Mercurial > dnsbl
view src/dnsbl.cpp @ 65:1ab70970c8c8
need to cleanup zombie children
| author | carl |
|---|---|
| date | Sun, 16 Jan 2005 17:40:22 -0800 |
| parents | 6add229288a8 |
| children | e6a2d0be7c5e |
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/* Copyright (c) 2004, 2005 Carl Byington - 510 Software Group, released under the GPL version 2 or any later version at your choice available at http://www.fsf.org/licenses/gpl.txt Based on a sample milter Copyright (c) 2000-2003 Sendmail, Inc. and its suppliers. Inspired by the DCC by Rhyolite Software -r port The port used to talk to our internal dns resolver processes -p port The port through which the MTA will connect to this milter. -t sec The timeout value. -c Check the config, and print a copy to stdout. Don't start the milter or do anything with the socket. -d Add debug syslog entries TODO: 1) Add config for max_recipients for each mail domain. Recipients in excess of that limit will be rejected, and the entire data will be rejected if it is sent. 2) Add config for poison addresses. If any recipient is poison, all recipients are rejected even if they would be whitelisted, and the data is rejected if sent. 3) Add option to only allow one recipient if the return path is empty. 4) Check if the envelope from domain name primary MX points 127.0.0.0/8 5) Add option for using smtp connections to verify addresses from backup mx machines. This allows the backup mx to learn the valid addresses on the primary machine. */ // from sendmail sample #include <sys/types.h> #include <sys/stat.h> #include <errno.h> #include <sysexits.h> #include <unistd.h> // needed for socket io #include <sys/ioctl.h> #include <net/if.h> #include <arpa/inet.h> #include <netinet/in.h> #include <netinet/tcp.h> #include <netdb.h> #include <sys/socket.h> #include <sys/un.h> // needed for thread #include <pthread.h> // needed for std c++ collections #include <set> #include <map> #include <list> // for the dns resolver #include <netinet/in.h> #include <arpa/nameser.h> #include <resolv.h> // misc stuff needed here #include <ctype.h> #include <fstream> #include <syslog.h> #include <pwd.h> #include <sys/wait.h> /* header for waitpid() and various macros */ #include <signal.h> /* header for signal functions */ static char* dnsbl_version="$Id$"; #define DEFAULT "default" #define WHITE "white" #define BLACK "black" #define OK "ok" #define MANY "many" enum status {oksofar, // not rejected yet white, // whitelisted by envelope from black, // blacklisted by envelope from or to reject, // rejected by a dns list reject_tag, // too many bad html tags reject_host}; // too many hosts/urls in body using namespace std; extern "C" { #include "libmilter/mfapi.h" sfsistat mlfi_connect(SMFICTX *ctx, char *hostname, _SOCK_ADDR *hostaddr); sfsistat mlfi_envfrom(SMFICTX *ctx, char **argv); sfsistat mlfi_envrcpt(SMFICTX *ctx, char **argv); sfsistat mlfi_body(SMFICTX *ctx, u_char *data, size_t len); sfsistat mlfi_eom(SMFICTX *ctx); sfsistat mlfi_abort(SMFICTX *ctx); sfsistat mlfi_close(SMFICTX *ctx); void sig_chld(int signo); } struct ltstr { bool operator()(char* s1, char* s2) const { return strcmp(s1, s2) < 0; } }; struct DNSBL { char *suffix; // blacklist suffix like blackholes.five-ten-sg.com char *message; // error message with one or two %s operators for the ip address replacement DNSBL(char *s, char *m); }; DNSBL::DNSBL(char *s, char *m) { suffix = s; message = m; } typedef DNSBL * DNSBLP; typedef list<DNSBLP> DNSBLL; typedef DNSBLL * DNSBLLP; typedef map<char *, char *, ltstr> string_map; typedef map<char *, string_map *, ltstr> from_map; typedef map<char *, DNSBLP, ltstr> dnsblp_map; typedef map<char *, DNSBLLP, ltstr> dnsbllp_map; typedef set<char *, ltstr> string_set; typedef set<int> int_set; typedef list<char *> string_list; typedef map<char *, int, ltstr> ns_mapper; struct ns_map { // all the strings are owned by the keys/values in the ns_host string map string_map ns_host; // nameserver name -> host name that uses this name server ns_mapper ns_ip; // nameserver name -> ip address of the name server }; struct CONFIG { // the only mutable stuff once it has been loaded from the config file int reference_count; // protected by the global config_mutex // all the rest is constant after loading from the config file int generation; time_t load_time; string_list config_files; dnsblp_map dnsbls; dnsbllp_map dnsblls; from_map env_from; string_map env_to_dnsbll; // map recipient to a named dnsbll string_map env_to_chkfrom; // map recipient to a named from map char * content_suffix; // for sbl url body filtering char * content_message; // "" string_set content_host_ignore;// hosts to ignore for content sbl checking char * host_limit_message; // error message for excessive host names int host_limit; // limit on host names bool host_random; // pick a random selection of host names rather than error for excessive hosts char * tag_limit_message; // error message for excessive bad html tags int tag_limit; // limit on bad html tags string_set html_tags; // set of valid html tags string_set tlds; // set of valid tld components CONFIG(); ~CONFIG(); }; CONFIG::CONFIG() { reference_count = 0; generation = 0; load_time = 0; content_suffix = NULL; content_message = NULL; host_limit_message = NULL; host_limit = 0; host_random = false; tag_limit_message = NULL; tag_limit = 0; } CONFIG::~CONFIG() { for (dnsblp_map::iterator i=dnsbls.begin(); i!=dnsbls.end(); i++) { DNSBLP d = (*i).second; // delete the underlying DNSBL objects. delete d; } for (dnsbllp_map::iterator i=dnsblls.begin(); i!=dnsblls.end(); i++) { DNSBLLP d = (*i).second; // *d is a list of pointers to DNSBL objects, but // the underlying objects have already been deleted above. delete d; } for (from_map::iterator i=env_from.begin(); i!=env_from.end(); i++) { string_map *d = (*i).second; delete d; } } static bool debug_syslog = false; static bool loader_run = true; // used to stop the config loader thread static string_set all_strings; // owns all the strings, only modified by the config loader thread static CONFIG * config = NULL; // protected by the config_mutex static int generation = 0; // protected by the config_mutex static pthread_mutex_t config_mutex; static pthread_mutex_t syslog_mutex; static pthread_mutex_t resolve_mutex; static pthread_mutex_t fd_pool_mutex; static std::set<int> fd_pool; static int NULL_SOCKET = -1; static char *resolver_port = NULL; // unix domain socket to talk to the dns resolver process static int resolver_socket = NULL_SOCKET; // socket used to listen for resolver requests static time_t ERROR_SOCKET_TIME = 60; // number of seconds between attempts to open the spam filter socket static time_t last_error_time; static int resolver_sock_count = 0; // protected with fd_pool_mutex static int resolver_pool_size = 0; // protected with fd_pool_mutex // packed structure to allow a single socket write to dump the // length and the following answer. The packing attribute is gcc specific. struct glommer { int length; #ifdef NS_PACKETSZ u_char answer[NS_PACKETSZ]; // with a resolver, we return resolver answers #else int answer; // without a resolver, we return a single ip4 address, 0 == no answer #endif } __attribute__ ((packed)); struct mlfiPriv; //////////////////////////////////////////////// // helper to discard the strings and objects held by an ns_map // static void discard(ns_map &s); static void discard(ns_map &s) { for (string_map::iterator i=s.ns_host.begin(); i!=s.ns_host.end(); i++) { char *x = (*i).first; char *y = (*i).second; free(x); free(y); } s.ns_ip.clear(); s.ns_host.clear(); } //////////////////////////////////////////////// // helper to register a string in an ns_map // static void register_string(ns_map &s, char *name, char *refer); static void register_string(ns_map &s, char *name, char *refer) { string_map::iterator i = s.ns_host.find(name); if (i != s.ns_host.end()) return; char *x = strdup(name); char *y = strdup(refer); s.ns_ip[x] = 0; s.ns_host[x] = y; } //////////////////////////////////////////////// // helper to discard the strings held by a string_set // static void discard(string_set &s); static void discard(string_set &s) { for (string_set::iterator i=s.begin(); i!=s.end(); i++) { free(*i); } s.clear(); } //////////////////////////////////////////////// // helper to register a string in a string set // static char* register_string(string_set &s, char *name); static char* register_string(string_set &s, char *name) { string_set::iterator i = s.find(name); if (i != s.end()) return *i; char *x = strdup(name); s.insert(x); return x; } //////////////////////////////////////////////// // syslog a message // static void my_syslog(mlfiPriv *priv, char *text); // include the content scanner #include "scanner.cpp" //////////////////////////////////////////////// // disconnect the fd from the dns resolver process // void my_disconnect(int sock, bool decrement = true); void my_disconnect(int sock, bool decrement) { if (sock != NULL_SOCKET) { if (decrement) { pthread_mutex_lock(&fd_pool_mutex); resolver_sock_count--; pthread_mutex_unlock(&fd_pool_mutex); } shutdown(sock, SHUT_RDWR); close(sock); } } //////////////////////////////////////////////// // return fd connected to the dns resolver process // int my_connect(); int my_connect() { // if we have had recent errors, don't even try to open the socket time_t now = time(NULL); if ((now - last_error_time) < ERROR_SOCKET_TIME) return NULL_SOCKET; // nothing recent, maybe this time it will work int sock = NULL_SOCKET; sockaddr_un server; memset(&server, '\0', sizeof(server)); server.sun_family = AF_UNIX; strncpy(server.sun_path, resolver_port, sizeof(server.sun_path)-1); sock = socket(AF_UNIX, SOCK_STREAM, 0); if (sock != NULL_SOCKET) { bool rc = (connect(sock, (sockaddr *)&server, sizeof(server)) == 0); if (!rc) { my_disconnect(sock, false); sock = NULL_SOCKET; last_error_time = now; } } else last_error_time = now; if (sock != NULL_SOCKET) { pthread_mutex_lock(&fd_pool_mutex); resolver_sock_count++; pthread_mutex_unlock(&fd_pool_mutex); } return sock; } //////////////////////////////////////////////// // mail filter private data, held for us by sendmail // struct mlfiPriv { // connection specific data CONFIG *pc; // global context with our maps int fd; // to talk to dns resolvers process bool err; // did we get any errors on the resolver socket? int ip; // ip4 address of the smtp client map<DNSBLP, status> checked; // status from those lists // message specific data char *mailaddr; // envelope from value char *queueid; // sendmail queue id bool authenticated; // client authenticated? if so, suppress all dnsbl checks bool have_whites; // have at least one whitelisted recipient? need to accept content and remove all non-whitelisted recipients if it fails bool only_whites; // every recipient is whitelisted? string_set non_whites; // remember the non-whitelisted recipients so we can remove them if need be recorder *memory; // memory for the content scanner url_scanner *scanner; // object to handle body scanning mlfiPriv(); ~mlfiPriv(); void reset(bool final = false); // for a new message void get_fd(); void return_fd(); int my_read(char *buf, int len); int my_write(char *buf, int len); }; mlfiPriv::mlfiPriv() { pthread_mutex_lock(&config_mutex); pc = config; pc->reference_count++; pthread_mutex_unlock(&config_mutex); get_fd(); ip = 0; mailaddr = NULL; queueid = NULL; authenticated = false; have_whites = false; only_whites = true; memory = new recorder(this, &pc->html_tags, &pc->tlds); scanner = new url_scanner(memory); } mlfiPriv::~mlfiPriv() { return_fd(); pthread_mutex_lock(&config_mutex); pc->reference_count--; pthread_mutex_unlock(&config_mutex); reset(true); } void mlfiPriv::reset(bool final) { if (mailaddr) free(mailaddr); if (queueid) free(queueid); discard(non_whites); delete memory; delete scanner; if (!final) { mailaddr = NULL; queueid = NULL; authenticated = false; have_whites = false; only_whites = true; memory = new recorder(this, &pc->html_tags, &pc->tlds); scanner = new url_scanner(memory); } } void mlfiPriv::get_fd() { err = true; fd = NULL_SOCKET; int result = pthread_mutex_lock(&fd_pool_mutex); if (!result) { std::set<int>::iterator i; i = fd_pool.begin(); if (i != fd_pool.end()) { // have at least one fd in the pool err = false; fd = *i; fd_pool.erase(fd); resolver_pool_size--; pthread_mutex_unlock(&fd_pool_mutex); } else { // pool is empty, get a new fd pthread_mutex_unlock(&fd_pool_mutex); fd = my_connect(); err = (fd == NULL_SOCKET); } } else { // cannot lock the pool, just get a new fd fd = my_connect(); err = (fd == NULL_SOCKET); } } void mlfiPriv::return_fd() { if (err) { // this fd got a socket error, so close it, rather than returning it to the pool my_disconnect(fd); } else { int result = pthread_mutex_lock(&fd_pool_mutex); if (!result) { if ((resolver_sock_count > resolver_pool_size*5) || (resolver_pool_size < 5)) { // return the fd to the pool fd_pool.insert(fd); resolver_pool_size++; pthread_mutex_unlock(&fd_pool_mutex); } else { // more than 20% of the open resolver sockets are in the pool, and the // pool as at least 5 sockets. that is enough, so just close this one. pthread_mutex_unlock(&fd_pool_mutex); my_disconnect(fd); } } else { // could not lock the pool, so just close the fd my_disconnect(fd); } } } int mlfiPriv::my_write(char *buf, int len) { if (err) return 0; int rs = 0; while (len) { int ws = write(fd, buf, len); if (ws > 0) { rs += ws; len -= ws; buf += ws; } else { // peer closed the socket! rs = 0; err = true; break; } } return rs; } int mlfiPriv::my_read(char *buf, int len) { if (err) return 0; int rs = 0; while (len > 1) { int ws = read(fd, buf, len); if (ws > 0) { rs += ws; len -= ws; buf += ws; } else { // peer closed the socket! rs = 0; err = true; break; } } return rs; } #define MLFIPRIV ((struct mlfiPriv *) smfi_getpriv(ctx)) //////////////////////////////////////////////// // syslog a message // static void my_syslog(mlfiPriv *priv, char *text) { char buf[1000]; if (priv) { snprintf(buf, sizeof(buf), "%s: %s", priv->queueid, text); text = buf; } pthread_mutex_lock(&syslog_mutex); openlog("dnsbl", LOG_PID, LOG_MAIL); syslog(LOG_NOTICE, "%s", text); closelog(); pthread_mutex_unlock(&syslog_mutex); } static void my_syslog(char *text); static void my_syslog(char *text) { my_syslog(NULL, text); } //////////////////////////////////////////////// // register a global string // static char* register_string(char *name); static char* register_string(char *name) { return register_string(all_strings, name); } static char* next_token(char *delim); static char* next_token(char *delim) { char *name = strtok(NULL, delim); if (!name) return name; return register_string(name); } //////////////////////////////////////////////// // lookup an email address in the env_from or env_to maps // static char* lookup1(char *email, string_map map); static char* lookup1(char *email, string_map map) { string_map::iterator i = map.find(email); if (i != map.end()) return (*i).second; char *x = strchr(email, '@'); if (!x) return DEFAULT; x++; i = map.find(x); if (i != map.end()) return (*i).second; return DEFAULT; } //////////////////////////////////////////////// // lookup an email address in the env_from or env_to maps // this email address is passed in from sendmail, and will // always be enclosed in <>. It may have mixed case, just // as the mail client sent it. // static char* lookup(char* email, string_map map); static char* lookup(char* email, string_map map) { int n = strlen(email)-2; if (n < 1) return DEFAULT; // malformed char *key = strdup(email+1); key[n] = '\0'; for (int i=0; i<n; i++) key[i] = tolower(key[i]); char *rc = lookup1(key, map); free(key); return rc; } //////////////////////////////////////////////// // find the dnsbl with a specific name // static DNSBLP find_dnsbl(CONFIG &dc, char *name); static DNSBLP find_dnsbl(CONFIG &dc, char *name) { dnsblp_map::iterator i = dc.dnsbls.find(name); if (i == dc.dnsbls.end()) return NULL; return (*i).second; } //////////////////////////////////////////////// // find the dnsbll with a specific name // static DNSBLLP find_dnsbll(CONFIG &dc, char *name); static DNSBLLP find_dnsbll(CONFIG &dc, char *name) { dnsbllp_map::iterator i = dc.dnsblls.find(name); if (i == dc.dnsblls.end()) return NULL; return (*i).second; } //////////////////////////////////////////////// // find the envfrom map with a specific name // static string_map* find_from_map(CONFIG &dc, char *name); static string_map* find_from_map(CONFIG &dc, char *name) { from_map::iterator i = dc.env_from.find(name); if (i == dc.env_from.end()) return NULL; return (*i).second; } static string_map& really_find_from_map(CONFIG &dc, char *name); static string_map& really_find_from_map(CONFIG &dc, char *name) { string_map *sm = find_from_map(dc, name); if (!sm) { sm = new string_map; dc.env_from[name] = sm; } return *sm; } //////////////////////////////////////////////// // read a resolver request from the socket, process it, and // write the result back to the socket. static void process_resolver_requests(int socket); static void process_resolver_requests(int socket) { #ifdef NS_MAXDNAME char question[NS_MAXDNAME]; #else char question[1000]; #endif glommer glom; int maxq = sizeof(question); while (true) { // read a question int rs = 0; while (true) { int ns = read(socket, question+rs, maxq-rs); if (ns > 0) { rs += ns; if (question[rs-1] == '\0') { // last byte read was the null terminator, we are done break; } } else { // peer closed the socket //my_syslog("!!child worker process, peer closed socket while reading question"); shutdown(socket, SHUT_RDWR); close(socket); return; } } // find the answer #ifdef NS_PACKETSZ //char text[1000]; //snprintf(text, sizeof(text), "!!child worker process has a question %s", question); //my_syslog(text); glom.length = res_search(question, ns_c_in, ns_t_a, glom.answer, sizeof(glom.answer)); if (glom.length < 0) glom.length = 0; // represent all errors as zero length answers #else glom.length = sizeof(glom.answer); glom.answer = 0; struct hostent *host = gethostbyname(question); if (host && (host->h_addrtype == AF_INET)) { memcpy(&glom.answer, host->h_addr, sizeof(glom.answer)); } #endif // write the answer char *buf = (char *)&glom; int len = glom.length + sizeof(glom.length); //snprintf(text, sizeof(text), "!!child worker process writing answer length %d for total %d", glom.length, len); //my_syslog(text); int ws = 0; while (len > ws) { int ns = write(socket, buf+ws, len-ws); if (ns > 0) { ws += ns; } else { // peer closed the socket! //my_syslog("!!child worker process, peer closed socket while writing answer"); shutdown(socket, SHUT_RDWR); close(socket); return; } } } } //////////////////////////////////////////////// // ask a dns question and get an A record answer - we don't try // very hard, just using the default resolver retry settings. // If we cannot get an answer, we just accept the mail. // // static int dns_interface(mlfiPriv &priv, char *question, bool maybe_ip, ns_map *nameservers); static int dns_interface(mlfiPriv &priv, char *question, bool maybe_ip, ns_map *nameservers) { // this part can be done without locking the resolver mutex. Each // milter thread is talking over its own socket to a separate resolver // process, which does the actual dns resolution. if (priv.err) return 0; // cannot ask more questions on this socket. priv.my_write(question, strlen(question)+1); // write the question including the null terminator glommer glom; char *buf = (char *)&glom; priv.my_read(buf, sizeof(glom.length)); buf += sizeof(glom.length); ///char text[1000]; ///snprintf(text, sizeof(text), "!!milter thread wrote question %s and has answer length %d", question, glom.length); ///my_syslog(text); if ((glom.length < 0) || (glom.length > sizeof(glom.answer))) { priv.err = true; return 0; // cannot process overlarge answers } priv.my_read(buf, glom.length); #ifdef NS_PACKETSZ // now we need to lock the resolver mutex to keep the milter threads from // stepping on each other while parsing the dns answer. int ret_address = 0; pthread_mutex_lock(&resolve_mutex); if (glom.length > 0) { // parse the answer ns_msg handle; ns_rr rr; if (ns_initparse(glom.answer, glom.length, &handle) == 0) { // look for ns names if (nameservers) { ns_map &ns = *nameservers; int rrnum = 0; while (ns_parserr(&handle, ns_s_ns, rrnum++, &rr) == 0) { if (ns_rr_type(rr) == ns_t_ns) { char nam[NS_MAXDNAME+1]; char *n = nam; const u_char *p = ns_rr_rdata(rr); while (((n-nam) < NS_MAXDNAME) && ((p-glom.answer) < glom.length) && *p) { size_t s = *(p++); if (s > 191) { // compression pointer s = (s-192)*256 + *(p++); if (s >= glom.length) break; // pointer outside bounds of answer p = glom.answer + s; s = *(p++); } if (s > 0) { if ((n-nam) >= (NS_MAXDNAME-s)) break; // destination would overflow name buffer if ((p-glom.answer) >= (glom.length-s)) break; // source outside bounds of answer memcpy(n, p, s); n += s; p += s; *(n++) = '.'; } } if (n-nam) n--; // remove trailing . *n = '\0'; // null terminate it register_string(ns, nam, question); // ns host to lookup later } } rrnum = 0; while (ns_parserr(&handle, ns_s_ar, rrnum++, &rr) == 0) { if (ns_rr_type(rr) == ns_t_a) { char* nam = (char*)ns_rr_name(rr); ns_mapper::iterator i = ns.ns_ip.find(nam); if (i != ns.ns_ip.end()) { // we want this ip address int address; memcpy(&address, ns_rr_rdata(rr), sizeof(address)); ns.ns_ip[nam] = address; } } } } int rrnum = 0; while (ns_parserr(&handle, ns_s_an, rrnum++, &rr) == 0) { if (ns_rr_type(rr) == ns_t_a) { int address; memcpy(&address, ns_rr_rdata(rr), sizeof(address)); ret_address = address; } } } } if (maybe_ip && !ret_address) { // might be a bare ip address in_addr ip; if (inet_aton(question, &ip)) { ret_address = ip.s_addr; } } pthread_mutex_unlock(&resolve_mutex); return ret_address; #else return glom.answer; #endif } //////////////////////////////////////////////// // check a single dnsbl // static status check_single(mlfiPriv &priv, int ip, char *suffix); static status check_single(mlfiPriv &priv, int ip, char *suffix) { // make a dns question const u_char *src = (const u_char *)&ip; if (src[0] == 127) return oksofar; // don't do dns lookups on localhost #ifdef NS_MAXDNAME char question[NS_MAXDNAME]; #else char question[1000]; #endif snprintf(question, sizeof(question), "%u.%u.%u.%u.%s.", src[3], src[2], src[1], src[0], suffix); // ask the question, if we get an A record it implies a blacklisted ip address return (dns_interface(priv, question, false, NULL)) ? reject : oksofar; } //////////////////////////////////////////////// // check a single dnsbl // static status check_single(mlfiPriv &priv, int ip, DNSBL &bl); static status check_single(mlfiPriv &priv, int ip, DNSBL &bl) { return check_single(priv, ip, bl.suffix); } //////////////////////////////////////////////// // check the dnsbls specified for this recipient // static status check_dnsbl(mlfiPriv &priv, DNSBLLP dnsbllp, DNSBLP &rejectlist); static status check_dnsbl(mlfiPriv &priv, DNSBLLP dnsbllp, DNSBLP &rejectlist) { if (priv.authenticated) return oksofar; if (!dnsbllp) return oksofar; DNSBLL &dnsbll = *dnsbllp; for (DNSBLL::iterator i=dnsbll.begin(); i!=dnsbll.end(); i++) { DNSBLP dp = *i; // non null by construction status st; map<DNSBLP, status>::iterator f = priv.checked.find(dp); if (f == priv.checked.end()) { // have not checked this list yet st = check_single(priv, priv.ip, *dp); rejectlist = dp; priv.checked[dp] = st; } else { st = (*f).second; rejectlist = (*f).first; } if (st == reject) return st; } return oksofar; } //////////////////////////////////////////////// // check the hosts from the body against the content dnsbl // static status check_hosts(mlfiPriv &priv, char *&host, int &ip); static status check_hosts(mlfiPriv &priv, char *&host, int &ip) { CONFIG &dc = *priv.pc; int count = 0; ns_map nameservers; bool ran = priv.pc->host_random; int lim = priv.pc->host_limit; // we should not look at more than this many hosts int cnt = priv.memory->hosts.size(); // number of hosts we could look at int_set ips; // remove duplicate ip addresses for (string_set::iterator i=priv.memory->hosts.begin(); i!=priv.memory->hosts.end(); i++) { host = *i; // a reference into priv.memory->hosts, which will live until this smtp transaction is closed // don't bother looking up hosts on the ignore list string_set::iterator j = priv.pc->content_host_ignore.find(host); if (j != priv.pc->content_host_ignore.end()) continue; // try to only look at lim/cnt fraction of the available cnt host names in random mode if ((cnt > lim) && (lim > 0) && ran) { int r = rand() % cnt; if (r >= lim) { char buf[1000]; snprintf(buf, sizeof(buf), "host %s skipped", host); my_syslog(&priv, buf); continue; } } count++; if ((count > lim) && (lim > 0) && (!ran)) { discard(nameservers); return reject_host; } ip = dns_interface(priv, host, true, &nameservers); if (debug_syslog) { char buf[1000]; if (ip) { char adr[sizeof "255.255.255.255"]; adr[0] = '\0'; inet_ntop(AF_INET, (const u_char *)&ip, adr, sizeof(adr)); snprintf(buf, sizeof(buf), "host %s found at %s", host, adr); } else { snprintf(buf, sizeof(buf), "host %s not found", host); } my_syslog(&priv, buf); } if (ip) { int_set::iterator i = ips.find(ip); if (i == ips.end()) { ips.insert(ip); status st = check_single(priv, ip, dc.content_suffix); if (st == reject) { discard(nameservers); return st; } } } } lim *= 4; // allow average of 3 ns per host name for (ns_mapper::iterator i=nameservers.ns_ip.begin(); i!=nameservers.ns_ip.end(); i++) { count++; if ((count > lim) && (lim > 0)) { if (ran) continue; // don't complain discard(nameservers); return reject_host; } host = (*i).first; // a transient reference that needs to be replaced before we return it ip = (*i).second; if (!ip) ip = dns_interface(priv, host, false, NULL); if (debug_syslog) { char buf[200]; if (ip) { char adr[sizeof "255.255.255.255"]; adr[0] = '\0'; inet_ntop(AF_INET, (const u_char *)&ip, adr, sizeof(adr)); snprintf(buf, sizeof(buf), "ns %s found at %s", host, adr); } else { snprintf(buf, sizeof(buf), "ns %s not found", host); } my_syslog(&priv, buf); } if (ip) { int_set::iterator i = ips.find(ip); if (i == ips.end()) { ips.insert(ip); status st = check_single(priv, ip, dc.content_suffix); if (st == reject) { string_map::iterator j = nameservers.ns_host.find(host); if (j != nameservers.ns_host.end()) { char *refer = (*j).second; char buf[1000]; snprintf(buf, sizeof(buf), "%s with nameserver %s", refer, host); host = register_string(priv.memory->hosts, buf); // put a copy into priv.memory->hosts, and return that reference } else { host = register_string(priv.memory->hosts, host); // put a copy into priv.memory->hosts, and return that reference } discard(nameservers); return st; } } } } discard(nameservers); host = NULL; int bin = priv.memory->binary_tags; int bad = priv.memory->bad_html_tags; lim = priv.pc->tag_limit; if (3*bin > bad) return oksofar; // probably .zip or .tar.gz with random content if ((bad > lim) && (lim > 0)) return reject_tag; return oksofar; } //////////////////////////////////////////////// // start of sendmail milter interfaces // sfsistat mlfi_connect(SMFICTX *ctx, char *hostname, _SOCK_ADDR *hostaddr) { // allocate some private memory mlfiPriv *priv = new mlfiPriv; if (hostaddr->sa_family == AF_INET) { priv->ip = ((struct sockaddr_in *)hostaddr)->sin_addr.s_addr; } // save the private data smfi_setpriv(ctx, (void*)priv); // continue processing return SMFIS_CONTINUE; } sfsistat mlfi_envfrom(SMFICTX *ctx, char **from) { mlfiPriv &priv = *MLFIPRIV; priv.mailaddr = strdup(from[0]); priv.authenticated = (smfi_getsymval(ctx, "{auth_authen}") != NULL); return SMFIS_CONTINUE; } sfsistat mlfi_envrcpt(SMFICTX *ctx, char **rcpt) { DNSBLP rejectlist = NULL; // list that caused the reject status st = oksofar; mlfiPriv &priv = *MLFIPRIV; CONFIG &dc = *priv.pc; if (!priv.queueid) priv.queueid = strdup(smfi_getsymval(ctx, "i")); char *rcptaddr = rcpt[0]; char *dnsname = lookup(rcptaddr, dc.env_to_dnsbll); char *fromname = lookup(rcptaddr, dc.env_to_chkfrom); if ((strcmp(dnsname, BLACK) == 0) || (strcmp(fromname, BLACK) == 0)) { st = black; // two options to blacklist this recipient } else if (strcmp(fromname, WHITE) == 0) { st = white; } else { // check an env_from map string_map *sm = find_from_map(dc, fromname); if (sm != NULL) { fromname = lookup(priv.mailaddr, *sm); // returns default if name not in map if (strcmp(fromname, BLACK) == 0) { st = black; // blacklist this envelope from value } if (strcmp(fromname, WHITE) == 0) { st = white; // blacklist this envelope from value } } } if ((st == oksofar) && (strcmp(dnsname, WHITE) != 0)) { // check dns lists st = check_dnsbl(priv, find_dnsbll(dc, dnsname), rejectlist); } if (st == reject) { // reject the recipient based on some dnsbl char adr[sizeof "255.255.255.255"]; adr[0] = '\0'; inet_ntop(AF_INET, (const u_char *)&priv.ip, adr, sizeof(adr)); char buf[2000]; snprintf(buf, sizeof(buf), rejectlist->message, adr, adr); smfi_setreply(ctx, "550", "5.7.1", buf); return SMFIS_REJECT; } else if (st == black) { // reject the recipient based on blacklisting either from or to smfi_setreply(ctx, "550", "5.7.1", "no such user"); return SMFIS_REJECT; } else { // accept the recipient if (st == oksofar) { // but remember the non-whites register_string(priv.non_whites, rcptaddr); priv.only_whites = false; } if (st == white) { priv.have_whites = true; } return SMFIS_CONTINUE; } } sfsistat mlfi_body(SMFICTX *ctx, u_char *data, size_t len) { mlfiPriv &priv = *MLFIPRIV; if (priv.authenticated) return SMFIS_CONTINUE; if (priv.only_whites) return SMFIS_CONTINUE; if (!priv.pc->content_suffix) return SMFIS_CONTINUE; priv.scanner->scan(data, len); return SMFIS_CONTINUE; } sfsistat mlfi_eom(SMFICTX *ctx) { sfsistat rc; mlfiPriv &priv = *MLFIPRIV; char *host = NULL; int ip; status st; // process end of message if (priv.authenticated || priv.only_whites || (!priv.pc->content_suffix) || ((st=check_hosts(priv, host, ip)) == oksofar)) rc = SMFIS_CONTINUE; else { if (!priv.have_whites) { // can reject the entire message char buf[2000]; if (st == reject_tag) { // rejected due to excessive bad html tags snprintf(buf, sizeof(buf), priv.pc->tag_limit_message); } else if (st == reject_host) { // rejected due to excessive unique host/urls snprintf(buf, sizeof(buf), priv.pc->host_limit_message); } else { char adr[sizeof "255.255.255.255"]; adr[0] = '\0'; inet_ntop(AF_INET, (const u_char *)&ip, adr, sizeof(adr)); snprintf(buf, sizeof(buf), priv.pc->content_message, host, adr); } smfi_setreply(ctx, "550", "5.7.1", buf); rc = SMFIS_REJECT; } else { // need to accept it but remove the recipients that don't want it for (string_set::iterator i=priv.non_whites.begin(); i!=priv.non_whites.end(); i++) { char *rcpt = *i; smfi_delrcpt(ctx, rcpt); } rc = SMFIS_CONTINUE; } } // reset for a new message on the same connection mlfi_abort(ctx); return rc; } sfsistat mlfi_abort(SMFICTX *ctx) { mlfiPriv &priv = *MLFIPRIV; priv.reset(); return SMFIS_CONTINUE; } sfsistat mlfi_close(SMFICTX *ctx) { mlfiPriv *priv = MLFIPRIV; if (!priv) return SMFIS_CONTINUE; delete priv; smfi_setpriv(ctx, NULL); return SMFIS_CONTINUE; } struct smfiDesc smfilter = { "DNSBL", // filter name SMFI_VERSION, // version code -- do not change SMFIF_DELRCPT, // flags mlfi_connect, // connection info filter NULL, // SMTP HELO command filter mlfi_envfrom, // envelope sender filter mlfi_envrcpt, // envelope recipient filter NULL, // header filter NULL, // end of header mlfi_body, // body block filter mlfi_eom, // end of message mlfi_abort, // message aborted mlfi_close, // connection cleanup }; static void dumpit(char *name, string_map map); static void dumpit(char *name, string_map map) { fprintf(stdout, "\n"); for (string_map::iterator i=map.begin(); i!=map.end(); i++) { fprintf(stdout, "%s %s->%s\n", name, (*i).first, (*i).second); } } static void dumpit(from_map map); static void dumpit(from_map map) { for (from_map::iterator i=map.begin(); i!=map.end(); i++) { char buf[2000]; snprintf(buf, sizeof(buf), "envelope from map for %s", (*i).first); string_map *sm = (*i).second; dumpit(buf, *sm); } } static void dumpit(CONFIG &dc); static void dumpit(CONFIG &dc) { dumpit(dc.env_from); dumpit("envelope to (dnsbl list)", dc.env_to_dnsbll); dumpit("envelope to (from map)", dc.env_to_chkfrom); fprintf(stdout, "\ndnsbls\n"); for (dnsblp_map::iterator i=dc.dnsbls.begin(); i!=dc.dnsbls.end(); i++) { fprintf(stdout, "%s %s %s\n", (*i).first, (*i).second->suffix, (*i).second->message); } fprintf(stdout, "\ndnsbl_lists\n"); for (dnsbllp_map::iterator i=dc.dnsblls.begin(); i!=dc.dnsblls.end(); i++) { char *name = (*i).first; DNSBLL &dl = *((*i).second); fprintf(stdout, "%s", name); for (DNSBLL::iterator j=dl.begin(); j!=dl.end(); j++) { DNSBL &d = **j; fprintf(stdout, " %s", d.suffix); } fprintf(stdout, "\n"); } if (dc.content_suffix) { fprintf(stdout, "\ncontent filtering enabled with %s %s\n", dc.content_suffix, dc.content_message); } for (string_set::iterator i=dc.content_host_ignore.begin(); i!=dc.content_host_ignore.end(); i++) { fprintf(stdout, "ignore %s\n", (*i)); } if (dc.host_limit && !dc.host_random) { fprintf(stdout, "\ncontent filtering for host names hard limit %d %s\n", dc.host_limit, dc.host_limit_message); } if (dc.host_limit && dc.host_random) { fprintf(stdout, "\ncontent filtering for host names soft limit %d\n", dc.host_limit); } if (dc.tag_limit) { fprintf(stdout, "\ncontent filtering for excessive html tags enabled with limit %d %s\n", dc.tag_limit, dc.tag_limit_message); } fprintf(stdout, "\nfiles\n"); for (string_list::iterator i=dc.config_files.begin(); i!=dc.config_files.end(); i++) { char *f = *i; fprintf(stdout, "config includes %s\n", f); } } //////////////////////////////////////////////// // check for redundant or recursive include files // static bool ok_to_include(CONFIG &dc, char *fn); static bool ok_to_include(CONFIG &dc, char *fn) { if (!fn) return false; bool ok = true; for (string_list::iterator i=dc.config_files.begin(); i!=dc.config_files.end(); i++) { char *f = *i; if (strcmp(f, fn) == 0) { my_syslog("redundant or recursive include file detected"); ok = false; break; } } return ok; } //////////////////////////////////////////////// // load a single config file // static void load_conf_dcc(CONFIG &dc, char *name, char *fn); static void load_conf_dcc(CONFIG &dc, char *name, char *fn) { ifstream is(fn); if (is.fail()) { char buf[1000]; snprintf(buf, sizeof(buf), "include file %s not found", fn); my_syslog(buf); return; } dc.config_files.push_back(fn); const int LINE_SIZE = 2000; char line[LINE_SIZE]; char *list = BLACK; char *delim = " \t"; int curline = 0; while (!is.eof()) { is.getline(line, LINE_SIZE); curline++; int n = strlen(line); if (!n) continue; for (int i=0; i<n; i++) line[i] = tolower(line[i]); if (line[0] == '#') continue; char *head = line; if (strspn(line, delim) == 0) { // have a leading ok/many tag to fetch char *cmd = strtok(line, delim); if (strcmp(cmd, MANY) == 0) list = BLACK; else if (strcmp(cmd, OK) == 0) list = WHITE; head = cmd + strlen(cmd) + 1; } char *cmd = strtok(head, delim); if (!cmd) continue; if (strcmp(cmd, "env_from") == 0) { char *from = next_token(delim); if (from) { string_map &fm = really_find_from_map(dc, name); fm[from] = list; } } else if (strcmp(cmd, "env_to") == 0) { char *to = next_token(delim); if (to) { dc.env_to_dnsbll[to] = list; dc.env_to_chkfrom[to] = list; } } else if (strcmp(cmd, "substitute") == 0) { char *tag = next_token(delim); if (tag && (strcmp(tag, "mail_host") == 0)) { char *from = next_token(delim); if (from) { string_map &fm = really_find_from_map(dc, name); fm[from] = list; } } } else if (strcmp(cmd, "include") == 0) { char *fn = next_token(delim); if (ok_to_include(dc, fn)) { load_conf_dcc(dc, name, fn); } } } is.close(); } static void load_conf(CONFIG &dc, char *fn); static void load_conf(CONFIG &dc, char *fn) { ifstream is(fn); if (is.fail()) { char buf[1000]; snprintf(buf, sizeof(buf), "include file %s not found", fn); my_syslog(buf); return; } dc.config_files.push_back(fn); map<char*, int, ltstr> commands; enum {dummy, tld, content, ignore, hostlimit, hostslimit, htmllimit, htmltag, dnsbl, dnsbll, envfrom, envto, include, includedcc}; commands["tld" ] = tld; commands["content" ] = content; commands["ignore" ] = ignore; commands["host_limit" ] = hostlimit; commands["host_soft_limit"] = hostslimit; commands["html_limit" ] = htmllimit; commands["html_tag" ] = htmltag; commands["dnsbl" ] = dnsbl; commands["dnsbl_list" ] = dnsbll; commands["env_from" ] = envfrom; commands["env_to" ] = envto; commands["include" ] = include; commands["include_dcc" ] = includedcc; const int LINE_SIZE = 2000; char line[LINE_SIZE]; char orig[LINE_SIZE]; char *delim = " \t"; int curline = 0; while (!is.eof()) { is.getline(line, LINE_SIZE); snprintf(orig, sizeof(orig), "%s", line); curline++; int n = strlen(line); for (int i=0; i<n; i++) line[i] = tolower(line[i]); char *cmd = strtok(line, delim); if (cmd && (cmd[0] != '#') && (cmd[0] != '\0')) { // have a decent command bool processed = false; switch (commands[cmd]) { case tld: { char *tld = next_token(delim); if (!tld) break; // no tld value dc.tlds.insert(tld); processed = true; } break; case content: { char *suff = strtok(NULL, delim); if (!suff) break; // no dns suffix char *msg = suff + strlen(suff); if ((msg - line) >= strlen(orig)) break; // line ended with the dns suffix msg = strchr(msg+1, '\''); if (!msg) break; // no reply message template msg++; // move over the leading ' if ((msg - line) >= strlen(orig)) break; // line ended with the leading quote char *last = strchr(msg, '\''); if (!last) break; // no trailing quote *last = '\0'; // make it a null terminator dc.content_suffix = register_string(suff); dc.content_message = register_string(msg); processed = true; } break; case ignore: { char *host = next_token(delim); if (!host) break; dc.content_host_ignore.insert(host); processed = true; } break; case hostlimit: { char *limit = strtok(NULL, delim); if (!limit) break; // no integer limit char *msg = limit + strlen(limit); if ((msg - line) >= strlen(orig)) break; // line ended with the limit msg = strchr(msg+1, '\''); if (!msg) break; // no reply message template msg++; // move over the leading ' if ((msg - line) >= strlen(orig)) break; // line ended with the leading quote char *last = strchr(msg, '\''); if (!last) break; // no trailing quote *last = '\0'; // make it a null terminator dc.host_limit = atoi(limit); dc.host_limit_message = register_string(msg); dc.host_random = false; processed = true; } break; case hostslimit: { char *limit = next_token(delim); if (!limit) break; // no integer limit dc.host_limit = atoi(limit); dc.host_random = true; processed = true; } break; case htmllimit: { char *limit = strtok(NULL, delim); if (!limit) break; // no integer limit char *msg = limit + strlen(limit); if ((msg - line) >= strlen(orig)) break; // line ended with the limit msg = strchr(msg+1, '\''); if (!msg) break; // no reply message template msg++; // move over the leading ' if ((msg - line) >= strlen(orig)) break; // line ended with the leading quote char *last = strchr(msg, '\''); if (!last) break; // no trailing quote *last = '\0'; // make it a null terminator dc.tag_limit = atoi(limit); dc.tag_limit_message = register_string(msg); processed = true; } break; case htmltag: { char *tag = next_token(delim); if (!tag) break; // no html tag value dc.html_tags.insert(tag); // base version char buf[200]; snprintf(buf, sizeof(buf), "/%s", tag); dc.html_tags.insert(register_string(buf)); // leading / snprintf(buf, sizeof(buf), "%s/", tag); dc.html_tags.insert(register_string(buf)); // trailing / processed = true; } break; case dnsbl: { // have a new dnsbl to use char *name = next_token(delim); if (!name) break; // no name name if (find_dnsbl(dc, name)) break; // duplicate entry char *suff = strtok(NULL, delim); if (!suff) break; // no dns suffic char *msg = suff + strlen(suff); if ((msg - line) >= strlen(orig)) break; // line ended with the dns suffix msg = strchr(msg+1, '\''); if (!msg) break; // no reply message template msg++; // move over the leading ' if ((msg - line) >= strlen(orig)) break; // line ended with the leading quote char *last = strchr(msg, '\''); if (!last) break; // no trailing quote *last = '\0'; // make it a null terminator dc.dnsbls[name] = new DNSBL(register_string(suff), register_string(msg)); processed = true; } break; case dnsbll: { // define a new combination of dnsbls char *name = next_token(delim); if (!name) break; if (find_dnsbll(dc, name)) break; // duplicate entry char *list = next_token(delim); if (!list || (*list == '\0') || (*list == '#')) break; DNSBLLP d = new DNSBLL; DNSBLP p = find_dnsbl(dc, list); if (p) d->push_back(p); while (true) { list = next_token(delim); if (!list || (*list == '\0') || (*list == '#')) break; DNSBLP p = find_dnsbl(dc, list); if (p) d->push_back(p); } dc.dnsblls[name] = d; processed = true; } break; case envfrom: { // add an entry into the named string_map char *name = next_token(delim); if (!name) break; char *from = next_token(delim); if (!from) break; char *list = next_token(delim); if (!list) break; if ((strcmp(list, WHITE) == 0) || (strcmp(list, BLACK) == 0)) { string_map &fm = really_find_from_map(dc, name); fm[from] = list; processed = true; } else { // list may be the name of a previously defined from_map string_map *m = find_from_map(dc, list); if (m && (strcmp(list,name) != 0)) { string_map &pm = *m; string_map &fm = really_find_from_map(dc, name); fm.insert(pm.begin(), pm.end()); processed = true; } } } break; case envto: { // define the dnsbl_list and env_from maps to use for this recipient char *to = next_token(delim); if (!to) break; char *list = next_token(delim); if (!list) break; char *from = next_token(delim); if (!from) break; dc.env_to_dnsbll[to] = list; dc.env_to_chkfrom[to] = from; processed = true; } break; case include: { char *fn = next_token(delim); if (ok_to_include(dc, fn)) { load_conf(dc, fn); processed = true; } } break; case includedcc: { char *name = next_token(delim); if (!name) break; char *fn = next_token(delim); if (ok_to_include(dc, fn)) { load_conf_dcc(dc, name, fn); processed = true; } } break; default: { } break; } if (!processed) { pthread_mutex_lock(&syslog_mutex); openlog("dnsbl", LOG_PID, LOG_MAIL); syslog(LOG_ERR, "ignoring file %s line %d : %s\n", fn, curline, orig); closelog(); pthread_mutex_unlock(&syslog_mutex); } } } is.close(); } //////////////////////////////////////////////// // reload the config // static CONFIG* new_conf(); static CONFIG* new_conf() { CONFIG *newc = new CONFIG; pthread_mutex_lock(&config_mutex); newc->generation = generation++; pthread_mutex_unlock(&config_mutex); char buf[200]; snprintf(buf, sizeof(buf), "loading configuration generation %d", newc->generation); my_syslog(buf); load_conf(*newc, "dnsbl.conf"); newc->load_time = time(NULL); return newc; } //////////////////////////////////////////////// // thread to watch the old config files for changes // and reload when needed. we also cleanup old // configs whose reference count has gone to zero. // static void* config_loader(void *arg); static void* config_loader(void *arg) { typedef set<CONFIG *> configp_set; configp_set old_configs; while (loader_run) { sleep(180); // look for modifications every 3 minutes if (!loader_run) break; CONFIG &dc = *config; time_t then = dc.load_time; struct stat st; bool reload = false; for (string_list::iterator i=dc.config_files.begin(); i!=dc.config_files.end(); i++) { char *fn = *i; if (stat(fn, &st)) reload = true; // file disappeared else if (st.st_mtime > then) reload = true; // file modified if (reload) break; } if (reload) { CONFIG *newc = new_conf(); // replace the global config pointer pthread_mutex_lock(&config_mutex); CONFIG *old = config; config = newc; pthread_mutex_unlock(&config_mutex); if (old) old_configs.insert(old); } // now look for old configs with zero ref counts for (configp_set::iterator i=old_configs.begin(); i!=old_configs.end(); ) { CONFIG *old = *i; if (!old->reference_count) { char buf[200]; snprintf(buf, sizeof(buf), "freeing memory for old configuration generation %d", old->generation); my_syslog(buf); delete old; // destructor does all the work old_configs.erase(i++); } else i++; } } return NULL; } static void usage(char *prog); static void usage(char *prog) { fprintf(stderr, "Usage: %s [-d] [-c] -r port -p sm-sock-addr [-t timeout]\n", prog); fprintf(stderr, "where port is for the connection to our own dns resolver processes\n"); fprintf(stderr, " and should be local-domain-socket-file-name\n"); fprintf(stderr, "where sm-sock-addr is for the connection to sendmail\n"); fprintf(stderr, " and should be one of\n"); fprintf(stderr, " inet:port@ip-address\n"); fprintf(stderr, " local:local-domain-socket-file-name\n"); fprintf(stderr, "-c will load and dump the config to stdout\n"); fprintf(stderr, "-d will add some syslog debug messages\n"); } static void setup_socket(char *sock); static void setup_socket(char *sock) { unlink(sock); // sockaddr_un addr; // memset(&addr, '\0', sizeof addr); // addr.sun_family = AF_UNIX; // strncpy(addr.sun_path, sock, sizeof(addr.sun_path)-1); // int s = socket(AF_UNIX, SOCK_STREAM, 0); // bind(s, (sockaddr*)&addr, sizeof(addr)); // close(s); } /* * The signal handler function -- only gets called when a SIGCHLD * is received, ie when a child terminates */ void sig_chld(int signo) { int status; /* Wait for any child without blocking */ while (waitpid(-1, &status, WNOHANG) > 0) { // ignore child exit status, we only do this to cleanup zombies } } int main(int argc, char**argv) { bool check = false; bool setconn = false; bool setreso = false; int c; const char *args = "r:p:t:hcd"; extern char *optarg; // Process command line options while ((c = getopt(argc, argv, args)) != -1) { switch (c) { case 'r': if (optarg == NULL || *optarg == '\0') { fprintf(stderr, "Illegal resolver socket: %s\n", optarg); exit(EX_USAGE); } resolver_port = strdup(optarg); setup_socket(resolver_port); setreso = true; break; case 'p': if (optarg == NULL || *optarg == '\0') { fprintf(stderr, "Illegal sendmail socket: %s\n", optarg); exit(EX_USAGE); } if (smfi_setconn(optarg) == MI_FAILURE) { fprintf(stderr, "smfi_setconn failed\n"); exit(EX_SOFTWARE); } if (strncasecmp(optarg, "unix:", 5) == 0) setup_socket(optarg + 5); else if (strncasecmp(optarg, "local:", 6) == 0) setup_socket(optarg + 6); setconn = true; break; case 't': if (optarg == NULL || *optarg == '\0') { fprintf(stderr, "Illegal timeout: %s\n", optarg); exit(EX_USAGE); } if (smfi_settimeout(atoi(optarg)) == MI_FAILURE) { fprintf(stderr, "smfi_settimeout failed\n"); exit(EX_SOFTWARE); } break; case 'c': check = true; break; case 'd': debug_syslog = true; break; case 'h': default: usage(argv[0]); exit(EX_USAGE); } } if (check) { CONFIG &dc = *new_conf(); dumpit(dc); return 0; } if (!setconn) { fprintf(stderr, "%s: Missing required -p argument\n", argv[0]); usage(argv[0]); exit(EX_USAGE); } if (!setreso) { fprintf(stderr, "%s: Missing required -r argument\n", argv[0]); usage(argv[0]); exit(EX_USAGE); } if (smfi_register(smfilter) == MI_FAILURE) { fprintf(stderr, "smfi_register failed\n"); exit(EX_UNAVAILABLE); } // switch to background mode if (daemon(1,0) < 0) { fprintf(stderr, "daemon() call failed\n"); exit(EX_UNAVAILABLE); } // write the pid const char *pidpath = "/var/run/dnsbl.pid"; unlink(pidpath); FILE *f = fopen(pidpath, "w"); if (f) { #ifdef linux // from a comment in the DCC source code: // Linux threads are broken. Signals given the // original process are delivered to only the // thread that happens to have that PID. The // sendmail libmilter thread that needs to hear // SIGINT and other signals does not, and that breaks // scripts that need to stop milters. // However, signaling the process group works. fprintf(f, "-%d\n", (u_int)getpgrp()); #else fprintf(f, "%d\n", (u_int)getpid()); #endif fclose(f); } // initialize the thread sync objects pthread_mutex_init(&config_mutex, 0); pthread_mutex_init(&syslog_mutex, 0); pthread_mutex_init(&resolve_mutex, 0); pthread_mutex_init(&fd_pool_mutex, 0); // drop root privs struct passwd *pw = getpwnam("dnsbl"); if (pw) { if (setgid(pw->pw_gid) == -1) { my_syslog("failed to switch to group dnsbl"); } if (setuid(pw->pw_uid) == -1) { my_syslog("failed to switch to user dnsbl"); } } // fork off the resolver listener process pid_t child = fork(); if (child < 0) { my_syslog("failed to create resolver listener process"); exit(0); } if (child == 0) { // we are the child - dns resolver listener process resolver_socket = socket(AF_UNIX, SOCK_STREAM, 0); if (resolver_socket < 0) { my_syslog("child failed to create resolver socket"); exit(0); // failed } sockaddr_un server; memset(&server, '\0', sizeof(server)); server.sun_family = AF_UNIX; strncpy(server.sun_path, resolver_port, sizeof(server.sun_path)-1); //try to bind the address to the socket. if (bind(resolver_socket, (sockaddr *)&server, sizeof(server)) < 0) { // bind failed shutdown(resolver_socket, SHUT_RDWR); close(resolver_socket); my_syslog("child failed to bind resolver socket"); exit(0); // failed } //listen on the socket. if (listen(resolver_socket, 10) < 0) { // listen failed shutdown(resolver_socket, SHUT_RDWR); close(resolver_socket); my_syslog("child failed to listen to resolver socket"); exit(0); // failed } // setup sigchld handler to prevent zombies struct sigaction act; act.sa_handler = sig_chld; // Assign sig_chld as our SIGCHLD handler sigemptyset(&act.sa_mask); // We don't want to block any other signals in this example act.sa_flags = SA_NOCLDSTOP; // only want children that have terminated if (sigaction(SIGCHLD, &act, NULL) < 0) { my_syslog("child failed to setup SIGCHLD handler"); exit(0); // failed } while (true) { sockaddr_un client; socklen_t clientlen = sizeof(client); int s = accept(resolver_socket, (sockaddr *)&client, &clientlen); if (s > 0) { // accept worked, it did not get cancelled before we could accept it // fork off a process to handle this connection int newchild = fork(); if (newchild == 0) { // this is the worker process // child does not need the listening socket close(resolver_socket); //my_syslog("child forked a worker process"); process_resolver_requests(s); //my_syslog("child terminated a worker process"); exit(0); } else { // this is the parent // parent does not need the accepted socket close(s); } } } exit(0); // make sure we don't fall thru. } else { sleep(2); // allow child to get started } // load the initial config config = new_conf(); // only create threads after the fork() in daemon pthread_t tid; if (pthread_create(&tid, 0, config_loader, 0)) my_syslog("failed to create config loader thread"); if (pthread_detach(tid)) my_syslog("failed to detach config loader thread"); time_t starting = time(NULL); int rc = smfi_main(); if ((rc != MI_SUCCESS) && (time(NULL) > starting+5*60)) { my_syslog("trying to restart after smfi_main()"); loader_run = false; // eventually the config loader thread will terminate execvp(argv[0], argv); } exit((rc == MI_SUCCESS) ? 0 : EX_UNAVAILABLE); }