/* $NetBSD: job.c,v 1.29 1999/09/04 04:21:28 christos Exp $ */ /* * Copyright (c) 1988, 1989, 1990 The Regents of the University of California. * Copyright (c) 1988, 1989 by Adam de Boor * Copyright (c) 1989 by Berkeley Softworks * All rights reserved. * * This code is derived from software contributed to Berkeley by * Adam de Boor. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * 3. All advertising materials mentioning features or use of this software * must display the following acknowledgement: * This product includes software developed by the University of * California, Berkeley and its contributors. * 4. Neither the name of the University nor the names of its contributors * may be used to endorse or promote products derived from this software * without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS ``AS IS'' AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. */ #ifdef MAKE_BOOTSTRAP static char rcsid[] = "$NetBSD: job.c,v 1.29 1999/09/04 04:21:28 christos Exp $"; #else #include #ifndef lint #if 0 static char sccsid[] = "@(#)job.c 8.2 (Berkeley) 3/19/94"; #else __RCSID("$NetBSD: job.c,v 1.29 1999/09/04 04:21:28 christos Exp $"); #endif #endif /* not lint */ #endif /*- * job.c -- * handle the creation etc. of our child processes. * * Interface: * Job_Make Start the creation of the given target. * * Job_CatchChildren Check for and handle the termination of any * children. This must be called reasonably * frequently to keep the whole make going at * a decent clip, since job table entries aren't * removed until their process is caught this way. * Its single argument is TRUE if the function * should block waiting for a child to terminate. * * Job_CatchOutput Print any output our children have produced. * Should also be called fairly frequently to * keep the user informed of what's going on. * If no output is waiting, it will block for * a time given by the SEL_* constants, below, * or until output is ready. * * Job_Init Called to intialize this module. in addition, * any commands attached to the .BEGIN target * are executed before this function returns. * Hence, the makefile must have been parsed * before this function is called. * * Job_End Cleanup any memory used. * * Job_Full Return TRUE if the job table is filled. * * Job_Empty Return TRUE if the job table is completely * empty. * * Job_ParseShell Given the line following a .SHELL target, parse * the line as a shell specification. Returns * FAILURE if the spec was incorrect. * * Job_Finish Perform any final processing which needs doing. * This includes the execution of any commands * which have been/were attached to the .END * target. It should only be called when the * job table is empty. * * Job_AbortAll Abort all currently running jobs. It doesn't * handle output or do anything for the jobs, * just kills them. It should only be called in * an emergency, as it were. * * Job_CheckCommands Verify that the commands for a target are * ok. Provide them if necessary and possible. * * Job_Touch Update a target without really updating it. * * Job_Wait Wait for all currently-running jobs to finish. */ #include #include #include #include #include #include #include #include #include #include #include #include "make.h" #include "hash.h" #include "dir.h" #include "job.h" #include "pathnames.h" #ifdef REMOTE #include "rmt.h" # define STATIC #else # define STATIC static #endif extern int errno; /* * error handling variables */ static int errors = 0; /* number of errors reported */ static int aborting = 0; /* why is the make aborting? */ #define ABORT_ERROR 1 /* Because of an error */ #define ABORT_INTERRUPT 2 /* Because it was interrupted */ #define ABORT_WAIT 3 /* Waiting for jobs to finish */ /* * XXX: Avoid SunOS bug... FILENO() is fp->_file, and file * is a char! So when we go above 127 we turn negative! */ #define FILENO(a) ((unsigned) fileno(a)) /* * post-make command processing. The node postCommands is really just the * .END target but we keep it around to avoid having to search for it * all the time. */ static GNode *postCommands; /* node containing commands to execute when * everything else is done */ static int numCommands; /* The number of commands actually printed * for a target. Should this number be * 0, no shell will be executed. */ /* * Return values from JobStart. */ #define JOB_RUNNING 0 /* Job is running */ #define JOB_ERROR 1 /* Error in starting the job */ #define JOB_FINISHED 2 /* The job is already finished */ #define JOB_STOPPED 3 /* The job is stopped */ /* * tfile is the name of a file into which all shell commands are put. It is * used over by removing it before the child shell is executed. The XXXXX in * the string are replaced by the pid of the make process in a 5-character * field with leading zeroes. */ static char tfile[] = TMPPAT; /* * Descriptions for various shells. */ static Shell shells[] = { /* * CSH description. The csh can do echo control by playing * with the setting of the 'echo' shell variable. Sadly, * however, it is unable to do error control nicely. */ { "csh", TRUE, "unset verbose", "set verbose", "unset verbose", 10, FALSE, "echo \"%s\"\n", "csh -c \"%s || exit 0\"", "v", "e", }, /* * SH description. Echo control is also possible and, under * sun UNIX anyway, one can even control error checking. */ { "sh", TRUE, "set -", "set -v", "set -", 5, TRUE, "set -e", "set +e", #ifdef OLDBOURNESHELL FALSE, "echo \"%s\"\n", "sh -c '%s || exit 0'\n", #endif #ifdef __NetBSD__ "vq", #else "v", #endif "e", }, /* * UNKNOWN. */ { (char *) 0, FALSE, (char *) 0, (char *) 0, (char *) 0, 0, FALSE, (char *) 0, (char *) 0, (char *) 0, (char *) 0, } }; static Shell *commandShell = &shells[DEFSHELL];/* this is the shell to * which we pass all * commands in the Makefile. * It is set by the * Job_ParseShell function */ static char *shellPath = NULL, /* full pathname of * executable image */ *shellName = NULL, /* last component of shell */ *shellArgv = NULL; /* Custom shell args */ static int maxJobs; /* The most children we can run at once */ static int maxLocal; /* The most local ones we can have */ STATIC int nJobs; /* The number of children currently running */ STATIC int nLocal; /* The number of local children */ STATIC Lst jobs; /* The structures that describe them */ STATIC Boolean jobFull; /* Flag to tell when the job table is full. It * is set TRUE when (1) the total number of * running jobs equals the maximum allowed or * (2) a job can only be run locally, but * nLocal equals maxLocal */ #ifndef RMT_WILL_WATCH static fd_set outputs; /* Set of descriptors of pipes connected to * the output channels of children */ #endif STATIC GNode *lastNode; /* The node for which output was most recently * produced. */ STATIC char *targFmt; /* Format string to use to head output from a * job when it's not the most-recent job heard * from */ #ifdef REMOTE # define TARG_FMT "--- %s at %s ---\n" /* Default format */ # define MESSAGE(fp, gn) \ (void) fprintf(fp, targFmt, gn->name, gn->rem.hname); #else # define TARG_FMT "--- %s ---\n" /* Default format */ # define MESSAGE(fp, gn) \ (void) fprintf(fp, targFmt, gn->name); #endif /* * When JobStart attempts to run a job remotely but can't, and isn't allowed * to run the job locally, or when Job_CatchChildren detects a job that has * been migrated home, the job is placed on the stoppedJobs queue to be run * when the next job finishes. */ STATIC Lst stoppedJobs; /* Lst of Job structures describing * jobs that were stopped due to concurrency * limits or migration home */ #if defined(USE_PGRP) && defined(SYSV) # define KILL(pid, sig) kill(-(pid), (sig)) #else # if defined(USE_PGRP) # define KILL(pid, sig) killpg((pid), (sig)) # else # define KILL(pid, sig) kill((pid), (sig)) # endif #endif /* * Grmpf... There is no way to set bits of the wait structure * anymore with the stupid W*() macros. I liked the union wait * stuff much more. So, we devise our own macros... This is * really ugly, use dramamine sparingly. You have been warned. */ #ifndef W_STOPCODE #define W_STOPCODE(sig) (((sig) << 8) | 0177) #endif #ifndef W_EXITCODE #define W_EXITCODE(ret, sig) ((ret << 8) | (sig)) #endif static int JobCondPassSig __P((ClientData, ClientData)); static void JobPassSig __P((int)); static int JobCmpPid __P((ClientData, ClientData)); static int JobPrintCommand __P((ClientData, ClientData)); static int JobSaveCommand __P((ClientData, ClientData)); static void JobClose __P((Job *)); #ifdef REMOTE static int JobCmpRmtID __P((Job *, int)); # ifdef RMT_WILL_WATCH static void JobLocalInput __P((int, Job *)); # endif #else static void JobFinish __P((Job *, int *)); static void JobExec __P((Job *, char **)); #endif static void JobMakeArgv __P((Job *, char **)); static void JobRestart __P((Job *)); static int JobStart __P((GNode *, int, Job *)); static char *JobOutput __P((Job *, char *, char *, int)); static void JobDoOutput __P((Job *, Boolean)); static Shell *JobMatchShell __P((char *)); static void JobInterrupt __P((int, int)); static void JobRestartJobs __P((void)); /*- *----------------------------------------------------------------------- * JobCondPassSig -- * Pass a signal to a job if the job is remote or if USE_PGRP * is defined. * * Results: * === 0 * * Side Effects: * None, except the job may bite it. * *----------------------------------------------------------------------- */ static int JobCondPassSig(jobp, signop) ClientData jobp; /* Job to biff */ ClientData signop; /* Signal to send it */ { Job *job = (Job *) jobp; int signo = *(int *) signop; #ifdef RMT_WANTS_SIGNALS if (job->flags & JOB_REMOTE) { (void) Rmt_Signal(job, signo); } else { KILL(job->pid, signo); } #else /* * Assume that sending the signal to job->pid will signal any remote * job as well. */ if (DEBUG(JOB)) { (void) fprintf(stdout, "JobCondPassSig passing signal %d to child %d.\n", signo, job->pid); (void) fflush(stdout); } KILL(job->pid, signo); #endif return 0; } /*- *----------------------------------------------------------------------- * JobPassSig -- * Pass a signal on to all remote jobs and to all local jobs if * USE_PGRP is defined, then die ourselves. * * Results: * None. * * Side Effects: * We die by the same signal. * *----------------------------------------------------------------------- */ static void JobPassSig(signo) int signo; /* The signal number we've received */ { sigset_t nmask, omask; struct sigaction act; int sigcont; if (DEBUG(JOB)) { (void) fprintf(stdout, "JobPassSig(%d) called.\n", signo); (void) fflush(stdout); } Lst_ForEach(jobs, JobCondPassSig, (ClientData) &signo); /* * Deal with proper cleanup based on the signal received. We only run * the .INTERRUPT target if the signal was in fact an interrupt. The other * three termination signals are more of a "get out *now*" command. */ if (signo == SIGINT) { JobInterrupt(TRUE, signo); } else if ((signo == SIGHUP) || (signo == SIGTERM) || (signo == SIGQUIT)) { JobInterrupt(FALSE, signo); } /* * Leave gracefully if SIGQUIT, rather than core dumping. */ if (signo == SIGQUIT) { Finish(0); } /* * Send ourselves the signal now we've given the message to everyone else. * Note we block everything else possible while we're getting the signal. * This ensures that all our jobs get continued when we wake up before * we take any other signal. */ sigfillset(&nmask); sigprocmask(SIG_SETMASK, &nmask, &omask); act.sa_handler = SIG_DFL; sigemptyset(&act.sa_mask); act.sa_flags = 0; sigaction(signo, &act, NULL); if (DEBUG(JOB)) { (void) fprintf(stdout, "JobPassSig passing signal to self, mask = %x.\n", ~0 & ~(1 << (signo-1))); (void) fflush(stdout); } (void) kill(getpid(), signo); if (signo != SIGTSTP) { sigcont = SIGCONT; Lst_ForEach(jobs, JobCondPassSig, (ClientData) &sigcont); } (void) sigprocmask(SIG_SETMASK, &omask, NULL); sigprocmask(SIG_SETMASK, &omask, NULL); if (signo != SIGCONT && signo != SIGTSTP) { act.sa_handler = JobPassSig; sigaction(sigcont, &act, NULL); } } /*- *----------------------------------------------------------------------- * JobCmpPid -- * Compare the pid of the job with the given pid and return 0 if they * are equal. This function is called from Job_CatchChildren via * Lst_Find to find the job descriptor of the finished job. * * Results: * 0 if the pid's match * * Side Effects: * None *----------------------------------------------------------------------- */ static int JobCmpPid(job, pid) ClientData job; /* job to examine */ ClientData pid; /* process id desired */ { return *(int *) pid - ((Job *) job)->pid; } #ifdef REMOTE /*- *----------------------------------------------------------------------- * JobCmpRmtID -- * Compare the rmtID of the job with the given rmtID and return 0 if they * are equal. * * Results: * 0 if the rmtID's match * * Side Effects: * None. *----------------------------------------------------------------------- */ static int JobCmpRmtID(job, rmtID) ClientData job; /* job to examine */ ClientData rmtID; /* remote id desired */ { return(*(int *) rmtID - *(int *) job->rmtID); } #endif /*- *----------------------------------------------------------------------- * JobPrintCommand -- * Put out another command for the given job. If the command starts * with an @ or a - we process it specially. In the former case, * so long as the -s and -n flags weren't given to make, we stick * a shell-specific echoOff command in the script. In the latter, * we ignore errors for the entire job, unless the shell has error * control. * If the command is just "..." we take all future commands for this * job to be commands to be executed once the entire graph has been * made and return non-zero to signal that the end of the commands * was reached. These commands are later attached to the postCommands * node and executed by Job_End when all things are done. * This function is called from JobStart via Lst_ForEach. * * Results: * Always 0, unless the command was "..." * * Side Effects: * If the command begins with a '-' and the shell has no error control, * the JOB_IGNERR flag is set in the job descriptor. * If the command is "..." and we're not ignoring such things, * tailCmds is set to the successor node of the cmd. * numCommands is incremented if the command is actually printed. *----------------------------------------------------------------------- */ static int JobPrintCommand(cmdp, jobp) ClientData cmdp; /* command string to print */ ClientData jobp; /* job for which to print it */ { Boolean noSpecials; /* true if we shouldn't worry about * inserting special commands into * the input stream. */ Boolean shutUp = FALSE; /* true if we put a no echo command * into the command file */ Boolean errOff = FALSE; /* true if we turned error checking * off before printing the command * and need to turn it back on */ char *cmdTemplate; /* Template to use when printing the * command */ char *cmdStart; /* Start of expanded command */ LstNode cmdNode; /* Node for replacing the command */ char *cmd = (char *) cmdp; Job *job = (Job *) jobp; noSpecials = noExecute && !(job->node->type & OP_MAKE); if (strcmp(cmd, "...") == 0) { job->node->type |= OP_SAVE_CMDS; if ((job->flags & JOB_IGNDOTS) == 0) { job->tailCmds = Lst_Succ(Lst_Member(job->node->commands, (ClientData)cmd)); return 1; } return 0; } #define DBPRINTF(fmt, arg) if (DEBUG(JOB)) { \ (void) fprintf(stdout, fmt, arg); \ (void) fflush(stdout); \ } \ (void) fprintf(job->cmdFILE, fmt, arg); \ (void) fflush(job->cmdFILE); numCommands += 1; /* * For debugging, we replace each command with the result of expanding * the variables in the command. */ cmdNode = Lst_Member(job->node->commands, (ClientData)cmd); cmdStart = cmd = Var_Subst(NULL, cmd, job->node, FALSE); Lst_Replace(cmdNode, (ClientData)cmdStart); cmdTemplate = "%s\n"; /* * Check for leading @' and -'s to control echoing and error checking. */ while (*cmd == '@' || *cmd == '-') { if (*cmd == '@') { shutUp = TRUE; } else { errOff = TRUE; } cmd++; } while (isspace((unsigned char) *cmd)) cmd++; if (shutUp) { if (!(job->flags & JOB_SILENT) && !noSpecials && commandShell->hasEchoCtl) { DBPRINTF("%s\n", commandShell->echoOff); } else { shutUp = FALSE; } } if (errOff) { if ( !(job->flags & JOB_IGNERR) && !noSpecials) { if (commandShell->hasErrCtl) { /* * we don't want the error-control commands showing * up either, so we turn off echoing while executing * them. We could put another field in the shell * structure to tell JobDoOutput to look for this * string too, but why make it any more complex than * it already is? */ if (!(job->flags & JOB_SILENT) && !shutUp && commandShell->hasEchoCtl) { DBPRINTF("%s\n", commandShell->echoOff); DBPRINTF("%s\n", commandShell->ignErr); DBPRINTF("%s\n", commandShell->echoOn); } else { DBPRINTF("%s\n", commandShell->ignErr); } } else if (commandShell->ignErr && (*commandShell->ignErr != '\0')) { /* * The shell has no error control, so we need to be * weird to get it to ignore any errors from the command. * If echoing is turned on, we turn it off and use the * errCheck template to echo the command. Leave echoing * off so the user doesn't see the weirdness we go through * to ignore errors. Set cmdTemplate to use the weirdness * instead of the simple "%s\n" template. */ if (!(job->flags & JOB_SILENT) && !shutUp && commandShell->hasEchoCtl) { DBPRINTF("%s\n", commandShell->echoOff); DBPRINTF(commandShell->errCheck, cmd); shutUp = TRUE; } cmdTemplate = commandShell->ignErr; /* * The error ignoration (hee hee) is already taken care * of by the ignErr template, so pretend error checking * is still on. */ errOff = FALSE; } else { errOff = FALSE; } } else { errOff = FALSE; } } DBPRINTF(cmdTemplate, cmd); free(cmdStart); if (errOff) { /* * If echoing is already off, there's no point in issuing the * echoOff command. Otherwise we issue it and pretend it was on * for the whole command... */ if (!shutUp && !(job->flags & JOB_SILENT) && commandShell->hasEchoCtl){ DBPRINTF("%s\n", commandShell->echoOff); shutUp = TRUE; } DBPRINTF("%s\n", commandShell->errCheck); } if (shutUp) { DBPRINTF("%s\n", commandShell->echoOn); } return 0; } /*- *----------------------------------------------------------------------- * JobSaveCommand -- * Save a command to be executed when everything else is done. * Callback function for JobFinish... * * Results: * Always returns 0 * * Side Effects: * The command is tacked onto the end of postCommands's commands list. * *----------------------------------------------------------------------- */ static int JobSaveCommand(cmd, gn) ClientData cmd; ClientData gn; { cmd = (ClientData) Var_Subst(NULL, (char *) cmd, (GNode *) gn, FALSE); (void) Lst_AtEnd(postCommands->commands, cmd); return(0); } /*- *----------------------------------------------------------------------- * JobClose -- * Called to close both input and output pipes when a job is finished. * * Results: * Nada * * Side Effects: * The file descriptors associated with the job are closed. * *----------------------------------------------------------------------- */ static void JobClose(job) Job *job; { if (usePipes) { #ifdef RMT_WILL_WATCH Rmt_Ignore(job->inPipe); #else FD_CLR(job->inPipe, &outputs); #endif if (job->outPipe != job->inPipe) { (void) close(job->outPipe); } JobDoOutput(job, TRUE); (void) close(job->inPipe); } else { (void) close(job->outFd); JobDoOutput(job, TRUE); } } /*- *----------------------------------------------------------------------- * JobFinish -- * Do final processing for the given job including updating * parents and starting new jobs as available/necessary. Note * that we pay no attention to the JOB_IGNERR flag here. * This is because when we're called because of a noexecute flag * or something, jstat.w_status is 0 and when called from * Job_CatchChildren, the status is zeroed if it s/b ignored. * * Results: * None * * Side Effects: * Some nodes may be put on the toBeMade queue. * Final commands for the job are placed on postCommands. * * If we got an error and are aborting (aborting == ABORT_ERROR) and * the job list is now empty, we are done for the day. * If we recognized an error (errors !=0), we set the aborting flag * to ABORT_ERROR so no more jobs will be started. *----------------------------------------------------------------------- */ /*ARGSUSED*/ static void JobFinish(job, status) Job *job; /* job to finish */ int *status; /* sub-why job went away */ { Boolean done; if ((WIFEXITED(*status) && (((WEXITSTATUS(*status) != 0) && !(job->flags & JOB_IGNERR)))) || WIFSIGNALED(*status)) { /* * If it exited non-zero and either we're doing things our * way or we're not ignoring errors, the job is finished. * Similarly, if the shell died because of a signal * the job is also finished. In these * cases, finish out the job's output before printing the exit * status... */ #ifdef REMOTE KILL(job->pid, SIGCONT); #endif JobClose(job); if (job->cmdFILE != NULL && job->cmdFILE != stdout) { (void) fclose(job->cmdFILE); } done = TRUE; #ifdef REMOTE if (job->flags & JOB_REMOTE) Rmt_Done(job->rmtID, job->node); #endif } else if (WIFEXITED(*status)) { /* * Deal with ignored errors in -B mode. We need to print a message * telling of the ignored error as well as setting status.w_status * to 0 so the next command gets run. To do this, we set done to be * TRUE if in -B mode and the job exited non-zero. */ done = WEXITSTATUS(*status) != 0; /* * Old comment said: "Note we don't * want to close down any of the streams until we know we're at the * end." * But we do. Otherwise when are we going to print the rest of the * stuff? */ JobClose(job); #ifdef REMOTE if (job->flags & JOB_REMOTE) Rmt_Done(job->rmtID, job->node); #endif /* REMOTE */ } else { /* * No need to close things down or anything. */ done = FALSE; } if (done || WIFSTOPPED(*status) || (WIFSIGNALED(*status) && (WTERMSIG(*status) == SIGCONT))) { FILE *out; if (compatMake && !usePipes && (job->flags & JOB_IGNERR)) { /* * If output is going to a file and this job is ignoring * errors, arrange to have the exit status sent to the * output file as well. */ out = fdopen(job->outFd, "w"); } else { out = stdout; } if (WIFEXITED(*status)) { if (DEBUG(JOB)) { (void) fprintf(stdout, "Process %d exited.\n", job->pid); (void) fflush(stdout); } if (WEXITSTATUS(*status) != 0) { if (usePipes && job->node != lastNode) { MESSAGE(out, job->node); lastNode = job->node; } (void) fprintf(out, "*** Error code %d%s\n", WEXITSTATUS(*status), (job->flags & JOB_IGNERR) ? "(ignored)" : ""); if (job->flags & JOB_IGNERR) { *status = 0; } } else if (DEBUG(JOB)) { if (usePipes && job->node != lastNode) { MESSAGE(out, job->node); lastNode = job->node; } (void) fprintf(out, "*** Completed successfully\n"); } } else if (WIFSTOPPED(*status) && WSTOPSIG(*status) != SIGCONT) { if (DEBUG(JOB)) { (void) fprintf(stdout, "Process %d stopped.\n", job->pid); (void) fflush(stdout); } if (usePipes && job->node != lastNode) { MESSAGE(out, job->node); lastNode = job->node; } if (!(job->flags & JOB_REMIGRATE)) { switch (WSTOPSIG(*status)) { case SIGTSTP: (void) fprintf(out, "*** Suspended\n"); break; case SIGSTOP: (void) fprintf(out, "*** Stopped\n"); break; default: (void) fprintf(out, "*** Stopped -- signal %d\n", WSTOPSIG(*status)); } } job->flags |= JOB_RESUME; (void)Lst_AtEnd(stoppedJobs, (ClientData)job); #ifdef REMOTE if (job->flags & JOB_REMIGRATE) JobRestart(job); #endif (void) fflush(out); return; } else if (WIFSTOPPED(*status) && WSTOPSIG(*status) == SIGCONT) { /* * If the beastie has continued, shift the Job from the stopped * list to the running one (or re-stop it if concurrency is * exceeded) and go and get another child. */ if (job->flags & (JOB_RESUME|JOB_REMIGRATE|JOB_RESTART)) { if (usePipes && job->node != lastNode) { MESSAGE(out, job->node); lastNode = job->node; } (void) fprintf(out, "*** Continued\n"); } if (!(job->flags & JOB_CONTINUING)) { if (DEBUG(JOB)) { (void) fprintf(stdout, "Warning: process %d was not continuing.\n", job->pid); (void) fflush(stdout); } #ifdef notdef /* * We don't really want to restart a job from scratch just * because it continued, especially not without killing the * continuing process! That's why this is ifdef'ed out. * FD - 9/17/90 */ JobRestart(job); #endif } job->flags &= ~JOB_CONTINUING; Lst_AtEnd(jobs, (ClientData)job); nJobs += 1; if (!(job->flags & JOB_REMOTE)) { if (DEBUG(JOB)) { (void) fprintf(stdout, "Process %d is continuing locally.\n", job->pid); (void) fflush(stdout); } nLocal += 1; } if (nJobs == maxJobs) { jobFull = TRUE; if (DEBUG(JOB)) { (void) fprintf(stdout, "Job queue is full.\n"); (void) fflush(stdout); } } (void) fflush(out); return; } else { if (usePipes && job->node != lastNode) { MESSAGE(out, job->node); lastNode = job->node; } (void) fprintf(out, "*** Signal %d\n", WTERMSIG(*status)); } (void) fflush(out); } /* * Now handle the -B-mode stuff. If the beast still isn't finished, * try and restart the job on the next command. If JobStart says it's * ok, it's ok. If there's an error, this puppy is done. */ if (compatMake && (WIFEXITED(*status) && !Lst_IsAtEnd(job->node->commands))) { switch (JobStart(job->node, job->flags & JOB_IGNDOTS, job)) { case JOB_RUNNING: done = FALSE; break; case JOB_ERROR: done = TRUE; *status = W_EXITCODE(1, 0); break; case JOB_FINISHED: /* * If we got back a JOB_FINISHED code, JobStart has already * called Make_Update and freed the job descriptor. We set * done to false here to avoid fake cycles and double frees. * JobStart needs to do the update so we can proceed up the * graph when given the -n flag.. */ done = FALSE; break; } } else { done = TRUE; } if (done && (aborting != ABORT_ERROR) && (aborting != ABORT_INTERRUPT) && (*status == 0)) { /* * As long as we aren't aborting and the job didn't return a non-zero * status that we shouldn't ignore, we call Make_Update to update * the parents. In addition, any saved commands for the node are placed * on the .END target. */ if (job->tailCmds != NILLNODE) { Lst_ForEachFrom(job->node->commands, job->tailCmds, JobSaveCommand, (ClientData)job->node); } job->node->made = MADE; Make_Update(job->node); free((Address)job); } else if (*status != 0) { errors += 1; free((Address)job); } JobRestartJobs(); /* * Set aborting if any error. */ if (errors && !keepgoing && (aborting != ABORT_INTERRUPT)) { /* * If we found any errors in this batch of children and the -k flag * wasn't given, we set the aborting flag so no more jobs get * started. */ aborting = ABORT_ERROR; } if ((aborting == ABORT_ERROR) && Job_Empty()) { /* * If we are aborting and the job table is now empty, we finish. */ (void) eunlink(tfile); Finish(errors); } } /*- *----------------------------------------------------------------------- * Job_Touch -- * Touch the given target. Called by JobStart when the -t flag was * given * * Results: * None * * Side Effects: * The data modification of the file is changed. In addition, if the * file did not exist, it is created. *----------------------------------------------------------------------- */ void Job_Touch(gn, silent) GNode *gn; /* the node of the file to touch */ Boolean silent; /* TRUE if should not print messages */ { int streamID; /* ID of stream opened to do the touch */ struct utimbuf times; /* Times for utime() call */ if (gn->type & (OP_JOIN|OP_USE|OP_EXEC|OP_OPTIONAL|OP_PHONY)) { /* * .JOIN, .USE, .ZEROTIME and .OPTIONAL targets are "virtual" targets * and, as such, shouldn't really be created. */ return; } if (!silent || (noExecute && !(gn->type & OP_MAKE))) { (void) fprintf(stdout, "touch %s\n", gn->name); (void) fflush(stdout); } if (noExecute && !(gn->type & OP_MAKE)) { return; } if (gn->type & OP_ARCHV) { Arch_Touch(gn); } else if (gn->type & OP_LIB) { Arch_TouchLib(gn); } else { char *file = gn->path ? gn->path : gn->name; times.actime = times.modtime = now; if (utime(file, ×) < 0){ streamID = open(file, O_RDWR | O_CREAT, 0666); if (streamID >= 0) { char c; /* * Read and write a byte to the file to change the * modification time, then close the file. */ if (read(streamID, &c, 1) == 1) { (void) lseek(streamID, (off_t)0, SEEK_SET); (void) write(streamID, &c, 1); } (void) close(streamID); } else { (void) fprintf(stdout, "*** couldn't touch %s: %s", file, strerror(errno)); (void) fflush(stdout); } } } } /*- *----------------------------------------------------------------------- * Job_CheckCommands -- * Make sure the given node has all the commands it needs. * * Results: * TRUE if the commands list is/was ok. * * Side Effects: * The node will have commands from the .DEFAULT rule added to it * if it needs them. *----------------------------------------------------------------------- */ Boolean Job_CheckCommands(gn, abortProc) GNode *gn; /* The target whose commands need * verifying */ void (*abortProc) __P((char *, ...)); /* Function to abort with message */ { if (OP_NOP(gn->type) && Lst_IsEmpty(gn->commands) && (gn->type & OP_LIB) == 0) { /* * No commands. Look for .DEFAULT rule from which we might infer * commands */ if ((DEFAULT != NILGNODE) && !Lst_IsEmpty(DEFAULT->commands)) { char *p1; /* * Make only looks for a .DEFAULT if the node was never the * target of an operator, so that's what we do too. If * a .DEFAULT was given, we substitute its commands for gn's * commands and set the IMPSRC variable to be the target's name * The DEFAULT node acts like a transformation rule, in that * gn also inherits any attributes or sources attached to * .DEFAULT itself. */ Make_HandleUse(DEFAULT, gn); Var_Set(IMPSRC, Var_Value(TARGET, gn, &p1), gn); if (p1) free(p1); } else if (Dir_MTime(gn) == 0) { /* * The node wasn't the target of an operator we have no .DEFAULT * rule to go on and the target doesn't already exist. There's * nothing more we can do for this branch. If the -k flag wasn't * given, we stop in our tracks, otherwise we just don't update * this node's parents so they never get examined. */ static const char msg[] = "make: don't know how to make"; if (gn->type & OP_OPTIONAL) { (void) fprintf(stdout, "%s %s(ignored)\n", msg, gn->name); (void) fflush(stdout); } else if (keepgoing) { (void) fprintf(stdout, "%s %s(continuing)\n", msg, gn->name); (void) fflush(stdout); return FALSE; } else { (*abortProc)("%s %s. Stop", msg, gn->name); return FALSE; } } } return TRUE; } #ifdef RMT_WILL_WATCH /*- *----------------------------------------------------------------------- * JobLocalInput -- * Handle a pipe becoming readable. Callback function for Rmt_Watch * * Results: * None * * Side Effects: * JobDoOutput is called. * *----------------------------------------------------------------------- */ /*ARGSUSED*/ static void JobLocalInput(stream, job) int stream; /* Stream that's ready (ignored) */ Job *job; /* Job to which the stream belongs */ { JobDoOutput(job, FALSE); } #endif /* RMT_WILL_WATCH */ /*- *----------------------------------------------------------------------- * JobExec -- * Execute the shell for the given job. Called from JobStart and * JobRestart. * * Results: * None. * * Side Effects: * A shell is executed, outputs is altered and the Job structure added * to the job table. * *----------------------------------------------------------------------- */ static void JobExec(job, argv) Job *job; /* Job to execute */ char **argv; { int cpid; /* ID of new child */ if (DEBUG(JOB)) { int i; (void) fprintf(stdout, "Running %s %sly\n", job->node->name, job->flags&JOB_REMOTE?"remote":"local"); (void) fprintf(stdout, "\tCommand: "); for (i = 0; argv[i] != NULL; i++) { (void) fprintf(stdout, "%s ", argv[i]); } (void) fprintf(stdout, "\n"); (void) fflush(stdout); } /* * Some jobs produce no output and it's disconcerting to have * no feedback of their running (since they produce no output, the * banner with their name in it never appears). This is an attempt to * provide that feedback, even if nothing follows it. */ if ((lastNode != job->node) && (job->flags & JOB_FIRST) && !(job->flags & JOB_SILENT)) { MESSAGE(stdout, job->node); lastNode = job->node; } #ifdef RMT_NO_EXEC if (job->flags & JOB_REMOTE) { goto jobExecFinish; } #endif /* RMT_NO_EXEC */ if ((cpid = vfork()) == -1) { Punt("Cannot fork"); } else if (cpid == 0) { /* * Must duplicate the input stream down to the child's input and * reset it to the beginning (again). Since the stream was marked * close-on-exec, we must clear that bit in the new input. */ if (dup2(FILENO(job->cmdFILE), 0) == -1) Punt("Cannot dup2: %s", strerror(errno)); (void) fcntl(0, F_SETFD, 0); (void) lseek(0, (off_t)0, SEEK_SET); if (usePipes) { /* * Set up the child's output to be routed through the pipe * we've created for it. */ if (dup2(job->outPipe, 1) == -1) Punt("Cannot dup2: %s", strerror(errno)); } else { /* * We're capturing output in a file, so we duplicate the * descriptor to the temporary file into the standard * output. */ if (dup2(job->outFd, 1) == -1) Punt("Cannot dup2: %s", strerror(errno)); } /* * The output channels are marked close on exec. This bit was * duplicated by the dup2 (on some systems), so we have to clear * it before routing the shell's error output to the same place as * its standard output. */ (void) fcntl(1, F_SETFD, 0); if (dup2(1, 2) == -1) Punt("Cannot dup2: %s", strerror(errno)); #ifdef USE_PGRP /* * We want to switch the child into a different process family so * we can kill it and all its descendants in one fell swoop, * by killing its process family, but not commit suicide. */ # if defined(SYSV) (void) setsid(); # else (void) setpgid(0, getpid()); # endif #endif /* USE_PGRP */ #ifdef REMOTE if (job->flags & JOB_REMOTE) { Rmt_Exec(shellPath, argv, FALSE); } else #endif /* REMOTE */ (void) execv(shellPath, argv); (void) write(2, "Could not execute shell\n", sizeof("Could not execute shell")); _exit(1); } else { #ifdef REMOTE sigset_t nmask, omask; sigemptyset(&nmask); sigaddset(&nmask, SIGCHLD); sigprocmask(SIG_BLOCK, &nmask, &omask); #endif job->pid = cpid; if (usePipes && (job->flags & JOB_FIRST) ) { /* * The first time a job is run for a node, we set the current * position in the buffer to the beginning and mark another * stream to watch in the outputs mask */ job->curPos = 0; #ifdef RMT_WILL_WATCH Rmt_Watch(job->inPipe, JobLocalInput, job); #else FD_SET(job->inPipe, &outputs); #endif /* RMT_WILL_WATCH */ } if (job->flags & JOB_REMOTE) { #ifndef REMOTE job->rmtID = 0; #else job->rmtID = Rmt_LastID(job->pid); #endif /* REMOTE */ } else { nLocal += 1; /* * XXX: Used to not happen if REMOTE. Why? */ if (job->cmdFILE != NULL && job->cmdFILE != stdout) { (void) fclose(job->cmdFILE); job->cmdFILE = NULL; } } #ifdef REMOTE sigprocmask(SIG_SETMASK, &omask, NULL); #endif } #ifdef RMT_NO_EXEC jobExecFinish: #endif /* * Now the job is actually running, add it to the table. */ nJobs += 1; (void) Lst_AtEnd(jobs, (ClientData)job); if (nJobs == maxJobs) { jobFull = TRUE; } } /*- *----------------------------------------------------------------------- * JobMakeArgv -- * Create the argv needed to execute the shell for a given job. * * * Results: * * Side Effects: * *----------------------------------------------------------------------- */ static void JobMakeArgv(job, argv) Job *job; char **argv; { int argc; static char args[10]; /* For merged arguments */ argv[0] = shellName; argc = 1; if ((commandShell->exit && (*commandShell->exit != '-')) || (commandShell->echo && (*commandShell->echo != '-'))) { /* * At least one of the flags doesn't have a minus before it, so * merge them together. Have to do this because the *(&(@*#*&#$# * Bourne shell thinks its second argument is a file to source. * Grrrr. Note the ten-character limitation on the combined arguments. */ (void)snprintf(args, sizeof(args), "-%s%s", ((job->flags & JOB_IGNERR) ? "" : (commandShell->exit ? commandShell->exit : "")), ((job->flags & JOB_SILENT) ? "" : (commandShell->echo ? commandShell->echo : ""))); if (args[1]) { argv[argc] = args; argc++; } } else { if (!(job->flags & JOB_IGNERR) && commandShell->exit) { argv[argc] = commandShell->exit; argc++; } if (!(job->flags & JOB_SILENT) && commandShell->echo) { argv[argc] = commandShell->echo; argc++; } } argv[argc] = NULL; } /*- *----------------------------------------------------------------------- * JobRestart -- * Restart a job that stopped for some reason. * * Results: * None. * * Side Effects: * jobFull will be set if the job couldn't be run. * *----------------------------------------------------------------------- */ static void JobRestart(job) Job *job; /* Job to restart */ { #ifdef REMOTE int host; #endif if (job->flags & JOB_REMIGRATE) { if ( #ifdef REMOTE verboseRemigrates || #endif DEBUG(JOB)) { (void) fprintf(stdout, "*** remigrating %x(%s)\n", job->pid, job->node->name); (void) fflush(stdout); } #ifdef REMOTE if (!Rmt_ReExport(job->pid, job->node, &host)) { if (verboseRemigrates || DEBUG(JOB)) { (void) fprintf(stdout, "*** couldn't migrate...\n"); (void) fflush(stdout); } #endif if (nLocal != maxLocal) { /* * Job cannot be remigrated, but there's room on the local * machine, so resume the job and note that another * local job has started. */ if ( #ifdef REMOTE verboseRemigrates || #endif DEBUG(JOB)) { (void) fprintf(stdout, "*** resuming on local machine\n"); (void) fflush(stdout); } KILL(job->pid, SIGCONT); nLocal +=1; #ifdef REMOTE job->flags &= ~(JOB_REMIGRATE|JOB_RESUME|JOB_REMOTE); job->flags |= JOB_CONTINUING; #else job->flags &= ~(JOB_REMIGRATE|JOB_RESUME); #endif } else { /* * Job cannot be restarted. Mark the table as full and * place the job back on the list of stopped jobs. */ if ( #ifdef REMOTE verboseRemigrates || #endif DEBUG(JOB)) { (void) fprintf(stdout, "*** holding\n"); (void) fflush(stdout); } (void)Lst_AtFront(stoppedJobs, (ClientData)job); jobFull = TRUE; if (DEBUG(JOB)) { (void) fprintf(stdout, "Job queue is full.\n"); (void) fflush(stdout); } return; } #ifdef REMOTE } else { /* * Clear out the remigrate and resume flags. Set the continuing * flag so we know later on that the process isn't exiting just * because of a signal. */ job->flags &= ~(JOB_REMIGRATE|JOB_RESUME); job->flags |= JOB_CONTINUING; job->rmtID = host; } #endif (void)Lst_AtEnd(jobs, (ClientData)job); nJobs += 1; if (nJobs == maxJobs) { jobFull = TRUE; if (DEBUG(JOB)) { (void) fprintf(stdout, "Job queue is full.\n"); (void) fflush(stdout); } } } else if (job->flags & JOB_RESTART) { /* * Set up the control arguments to the shell. This is based on the * flags set earlier for this job. If the JOB_IGNERR flag is clear, * the 'exit' flag of the commandShell is used to cause it to exit * upon receiving an error. If the JOB_SILENT flag is clear, the * 'echo' flag of the commandShell is used to get it to start echoing * as soon as it starts processing commands. */ char *argv[10]; JobMakeArgv(job, argv); if (DEBUG(JOB)) { (void) fprintf(stdout, "Restarting %s...", job->node->name); (void) fflush(stdout); } #ifdef REMOTE if ((job->node->type&OP_NOEXPORT) || (nLocal < maxLocal && runLocalFirst) # ifdef RMT_NO_EXEC || !Rmt_Export(shellPath, argv, job) # else || !Rmt_Begin(shellPath, argv, job->node) # endif #endif { if (((nLocal >= maxLocal) && !(job->flags & JOB_SPECIAL))) { /* * Can't be exported and not allowed to run locally -- put it * back on the hold queue and mark the table full */ if (DEBUG(JOB)) { (void) fprintf(stdout, "holding\n"); (void) fflush(stdout); } (void)Lst_AtFront(stoppedJobs, (ClientData)job); jobFull = TRUE; if (DEBUG(JOB)) { (void) fprintf(stdout, "Job queue is full.\n"); (void) fflush(stdout); } return; } else { /* * Job may be run locally. */ if (DEBUG(JOB)) { (void) fprintf(stdout, "running locally\n"); (void) fflush(stdout); } job->flags &= ~JOB_REMOTE; } } #ifdef REMOTE else { /* * Can be exported. Hooray! */ if (DEBUG(JOB)) { (void) fprintf(stdout, "exporting\n"); (void) fflush(stdout); } job->flags |= JOB_REMOTE; } #endif JobExec(job, argv); } else { /* * The job has stopped and needs to be restarted. Why it stopped, * we don't know... */ if (DEBUG(JOB)) { (void) fprintf(stdout, "Resuming %s...", job->node->name); (void) fflush(stdout); } if (((job->flags & JOB_REMOTE) || (nLocal < maxLocal) || #ifdef REMOTE (((job->flags & JOB_SPECIAL) && (job->node->type & OP_NOEXPORT)) && (maxLocal == 0))) && #else ((job->flags & JOB_SPECIAL) && (maxLocal == 0))) && #endif (nJobs != maxJobs)) { /* * If the job is remote, it's ok to resume it as long as the * maximum concurrency won't be exceeded. If it's local and * we haven't reached the local concurrency limit already (or the * job must be run locally and maxLocal is 0), it's also ok to * resume it. */ Boolean error; extern int errno; int status; #ifdef RMT_WANTS_SIGNALS if (job->flags & JOB_REMOTE) { error = !Rmt_Signal(job, SIGCONT); } else #endif /* RMT_WANTS_SIGNALS */ error = (KILL(job->pid, SIGCONT) != 0); if (!error) { /* * Make sure the user knows we've continued the beast and * actually put the thing in the job table. */ job->flags |= JOB_CONTINUING; status = W_STOPCODE(SIGCONT); JobFinish(job, &status); job->flags &= ~(JOB_RESUME|JOB_CONTINUING); if (DEBUG(JOB)) { (void) fprintf(stdout, "done\n"); (void) fflush(stdout); } } else { Error("couldn't resume %s: %s", job->node->name, strerror(errno)); status = W_EXITCODE(1, 0); JobFinish(job, &status); } } else { /* * Job cannot be restarted. Mark the table as full and * place the job back on the list of stopped jobs. */ if (DEBUG(JOB)) { (void) fprintf(stdout, "table full\n"); (void) fflush(stdout); } (void) Lst_AtFront(stoppedJobs, (ClientData)job); jobFull = TRUE; if (DEBUG(JOB)) { (void) fprintf(stdout, "Job queue is full.\n"); (void) fflush(stdout); } } } } /*- *----------------------------------------------------------------------- * JobStart -- * Start a target-creation process going for the target described * by the graph node gn. * * Results: * JOB_ERROR if there was an error in the commands, JOB_FINISHED * if there isn't actually anything left to do for the job and * JOB_RUNNING if the job has been started. * * Side Effects: * A new Job node is created and added to the list of running * jobs. PMake is forked and a child shell created. *----------------------------------------------------------------------- */ static int JobStart(gn, flags, previous) GNode *gn; /* target to create */ int flags; /* flags for the job to override normal ones. * e.g. JOB_SPECIAL or JOB_IGNDOTS */ Job *previous; /* The previous Job structure for this node, * if any. */ { register Job *job; /* new job descriptor */ char *argv[10]; /* Argument vector to shell */ static int jobno = 0; /* job number of catching output in a file */ Boolean cmdsOK; /* true if the nodes commands were all right */ Boolean local; /* Set true if the job was run locally */ Boolean noExec; /* Set true if we decide not to run the job */ if (previous != NULL) { previous->flags &= ~(JOB_FIRST|JOB_IGNERR|JOB_SILENT|JOB_REMOTE); job = previous; } else { job = (Job *) emalloc(sizeof(Job)); if (job == NULL) { Punt("JobStart out of memory"); } flags |= JOB_FIRST; } job->node = gn; job->tailCmds = NILLNODE; /* * Set the initial value of the flags for this job based on the global * ones and the node's attributes... Any flags supplied by the caller * are also added to the field. */ job->flags = 0; if (Targ_Ignore(gn)) { job->flags |= JOB_IGNERR; } if (Targ_Silent(gn)) { job->flags |= JOB_SILENT; } job->flags |= flags; /* * Check the commands now so any attributes from .DEFAULT have a chance * to migrate to the node */ if (!compatMake && job->flags & JOB_FIRST) { cmdsOK = Job_CheckCommands(gn, Error); } else { cmdsOK = TRUE; } /* * If the -n flag wasn't given, we open up OUR (not the child's) * temporary file to stuff commands in it. The thing is rd/wr so we don't * need to reopen it to feed it to the shell. If the -n flag *was* given, * we just set the file to be stdout. Cute, huh? */ if ((gn->type & OP_MAKE) || (!noExecute && !touchFlag)) { /* * We're serious here, but if the commands were bogus, we're * also dead... */ if (!cmdsOK) { DieHorribly(); } job->cmdFILE = fopen(tfile, "w+"); if (job->cmdFILE == NULL) { Punt("Could not open %s", tfile); } (void) fcntl(FILENO(job->cmdFILE), F_SETFD, 1); /* * Send the commands to the command file, flush all its buffers then * rewind and remove the thing. */ noExec = FALSE; /* * used to be backwards; replace when start doing multiple commands * per shell. */ if (compatMake) { /* * Be compatible: If this is the first time for this node, * verify its commands are ok and open the commands list for * sequential access by later invocations of JobStart. * Once that is done, we take the next command off the list * and print it to the command file. If the command was an * ellipsis, note that there's nothing more to execute. */ if ((job->flags&JOB_FIRST) && (Lst_Open(gn->commands) != SUCCESS)){ cmdsOK = FALSE; } else { LstNode ln = Lst_Next(gn->commands); if ((ln == NILLNODE) || JobPrintCommand((ClientData) Lst_Datum(ln), (ClientData) job)) { noExec = TRUE; Lst_Close(gn->commands); } if (noExec && !(job->flags & JOB_FIRST)) { /* * If we're not going to execute anything, the job * is done and we need to close down the various * file descriptors we've opened for output, then * call JobDoOutput to catch the final characters or * send the file to the screen... Note that the i/o streams * are only open if this isn't the first job. * Note also that this could not be done in * Job_CatchChildren b/c it wasn't clear if there were * more commands to execute or not... */ JobClose(job); } } } else { /* * We can do all the commands at once. hooray for sanity */ numCommands = 0; Lst_ForEach(gn->commands, JobPrintCommand, (ClientData)job); /* * If we didn't print out any commands to the shell script, * there's not much point in executing the shell, is there? */ if (numCommands == 0) { noExec = TRUE; } } } else if (noExecute) { /* * Not executing anything -- just print all the commands to stdout * in one fell swoop. This will still set up job->tailCmds correctly. */ if (lastNode != gn) { MESSAGE(stdout, gn); lastNode = gn; } job->cmdFILE = stdout; /* * Only print the commands if they're ok, but don't die if they're * not -- just let the user know they're bad and keep going. It * doesn't do any harm in this case and may do some good. */ if (cmdsOK) { Lst_ForEach(gn->commands, JobPrintCommand, (ClientData)job); } /* * Don't execute the shell, thank you. */ noExec = TRUE; } else { /* * Just touch the target and note that no shell should be executed. * Set cmdFILE to stdout to make life easier. Check the commands, too, * but don't die if they're no good -- it does no harm to keep working * up the graph. */ job->cmdFILE = stdout; Job_Touch(gn, job->flags&JOB_SILENT); noExec = TRUE; } /* * If we're not supposed to execute a shell, don't. */ if (noExec) { /* * Unlink and close the command file if we opened one */ if (job->cmdFILE != stdout) { (void) eunlink(tfile); if (job->cmdFILE != NULL) (void) fclose(job->cmdFILE); } else { (void) fflush(stdout); } /* * We only want to work our way up the graph if we aren't here because * the commands for the job were no good. */ if (cmdsOK) { if (aborting == 0) { if (job->tailCmds != NILLNODE) { Lst_ForEachFrom(job->node->commands, job->tailCmds, JobSaveCommand, (ClientData)job->node); } Make_Update(job->node); } free((Address)job); return(JOB_FINISHED); } else { free((Address)job); return(JOB_ERROR); } } else { (void) fflush(job->cmdFILE); (void) eunlink(tfile); } /* * Set up the control arguments to the shell. This is based on the flags * set earlier for this job. */ JobMakeArgv(job, argv); /* * If we're using pipes to catch output, create the pipe by which we'll * get the shell's output. If we're using files, print out that we're * starting a job and then set up its temporary-file name. This is just * tfile with two extra digits tacked on -- jobno. */ if (!compatMake || (job->flags & JOB_FIRST)) { if (usePipes) { int fd[2]; if (pipe(fd) == -1) Punt("Cannot create pipe: %s", strerror(errno)); job->inPipe = fd[0]; job->outPipe = fd[1]; (void) fcntl(job->inPipe, F_SETFD, 1); (void) fcntl(job->outPipe, F_SETFD, 1); } else { (void) fprintf(stdout, "Remaking `%s'\n", gn->name); (void) fflush(stdout); (void)snprintf(job->outFile, sizeof(job->outFile), "%s%02d", tfile, jobno); jobno = (jobno + 1) % 100; job->outFd = open(job->outFile,O_WRONLY|O_CREAT|O_APPEND,0600); (void) fcntl(job->outFd, F_SETFD, 1); } } #ifdef REMOTE if (!(gn->type & OP_NOEXPORT) && !(runLocalFirst && nLocal < maxLocal)) { #ifdef RMT_NO_EXEC local = !Rmt_Export(shellPath, argv, job); #else local = !Rmt_Begin(shellPath, argv, job->node); #endif /* RMT_NO_EXEC */ if (!local) { job->flags |= JOB_REMOTE; } } else #endif local = TRUE; if (local && (((nLocal >= maxLocal) && !(job->flags & JOB_SPECIAL) && #ifdef REMOTE (!(gn->type & OP_NOEXPORT) || (maxLocal != 0)) #else (maxLocal != 0) #endif ))) { /* * The job can only be run locally, but we've hit the limit of * local concurrency, so put the job on hold until some other job * finishes. Note that the special jobs (.BEGIN, .INTERRUPT and .END) * may be run locally even when the local limit has been reached * (e.g. when maxLocal == 0), though they will be exported if at * all possible. In addition, any target marked with .NOEXPORT will * be run locally if maxLocal is 0. */ jobFull = TRUE; if (DEBUG(JOB)) { (void) fprintf(stdout, "Can only run job locally.\n"); (void) fflush(stdout); } job->flags |= JOB_RESTART; (void) Lst_AtEnd(stoppedJobs, (ClientData)job); } else { if ((nLocal >= maxLocal) && local) { /* * If we're running this job locally as a special case (see above), * at least say the table is full. */ jobFull = TRUE; if (DEBUG(JOB)) { (void) fprintf(stdout, "Local job queue is full.\n"); (void) fflush(stdout); } } JobExec(job, argv); } return(JOB_RUNNING); } static char * JobOutput(job, cp, endp, msg) register Job *job; register char *cp, *endp; int msg; { register char *ecp; if (commandShell->noPrint) { ecp = Str_FindSubstring(cp, commandShell->noPrint); while (ecp != NULL) { if (cp != ecp) { *ecp = '\0'; if (msg && job->node != lastNode) { MESSAGE(stdout, job->node); lastNode = job->node; } /* * The only way there wouldn't be a newline after * this line is if it were the last in the buffer. * however, since the non-printable comes after it, * there must be a newline, so we don't print one. */ (void) fprintf(stdout, "%s", cp); (void) fflush(stdout); } cp = ecp + commandShell->noPLen; if (cp != endp) { /* * Still more to print, look again after skipping * the whitespace following the non-printable * command.... */ cp++; while (*cp == ' ' || *cp == '\t' || *cp == '\n') { cp++; } ecp = Str_FindSubstring(cp, commandShell->noPrint); } else { return cp; } } } return cp; } /*- *----------------------------------------------------------------------- * JobDoOutput -- * This function is called at different times depending on * whether the user has specified that output is to be collected * via pipes or temporary files. In the former case, we are called * whenever there is something to read on the pipe. We collect more * output from the given job and store it in the job's outBuf. If * this makes up a line, we print it tagged by the job's identifier, * as necessary. * If output has been collected in a temporary file, we open the * file and read it line by line, transfering it to our own * output channel until the file is empty. At which point we * remove the temporary file. * In both cases, however, we keep our figurative eye out for the * 'noPrint' line for the shell from which the output came. If * we recognize a line, we don't print it. If the command is not * alone on the line (the character after it is not \0 or \n), we * do print whatever follows it. * * Results: * None * * Side Effects: * curPos may be shifted as may the contents of outBuf. *----------------------------------------------------------------------- */ STATIC void JobDoOutput(job, finish) register Job *job; /* the job whose output needs printing */ Boolean finish; /* TRUE if this is the last time we'll be * called for this job */ { Boolean gotNL = FALSE; /* true if got a newline */ Boolean fbuf; /* true if our buffer filled up */ register int nr; /* number of bytes read */ register int i; /* auxiliary index into outBuf */ register int max; /* limit for i (end of current data) */ int nRead; /* (Temporary) number of bytes read */ FILE *oFILE; /* Stream pointer to shell's output file */ char inLine[132]; if (usePipes) { /* * Read as many bytes as will fit in the buffer. */ end_loop: gotNL = FALSE; fbuf = FALSE; nRead = read(job->inPipe, &job->outBuf[job->curPos], JOB_BUFSIZE - job->curPos); if (nRead < 0) { if (DEBUG(JOB)) { perror("JobDoOutput(piperead)"); } nr = 0; } else { nr = nRead; } /* * If we hit the end-of-file (the job is dead), we must flush its * remaining output, so pretend we read a newline if there's any * output remaining in the buffer. * Also clear the 'finish' flag so we stop looping. */ if ((nr == 0) && (job->curPos != 0)) { job->outBuf[job->curPos] = '\n'; nr = 1; finish = FALSE; } else if (nr == 0) { finish = FALSE; } /* * Look for the last newline in the bytes we just got. If there is * one, break out of the loop with 'i' as its index and gotNL set * TRUE. */ max = job->curPos + nr; for (i = job->curPos + nr - 1; i >= job->curPos; i--) { if (job->outBuf[i] == '\n') { gotNL = TRUE; break; } else if (job->outBuf[i] == '\0') { /* * Why? */ job->outBuf[i] = ' '; } } if (!gotNL) { job->curPos += nr; if (job->curPos == JOB_BUFSIZE) { /* * If we've run out of buffer space, we have no choice * but to print the stuff. sigh. */ fbuf = TRUE; i = job->curPos; } } if (gotNL || fbuf) { /* * Need to send the output to the screen. Null terminate it * first, overwriting the newline character if there was one. * So long as the line isn't one we should filter (according * to the shell description), we print the line, preceeded * by a target banner if this target isn't the same as the * one for which we last printed something. * The rest of the data in the buffer are then shifted down * to the start of the buffer and curPos is set accordingly. */ job->outBuf[i] = '\0'; if (i >= job->curPos) { char *cp; cp = JobOutput(job, job->outBuf, &job->outBuf[i], FALSE); /* * There's still more in that thar buffer. This time, though, * we know there's no newline at the end, so we add one of * our own free will. */ if (*cp != '\0') { if (job->node != lastNode) { MESSAGE(stdout, job->node); lastNode = job->node; } (void) fprintf(stdout, "%s%s", cp, gotNL ? "\n" : ""); (void) fflush(stdout); } } if (i < max - 1) { /* shift the remaining characters down */ (void) memcpy(job->outBuf, &job->outBuf[i + 1], max - (i + 1)); job->curPos = max - (i + 1); } else { /* * We have written everything out, so we just start over * from the start of the buffer. No copying. No nothing. */ job->curPos = 0; } } if (finish) { /* * If the finish flag is true, we must loop until we hit * end-of-file on the pipe. This is guaranteed to happen * eventually since the other end of the pipe is now closed * (we closed it explicitly and the child has exited). When * we do get an EOF, finish will be set FALSE and we'll fall * through and out. */ goto end_loop; } } else { /* * We've been called to retrieve the output of the job from the * temporary file where it's been squirreled away. This consists of * opening the file, reading the output line by line, being sure not * to print the noPrint line for the shell we used, then close and * remove the temporary file. Very simple. * * Change to read in blocks and do FindSubString type things as for * pipes? That would allow for "@echo -n..." */ oFILE = fopen(job->outFile, "r"); if (oFILE != NULL) { (void) fprintf(stdout, "Results of making %s:\n", job->node->name); (void) fflush(stdout); while (fgets(inLine, sizeof(inLine), oFILE) != NULL) { register char *cp, *endp, *oendp; cp = inLine; oendp = endp = inLine + strlen(inLine); if (endp[-1] == '\n') { *--endp = '\0'; } cp = JobOutput(job, inLine, endp, FALSE); /* * There's still more in that thar buffer. This time, though, * we know there's no newline at the end, so we add one of * our own free will. */ (void) fprintf(stdout, "%s", cp); (void) fflush(stdout); if (endp != oendp) { (void) fprintf(stdout, "\n"); (void) fflush(stdout); } } (void) fclose(oFILE); (void) eunlink(job->outFile); } } } /*- *----------------------------------------------------------------------- * Job_CatchChildren -- * Handle the exit of a child. Called from Make_Make. * * Results: * none. * * Side Effects: * The job descriptor is removed from the list of children. * * Notes: * We do waits, blocking or not, according to the wisdom of our * caller, until there are no more children to report. For each * job, call JobFinish to finish things off. This will take care of * putting jobs on the stoppedJobs queue. * *----------------------------------------------------------------------- */ void Job_CatchChildren(block) Boolean block; /* TRUE if should block on the wait. */ { int pid; /* pid of dead child */ register Job *job; /* job descriptor for dead child */ LstNode jnode; /* list element for finding job */ int status; /* Exit/termination status */ /* * Don't even bother if we know there's no one around. */ if (nLocal == 0) { return; } while ((pid = waitpid((pid_t) -1, &status, (block?0:WNOHANG)|WUNTRACED)) > 0) { if (DEBUG(JOB)) { (void) fprintf(stdout, "Process %d exited or stopped %x.\n", pid, status); (void) fflush(stdout); } jnode = Lst_Find(jobs, (ClientData)&pid, JobCmpPid); if (jnode == NILLNODE) { if (WIFSTOPPED(status) && (WSTOPSIG(status) == SIGCONT)) { jnode = Lst_Find(stoppedJobs, (ClientData) &pid, JobCmpPid); if (jnode == NILLNODE) { Error("Resumed child (%d) not in table", pid); continue; } job = (Job *)Lst_Datum(jnode); (void) Lst_Remove(stoppedJobs, jnode); } else { Error("Child (%d) not in table?", pid); continue; } } else { job = (Job *) Lst_Datum(jnode); (void) Lst_Remove(jobs, jnode); nJobs -= 1; if (jobFull && DEBUG(JOB)) { (void) fprintf(stdout, "Job queue is no longer full.\n"); (void) fflush(stdout); } jobFull = FALSE; #ifdef REMOTE if (!(job->flags & JOB_REMOTE)) { if (DEBUG(JOB)) { (void) fprintf(stdout, "Job queue has one fewer local process.\n"); (void) fflush(stdout); } nLocal -= 1; } #else nLocal -= 1; #endif } JobFinish(job, &status); } } /*- *----------------------------------------------------------------------- * Job_CatchOutput -- * Catch the output from our children, if we're using * pipes do so. Otherwise just block time until we get a * signal (most likely a SIGCHLD) since there's no point in * just spinning when there's nothing to do and the reaping * of a child can wait for a while. * * Results: * None * * Side Effects: * Output is read from pipes if we're piping. * ----------------------------------------------------------------------- */ void Job_CatchOutput() { int nfds; struct timeval timeout; fd_set readfds; register LstNode ln; register Job *job; #ifdef RMT_WILL_WATCH int pnJobs; /* Previous nJobs */ #endif (void) fflush(stdout); #ifdef RMT_WILL_WATCH pnJobs = nJobs; /* * It is possible for us to be called with nJobs equal to 0. This happens * if all the jobs finish and a job that is stopped cannot be run * locally (eg if maxLocal is 0) and cannot be exported. The job will * be placed back on the stoppedJobs queue, Job_Empty() will return false, * Make_Run will call us again when there's nothing for which to wait. * nJobs never changes, so we loop forever. Hence the check. It could * be argued that we should sleep for a bit so as not to swamp the * exportation system with requests. Perhaps we should. * * NOTE: IT IS THE RESPONSIBILITY OF Rmt_Wait TO CALL Job_CatchChildren * IN A TIMELY FASHION TO CATCH ANY LOCALLY RUNNING JOBS THAT EXIT. * It may use the variable nLocal to determine if it needs to call * Job_CatchChildren (if nLocal is 0, there's nothing for which to * wait...) */ while (nJobs != 0 && pnJobs == nJobs) { Rmt_Wait(); } #else if (usePipes) { readfds = outputs; timeout.tv_sec = SEL_SEC; timeout.tv_usec = SEL_USEC; if ((nfds = select(FD_SETSIZE, &readfds, (fd_set *) 0, (fd_set *) 0, &timeout)) <= 0) return; else { if (Lst_Open(jobs) == FAILURE) { Punt("Cannot open job table"); } while (nfds && (ln = Lst_Next(jobs)) != NILLNODE) { job = (Job *) Lst_Datum(ln); if (FD_ISSET(job->inPipe, &readfds)) { JobDoOutput(job, FALSE); nfds -= 1; } } Lst_Close(jobs); } } #endif /* RMT_WILL_WATCH */ } /*- *----------------------------------------------------------------------- * Job_Make -- * Start the creation of a target. Basically a front-end for * JobStart used by the Make module. * * Results: * None. * * Side Effects: * Another job is started. * *----------------------------------------------------------------------- */ void Job_Make(gn) GNode *gn; { (void) JobStart(gn, 0, NULL); } /*- *----------------------------------------------------------------------- * Job_Init -- * Initialize the process module * * Results: * none * * Side Effects: * lists and counters are initialized *----------------------------------------------------------------------- */ void Job_Init(maxproc, maxlocal) int maxproc; /* the greatest number of jobs which may be * running at one time */ int maxlocal; /* the greatest number of local jobs which may * be running at once. */ { GNode *begin; /* node for commands to do at the very start */ (void) snprintf(tfile, sizeof(tfile), "/tmp/make%05ld", (unsigned long)getpid()); jobs = Lst_Init(FALSE); stoppedJobs = Lst_Init(FALSE); maxJobs = maxproc; maxLocal = maxlocal; nJobs = 0; nLocal = 0; jobFull = FALSE; aborting = 0; errors = 0; lastNode = NILGNODE; if (maxJobs == 1 #ifdef REMOTE || noMessages #endif ) { /* * If only one job can run at a time, there's no need for a banner, * no is there? */ targFmt = ""; } else { targFmt = TARG_FMT; } if (shellPath == NULL) { /* * The user didn't specify a shell to use, so we are using the * default one... Both the absolute path and the last component * must be set. The last component is taken from the 'name' field * of the default shell description pointed-to by commandShell. * All default shells are located in _PATH_DEFSHELLDIR. */ shellName = commandShell->name; shellPath = str_concat(_PATH_DEFSHELLDIR, shellName, STR_ADDSLASH); } if (commandShell->exit == NULL) { commandShell->exit = ""; } if (commandShell->echo == NULL) { commandShell->echo = ""; } /* * Catch the four signals that POSIX specifies if they aren't ignored. * JobPassSig will take care of calling JobInterrupt if appropriate. */ if (signal(SIGINT, SIG_IGN) != SIG_IGN) { (void) signal(SIGINT, JobPassSig); } if (signal(SIGHUP, SIG_IGN) != SIG_IGN) { (void) signal(SIGHUP, JobPassSig); } if (signal(SIGQUIT, SIG_IGN) != SIG_IGN) { (void) signal(SIGQUIT, JobPassSig); } if (signal(SIGTERM, SIG_IGN) != SIG_IGN) { (void) signal(SIGTERM, JobPassSig); } /* * There are additional signals that need to be caught and passed if * either the export system wants to be told directly of signals or if * we're giving each job its own process group (since then it won't get * signals from the terminal driver as we own the terminal) */ #if defined(RMT_WANTS_SIGNALS) || defined(USE_PGRP) if (signal(SIGTSTP, SIG_IGN) != SIG_IGN) { (void) signal(SIGTSTP, JobPassSig); } if (signal(SIGTTOU, SIG_IGN) != SIG_IGN) { (void) signal(SIGTTOU, JobPassSig); } if (signal(SIGTTIN, SIG_IGN) != SIG_IGN) { (void) signal(SIGTTIN, JobPassSig); } if (signal(SIGWINCH, SIG_IGN) != SIG_IGN) { (void) signal(SIGWINCH, JobPassSig); } #endif begin = Targ_FindNode(".BEGIN", TARG_NOCREATE); if (begin != NILGNODE) { JobStart(begin, JOB_SPECIAL, (Job *)0); while (nJobs) { Job_CatchOutput(); #ifndef RMT_WILL_WATCH Job_CatchChildren(!usePipes); #endif /* RMT_WILL_WATCH */ } } postCommands = Targ_FindNode(".END", TARG_CREATE); } /*- *----------------------------------------------------------------------- * Job_Full -- * See if the job table is full. It is considered full if it is OR * if we are in the process of aborting OR if we have * reached/exceeded our local quota. This prevents any more jobs * from starting up. * * Results: * TRUE if the job table is full, FALSE otherwise * Side Effects: * None. *----------------------------------------------------------------------- */ Boolean Job_Full() { return(aborting || jobFull); } /*- *----------------------------------------------------------------------- * Job_Empty -- * See if the job table is empty. Because the local concurrency may * be set to 0, it is possible for the job table to become empty, * while the list of stoppedJobs remains non-empty. In such a case, * we want to restart as many jobs as we can. * * Results: * TRUE if it is. FALSE if it ain't. * * Side Effects: * None. * * ----------------------------------------------------------------------- */ Boolean Job_Empty() { if (nJobs == 0) { if (!Lst_IsEmpty(stoppedJobs) && !aborting) { /* * The job table is obviously not full if it has no jobs in * it...Try and restart the stopped jobs. */ jobFull = FALSE; JobRestartJobs(); return(FALSE); } else { return(TRUE); } } else { return(FALSE); } } /*- *----------------------------------------------------------------------- * JobMatchShell -- * Find a matching shell in 'shells' given its final component. * * Results: * A pointer to the Shell structure. * * Side Effects: * None. * *----------------------------------------------------------------------- */ static Shell * JobMatchShell(name) char *name; /* Final component of shell path */ { register Shell *sh; /* Pointer into shells table */ Shell *match; /* Longest-matching shell */ register char *cp1, *cp2; char *eoname; eoname = name + strlen(name); match = NULL; for (sh = shells; sh->name != NULL; sh++) { for (cp1 = eoname - strlen(sh->name), cp2 = sh->name; *cp1 != '\0' && *cp1 == *cp2; cp1++, cp2++) { continue; } if (*cp1 != *cp2) { continue; } else if (match == NULL || strlen(match->name) < strlen(sh->name)) { match = sh; } } return(match == NULL ? sh : match); } /*- *----------------------------------------------------------------------- * Job_ParseShell -- * Parse a shell specification and set up commandShell, shellPath * and shellName appropriately. * * Results: * FAILURE if the specification was incorrect. * * Side Effects: * commandShell points to a Shell structure (either predefined or * created from the shell spec), shellPath is the full path of the * shell described by commandShell, while shellName is just the * final component of shellPath. * * Notes: * A shell specification consists of a .SHELL target, with dependency * operator, followed by a series of blank-separated words. Double * quotes can be used to use blanks in words. A backslash escapes * anything (most notably a double-quote and a space) and * provides the functionality it does in C. Each word consists of * keyword and value separated by an equal sign. There should be no * unnecessary spaces in the word. The keywords are as follows: * name Name of shell. * path Location of shell. Overrides "name" if given * quiet Command to turn off echoing. * echo Command to turn echoing on * filter Result of turning off echoing that shouldn't be * printed. * echoFlag Flag to turn echoing on at the start * errFlag Flag to turn error checking on at the start * hasErrCtl True if shell has error checking control * check Command to turn on error checking if hasErrCtl * is TRUE or template of command to echo a command * for which error checking is off if hasErrCtl is * FALSE. * ignore Command to turn off error checking if hasErrCtl * is TRUE or template of command to execute a * command so as to ignore any errors it returns if * hasErrCtl is FALSE. * *----------------------------------------------------------------------- */ ReturnStatus Job_ParseShell(line) char *line; /* The shell spec */ { char **words; int wordCount; register char **argv; register int argc; char *path; Shell newShell; Boolean fullSpec = FALSE; while (isspace((unsigned char)*line)) { line++; } if (shellArgv) free(shellArgv); words = brk_string(line, &wordCount, TRUE, &shellArgv); memset((Address)&newShell, 0, sizeof(newShell)); /* * Parse the specification by keyword */ for (path = NULL, argc = wordCount - 1, argv = words; argc != 0; argc--, argv++) { if (strncmp(*argv, "path=", 5) == 0) { path = &argv[0][5]; } else if (strncmp(*argv, "name=", 5) == 0) { newShell.name = &argv[0][5]; } else { if (strncmp(*argv, "quiet=", 6) == 0) { newShell.echoOff = &argv[0][6]; } else if (strncmp(*argv, "echo=", 5) == 0) { newShell.echoOn = &argv[0][5]; } else if (strncmp(*argv, "filter=", 7) == 0) { newShell.noPrint = &argv[0][7]; newShell.noPLen = strlen(newShell.noPrint); } else if (strncmp(*argv, "echoFlag=", 9) == 0) { newShell.echo = &argv[0][9]; } else if (strncmp(*argv, "errFlag=", 8) == 0) { newShell.exit = &argv[0][8]; } else if (strncmp(*argv, "hasErrCtl=", 10) == 0) { char c = argv[0][10]; newShell.hasErrCtl = !((c != 'Y') && (c != 'y') && (c != 'T') && (c != 't')); } else if (strncmp(*argv, "check=", 6) == 0) { newShell.errCheck = &argv[0][6]; } else if (strncmp(*argv, "ignore=", 7) == 0) { newShell.ignErr = &argv[0][7]; } else { Parse_Error(PARSE_FATAL, "Unknown keyword \"%s\"", *argv); free(words); return(FAILURE); } fullSpec = TRUE; } } if (path == NULL) { /* * If no path was given, the user wants one of the pre-defined shells, * yes? So we find the one s/he wants with the help of JobMatchShell * and set things up the right way. shellPath will be set up by * Job_Init. */ if (newShell.name == NULL) { Parse_Error(PARSE_FATAL, "Neither path nor name specified"); return(FAILURE); } else { commandShell = JobMatchShell(newShell.name); shellName = newShell.name; } } else { /* * The user provided a path. If s/he gave nothing else (fullSpec is * FALSE), try and find a matching shell in the ones we know of. * Else we just take the specification at its word and copy it * to a new location. In either case, we need to record the * path the user gave for the shell. */ shellPath = path; path = strrchr(path, '/'); if (path == NULL) { path = shellPath; } else { path += 1; } if (newShell.name != NULL) { shellName = newShell.name; } else { shellName = path; } if (!fullSpec) { commandShell = JobMatchShell(shellName); } else { commandShell = (Shell *) emalloc(sizeof(Shell)); *commandShell = newShell; } } if (commandShell->echoOn && commandShell->echoOff) { commandShell->hasEchoCtl = TRUE; } if (!commandShell->hasErrCtl) { if (commandShell->errCheck == NULL) { commandShell->errCheck = ""; } if (commandShell->ignErr == NULL) { commandShell->ignErr = "%s\n"; } } /* * Do not free up the words themselves, since they might be in use by the * shell specification. */ free(words); return SUCCESS; } /*- *----------------------------------------------------------------------- * JobInterrupt -- * Handle the receipt of an interrupt. * * Results: * None * * Side Effects: * All children are killed. Another job will be started if the * .INTERRUPT target was given. *----------------------------------------------------------------------- */ static void JobInterrupt(runINTERRUPT, signo) int runINTERRUPT; /* Non-zero if commands for the .INTERRUPT * target should be executed */ int signo; /* signal received */ { LstNode ln; /* element in job table */ Job *job; /* job descriptor in that element */ GNode *interrupt; /* the node describing the .INTERRUPT target */ aborting = ABORT_INTERRUPT; (void) Lst_Open(jobs); while ((ln = Lst_Next(jobs)) != NILLNODE) { job = (Job *) Lst_Datum(ln); if (!Targ_Precious(job->node)) { char *file = (job->node->path == NULL ? job->node->name : job->node->path); if (!noExecute && eunlink(file) != -1) { Error("*** %s removed", file); } } #ifdef RMT_WANTS_SIGNALS if (job->flags & JOB_REMOTE) { /* * If job is remote, let the Rmt module do the killing. */ if (!Rmt_Signal(job, signo)) { /* * If couldn't kill the thing, finish it out now with an * error code, since no exit report will come in likely. */ int status; status.w_status = 0; status.w_retcode = 1; JobFinish(job, &status); } } else if (job->pid) { KILL(job->pid, signo); } #else if (job->pid) { if (DEBUG(JOB)) { (void) fprintf(stdout, "JobInterrupt passing signal to child %d.\n", job->pid); (void) fflush(stdout); } KILL(job->pid, signo); } #endif /* RMT_WANTS_SIGNALS */ } #ifdef REMOTE (void)Lst_Open(stoppedJobs); while ((ln = Lst_Next(stoppedJobs)) != NILLNODE) { job = (Job *) Lst_Datum(ln); if (job->flags & JOB_RESTART) { if (DEBUG(JOB)) { (void) fprintf(stdout, "%s%s", "JobInterrupt skipping job on stopped queue", "-- it was waiting to be restarted.\n"); (void) fflush(stdout); } continue; } if (!Targ_Precious(job->node)) { char *file = (job->node->path == NULL ? job->node->name : job->node->path); if (eunlink(file) == 0) { Error("*** %s removed", file); } } /* * Resume the thing so it will take the signal. */ if (DEBUG(JOB)) { (void) fprintf(stdout, "JobInterrupt passing CONT to stopped child %d.\n", job->pid); (void) fflush(stdout); } KILL(job->pid, SIGCONT); #ifdef RMT_WANTS_SIGNALS if (job->flags & JOB_REMOTE) { /* * If job is remote, let the Rmt module do the killing. */ if (!Rmt_Signal(job, SIGINT)) { /* * If couldn't kill the thing, finish it out now with an * error code, since no exit report will come in likely. */ int status; status.w_status = 0; status.w_retcode = 1; JobFinish(job, &status); } } else if (job->pid) { if (DEBUG(JOB)) { (void) fprintf(stdout, "JobInterrupt passing interrupt to stopped child %d.\n", job->pid); (void) fflush(stdout); } KILL(job->pid, SIGINT); } #endif /* RMT_WANTS_SIGNALS */ } #endif Lst_Close(stoppedJobs); if (runINTERRUPT && !touchFlag) { interrupt = Targ_FindNode(".INTERRUPT", TARG_NOCREATE); if (interrupt != NILGNODE) { ignoreErrors = FALSE; JobStart(interrupt, JOB_IGNDOTS, (Job *)0); while (nJobs) { Job_CatchOutput(); #ifndef RMT_WILL_WATCH Job_CatchChildren(!usePipes); #endif /* RMT_WILL_WATCH */ } } } (void) eunlink(tfile); exit(signo); } /* *----------------------------------------------------------------------- * Job_Finish -- * Do final processing such as the running of the commands * attached to the .END target. * * Results: * Number of errors reported. * * Side Effects: * The process' temporary file (tfile) is removed if it still * existed. *----------------------------------------------------------------------- */ int Job_Finish() { if (postCommands != NILGNODE && !Lst_IsEmpty(postCommands->commands)) { if (errors) { Error("Errors reported so .END ignored"); } else { JobStart(postCommands, JOB_SPECIAL | JOB_IGNDOTS, NULL); while (nJobs) { Job_CatchOutput(); #ifndef RMT_WILL_WATCH Job_CatchChildren(!usePipes); #endif /* RMT_WILL_WATCH */ } } } (void) eunlink(tfile); return(errors); } /*- *----------------------------------------------------------------------- * Job_End -- * Cleanup any memory used by the jobs module * * Results: * None. * * Side Effects: * Memory is freed *----------------------------------------------------------------------- */ void Job_End() { if (shellArgv) free(shellArgv); } /*- *----------------------------------------------------------------------- * Job_Wait -- * Waits for all running jobs to finish and returns. Sets 'aborting' * to ABORT_WAIT to prevent other jobs from starting. * * Results: * None. * * Side Effects: * Currently running jobs finish. * *----------------------------------------------------------------------- */ void Job_Wait() { aborting = ABORT_WAIT; while (nJobs != 0) { Job_CatchOutput(); #ifndef RMT_WILL_WATCH Job_CatchChildren(!usePipes); #endif /* RMT_WILL_WATCH */ } aborting = 0; } /*- *----------------------------------------------------------------------- * Job_AbortAll -- * Abort all currently running jobs without handling output or anything. * This function is to be called only in the event of a major * error. Most definitely NOT to be called from JobInterrupt. * * Results: * None * * Side Effects: * All children are killed, not just the firstborn *----------------------------------------------------------------------- */ void Job_AbortAll() { LstNode ln; /* element in job table */ Job *job; /* the job descriptor in that element */ int foo; aborting = ABORT_ERROR; if (nJobs) { (void) Lst_Open(jobs); while ((ln = Lst_Next(jobs)) != NILLNODE) { job = (Job *) Lst_Datum(ln); /* * kill the child process with increasingly drastic signals to make * darn sure it's dead. */ #ifdef RMT_WANTS_SIGNALS if (job->flags & JOB_REMOTE) { Rmt_Signal(job, SIGINT); Rmt_Signal(job, SIGKILL); } else { KILL(job->pid, SIGINT); KILL(job->pid, SIGKILL); } #else KILL(job->pid, SIGINT); KILL(job->pid, SIGKILL); #endif /* RMT_WANTS_SIGNALS */ } } /* * Catch as many children as want to report in at first, then give up */ while (waitpid((pid_t) -1, &foo, WNOHANG) > 0) continue; (void) eunlink(tfile); } #ifdef REMOTE /*- *----------------------------------------------------------------------- * JobFlagForMigration -- * Handle the eviction of a child. Called from RmtStatusChange. * Flags the child as remigratable and then suspends it. * * Results: * none. * * Side Effects: * The job descriptor is flagged for remigration. * *----------------------------------------------------------------------- */ void JobFlagForMigration(hostID) int hostID; /* ID of host we used, for matching children. */ { register Job *job; /* job descriptor for dead child */ LstNode jnode; /* list element for finding job */ if (DEBUG(JOB)) { (void) fprintf(stdout, "JobFlagForMigration(%d) called.\n", hostID); (void) fflush(stdout); } jnode = Lst_Find(jobs, (ClientData)hostID, JobCmpRmtID); if (jnode == NILLNODE) { jnode = Lst_Find(stoppedJobs, (ClientData)hostID, JobCmpRmtID); if (jnode == NILLNODE) { if (DEBUG(JOB)) { Error("Evicting host(%d) not in table", hostID); } return; } } job = (Job *) Lst_Datum(jnode); if (DEBUG(JOB)) { (void) fprintf(stdout, "JobFlagForMigration(%d) found job '%s'.\n", hostID, job->node->name); (void) fflush(stdout); } KILL(job->pid, SIGSTOP); job->flags |= JOB_REMIGRATE; } #endif /*- *----------------------------------------------------------------------- * JobRestartJobs -- * Tries to restart stopped jobs if there are slots available. * Note that this tries to restart them regardless of pending errors. * It's not good to leave stopped jobs lying around! * * Results: * None. * * Side Effects: * Resumes(and possibly migrates) jobs. * *----------------------------------------------------------------------- */ static void JobRestartJobs() { while (!jobFull && !Lst_IsEmpty(stoppedJobs)) { if (DEBUG(JOB)) { (void) fprintf(stdout, "Job queue is not full. Restarting a stopped job.\n"); (void) fflush(stdout); } JobRestart((Job *)Lst_DeQueue(stoppedJobs)); } }