/* * Copyright (c) 1998-2005 Sendmail, Inc. and its suppliers. * All rights reserved. * Copyright (c) 1983, 1995-1997 Eric P. Allman. All rights reserved. * Copyright (c) 1988, 1993 * The Regents of the University of California. All rights reserved. * * By using this file, you agree to the terms and conditions set * forth in the LICENSE file which can be found at the top level of * the sendmail distribution. * */ #pragma ident "%Z%%M% %I% %E% SMI" #include #include SM_RCSID("@(#)$Id: queue.c,v 8.949 2005/07/21 00:58:33 ca Exp $") #include # define RELEASE_QUEUE (void) 0 # define ST_INODE(st) (st).st_ino # define sm_file_exists(errno) ((errno) == EEXIST) # if HASFLOCK && defined(O_EXLOCK) # define SM_OPEN_EXLOCK 1 # define TF_OPEN_FLAGS (O_CREAT|O_WRONLY|O_EXCL|O_EXLOCK) # else /* HASFLOCK && defined(O_EXLOCK) */ # define TF_OPEN_FLAGS (O_CREAT|O_WRONLY|O_EXCL) # endif /* HASFLOCK && defined(O_EXLOCK) */ #ifndef SM_OPEN_EXLOCK # define SM_OPEN_EXLOCK 0 #endif /* ! SM_OPEN_EXLOCK */ /* ** Historical notes: ** QF_VERSION == 4 was sendmail 8.10/8.11 without _FFR_QUEUEDELAY ** QF_VERSION == 5 was sendmail 8.10/8.11 with _FFR_QUEUEDELAY ** QF_VERSION == 6 was sendmail 8.12 without _FFR_QUEUEDELAY ** QF_VERSION == 7 was sendmail 8.12 with _FFR_QUEUEDELAY ** QF_VERSION == 8 is sendmail 8.13 */ #define QF_VERSION 8 /* version number of this queue format */ static char queue_letter __P((ENVELOPE *, int)); static bool quarantine_queue_item __P((int, int, ENVELOPE *, char *)); /* Naming convention: qgrp: index of queue group, qg: QUEUEGROUP */ /* ** Work queue. */ struct work { char *w_name; /* name of control file */ char *w_host; /* name of recipient host */ bool w_lock; /* is message locked? */ bool w_tooyoung; /* is it too young to run? */ long w_pri; /* priority of message, see below */ time_t w_ctime; /* creation time */ time_t w_mtime; /* modification time */ int w_qgrp; /* queue group located in */ int w_qdir; /* queue directory located in */ struct work *w_next; /* next in queue */ }; typedef struct work WORK; static WORK *WorkQ; /* queue of things to be done */ static int NumWorkGroups; /* number of work groups */ static time_t Current_LA_time = 0; /* Get new load average every 30 seconds. */ #define GET_NEW_LA_TIME 30 #define SM_GET_LA(now) \ do \ { \ now = curtime(); \ if (Current_LA_time < now - GET_NEW_LA_TIME) \ { \ sm_getla(); \ Current_LA_time = now; \ } \ } while (0) /* ** DoQueueRun indicates that a queue run is needed. ** Notice: DoQueueRun is modified in a signal handler! */ static bool volatile DoQueueRun; /* non-interrupt time queue run needed */ /* ** Work group definition structure. ** Each work group contains one or more queue groups. This is done ** to manage the number of queue group runners active at the same time ** to be within the constraints of MaxQueueChildren (if it is set). ** The number of queue groups that can be run on the next work run ** is kept track of. The queue groups are run in a round robin. */ struct workgrp { int wg_numqgrp; /* number of queue groups in work grp */ int wg_runners; /* total runners */ int wg_curqgrp; /* current queue group */ QUEUEGRP **wg_qgs; /* array of queue groups */ int wg_maxact; /* max # of active runners */ time_t wg_lowqintvl; /* lowest queue interval */ int wg_restart; /* needs restarting? */ int wg_restartcnt; /* count of times restarted */ }; typedef struct workgrp WORKGRP; static WORKGRP volatile WorkGrp[MAXWORKGROUPS + 1]; /* work groups */ #if SM_HEAP_CHECK static SM_DEBUG_T DebugLeakQ = SM_DEBUG_INITIALIZER("leak_q", "@(#)$Debug: leak_q - trace memory leaks during queue processing $"); #endif /* SM_HEAP_CHECK */ /* ** We use EmptyString instead of "" to avoid ** 'zero-length format string' warnings from gcc */ static const char EmptyString[] = ""; static void grow_wlist __P((int, int)); static int multiqueue_cache __P((char *, int, QUEUEGRP *, int, unsigned int *)); static int gatherq __P((int, int, bool, bool *, bool *)); static int sortq __P((int)); static void printctladdr __P((ADDRESS *, SM_FILE_T *)); static bool readqf __P((ENVELOPE *, bool)); static void restart_work_group __P((int)); static void runner_work __P((ENVELOPE *, int, bool, int, int)); static void schedule_queue_runs __P((bool, int, bool)); static char *strrev __P((char *)); static ADDRESS *setctluser __P((char *, int, ENVELOPE *)); #if _FFR_RHS static int sm_strshufflecmp __P((char *, char *)); static void init_shuffle_alphabet __P(()); #endif /* _FFR_RHS */ static int workcmpf0(); static int workcmpf1(); static int workcmpf2(); static int workcmpf3(); static int workcmpf4(); static int randi = 3; /* index for workcmpf5() */ static int workcmpf5(); static int workcmpf6(); #if _FFR_RHS static int workcmpf7(); #endif /* _FFR_RHS */ #if RANDOMSHIFT # define get_rand_mod(m) ((get_random() >> RANDOMSHIFT) % (m)) #else /* RANDOMSHIFT */ # define get_rand_mod(m) (get_random() % (m)) #endif /* RANDOMSHIFT */ /* ** File system definition. ** Used to keep track of how much free space is available ** on a file system in which one or more queue directories reside. */ typedef struct filesys_shared FILESYS; struct filesys_shared { dev_t fs_dev; /* unique device id */ long fs_avail; /* number of free blocks available */ long fs_blksize; /* block size, in bytes */ }; /* probably kept in shared memory */ static FILESYS FileSys[MAXFILESYS]; /* queue file systems */ static char *FSPath[MAXFILESYS]; /* pathnames for file systems */ #if SM_CONF_SHM /* ** Shared memory data ** ** Current layout: ** size -- size of shared memory segment ** pid -- pid of owner, should be a unique id to avoid misinterpretations ** by other processes. ** tag -- should be a unique id to avoid misinterpretations by others. ** idea: hash over configuration data that will be stored here. ** NumFileSys -- number of file systems. ** FileSys -- (arrary of) structure for used file systems. ** RSATmpCnt -- counter for number of uses of ephemeral RSA key. ** QShm -- (array of) structure for information about queue directories. */ /* ** Queue data in shared memory */ typedef struct queue_shared QUEUE_SHM_T; struct queue_shared { int qs_entries; /* number of entries */ /* XXX more to follow? */ }; static void *Pshm; /* pointer to shared memory */ static FILESYS *PtrFileSys; /* pointer to queue file system array */ int ShmId = SM_SHM_NO_ID; /* shared memory id */ static QUEUE_SHM_T *QShm; /* pointer to shared queue data */ static size_t shms; # define SHM_OFF_PID(p) (((char *) (p)) + sizeof(int)) # define SHM_OFF_TAG(p) (((char *) (p)) + sizeof(pid_t) + sizeof(int)) # define SHM_OFF_HEAD (sizeof(pid_t) + sizeof(int) * 2) /* how to access FileSys */ # define FILE_SYS(i) (PtrFileSys[i]) /* first entry is a tag, for now just the size */ # define OFF_FILE_SYS(p) (((char *) (p)) + SHM_OFF_HEAD) /* offset for PNumFileSys */ # define OFF_NUM_FILE_SYS(p) (((char *) (p)) + SHM_OFF_HEAD + sizeof(FileSys)) /* offset for PRSATmpCnt */ # define OFF_RSA_TMP_CNT(p) (((char *) (p)) + SHM_OFF_HEAD + sizeof(FileSys) + sizeof(int)) int *PRSATmpCnt; /* offset for queue_shm */ # define OFF_QUEUE_SHM(p) (((char *) (p)) + SHM_OFF_HEAD + sizeof(FileSys) + sizeof(int) * 2) # define QSHM_ENTRIES(i) QShm[i].qs_entries /* basic size of shared memory segment */ # define SM_T_SIZE (SHM_OFF_HEAD + sizeof(FileSys) + sizeof(int) * 2) static unsigned int hash_q __P((char *, unsigned int)); /* ** HASH_Q -- simple hash function ** ** Parameters: ** p -- string to hash. ** h -- hash start value (from previous run). ** ** Returns: ** hash value. */ static unsigned int hash_q(p, h) char *p; unsigned int h; { int c, d; while (*p != '\0') { d = *p++; c = d; c ^= c<<6; h += (c<<11) ^ (c>>1); h ^= (d<<14) + (d<<7) + (d<<4) + d; } return h; } #else /* SM_CONF_SHM */ # define FILE_SYS(i) FileSys[i] #endif /* SM_CONF_SHM */ /* access to the various components of file system data */ #define FILE_SYS_NAME(i) FSPath[i] #define FILE_SYS_AVAIL(i) FILE_SYS(i).fs_avail #define FILE_SYS_BLKSIZE(i) FILE_SYS(i).fs_blksize #define FILE_SYS_DEV(i) FILE_SYS(i).fs_dev /* ** Current qf file field assignments: ** ** A AUTH= parameter ** B body type ** C controlling user ** D data file name ** d data file directory name (added in 8.12) ** E error recipient ** F flag bits ** G free (was: queue delay algorithm if _FFR_QUEUEDELAY) ** H header ** I data file's inode number ** K time of last delivery attempt ** L Solaris Content-Length: header (obsolete) ** M message ** N number of delivery attempts ** P message priority ** q quarantine reason ** Q original recipient (ORCPT=) ** r final recipient (Final-Recipient: DSN field) ** R recipient ** S sender ** T init time ** V queue file version ** X free (was: character set if _FFR_SAVE_CHARSET) ** Y free (was: current delay if _FFR_QUEUEDELAY) ** Z original envelope id from ESMTP ** ! deliver by (added in 8.12) ** $ define macro ** . terminate file */ /* ** QUEUEUP -- queue a message up for future transmission. ** ** Parameters: ** e -- the envelope to queue up. ** announce -- if true, tell when you are queueing up. ** msync -- if true, then fsync() if SuperSafe interactive mode. ** ** Returns: ** none. ** ** Side Effects: ** The current request is saved in a control file. ** The queue file is left locked. */ void queueup(e, announce, msync) register ENVELOPE *e; bool announce; bool msync; { register SM_FILE_T *tfp; register HDR *h; register ADDRESS *q; int tfd = -1; int i; bool newid; register char *p; MAILER nullmailer; MCI mcibuf; char qf[MAXPATHLEN]; char tf[MAXPATHLEN]; char df[MAXPATHLEN]; char buf[MAXLINE]; /* ** Create control file. */ #define OPEN_TF do \ { \ MODE_T oldumask = 0; \ \ if (bitset(S_IWGRP, QueueFileMode)) \ oldumask = umask(002); \ tfd = open(tf, TF_OPEN_FLAGS, QueueFileMode); \ if (bitset(S_IWGRP, QueueFileMode)) \ (void) umask(oldumask); \ } while (0) newid = (e->e_id == NULL) || !bitset(EF_INQUEUE, e->e_flags); (void) sm_strlcpy(tf, queuename(e, NEWQFL_LETTER), sizeof tf); tfp = e->e_lockfp; if (tfp == NULL && newid) { /* ** open qf file directly: this will give an error if the file ** already exists and hence prevent problems if a queue-id ** is reused (e.g., because the clock is set back). */ (void) sm_strlcpy(tf, queuename(e, ANYQFL_LETTER), sizeof tf); OPEN_TF; if (tfd < 0 || #if !SM_OPEN_EXLOCK !lockfile(tfd, tf, NULL, LOCK_EX|LOCK_NB) || #endif /* !SM_OPEN_EXLOCK */ (tfp = sm_io_open(SmFtStdiofd, SM_TIME_DEFAULT, (void *) &tfd, SM_IO_WRONLY, NULL)) == NULL) { int save_errno = errno; printopenfds(true); errno = save_errno; syserr("!queueup: cannot create queue file %s, euid=%d, fd=%d, fp=%p", tf, (int) geteuid(), tfd, tfp); /* NOTREACHED */ } e->e_lockfp = tfp; upd_qs(e, 1, 0, "queueup"); } /* if newid, write the queue file directly (instead of temp file) */ if (!newid) { /* get a locked tf file */ for (i = 0; i < 128; i++) { if (tfd < 0) { OPEN_TF; if (tfd < 0) { if (errno != EEXIST) break; if (LogLevel > 0 && (i % 32) == 0) sm_syslog(LOG_ALERT, e->e_id, "queueup: cannot create %s, uid=%d: %s", tf, (int) geteuid(), sm_errstring(errno)); } #if SM_OPEN_EXLOCK else break; #endif /* SM_OPEN_EXLOCK */ } if (tfd >= 0) { #if SM_OPEN_EXLOCK /* file is locked by open() */ break; #else /* SM_OPEN_EXLOCK */ if (lockfile(tfd, tf, NULL, LOCK_EX|LOCK_NB)) break; else #endif /* SM_OPEN_EXLOCK */ if (LogLevel > 0 && (i % 32) == 0) sm_syslog(LOG_ALERT, e->e_id, "queueup: cannot lock %s: %s", tf, sm_errstring(errno)); if ((i % 32) == 31) { (void) close(tfd); tfd = -1; } } if ((i % 32) == 31) { /* save the old temp file away */ (void) rename(tf, queuename(e, TEMPQF_LETTER)); } else (void) sleep(i % 32); } if (tfd < 0 || (tfp = sm_io_open(SmFtStdiofd, SM_TIME_DEFAULT, (void *) &tfd, SM_IO_WRONLY_B, NULL)) == NULL) { int save_errno = errno; printopenfds(true); errno = save_errno; syserr("!queueup: cannot create queue temp file %s, uid=%d", tf, (int) geteuid()); } } if (tTd(40, 1)) sm_dprintf("\n>>>>> queueing %s/%s%s >>>>>\n", qid_printqueue(e->e_qgrp, e->e_qdir), queuename(e, ANYQFL_LETTER), newid ? " (new id)" : ""); if (tTd(40, 3)) { sm_dprintf(" e_flags="); printenvflags(e); } if (tTd(40, 32)) { sm_dprintf(" sendq="); printaddr(sm_debug_file(), e->e_sendqueue, true); } if (tTd(40, 9)) { sm_dprintf(" tfp="); dumpfd(sm_io_getinfo(tfp, SM_IO_WHAT_FD, NULL), true, false); sm_dprintf(" lockfp="); if (e->e_lockfp == NULL) sm_dprintf("NULL\n"); else dumpfd(sm_io_getinfo(e->e_lockfp, SM_IO_WHAT_FD, NULL), true, false); } /* ** If there is no data file yet, create one. */ (void) sm_strlcpy(df, queuename(e, DATAFL_LETTER), sizeof df); if (bitset(EF_HAS_DF, e->e_flags)) { if (e->e_dfp != NULL && SuperSafe != SAFE_REALLY && SuperSafe != SAFE_REALLY_POSTMILTER && sm_io_setinfo(e->e_dfp, SM_BF_COMMIT, NULL) < 0 && errno != EINVAL) { syserr("!queueup: cannot commit data file %s, uid=%d", queuename(e, DATAFL_LETTER), (int) geteuid()); } if (e->e_dfp != NULL && SuperSafe == SAFE_INTERACTIVE && msync) { if (tTd(40,32)) sm_syslog(LOG_INFO, e->e_id, "queueup: fsync(e->e_dfp)"); if (fsync(sm_io_getinfo(e->e_dfp, SM_IO_WHAT_FD, NULL)) < 0) { if (newid) syserr("!552 Error writing data file %s", df); else syserr("!452 Error writing data file %s", df); } } } else { int dfd; MODE_T oldumask = 0; register SM_FILE_T *dfp = NULL; struct stat stbuf; if (e->e_dfp != NULL && sm_io_getinfo(e->e_dfp, SM_IO_WHAT_ISTYPE, BF_FILE_TYPE)) syserr("committing over bf file"); if (bitset(S_IWGRP, QueueFileMode)) oldumask = umask(002); dfd = open(df, O_WRONLY|O_CREAT|O_TRUNC|QF_O_EXTRA, QueueFileMode); if (bitset(S_IWGRP, QueueFileMode)) (void) umask(oldumask); if (dfd < 0 || (dfp = sm_io_open(SmFtStdiofd, SM_TIME_DEFAULT, (void *) &dfd, SM_IO_WRONLY_B, NULL)) == NULL) syserr("!queueup: cannot create data temp file %s, uid=%d", df, (int) geteuid()); if (fstat(dfd, &stbuf) < 0) e->e_dfino = -1; else { e->e_dfdev = stbuf.st_dev; e->e_dfino = ST_INODE(stbuf); } e->e_flags |= EF_HAS_DF; memset(&mcibuf, '\0', sizeof mcibuf); mcibuf.mci_out = dfp; mcibuf.mci_mailer = FileMailer; (*e->e_putbody)(&mcibuf, e, NULL); if (SuperSafe == SAFE_REALLY || SuperSafe == SAFE_REALLY_POSTMILTER || (SuperSafe == SAFE_INTERACTIVE && msync)) { if (tTd(40,32)) sm_syslog(LOG_INFO, e->e_id, "queueup: fsync(dfp)"); if (fsync(sm_io_getinfo(dfp, SM_IO_WHAT_FD, NULL)) < 0) { if (newid) syserr("!552 Error writing data file %s", df); else syserr("!452 Error writing data file %s", df); } } if (sm_io_close(dfp, SM_TIME_DEFAULT) < 0) syserr("!queueup: cannot save data temp file %s, uid=%d", df, (int) geteuid()); e->e_putbody = putbody; } /* ** Output future work requests. ** Priority and creation time should be first, since ** they are required by gatherq. */ /* output queue version number (must be first!) */ (void) sm_io_fprintf(tfp, SM_TIME_DEFAULT, "V%d\n", QF_VERSION); /* output creation time */ (void) sm_io_fprintf(tfp, SM_TIME_DEFAULT, "T%ld\n", (long) e->e_ctime); /* output last delivery time */ (void) sm_io_fprintf(tfp, SM_TIME_DEFAULT, "K%ld\n", (long) e->e_dtime); /* output number of delivery attempts */ (void) sm_io_fprintf(tfp, SM_TIME_DEFAULT, "N%d\n", e->e_ntries); /* output message priority */ (void) sm_io_fprintf(tfp, SM_TIME_DEFAULT, "P%ld\n", e->e_msgpriority); /* ** If data file is in a different directory than the queue file, ** output a "d" record naming the directory of the data file. */ if (e->e_dfqgrp != e->e_qgrp) { (void) sm_io_fprintf(tfp, SM_TIME_DEFAULT, "d%s\n", Queue[e->e_dfqgrp]->qg_qpaths[e->e_dfqdir].qp_name); } /* output inode number of data file */ /* XXX should probably include device major/minor too */ if (e->e_dfino != -1) { (void) sm_io_fprintf(tfp, SM_TIME_DEFAULT, "I%ld/%ld/%llu\n", (long) major(e->e_dfdev), (long) minor(e->e_dfdev), (ULONGLONG_T) e->e_dfino); } /* output body type */ if (e->e_bodytype != NULL) (void) sm_io_fprintf(tfp, SM_TIME_DEFAULT, "B%s\n", denlstring(e->e_bodytype, true, false)); /* quarantine reason */ if (e->e_quarmsg != NULL) (void) sm_io_fprintf(tfp, SM_TIME_DEFAULT, "q%s\n", denlstring(e->e_quarmsg, true, false)); /* message from envelope, if it exists */ if (e->e_message != NULL) (void) sm_io_fprintf(tfp, SM_TIME_DEFAULT, "M%s\n", denlstring(e->e_message, true, false)); /* send various flag bits through */ p = buf; if (bitset(EF_WARNING, e->e_flags)) *p++ = 'w'; if (bitset(EF_RESPONSE, e->e_flags)) *p++ = 'r'; if (bitset(EF_HAS8BIT, e->e_flags)) *p++ = '8'; if (bitset(EF_DELETE_BCC, e->e_flags)) *p++ = 'b'; if (bitset(EF_RET_PARAM, e->e_flags)) *p++ = 'd'; if (bitset(EF_NO_BODY_RETN, e->e_flags)) *p++ = 'n'; if (bitset(EF_SPLIT, e->e_flags)) *p++ = 's'; *p++ = '\0'; if (buf[0] != '\0') (void) sm_io_fprintf(tfp, SM_TIME_DEFAULT, "F%s\n", buf); /* save $={persistentMacros} macro values */ queueup_macros(macid("{persistentMacros}"), tfp, e); /* output name of sender */ if (bitnset(M_UDBENVELOPE, e->e_from.q_mailer->m_flags)) p = e->e_sender; else p = e->e_from.q_paddr; (void) sm_io_fprintf(tfp, SM_TIME_DEFAULT, "S%s\n", denlstring(p, true, false)); /* output ESMTP-supplied "original" information */ if (e->e_envid != NULL) (void) sm_io_fprintf(tfp, SM_TIME_DEFAULT, "Z%s\n", denlstring(e->e_envid, true, false)); /* output AUTH= parameter */ if (e->e_auth_param != NULL) (void) sm_io_fprintf(tfp, SM_TIME_DEFAULT, "A%s\n", denlstring(e->e_auth_param, true, false)); if (e->e_dlvr_flag != 0) (void) sm_io_fprintf(tfp, SM_TIME_DEFAULT, "!%c %ld\n", (char) e->e_dlvr_flag, e->e_deliver_by); /* output list of recipient addresses */ printctladdr(NULL, NULL); for (q = e->e_sendqueue; q != NULL; q = q->q_next) { if (!QS_IS_UNDELIVERED(q->q_state)) continue; /* message for this recipient, if it exists */ if (q->q_message != NULL) (void) sm_io_fprintf(tfp, SM_TIME_DEFAULT, "M%s\n", denlstring(q->q_message, true, false)); printctladdr(q, tfp); if (q->q_orcpt != NULL) (void) sm_io_fprintf(tfp, SM_TIME_DEFAULT, "Q%s\n", denlstring(q->q_orcpt, true, false)); if (q->q_finalrcpt != NULL) (void) sm_io_fprintf(tfp, SM_TIME_DEFAULT, "r%s\n", denlstring(q->q_finalrcpt, true, false)); (void) sm_io_putc(tfp, SM_TIME_DEFAULT, 'R'); if (bitset(QPRIMARY, q->q_flags)) (void) sm_io_putc(tfp, SM_TIME_DEFAULT, 'P'); if (bitset(QHASNOTIFY, q->q_flags)) (void) sm_io_putc(tfp, SM_TIME_DEFAULT, 'N'); if (bitset(QPINGONSUCCESS, q->q_flags)) (void) sm_io_putc(tfp, SM_TIME_DEFAULT, 'S'); if (bitset(QPINGONFAILURE, q->q_flags)) (void) sm_io_putc(tfp, SM_TIME_DEFAULT, 'F'); if (bitset(QPINGONDELAY, q->q_flags)) (void) sm_io_putc(tfp, SM_TIME_DEFAULT, 'D'); if (q->q_alias != NULL && bitset(QALIAS, q->q_alias->q_flags)) (void) sm_io_putc(tfp, SM_TIME_DEFAULT, 'A'); (void) sm_io_putc(tfp, SM_TIME_DEFAULT, ':'); (void) sm_io_fprintf(tfp, SM_TIME_DEFAULT, "%s\n", denlstring(q->q_paddr, true, false)); if (announce) { char *tag = "queued"; if (e->e_quarmsg != NULL) tag = "quarantined"; e->e_to = q->q_paddr; message(tag); if (LogLevel > 8) logdelivery(q->q_mailer, NULL, q->q_status, tag, NULL, (time_t) 0, e); e->e_to = NULL; } if (tTd(40, 1)) { sm_dprintf("queueing "); printaddr(sm_debug_file(), q, false); } } /* ** Output headers for this message. ** Expand macros completely here. Queue run will deal with ** everything as absolute headers. ** All headers that must be relative to the recipient ** can be cracked later. ** We set up a "null mailer" -- i.e., a mailer that will have ** no effect on the addresses as they are output. */ memset((char *) &nullmailer, '\0', sizeof nullmailer); nullmailer.m_re_rwset = nullmailer.m_rh_rwset = nullmailer.m_se_rwset = nullmailer.m_sh_rwset = -1; nullmailer.m_eol = "\n"; memset(&mcibuf, '\0', sizeof mcibuf); mcibuf.mci_mailer = &nullmailer; mcibuf.mci_out = tfp; macdefine(&e->e_macro, A_PERM, 'g', "\201f"); for (h = e->e_header; h != NULL; h = h->h_link) { if (h->h_value == NULL) continue; /* don't output resent headers on non-resent messages */ if (bitset(H_RESENT, h->h_flags) && !bitset(EF_RESENT, e->e_flags)) continue; /* expand macros; if null, don't output header at all */ if (bitset(H_DEFAULT, h->h_flags)) { (void) expand(h->h_value, buf, sizeof buf, e); if (buf[0] == '\0') continue; } /* output this header */ (void) sm_io_fprintf(tfp, SM_TIME_DEFAULT, "H?"); /* output conditional macro if present */ if (h->h_macro != '\0') { if (bitset(0200, h->h_macro)) (void) sm_io_fprintf(tfp, SM_TIME_DEFAULT, "${%s}", macname(bitidx(h->h_macro))); else (void) sm_io_fprintf(tfp, SM_TIME_DEFAULT, "$%c", h->h_macro); } else if (!bitzerop(h->h_mflags) && bitset(H_CHECK|H_ACHECK, h->h_flags)) { int j; /* if conditional, output the set of conditions */ for (j = '\0'; j <= '\177'; j++) if (bitnset(j, h->h_mflags)) (void) sm_io_putc(tfp, SM_TIME_DEFAULT, j); } (void) sm_io_putc(tfp, SM_TIME_DEFAULT, '?'); /* output the header: expand macros, convert addresses */ if (bitset(H_DEFAULT, h->h_flags) && !bitset(H_BINDLATE, h->h_flags)) { (void) sm_io_fprintf(tfp, SM_TIME_DEFAULT, "%s: %s\n", h->h_field, denlstring(buf, false, true)); } else if (bitset(H_FROM|H_RCPT, h->h_flags) && !bitset(H_BINDLATE, h->h_flags)) { bool oldstyle = bitset(EF_OLDSTYLE, e->e_flags); SM_FILE_T *savetrace = TrafficLogFile; TrafficLogFile = NULL; if (bitset(H_FROM, h->h_flags)) oldstyle = false; commaize(h, h->h_value, oldstyle, &mcibuf, e); TrafficLogFile = savetrace; } else { (void) sm_io_fprintf(tfp, SM_TIME_DEFAULT, "%s: %s\n", h->h_field, denlstring(h->h_value, false, true)); } } /* ** Clean up. ** ** Write a terminator record -- this is to prevent ** scurrilous crackers from appending any data. */ (void) sm_io_fprintf(tfp, SM_TIME_DEFAULT, ".\n"); if (sm_io_flush(tfp, SM_TIME_DEFAULT) != 0 || ((SuperSafe == SAFE_REALLY || SuperSafe == SAFE_REALLY_POSTMILTER || (SuperSafe == SAFE_INTERACTIVE && msync)) && fsync(sm_io_getinfo(tfp, SM_IO_WHAT_FD, NULL)) < 0) || sm_io_error(tfp)) { if (newid) syserr("!552 Error writing control file %s", tf); else syserr("!452 Error writing control file %s", tf); } if (!newid) { char new = queue_letter(e, ANYQFL_LETTER); /* rename (locked) tf to be (locked) [qh]f */ (void) sm_strlcpy(qf, queuename(e, ANYQFL_LETTER), sizeof qf); if (rename(tf, qf) < 0) syserr("cannot rename(%s, %s), uid=%d", tf, qf, (int) geteuid()); else { /* ** Check if type has changed and only ** remove the old item if the rename above ** succeeded. */ if (e->e_qfletter != '\0' && e->e_qfletter != new) { if (tTd(40, 5)) { sm_dprintf("type changed from %c to %c\n", e->e_qfletter, new); } if (unlink(queuename(e, e->e_qfletter)) < 0) { /* XXX: something more drastic? */ if (LogLevel > 0) sm_syslog(LOG_ERR, e->e_id, "queueup: unlink(%s) failed: %s", queuename(e, e->e_qfletter), sm_errstring(errno)); } } } e->e_qfletter = new; /* ** fsync() after renaming to make sure metadata is ** written to disk on filesystems in which renames are ** not guaranteed. */ if (SuperSafe != SAFE_NO) { /* for softupdates */ if (tfd >= 0 && fsync(tfd) < 0) { syserr("!queueup: cannot fsync queue temp file %s", tf); } SYNC_DIR(qf, true); } /* close and unlock old (locked) queue file */ if (e->e_lockfp != NULL) (void) sm_io_close(e->e_lockfp, SM_TIME_DEFAULT); e->e_lockfp = tfp; /* save log info */ if (LogLevel > 79) sm_syslog(LOG_DEBUG, e->e_id, "queueup %s", qf); } else { /* save log info */ if (LogLevel > 79) sm_syslog(LOG_DEBUG, e->e_id, "queueup %s", tf); e->e_qfletter = queue_letter(e, ANYQFL_LETTER); } errno = 0; e->e_flags |= EF_INQUEUE; if (tTd(40, 1)) sm_dprintf("<<<<< done queueing %s <<<<<\n\n", e->e_id); return; } /* ** PRINTCTLADDR -- print control address to file. ** ** Parameters: ** a -- address. ** tfp -- file pointer. ** ** Returns: ** none. ** ** Side Effects: ** The control address (if changed) is printed to the file. ** The last control address and uid are saved. */ static void printctladdr(a, tfp) register ADDRESS *a; SM_FILE_T *tfp; { char *user; register ADDRESS *q; uid_t uid; gid_t gid; static ADDRESS *lastctladdr = NULL; static uid_t lastuid; /* initialization */ if (a == NULL || a->q_alias == NULL || tfp == NULL) { if (lastctladdr != NULL && tfp != NULL) (void) sm_io_fprintf(tfp, SM_TIME_DEFAULT, "C\n"); lastctladdr = NULL; lastuid = 0; return; } /* find the active uid */ q = getctladdr(a); if (q == NULL) { user = NULL; uid = 0; gid = 0; } else { user = q->q_ruser != NULL ? q->q_ruser : q->q_user; uid = q->q_uid; gid = q->q_gid; } a = a->q_alias; /* check to see if this is the same as last time */ if (lastctladdr != NULL && uid == lastuid && strcmp(lastctladdr->q_paddr, a->q_paddr) == 0) return; lastuid = uid; lastctladdr = a; if (uid == 0 || user == NULL || user[0] == '\0') (void) sm_io_fprintf(tfp, SM_TIME_DEFAULT, "C"); else (void) sm_io_fprintf(tfp, SM_TIME_DEFAULT, "C%s:%ld:%ld", denlstring(user, true, false), (long) uid, (long) gid); (void) sm_io_fprintf(tfp, SM_TIME_DEFAULT, ":%s\n", denlstring(a->q_paddr, true, false)); } /* ** RUNNERS_SIGTERM -- propagate a SIGTERM to queue runner process ** ** This propagates the signal to the child processes that are queue ** runners. This is for a queue runner "cleanup". After all of the ** child queue runner processes are signaled (it should be SIGTERM ** being the sig) then the old signal handler (Oldsh) is called ** to handle any cleanup set for this process (provided it is not ** SIG_DFL or SIG_IGN). The signal may not be handled immediately ** if the BlockOldsh flag is set. If the current process doesn't ** have a parent then handle the signal immediately, regardless of ** BlockOldsh. ** ** Parameters: ** sig -- the signal number being sent ** ** Returns: ** none. ** ** Side Effects: ** Sets the NoMoreRunners boolean to true to stop more runners ** from being started in runqueue(). ** ** NOTE: THIS CAN BE CALLED FROM A SIGNAL HANDLER. DO NOT ADD ** ANYTHING TO THIS ROUTINE UNLESS YOU KNOW WHAT YOU ARE ** DOING. */ static bool volatile NoMoreRunners = false; static sigfunc_t Oldsh_term = SIG_DFL; static sigfunc_t Oldsh_hup = SIG_DFL; static sigfunc_t volatile Oldsh = SIG_DFL; static bool BlockOldsh = false; static int volatile Oldsig = 0; static SIGFUNC_DECL runners_sigterm __P((int)); static SIGFUNC_DECL runners_sighup __P((int)); static SIGFUNC_DECL runners_sigterm(sig) int sig; { int save_errno = errno; FIX_SYSV_SIGNAL(sig, runners_sigterm); errno = save_errno; CHECK_CRITICAL(sig); NoMoreRunners = true; Oldsh = Oldsh_term; Oldsig = sig; proc_list_signal(PROC_QUEUE, sig); if (!BlockOldsh || getppid() <= 1) { /* Check that a valid 'old signal handler' is callable */ if (Oldsh_term != SIG_DFL && Oldsh_term != SIG_IGN && Oldsh_term != runners_sigterm) (*Oldsh_term)(sig); } errno = save_errno; return SIGFUNC_RETURN; } /* ** RUNNERS_SIGHUP -- propagate a SIGHUP to queue runner process ** ** This propagates the signal to the child processes that are queue ** runners. This is for a queue runner "cleanup". After all of the ** child queue runner processes are signaled (it should be SIGHUP ** being the sig) then the old signal handler (Oldsh) is called to ** handle any cleanup set for this process (provided it is not SIG_DFL ** or SIG_IGN). The signal may not be handled immediately if the ** BlockOldsh flag is set. If the current process doesn't have ** a parent then handle the signal immediately, regardless of ** BlockOldsh. ** ** Parameters: ** sig -- the signal number being sent ** ** Returns: ** none. ** ** Side Effects: ** Sets the NoMoreRunners boolean to true to stop more runners ** from being started in runqueue(). ** ** NOTE: THIS CAN BE CALLED FROM A SIGNAL HANDLER. DO NOT ADD ** ANYTHING TO THIS ROUTINE UNLESS YOU KNOW WHAT YOU ARE ** DOING. */ static SIGFUNC_DECL runners_sighup(sig) int sig; { int save_errno = errno; FIX_SYSV_SIGNAL(sig, runners_sighup); errno = save_errno; CHECK_CRITICAL(sig); NoMoreRunners = true; Oldsh = Oldsh_hup; Oldsig = sig; proc_list_signal(PROC_QUEUE, sig); if (!BlockOldsh || getppid() <= 1) { /* Check that a valid 'old signal handler' is callable */ if (Oldsh_hup != SIG_DFL && Oldsh_hup != SIG_IGN && Oldsh_hup != runners_sighup) (*Oldsh_hup)(sig); } errno = save_errno; return SIGFUNC_RETURN; } /* ** MARK_WORK_GROUP_RESTART -- mark a work group as needing a restart ** ** Sets a workgroup for restarting. ** ** Parameters: ** wgrp -- the work group id to restart. ** reason -- why (signal?), -1 to turn off restart ** ** Returns: ** none. ** ** Side effects: ** May set global RestartWorkGroup to true. ** ** NOTE: THIS CAN BE CALLED FROM A SIGNAL HANDLER. DO NOT ADD ** ANYTHING TO THIS ROUTINE UNLESS YOU KNOW WHAT YOU ARE ** DOING. */ void mark_work_group_restart(wgrp, reason) int wgrp; int reason; { if (wgrp < 0 || wgrp > NumWorkGroups) return; WorkGrp[wgrp].wg_restart = reason; if (reason >= 0) RestartWorkGroup = true; } /* ** RESTART_MARKED_WORK_GROUPS -- restart work groups marked as needing restart ** ** Restart any workgroup marked as needing a restart provided more ** runners are allowed. ** ** Parameters: ** none. ** ** Returns: ** none. ** ** Side effects: ** Sets global RestartWorkGroup to false. */ void restart_marked_work_groups() { int i; int wasblocked; if (NoMoreRunners) return; /* Block SIGCHLD so reapchild() doesn't mess with us */ wasblocked = sm_blocksignal(SIGCHLD); for (i = 0; i < NumWorkGroups; i++) { if (WorkGrp[i].wg_restart >= 0) { if (LogLevel > 8) sm_syslog(LOG_ERR, NOQID, "restart queue runner=%d due to signal 0x%x", i, WorkGrp[i].wg_restart); restart_work_group(i); } } RestartWorkGroup = false; if (wasblocked == 0) (void) sm_releasesignal(SIGCHLD); } /* ** RESTART_WORK_GROUP -- restart a specific work group ** ** Restart a specific workgroup provided more runners are allowed. ** If the requested work group has been restarted too many times log ** this and refuse to restart. ** ** Parameters: ** wgrp -- the work group id to restart ** ** Returns: ** none. ** ** Side Effects: ** starts another process doing the work of wgrp */ #define MAX_PERSIST_RESTART 10 /* max allowed number of restarts */ static void restart_work_group(wgrp) int wgrp; { if (NoMoreRunners || wgrp < 0 || wgrp > NumWorkGroups) return; WorkGrp[wgrp].wg_restart = -1; if (WorkGrp[wgrp].wg_restartcnt < MAX_PERSIST_RESTART) { /* avoid overflow; increment here */ WorkGrp[wgrp].wg_restartcnt++; (void) run_work_group(wgrp, RWG_FORK|RWG_PERSISTENT|RWG_RUNALL); } else { sm_syslog(LOG_ERR, NOQID, "ERROR: persistent queue runner=%d restarted too many times, queue runner lost", wgrp); } } /* ** SCHEDULE_QUEUE_RUNS -- schedule the next queue run for a work group. ** ** Parameters: ** runall -- schedule even if individual bit is not set. ** wgrp -- the work group id to schedule. ** didit -- the queue run was performed for this work group. ** ** Returns: ** nothing */ #define INCR_MOD(v, m) if (++v >= m) \ v = 0; \ else static void schedule_queue_runs(runall, wgrp, didit) bool runall; int wgrp; bool didit; { int qgrp, cgrp, endgrp; #if _FFR_QUEUE_SCHED_DBG time_t lastsched; bool sched; #endif /* _FFR_QUEUE_SCHED_DBG */ time_t now; time_t minqintvl; /* ** This is a bit ugly since we have to duplicate the ** code that "walks" through a work queue group. */ now = curtime(); minqintvl = 0; cgrp = endgrp = WorkGrp[wgrp].wg_curqgrp; do { time_t qintvl; #if _FFR_QUEUE_SCHED_DBG lastsched = 0; sched = false; #endif /* _FFR_QUEUE_SCHED_DBG */ qgrp = WorkGrp[wgrp].wg_qgs[cgrp]->qg_index; if (Queue[qgrp]->qg_queueintvl > 0) qintvl = Queue[qgrp]->qg_queueintvl; else if (QueueIntvl > 0) qintvl = QueueIntvl; else qintvl = (time_t) 0; #if _FFR_QUEUE_SCHED_DBG lastsched = Queue[qgrp]->qg_nextrun; #endif /* _FFR_QUEUE_SCHED_DBG */ if ((runall || Queue[qgrp]->qg_nextrun <= now) && qintvl > 0) { #if _FFR_QUEUE_SCHED_DBG sched = true; #endif /* _FFR_QUEUE_SCHED_DBG */ if (minqintvl == 0 || qintvl < minqintvl) minqintvl = qintvl; /* ** Only set a new time if a queue run was performed ** for this queue group. If the queue was not run, ** we could starve it by setting a new time on each ** call. */ if (didit) Queue[qgrp]->qg_nextrun += qintvl; } #if _FFR_QUEUE_SCHED_DBG if (tTd(69, 10)) sm_syslog(LOG_INFO, NOQID, "sqr: wgrp=%d, cgrp=%d, qgrp=%d, intvl=%ld, QI=%ld, runall=%d, lastrun=%ld, nextrun=%ld, sched=%d", wgrp, cgrp, qgrp, Queue[qgrp]->qg_queueintvl, QueueIntvl, runall, lastsched, Queue[qgrp]->qg_nextrun, sched); #endif /* _FFR_QUEUE_SCHED_DBG */ INCR_MOD(cgrp, WorkGrp[wgrp].wg_numqgrp); } while (endgrp != cgrp); if (minqintvl > 0) (void) sm_setevent(minqintvl, runqueueevent, 0); } #if _FFR_QUEUE_RUN_PARANOIA /* ** CHECKQUEUERUNNER -- check whether a queue group hasn't been run. ** ** Use this if events may get lost and hence queue runners may not ** be started and mail will pile up in a queue. ** ** Parameters: ** none. ** ** Returns: ** true if a queue run is necessary. ** ** Side Effects: ** may schedule a queue run. */ bool checkqueuerunner() { int qgrp; time_t now, minqintvl; now = curtime(); minqintvl = 0; for (qgrp = 0; qgrp < NumQueue && Queue[qgrp] != NULL; qgrp++) { time_t qintvl; if (Queue[qgrp]->qg_queueintvl > 0) qintvl = Queue[qgrp]->qg_queueintvl; else if (QueueIntvl > 0) qintvl = QueueIntvl; else qintvl = (time_t) 0; if (Queue[qgrp]->qg_nextrun <= now - qintvl) { if (minqintvl == 0 || qintvl < minqintvl) minqintvl = qintvl; if (LogLevel > 1) sm_syslog(LOG_WARNING, NOQID, "checkqueuerunner: queue %d should have been run at %s, queue interval %ld", qgrp, arpadate(ctime(&Queue[qgrp]->qg_nextrun)), qintvl); } } if (minqintvl > 0) { (void) sm_setevent(minqintvl, runqueueevent, 0); return true; } return false; } #endif /* _FFR_QUEUE_RUN_PARANOIA */ /* ** RUNQUEUE -- run the jobs in the queue. ** ** Gets the stuff out of the queue in some presumably logical ** order and processes them. ** ** Parameters: ** forkflag -- true if the queue scanning should be done in ** a child process. We double-fork so it is not our ** child and we don't have to clean up after it. ** false can be ignored if we have multiple queues. ** verbose -- if true, print out status information. ** persistent -- persistent queue runner? ** runall -- run all groups or only a subset (DoQueueRun)? ** ** Returns: ** true if the queue run successfully began. ** ** Side Effects: ** runs things in the mail queue using run_work_group(). ** maybe schedules next queue run. */ static ENVELOPE QueueEnvelope; /* the queue run envelope */ static time_t LastQueueTime = 0; /* last time a queue ID assigned */ static pid_t LastQueuePid = -1; /* last PID which had a queue ID */ /* values for qp_supdirs */ #define QP_NOSUB 0x0000 /* No subdirectories */ #define QP_SUBDF 0x0001 /* "df" subdirectory */ #define QP_SUBQF 0x0002 /* "qf" subdirectory */ #define QP_SUBXF 0x0004 /* "xf" subdirectory */ bool runqueue(forkflag, verbose, persistent, runall) bool forkflag; bool verbose; bool persistent; bool runall; { int i; bool ret = true; static int curnum = 0; sigfunc_t cursh; #if SM_HEAP_CHECK SM_NONVOLATILE int oldgroup = 0; if (sm_debug_active(&DebugLeakQ, 1)) { oldgroup = sm_heap_group(); sm_heap_newgroup(); sm_dprintf("runqueue() heap group #%d\n", sm_heap_group()); } #endif /* SM_HEAP_CHECK */ /* queue run has been started, don't do any more this time */ DoQueueRun = false; /* more than one queue or more than one directory per queue */ if (!forkflag && !verbose && (WorkGrp[0].wg_qgs[0]->qg_numqueues > 1 || NumWorkGroups > 1 || WorkGrp[0].wg_numqgrp > 1)) forkflag = true; /* ** For controlling queue runners via signals sent to this process. ** Oldsh* will get called too by runners_sig* (if it is not SIG_IGN ** or SIG_DFL) to preserve cleanup behavior. Now that this process ** will have children (and perhaps grandchildren) this handler will ** be left in place. This is because this process, once it has ** finished spinning off queue runners, may go back to doing something ** else (like being a daemon). And we still want on a SIG{TERM,HUP} to ** clean up the child queue runners. Only install 'runners_sig*' once ** else we'll get stuck looping forever. */ cursh = sm_signal(SIGTERM, runners_sigterm); if (cursh != runners_sigterm) Oldsh_term = cursh; cursh = sm_signal(SIGHUP, runners_sighup); if (cursh != runners_sighup) Oldsh_hup = cursh; for (i = 0; i < NumWorkGroups && !NoMoreRunners; i++) { int rwgflags = RWG_NONE; /* ** If MaxQueueChildren active then test whether the start ** of the next queue group's additional queue runners (maximum) ** will result in MaxQueueChildren being exceeded. ** ** Note: do not use continue; even though another workgroup ** may have fewer queue runners, this would be "unfair", ** i.e., this work group might "starve" then. */ #if _FFR_QUEUE_SCHED_DBG if (tTd(69, 10)) sm_syslog(LOG_INFO, NOQID, "rq: curnum=%d, MaxQueueChildren=%d, CurRunners=%d, WorkGrp[curnum].wg_maxact=%d", curnum, MaxQueueChildren, CurRunners, WorkGrp[curnum].wg_maxact); #endif /* _FFR_QUEUE_SCHED_DBG */ if (MaxQueueChildren > 0 && CurRunners + WorkGrp[curnum].wg_maxact > MaxQueueChildren) break; /* ** Pick up where we left off (curnum), in case we ** used up all the children last time without finishing. ** This give a round-robin fairness to queue runs. ** ** Increment CurRunners before calling run_work_group() ** to avoid a "race condition" with proc_list_drop() which ** decrements CurRunners if the queue runners terminate. ** Notice: CurRunners is an upper limit, in some cases ** (too few jobs in the queue) this value is larger than ** the actual number of queue runners. The discrepancy can ** increase if some queue runners "hang" for a long time. */ CurRunners += WorkGrp[curnum].wg_maxact; if (forkflag) rwgflags |= RWG_FORK; if (verbose) rwgflags |= RWG_VERBOSE; if (persistent) rwgflags |= RWG_PERSISTENT; if (runall) rwgflags |= RWG_RUNALL; ret = run_work_group(curnum, rwgflags); /* ** Failure means a message was printed for ETRN ** and subsequent queues are likely to fail as well. ** Decrement CurRunners in that case because ** none have been started. */ if (!ret) { CurRunners -= WorkGrp[curnum].wg_maxact; break; } if (!persistent) schedule_queue_runs(runall, curnum, true); INCR_MOD(curnum, NumWorkGroups); } /* schedule left over queue runs */ if (i < NumWorkGroups && !NoMoreRunners && !persistent) { int h; for (h = curnum; i < NumWorkGroups; i++) { schedule_queue_runs(runall, h, false); INCR_MOD(h, NumWorkGroups); } } #if SM_HEAP_CHECK if (sm_debug_active(&DebugLeakQ, 1)) sm_heap_setgroup(oldgroup); #endif /* SM_HEAP_CHECK */ return ret; } #if _FFR_SKIP_DOMAINS /* ** SKIP_DOMAINS -- Skip 'skip' number of domains in the WorkQ. ** ** Added by Stephen Frost to support ** having each runner process every N'th domain instead of ** every N'th message. ** ** Parameters: ** skip -- number of domains in WorkQ to skip. ** ** Returns: ** total number of messages skipped. ** ** Side Effects: ** may change WorkQ */ static int skip_domains(skip) int skip; { int n, seqjump; for (n = 0, seqjump = 0; n < skip && WorkQ != NULL; seqjump++) { if (WorkQ->w_next != NULL) { if (WorkQ->w_host != NULL && WorkQ->w_next->w_host != NULL) { if (sm_strcasecmp(WorkQ->w_host, WorkQ->w_next->w_host) != 0) n++; } else { if ((WorkQ->w_host != NULL && WorkQ->w_next->w_host == NULL) || (WorkQ->w_host == NULL && WorkQ->w_next->w_host != NULL)) n++; } } WorkQ = WorkQ->w_next; } return seqjump; } #endif /* _FFR_SKIP_DOMAINS */ /* ** RUNNER_WORK -- have a queue runner do its work ** ** Have a queue runner do its work a list of entries. ** When work isn't directly being done then this process can take a signal ** and terminate immediately (in a clean fashion of course). ** When work is directly being done, it's not to be interrupted ** immediately: the work should be allowed to finish at a clean point ** before termination (in a clean fashion of course). ** ** Parameters: ** e -- envelope. ** sequenceno -- 'th process to run WorkQ. ** didfork -- did the calling process fork()? ** skip -- process only each skip'th item. ** njobs -- number of jobs in WorkQ. ** ** Returns: ** none. ** ** Side Effects: ** runs things in the mail queue. */ static void runner_work(e, sequenceno, didfork, skip, njobs) register ENVELOPE *e; int sequenceno; bool didfork; int skip; int njobs; { int n, seqjump; WORK *w; time_t now; SM_GET_LA(now); /* ** Here we temporarily block the second calling of the handlers. ** This allows us to handle the signal without terminating in the ** middle of direct work. If a signal does come, the test for ** NoMoreRunners will find it. */ BlockOldsh = true; seqjump = skip; /* process them once at a time */ while (WorkQ != NULL) { #if SM_HEAP_CHECK SM_NONVOLATILE int oldgroup = 0; if (sm_debug_active(&DebugLeakQ, 1)) { oldgroup = sm_heap_group(); sm_heap_newgroup(); sm_dprintf("run_queue_group() heap group #%d\n", sm_heap_group()); } #endif /* SM_HEAP_CHECK */ /* do no more work */ if (NoMoreRunners) { /* Check that a valid signal handler is callable */ if (Oldsh != SIG_DFL && Oldsh != SIG_IGN && Oldsh != runners_sighup && Oldsh != runners_sigterm) (*Oldsh)(Oldsig); break; } w = WorkQ; /* assign current work item */ /* ** Set the head of the WorkQ to the next work item. ** It is set 'skip' ahead (the number of parallel queue ** runners working on WorkQ together) since each runner ** works on every 'skip'th (N-th) item. #if _FFR_SKIP_DOMAINS ** In the case of the BYHOST Queue Sort Order, the 'item' ** is a domain, so we work on every 'skip'th (N-th) domain. #endif * _FFR_SKIP_DOMAINS * */ #if _FFR_SKIP_DOMAINS if (QueueSortOrder == QSO_BYHOST) { seqjump = 1; if (WorkQ->w_next != NULL) { if (WorkQ->w_host != NULL && WorkQ->w_next->w_host != NULL) { if (sm_strcasecmp(WorkQ->w_host, WorkQ->w_next->w_host) != 0) seqjump = skip_domains(skip); else WorkQ = WorkQ->w_next; } else { if ((WorkQ->w_host != NULL && WorkQ->w_next->w_host == NULL) || (WorkQ->w_host == NULL && WorkQ->w_next->w_host != NULL)) seqjump = skip_domains(skip); else WorkQ = WorkQ->w_next; } } else WorkQ = WorkQ->w_next; } else #endif /* _FFR_SKIP_DOMAINS */ { for (n = 0; n < skip && WorkQ != NULL; n++) WorkQ = WorkQ->w_next; } e->e_to = NULL; /* ** Ignore jobs that are too expensive for the moment. ** ** Get new load average every GET_NEW_LA_TIME seconds. */ SM_GET_LA(now); if (shouldqueue(WkRecipFact, Current_LA_time)) { char *msg = "Aborting queue run: load average too high"; if (Verbose) message("%s", msg); if (LogLevel > 8) sm_syslog(LOG_INFO, NOQID, "runqueue: %s", msg); break; } if (shouldqueue(w->w_pri, w->w_ctime)) { if (Verbose) message(EmptyString); if (QueueSortOrder == QSO_BYPRIORITY) { if (Verbose) message("Skipping %s/%s (sequence %d of %d) and flushing rest of queue", qid_printqueue(w->w_qgrp, w->w_qdir), w->w_name + 2, sequenceno, njobs); if (LogLevel > 8) sm_syslog(LOG_INFO, NOQID, "runqueue: Flushing queue from %s/%s (pri %ld, LA %d, %d of %d)", qid_printqueue(w->w_qgrp, w->w_qdir), w->w_name + 2, w->w_pri, CurrentLA, sequenceno, njobs); break; } else if (Verbose) message("Skipping %s/%s (sequence %d of %d)", qid_printqueue(w->w_qgrp, w->w_qdir), w->w_name + 2, sequenceno, njobs); } else { if (Verbose) { message(EmptyString); message("Running %s/%s (sequence %d of %d)", qid_printqueue(w->w_qgrp, w->w_qdir), w->w_name + 2, sequenceno, njobs); } if (didfork && MaxQueueChildren > 0) { sm_blocksignal(SIGCHLD); (void) sm_signal(SIGCHLD, reapchild); } if (tTd(63, 100)) sm_syslog(LOG_DEBUG, NOQID, "runqueue %s dowork(%s)", qid_printqueue(w->w_qgrp, w->w_qdir), w->w_name + 2); (void) dowork(w->w_qgrp, w->w_qdir, w->w_name + 2, ForkQueueRuns, false, e); errno = 0; } sm_free(w->w_name); /* XXX */ if (w->w_host != NULL) sm_free(w->w_host); /* XXX */ sm_free((char *) w); /* XXX */ sequenceno += seqjump; /* next sequence number */ #if SM_HEAP_CHECK if (sm_debug_active(&DebugLeakQ, 1)) sm_heap_setgroup(oldgroup); #endif /* SM_HEAP_CHECK */ } BlockOldsh = false; /* check the signals didn't happen during the revert */ if (NoMoreRunners) { /* Check that a valid signal handler is callable */ if (Oldsh != SIG_DFL && Oldsh != SIG_IGN && Oldsh != runners_sighup && Oldsh != runners_sigterm) (*Oldsh)(Oldsig); } Oldsh = SIG_DFL; /* after the NoMoreRunners check */ } /* ** RUN_WORK_GROUP -- run the jobs in a queue group from a work group. ** ** Gets the stuff out of the queue in some presumably logical ** order and processes them. ** ** Parameters: ** wgrp -- work group to process. ** flags -- RWG_* flags ** ** Returns: ** true if the queue run successfully began. ** ** Side Effects: ** runs things in the mail queue. */ /* Minimum sleep time for persistent queue runners */ #define MIN_SLEEP_TIME 5 bool run_work_group(wgrp, flags) int wgrp; int flags; { register ENVELOPE *e; int njobs, qdir; int sequenceno = 1; int qgrp, endgrp, h, i; time_t now; bool full, more; SM_RPOOL_T *rpool; extern void rmexpstab __P((void)); extern ENVELOPE BlankEnvelope; extern SIGFUNC_DECL reapchild __P((int)); if (wgrp < 0) return false; /* ** If no work will ever be selected, don't even bother reading ** the queue. */ SM_GET_LA(now); if (!bitset(RWG_PERSISTENT, flags) && shouldqueue(WkRecipFact, Current_LA_time)) { char *msg = "Skipping queue run -- load average too high"; if (bitset(RWG_VERBOSE, flags)) message("458 %s\n", msg); if (LogLevel > 8) sm_syslog(LOG_INFO, NOQID, "runqueue: %s", msg); return false; } /* ** See if we already have too many children. */ if (bitset(RWG_FORK, flags) && WorkGrp[wgrp].wg_lowqintvl > 0 && !bitset(RWG_PERSISTENT, flags) && MaxChildren > 0 && CurChildren >= MaxChildren) { char *msg = "Skipping queue run -- too many children"; if (bitset(RWG_VERBOSE, flags)) message("458 %s (%d)\n", msg, CurChildren); if (LogLevel > 8) sm_syslog(LOG_INFO, NOQID, "runqueue: %s (%d)", msg, CurChildren); return false; } /* ** See if we want to go off and do other useful work. */ if (bitset(RWG_FORK, flags)) { pid_t pid; (void) sm_blocksignal(SIGCHLD); (void) sm_signal(SIGCHLD, reapchild); pid = dofork(); if (pid == -1) { const char *msg = "Skipping queue run -- fork() failed"; const char *err = sm_errstring(errno); if (bitset(RWG_VERBOSE, flags)) message("458 %s: %s\n", msg, err); if (LogLevel > 8) sm_syslog(LOG_INFO, NOQID, "runqueue: %s: %s", msg, err); (void) sm_releasesignal(SIGCHLD); return false; } if (pid != 0) { /* parent -- pick up intermediate zombie */ (void) sm_blocksignal(SIGALRM); /* wgrp only used when queue runners are persistent */ proc_list_add(pid, "Queue runner", PROC_QUEUE, WorkGrp[wgrp].wg_maxact, bitset(RWG_PERSISTENT, flags) ? wgrp : -1, NULL); (void) sm_releasesignal(SIGALRM); (void) sm_releasesignal(SIGCHLD); return true; } /* child -- clean up signals */ /* Reset global flags */ RestartRequest = NULL; RestartWorkGroup = false; ShutdownRequest = NULL; PendingSignal = 0; CurrentPid = getpid(); close_sendmail_pid(); /* ** Initialize exception stack and default exception ** handler for child process. */ sm_exc_newthread(fatal_error); clrcontrol(); proc_list_clear(); /* Add parent process as first child item */ proc_list_add(CurrentPid, "Queue runner child process", PROC_QUEUE_CHILD, 0, -1, NULL); (void) sm_releasesignal(SIGCHLD); (void) sm_signal(SIGCHLD, SIG_DFL); (void) sm_signal(SIGHUP, SIG_DFL); (void) sm_signal(SIGTERM, intsig); } /* ** Release any resources used by the daemon code. */ clrdaemon(); /* force it to run expensive jobs */ NoConnect = false; /* drop privileges */ if (geteuid() == (uid_t) 0) (void) drop_privileges(false); /* ** Create ourselves an envelope */ CurEnv = &QueueEnvelope; rpool = sm_rpool_new_x(NULL); e = newenvelope(&QueueEnvelope, CurEnv, rpool); e->e_flags = BlankEnvelope.e_flags; e->e_parent = NULL; /* make sure we have disconnected from parent */ if (bitset(RWG_FORK, flags)) { disconnect(1, e); QuickAbort = false; } /* ** If we are running part of the queue, always ignore stored ** host status. */ if (QueueLimitId != NULL || QueueLimitSender != NULL || QueueLimitQuarantine != NULL || QueueLimitRecipient != NULL) { IgnoreHostStatus = true; MinQueueAge = 0; } /* ** Here is where we choose the queue group from the work group. ** The caller of the "domorework" label must setup a new envelope. */ endgrp = WorkGrp[wgrp].wg_curqgrp; /* to not spin endlessly */ domorework: /* ** Run a queue group if: ** RWG_RUNALL bit is set or the bit for this group is set. */ now = curtime(); for (;;) { /* ** Find the next queue group within the work group that ** has been marked as needing a run. */ qgrp = WorkGrp[wgrp].wg_qgs[WorkGrp[wgrp].wg_curqgrp]->qg_index; WorkGrp[wgrp].wg_curqgrp++; /* advance */ WorkGrp[wgrp].wg_curqgrp %= WorkGrp[wgrp].wg_numqgrp; /* wrap */ if (bitset(RWG_RUNALL, flags) || (Queue[qgrp]->qg_nextrun <= now && Queue[qgrp]->qg_nextrun != (time_t) -1)) break; if (endgrp == WorkGrp[wgrp].wg_curqgrp) { e->e_id = NULL; if (bitset(RWG_FORK, flags)) finis(true, true, ExitStat); return true; /* we're done */ } } qdir = Queue[qgrp]->qg_curnum; /* round-robin init of queue position */ #if _FFR_QUEUE_SCHED_DBG if (tTd(69, 12)) sm_syslog(LOG_INFO, NOQID, "rwg: wgrp=%d, qgrp=%d, qdir=%d, name=%s, curqgrp=%d, numgrps=%d", wgrp, qgrp, qdir, qid_printqueue(qgrp, qdir), WorkGrp[wgrp].wg_curqgrp, WorkGrp[wgrp].wg_numqgrp); #endif /* _FFR_QUEUE_SCHED_DBG */ #if HASNICE /* tweak niceness of queue runs */ if (Queue[qgrp]->qg_nice > 0) (void) nice(Queue[qgrp]->qg_nice); #endif /* HASNICE */ /* XXX running queue group... */ sm_setproctitle(true, CurEnv, "running queue: %s", qid_printqueue(qgrp, qdir)); if (LogLevel > 69 || tTd(63, 99)) sm_syslog(LOG_DEBUG, NOQID, "runqueue %s, pid=%d, forkflag=%d", qid_printqueue(qgrp, qdir), (int) CurrentPid, bitset(RWG_FORK, flags)); /* ** Start making passes through the queue. ** First, read and sort the entire queue. ** Then, process the work in that order. ** But if you take too long, start over. */ for (i = 0; i < Queue[qgrp]->qg_numqueues; i++) { h = gatherq(qgrp, qdir, false, &full, &more); #if SM_CONF_SHM if (ShmId != SM_SHM_NO_ID) QSHM_ENTRIES(Queue[qgrp]->qg_qpaths[qdir].qp_idx) = h; #endif /* SM_CONF_SHM */ /* If there are no more items in this queue advance */ if (!more) { /* A round-robin advance */ qdir++; qdir %= Queue[qgrp]->qg_numqueues; } /* Has the WorkList reached the limit? */ if (full) break; /* don't try to gather more */ } /* order the existing work requests */ njobs = sortq(Queue[qgrp]->qg_maxlist); Queue[qgrp]->qg_curnum = qdir; /* update */ if (!Verbose && bitnset(QD_FORK, Queue[qgrp]->qg_flags)) { int loop, maxrunners; pid_t pid; /* ** For this WorkQ we want to fork off N children (maxrunners) ** at this point. Each child has a copy of WorkQ. Each child ** will process every N-th item. The parent will wait for all ** of the children to finish before moving on to the next ** queue group within the work group. This saves us forking ** a new runner-child for each work item. ** It's valid for qg_maxqrun == 0 since this may be an ** explicit "don't run this queue" setting. */ maxrunners = Queue[qgrp]->qg_maxqrun; /* No need to have more runners then there are jobs */ if (maxrunners > njobs) maxrunners = njobs; for (loop = 0; loop < maxrunners; loop++) { /* ** Since the delivery may happen in a child and the ** parent does not wait, the parent may close the ** maps thereby removing any shared memory used by ** the map. Therefore, close the maps now so the ** child will dynamically open them if necessary. */ closemaps(false); pid = fork(); if (pid < 0) { syserr("run_work_group: cannot fork"); return false; } else if (pid > 0) { /* parent -- clean out connection cache */ mci_flush(false, NULL); #if _FFR_SKIP_DOMAINS if (QueueSortOrder == QSO_BYHOST) { sequenceno += skip_domains(1); } else #endif /* _FFR_SKIP_DOMAINS */ { /* for the skip */ WorkQ = WorkQ->w_next; sequenceno++; } proc_list_add(pid, "Queue child runner process", PROC_QUEUE_CHILD, 0, -1, NULL); /* No additional work, no additional runners */ if (WorkQ == NULL) break; } else { /* child -- Reset global flags */ RestartRequest = NULL; RestartWorkGroup = false; ShutdownRequest = NULL; PendingSignal = 0; CurrentPid = getpid(); close_sendmail_pid(); /* ** Initialize exception stack and default ** exception handler for child process. ** When fork()'d the child now has a private ** copy of WorkQ at its current position. */ sm_exc_newthread(fatal_error); /* ** SMTP processes (whether -bd or -bs) set ** SIGCHLD to reapchild to collect ** children status. However, at delivery ** time, that status must be collected ** by sm_wait() to be dealt with properly ** (check success of delivery based ** on status code, etc). Therefore, if we ** are an SMTP process, reset SIGCHLD ** back to the default so reapchild ** doesn't collect status before ** sm_wait(). */ if (OpMode == MD_SMTP || OpMode == MD_DAEMON || MaxQueueChildren > 0) { proc_list_clear(); sm_releasesignal(SIGCHLD); (void) sm_signal(SIGCHLD, SIG_DFL); } /* child -- error messages to the transcript */ QuickAbort = OnlyOneError = false; runner_work(e, sequenceno, true, maxrunners, njobs); /* This child is done */ finis(true, true, ExitStat); /* NOTREACHED */ } } sm_releasesignal(SIGCHLD); /* ** Wait until all of the runners have completed before ** seeing if there is another queue group in the ** work group to process. ** XXX Future enhancement: don't wait() for all children ** here, just go ahead and make sure that overall the number ** of children is not exceeded. */ while (CurChildren > 0) { int status; pid_t ret; while ((ret = sm_wait(&status)) <= 0) continue; proc_list_drop(ret, status, NULL); } } else if (Queue[qgrp]->qg_maxqrun > 0 || bitset(RWG_FORCE, flags)) { /* ** When current process will not fork children to do the work, ** it will do the work itself. The 'skip' will be 1 since ** there are no child runners to divide the work across. */ runner_work(e, sequenceno, false, 1, njobs); } /* free memory allocated by newenvelope() above */ sm_rpool_free(rpool); QueueEnvelope.e_rpool = NULL; /* Are there still more queues in the work group to process? */ if (endgrp != WorkGrp[wgrp].wg_curqgrp) { rpool = sm_rpool_new_x(NULL); e = newenvelope(&QueueEnvelope, CurEnv, rpool); e->e_flags = BlankEnvelope.e_flags; goto domorework; } /* No more queues in work group to process. Now check persistent. */ if (bitset(RWG_PERSISTENT, flags)) { sequenceno = 1; sm_setproctitle(true, CurEnv, "running queue: %s", qid_printqueue(qgrp, qdir)); /* ** close bogus maps, i.e., maps which caused a tempfail, ** so we get fresh map connections on the next lookup. ** closemaps() is also called when children are started. */ closemaps(true); /* Close any cached connections. */ mci_flush(true, NULL); /* Clean out expired related entries. */ rmexpstab(); #if NAMED_BIND /* Update MX records for FallbackMX. */ if (FallbackMX != NULL) (void) getfallbackmxrr(FallbackMX); #endif /* NAMED_BIND */ #if USERDB /* close UserDatabase */ _udbx_close(); #endif /* USERDB */ #if SM_HEAP_CHECK if (sm_debug_active(&SmHeapCheck, 2) && access("memdump", F_OK) == 0 ) { SM_FILE_T *out; remove("memdump"); out = sm_io_open(SmFtStdio, SM_TIME_DEFAULT, "memdump.out", SM_IO_APPEND, NULL); if (out != NULL) { (void) sm_io_fprintf(out, SM_TIME_DEFAULT, "----------------------\n"); sm_heap_report(out, sm_debug_level(&SmHeapCheck) - 1); (void) sm_io_close(out, SM_TIME_DEFAULT); } } #endif /* SM_HEAP_CHECK */ /* let me rest for a second to catch my breath */ if (njobs == 0 && WorkGrp[wgrp].wg_lowqintvl < MIN_SLEEP_TIME) sleep(MIN_SLEEP_TIME); else if (WorkGrp[wgrp].wg_lowqintvl <= 0) sleep(QueueIntvl > 0 ? QueueIntvl : MIN_SLEEP_TIME); else sleep(WorkGrp[wgrp].wg_lowqintvl); /* ** Get the LA outside the WorkQ loop if necessary. ** In a persistent queue runner the code is repeated over ** and over but gatherq() may ignore entries due to ** shouldqueue() (do we really have to do this twice?). ** Hence the queue runners would just idle around when once ** CurrentLA caused all entries in a queue to be ignored. */ if (njobs == 0) SM_GET_LA(now); rpool = sm_rpool_new_x(NULL); e = newenvelope(&QueueEnvelope, CurEnv, rpool); e->e_flags = BlankEnvelope.e_flags; goto domorework; } /* exit without the usual cleanup */ e->e_id = NULL; if (bitset(RWG_FORK, flags)) finis(true, true, ExitStat); /* NOTREACHED */ return true; } /* ** DOQUEUERUN -- do a queue run? */ bool doqueuerun() { return DoQueueRun; } /* ** RUNQUEUEEVENT -- Sets a flag to indicate that a queue run should be done. ** ** Parameters: ** none. ** ** Returns: ** none. ** ** Side Effects: ** The invocation of this function via an alarm may interrupt ** a set of actions. Thus errno may be set in that context. ** We need to restore errno at the end of this function to ensure ** that any work done here that sets errno doesn't return a ** misleading/false errno value. Errno may be EINTR upon entry to ** this function because of non-restartable/continuable system ** API was active. Iff this is true we will override errno as ** a timeout (as a more accurate error message). ** ** NOTE: THIS CAN BE CALLED FROM A SIGNAL HANDLER. DO NOT ADD ** ANYTHING TO THIS ROUTINE UNLESS YOU KNOW WHAT YOU ARE ** DOING. */ void runqueueevent(ignore) int ignore; { int save_errno = errno; /* ** Set the general bit that we want a queue run, ** tested in doqueuerun() */ DoQueueRun = true; #if _FFR_QUEUE_SCHED_DBG if (tTd(69, 10)) sm_syslog(LOG_INFO, NOQID, "rqe: done"); #endif /* _FFR_QUEUE_SCHED_DBG */ errno = save_errno; if (errno == EINTR) errno = ETIMEDOUT; } /* ** GATHERQ -- gather messages from the message queue(s) the work queue. ** ** Parameters: ** qgrp -- the index of the queue group. ** qdir -- the index of the queue directory. ** doall -- if set, include everything in the queue (even ** the jobs that cannot be run because the load ** average is too high, or MaxQueueRun is reached). ** Otherwise, exclude those jobs. ** full -- (optional) to be set 'true' if WorkList is full ** more -- (optional) to be set 'true' if there are still more ** messages in this queue not added to WorkList ** ** Returns: ** The number of request in the queue (not necessarily ** the number of requests in WorkList however). ** ** Side Effects: ** prepares available work into WorkList */ #define NEED_P 0001 /* 'P': priority */ #define NEED_T 0002 /* 'T': time */ #define NEED_R 0004 /* 'R': recipient */ #define NEED_S 0010 /* 'S': sender */ #define NEED_H 0020 /* host */ #define HAS_QUARANTINE 0040 /* has an unexpected 'q' line */ #define NEED_QUARANTINE 0100 /* 'q': reason */ static WORK *WorkList = NULL; /* list of unsort work */ static int WorkListSize = 0; /* current max size of WorkList */ static int WorkListCount = 0; /* # of work items in WorkList */ static int gatherq(qgrp, qdir, doall, full, more) int qgrp; int qdir; bool doall; bool *full; bool *more; { register struct dirent *d; register WORK *w; register char *p; DIR *f; int i, num_ent; int wn; QUEUE_CHAR *check; char qd[MAXPATHLEN]; char qf[MAXPATHLEN]; wn = WorkListCount - 1; num_ent = 0; if (qdir == NOQDIR) (void) sm_strlcpy(qd, ".", sizeof qd); else (void) sm_strlcpyn(qd, sizeof qd, 2, Queue[qgrp]->qg_qpaths[qdir].qp_name, (bitset(QP_SUBQF, Queue[qgrp]->qg_qpaths[qdir].qp_subdirs) ? "/qf" : "")); if (tTd(41, 1)) { sm_dprintf("gatherq:\n"); check = QueueLimitId; while (check != NULL) { sm_dprintf("\tQueueLimitId = %s%s\n", check->queue_negate ? "!" : "", check->queue_match); check = check->queue_next; } check = QueueLimitSender; while (check != NULL) { sm_dprintf("\tQueueLimitSender = %s%s\n", check->queue_negate ? "!" : "", check->queue_match); check = check->queue_next; } check = QueueLimitRecipient; while (check != NULL) { sm_dprintf("\tQueueLimitRecipient = %s%s\n", check->queue_negate ? "!" : "", check->queue_match); check = check->queue_next; } if (QueueMode == QM_QUARANTINE) { check = QueueLimitQuarantine; while (check != NULL) { sm_dprintf("\tQueueLimitQuarantine = %s%s\n", check->queue_negate ? "!" : "", check->queue_match); check = check->queue_next; } } } /* open the queue directory */ f = opendir(qd); if (f == NULL) { syserr("gatherq: cannot open \"%s\"", qid_printqueue(qgrp, qdir)); if (full != NULL) *full = WorkListCount >= MaxQueueRun && MaxQueueRun > 0; if (more != NULL) *more = false; return 0; } /* ** Read the work directory. */ while ((d = readdir(f)) != NULL) { SM_FILE_T *cf; int qfver = 0; char lbuf[MAXNAME + 1]; struct stat sbuf; if (tTd(41, 50)) sm_dprintf("gatherq: checking %s..", d->d_name); /* is this an interesting entry? */ if (!(((QueueMode == QM_NORMAL && d->d_name[0] == NORMQF_LETTER) || (QueueMode == QM_QUARANTINE && d->d_name[0] == QUARQF_LETTER) || (QueueMode == QM_LOST && d->d_name[0] == LOSEQF_LETTER)) && d->d_name[1] == 'f')) { if (tTd(41, 50)) sm_dprintf(" skipping\n"); continue; } if (tTd(41, 50)) sm_dprintf("\n"); if (strlen(d->d_name) >= MAXQFNAME) { if (Verbose) (void) sm_io_fprintf(smioout, SM_TIME_DEFAULT, "gatherq: %s too long, %d max characters\n", d->d_name, MAXQFNAME); if (LogLevel > 0) sm_syslog(LOG_ALERT, NOQID, "gatherq: %s too long, %d max characters", d->d_name, MAXQFNAME); continue; } check = QueueLimitId; while (check != NULL) { if (strcontainedin(false, check->queue_match, d->d_name) != check->queue_negate) break; else check = check->queue_next; } if (QueueLimitId != NULL && check == NULL) continue; /* grow work list if necessary */ if (++wn >= MaxQueueRun && MaxQueueRun > 0) { if (wn == MaxQueueRun && LogLevel > 0) sm_syslog(LOG_WARNING, NOQID, "WorkList for %s maxed out at %d", qid_printqueue(qgrp, qdir), MaxQueueRun); if (doall) continue; /* just count entries */ break; } if (wn >= WorkListSize) { grow_wlist(qgrp, qdir); if (wn >= WorkListSize) continue; } SM_ASSERT(wn >= 0); w = &WorkList[wn]; (void) sm_strlcpyn(qf, sizeof qf, 3, qd, "/", d->d_name); if (stat(qf, &sbuf) < 0) { if (errno != ENOENT) sm_syslog(LOG_INFO, NOQID, "gatherq: can't stat %s/%s", qid_printqueue(qgrp, qdir), d->d_name); wn--; continue; } if (!bitset(S_IFREG, sbuf.st_mode)) { /* Yikes! Skip it or we will hang on open! */ if (!((d->d_name[0] == DATAFL_LETTER || d->d_name[0] == NORMQF_LETTER || d->d_name[0] == QUARQF_LETTER || d->d_name[0] == LOSEQF_LETTER || d->d_name[0] == XSCRPT_LETTER) && d->d_name[1] == 'f' && d->d_name[2] == '\0')) syserr("gatherq: %s/%s is not a regular file", qid_printqueue(qgrp, qdir), d->d_name); wn--; continue; } /* avoid work if possible */ if ((QueueSortOrder == QSO_BYFILENAME || QueueSortOrder == QSO_BYMODTIME || QueueSortOrder == QSO_RANDOM) && QueueLimitQuarantine == NULL && QueueLimitSender == NULL && QueueLimitRecipient == NULL) { w->w_qgrp = qgrp; w->w_qdir = qdir; w->w_name = newstr(d->d_name); w->w_host = NULL; w->w_lock = w->w_tooyoung = false; w->w_pri = 0; w->w_ctime = 0; w->w_mtime = sbuf.st_mtime; ++num_ent; continue; } /* open control file */ cf = sm_io_open(SmFtStdio, SM_TIME_DEFAULT, qf, SM_IO_RDONLY_B, NULL); if (cf == NULL && OpMode != MD_PRINT) { /* this may be some random person sending hir msgs */ if (tTd(41, 2)) sm_dprintf("gatherq: cannot open %s: %s\n", d->d_name, sm_errstring(errno)); errno = 0; wn--; continue; } w->w_qgrp = qgrp; w->w_qdir = qdir; w->w_name = newstr(d->d_name); w->w_host = NULL; if (cf != NULL) { w->w_lock = !lockfile(sm_io_getinfo(cf, SM_IO_WHAT_FD, NULL), w->w_name, NULL, LOCK_SH|LOCK_NB); } w->w_tooyoung = false; /* make sure jobs in creation don't clog queue */ w->w_pri = 0x7fffffff; w->w_ctime = 0; w->w_mtime = sbuf.st_mtime; /* extract useful information */ i = NEED_P|NEED_T; if (QueueSortOrder == QSO_BYHOST #if _FFR_RHS || QueueSortOrder == QSO_BYSHUFFLE #endif /* _FFR_RHS */ ) { /* need w_host set for host sort order */ i |= NEED_H; } if (QueueLimitSender != NULL) i |= NEED_S; if (QueueLimitRecipient != NULL) i |= NEED_R; if (QueueLimitQuarantine != NULL) i |= NEED_QUARANTINE; while (cf != NULL && i != 0 && sm_io_fgets(cf, SM_TIME_DEFAULT, lbuf, sizeof lbuf) != NULL) { int c; time_t age; p = strchr(lbuf, '\n'); if (p != NULL) *p = '\0'; else { /* flush rest of overly long line */ while ((c = sm_io_getc(cf, SM_TIME_DEFAULT)) != SM_IO_EOF && c != '\n') continue; } switch (lbuf[0]) { case 'V': qfver = atoi(&lbuf[1]); break; case 'P': w->w_pri = atol(&lbuf[1]); i &= ~NEED_P; break; case 'T': w->w_ctime = atol(&lbuf[1]); i &= ~NEED_T; break; case 'q': if (QueueMode != QM_QUARANTINE && QueueMode != QM_LOST) { if (tTd(41, 49)) sm_dprintf("%s not marked as quarantined but has a 'q' line\n", w->w_name); i |= HAS_QUARANTINE; } else if (QueueMode == QM_QUARANTINE) { if (QueueLimitQuarantine == NULL) { i &= ~NEED_QUARANTINE; break; } p = &lbuf[1]; check = QueueLimitQuarantine; while (check != NULL) { if (strcontainedin(false, check->queue_match, p) != check->queue_negate) break; else check = check->queue_next; } if (check != NULL) i &= ~NEED_QUARANTINE; } break; case 'R': if (w->w_host == NULL && (p = strrchr(&lbuf[1], '@')) != NULL) { #if _FFR_RHS if (QueueSortOrder == QSO_BYSHUFFLE) w->w_host = newstr(&p[1]); else #endif /* _FFR_RHS */ w->w_host = strrev(&p[1]); makelower(w->w_host); i &= ~NEED_H; } if (QueueLimitRecipient == NULL) { i &= ~NEED_R; break; } if (qfver > 0) { p = strchr(&lbuf[1], ':'); if (p == NULL) p = &lbuf[1]; else ++p; /* skip over ':' */ } else p = &lbuf[1]; check = QueueLimitRecipient; while (check != NULL) { if (strcontainedin(true, check->queue_match, p) != check->queue_negate) break; else check = check->queue_next; } if (check != NULL) i &= ~NEED_R; break; case 'S': check = QueueLimitSender; while (check != NULL) { if (strcontainedin(true, check->queue_match, &lbuf[1]) != check->queue_negate) break; else check = check->queue_next; } if (check != NULL) i &= ~NEED_S; break; case 'K': age = curtime() - (time_t) atol(&lbuf[1]); if (age >= 0 && MinQueueAge > 0 && age < MinQueueAge) w->w_tooyoung = true; break; case 'N': if (atol(&lbuf[1]) == 0) w->w_tooyoung = false; break; } } if (cf != NULL) (void) sm_io_close(cf, SM_TIME_DEFAULT); if ((!doall && shouldqueue(w->w_pri, w->w_ctime)) || bitset(HAS_QUARANTINE, i) || bitset(NEED_QUARANTINE, i) || bitset(NEED_R|NEED_S, i)) { /* don't even bother sorting this job in */ if (tTd(41, 49)) sm_dprintf("skipping %s (%x)\n", w->w_name, i); sm_free(w->w_name); /* XXX */ if (w->w_host != NULL) sm_free(w->w_host); /* XXX */ wn--; } else ++num_ent; } (void) closedir(f); wn++; i = wn - WorkListCount; WorkListCount += SM_MIN(num_ent, WorkListSize); if (more != NULL) *more = WorkListCount < wn; if (full != NULL) *full = (wn >= MaxQueueRun && MaxQueueRun > 0) || (WorkList == NULL && wn > 0); return i; } /* ** SORTQ -- sort the work list ** ** First the old WorkQ is cleared away. Then the WorkList is sorted ** for all items so that important (higher sorting value) items are not ** trunctated off. Then the most important items are moved from ** WorkList to WorkQ. The lower count of 'max' or MaxListCount items ** are moved. ** ** Parameters: ** max -- maximum number of items to be placed in WorkQ ** ** Returns: ** the number of items in WorkQ ** ** Side Effects: ** WorkQ gets released and filled with new work. WorkList ** gets released. Work items get sorted in order. */ static int sortq(max) int max; { register int i; /* local counter */ register WORK *w; /* tmp item pointer */ int wc = WorkListCount; /* trim size for WorkQ */ if (WorkQ != NULL) { WORK *nw; /* Clear out old WorkQ. */ for (w = WorkQ; w != NULL; w = nw) { nw = w->w_next; sm_free(w->w_name); /* XXX */ if (w->w_host != NULL) sm_free(w->w_host); /* XXX */ sm_free((char *) w); /* XXX */ } WorkQ = NULL; } if (WorkList == NULL || wc <= 0) return 0; /* ** The sort now takes place using all of the items in WorkList. ** The list gets trimmed to the most important items after the sort. ** If the trim were to happen before the sort then one or more ** important items might get truncated off -- not what we want. */ if (QueueSortOrder == QSO_BYHOST) { /* ** Sort the work directory for the first time, ** based on host name, lock status, and priority. */ qsort((char *) WorkList, wc, sizeof *WorkList, workcmpf1); /* ** If one message to host is locked, "lock" all messages ** to that host. */ i = 0; while (i < wc) { if (!WorkList[i].w_lock) { i++; continue; } w = &WorkList[i]; while (++i < wc) { if (WorkList[i].w_host == NULL && w->w_host == NULL) WorkList[i].w_lock = true; else if (WorkList[i].w_host != NULL && w->w_host != NULL && sm_strcasecmp(WorkList[i].w_host, w->w_host) == 0) WorkList[i].w_lock = true; else break; } } /* ** Sort the work directory for the second time, ** based on lock status, host name, and priority. */ qsort((char *) WorkList, wc, sizeof *WorkList, workcmpf2); } else if (QueueSortOrder == QSO_BYTIME) { /* ** Simple sort based on submission time only. */ qsort((char *) WorkList, wc, sizeof *WorkList, workcmpf3); } else if (QueueSortOrder == QSO_BYFILENAME) { /* ** Sort based on queue filename. */ qsort((char *) WorkList, wc, sizeof *WorkList, workcmpf4); } else if (QueueSortOrder == QSO_RANDOM) { /* ** Sort randomly. To avoid problems with an instable sort, ** use a random index into the queue file name to start ** comparison. */ randi = get_rand_mod(MAXQFNAME); if (randi < 2) randi = 3; qsort((char *) WorkList, wc, sizeof *WorkList, workcmpf5); } else if (QueueSortOrder == QSO_BYMODTIME) { /* ** Simple sort based on modification time of queue file. ** This puts the oldest items first. */ qsort((char *) WorkList, wc, sizeof *WorkList, workcmpf6); } #if _FFR_RHS else if (QueueSortOrder == QSO_BYSHUFFLE) { /* ** Simple sort based on shuffled host name. */ init_shuffle_alphabet(); qsort((char *) WorkList, wc, sizeof *WorkList, workcmpf7); } #endif /* _FFR_RHS */ else if (QueueSortOrder == QSO_BYPRIORITY) { /* ** Simple sort based on queue priority only. */ qsort((char *) WorkList, wc, sizeof *WorkList, workcmpf0); } /* else don't sort at all */ /* Check if the per queue group item limit will be exceeded */ if (wc > max && max > 0) wc = max; /* ** Convert the work list into canonical form. ** Should be turning it into a list of envelopes here perhaps. ** Only take the most important items up to the per queue group ** maximum. */ for (i = wc; --i >= 0; ) { w = (WORK *) xalloc(sizeof *w); w->w_qgrp = WorkList[i].w_qgrp; w->w_qdir = WorkList[i].w_qdir; w->w_name = WorkList[i].w_name; w->w_host = WorkList[i].w_host; w->w_lock = WorkList[i].w_lock; w->w_tooyoung = WorkList[i].w_tooyoung; w->w_pri = WorkList[i].w_pri; w->w_ctime = WorkList[i].w_ctime; w->w_mtime = WorkList[i].w_mtime; w->w_next = WorkQ; WorkQ = w; } /* free the rest of the list */ for (i = WorkListCount; --i >= wc; ) { sm_free(WorkList[i].w_name); if (WorkList[i].w_host != NULL) sm_free(WorkList[i].w_host); } if (WorkList != NULL) sm_free(WorkList); /* XXX */ WorkList = NULL; WorkListSize = 0; WorkListCount = 0; if (tTd(40, 1)) { for (w = WorkQ; w != NULL; w = w->w_next) { if (w->w_host != NULL) sm_dprintf("%22s: pri=%ld %s\n", w->w_name, w->w_pri, w->w_host); else sm_dprintf("%32s: pri=%ld\n", w->w_name, w->w_pri); } } return wc; /* return number of WorkQ items */ } /* ** GROW_WLIST -- make the work list larger ** ** Parameters: ** qgrp -- the index for the queue group. ** qdir -- the index for the queue directory. ** ** Returns: ** none. ** ** Side Effects: ** Adds another QUEUESEGSIZE entries to WorkList if possible. ** It can fail if there isn't enough memory, so WorkListSize ** should be checked again upon return. */ static void grow_wlist(qgrp, qdir) int qgrp; int qdir; { if (tTd(41, 1)) sm_dprintf("grow_wlist: WorkListSize=%d\n", WorkListSize); if (WorkList == NULL) { WorkList = (WORK *) xalloc((sizeof *WorkList) * (QUEUESEGSIZE + 1)); WorkListSize = QUEUESEGSIZE; } else { int newsize = WorkListSize + QUEUESEGSIZE; WORK *newlist = (WORK *) sm_realloc((char *) WorkList, (unsigned) sizeof(WORK) * (newsize + 1)); if (newlist != NULL) { WorkListSize = newsize; WorkList = newlist; if (LogLevel > 1) { sm_syslog(LOG_INFO, NOQID, "grew WorkList for %s to %d", qid_printqueue(qgrp, qdir), WorkListSize); } } else if (LogLevel > 0) { sm_syslog(LOG_ALERT, NOQID, "FAILED to grow WorkList for %s to %d", qid_printqueue(qgrp, qdir), newsize); } } if (tTd(41, 1)) sm_dprintf("grow_wlist: WorkListSize now %d\n", WorkListSize); } /* ** WORKCMPF0 -- simple priority-only compare function. ** ** Parameters: ** a -- the first argument. ** b -- the second argument. ** ** Returns: ** -1 if a < b ** 0 if a == b ** +1 if a > b ** */ static int workcmpf0(a, b) register WORK *a; register WORK *b; { long pa = a->w_pri; long pb = b->w_pri; if (pa == pb) return 0; else if (pa > pb) return 1; else return -1; } /* ** WORKCMPF1 -- first compare function for ordering work based on host name. ** ** Sorts on host name, lock status, and priority in that order. ** ** Parameters: ** a -- the first argument. ** b -- the second argument. ** ** Returns: ** <0 if a < b ** 0 if a == b ** >0 if a > b ** */ static int workcmpf1(a, b) register WORK *a; register WORK *b; { int i; /* host name */ if (a->w_host != NULL && b->w_host == NULL) return 1; else if (a->w_host == NULL && b->w_host != NULL) return -1; if (a->w_host != NULL && b->w_host != NULL && (i = sm_strcasecmp(a->w_host, b->w_host)) != 0) return i; /* lock status */ if (a->w_lock != b->w_lock) return b->w_lock - a->w_lock; /* job priority */ return workcmpf0(a, b); } /* ** WORKCMPF2 -- second compare function for ordering work based on host name. ** ** Sorts on lock status, host name, and priority in that order. ** ** Parameters: ** a -- the first argument. ** b -- the second argument. ** ** Returns: ** <0 if a < b ** 0 if a == b ** >0 if a > b ** */ static int workcmpf2(a, b) register WORK *a; register WORK *b; { int i; /* lock status */ if (a->w_lock != b->w_lock) return a->w_lock - b->w_lock; /* host name */ if (a->w_host != NULL && b->w_host == NULL) return 1; else if (a->w_host == NULL && b->w_host != NULL) return -1; if (a->w_host != NULL && b->w_host != NULL && (i = sm_strcasecmp(a->w_host, b->w_host)) != 0) return i; /* job priority */ return workcmpf0(a, b); } /* ** WORKCMPF3 -- simple submission-time-only compare function. ** ** Parameters: ** a -- the first argument. ** b -- the second argument. ** ** Returns: ** -1 if a < b ** 0 if a == b ** +1 if a > b ** */ static int workcmpf3(a, b) register WORK *a; register WORK *b; { if (a->w_ctime > b->w_ctime) return 1; else if (a->w_ctime < b->w_ctime) return -1; else return 0; } /* ** WORKCMPF4 -- compare based on file name ** ** Parameters: ** a -- the first argument. ** b -- the second argument. ** ** Returns: ** -1 if a < b ** 0 if a == b ** +1 if a > b ** */ static int workcmpf4(a, b) register WORK *a; register WORK *b; { return strcmp(a->w_name, b->w_name); } /* ** WORKCMPF5 -- compare based on assigned random number ** ** Parameters: ** a -- the first argument (ignored). ** b -- the second argument (ignored). ** ** Returns: ** randomly 1/-1 */ /* ARGSUSED0 */ static int workcmpf5(a, b) register WORK *a; register WORK *b; { if (strlen(a->w_name) < randi || strlen(b->w_name) < randi) return -1; return a->w_name[randi] - b->w_name[randi]; } /* ** WORKCMPF6 -- simple modification-time-only compare function. ** ** Parameters: ** a -- the first argument. ** b -- the second argument. ** ** Returns: ** -1 if a < b ** 0 if a == b ** +1 if a > b ** */ static int workcmpf6(a, b) register WORK *a; register WORK *b; { if (a->w_mtime > b->w_mtime) return 1; else if (a->w_mtime < b->w_mtime) return -1; else return 0; } #if _FFR_RHS /* ** WORKCMPF7 -- compare function for ordering work based on shuffled host name. ** ** Sorts on lock status, host name, and priority in that order. ** ** Parameters: ** a -- the first argument. ** b -- the second argument. ** ** Returns: ** <0 if a < b ** 0 if a == b ** >0 if a > b ** */ static int workcmpf7(a, b) register WORK *a; register WORK *b; { int i; /* lock status */ if (a->w_lock != b->w_lock) return a->w_lock - b->w_lock; /* host name */ if (a->w_host != NULL && b->w_host == NULL) return 1; else if (a->w_host == NULL && b->w_host != NULL) return -1; if (a->w_host != NULL && b->w_host != NULL && (i = sm_strshufflecmp(a->w_host, b->w_host)) != 0) return i; /* job priority */ return workcmpf0(a, b); } #endif /* _FFR_RHS */ /* ** STRREV -- reverse string ** ** Returns a pointer to a new string that is the reverse of ** the string pointed to by fwd. The space for the new ** string is obtained using xalloc(). ** ** Parameters: ** fwd -- the string to reverse. ** ** Returns: ** the reversed string. */ static char * strrev(fwd) char *fwd; { char *rev = NULL; int len, cnt; len = strlen(fwd); rev = xalloc(len + 1); for (cnt = 0; cnt < len; ++cnt) rev[cnt] = fwd[len - cnt - 1]; rev[len] = '\0'; return rev; } #if _FFR_RHS # define NASCII 128 # define NCHAR 256 static unsigned char ShuffledAlphabet[NCHAR]; void init_shuffle_alphabet() { static bool init = false; int i; if (init) return; /* fill the ShuffledAlphabet */ for (i = 0; i < NASCII; i++) ShuffledAlphabet[i] = i; /* mix it */ for (i = 1; i < NASCII; i++) { register int j = get_random() % NASCII; register int tmp; tmp = ShuffledAlphabet[j]; ShuffledAlphabet[j] = ShuffledAlphabet[i]; ShuffledAlphabet[i] = tmp; } /* make it case insensitive */ for (i = 'A'; i <= 'Z'; i++) ShuffledAlphabet[i] = ShuffledAlphabet[i + 'a' - 'A']; /* fill the upper part */ for (i = 0; i < NASCII; i++) ShuffledAlphabet[i + NASCII] = ShuffledAlphabet[i]; init = true; } static int sm_strshufflecmp(a, b) char *a; char *b; { const unsigned char *us1 = (const unsigned char *) a; const unsigned char *us2 = (const unsigned char *) b; while (ShuffledAlphabet[*us1] == ShuffledAlphabet[*us2++]) { if (*us1++ == '\0') return 0; } return (ShuffledAlphabet[*us1] - ShuffledAlphabet[*--us2]); } #endif /* _FFR_RHS */ /* ** DOWORK -- do a work request. ** ** Parameters: ** qgrp -- the index of the queue group for the job. ** qdir -- the index of the queue directory for the job. ** id -- the ID of the job to run. ** forkflag -- if set, run this in background. ** requeueflag -- if set, reinstantiate the queue quickly. ** This is used when expanding aliases in the queue. ** If forkflag is also set, it doesn't wait for the ** child. ** e - the envelope in which to run it. ** ** Returns: ** process id of process that is running the queue job. ** ** Side Effects: ** The work request is satisfied if possible. */ pid_t dowork(qgrp, qdir, id, forkflag, requeueflag, e) int qgrp; int qdir; char *id; bool forkflag; bool requeueflag; register ENVELOPE *e; { register pid_t pid; SM_RPOOL_T *rpool; if (tTd(40, 1)) sm_dprintf("dowork(%s/%s)\n", qid_printqueue(qgrp, qdir), id); /* ** Fork for work. */ if (forkflag) { /* ** Since the delivery may happen in a child and the ** parent does not wait, the parent may close the ** maps thereby removing any shared memory used by ** the map. Therefore, close the maps now so the ** child will dynamically open them if necessary. */ closemaps(false); pid = fork(); if (pid < 0) { syserr("dowork: cannot fork"); return 0; } else if (pid > 0) { /* parent -- clean out connection cache */ mci_flush(false, NULL); } else { /* ** Initialize exception stack and default exception ** handler for child process. */ /* Reset global flags */ RestartRequest = NULL; RestartWorkGroup = false; ShutdownRequest = NULL; PendingSignal = 0; CurrentPid = getpid(); sm_exc_newthread(fatal_error); /* ** See note above about SMTP processes and SIGCHLD. */ if (OpMode == MD_SMTP || OpMode == MD_DAEMON || MaxQueueChildren > 0) { proc_list_clear(); sm_releasesignal(SIGCHLD); (void) sm_signal(SIGCHLD, SIG_DFL); } /* child -- error messages to the transcript */ QuickAbort = OnlyOneError = false; } } else { pid = 0; } if (pid == 0) { /* ** CHILD ** Lock the control file to avoid duplicate deliveries. ** Then run the file as though we had just read it. ** We save an idea of the temporary name so we ** can recover on interrupt. */ if (forkflag) { /* Reset global flags */ RestartRequest = NULL; RestartWorkGroup = false; ShutdownRequest = NULL; PendingSignal = 0; } /* set basic modes, etc. */ sm_clear_events(); clearstats(); rpool = sm_rpool_new_x(NULL); clearenvelope(e, false, rpool); e->e_flags |= EF_QUEUERUN|EF_GLOBALERRS; set_delivery_mode(SM_DELIVER, e); e->e_errormode = EM_MAIL; e->e_id = id; e->e_qgrp = qgrp; e->e_qdir = qdir; GrabTo = UseErrorsTo = false; ExitStat = EX_OK; if (forkflag) { disconnect(1, e); set_op_mode(MD_QUEUERUN); } sm_setproctitle(true, e, "%s from queue", qid_printname(e)); if (LogLevel > 76) sm_syslog(LOG_DEBUG, e->e_id, "dowork, pid=%d", (int) CurrentPid); /* don't use the headers from sendmail.cf... */ e->e_header = NULL; /* read the queue control file -- return if locked */ if (!readqf(e, false)) { if (tTd(40, 4) && e->e_id != NULL) sm_dprintf("readqf(%s) failed\n", qid_printname(e)); e->e_id = NULL; if (forkflag) finis(false, true, EX_OK); else { /* adding this frees 8 bytes */ clearenvelope(e, false, rpool); /* adding this frees 12 bytes */ sm_rpool_free(rpool); e->e_rpool = NULL; return 0; } } e->e_flags |= EF_INQUEUE; eatheader(e, requeueflag, true); if (requeueflag) queueup(e, false, false); /* do the delivery */ sendall(e, SM_DELIVER); /* finish up and exit */ if (forkflag) finis(true, true, ExitStat); else { dropenvelope(e, true, false); sm_rpool_free(rpool); e->e_rpool = NULL; } } e->e_id = NULL; return pid; } /* ** DOWORKLIST -- process a list of envelopes as work requests ** ** Similar to dowork(), except that after forking, it processes an ** envelope and its siblings, treating each envelope as a work request. ** ** Parameters: ** el -- envelope to be processed including its siblings. ** forkflag -- if set, run this in background. ** requeueflag -- if set, reinstantiate the queue quickly. ** This is used when expanding aliases in the queue. ** If forkflag is also set, it doesn't wait for the ** child. ** ** Returns: ** process id of process that is running the queue job. ** ** Side Effects: ** The work request is satisfied if possible. */ pid_t doworklist(el, forkflag, requeueflag) ENVELOPE *el; bool forkflag; bool requeueflag; { register pid_t pid; ENVELOPE *ei; if (tTd(40, 1)) sm_dprintf("doworklist()\n"); /* ** Fork for work. */ if (forkflag) { /* ** Since the delivery may happen in a child and the ** parent does not wait, the parent may close the ** maps thereby removing any shared memory used by ** the map. Therefore, close the maps now so the ** child will dynamically open them if necessary. */ closemaps(false); pid = fork(); if (pid < 0) { syserr("doworklist: cannot fork"); return 0; } else if (pid > 0) { /* parent -- clean out connection cache */ mci_flush(false, NULL); } else { /* ** Initialize exception stack and default exception ** handler for child process. */ /* Reset global flags */ RestartRequest = NULL; RestartWorkGroup = false; ShutdownRequest = NULL; PendingSignal = 0; CurrentPid = getpid(); sm_exc_newthread(fatal_error); /* ** See note above about SMTP processes and SIGCHLD. */ if (OpMode == MD_SMTP || OpMode == MD_DAEMON || MaxQueueChildren > 0) { proc_list_clear(); sm_releasesignal(SIGCHLD); (void) sm_signal(SIGCHLD, SIG_DFL); } /* child -- error messages to the transcript */ QuickAbort = OnlyOneError = false; } } else { pid = 0; } if (pid != 0) return pid; /* ** IN CHILD ** Lock the control file to avoid duplicate deliveries. ** Then run the file as though we had just read it. ** We save an idea of the temporary name so we ** can recover on interrupt. */ if (forkflag) { /* Reset global flags */ RestartRequest = NULL; RestartWorkGroup = false; ShutdownRequest = NULL; PendingSignal = 0; } /* set basic modes, etc. */ sm_clear_events(); clearstats(); GrabTo = UseErrorsTo = false; ExitStat = EX_OK; if (forkflag) { disconnect(1, el); set_op_mode(MD_QUEUERUN); } if (LogLevel > 76) sm_syslog(LOG_DEBUG, el->e_id, "doworklist, pid=%d", (int) CurrentPid); for (ei = el; ei != NULL; ei = ei->e_sibling) { ENVELOPE e; SM_RPOOL_T *rpool; if (WILL_BE_QUEUED(ei->e_sendmode)) continue; else if (QueueMode != QM_QUARANTINE && ei->e_quarmsg != NULL) continue; rpool = sm_rpool_new_x(NULL); clearenvelope(&e, true, rpool); e.e_flags |= EF_QUEUERUN|EF_GLOBALERRS; set_delivery_mode(SM_DELIVER, &e); e.e_errormode = EM_MAIL; e.e_id = ei->e_id; e.e_qgrp = ei->e_qgrp; e.e_qdir = ei->e_qdir; openxscript(&e); sm_setproctitle(true, &e, "%s from queue", qid_printname(&e)); /* don't use the headers from sendmail.cf... */ e.e_header = NULL; CurEnv = &e; /* read the queue control file -- return if locked */ if (readqf(&e, false)) { e.e_flags |= EF_INQUEUE; eatheader(&e, requeueflag, true); if (requeueflag) queueup(&e, false, false); /* do the delivery */ sendall(&e, SM_DELIVER); dropenvelope(&e, true, false); } else { if (tTd(40, 4) && e.e_id != NULL) sm_dprintf("readqf(%s) failed\n", qid_printname(&e)); } sm_rpool_free(rpool); ei->e_id = NULL; } /* restore CurEnv */ CurEnv = el; /* finish up and exit */ if (forkflag) finis(true, true, ExitStat); return 0; } /* ** READQF -- read queue file and set up environment. ** ** Parameters: ** e -- the envelope of the job to run. ** openonly -- only open the qf (returned as e_lockfp) ** ** Returns: ** true if it successfully read the queue file. ** false otherwise. ** ** Side Effects: ** The queue file is returned locked. */ static bool readqf(e, openonly) register ENVELOPE *e; bool openonly; { register SM_FILE_T *qfp; ADDRESS *ctladdr; struct stat st, stf; char *bp; int qfver = 0; long hdrsize = 0; register char *p; char *frcpt = NULL; char *orcpt = NULL; bool nomore = false; bool bogus = false; MODE_T qsafe; char *err; char qf[MAXPATHLEN]; char buf[MAXLINE]; /* ** Read and process the file. */ (void) sm_strlcpy(qf, queuename(e, ANYQFL_LETTER), sizeof qf); qfp = sm_io_open(SmFtStdio, SM_TIME_DEFAULT, qf, SM_IO_RDWR_B, NULL); if (qfp == NULL) { int save_errno = errno; if (tTd(40, 8)) sm_dprintf("readqf(%s): sm_io_open failure (%s)\n", qf, sm_errstring(errno)); errno = save_errno; if (errno != ENOENT ) syserr("readqf: no control file %s", qf); RELEASE_QUEUE; return false; } if (!lockfile(sm_io_getinfo(qfp, SM_IO_WHAT_FD, NULL), qf, NULL, LOCK_EX|LOCK_NB)) { /* being processed by another queuer */ if (Verbose) (void) sm_io_fprintf(smioout, SM_TIME_DEFAULT, "%s: locked\n", e->e_id); if (tTd(40, 8)) sm_dprintf("%s: locked\n", e->e_id); if (LogLevel > 19) sm_syslog(LOG_DEBUG, e->e_id, "locked"); (void) sm_io_close(qfp, SM_TIME_DEFAULT); RELEASE_QUEUE; return false; } RELEASE_QUEUE; /* ** Prevent locking race condition. ** ** Process A: readqf(): qfp = fopen(qffile) ** Process B: queueup(): rename(tf, qf) ** Process B: unlocks(tf) ** Process A: lockfile(qf); ** ** Process A (us) has the old qf file (before the rename deleted ** the directory entry) and will be delivering based on old data. ** This can lead to multiple deliveries of the same recipients. ** ** Catch this by checking if the underlying qf file has changed ** *after* acquiring our lock and if so, act as though the file ** was still locked (i.e., just return like the lockfile() case ** above. */ if (stat(qf, &stf) < 0 || fstat(sm_io_getinfo(qfp, SM_IO_WHAT_FD, NULL), &st) < 0) { /* must have been being processed by someone else */ if (tTd(40, 8)) sm_dprintf("readqf(%s): [f]stat failure (%s)\n", qf, sm_errstring(errno)); (void) sm_io_close(qfp, SM_TIME_DEFAULT); return false; } if (st.st_nlink != stf.st_nlink || st.st_dev != stf.st_dev || ST_INODE(st) != ST_INODE(stf) || #if HAS_ST_GEN && 0 /* AFS returns garbage in st_gen */ st.st_gen != stf.st_gen || #endif /* HAS_ST_GEN && 0 */ st.st_uid != stf.st_uid || st.st_gid != stf.st_gid || st.st_size != stf.st_size) { /* changed after opened */ if (Verbose) (void) sm_io_fprintf(smioout, SM_TIME_DEFAULT, "%s: changed\n", e->e_id); if (tTd(40, 8)) sm_dprintf("%s: changed\n", e->e_id); if (LogLevel > 19) sm_syslog(LOG_DEBUG, e->e_id, "changed"); (void) sm_io_close(qfp, SM_TIME_DEFAULT); return false; } /* ** Check the queue file for plausibility to avoid attacks. */ qsafe = S_IWOTH|S_IWGRP; if (bitset(S_IWGRP, QueueFileMode)) qsafe &= ~S_IWGRP; bogus = st.st_uid != geteuid() && st.st_uid != TrustedUid && geteuid() != RealUid; /* ** If this qf file results from a set-group-ID binary, then ** we check whether the directory is group-writable, ** the queue file mode contains the group-writable bit, and ** the groups are the same. ** Notice: this requires that the set-group-ID binary is used to ** run the queue! */ if (bogus && st.st_gid == getegid() && UseMSP) { char delim; struct stat dst; bp = SM_LAST_DIR_DELIM(qf); if (bp == NULL) delim = '\0'; else { delim = *bp; *bp = '\0'; } if (stat(delim == '\0' ? "." : qf, &dst) < 0) syserr("readqf: cannot stat directory %s", delim == '\0' ? "." : qf); else { bogus = !(bitset(S_IWGRP, QueueFileMode) && bitset(S_IWGRP, dst.st_mode) && dst.st_gid == st.st_gid); } if (delim != '\0') *bp = delim; } if (!bogus) bogus = bitset(qsafe, st.st_mode); if (bogus) { if (LogLevel > 0) { sm_syslog(LOG_ALERT, e->e_id, "bogus queue file, uid=%d, gid=%d, mode=%o", st.st_uid, st.st_gid, st.st_mode); } if (tTd(40, 8)) sm_dprintf("readqf(%s): bogus file\n", qf); e->e_flags |= EF_INQUEUE; if (!openonly) loseqfile(e, "bogus file uid/gid in mqueue"); (void) sm_io_close(qfp, SM_TIME_DEFAULT); return false; } if (st.st_size == 0) { /* must be a bogus file -- if also old, just remove it */ if (!openonly && st.st_ctime + 10 * 60 < curtime()) { (void) xunlink(queuename(e, DATAFL_LETTER)); (void) xunlink(queuename(e, ANYQFL_LETTER)); } (void) sm_io_close(qfp, SM_TIME_DEFAULT); return false; } if (st.st_nlink == 0) { /* ** Race condition -- we got a file just as it was being ** unlinked. Just assume it is zero length. */ (void) sm_io_close(qfp, SM_TIME_DEFAULT); return false; } #if _FFR_TRUSTED_QF /* ** If we don't own the file mark it as unsafe. ** However, allow TrustedUser to own it as well ** in case TrustedUser manipulates the queue. */ if (st.st_uid != geteuid() && st.st_uid != TrustedUid) e->e_flags |= EF_UNSAFE; #else /* _FFR_TRUSTED_QF */ /* If we don't own the file mark it as unsafe */ if (st.st_uid != geteuid()) e->e_flags |= EF_UNSAFE; #endif /* _FFR_TRUSTED_QF */ /* good file -- save this lock */ e->e_lockfp = qfp; /* Just wanted the open file */ if (openonly) return true; /* do basic system initialization */ initsys(e); macdefine(&e->e_macro, A_PERM, 'i', e->e_id); LineNumber = 0; e->e_flags |= EF_GLOBALERRS; set_op_mode(MD_QUEUERUN); ctladdr = NULL; e->e_qfletter = queue_letter(e, ANYQFL_LETTER); e->e_dfqgrp = e->e_qgrp; e->e_dfqdir = e->e_qdir; #if _FFR_QUEUE_MACRO macdefine(&e->e_macro, A_TEMP, macid("{queue}"), qid_printqueue(e->e_qgrp, e->e_qdir)); #endif /* _FFR_QUEUE_MACRO */ e->e_dfino = -1; e->e_msgsize = -1; while ((bp = fgetfolded(buf, sizeof buf, qfp)) != NULL) { unsigned long qflags; ADDRESS *q; int r; time_t now; auto char *ep; if (tTd(40, 4)) sm_dprintf("+++++ %s\n", bp); if (nomore) { /* hack attack */ hackattack: syserr("SECURITY ALERT: extra or bogus data in queue file: %s", bp); err = "bogus queue line"; goto fail; } switch (bp[0]) { case 'A': /* AUTH= parameter */ if (!xtextok(&bp[1])) goto hackattack; e->e_auth_param = sm_rpool_strdup_x(e->e_rpool, &bp[1]); break; case 'B': /* body type */ r = check_bodytype(&bp[1]); if (!BODYTYPE_VALID(r)) goto hackattack; e->e_bodytype = sm_rpool_strdup_x(e->e_rpool, &bp[1]); break; case 'C': /* specify controlling user */ ctladdr = setctluser(&bp[1], qfver, e); break; case 'D': /* data file name */ /* obsolete -- ignore */ break; case 'd': /* data file directory name */ { int qgrp, qdir; #if _FFR_MSP_PARANOIA /* forbid queue groups in MSP? */ if (UseMSP) goto hackattack; #endif /* _FFR_MSP_PARANOIA */ for (qgrp = 0; qgrp < NumQueue && Queue[qgrp] != NULL; ++qgrp) { for (qdir = 0; qdir < Queue[qgrp]->qg_numqueues; ++qdir) { if (strcmp(&bp[1], Queue[qgrp]->qg_qpaths[qdir].qp_name) == 0) { e->e_dfqgrp = qgrp; e->e_dfqdir = qdir; goto done; } } } err = "bogus queue file directory"; goto fail; done: break; } case 'E': /* specify error recipient */ /* no longer used */ break; case 'F': /* flag bits */ if (strncmp(bp, "From ", 5) == 0) { /* we are being spoofed! */ syserr("SECURITY ALERT: bogus qf line %s", bp); err = "bogus queue line"; goto fail; } for (p = &bp[1]; *p != '\0'; p++) { switch (*p) { case '8': /* has 8 bit data */ e->e_flags |= EF_HAS8BIT; break; case 'b': /* delete Bcc: header */ e->e_flags |= EF_DELETE_BCC; break; case 'd': /* envelope has DSN RET= */ e->e_flags |= EF_RET_PARAM; break; case 'n': /* don't return body */ e->e_flags |= EF_NO_BODY_RETN; break; case 'r': /* response */ e->e_flags |= EF_RESPONSE; break; case 's': /* split */ e->e_flags |= EF_SPLIT; break; case 'w': /* warning sent */ e->e_flags |= EF_WARNING; break; } } break; case 'q': /* quarantine reason */ e->e_quarmsg = sm_rpool_strdup_x(e->e_rpool, &bp[1]); macdefine(&e->e_macro, A_PERM, macid("{quarantine}"), e->e_quarmsg); break; case 'H': /* header */ /* ** count size before chompheader() destroys the line. ** this isn't accurate due to macro expansion, but ** better than before. "-3" to skip H?? at least. */ hdrsize += strlen(bp) - 3; (void) chompheader(&bp[1], CHHDR_QUEUE, NULL, e); break; case 'I': /* data file's inode number */ /* regenerated below */ break; case 'K': /* time of last delivery attempt */ e->e_dtime = atol(&buf[1]); break; case 'L': /* Solaris Content-Length: */ case 'M': /* message */ /* ignore this; we want a new message next time */ break; case 'N': /* number of delivery attempts */ e->e_ntries = atoi(&buf[1]); /* if this has been tried recently, let it be */ now = curtime(); if (e->e_ntries > 0 && e->e_dtime <= now && now < e->e_dtime + MinQueueAge) { char *howlong; howlong = pintvl(now - e->e_dtime, true); if (Verbose) (void) sm_io_fprintf(smioout, SM_TIME_DEFAULT, "%s: too young (%s)\n", e->e_id, howlong); if (tTd(40, 8)) sm_dprintf("%s: too young (%s)\n", e->e_id, howlong); if (LogLevel > 19) sm_syslog(LOG_DEBUG, e->e_id, "too young (%s)", howlong); e->e_id = NULL; unlockqueue(e); return false; } macdefine(&e->e_macro, A_TEMP, macid("{ntries}"), &buf[1]); #if NAMED_BIND /* adjust BIND parameters immediately */ if (e->e_ntries == 0) { _res.retry = TimeOuts.res_retry[RES_TO_FIRST]; _res.retrans = TimeOuts.res_retrans[RES_TO_FIRST]; } else { _res.retry = TimeOuts.res_retry[RES_TO_NORMAL]; _res.retrans = TimeOuts.res_retrans[RES_TO_NORMAL]; } #endif /* NAMED_BIND */ break; case 'P': /* message priority */ e->e_msgpriority = atol(&bp[1]) + WkTimeFact; break; case 'Q': /* original recipient */ orcpt = sm_rpool_strdup_x(e->e_rpool, &bp[1]); break; case 'r': /* final recipient */ frcpt = sm_rpool_strdup_x(e->e_rpool, &bp[1]); break; case 'R': /* specify recipient */ p = bp; qflags = 0; if (qfver >= 1) { /* get flag bits */ while (*++p != '\0' && *p != ':') { switch (*p) { case 'N': qflags |= QHASNOTIFY; break; case 'S': qflags |= QPINGONSUCCESS; break; case 'F': qflags |= QPINGONFAILURE; break; case 'D': qflags |= QPINGONDELAY; break; case 'P': qflags |= QPRIMARY; break; case 'A': if (ctladdr != NULL) ctladdr->q_flags |= QALIAS; break; default: /* ignore or complain? */ break; } } } else qflags |= QPRIMARY; macdefine(&e->e_macro, A_PERM, macid("{addr_type}"), "e r"); if (*p != '\0') q = parseaddr(++p, NULLADDR, RF_COPYALL, '\0', NULL, e, true); else q = NULL; if (q != NULL) { /* make sure we keep the current qgrp */ if (ISVALIDQGRP(e->e_qgrp)) q->q_qgrp = e->e_qgrp; q->q_alias = ctladdr; if (qfver >= 1) q->q_flags &= ~Q_PINGFLAGS; q->q_flags |= qflags; q->q_finalrcpt = frcpt; q->q_orcpt = orcpt; (void) recipient(q, &e->e_sendqueue, 0, e); } frcpt = NULL; orcpt = NULL; macdefine(&e->e_macro, A_PERM, macid("{addr_type}"), NULL); break; case 'S': /* sender */ setsender(sm_rpool_strdup_x(e->e_rpool, &bp[1]), e, NULL, '\0', true); break; case 'T': /* init time */ e->e_ctime = atol(&bp[1]); break; case 'V': /* queue file version number */ qfver = atoi(&bp[1]); if (qfver <= QF_VERSION) break; syserr("Version number in queue file (%d) greater than max (%d)", qfver, QF_VERSION); err = "unsupported queue file version"; goto fail; /* NOTREACHED */ break; case 'Z': /* original envelope id from ESMTP */ e->e_envid = sm_rpool_strdup_x(e->e_rpool, &bp[1]); macdefine(&e->e_macro, A_PERM, macid("{dsn_envid}"), e->e_envid); break; case '!': /* deliver by */ /* format: flag (1 char) space long-integer */ e->e_dlvr_flag = buf[1]; e->e_deliver_by = strtol(&buf[3], NULL, 10); case '$': /* define macro */ { char *p; /* XXX elimate p? */ r = macid_parse(&bp[1], &ep); if (r == 0) break; p = sm_rpool_strdup_x(e->e_rpool, ep); macdefine(&e->e_macro, A_PERM, r, p); } break; case '.': /* terminate file */ nomore = true; break; #if _FFR_QUEUEDELAY case 'G': case 'Y': /* ** Maintain backward compatibility for ** users who defined _FFR_QUEUEDELAY in ** previous releases. Remove this ** code in 8.14 or 8.15. */ if (qfver == 5 || qfver == 7) break; /* If not qfver 5 or 7, then 'G' or 'Y' is invalid */ /* FALLTHROUGH */ #endif /* _FFR_QUEUEDELAY */ default: syserr("readqf: %s: line %d: bad line \"%s\"", qf, LineNumber, shortenstring(bp, MAXSHORTSTR)); err = "unrecognized line"; goto fail; } if (bp != buf) sm_free(bp); /* XXX */ } /* ** If we haven't read any lines, this queue file is empty. ** Arrange to remove it without referencing any null pointers. */ if (LineNumber == 0) { errno = 0; e->e_flags |= EF_CLRQUEUE|EF_FATALERRS|EF_RESPONSE; return true; } /* Check to make sure we have a complete queue file read */ if (!nomore) { syserr("readqf: %s: incomplete queue file read", qf); (void) sm_io_close(qfp, SM_TIME_DEFAULT); return false; } /* possibly set ${dsn_ret} macro */ if (bitset(EF_RET_PARAM, e->e_flags)) { if (bitset(EF_NO_BODY_RETN, e->e_flags)) macdefine(&e->e_macro, A_PERM, macid("{dsn_ret}"), "hdrs"); else macdefine(&e->e_macro, A_PERM, macid("{dsn_ret}"), "full"); } /* ** Arrange to read the data file. */ p = queuename(e, DATAFL_LETTER); e->e_dfp = sm_io_open(SmFtStdio, SM_TIME_DEFAULT, p, SM_IO_RDONLY_B, NULL); if (e->e_dfp == NULL) { syserr("readqf: cannot open %s", p); } else { e->e_flags |= EF_HAS_DF; if (fstat(sm_io_getinfo(e->e_dfp, SM_IO_WHAT_FD, NULL), &st) >= 0) { e->e_msgsize = st.st_size + hdrsize; e->e_dfdev = st.st_dev; e->e_dfino = ST_INODE(st); (void) sm_snprintf(buf, sizeof buf, "%ld", e->e_msgsize); macdefine(&e->e_macro, A_TEMP, macid("{msg_size}"), buf); } } return true; fail: /* ** There was some error reading the qf file (reason is in err var.) ** Cleanup: ** close file; clear e_lockfp since it is the same as qfp, ** hence it is invalid (as file) after qfp is closed; ** the qf file is on disk, so set the flag to avoid calling ** queueup() with bogus data. */ if (qfp != NULL) (void) sm_io_close(qfp, SM_TIME_DEFAULT); e->e_lockfp = NULL; e->e_flags |= EF_INQUEUE; loseqfile(e, err); return false; } /* ** PRTSTR -- print a string, "unprintable" characters are shown as \oct ** ** Parameters: ** s -- string to print ** ml -- maximum length of output ** ** Returns: ** number of entries ** ** Side Effects: ** Prints a string on stdout. */ static void prtstr(s, ml) char *s; int ml; { int c; if (s == NULL) return; while (ml-- > 0 && ((c = *s++) != '\0')) { if (c == '\\') { if (ml-- > 0) { (void) sm_io_putc(smioout, SM_TIME_DEFAULT, c); (void) sm_io_putc(smioout, SM_TIME_DEFAULT, c); } } else if (isascii(c) && isprint(c)) (void) sm_io_putc(smioout, SM_TIME_DEFAULT, c); else { if ((ml -= 3) > 0) (void) sm_io_fprintf(smioout, SM_TIME_DEFAULT, "\\%03o", c & 0xFF); } } } /* ** PRINTNQE -- print out number of entries in the mail queue ** ** Parameters: ** out -- output file pointer. ** prefix -- string to output in front of each line. ** ** Returns: ** none. */ void printnqe(out, prefix) SM_FILE_T *out; char *prefix; { #if SM_CONF_SHM int i, k = 0, nrequests = 0; bool unknown = false; if (ShmId == SM_SHM_NO_ID) { if (prefix == NULL) (void) sm_io_fprintf(out, SM_TIME_DEFAULT, "Data unavailable: shared memory not updated\n"); else (void) sm_io_fprintf(out, SM_TIME_DEFAULT, "%sNOTCONFIGURED:-1\r\n", prefix); return; } for (i = 0; i < NumQueue && Queue[i] != NULL; i++) { int j; k++; for (j = 0; j < Queue[i]->qg_numqueues; j++) { int n; if (StopRequest) stop_sendmail(); n = QSHM_ENTRIES(Queue[i]->qg_qpaths[j].qp_idx); if (prefix != NULL) (void) sm_io_fprintf(out, SM_TIME_DEFAULT, "%s%s:%d\r\n", prefix, qid_printqueue(i, j), n); else if (n < 0) { (void) sm_io_fprintf(out, SM_TIME_DEFAULT, "%s: unknown number of entries\n", qid_printqueue(i, j)); unknown = true; } else if (n == 0) { (void) sm_io_fprintf(out, SM_TIME_DEFAULT, "%s is empty\n", qid_printqueue(i, j)); } else if (n > 0) { (void) sm_io_fprintf(out, SM_TIME_DEFAULT, "%s: entries=%d\n", qid_printqueue(i, j), n); nrequests += n; k++; } } } if (prefix == NULL && k > 1) (void) sm_io_fprintf(out, SM_TIME_DEFAULT, "\t\tTotal requests: %d%s\n", nrequests, unknown ? " (about)" : ""); #else /* SM_CONF_SHM */ if (prefix == NULL) (void) sm_io_fprintf(out, SM_TIME_DEFAULT, "Data unavailable without shared memory support\n"); else (void) sm_io_fprintf(out, SM_TIME_DEFAULT, "%sNOTAVAILABLE:-1\r\n", prefix); #endif /* SM_CONF_SHM */ } /* ** PRINTQUEUE -- print out a representation of the mail queue ** ** Parameters: ** none. ** ** Returns: ** none. ** ** Side Effects: ** Prints a listing of the mail queue on the standard output. */ void printqueue() { int i, k = 0, nrequests = 0; for (i = 0; i < NumQueue && Queue[i] != NULL; i++) { int j; k++; for (j = 0; j < Queue[i]->qg_numqueues; j++) { if (StopRequest) stop_sendmail(); nrequests += print_single_queue(i, j); k++; } } if (k > 1) (void) sm_io_fprintf(smioout, SM_TIME_DEFAULT, "\t\tTotal requests: %d\n", nrequests); } /* ** PRINT_SINGLE_QUEUE -- print out a representation of a single mail queue ** ** Parameters: ** qgrp -- the index of the queue group. ** qdir -- the queue directory. ** ** Returns: ** number of requests in mail queue. ** ** Side Effects: ** Prints a listing of the mail queue on the standard output. */ int print_single_queue(qgrp, qdir) int qgrp; int qdir; { register WORK *w; SM_FILE_T *f; int nrequests; char qd[MAXPATHLEN]; char qddf[MAXPATHLEN]; char buf[MAXLINE]; if (qdir == NOQDIR) { (void) sm_strlcpy(qd, ".", sizeof qd); (void) sm_strlcpy(qddf, ".", sizeof qddf); } else { (void) sm_strlcpyn(qd, sizeof qd, 2, Queue[qgrp]->qg_qpaths[qdir].qp_name, (bitset(QP_SUBQF, Queue[qgrp]->qg_qpaths[qdir].qp_subdirs) ? "/qf" : "")); (void) sm_strlcpyn(qddf, sizeof qddf, 2, Queue[qgrp]->qg_qpaths[qdir].qp_name, (bitset(QP_SUBDF, Queue[qgrp]->qg_qpaths[qdir].qp_subdirs) ? "/df" : "")); } /* ** Check for permission to print the queue */ if (bitset(PRIV_RESTRICTMAILQ, PrivacyFlags) && RealUid != 0) { struct stat st; #ifdef NGROUPS_MAX int n; extern GIDSET_T InitialGidSet[NGROUPS_MAX]; #endif /* NGROUPS_MAX */ if (stat(qd, &st) < 0) { syserr("Cannot stat %s", qid_printqueue(qgrp, qdir)); return 0; } #ifdef NGROUPS_MAX n = NGROUPS_MAX; while (--n >= 0) { if (InitialGidSet[n] == st.st_gid) break; } if (n < 0 && RealGid != st.st_gid) #else /* NGROUPS_MAX */ if (RealGid != st.st_gid) #endif /* NGROUPS_MAX */ { usrerr("510 You are not permitted to see the queue"); setstat(EX_NOPERM); return 0; } } /* ** Read and order the queue. */ nrequests = gatherq(qgrp, qdir, true, NULL, NULL); (void) sortq(Queue[qgrp]->qg_maxlist); /* ** Print the work list that we have read. */ /* first see if there is anything */ if (nrequests <= 0) { (void) sm_io_fprintf(smioout, SM_TIME_DEFAULT, "%s is empty\n", qid_printqueue(qgrp, qdir)); return 0; } sm_getla(); /* get load average */ (void) sm_io_fprintf(smioout, SM_TIME_DEFAULT, "\t\t%s (%d request%s", qid_printqueue(qgrp, qdir), nrequests, nrequests == 1 ? "" : "s"); if (MaxQueueRun > 0 && nrequests > MaxQueueRun) (void) sm_io_fprintf(smioout, SM_TIME_DEFAULT, ", only %d printed", MaxQueueRun); if (Verbose) (void) sm_io_fprintf(smioout, SM_TIME_DEFAULT, ")\n-----Q-ID----- --Size-- -Priority- ---Q-Time--- --------Sender/Recipient--------\n"); else (void) sm_io_fprintf(smioout, SM_TIME_DEFAULT, ")\n-----Q-ID----- --Size-- -----Q-Time----- ------------Sender/Recipient-----------\n"); for (w = WorkQ; w != NULL; w = w->w_next) { struct stat st; auto time_t submittime = 0; long dfsize; int flags = 0; int qfver; char quarmsg[MAXLINE]; char statmsg[MAXLINE]; char bodytype[MAXNAME + 1]; char qf[MAXPATHLEN]; if (StopRequest) stop_sendmail(); (void) sm_io_fprintf(smioout, SM_TIME_DEFAULT, "%13s", w->w_name + 2); (void) sm_strlcpyn(qf, sizeof qf, 3, qd, "/", w->w_name); f = sm_io_open(SmFtStdio, SM_TIME_DEFAULT, qf, SM_IO_RDONLY_B, NULL); if (f == NULL) { if (errno == EPERM) (void) sm_io_fprintf(smioout, SM_TIME_DEFAULT, " (permission denied)\n"); else if (errno == ENOENT) (void) sm_io_fprintf(smioout, SM_TIME_DEFAULT, " (job completed)\n"); else (void) sm_io_fprintf(smioout, SM_TIME_DEFAULT, " (%s)\n", sm_errstring(errno)); errno = 0; continue; } w->w_name[0] = DATAFL_LETTER; (void) sm_strlcpyn(qf, sizeof qf, 3, qddf, "/", w->w_name); if (stat(qf, &st) >= 0) dfsize = st.st_size; else { ENVELOPE e; /* ** Maybe the df file can't be statted because ** it is in a different directory than the qf file. ** In order to find out, we must read the qf file. */ newenvelope(&e, &BlankEnvelope, sm_rpool_new_x(NULL)); e.e_id = w->w_name + 2; e.e_qgrp = qgrp; e.e_qdir = qdir; dfsize = -1; if (readqf(&e, false)) { char *df = queuename(&e, DATAFL_LETTER); if (stat(df, &st) >= 0) dfsize = st.st_size; } if (e.e_lockfp != NULL) { (void) sm_io_close(e.e_lockfp, SM_TIME_DEFAULT); e.e_lockfp = NULL; } clearenvelope(&e, false, e.e_rpool); sm_rpool_free(e.e_rpool); } if (w->w_lock) (void) sm_io_fprintf(smioout, SM_TIME_DEFAULT, "*"); else if (QueueMode == QM_LOST) (void) sm_io_fprintf(smioout, SM_TIME_DEFAULT, "?"); else if (w->w_tooyoung) (void) sm_io_fprintf(smioout, SM_TIME_DEFAULT, "-"); else if (shouldqueue(w->w_pri, w->w_ctime)) (void) sm_io_fprintf(smioout, SM_TIME_DEFAULT, "X"); else (void) sm_io_fprintf(smioout, SM_TIME_DEFAULT, " "); errno = 0; quarmsg[0] = '\0'; statmsg[0] = bodytype[0] = '\0'; qfver = 0; while (sm_io_fgets(f, SM_TIME_DEFAULT, buf, sizeof buf) != NULL) { register int i; register char *p; if (StopRequest) stop_sendmail(); fixcrlf(buf, true); switch (buf[0]) { case 'V': /* queue file version */ qfver = atoi(&buf[1]); break; case 'M': /* error message */ if ((i = strlen(&buf[1])) >= sizeof statmsg) i = sizeof statmsg - 1; memmove(statmsg, &buf[1], i); statmsg[i] = '\0'; break; case 'q': /* quarantine reason */ if ((i = strlen(&buf[1])) >= sizeof quarmsg) i = sizeof quarmsg - 1; memmove(quarmsg, &buf[1], i); quarmsg[i] = '\0'; break; case 'B': /* body type */ if ((i = strlen(&buf[1])) >= sizeof bodytype) i = sizeof bodytype - 1; memmove(bodytype, &buf[1], i); bodytype[i] = '\0'; break; case 'S': /* sender name */ if (Verbose) { (void) sm_io_fprintf(smioout, SM_TIME_DEFAULT, "%8ld %10ld%c%.12s ", dfsize, w->w_pri, bitset(EF_WARNING, flags) ? '+' : ' ', ctime(&submittime) + 4); prtstr(&buf[1], 78); } else { (void) sm_io_fprintf(smioout, SM_TIME_DEFAULT, "%8ld %.16s ", dfsize, ctime(&submittime)); prtstr(&buf[1], 39); } if (quarmsg[0] != '\0') { (void) sm_io_fprintf(smioout, SM_TIME_DEFAULT, "\n QUARANTINE: %.*s", Verbose ? 100 : 60, quarmsg); quarmsg[0] = '\0'; } if (statmsg[0] != '\0' || bodytype[0] != '\0') { (void) sm_io_fprintf(smioout, SM_TIME_DEFAULT, "\n %10.10s", bodytype); if (statmsg[0] != '\0') (void) sm_io_fprintf(smioout, SM_TIME_DEFAULT, " (%.*s)", Verbose ? 100 : 60, statmsg); statmsg[0] = '\0'; } break; case 'C': /* controlling user */ if (Verbose) (void) sm_io_fprintf(smioout, SM_TIME_DEFAULT, "\n\t\t\t\t\t\t(---%.64s---)", &buf[1]); break; case 'R': /* recipient name */ p = &buf[1]; if (qfver >= 1) { p = strchr(p, ':'); if (p == NULL) break; p++; } if (Verbose) { (void) sm_io_fprintf(smioout, SM_TIME_DEFAULT, "\n\t\t\t\t\t\t"); prtstr(p, 71); } else { (void) sm_io_fprintf(smioout, SM_TIME_DEFAULT, "\n\t\t\t\t\t "); prtstr(p, 38); } if (Verbose && statmsg[0] != '\0') { (void) sm_io_fprintf(smioout, SM_TIME_DEFAULT, "\n\t\t (%.100s)", statmsg); statmsg[0] = '\0'; } break; case 'T': /* creation time */ submittime = atol(&buf[1]); break; case 'F': /* flag bits */ for (p = &buf[1]; *p != '\0'; p++) { switch (*p) { case 'w': flags |= EF_WARNING; break; } } } } if (submittime == (time_t) 0) (void) sm_io_fprintf(smioout, SM_TIME_DEFAULT, " (no control file)"); (void) sm_io_fprintf(smioout, SM_TIME_DEFAULT, "\n"); (void) sm_io_close(f, SM_TIME_DEFAULT); } return nrequests; } /* ** QUEUE_LETTER -- get the proper queue letter for the current QueueMode. ** ** Parameters: ** e -- envelope to build it in/from. ** type -- the file type, used as the first character ** of the file name. ** ** Returns: ** the letter to use */ static char queue_letter(e, type) ENVELOPE *e; int type; { /* Change type according to QueueMode */ if (type == ANYQFL_LETTER) { if (e->e_quarmsg != NULL) type = QUARQF_LETTER; else { switch (QueueMode) { case QM_NORMAL: type = NORMQF_LETTER; break; case QM_QUARANTINE: type = QUARQF_LETTER; break; case QM_LOST: type = LOSEQF_LETTER; break; default: /* should never happen */ abort(); /* NOTREACHED */ } } } return type; } /* ** QUEUENAME -- build a file name in the queue directory for this envelope. ** ** Parameters: ** e -- envelope to build it in/from. ** type -- the file type, used as the first character ** of the file name. ** ** Returns: ** a pointer to the queue name (in a static buffer). ** ** Side Effects: ** If no id code is already assigned, queuename() will ** assign an id code with assign_queueid(). If no queue ** directory is assigned, one will be set with setnewqueue(). */ char * queuename(e, type) register ENVELOPE *e; int type; { int qd, qg; char *sub = "/"; char pref[3]; static char buf[MAXPATHLEN]; /* Assign an ID if needed */ if (e->e_id == NULL) assign_queueid(e); type = queue_letter(e, type); /* begin of filename */ pref[0] = (char) type; pref[1] = 'f'; pref[2] = '\0'; /* Assign a queue group/directory if needed */ if (type == XSCRPT_LETTER) { /* ** We don't want to call setnewqueue() if we are fetching ** the pathname of the transcript file, because setnewqueue ** chooses a queue, and sometimes we need to write to the ** transcript file before we have gathered enough information ** to choose a queue. */ if (e->e_xfqgrp == NOQGRP || e->e_xfqdir == NOQDIR) { if (e->e_qgrp != NOQGRP && e->e_qdir != NOQDIR) { e->e_xfqgrp = e->e_qgrp; e->e_xfqdir = e->e_qdir; } else { e->e_xfqgrp = 0; if (Queue[e->e_xfqgrp]->qg_numqueues <= 1) e->e_xfqdir = 0; else { e->e_xfqdir = get_rand_mod( Queue[e->e_xfqgrp]->qg_numqueues); } } } qd = e->e_xfqdir; qg = e->e_xfqgrp; } else { if (e->e_qgrp == NOQGRP || e->e_qdir == NOQDIR) setnewqueue(e); if (type == DATAFL_LETTER) { qd = e->e_dfqdir; qg = e->e_dfqgrp; } else { qd = e->e_qdir; qg = e->e_qgrp; } } /* xf files always have a valid qd and qg picked above */ if (e->e_qdir == NOQDIR && type != XSCRPT_LETTER) (void) sm_strlcpyn(buf, sizeof buf, 2, pref, e->e_id); else { switch (type) { case DATAFL_LETTER: if (bitset(QP_SUBDF, Queue[qg]->qg_qpaths[qd].qp_subdirs)) sub = "/df/"; break; case QUARQF_LETTER: case TEMPQF_LETTER: case NEWQFL_LETTER: case LOSEQF_LETTER: case NORMQF_LETTER: if (bitset(QP_SUBQF, Queue[qg]->qg_qpaths[qd].qp_subdirs)) sub = "/qf/"; break; case XSCRPT_LETTER: if (bitset(QP_SUBXF, Queue[qg]->qg_qpaths[qd].qp_subdirs)) sub = "/xf/"; break; default: sm_abort("queuename: bad queue file type %d", type); } (void) sm_strlcpyn(buf, sizeof buf, 4, Queue[qg]->qg_qpaths[qd].qp_name, sub, pref, e->e_id); } if (tTd(7, 2)) sm_dprintf("queuename: %s\n", buf); return buf; } /* ** INIT_QID_ALG -- Initialize the (static) parameters that are used to ** generate a queue ID. ** ** This function is called by the daemon to reset ** LastQueueTime and LastQueuePid which are used by assign_queueid(). ** Otherwise the algorithm may cause problems because ** LastQueueTime and LastQueuePid are set indirectly by main() ** before the daemon process is started, hence LastQueuePid is not ** the pid of the daemon and therefore a child of the daemon can ** actually have the same pid as LastQueuePid which means the section ** in assign_queueid(): ** * see if we need to get a new base time/pid * ** is NOT triggered which will cause the same queue id to be generated. ** ** Parameters: ** none ** ** Returns: ** none. */ void init_qid_alg() { LastQueueTime = 0; LastQueuePid = -1; } /* ** ASSIGN_QUEUEID -- assign a queue ID for this envelope. ** ** Assigns an id code if one does not already exist. ** This code assumes that nothing will remain in the queue for ** longer than 60 years. It is critical that files with the given ** name do not already exist in the queue. ** [No longer initializes e_qdir to NOQDIR.] ** ** Parameters: ** e -- envelope to set it in. ** ** Returns: ** none. */ static const char QueueIdChars[] = "0123456789ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijklmnopqrstuvwxyz"; # define QIC_LEN 60 # define QIC_LEN_R 62 /* ** Note: the length is "officially" 60 because minutes and seconds are ** usually only 0-59. However (Linux): ** tm_sec The number of seconds after the minute, normally in ** the range 0 to 59, but can be up to 61 to allow for ** leap seconds. ** Hence the real length of the string is 62 to take this into account. ** Alternatively % QIC_LEN can (should) be used for access everywhere. */ # define queuenextid() CurrentPid void assign_queueid(e) register ENVELOPE *e; { pid_t pid = queuenextid(); static int cX = 0; static long random_offset; struct tm *tm; char idbuf[MAXQFNAME - 2]; int seq; if (e->e_id != NULL) return; /* see if we need to get a new base time/pid */ if (cX >= QIC_LEN * QIC_LEN || LastQueueTime == 0 || LastQueuePid != pid) { time_t then = LastQueueTime; /* if the first time through, pick a random offset */ if (LastQueueTime == 0) random_offset = get_random(); while ((LastQueueTime = curtime()) == then && LastQueuePid == pid) { (void) sleep(1); } LastQueuePid = queuenextid(); cX = 0; } /* ** Generate a new sequence number between 0 and QIC_LEN*QIC_LEN-1. ** This lets us generate up to QIC_LEN*QIC_LEN unique queue ids ** per second, per process. With envelope splitting, ** a single message can consume many queue ids. */ seq = (int)((cX + random_offset) % (QIC_LEN * QIC_LEN)); ++cX; if (tTd(7, 50)) sm_dprintf("assign_queueid: random_offset = %ld (%d)\n", random_offset, seq); tm = gmtime(&LastQueueTime); idbuf[0] = QueueIdChars[tm->tm_year % QIC_LEN]; idbuf[1] = QueueIdChars[tm->tm_mon]; idbuf[2] = QueueIdChars[tm->tm_mday]; idbuf[3] = QueueIdChars[tm->tm_hour]; idbuf[4] = QueueIdChars[tm->tm_min % QIC_LEN_R]; idbuf[5] = QueueIdChars[tm->tm_sec % QIC_LEN_R]; idbuf[6] = QueueIdChars[seq / QIC_LEN]; idbuf[7] = QueueIdChars[seq % QIC_LEN]; (void) sm_snprintf(&idbuf[8], sizeof idbuf - 8, "%06d", (int) LastQueuePid); e->e_id = sm_rpool_strdup_x(e->e_rpool, idbuf); macdefine(&e->e_macro, A_PERM, 'i', e->e_id); #if 0 /* XXX: inherited from MainEnvelope */ e->e_qgrp = NOQGRP; /* too early to do anything else */ e->e_qdir = NOQDIR; e->e_xfqgrp = NOQGRP; #endif /* 0 */ /* New ID means it's not on disk yet */ e->e_qfletter = '\0'; if (tTd(7, 1)) sm_dprintf("assign_queueid: assigned id %s, e=%p\n", e->e_id, e); if (LogLevel > 93) sm_syslog(LOG_DEBUG, e->e_id, "assigned id"); } /* ** SYNC_QUEUE_TIME -- Assure exclusive PID in any given second ** ** Make sure one PID can't be used by two processes in any one second. ** ** If the system rotates PIDs fast enough, may get the ** same pid in the same second for two distinct processes. ** This will interfere with the queue file naming system. ** ** Parameters: ** none ** ** Returns: ** none */ void sync_queue_time() { #if FAST_PID_RECYCLE if (OpMode != MD_TEST && OpMode != MD_VERIFY && LastQueueTime > 0 && LastQueuePid == CurrentPid && curtime() == LastQueueTime) (void) sleep(1); #endif /* FAST_PID_RECYCLE */ } /* ** UNLOCKQUEUE -- unlock the queue entry for a specified envelope ** ** Parameters: ** e -- the envelope to unlock. ** ** Returns: ** none ** ** Side Effects: ** unlocks the queue for `e'. */ void unlockqueue(e) ENVELOPE *e; { if (tTd(51, 4)) sm_dprintf("unlockqueue(%s)\n", e->e_id == NULL ? "NOQUEUE" : e->e_id); /* if there is a lock file in the envelope, close it */ if (e->e_lockfp != NULL) (void) sm_io_close(e->e_lockfp, SM_TIME_DEFAULT); e->e_lockfp = NULL; /* don't create a queue id if we don't already have one */ if (e->e_id == NULL) return; /* remove the transcript */ if (LogLevel > 87) sm_syslog(LOG_DEBUG, e->e_id, "unlock"); if (!tTd(51, 104)) (void) xunlink(queuename(e, XSCRPT_LETTER)); } /* ** SETCTLUSER -- create a controlling address ** ** Create a fake "address" given only a local login name; this is ** used as a "controlling user" for future recipient addresses. ** ** Parameters: ** user -- the user name of the controlling user. ** qfver -- the version stamp of this queue file. ** e -- envelope ** ** Returns: ** An address descriptor for the controlling user, ** using storage allocated from e->e_rpool. ** */ static ADDRESS * setctluser(user, qfver, e) char *user; int qfver; ENVELOPE *e; { register ADDRESS *a; struct passwd *pw; char *p; /* ** See if this clears our concept of controlling user. */ if (user == NULL || *user == '\0') return NULL; /* ** Set up addr fields for controlling user. */ a = (ADDRESS *) sm_rpool_malloc_x(e->e_rpool, sizeof *a); memset((char *) a, '\0', sizeof *a); if (*user == ':') { p = &user[1]; a->q_user = sm_rpool_strdup_x(e->e_rpool, p); } else { p = strtok(user, ":"); a->q_user = sm_rpool_strdup_x(e->e_rpool, user); if (qfver >= 2) { if ((p = strtok(NULL, ":")) != NULL) a->q_uid = atoi(p); if ((p = strtok(NULL, ":")) != NULL) a->q_gid = atoi(p); if ((p = strtok(NULL, ":")) != NULL) { char *o; a->q_flags |= QGOODUID; /* if there is another ':': restore it */ if ((o = strtok(NULL, ":")) != NULL && o > p) o[-1] = ':'; } } else if ((pw = sm_getpwnam(user)) != NULL) { if (*pw->pw_dir == '\0') a->q_home = NULL; else if (strcmp(pw->pw_dir, "/") == 0) a->q_home = ""; else a->q_home = sm_rpool_strdup_x(e->e_rpool, pw->pw_dir); a->q_uid = pw->pw_uid; a->q_gid = pw->pw_gid; a->q_flags |= QGOODUID; } } a->q_flags |= QPRIMARY; /* flag as a "ctladdr" */ a->q_mailer = LocalMailer; if (p == NULL) a->q_paddr = sm_rpool_strdup_x(e->e_rpool, a->q_user); else a->q_paddr = sm_rpool_strdup_x(e->e_rpool, p); return a; } /* ** LOSEQFILE -- rename queue file with LOSEQF_LETTER & try to let someone know ** ** Parameters: ** e -- the envelope (e->e_id will be used). ** why -- reported to whomever can hear. ** ** Returns: ** none. */ void loseqfile(e, why) register ENVELOPE *e; char *why; { bool loseit = true; char *p; char buf[MAXPATHLEN]; if (e == NULL || e->e_id == NULL) return; p = queuename(e, ANYQFL_LETTER); if (sm_strlcpy(buf, p, sizeof buf) >= sizeof buf) return; if (!bitset(EF_INQUEUE, e->e_flags)) queueup(e, false, true); else if (QueueMode == QM_LOST) loseit = false; /* if already lost, no need to re-lose */ if (loseit) { p = queuename(e, LOSEQF_LETTER); if (rename(buf, p) < 0) syserr("cannot rename(%s, %s), uid=%d", buf, p, (int) geteuid()); else if (LogLevel > 0) sm_syslog(LOG_ALERT, e->e_id, "Losing %s: %s", buf, why); } if (e->e_dfp != NULL) { (void) sm_io_close(e->e_dfp, SM_TIME_DEFAULT); e->e_dfp = NULL; } e->e_flags &= ~EF_HAS_DF; } /* ** NAME2QID -- translate a queue group name to a queue group id ** ** Parameters: ** queuename -- name of queue group. ** ** Returns: ** queue group id if found. ** NOQGRP otherwise. */ int name2qid(queuename) char *queuename; { register STAB *s; s = stab(queuename, ST_QUEUE, ST_FIND); if (s == NULL) return NOQGRP; return s->s_quegrp->qg_index; } /* ** QID_PRINTNAME -- create externally printable version of queue id ** ** Parameters: ** e -- the envelope. ** ** Returns: ** a printable version */ char * qid_printname(e) ENVELOPE *e; { char *id; static char idbuf[MAXQFNAME + 34]; if (e == NULL) return ""; if (e->e_id == NULL) id = ""; else id = e->e_id; if (e->e_qdir == NOQDIR) return id; (void) sm_snprintf(idbuf, sizeof idbuf, "%.32s/%s", Queue[e->e_qgrp]->qg_qpaths[e->e_qdir].qp_name, id); return idbuf; } /* ** QID_PRINTQUEUE -- create full version of queue directory for data files ** ** Parameters: ** qgrp -- index in queue group. ** qdir -- the short version of the queue directory ** ** Returns: ** the full pathname to the queue (might point to a static var) */ char * qid_printqueue(qgrp, qdir) int qgrp; int qdir; { char *subdir; static char dir[MAXPATHLEN]; if (qdir == NOQDIR) return Queue[qgrp]->qg_qdir; if (strcmp(Queue[qgrp]->qg_qpaths[qdir].qp_name, ".") == 0) subdir = NULL; else subdir = Queue[qgrp]->qg_qpaths[qdir].qp_name; (void) sm_strlcpyn(dir, sizeof dir, 4, Queue[qgrp]->qg_qdir, subdir == NULL ? "" : "/", subdir == NULL ? "" : subdir, (bitset(QP_SUBDF, Queue[qgrp]->qg_qpaths[qdir].qp_subdirs) ? "/df" : "")); return dir; } /* ** PICKQDIR -- Pick a queue directory from a queue group ** ** Parameters: ** qg -- queue group ** fsize -- file size in bytes ** e -- envelope, or NULL ** ** Result: ** NOQDIR if no queue directory in qg has enough free space to ** hold a file of size 'fsize', otherwise the index of ** a randomly selected queue directory which resides on a ** file system with enough disk space. ** XXX This could be extended to select a queuedir with ** a few (the fewest?) number of entries. That data ** is available if shared memory is used. ** ** Side Effects: ** If the request fails and e != NULL then sm_syslog is called. */ int pickqdir(qg, fsize, e) QUEUEGRP *qg; long fsize; ENVELOPE *e; { int qdir; int i; long avail = 0; /* Pick a random directory, as a starting point. */ if (qg->qg_numqueues <= 1) qdir = 0; else qdir = get_rand_mod(qg->qg_numqueues); if (MinBlocksFree <= 0 && fsize <= 0) return qdir; /* ** Now iterate over the queue directories, ** looking for a directory with enough space for this message. */ i = qdir; do { QPATHS *qp = &qg->qg_qpaths[i]; long needed = 0; long fsavail = 0; if (fsize > 0) needed += fsize / FILE_SYS_BLKSIZE(qp->qp_fsysidx) + ((fsize % FILE_SYS_BLKSIZE(qp->qp_fsysidx) > 0) ? 1 : 0); if (MinBlocksFree > 0) needed += MinBlocksFree; fsavail = FILE_SYS_AVAIL(qp->qp_fsysidx); #if SM_CONF_SHM if (fsavail <= 0) { long blksize; /* ** might be not correctly updated, ** let's try to get the info directly. */ fsavail = freediskspace(FILE_SYS_NAME(qp->qp_fsysidx), &blksize); if (fsavail < 0) fsavail = 0; } #endif /* SM_CONF_SHM */ if (needed <= fsavail) return i; if (avail < fsavail) avail = fsavail; if (qg->qg_numqueues > 0) i = (i + 1) % qg->qg_numqueues; } while (i != qdir); if (e != NULL && LogLevel > 0) sm_syslog(LOG_ALERT, e->e_id, "low on space (%s needs %ld bytes + %ld blocks in %s), max avail: %ld", CurHostName == NULL ? "SMTP-DAEMON" : CurHostName, fsize, MinBlocksFree, qg->qg_qdir, avail); return NOQDIR; } /* ** SETNEWQUEUE -- Sets a new queue group and directory ** ** Assign a queue group and directory to an envelope and store the ** directory in e->e_qdir. ** ** Parameters: ** e -- envelope to assign a queue for. ** ** Returns: ** true if successful ** false otherwise ** ** Side Effects: ** On success, e->e_qgrp and e->e_qdir are non-negative. ** On failure (not enough disk space), ** e->qgrp = NOQGRP, e->e_qdir = NOQDIR ** and usrerr() is invoked (which could raise an exception). */ bool setnewqueue(e) ENVELOPE *e; { if (tTd(41, 20)) sm_dprintf("setnewqueue: called\n"); /* not set somewhere else */ if (e->e_qgrp == NOQGRP) { ADDRESS *q; /* ** Use the queue group of the "first" recipient, as set by ** the "queuegroup" rule set. If that is not defined, then ** use the queue group of the mailer of the first recipient. ** If that is not defined either, then use the default ** queue group. ** Notice: "first" depends on the sorting of sendqueue ** in recipient(). ** To avoid problems with "bad" recipients look ** for a valid address first. */ q = e->e_sendqueue; while (q != NULL && (QS_IS_BADADDR(q->q_state) || QS_IS_DEAD(q->q_state))) { q = q->q_next; } if (q == NULL) e->e_qgrp = 0; else if (q->q_qgrp >= 0) e->e_qgrp = q->q_qgrp; else if (q->q_mailer != NULL && ISVALIDQGRP(q->q_mailer->m_qgrp)) e->e_qgrp = q->q_mailer->m_qgrp; else e->e_qgrp = 0; e->e_dfqgrp = e->e_qgrp; } if (ISVALIDQDIR(e->e_qdir) && ISVALIDQDIR(e->e_dfqdir)) { if (tTd(41, 20)) sm_dprintf("setnewqueue: e_qdir already assigned (%s)\n", qid_printqueue(e->e_qgrp, e->e_qdir)); return true; } filesys_update(); e->e_qdir = pickqdir(Queue[e->e_qgrp], e->e_msgsize, e); if (e->e_qdir == NOQDIR) { e->e_qgrp = NOQGRP; if (!bitset(EF_FATALERRS, e->e_flags)) usrerr("452 4.4.5 Insufficient disk space; try again later"); e->e_flags |= EF_FATALERRS; return false; } if (tTd(41, 3)) sm_dprintf("setnewqueue: Assigned queue directory %s\n", qid_printqueue(e->e_qgrp, e->e_qdir)); if (e->e_xfqgrp == NOQGRP || e->e_xfqdir == NOQDIR) { e->e_xfqgrp = e->e_qgrp; e->e_xfqdir = e->e_qdir; } e->e_dfqdir = e->e_qdir; return true; } /* ** CHKQDIR -- check a queue directory ** ** Parameters: ** name -- name of queue directory ** sff -- flags for safefile() ** ** Returns: ** is it a queue directory? */ static bool chkqdir(name, sff) char *name; long sff; { struct stat statb; int i; /* skip over . and .. directories */ if (name[0] == '.' && (name[1] == '\0' || (name[1] == '.' && name[2] == '\0'))) return false; #if HASLSTAT if (lstat(name, &statb) < 0) #else /* HASLSTAT */ if (stat(name, &statb) < 0) #endif /* HASLSTAT */ { if (tTd(41, 2)) sm_dprintf("chkqdir: stat(\"%s\"): %s\n", name, sm_errstring(errno)); return false; } #if HASLSTAT if (S_ISLNK(statb.st_mode)) { /* ** For a symlink we need to make sure the ** target is a directory */ if (stat(name, &statb) < 0) { if (tTd(41, 2)) sm_dprintf("chkqdir: stat(\"%s\"): %s\n", name, sm_errstring(errno)); return false; } } #endif /* HASLSTAT */ if (!S_ISDIR(statb.st_mode)) { if (tTd(41, 2)) sm_dprintf("chkqdir: \"%s\": Not a directory\n", name); return false; } /* Print a warning if unsafe (but still use it) */ /* XXX do this only if we want the warning? */ i = safedirpath(name, RunAsUid, RunAsGid, NULL, sff, 0, 0); if (i != 0) { if (tTd(41, 2)) sm_dprintf("chkqdir: \"%s\": Not safe: %s\n", name, sm_errstring(i)); #if _FFR_CHK_QUEUE if (LogLevel > 8) sm_syslog(LOG_WARNING, NOQID, "queue directory \"%s\": Not safe: %s", name, sm_errstring(i)); #endif /* _FFR_CHK_QUEUE */ } return true; } /* ** MULTIQUEUE_CACHE -- cache a list of paths to queues. ** ** Each potential queue is checked as the cache is built. ** Thereafter, each is blindly trusted. ** Note that we can be called again after a timeout to rebuild ** (although code for that is not ready yet). ** ** Parameters: ** basedir -- base of all queue directories. ** blen -- strlen(basedir). ** qg -- queue group. ** qn -- number of queue directories already cached. ** phash -- pointer to hash value over queue dirs. #if SM_CONF_SHM ** only used if shared memory is active. #endif * SM_CONF_SHM * ** ** Returns: ** new number of queue directories. */ #define INITIAL_SLOTS 20 #define ADD_SLOTS 10 static int multiqueue_cache(basedir, blen, qg, qn, phash) char *basedir; int blen; QUEUEGRP *qg; int qn; unsigned int *phash; { char *cp; int i, len; int slotsleft = 0; long sff = SFF_ANYFILE; char qpath[MAXPATHLEN]; char subdir[MAXPATHLEN]; char prefix[MAXPATHLEN]; /* dir relative to basedir */ if (tTd(41, 20)) sm_dprintf("multiqueue_cache: called\n"); /* Initialize to current directory */ prefix[0] = '.'; prefix[1] = '\0'; if (qg->qg_numqueues != 0 && qg->qg_qpaths != NULL) { for (i = 0; i < qg->qg_numqueues; i++) { if (qg->qg_qpaths[i].qp_name != NULL) (void) sm_free(qg->qg_qpaths[i].qp_name); /* XXX */ } (void) sm_free((char *) qg->qg_qpaths); /* XXX */ qg->qg_qpaths = NULL; qg->qg_numqueues = 0; } /* If running as root, allow safedirpath() checks to use privs */ if (RunAsUid == 0) sff |= SFF_ROOTOK; #if _FFR_CHK_QUEUE sff |= SFF_SAFEDIRPATH|SFF_NOWWFILES; if (!UseMSP) sff |= SFF_NOGWFILES; #endif /* _FFR_CHK_QUEUE */ if (!SM_IS_DIR_START(qg->qg_qdir)) { /* ** XXX we could add basedir, but then we have to realloc() ** the string... Maybe another time. */ syserr("QueuePath %s not absolute", qg->qg_qdir); ExitStat = EX_CONFIG; return qn; } /* qpath: directory of current workgroup */ len = sm_strlcpy(qpath, qg->qg_qdir, sizeof qpath); if (len >= sizeof qpath) { syserr("QueuePath %.256s too long (%d max)", qg->qg_qdir, (int) sizeof qpath); ExitStat = EX_CONFIG; return qn; } /* begin of qpath must be same as basedir */ if (strncmp(basedir, qpath, blen) != 0 && (strncmp(basedir, qpath, blen - 1) != 0 || len != blen - 1)) { syserr("QueuePath %s not subpath of QueueDirectory %s", qpath, basedir); ExitStat = EX_CONFIG; return qn; } /* Do we have a nested subdirectory? */ if (blen < len && SM_FIRST_DIR_DELIM(qg->qg_qdir + blen) != NULL) { /* Copy subdirectory into prefix for later use */ if (sm_strlcpy(prefix, qg->qg_qdir + blen, sizeof prefix) >= sizeof prefix) { syserr("QueuePath %.256s too long (%d max)", qg->qg_qdir, (int) sizeof qpath); ExitStat = EX_CONFIG; return qn; } cp = SM_LAST_DIR_DELIM(prefix); SM_ASSERT(cp != NULL); *cp = '\0'; /* cut off trailing / */ } /* This is guaranteed by the basedir check above */ SM_ASSERT(len >= blen - 1); cp = &qpath[len - 1]; if (*cp == '*') { register DIR *dp; register struct dirent *d; int off; char *delim; char relpath[MAXPATHLEN]; *cp = '\0'; /* Overwrite wildcard */ if ((cp = SM_LAST_DIR_DELIM(qpath)) == NULL) { syserr("QueueDirectory: can not wildcard relative path"); if (tTd(41, 2)) sm_dprintf("multiqueue_cache: \"%s*\": Can not wildcard relative path.\n", qpath); ExitStat = EX_CONFIG; return qn; } if (cp == qpath) { /* ** Special case of top level wildcard, like /foo* ** Change to //foo* */ (void) sm_strlcpy(qpath + 1, qpath, sizeof qpath - 1); ++cp; } delim = cp; *(cp++) = '\0'; /* Replace / with \0 */ len = strlen(cp); /* Last component of queue directory */ /* ** Path relative to basedir, with trailing / ** It will be modified below to specify the subdirectories ** so they can be opened without chdir(). */ off = sm_strlcpyn(relpath, sizeof relpath, 2, prefix, "/"); SM_ASSERT(off < sizeof relpath); if (tTd(41, 2)) sm_dprintf("multiqueue_cache: prefix=\"%s%s\"\n", relpath, cp); /* It is always basedir: we don't need to store it per group */ /* XXX: optimize this! -> one more global? */ qg->qg_qdir = newstr(basedir); qg->qg_qdir[blen - 1] = '\0'; /* cut off trailing / */ /* ** XXX Should probably wrap this whole loop in a timeout ** in case some wag decides to NFS mount the queues. */ /* Test path to get warning messages. */ if (qn == 0) { /* XXX qg_runasuid and qg_runasgid for specials? */ i = safedirpath(basedir, RunAsUid, RunAsGid, NULL, sff, 0, 0); if (i != 0 && tTd(41, 2)) sm_dprintf("multiqueue_cache: \"%s\": Not safe: %s\n", basedir, sm_errstring(i)); } if ((dp = opendir(prefix)) == NULL) { syserr("can not opendir(%s/%s)", qg->qg_qdir, prefix); if (tTd(41, 2)) sm_dprintf("multiqueue_cache: opendir(\"%s/%s\"): %s\n", qg->qg_qdir, prefix, sm_errstring(errno)); ExitStat = EX_CONFIG; return qn; } while ((d = readdir(dp)) != NULL) { i = strlen(d->d_name); if (i < len || strncmp(d->d_name, cp, len) != 0) { if (tTd(41, 5)) sm_dprintf("multiqueue_cache: \"%s\", skipped\n", d->d_name); continue; } /* Create relative pathname: prefix + local directory */ i = sizeof(relpath) - off; if (sm_strlcpy(relpath + off, d->d_name, i) >= i) continue; /* way too long */ if (!chkqdir(relpath, sff)) continue; if (qg->qg_qpaths == NULL) { slotsleft = INITIAL_SLOTS; qg->qg_qpaths = (QPATHS *)xalloc((sizeof *qg->qg_qpaths) * slotsleft); qg->qg_numqueues = 0; } else if (slotsleft < 1) { qg->qg_qpaths = (QPATHS *)sm_realloc((char *)qg->qg_qpaths, (sizeof *qg->qg_qpaths) * (qg->qg_numqueues + ADD_SLOTS)); if (qg->qg_qpaths == NULL) { (void) closedir(dp); return qn; } slotsleft += ADD_SLOTS; } /* check subdirs */ qg->qg_qpaths[qg->qg_numqueues].qp_subdirs = QP_NOSUB; #define CHKRSUBDIR(name, flag) \ (void) sm_strlcpyn(subdir, sizeof subdir, 3, relpath, "/", name); \ if (chkqdir(subdir, sff)) \ qg->qg_qpaths[qg->qg_numqueues].qp_subdirs |= flag; \ else CHKRSUBDIR("qf", QP_SUBQF); CHKRSUBDIR("df", QP_SUBDF); CHKRSUBDIR("xf", QP_SUBXF); /* assert(strlen(d->d_name) < MAXPATHLEN - 14) */ /* maybe even - 17 (subdirs) */ if (prefix[0] != '.') qg->qg_qpaths[qg->qg_numqueues].qp_name = newstr(relpath); else qg->qg_qpaths[qg->qg_numqueues].qp_name = newstr(d->d_name); if (tTd(41, 2)) sm_dprintf("multiqueue_cache: %d: \"%s\" cached (%x).\n", qg->qg_numqueues, relpath, qg->qg_qpaths[qg->qg_numqueues].qp_subdirs); #if SM_CONF_SHM qg->qg_qpaths[qg->qg_numqueues].qp_idx = qn; *phash = hash_q(relpath, *phash); #endif /* SM_CONF_SHM */ qg->qg_numqueues++; ++qn; slotsleft--; } (void) closedir(dp); /* undo damage */ *delim = '/'; } if (qg->qg_numqueues == 0) { qg->qg_qpaths = (QPATHS *) xalloc(sizeof *qg->qg_qpaths); /* test path to get warning messages */ i = safedirpath(qpath, RunAsUid, RunAsGid, NULL, sff, 0, 0); if (i == ENOENT) { syserr("can not opendir(%s)", qpath); if (tTd(41, 2)) sm_dprintf("multiqueue_cache: opendir(\"%s\"): %s\n", qpath, sm_errstring(i)); ExitStat = EX_CONFIG; return qn; } qg->qg_qpaths[0].qp_subdirs = QP_NOSUB; qg->qg_numqueues = 1; /* check subdirs */ #define CHKSUBDIR(name, flag) \ (void) sm_strlcpyn(subdir, sizeof subdir, 3, qg->qg_qdir, "/", name); \ if (chkqdir(subdir, sff)) \ qg->qg_qpaths[0].qp_subdirs |= flag; \ else CHKSUBDIR("qf", QP_SUBQF); CHKSUBDIR("df", QP_SUBDF); CHKSUBDIR("xf", QP_SUBXF); if (qg->qg_qdir[blen - 1] != '\0' && qg->qg_qdir[blen] != '\0') { /* ** Copy the last component into qpaths and ** cut off qdir */ qg->qg_qpaths[0].qp_name = newstr(qg->qg_qdir + blen); qg->qg_qdir[blen - 1] = '\0'; } else qg->qg_qpaths[0].qp_name = newstr("."); #if SM_CONF_SHM qg->qg_qpaths[0].qp_idx = qn; *phash = hash_q(qg->qg_qpaths[0].qp_name, *phash); #endif /* SM_CONF_SHM */ ++qn; } return qn; } /* ** FILESYS_FIND -- find entry in FileSys table, or add new one ** ** Given the pathname of a directory, determine the file system ** in which that directory resides, and return a pointer to the ** entry in the FileSys table that describes the file system. ** A new entry is added if necessary (and requested). ** If the directory does not exist, -1 is returned. ** ** Parameters: ** name -- name of directory (must be persistent!) ** path -- pathname of directory (name plus maybe "/df") ** add -- add to structure if not found. ** ** Returns: ** >=0: found: index in file system table ** <0: some error, i.e., ** FSF_TOO_MANY: too many filesystems (-> syserr()) ** FSF_STAT_FAIL: can't stat() filesystem (-> syserr()) ** FSF_NOT_FOUND: not in list */ static short filesys_find __P((char *, char *, bool)); #define FSF_NOT_FOUND (-1) #define FSF_STAT_FAIL (-2) #define FSF_TOO_MANY (-3) static short filesys_find(name, path, add) char *name; char *path; bool add; { struct stat st; short i; if (stat(path, &st) < 0) { syserr("cannot stat queue directory %s", path); return FSF_STAT_FAIL; } for (i = 0; i < NumFileSys; ++i) { if (FILE_SYS_DEV(i) == st.st_dev) return i; } if (i >= MAXFILESYS) { syserr("too many queue file systems (%d max)", MAXFILESYS); return FSF_TOO_MANY; } if (!add) return FSF_NOT_FOUND; ++NumFileSys; FILE_SYS_NAME(i) = name; FILE_SYS_DEV(i) = st.st_dev; FILE_SYS_AVAIL(i) = 0; FILE_SYS_BLKSIZE(i) = 1024; /* avoid divide by zero */ return i; } /* ** FILESYS_SETUP -- set up mapping from queue directories to file systems ** ** This data structure is used to efficiently check the amount of ** free space available in a set of queue directories. ** ** Parameters: ** add -- initialize structure if necessary. ** ** Returns: ** 0: success ** <0: some error, i.e., ** FSF_NOT_FOUND: not in list ** FSF_STAT_FAIL: can't stat() filesystem (-> syserr()) ** FSF_TOO_MANY: too many filesystems (-> syserr()) */ static int filesys_setup __P((bool)); static int filesys_setup(add) bool add; { int i, j; short fs; int ret; ret = 0; for (i = 0; i < NumQueue && Queue[i] != NULL; i++) { for (j = 0; j < Queue[i]->qg_numqueues; ++j) { QPATHS *qp = &Queue[i]->qg_qpaths[j]; char qddf[MAXPATHLEN]; (void) sm_strlcpyn(qddf, sizeof qddf, 2, qp->qp_name, (bitset(QP_SUBDF, qp->qp_subdirs) ? "/df" : "")); fs = filesys_find(qp->qp_name, qddf, add); if (fs >= 0) qp->qp_fsysidx = fs; else qp->qp_fsysidx = 0; if (fs < ret) ret = fs; } } return ret; } /* ** FILESYS_UPDATE -- update amount of free space on all file systems ** ** The FileSys table is used to cache the amount of free space ** available on all queue directory file systems. ** This function updates the cached information if it has expired. ** ** Parameters: ** none. ** ** Returns: ** none. ** ** Side Effects: ** Updates FileSys table. */ void filesys_update() { int i; long avail, blksize; time_t now; static time_t nextupdate = 0; #if SM_CONF_SHM /* only the daemon updates this structure */ if (ShmId != SM_SHM_NO_ID && DaemonPid != CurrentPid) return; #endif /* SM_CONF_SHM */ now = curtime(); if (now < nextupdate) return; nextupdate = now + FILESYS_UPDATE_INTERVAL; for (i = 0; i < NumFileSys; ++i) { FILESYS *fs = &FILE_SYS(i); avail = freediskspace(FILE_SYS_NAME(i), &blksize); if (avail < 0 || blksize <= 0) { if (LogLevel > 5) sm_syslog(LOG_ERR, NOQID, "filesys_update failed: %s, fs=%s, avail=%ld, blocksize=%ld", sm_errstring(errno), FILE_SYS_NAME(i), avail, blksize); fs->fs_avail = 0; fs->fs_blksize = 1024; /* avoid divide by zero */ nextupdate = now + 2; /* let's do this soon again */ } else { fs->fs_avail = avail; fs->fs_blksize = blksize; } } } #if _FFR_ANY_FREE_FS /* ** FILESYS_FREE -- check whether there is at least one fs with enough space. ** ** Parameters: ** fsize -- file size in bytes ** ** Returns: ** true iff there is one fs with more than fsize bytes free. */ bool filesys_free(fsize) long fsize; { int i; if (fsize <= 0) return true; for (i = 0; i < NumFileSys; ++i) { long needed = 0; if (FILE_SYS_AVAIL(i) < 0 || FILE_SYS_BLKSIZE(i) <= 0) continue; needed += fsize / FILE_SYS_BLKSIZE(i) + ((fsize % FILE_SYS_BLKSIZE(i) > 0) ? 1 : 0) + MinBlocksFree; if (needed <= FILE_SYS_AVAIL(i)) return true; } return false; } #endif /* _FFR_ANY_FREE_FS */ #if _FFR_CONTROL_MSTAT /* ** DISK_STATUS -- show amount of free space in queue directories ** ** Parameters: ** out -- output file pointer. ** prefix -- string to output in front of each line. ** ** Returns: ** none. */ void disk_status(out, prefix) SM_FILE_T *out; char *prefix; { int i; long avail, blksize; long free; for (i = 0; i < NumFileSys; ++i) { avail = freediskspace(FILE_SYS_NAME(i), &blksize); if (avail >= 0 && blksize > 0) { free = (long)((double) avail * ((double) blksize / 1024)); } else free = -1; (void) sm_io_fprintf(out, SM_TIME_DEFAULT, "%s%d/%s/%ld\r\n", prefix, i, FILE_SYS_NAME(i), free); } } #endif /* _FFR_CONTROL_MSTAT */ #if SM_CONF_SHM /* ** INIT_SEM -- initialize semaphore system ** ** Parameters: ** owner -- is this the owner of semaphores? ** ** Returns: ** none. */ #if _FFR_USE_SEM_LOCKING #if SM_CONF_SEM static int SemId = -1; /* Semaphore Id */ int SemKey = SM_SEM_KEY; #endif /* SM_CONF_SEM */ #endif /* _FFR_USE_SEM_LOCKING */ static void init_sem __P((bool)); static void init_sem(owner) bool owner; { #if _FFR_USE_SEM_LOCKING #if SM_CONF_SEM SemId = sm_sem_start(SemKey, 1, 0, owner); if (SemId < 0) { sm_syslog(LOG_ERR, NOQID, "func=init_sem, sem_key=%ld, sm_sem_start=%d", (long) SemKey, SemId); return; } #endif /* SM_CONF_SEM */ #endif /* _FFR_USE_SEM_LOCKING */ return; } /* ** STOP_SEM -- stop semaphore system ** ** Parameters: ** owner -- is this the owner of semaphores? ** ** Returns: ** none. */ static void stop_sem __P((bool)); static void stop_sem(owner) bool owner; { #if _FFR_USE_SEM_LOCKING #if SM_CONF_SEM if (owner && SemId >= 0) sm_sem_stop(SemId); #endif /* SM_CONF_SEM */ #endif /* _FFR_USE_SEM_LOCKING */ return; } /* ** UPD_QS -- update information about queue when adding/deleting an entry ** ** Parameters: ** e -- envelope. ** count -- add/remove entry (+1/0/-1: add/no change/remove) ** space -- update the space available as well. ** (>0/0/<0: add/no change/remove) ** where -- caller (for logging) ** ** Returns: ** none. ** ** Side Effects: ** Modifies available space in filesystem. ** Changes number of entries in queue directory. */ void upd_qs(e, count, space, where) ENVELOPE *e; int count; int space; char *where; { short fidx; int idx; # if _FFR_USE_SEM_LOCKING int r; # endif /* _FFR_USE_SEM_LOCKING */ long s; if (ShmId == SM_SHM_NO_ID || e == NULL) return; if (e->e_qgrp == NOQGRP || e->e_qdir == NOQDIR) return; idx = Queue[e->e_qgrp]->qg_qpaths[e->e_qdir].qp_idx; if (tTd(73,2)) sm_dprintf("func=upd_qs, count=%d, space=%d, where=%s, idx=%d, entries=%d\n", count, space, where, idx, QSHM_ENTRIES(idx)); /* XXX in theory this needs to be protected with a mutex */ if (QSHM_ENTRIES(idx) >= 0 && count != 0) { # if _FFR_USE_SEM_LOCKING r = sm_sem_acq(SemId, 0, 1); # endif /* _FFR_USE_SEM_LOCKING */ QSHM_ENTRIES(idx) += count; # if _FFR_USE_SEM_LOCKING if (r >= 0) r = sm_sem_rel(SemId, 0, 1); # endif /* _FFR_USE_SEM_LOCKING */ } fidx = Queue[e->e_qgrp]->qg_qpaths[e->e_qdir].qp_fsysidx; if (fidx < 0) return; /* update available space also? (might be loseqfile) */ if (space == 0) return; /* convert size to blocks; this causes rounding errors */ s = e->e_msgsize / FILE_SYS_BLKSIZE(fidx); if (s == 0) return; /* XXX in theory this needs to be protected with a mutex */ if (space > 0) FILE_SYS_AVAIL(fidx) += s; else FILE_SYS_AVAIL(fidx) -= s; } #if _FFR_SELECT_SHM static bool write_key_file __P((char *, long)); static long read_key_file __P((char *, long)); /* ** WRITE_KEY_FILE -- record some key into a file. ** ** Parameters: ** keypath -- file name. ** key -- key to write. ** ** Returns: ** true iff file could be written. ** ** Side Effects: ** writes file. */ static bool write_key_file(keypath, key) char *keypath; long key; { bool ok; long sff; SM_FILE_T *keyf; ok = false; if (keypath == NULL || *keypath == '\0') return ok; sff = SFF_NOLINK|SFF_ROOTOK|SFF_REGONLY|SFF_CREAT; if (TrustedUid != 0 && RealUid == TrustedUid) sff |= SFF_OPENASROOT; keyf = safefopen(keypath, O_WRONLY|O_TRUNC, FileMode, sff); if (keyf == NULL) { sm_syslog(LOG_ERR, NOQID, "unable to write %s: %s", keypath, sm_errstring(errno)); } else { if (geteuid() == 0 && RunAsUid != 0) { # if HASFCHOWN int fd; fd = keyf->f_file; if (fd >= 0 && fchown(fd, RunAsUid, -1) < 0) { int err = errno; sm_syslog(LOG_ALERT, NOQID, "ownership change on %s to %d failed: %s", keypath, RunAsUid, sm_errstring(err)); } # endif /* HASFCHOWN */ } ok = sm_io_fprintf(keyf, SM_TIME_DEFAULT, "%ld\n", key) != SM_IO_EOF; ok = (sm_io_close(keyf, SM_TIME_DEFAULT) != SM_IO_EOF) && ok; } return ok; } /* ** READ_KEY_FILE -- read a key from a file. ** ** Parameters: ** keypath -- file name. ** key -- default key. ** ** Returns: ** key. */ static long read_key_file(keypath, key) char *keypath; long key; { int r; long sff, n; SM_FILE_T *keyf; if (keypath == NULL || *keypath == '\0') return key; sff = SFF_NOLINK|SFF_ROOTOK|SFF_REGONLY; if (RealUid == 0 || (TrustedUid != 0 && RealUid == TrustedUid)) sff |= SFF_OPENASROOT; keyf = safefopen(keypath, O_RDONLY, FileMode, sff); if (keyf == NULL) { sm_syslog(LOG_ERR, NOQID, "unable to read %s: %s", keypath, sm_errstring(errno)); } else { r = sm_io_fscanf(keyf, SM_TIME_DEFAULT, "%ld", &n); if (r == 1) key = n; (void) sm_io_close(keyf, SM_TIME_DEFAULT); } return key; } #endif /* _FFR_SELECT_SHM */ /* ** INIT_SHM -- initialize shared memory structure ** ** Initialize or attach to shared memory segment. ** Currently it is not a fatal error if this doesn't work. ** However, it causes us to have a "fallback" storage location ** for everything that is supposed to be in the shared memory, ** which makes the code slightly ugly. ** ** Parameters: ** qn -- number of queue directories. ** owner -- owner of shared memory. ** hash -- identifies data that is stored in shared memory. ** ** Returns: ** none. */ static void init_shm __P((int, bool, unsigned int)); static void init_shm(qn, owner, hash) int qn; bool owner; unsigned int hash; { int i; int count; int save_errno; #if _FFR_SELECT_SHM bool keyselect; #endif /* _FFR_SELECT_SHM */ PtrFileSys = &FileSys[0]; PNumFileSys = &Numfilesys; #if _FFR_SELECT_SHM /* if this "key" is specified: select one yourself */ # define SEL_SHM_KEY ((key_t) -1) # define FIRST_SHM_KEY 25 #endif /* _FFR_SELECT_SHM */ /* This allows us to disable shared memory at runtime. */ if (ShmKey == 0) return; count = 0; shms = SM_T_SIZE + qn * sizeof(QUEUE_SHM_T); #if _FFR_SELECT_SHM keyselect = ShmKey == SEL_SHM_KEY; if (keyselect) { if (owner) ShmKey = FIRST_SHM_KEY; else { ShmKey = read_key_file(ShmKeyFile, ShmKey); keyselect = false; if (ShmKey == SEL_SHM_KEY) goto error; } } #endif /* _FFR_SELECT_SHM */ for (;;) { /* allow read/write access for group? */ Pshm = sm_shmstart(ShmKey, shms, SHM_R|SHM_W|(SHM_R>>3)|(SHM_W>>3), &ShmId, owner); save_errno = errno; if (Pshm != NULL || !sm_file_exists(save_errno)) break; if (++count >= 3) { #if _FFR_SELECT_SHM if (keyselect) { ++ShmKey; /* back where we started? */ if (ShmKey == SEL_SHM_KEY) break; continue; } #endif /* _FFR_SELECT_SHM */ break; } #if _FFR_SELECT_SHM /* only sleep if we are at the first key */ if (!keyselect || ShmKey == SEL_SHM_KEY) #endif /* _FFR_SELECT_SHM */ sleep(count); } if (Pshm != NULL) { int *p; #if _FFR_SELECT_SHM if (keyselect) (void) write_key_file(ShmKeyFile, (long) ShmKey); #endif /* _FFR_SELECT_SHM */ if (owner && RunAsUid != 0) { i = sm_shmsetowner(ShmId, RunAsUid, RunAsGid, 0660); if (i != 0) sm_syslog(LOG_ERR, NOQID, "key=%ld, sm_shmsetowner=%d, RunAsUid=%d, RunAsGid=%d", (long) ShmKey, i, RunAsUid, RunAsGid); } p = (int *) Pshm; if (owner) { *p = (int) shms; *((pid_t *) SHM_OFF_PID(Pshm)) = CurrentPid; p = (int *) SHM_OFF_TAG(Pshm); *p = hash; } else { if (*p != (int) shms) { save_errno = EINVAL; cleanup_shm(false); goto error; } p = (int *) SHM_OFF_TAG(Pshm); if (*p != (int) hash) { save_errno = EINVAL; cleanup_shm(false); goto error; } /* ** XXX how to check the pid? ** Read it from the pid-file? That does ** not need to exist. ** We could disable shm if we can't confirm ** that it is the right one. */ } PtrFileSys = (FILESYS *) OFF_FILE_SYS(Pshm); PNumFileSys = (int *) OFF_NUM_FILE_SYS(Pshm); QShm = (QUEUE_SHM_T *) OFF_QUEUE_SHM(Pshm); PRSATmpCnt = (int *) OFF_RSA_TMP_CNT(Pshm); *PRSATmpCnt = 0; if (owner) { /* initialize values in shared memory */ NumFileSys = 0; for (i = 0; i < qn; i++) QShm[i].qs_entries = -1; } init_sem(owner); return; } error: if (LogLevel > (owner ? 8 : 11)) { sm_syslog(owner ? LOG_ERR : LOG_NOTICE, NOQID, "can't %s shared memory, key=%ld: %s", owner ? "initialize" : "attach to", (long) ShmKey, sm_errstring(save_errno)); } } #endif /* SM_CONF_SHM */ /* ** SETUP_QUEUES -- setup all queue groups ** ** Parameters: ** owner -- owner of shared memory. ** ** Returns: ** none. ** #if SM_CONF_SHM ** Side Effects: ** attaches shared memory. #endif * SM_CONF_SHM * */ void setup_queues(owner) bool owner; { int i, qn, len; unsigned int hashval; time_t now; char basedir[MAXPATHLEN]; struct stat st; /* ** Determine basedir for all queue directories. ** All queue directories must be (first level) subdirectories ** of the basedir. The basedir is the QueueDir ** without wildcards, but with trailing / */ hashval = 0; errno = 0; len = sm_strlcpy(basedir, QueueDir, sizeof basedir); /* Provide space for trailing '/' */ if (len >= sizeof basedir - 1) { syserr("QueueDirectory: path too long: %d, max %d", len, (int) sizeof basedir - 1); ExitStat = EX_CONFIG; return; } SM_ASSERT(len > 0); if (basedir[len - 1] == '*') { char *cp; cp = SM_LAST_DIR_DELIM(basedir); if (cp == NULL) { syserr("QueueDirectory: can not wildcard relative path \"%s\"", QueueDir); if (tTd(41, 2)) sm_dprintf("setup_queues: \"%s\": Can not wildcard relative path.\n", QueueDir); ExitStat = EX_CONFIG; return; } /* cut off wildcard pattern */ *++cp = '\0'; len = cp - basedir; } else if (!SM_IS_DIR_DELIM(basedir[len - 1])) { /* append trailing slash since it is a directory */ basedir[len] = '/'; basedir[++len] = '\0'; } /* len counts up to the last directory delimiter */ SM_ASSERT(basedir[len - 1] == '/'); if (chdir(basedir) < 0) { int save_errno = errno; syserr("can not chdir(%s)", basedir); if (save_errno == EACCES) (void) sm_io_fprintf(smioerr, SM_TIME_DEFAULT, "Program mode requires special privileges, e.g., root or TrustedUser.\n"); if (tTd(41, 2)) sm_dprintf("setup_queues: \"%s\": %s\n", basedir, sm_errstring(errno)); ExitStat = EX_CONFIG; return; } #if SM_CONF_SHM hashval = hash_q(basedir, hashval); #endif /* SM_CONF_SHM */ /* initialize for queue runs */ DoQueueRun = false; now = curtime(); for (i = 0; i < NumQueue && Queue[i] != NULL; i++) Queue[i]->qg_nextrun = now; if (UseMSP && OpMode != MD_TEST) { long sff = SFF_CREAT; if (stat(".", &st) < 0) { syserr("can not stat(%s)", basedir); if (tTd(41, 2)) sm_dprintf("setup_queues: \"%s\": %s\n", basedir, sm_errstring(errno)); ExitStat = EX_CONFIG; return; } if (RunAsUid == 0) sff |= SFF_ROOTOK; /* ** Check queue directory permissions. ** Can we write to a group writable queue directory? */ if (bitset(S_IWGRP, QueueFileMode) && bitset(S_IWGRP, st.st_mode) && safefile(" ", RunAsUid, RunAsGid, RunAsUserName, sff, QueueFileMode, NULL) != 0) { syserr("can not write to queue directory %s (RunAsGid=%d, required=%d)", basedir, (int) RunAsGid, (int) st.st_gid); } if (bitset(S_IWOTH|S_IXOTH, st.st_mode)) { #if _FFR_MSP_PARANOIA syserr("dangerous permissions=%o on queue directory %s", (int) st.st_mode, basedir); #else /* _FFR_MSP_PARANOIA */ if (LogLevel > 0) sm_syslog(LOG_ERR, NOQID, "dangerous permissions=%o on queue directory %s", (int) st.st_mode, basedir); #endif /* _FFR_MSP_PARANOIA */ } #if _FFR_MSP_PARANOIA if (NumQueue > 1) syserr("can not use multiple queues for MSP"); #endif /* _FFR_MSP_PARANOIA */ } /* initial number of queue directories */ qn = 0; for (i = 0; i < NumQueue && Queue[i] != NULL; i++) qn = multiqueue_cache(basedir, len, Queue[i], qn, &hashval); #if SM_CONF_SHM init_shm(qn, owner, hashval); i = filesys_setup(owner || ShmId == SM_SHM_NO_ID); if (i == FSF_NOT_FOUND) { /* ** We didn't get the right filesystem data ** This may happen if we don't have the right shared memory. ** So let's do this without shared memory. */ SM_ASSERT(!owner); cleanup_shm(false); /* release shared memory */ i = filesys_setup(false); if (i < 0) syserr("filesys_setup failed twice, result=%d", i); else if (LogLevel > 8) sm_syslog(LOG_WARNING, NOQID, "shared memory does not contain expected data, ignored"); } #else /* SM_CONF_SHM */ i = filesys_setup(true); #endif /* SM_CONF_SHM */ if (i < 0) ExitStat = EX_CONFIG; } #if SM_CONF_SHM /* ** CLEANUP_SHM -- do some cleanup work for shared memory etc ** ** Parameters: ** owner -- owner of shared memory? ** ** Returns: ** none. ** ** Side Effects: ** detaches shared memory. */ void cleanup_shm(owner) bool owner; { if (ShmId != SM_SHM_NO_ID) { if (sm_shmstop(Pshm, ShmId, owner) < 0 && LogLevel > 8) sm_syslog(LOG_INFO, NOQID, "sm_shmstop failed=%s", sm_errstring(errno)); Pshm = NULL; ShmId = SM_SHM_NO_ID; } stop_sem(owner); } #endif /* SM_CONF_SHM */ /* ** CLEANUP_QUEUES -- do some cleanup work for queues ** ** Parameters: ** none. ** ** Returns: ** none. ** */ void cleanup_queues() { sync_queue_time(); } /* ** SET_DEF_QUEUEVAL -- set default values for a queue group. ** ** Parameters: ** qg -- queue group ** all -- set all values (true for default group)? ** ** Returns: ** none. ** ** Side Effects: ** sets default values for the queue group. */ void set_def_queueval(qg, all) QUEUEGRP *qg; bool all; { if (bitnset(QD_DEFINED, qg->qg_flags)) return; if (all) qg->qg_qdir = QueueDir; #if _FFR_QUEUE_GROUP_SORTORDER qg->qg_sortorder = QueueSortOrder; #endif /* _FFR_QUEUE_GROUP_SORTORDER */ qg->qg_maxqrun = all ? MaxRunnersPerQueue : -1; qg->qg_nice = NiceQueueRun; } /* ** MAKEQUEUE -- define a new queue. ** ** Parameters: ** line -- description of queue. This is in labeled fields. ** The fields are: ** F -- the flags associated with the queue ** I -- the interval between running the queue ** J -- the maximum # of jobs in work list ** [M -- the maximum # of jobs in a queue run] ** N -- the niceness at which to run ** P -- the path to the queue ** S -- the queue sorting order ** R -- number of parallel queue runners ** r -- max recipients per envelope ** The first word is the canonical name of the queue. ** qdef -- this is a 'Q' definition from .cf ** ** Returns: ** none. ** ** Side Effects: ** enters the queue into the queue table. */ void makequeue(line, qdef) char *line; bool qdef; { register char *p; register QUEUEGRP *qg; register STAB *s; int i; char fcode; /* allocate a queue and set up defaults */ qg = (QUEUEGRP *) xalloc(sizeof *qg); memset((char *) qg, '\0', sizeof *qg); if (line[0] == '\0') { syserr("name required for queue"); return; } /* collect the queue name */ for (p = line; *p != '\0' && *p != ',' && !(isascii(*p) && isspace(*p)); p++) continue; if (*p != '\0') *p++ = '\0'; qg->qg_name = newstr(line); /* set default values, can be overridden below */ set_def_queueval(qg, false); /* now scan through and assign info from the fields */ while (*p != '\0') { auto char *delimptr; while (*p != '\0' && (*p == ',' || (isascii(*p) && isspace(*p)))) p++; /* p now points to field code */ fcode = *p; while (*p != '\0' && *p != '=' && *p != ',') p++; if (*p++ != '=') { syserr("queue %s: `=' expected", qg->qg_name); return; } while (isascii(*p) && isspace(*p)) p++; /* p now points to the field body */ p = munchstring(p, &delimptr, ','); /* install the field into the queue struct */ switch (fcode) { case 'P': /* pathname */ if (*p == '\0') syserr("queue %s: empty path name", qg->qg_name); else qg->qg_qdir = newstr(p); break; case 'F': /* flags */ for (; *p != '\0'; p++) if (!(isascii(*p) && isspace(*p))) setbitn(*p, qg->qg_flags); break; /* ** Do we need two intervals here: ** One for persistent queue runners, ** one for "normal" queue runs? */ case 'I': /* interval between running the queue */ qg->qg_queueintvl = convtime(p, 'm'); break; case 'N': /* run niceness */ qg->qg_nice = atoi(p); break; case 'R': /* maximum # of runners for the group */ i = atoi(p); /* can't have more runners than allowed total */ if (MaxQueueChildren > 0 && i > MaxQueueChildren) { qg->qg_maxqrun = MaxQueueChildren; (void) sm_io_fprintf(smioout, SM_TIME_DEFAULT, "Q=%s: R=%d exceeds MaxQueueChildren=%d, set to MaxQueueChildren\n", qg->qg_name, i, MaxQueueChildren); } else qg->qg_maxqrun = i; break; case 'J': /* maximum # of jobs in work list */ qg->qg_maxlist = atoi(p); break; case 'r': /* max recipients per envelope */ qg->qg_maxrcpt = atoi(p); break; #if _FFR_QUEUE_GROUP_SORTORDER case 'S': /* queue sorting order */ switch (*p) { case 'h': /* Host first */ case 'H': qg->qg_sortorder = QSO_BYHOST; break; case 'p': /* Priority order */ case 'P': qg->qg_sortorder = QSO_BYPRIORITY; break; case 't': /* Submission time */ case 'T': qg->qg_sortorder = QSO_BYTIME; break; case 'f': /* File name */ case 'F': qg->qg_sortorder = QSO_BYFILENAME; break; case 'm': /* Modification time */ case 'M': qg->qg_sortorder = QSO_BYMODTIME; break; case 'r': /* Random */ case 'R': qg->qg_sortorder = QSO_RANDOM; break; # if _FFR_RHS case 's': /* Shuffled host name */ case 'S': qg->qg_sortorder = QSO_BYSHUFFLE; break; # endif /* _FFR_RHS */ case 'n': /* none */ case 'N': qg->qg_sortorder = QSO_NONE; break; default: syserr("Invalid queue sort order \"%s\"", p); } break; #endif /* _FFR_QUEUE_GROUP_SORTORDER */ default: syserr("Q%s: unknown queue equate %c=", qg->qg_name, fcode); break; } p = delimptr; } #if !HASNICE if (qg->qg_nice != NiceQueueRun) { (void) sm_io_fprintf(smioout, SM_TIME_DEFAULT, "Q%s: Warning: N= set on system that doesn't support nice()\n", qg->qg_name); } #endif /* !HASNICE */ /* do some rationality checking */ if (NumQueue >= MAXQUEUEGROUPS) { syserr("too many queue groups defined (%d max)", MAXQUEUEGROUPS); return; } if (qg->qg_qdir == NULL) { if (QueueDir == NULL || *QueueDir == '\0') { syserr("QueueDir must be defined before queue groups"); return; } qg->qg_qdir = newstr(QueueDir); } if (qg->qg_maxqrun > 1 && !bitnset(QD_FORK, qg->qg_flags)) { (void) sm_io_fprintf(smioout, SM_TIME_DEFAULT, "Warning: Q=%s: R=%d: multiple queue runners specified\n\tbut flag '%c' is not set\n", qg->qg_name, qg->qg_maxqrun, QD_FORK); } /* enter the queue into the symbol table */ if (tTd(37, 8)) sm_syslog(LOG_INFO, NOQID, "Adding %s to stab, path: %s", qg->qg_name, qg->qg_qdir); s = stab(qg->qg_name, ST_QUEUE, ST_ENTER); if (s->s_quegrp != NULL) { i = s->s_quegrp->qg_index; /* XXX what about the pointers inside this struct? */ sm_free(s->s_quegrp); /* XXX */ } else i = NumQueue++; Queue[i] = s->s_quegrp = qg; qg->qg_index = i; /* set default value for max queue runners */ if (qg->qg_maxqrun < 0) { if (MaxRunnersPerQueue > 0) qg->qg_maxqrun = MaxRunnersPerQueue; else qg->qg_maxqrun = 1; } if (qdef) setbitn(QD_DEFINED, qg->qg_flags); } #if 0 /* ** HASHFQN -- calculate a hash value for a fully qualified host name ** ** Arguments: ** fqn -- an all lower-case host.domain string ** buckets -- the number of buckets (queue directories) ** ** Returns: ** a bucket number (signed integer) ** -1 on error ** ** Contributed by Exactis.com, Inc. */ int hashfqn(fqn, buckets) register char *fqn; int buckets; { register char *p; register int h = 0, hash, cnt; if (fqn == NULL) return -1; /* ** A variation on the gdb hash ** This is the best as of Feb 19, 1996 --bcx */ p = fqn; h = 0x238F13AF * strlen(p); for (cnt = 0; *p != 0; ++p, cnt++) { h = (h + (*p << (cnt * 5 % 24))) & 0x7FFFFFFF; } h = (1103515243 * h + 12345) & 0x7FFFFFFF; if (buckets < 2) hash = 0; else hash = (h % buckets); return hash; } #endif /* 0 */ /* ** A structure for sorting Queue according to maxqrun without ** screwing up Queue itself. */ struct sortqgrp { int sg_idx; /* original index */ int sg_maxqrun; /* max queue runners */ }; typedef struct sortqgrp SORTQGRP_T; static int cmpidx __P((const void *, const void *)); static int cmpidx(a, b) const void *a; const void *b; { /* The sort is highest to lowest, so the comparison is reversed */ if (((SORTQGRP_T *)a)->sg_maxqrun < ((SORTQGRP_T *)b)->sg_maxqrun) return 1; else if (((SORTQGRP_T *)a)->sg_maxqrun > ((SORTQGRP_T *)b)->sg_maxqrun) return -1; else return 0; } /* ** MAKEWORKGROUP -- balance queue groups into work groups per MaxQueueChildren ** ** Take the now defined queue groups and assign them to work groups. ** This is done to balance out the number of concurrently active ** queue runners such that MaxQueueChildren is not exceeded. This may ** result in more than one queue group per work group. In such a case ** the number of running queue groups in that work group will have no ** more than the work group maximum number of runners (a "fair" portion ** of MaxQueueRunners). All queue groups within a work group will get a ** chance at running. ** ** Parameters: ** none. ** ** Returns: ** nothing. ** ** Side Effects: ** Sets up WorkGrp structure. */ void makeworkgroups() { int i, j, total_runners, dir, h; SORTQGRP_T si[MAXQUEUEGROUPS + 1]; total_runners = 0; if (NumQueue == 1 && strcmp(Queue[0]->qg_name, "mqueue") == 0) { /* ** There is only the "mqueue" queue group (a default) ** containing all of the queues. We want to provide to ** this queue group the maximum allowable queue runners. ** To match older behavior (8.10/8.11) we'll try for ** 1 runner per queue capping it at MaxQueueChildren. ** So if there are N queues, then there will be N runners ** for the "mqueue" queue group (where N is kept less than ** MaxQueueChildren). */ NumWorkGroups = 1; WorkGrp[0].wg_numqgrp = 1; WorkGrp[0].wg_qgs = (QUEUEGRP **) xalloc(sizeof(QUEUEGRP *)); WorkGrp[0].wg_qgs[0] = Queue[0]; if (MaxQueueChildren > 0 && Queue[0]->qg_numqueues > MaxQueueChildren) WorkGrp[0].wg_runners = MaxQueueChildren; else WorkGrp[0].wg_runners = Queue[0]->qg_numqueues; Queue[0]->qg_wgrp = 0; /* can't have more runners than allowed total */ if (MaxQueueChildren > 0 && Queue[0]->qg_maxqrun > MaxQueueChildren) Queue[0]->qg_maxqrun = MaxQueueChildren; WorkGrp[0].wg_maxact = Queue[0]->qg_maxqrun; WorkGrp[0].wg_lowqintvl = Queue[0]->qg_queueintvl; return; } for (i = 0; i < NumQueue; i++) { si[i].sg_maxqrun = Queue[i]->qg_maxqrun; si[i].sg_idx = i; } qsort(si, NumQueue, sizeof(si[0]), cmpidx); NumWorkGroups = 0; for (i = 0; i < NumQueue; i++) { total_runners += si[i].sg_maxqrun; if (MaxQueueChildren <= 0 || total_runners <= MaxQueueChildren) NumWorkGroups++; else break; } if (NumWorkGroups < 1) NumWorkGroups = 1; /* gotta have one at least */ else if (NumWorkGroups > MAXWORKGROUPS) NumWorkGroups = MAXWORKGROUPS; /* the limit */ /* ** We now know the number of work groups to pack the queue groups ** into. The queue groups in 'Queue' are sorted from highest ** to lowest for the number of runners per queue group. ** We put the queue groups with the largest number of runners ** into work groups first. Then the smaller ones are fitted in ** where it looks best. */ j = 0; dir = 1; for (i = 0; i < NumQueue; i++) { /* a to-and-fro packing scheme, continue from last position */ if (j >= NumWorkGroups) { dir = -1; j = NumWorkGroups - 1; } else if (j < 0) { j = 0; dir = 1; } if (WorkGrp[j].wg_qgs == NULL) WorkGrp[j].wg_qgs = (QUEUEGRP **)sm_malloc(sizeof(QUEUEGRP *) * (WorkGrp[j].wg_numqgrp + 1)); else WorkGrp[j].wg_qgs = (QUEUEGRP **)sm_realloc(WorkGrp[j].wg_qgs, sizeof(QUEUEGRP *) * (WorkGrp[j].wg_numqgrp + 1)); if (WorkGrp[j].wg_qgs == NULL) { syserr("!cannot allocate memory for work queues, need %d bytes", (int) (sizeof(QUEUEGRP *) * (WorkGrp[j].wg_numqgrp + 1))); } h = si[i].sg_idx; WorkGrp[j].wg_qgs[WorkGrp[j].wg_numqgrp] = Queue[h]; WorkGrp[j].wg_numqgrp++; WorkGrp[j].wg_runners += Queue[h]->qg_maxqrun; Queue[h]->qg_wgrp = j; if (WorkGrp[j].wg_maxact == 0) { /* can't have more runners than allowed total */ if (MaxQueueChildren > 0 && Queue[h]->qg_maxqrun > MaxQueueChildren) Queue[h]->qg_maxqrun = MaxQueueChildren; WorkGrp[j].wg_maxact = Queue[h]->qg_maxqrun; } /* ** XXX: must wg_lowqintvl be the GCD? ** qg1: 2m, qg2: 3m, minimum: 2m, when do queue runs for ** qg2 occur? */ /* keep track of the lowest interval for a persistent runner */ if (Queue[h]->qg_queueintvl > 0 && WorkGrp[j].wg_lowqintvl < Queue[h]->qg_queueintvl) WorkGrp[j].wg_lowqintvl = Queue[h]->qg_queueintvl; j += dir; } if (tTd(41, 9)) { for (i = 0; i < NumWorkGroups; i++) { sm_dprintf("Workgroup[%d]=", i); for (j = 0; j < WorkGrp[i].wg_numqgrp; j++) { sm_dprintf("%s, ", WorkGrp[i].wg_qgs[j]->qg_name); } sm_dprintf("\n"); } } } /* ** DUP_DF -- duplicate envelope data file ** ** Copy the data file from the 'old' envelope to the 'new' envelope ** in the most efficient way possible. ** ** Create a hard link from the 'old' data file to the 'new' data file. ** If the old and new queue directories are on different file systems, ** then the new data file link is created in the old queue directory, ** and the new queue file will contain a 'd' record pointing to the ** directory containing the new data file. ** ** Parameters: ** old -- old envelope. ** new -- new envelope. ** ** Results: ** Returns true on success, false on failure. ** ** Side Effects: ** On success, the new data file is created. ** On fatal failure, EF_FATALERRS is set in old->e_flags. */ static bool dup_df __P((ENVELOPE *, ENVELOPE *)); static bool dup_df(old, new) ENVELOPE *old; ENVELOPE *new; { int ofs, nfs, r; char opath[MAXPATHLEN]; char npath[MAXPATHLEN]; if (!bitset(EF_HAS_DF, old->e_flags)) { /* ** this can happen if: SuperSafe != True ** and a bounce mail is sent that is split. */ queueup(old, false, true); } SM_REQUIRE(ISVALIDQGRP(old->e_qgrp) && ISVALIDQDIR(old->e_qdir)); SM_REQUIRE(ISVALIDQGRP(new->e_qgrp) && ISVALIDQDIR(new->e_qdir)); (void) sm_strlcpy(opath, queuename(old, DATAFL_LETTER), sizeof opath); (void) sm_strlcpy(npath, queuename(new, DATAFL_LETTER), sizeof npath); if (old->e_dfp != NULL) { r = sm_io_setinfo(old->e_dfp, SM_BF_COMMIT, NULL); if (r < 0 && errno != EINVAL) { syserr("@can't commit %s", opath); old->e_flags |= EF_FATALERRS; return false; } } /* ** Attempt to create a hard link, if we think both old and new ** are on the same file system, otherwise copy the file. ** ** Don't waste time attempting a hard link unless old and new ** are on the same file system. */ SM_REQUIRE(ISVALIDQGRP(old->e_dfqgrp) && ISVALIDQDIR(old->e_dfqdir)); SM_REQUIRE(ISVALIDQGRP(new->e_dfqgrp) && ISVALIDQDIR(new->e_dfqdir)); ofs = Queue[old->e_dfqgrp]->qg_qpaths[old->e_dfqdir].qp_fsysidx; nfs = Queue[new->e_dfqgrp]->qg_qpaths[new->e_dfqdir].qp_fsysidx; if (FILE_SYS_DEV(ofs) == FILE_SYS_DEV(nfs)) { if (link(opath, npath) == 0) { new->e_flags |= EF_HAS_DF; SYNC_DIR(npath, true); return true; } goto error; } /* ** Can't link across queue directories, so try to create a hard ** link in the same queue directory as the old df file. ** The qf file will refer to the new df file using a 'd' record. */ new->e_dfqgrp = old->e_dfqgrp; new->e_dfqdir = old->e_dfqdir; (void) sm_strlcpy(npath, queuename(new, DATAFL_LETTER), sizeof npath); if (link(opath, npath) == 0) { new->e_flags |= EF_HAS_DF; SYNC_DIR(npath, true); return true; } error: if (LogLevel > 0) sm_syslog(LOG_ERR, old->e_id, "dup_df: can't link %s to %s, error=%s, envelope splitting failed", opath, npath, sm_errstring(errno)); return false; } /* ** SPLIT_ENV -- Allocate a new envelope based on a given envelope. ** ** Parameters: ** e -- envelope. ** sendqueue -- sendqueue for new envelope. ** qgrp -- index of queue group. ** qdir -- queue directory. ** ** Results: ** new envelope. ** */ static ENVELOPE *split_env __P((ENVELOPE *, ADDRESS *, int, int)); static ENVELOPE * split_env(e, sendqueue, qgrp, qdir) ENVELOPE *e; ADDRESS *sendqueue; int qgrp; int qdir; { ENVELOPE *ee; ee = (ENVELOPE *) sm_rpool_malloc_x(e->e_rpool, sizeof *ee); STRUCTCOPY(*e, *ee); ee->e_message = NULL; /* XXX use original message? */ ee->e_id = NULL; assign_queueid(ee); ee->e_sendqueue = sendqueue; ee->e_flags &= ~(EF_INQUEUE|EF_CLRQUEUE|EF_FATALERRS |EF_SENDRECEIPT|EF_RET_PARAM|EF_HAS_DF); ee->e_flags |= EF_NORECEIPT; /* XXX really? */ ee->e_from.q_state = QS_SENDER; ee->e_dfp = NULL; ee->e_lockfp = NULL; if (e->e_xfp != NULL) ee->e_xfp = sm_io_dup(e->e_xfp); /* failed to dup e->e_xfp, start a new transcript */ if (ee->e_xfp == NULL) openxscript(ee); ee->e_qgrp = ee->e_dfqgrp = qgrp; ee->e_qdir = ee->e_dfqdir = qdir; ee->e_errormode = EM_MAIL; ee->e_statmsg = NULL; if (e->e_quarmsg != NULL) ee->e_quarmsg = sm_rpool_strdup_x(ee->e_rpool, e->e_quarmsg); /* ** XXX Not sure if this copying is necessary. ** sendall() does this copying, but I (dm) don't know if that is ** because of the storage management discipline we were using ** before rpools were introduced, or if it is because these lists ** can be modified later. */ ee->e_header = copyheader(e->e_header, ee->e_rpool); ee->e_errorqueue = copyqueue(e->e_errorqueue, ee->e_rpool); return ee; } /* return values from split functions, check also below! */ #define SM_SPLIT_FAIL (0) #define SM_SPLIT_NONE (1) #define SM_SPLIT_NEW(n) (1 + (n)) /* ** SPLIT_ACROSS_QUEUE_GROUPS ** ** This function splits an envelope across multiple queue groups ** based on the queue group of each recipient. ** ** Parameters: ** e -- envelope. ** ** Results: ** SM_SPLIT_FAIL on failure ** SM_SPLIT_NONE if no splitting occurred, ** or 1 + the number of additional envelopes created. ** ** Side Effects: ** On success, e->e_sibling points to a list of zero or more ** additional envelopes, and the associated data files exist ** on disk. But the queue files are not created. ** ** On failure, e->e_sibling is not changed. ** The order of recipients in e->e_sendqueue is permuted. ** Abandoned data files for additional envelopes that failed ** to be created may exist on disk. */ static int q_qgrp_compare __P((const void *, const void *)); static int e_filesys_compare __P((const void *, const void *)); static int q_qgrp_compare(p1, p2) const void *p1; const void *p2; { ADDRESS **pq1 = (ADDRESS **) p1; ADDRESS **pq2 = (ADDRESS **) p2; return (*pq1)->q_qgrp - (*pq2)->q_qgrp; } static int e_filesys_compare(p1, p2) const void *p1; const void *p2; { ENVELOPE **pe1 = (ENVELOPE **) p1; ENVELOPE **pe2 = (ENVELOPE **) p2; int fs1, fs2; fs1 = Queue[(*pe1)->e_qgrp]->qg_qpaths[(*pe1)->e_qdir].qp_fsysidx; fs2 = Queue[(*pe2)->e_qgrp]->qg_qpaths[(*pe2)->e_qdir].qp_fsysidx; if (FILE_SYS_DEV(fs1) < FILE_SYS_DEV(fs2)) return -1; if (FILE_SYS_DEV(fs1) > FILE_SYS_DEV(fs2)) return 1; return 0; } static int split_across_queue_groups(e) ENVELOPE *e; { int naddrs, nsplits, i; bool changed; char **pvp; ADDRESS *q, **addrs; ENVELOPE *ee, *es; ENVELOPE *splits[MAXQUEUEGROUPS]; char pvpbuf[PSBUFSIZE]; SM_REQUIRE(ISVALIDQGRP(e->e_qgrp)); /* Count addresses and assign queue groups. */ naddrs = 0; changed = false; for (q = e->e_sendqueue; q != NULL; q = q->q_next) { if (QS_IS_DEAD(q->q_state)) continue; ++naddrs; /* bad addresses and those already sent stay put */ if (QS_IS_BADADDR(q->q_state) || QS_IS_SENT(q->q_state)) q->q_qgrp = e->e_qgrp; else if (!ISVALIDQGRP(q->q_qgrp)) { /* call ruleset which should return a queue group */ i = rscap(RS_QUEUEGROUP, q->q_user, NULL, e, &pvp, pvpbuf, sizeof(pvpbuf)); if (i == EX_OK && pvp != NULL && pvp[0] != NULL && (pvp[0][0] & 0377) == CANONNET && pvp[1] != NULL && pvp[1][0] != '\0') { i = name2qid(pvp[1]); if (ISVALIDQGRP(i)) { q->q_qgrp = i; changed = true; if (tTd(20, 4)) sm_syslog(LOG_INFO, NOQID, "queue group name %s -> %d", pvp[1], i); continue; } else if (LogLevel > 10) sm_syslog(LOG_INFO, NOQID, "can't find queue group name %s, selection ignored", pvp[1]); } if (q->q_mailer != NULL && ISVALIDQGRP(q->q_mailer->m_qgrp)) { changed = true; q->q_qgrp = q->q_mailer->m_qgrp; } else if (ISVALIDQGRP(e->e_qgrp)) q->q_qgrp = e->e_qgrp; else q->q_qgrp = 0; } } /* only one address? nothing to split. */ if (naddrs <= 1 && !changed) return SM_SPLIT_NONE; /* sort the addresses by queue group */ addrs = sm_rpool_malloc_x(e->e_rpool, naddrs * sizeof(ADDRESS *)); for (i = 0, q = e->e_sendqueue; q != NULL; q = q->q_next) { if (QS_IS_DEAD(q->q_state)) continue; addrs[i++] = q; } qsort(addrs, naddrs, sizeof(ADDRESS *), q_qgrp_compare); /* split into multiple envelopes, by queue group */ nsplits = 0; es = NULL; e->e_sendqueue = NULL; for (i = 0; i < naddrs; ++i) { if (i == naddrs - 1 || addrs[i]->q_qgrp != addrs[i + 1]->q_qgrp) addrs[i]->q_next = NULL; else addrs[i]->q_next = addrs[i + 1]; /* same queue group as original envelope? */ if (addrs[i]->q_qgrp == e->e_qgrp) { if (e->e_sendqueue == NULL) e->e_sendqueue = addrs[i]; continue; } /* different queue group than original envelope */ if (es == NULL || addrs[i]->q_qgrp != es->e_qgrp) { ee = split_env(e, addrs[i], addrs[i]->q_qgrp, NOQDIR); es = ee; splits[nsplits++] = ee; } } /* no splits? return right now. */ if (nsplits <= 0) return SM_SPLIT_NONE; /* assign a queue directory to each additional envelope */ for (i = 0; i < nsplits; ++i) { es = splits[i]; #if 0 es->e_qdir = pickqdir(Queue[es->e_qgrp], es->e_msgsize, es); #endif /* 0 */ if (!setnewqueue(es)) goto failure; } /* sort the additional envelopes by queue file system */ qsort(splits, nsplits, sizeof(ENVELOPE *), e_filesys_compare); /* create data files for each additional envelope */ if (!dup_df(e, splits[0])) { i = 0; goto failure; } for (i = 1; i < nsplits; ++i) { /* copy or link to the previous data file */ if (!dup_df(splits[i - 1], splits[i])) goto failure; } /* success: prepend the new envelopes to the e->e_sibling list */ for (i = 0; i < nsplits; ++i) { es = splits[i]; es->e_sibling = e->e_sibling; e->e_sibling = es; } return SM_SPLIT_NEW(nsplits); /* failure: clean up */ failure: if (i > 0) { int j; for (j = 0; j < i; j++) (void) unlink(queuename(splits[j], DATAFL_LETTER)); } e->e_sendqueue = addrs[0]; for (i = 0; i < naddrs - 1; ++i) addrs[i]->q_next = addrs[i + 1]; addrs[naddrs - 1]->q_next = NULL; return SM_SPLIT_FAIL; } /* ** SPLIT_WITHIN_QUEUE ** ** Split an envelope with multiple recipients into several ** envelopes within the same queue directory, if the number of ** recipients exceeds the limit for the queue group. ** ** Parameters: ** e -- envelope. ** ** Results: ** SM_SPLIT_FAIL on failure ** SM_SPLIT_NONE if no splitting occurred, ** or 1 + the number of additional envelopes created. */ #define SPLIT_LOG_LEVEL 8 static int split_within_queue __P((ENVELOPE *)); static int split_within_queue(e) ENVELOPE *e; { int maxrcpt, nrcpt, ndead, nsplit, i; int j, l; char *lsplits; ADDRESS *q, **addrs; ENVELOPE *ee, *firstsibling; if (!ISVALIDQGRP(e->e_qgrp) || bitset(EF_SPLIT, e->e_flags)) return SM_SPLIT_NONE; /* don't bother if there is no recipient limit */ maxrcpt = Queue[e->e_qgrp]->qg_maxrcpt; if (maxrcpt <= 0) return SM_SPLIT_NONE; /* count recipients */ nrcpt = 0; for (q = e->e_sendqueue; q != NULL; q = q->q_next) { if (QS_IS_DEAD(q->q_state)) continue; ++nrcpt; } if (nrcpt <= maxrcpt) return SM_SPLIT_NONE; /* ** Preserve the recipient list ** so that we can restore it in case of error. ** (But we discard dead addresses.) */ addrs = sm_rpool_malloc_x(e->e_rpool, nrcpt * sizeof(ADDRESS *)); for (i = 0, q = e->e_sendqueue; q != NULL; q = q->q_next) { if (QS_IS_DEAD(q->q_state)) continue; addrs[i++] = q; } /* ** Partition the recipient list so that bad and sent addresses ** come first. These will go with the original envelope, and ** do not count towards the maxrcpt limit. ** addrs[] does not contain QS_IS_DEAD() addresses. */ ndead = 0; for (i = 0; i < nrcpt; ++i) { if (QS_IS_BADADDR(addrs[i]->q_state) || QS_IS_SENT(addrs[i]->q_state) || QS_IS_DEAD(addrs[i]->q_state)) /* for paranoia's sake */ { if (i > ndead) { ADDRESS *tmp = addrs[i]; addrs[i] = addrs[ndead]; addrs[ndead] = tmp; } ++ndead; } } /* Check if no splitting required. */ if (nrcpt - ndead <= maxrcpt) return SM_SPLIT_NONE; /* fix links */ for (i = 0; i < nrcpt - 1; ++i) addrs[i]->q_next = addrs[i + 1]; addrs[nrcpt - 1]->q_next = NULL; e->e_sendqueue = addrs[0]; /* prepare buffer for logging */ if (LogLevel > SPLIT_LOG_LEVEL) { l = MAXLINE; lsplits = sm_malloc(l); if (lsplits != NULL) *lsplits = '\0'; j = 0; } else { /* get rid of stupid compiler warnings */ lsplits = NULL; j = l = 0; } /* split the envelope */ firstsibling = e->e_sibling; i = maxrcpt + ndead; nsplit = 0; for (;;) { addrs[i - 1]->q_next = NULL; ee = split_env(e, addrs[i], e->e_qgrp, e->e_qdir); if (!dup_df(e, ee)) { ee = firstsibling; while (ee != NULL) { (void) unlink(queuename(ee, DATAFL_LETTER)); ee = ee->e_sibling; } /* Error. Restore e's sibling & recipient lists. */ e->e_sibling = firstsibling; for (i = 0; i < nrcpt - 1; ++i) addrs[i]->q_next = addrs[i + 1]; if (lsplits != NULL) sm_free(lsplits); return SM_SPLIT_FAIL; } /* prepend the new envelope to e->e_sibling */ ee->e_sibling = e->e_sibling; e->e_sibling = ee; ++nsplit; if (LogLevel > SPLIT_LOG_LEVEL && lsplits != NULL) { if (j >= l - strlen(ee->e_id) - 3) { char *p; l += MAXLINE; p = sm_realloc(lsplits, l); if (p == NULL) { /* let's try to get this done */ sm_free(lsplits); lsplits = NULL; } else lsplits = p; } if (lsplits != NULL) { if (j == 0) j += sm_strlcat(lsplits + j, ee->e_id, l - j); else j += sm_strlcat2(lsplits + j, "; ", ee->e_id, l - j); SM_ASSERT(j < l); } } if (nrcpt - i <= maxrcpt) break; i += maxrcpt; } if (LogLevel > SPLIT_LOG_LEVEL && lsplits != NULL) { if (nsplit > 0) { sm_syslog(LOG_NOTICE, e->e_id, "split: maxrcpts=%d, rcpts=%d, count=%d, id%s=%s", maxrcpt, nrcpt - ndead, nsplit, nsplit > 1 ? "s" : "", lsplits); } sm_free(lsplits); } return SM_SPLIT_NEW(nsplit); } /* ** SPLIT_BY_RECIPIENT ** ** Split an envelope with multiple recipients into multiple ** envelopes as required by the sendmail configuration. ** ** Parameters: ** e -- envelope. ** ** Results: ** Returns true on success, false on failure. ** ** Side Effects: ** see split_across_queue_groups(), split_within_queue(e) */ bool split_by_recipient(e) ENVELOPE *e; { int split, n, i, j, l; char *lsplits; ENVELOPE *ee, *next, *firstsibling; if (OpMode == SM_VERIFY || !ISVALIDQGRP(e->e_qgrp) || bitset(EF_SPLIT, e->e_flags)) return true; n = split_across_queue_groups(e); if (n == SM_SPLIT_FAIL) return false; firstsibling = ee = e->e_sibling; if (n > 1 && LogLevel > SPLIT_LOG_LEVEL) { l = MAXLINE; lsplits = sm_malloc(l); if (lsplits != NULL) *lsplits = '\0'; j = 0; } else { /* get rid of stupid compiler warnings */ lsplits = NULL; j = l = 0; } for (i = 1; i < n; ++i) { next = ee->e_sibling; if (split_within_queue(ee) == SM_SPLIT_FAIL) { e->e_sibling = firstsibling; return false; } ee->e_flags |= EF_SPLIT; if (LogLevel > SPLIT_LOG_LEVEL && lsplits != NULL) { if (j >= l - strlen(ee->e_id) - 3) { char *p; l += MAXLINE; p = sm_realloc(lsplits, l); if (p == NULL) { /* let's try to get this done */ sm_free(lsplits); lsplits = NULL; } else lsplits = p; } if (lsplits != NULL) { if (j == 0) j += sm_strlcat(lsplits + j, ee->e_id, l - j); else j += sm_strlcat2(lsplits + j, "; ", ee->e_id, l - j); SM_ASSERT(j < l); } } ee = next; } if (LogLevel > SPLIT_LOG_LEVEL && lsplits != NULL && n > 1) { sm_syslog(LOG_NOTICE, e->e_id, "split: count=%d, id%s=%s", n - 1, n > 2 ? "s" : "", lsplits); sm_free(lsplits); } split = split_within_queue(e) != SM_SPLIT_FAIL; if (split) e->e_flags |= EF_SPLIT; return split; } /* ** QUARANTINE_QUEUE_ITEM -- {un,}quarantine a single envelope ** ** Add/remove quarantine reason and requeue appropriately. ** ** Parameters: ** qgrp -- queue group for the item ** qdir -- queue directory in the given queue group ** e -- envelope information for the item ** reason -- quarantine reason, NULL means unquarantine. ** ** Results: ** true if item changed, false otherwise ** ** Side Effects: ** Changes quarantine tag in queue file and renames it. */ static bool quarantine_queue_item(qgrp, qdir, e, reason) int qgrp; int qdir; ENVELOPE *e; char *reason; { bool dirty = false; bool failing = false; bool foundq = false; bool finished = false; int fd; int flags; int oldtype; int newtype; int save_errno; MODE_T oldumask = 0; SM_FILE_T *oldqfp, *tempqfp; char *bp; char oldqf[MAXPATHLEN]; char tempqf[MAXPATHLEN]; char newqf[MAXPATHLEN]; char buf[MAXLINE]; oldtype = queue_letter(e, ANYQFL_LETTER); (void) sm_strlcpy(oldqf, queuename(e, ANYQFL_LETTER), sizeof oldqf); (void) sm_strlcpy(tempqf, queuename(e, NEWQFL_LETTER), sizeof tempqf); /* ** Instead of duplicating all the open ** and lock code here, tell readqf() to ** do that work and return the open ** file pointer in e_lockfp. Note that ** we must release the locks properly when ** we are done. */ if (!readqf(e, true)) { (void) sm_io_fprintf(smioout, SM_TIME_DEFAULT, "Skipping %s\n", qid_printname(e)); return false; } oldqfp = e->e_lockfp; /* open the new queue file */ flags = O_CREAT|O_WRONLY|O_EXCL; if (bitset(S_IWGRP, QueueFileMode)) oldumask = umask(002); fd = open(tempqf, flags, QueueFileMode); if (bitset(S_IWGRP, QueueFileMode)) (void) umask(oldumask); RELEASE_QUEUE; if (fd < 0) { save_errno = errno; (void) sm_io_fprintf(smioout, SM_TIME_DEFAULT, "Skipping %s: Could not open %s: %s\n", qid_printname(e), tempqf, sm_errstring(save_errno)); (void) sm_io_close(oldqfp, SM_TIME_DEFAULT); return false; } if (!lockfile(fd, tempqf, NULL, LOCK_EX|LOCK_NB)) { (void) sm_io_fprintf(smioout, SM_TIME_DEFAULT, "Skipping %s: Could not lock %s\n", qid_printname(e), tempqf); (void) close(fd); (void) sm_io_close(oldqfp, SM_TIME_DEFAULT); return false; } tempqfp = sm_io_open(SmFtStdiofd, SM_TIME_DEFAULT, (void *) &fd, SM_IO_WRONLY_B, NULL); if (tempqfp == NULL) { (void) sm_io_fprintf(smioout, SM_TIME_DEFAULT, "Skipping %s: Could not lock %s\n", qid_printname(e), tempqf); (void) close(fd); (void) sm_io_close(oldqfp, SM_TIME_DEFAULT); return false; } /* Copy the data over, changing the quarantine reason */ while ((bp = fgetfolded(buf, sizeof buf, oldqfp)) != NULL) { if (tTd(40, 4)) sm_dprintf("+++++ %s\n", bp); switch (bp[0]) { case 'q': /* quarantine reason */ foundq = true; if (reason == NULL) { if (Verbose) { (void) sm_io_fprintf(smioout, SM_TIME_DEFAULT, "%s: Removed quarantine of \"%s\"\n", e->e_id, &bp[1]); } sm_syslog(LOG_INFO, e->e_id, "unquarantine"); dirty = true; continue; } else if (strcmp(reason, &bp[1]) == 0) { if (Verbose) { (void) sm_io_fprintf(smioout, SM_TIME_DEFAULT, "%s: Already quarantined with \"%s\"\n", e->e_id, reason); } (void) sm_io_fprintf(tempqfp, SM_TIME_DEFAULT, "q%s\n", reason); } else { if (Verbose) { (void) sm_io_fprintf(smioout, SM_TIME_DEFAULT, "%s: Quarantine changed from \"%s\" to \"%s\"\n", e->e_id, &bp[1], reason); } (void) sm_io_fprintf(tempqfp, SM_TIME_DEFAULT, "q%s\n", reason); sm_syslog(LOG_INFO, e->e_id, "quarantine=%s", reason); dirty = true; } break; case 'S': /* ** If we are quarantining an unquarantined item, ** need to put in a new 'q' line before it's ** too late. */ if (!foundq && reason != NULL) { if (Verbose) { (void) sm_io_fprintf(smioout, SM_TIME_DEFAULT, "%s: Quarantined with \"%s\"\n", e->e_id, reason); } (void) sm_io_fprintf(tempqfp, SM_TIME_DEFAULT, "q%s\n", reason); sm_syslog(LOG_INFO, e->e_id, "quarantine=%s", reason); foundq = true; dirty = true; } /* Copy the line to the new file */ (void) sm_io_fprintf(tempqfp, SM_TIME_DEFAULT, "%s\n", bp); break; case '.': finished = true; /* FALLTHROUGH */ default: /* Copy the line to the new file */ (void) sm_io_fprintf(tempqfp, SM_TIME_DEFAULT, "%s\n", bp); break; } } /* Make sure we read the whole old file */ errno = sm_io_error(tempqfp); if (errno != 0 && errno != SM_IO_EOF) { save_errno = errno; (void) sm_io_fprintf(smioout, SM_TIME_DEFAULT, "Skipping %s: Error reading %s: %s\n", qid_printname(e), oldqf, sm_errstring(save_errno)); failing = true; } if (!failing && !finished) { (void) sm_io_fprintf(smioout, SM_TIME_DEFAULT, "Skipping %s: Incomplete file: %s\n", qid_printname(e), oldqf); failing = true; } /* Check if we actually changed anything or we can just bail now */ if (!dirty) { /* pretend we failed, even though we technically didn't */ failing = true; } /* Make sure we wrote things out safely */ if (!failing && (sm_io_flush(tempqfp, SM_TIME_DEFAULT) != 0 || ((SuperSafe == SAFE_REALLY || SuperSafe == SAFE_REALLY_POSTMILTER || SuperSafe == SAFE_INTERACTIVE) && fsync(sm_io_getinfo(tempqfp, SM_IO_WHAT_FD, NULL)) < 0) || ((errno = sm_io_error(tempqfp)) != 0))) { save_errno = errno; (void) sm_io_fprintf(smioout, SM_TIME_DEFAULT, "Skipping %s: Error writing %s: %s\n", qid_printname(e), tempqf, sm_errstring(save_errno)); failing = true; } /* Figure out the new filename */ newtype = (reason == NULL ? NORMQF_LETTER : QUARQF_LETTER); if (oldtype == newtype) { /* going to rename tempqf to oldqf */ (void) sm_strlcpy(newqf, oldqf, sizeof newqf); } else { /* going to rename tempqf to new name based on newtype */ (void) sm_strlcpy(newqf, queuename(e, newtype), sizeof newqf); } save_errno = 0; /* rename tempqf to newqf */ if (!failing && rename(tempqf, newqf) < 0) save_errno = (errno == 0) ? EINVAL : errno; /* Check rename() success */ if (!failing && save_errno != 0) { sm_syslog(LOG_DEBUG, e->e_id, "quarantine_queue_item: rename(%s, %s): %s", tempqf, newqf, sm_errstring(save_errno)); (void) sm_io_fprintf(smioout, SM_TIME_DEFAULT, "Error renaming %s to %s: %s\n", tempqf, newqf, sm_errstring(save_errno)); if (oldtype == newtype) { /* ** Bail here since we don't know the state of ** the filesystem and may need to keep tempqf ** for the user to rescue us. */ RELEASE_QUEUE; errno = save_errno; syserr("!452 Error renaming control file %s", tempqf); /* NOTREACHED */ } else { /* remove new file (if rename() half completed) */ if (xunlink(newqf) < 0) { save_errno = errno; (void) sm_io_fprintf(smioout, SM_TIME_DEFAULT, "Error removing %s: %s\n", newqf, sm_errstring(save_errno)); } /* tempqf removed below */ failing = true; } } /* If changing file types, need to remove old type */ if (!failing && oldtype != newtype) { if (xunlink(oldqf) < 0) { save_errno = errno; (void) sm_io_fprintf(smioout, SM_TIME_DEFAULT, "Error removing %s: %s\n", oldqf, sm_errstring(save_errno)); } } /* see if anything above failed */ if (failing) { /* Something failed: remove new file, old file still there */ (void) xunlink(tempqf); } /* ** fsync() after file operations to make sure metadata is ** written to disk on filesystems in which renames are ** not guaranteed. It's ok if they fail, mail won't be lost. */ if (SuperSafe != SAFE_NO) { /* for soft-updates */ (void) fsync(sm_io_getinfo(tempqfp, SM_IO_WHAT_FD, NULL)); if (!failing) { /* for soft-updates */ (void) fsync(sm_io_getinfo(oldqfp, SM_IO_WHAT_FD, NULL)); } /* for other odd filesystems */ SYNC_DIR(tempqf, false); } /* Close up shop */ RELEASE_QUEUE; if (tempqfp != NULL) (void) sm_io_close(tempqfp, SM_TIME_DEFAULT); if (oldqfp != NULL) (void) sm_io_close(oldqfp, SM_TIME_DEFAULT); /* All went well */ return !failing; } /* ** QUARANTINE_QUEUE -- {un,}quarantine matching items in the queue ** ** Read all matching queue items, add/remove quarantine ** reason, and requeue appropriately. ** ** Parameters: ** reason -- quarantine reason, "." means unquarantine. ** qgrplimit -- limit to single queue group unless NOQGRP ** ** Results: ** none. ** ** Side Effects: ** Lots of changes to the queue. */ void quarantine_queue(reason, qgrplimit) char *reason; int qgrplimit; { int changed = 0; int qgrp; /* Convert internal representation of unquarantine */ if (reason != NULL && reason[0] == '.' && reason[1] == '\0') reason = NULL; if (reason != NULL) { /* clean it */ reason = newstr(denlstring(reason, true, true)); } for (qgrp = 0; qgrp < NumQueue && Queue[qgrp] != NULL; qgrp++) { int qdir; if (qgrplimit != NOQGRP && qgrplimit != qgrp) continue; for (qdir = 0; qdir < Queue[qgrp]->qg_numqueues; qdir++) { int i; int nrequests; if (StopRequest) stop_sendmail(); nrequests = gatherq(qgrp, qdir, true, NULL, NULL); /* first see if there is anything */ if (nrequests <= 0) { if (Verbose) { (void) sm_io_fprintf(smioout, SM_TIME_DEFAULT, "%s: no matches\n", qid_printqueue(qgrp, qdir)); } continue; } if (Verbose) { (void) sm_io_fprintf(smioout, SM_TIME_DEFAULT, "Processing %s:\n", qid_printqueue(qgrp, qdir)); } for (i = 0; i < WorkListCount; i++) { ENVELOPE e; if (StopRequest) stop_sendmail(); /* setup envelope */ clearenvelope(&e, true, sm_rpool_new_x(NULL)); e.e_id = WorkList[i].w_name + 2; e.e_qgrp = qgrp; e.e_qdir = qdir; if (tTd(70, 101)) { sm_io_fprintf(smioout, SM_TIME_DEFAULT, "Would do %s\n", e.e_id); changed++; } else if (quarantine_queue_item(qgrp, qdir, &e, reason)) changed++; /* clean up */ sm_rpool_free(e.e_rpool); e.e_rpool = NULL; } if (WorkList != NULL) sm_free(WorkList); /* XXX */ WorkList = NULL; WorkListSize = 0; WorkListCount = 0; } } if (Verbose) { if (changed == 0) (void) sm_io_fprintf(smioout, SM_TIME_DEFAULT, "No changes\n"); else (void) sm_io_fprintf(smioout, SM_TIME_DEFAULT, "%d change%s\n", changed, changed == 1 ? "" : "s"); } }