr=%lu\n", n, d, (unsigned long)st->ednserr)) return; /* qudp */ if(!ssl_printf(ssl, "%s%snum.udp=%lu\n", n, d, (unsigned long)st->qudp)) return; /* qudp6 */ if(!ssl_printf(ssl, "%s%snum.udp6=%lu\n", n, d, (unsigned long)st->qudp6)) return; /* ctcp */ if(!ssl_printf(ssl, "%s%snum.tcp=%lu\n", n, d, (unsigned long)st->ctcp)) return; /* ctcp6 */ if(!ssl_printf(ssl, "%s%snum.tcp6=%lu\n", n, d, (unsigned long)st->ctcp6)) return; /* ctls */ if(!ssl_printf(ssl, "%s%snum.tls=%lu\n", n, d, (unsigned long)st->ctls)) return; /* ctls6 */ if(!ssl_printf(ssl, "%s%snum.tls6=%lu\n", n, d, (unsigned long)st->ctls6)) return; /* nona */ if(!ssl_printf(ssl, "%s%snum.answer_wo_aa=%lu\n", n, d, (unsigned long)st->nona)) return; /* rxerr */ if(!ssl_printf(ssl, "%s%snum.rxerr=%lu\n", n, d, (unsigned long)st->rxerr)) return; /* txerr */ if(!ssl_printf(ssl, "%s%snum.txerr=%lu\n", n, d, (unsigned long)st->txerr)) return; /* number of requested-axfr, number of times axfr served to clients */ if(!ssl_printf(ssl, "%s%snum.raxfr=%lu\n", n, d, (unsigned long)st->raxfr)) return; /* truncated */ if(!ssl_printf(ssl, "%s%snum.truncated=%lu\n", n, d, (unsigned long)st->truncated)) return; /* dropped */ if(!ssl_printf(ssl, "%s%snum.dropped=%lu\n", n, d, (unsigned long)st->dropped)) return; } #ifdef USE_ZONE_STATS static void resize_zonestat(xfrd_state_type* xfrd, size_t num) { struct nsdst** a = xalloc_array_zero(num, sizeof(struct nsdst*)); if(xfrd->zonestat_clear_num != 0) memcpy(a, xfrd->zonestat_clear, xfrd->zonestat_clear_num * sizeof(struct nsdst*)); free(xfrd->zonestat_clear); xfrd->zonestat_clear = a; xfrd->zonestat_clear_num = num; } static void zonestat_print(RES* ssl, xfrd_state_type* xfrd, int clear) { struct zonestatname* n; struct nsdst stat0, stat1; RBTREE_FOR(n, struct zonestatname*, xfrd->nsd->options->zonestatnames){ char* name = (char*)n->node.key; if(n->id >= xfrd->zonestat_safe) continue; /* newly allocated and reload has not yet done and replied with new size */ if(name == NULL || name[0]==0) continue; /* empty name, do not output */ /* the statistics are stored in two blocks, during reload * the newly forked processes get the other block to use, * these blocks are mmapped and are currently in use to * add statistics to */ memcpy(&stat0, &xfrd->nsd->zonestat[0][n->id], sizeof(stat0)); memcpy(&stat1, &xfrd->nsd->zonestat[1][n->id], sizeof(stat1)); stats_add(&stat0, &stat1); /* save a copy of current (cumulative) stats in stat1 */ memcpy(&stat1, &stat0, sizeof(stat1)); /* subtract last total of stats that was 'cleared' */ if(n->id < xfrd->zonestat_clear_num && xfrd->zonestat_clear[n->id]) stats_subtract(&stat0, xfrd->zonestat_clear[n->id]); if(clear) { /* extend storage array if needed */ if(n->id >= xfrd->zonestat_clear_num) { if(n->id+1 < xfrd->nsd->options->zonestatnames->count) resize_zonestat(xfrd, xfrd->nsd->options->zonestatnames->count); else resize_zonestat(xfrd, n->id+1); } if(!xfrd->zonestat_clear[n->id]) xfrd->zonestat_clear[n->id] = xalloc( sizeof(struct nsdst)); /* store last total of stats */ memcpy(xfrd->zonestat_clear[n->id], &stat1, sizeof(struct nsdst)); } /* stat0 contains the details that we want to print */ if(!ssl_printf(ssl, "%s%snum.queries=%lu\n", name, ".", (unsigned long)(stat0.qudp + stat0.qudp6 + stat0.ctcp + stat0.ctcp6 + stat0.ctls + stat0.ctls6))) return; print_stat_block(ssl, name, ".", &stat0); } } #endif /* USE_ZONE_STATS */ static void print_stats(RES* ssl, xfrd_state_type* xfrd, struct timeval* now, int clear) { size_t i; stc_type total = 0; struct timeval elapsed, uptime; /* per CPU and total */ for(i=0; insd->child_count; i++) { if(!ssl_printf(ssl, "server%d.queries=%lu\n", (int)i, (unsigned long)xfrd->nsd->children[i].query_count)) return; total += xfrd->nsd->children[i].query_count; } if(!ssl_printf(ssl, "num.queries=%lu\n", (unsigned long)total)) return; /* time elapsed and uptime (in seconds) */ timeval_subtract(&uptime, now, &xfrd->nsd->rc->boot_time); timeval_subtract(&elapsed, now, &xfrd->nsd->rc->stats_time); if(!ssl_printf(ssl, "time.boot=%lu.%6.6lu\n", (unsigned long)uptime.tv_sec, (unsigned long)uptime.tv_usec)) return; if(!ssl_printf(ssl, "time.elapsed=%lu.%6.6lu\n", (unsigned long)elapsed.tv_sec, (unsigned long)elapsed.tv_usec)) return; /* mem info, database on disksize */ if(!print_longnum(ssl, "size.db.disk=", xfrd->nsd->st.db_disk)) return; if(!print_longnum(ssl, "size.db.mem=", xfrd->nsd->st.db_mem)) return; if(!print_longnum(ssl, "size.xfrd.mem=", region_get_mem(xfrd->region))) return; if(!print_longnum(ssl, "size.config.disk=", xfrd->nsd->options->zonelist_off)) return; if(!print_longnum(ssl, "size.config.mem=", region_get_mem( xfrd->nsd->options->region))) return; print_stat_block(ssl, "", "", &xfrd->nsd->st); /* zone statistics */ if(!ssl_printf(ssl, "zone.master=%lu\n", (unsigned long)(xfrd->notify_zones->count - xfrd->zones->count))) return; if(!ssl_printf(ssl, "zone.slave=%lu\n", (unsigned long)xfrd->zones->count)) return; #ifdef USE_ZONE_STATS zonestat_print(ssl, xfrd, clear); /* per-zone statistics */ #else (void)clear; #endif } static void clear_stats(xfrd_state_type* xfrd) { size_t i; uint64_t dbd = xfrd->nsd->st.db_disk; uint64_t dbm = xfrd->nsd->st.db_mem; for(i=0; insd->child_count; i++) { xfrd->nsd->children[i].query_count = 0; } memset(&xfrd->nsd->st, 0, sizeof(struct nsdst)); /* zonestats are cleared by storing the cumulative value that * was last printed in the zonestat_clear array, and subtracting * that before the next stats printout */ xfrd->nsd->st.db_disk = dbd; xfrd->nsd->st.db_mem = dbm; } void daemon_remote_process_stats(struct daemon_remote* rc) { RES res; struct rc_state* s; struct timeval now; if(!rc) return; if(gettimeofday(&now, NULL) == -1) log_msg(LOG_ERR, "gettimeofday: %s", strerror(errno)); /* pop one and give it stats */ while((s = rc->stats_list)) { assert(s->in_stats_list); res.ssl = s->ssl; res.fd = s->fd; print_stats(&res, rc->xfrd, &now, (s->in_stats_list == 1)); if(s->in_stats_list == 1) { clear_stats(rc->xfrd); rc->stats_time = now; } VERBOSITY(3, (LOG_INFO, "remote control stats printed")); rc->stats_list = s->next; s->in_stats_list = 0; clean_point(rc, s); } } #endif /* BIND8_STATS */ int create_local_accept_sock(const char *path, int* noproto) { #ifdef HAVE_SYS_UN_H int s; struct sockaddr_un usock; VERBOSITY(3, (LOG_INFO, "creating unix socket %s", path)); #ifdef HAVE_STRUCT_SOCKADDR_UN_SUN_LEN /* this member exists on BSDs, not Linux */ usock.sun_len = (unsigned)sizeof(usock); #endif usock.sun_family = AF_LOCAL; /* length is 92-108, 104 on FreeBSD */ (void)strlcpy(usock.sun_path, path, sizeof(usock.sun_path)); if ((s = socket(AF_LOCAL, SOCK_STREAM, 0)) == -1) { log_msg(LOG_ERR, "Cannot create local socket %s (%s)", path, strerror(errno)); return -1; } if (unlink(path) && errno != ENOENT) { /* The socket already exists and cannot be removed */ log_msg(LOG_ERR, "Cannot remove old local socket %s (%s)", path, strerror(errno)); goto err; } if (bind(s, (struct sockaddr *)&usock, (socklen_t)sizeof(struct sockaddr_un)) == -1) { log_msg(LOG_ERR, "Cannot bind local socket %s (%s)", path, strerror(errno)); goto err; } if (fcntl(s, F_SETFL, O_NONBLOCK) == -1) { log_msg(LOG_ERR, "Cannot set non-blocking mode"); goto err; } if (listen(s, TCP_BACKLOG) == -1) { log_msg(LOG_ERR, "can't listen: %s", strerror(errno)); goto err; } (void)noproto; /*unused*/ return s; err: close(s); return -1; #else (void)path; log_msg(LOG_ERR, "Local sockets are not supported"); *noproto = 1; return -1; #endif } #endif /* HAVE_SSL */