mom_mach.c

来自「OpenPBS」· C语言 代码 · 共 2,003 行 · 第 1/3 页

 *	    1.	MOM has already forked, and we are called from the child.
 *	    2.	The child is still running as root.
 *	    3.  Standard error is open to the user's file.
 *
 *	If set_mode is SET_LIMIT_ALTER, we are beening called to modify
 *	existing limits.  Cannot alter those set by setrlimit (kernel)
 *	because we are the wrong process.  
 */
int mom_set_limits(pjob, set_mode)
    job			*pjob;
    int			 set_mode;	/* SET_LIMIT_SET or SET_LIMIT_ALTER */
{
	char		*id = "mom_set_limits";
	char		*pname;
	int		retval;
	unsigned long	value;	/* place in which to build resource value */
	resource	*pres;
       	struct rlimit	reslim;
	unsigned long	mem_limit  = 0;

	DBPRT(("%s: entered\n", id))
	assert(pjob != NULL);
	assert(pjob->ji_wattr[(int)JOB_ATR_resource].at_type == ATR_TYPE_RESC);
	pres = (resource *)
	    GET_NEXT(pjob->ji_wattr[(int)JOB_ATR_resource].at_val.at_list);

/*
 * Cycle through all the resource specifications,
 * setting limits appropriately.
 */

	while (pres != NULL) {
		assert(pres->rs_defin != NULL);
		pname = pres->rs_defin->rs_name;
		assert(pname != NULL);
		assert(*pname != '\0');

		if (strcmp(pname, "cput") == 0) {
			/* cpu time - check, if less than pcput use it */
			retval = gettime(pres, &value);
			if (retval != PBSE_NONE)
			        return (error(pname, retval));
		} else if (strcmp(pname, "pcput") == 0) {
			/* process cpu time - set */
			retval = gettime(pres, &value);
			if (retval != PBSE_NONE)
			        return (error(pname, retval));
			reslim.rlim_cur = reslim.rlim_max = 
				(unsigned long)((double)value / cputfactor);
			if (setrlimit(RLIMIT_CPU, &reslim) < 0)
	        		return (error("RLIMIT_CPU", PBSE_SYSTEM));
		} else if (strcmp(pname, "file") == 0) {	/* set */
			if (set_mode == SET_LIMIT_SET)  {
			    retval = getsize(pres, &value);
			    if (retval != PBSE_NONE)
			        return (error(pname, retval));
			    if (value > INT_MAX)
			        return (error(pname, PBSE_BADATVAL));
			    reslim.rlim_cur = reslim.rlim_max = value;
			    if (setrlimit(RLIMIT_FSIZE, &reslim) < 0)
			        return (error(pname, PBSE_SYSTEM));
			}
		} else if (strcmp(pname, "vmem") == 0) {	/* check */
			retval = getsize(pres, &value);
			if (retval != PBSE_NONE)
			        return (error(pname, retval));
			if ((mem_limit == 0) || (value < mem_limit))
				mem_limit = value;
		} else if (strcmp(pname, "pvmem") == 0) {	/* set */
			if (set_mode == SET_LIMIT_SET)  {
			    retval = getsize(pres, &value);
			    if (retval != PBSE_NONE)
			        return (error(pname, retval));
			    if (value > INT_MAX)
			        return (error(pname, PBSE_BADATVAL));
			if ((mem_limit == 0) || (value < mem_limit))
				mem_limit = value;
			}
		} else if (strcmp(pname, "mem") == 0) {		/* ignore */
		} else if (strcmp(pname, "pmem") == 0) {	/* set */
			if (set_mode == SET_LIMIT_SET)  {
			    retval = getsize(pres, &value);
			    if (retval != PBSE_NONE)
			        return (error(pname, retval));
			    reslim.rlim_cur = reslim.rlim_max = value;
			    if (setrlimit(RLIMIT_RSS, &reslim) < 0)
	        		return (error("RLIMIT_RSS", PBSE_SYSTEM));
			}
		} else if (strcmp(pname, "walltime") == 0) {	/* Check */
			retval = gettime(pres, &value);
			if (retval != PBSE_NONE)
			        return (error(pname, retval));
		} else if (strcmp(pname, "nice") == 0) {	/* set nice */
			if (set_mode == SET_LIMIT_SET)  {
			    errno = 0;
			    if ((nice((int)pres->rs_value.at_val.at_long) == -1)
				&& (errno != 0))
				return (error(pname, PBSE_BADATVAL));
			}
		} else if ((pres->rs_defin->rs_flags & ATR_DFLAG_RMOMIG) == 0)
			/* don't recognize and not marked as ignore by mom */
			return (error(pname, PBSE_UNKRESC));
		pres = (resource *)GET_NEXT(pres->rs_link);
	}
	if (set_mode == SET_LIMIT_SET)  {
	    /* if either of vmem or pvmem was given, set sys limit to lesser */
	    if (mem_limit != 0) {
		reslim.rlim_cur = reslim.rlim_max = mem_limit;
		if (setrlimit(RLIMIT_DATA, &reslim) < 0)
	        	return (error("RLIMIT_DATA", PBSE_SYSTEM));
		if (setrlimit(RLIMIT_STACK, &reslim) < 0)
	        	return (error("RLIMIT_STACK", PBSE_SYSTEM));
	    }
	}
	return (PBSE_NONE);
}
/*
 * State whether MOM main loop has to poll this job to determine if some
 * limits are being exceeded.
 *
 *	Sets flag TRUE if polling is necessary, FALSE otherwise.  Actual
 *	polling is done using the mom_over_limit machine-dependent function.
 */

int mom_do_poll(pjob)
    job			*pjob;
{
	char		*id = "mom_do_poll";
	char		*pname;
	resource	*pres;

	DBPRT(("%s: entered\n", id))
	assert(pjob != NULL);
	assert(pjob->ji_wattr[(int)JOB_ATR_resource].at_type == ATR_TYPE_RESC);
	pres = (resource *)
	    GET_NEXT(pjob->ji_wattr[(int)JOB_ATR_resource].at_val.at_list);

	while (pres != NULL) {
		assert(pres->rs_defin != NULL);
		pname = pres->rs_defin->rs_name;
		assert(pname != NULL);
		assert(*pname != '\0');

		if (strcmp(pname, "walltime") == 0 ||
		    strcmp(pname, "cput") == 0 ||
		    strcmp(pname, "pcput") == 0 ||
		    strcmp(pname, "pvmem") == 0 ||
		    strcmp(pname, "vmem") == 0)
			return (TRUE);
		pres = (resource *)GET_NEXT(pres->rs_link);
	}

	return (FALSE);
}

/*
 * Setup for polling.
 *
 *	Open kernel device and get namelist info.
 */
int mom_open_poll()
{
	char		*id = "mom_open_poll";

	DBPRT(("%s: entered\n", id))
	pagesize = getpagesize();

	return (PBSE_NONE);
}

/*
 * Declare start of polling loop.
 *
 */

int mom_get_sample()
{
	return (PBSE_NONE);
}

/*
 * Measure job resource usage and compare with its limits.
 *
 *	If it has exceeded any well-formed polled limit return TRUE.
 *	Otherwise, return FALSE.
 */

int mom_over_limit(pjob)
    job			*pjob;
{
	char		*id = "mom_over_limit";
	char		*pname;
	int		retval;
	unsigned long	value, num;
	resource	*pres;

	assert(pjob != NULL);
	assert(pjob->ji_wattr[(int)JOB_ATR_resource].at_type == ATR_TYPE_RESC);
	pres = (resource *)
	    GET_NEXT(pjob->ji_wattr[(int)JOB_ATR_resource].at_val.at_list);

	for ( ; pres != NULL; pres = (resource *)GET_NEXT(pres->rs_link)) {
		assert(pres->rs_defin != NULL);
		pname = pres->rs_defin->rs_name;
		assert(pname != NULL);
		assert(*pname != '\0');
		if (strcmp(pname, "cput") == 0) {
			retval = gettime(pres, &value);
			if (retval != PBSE_NONE)
				continue;
			if ((num = cput_sum(pjob)) > value) {
				sprintf(log_buffer,
					"cput %lu exceeded limit %lu",
					num, value);
				return (TRUE);
			}
		} else if (strcmp(pname, "pcput") == 0) {
			retval = gettime(pres, &value);
			if (retval != PBSE_NONE)
				continue;
			if (overcpu_proc(pjob, value)) {
				sprintf(log_buffer,
					"pcput exceeded limit %lu",
					value);
				return (TRUE);
			}
		} else if (strcmp(pname, "vmem") == 0) {
			retval = getsize(pres, &value);
			if (retval != PBSE_NONE)
				continue;
			if ((num = mem_sum(pjob)) > value) {
				sprintf(log_buffer,
					"vmem %lu exceeded limit %lu",
					num, value);
				return (TRUE);
			}
		} else if (strcmp(pname, "pvmem") == 0) {
			retval = getsize(pres, &value);
			if (retval != PBSE_NONE)
				continue;
			if (overmem_proc(pjob, value)) {
				sprintf(log_buffer,
					"pvmem exceeded limit %lu",
					value);
				return (TRUE);
			}
		} else if (strcmp(pname, "walltime") == 0) {
			retval = gettime(pres, &value);
			if (retval != PBSE_NONE)
				continue;
			num = (unsigned long)((double)(time_now - pjob->ji_qs.ji_stime) * wallfactor);
			if (num > value) {
				sprintf(log_buffer,
					"walltime %d exceeded limit %d",
					num, value);
				return (TRUE);
			}
		}
	}

	return (FALSE);
}

/*
 * Update the job attribute for resources used.
 *
 *	The first time this is called for a job, set up resource entries for
 *	each resource that can be reported for this machine.  Fill in the
 *	correct values.  Return an error code.
 */
int mom_set_use(pjob)
    job			*pjob;
{
	char			*id = "mom_set_use";
	resource		*pres;
	attribute		*at;
	resource_def		*rd;
	unsigned long		*lp, lnum;

	assert(pjob != NULL);
	at = &pjob->ji_wattr[(int)JOB_ATR_resc_used];
	assert(at->at_type == ATR_TYPE_RESC);

	at->at_flags |= ATR_VFLAG_MODIFY;
	if ((at->at_flags & ATR_VFLAG_SET) == 0) {
		at->at_flags |= ATR_VFLAG_SET;

		rd = find_resc_def(svr_resc_def, "cput", svr_resc_size);
		assert(rd != NULL);
		pres = add_resource_entry(at, rd);
		pres->rs_value.at_flags |= ATR_VFLAG_SET;
		pres->rs_value.at_type = ATR_TYPE_LONG;

		rd = find_resc_def(svr_resc_def, "vmem", svr_resc_size);
		assert(rd != NULL);
		pres = add_resource_entry(at, rd);
		pres->rs_value.at_flags |= ATR_VFLAG_SET;
		pres->rs_value.at_type = ATR_TYPE_SIZE;
		pres->rs_value.at_val.at_size.atsv_shift = 10;	/* KB */
		pres->rs_value.at_val.at_size.atsv_units = ATR_SV_BYTESZ;

		rd = find_resc_def(svr_resc_def, "walltime", svr_resc_size);
		assert(rd != NULL);
		pres = add_resource_entry(at, rd);
		pres->rs_value.at_flags |= ATR_VFLAG_SET;
		pres->rs_value.at_type = ATR_TYPE_LONG;

		rd = find_resc_def(svr_resc_def, "mem", svr_resc_size);
		assert(rd != NULL);
		pres = add_resource_entry(at, rd);
		pres->rs_value.at_flags |= ATR_VFLAG_SET;
		pres->rs_value.at_type = ATR_TYPE_SIZE;
		pres->rs_value.at_val.at_size.atsv_shift = 10;	/* KB */
		pres->rs_value.at_val.at_size.atsv_units = ATR_SV_BYTESZ;
	}

	rd = find_resc_def(svr_resc_def, "cput", svr_resc_size);
	assert(rd != NULL);
	pres = find_resc_entry(at, rd);
	assert(pres != NULL);
	lp = (unsigned long *)&pres->rs_value.at_val.at_long;
	lnum = cput_sum(pjob);
	*lp = MAX(*lp, lnum);

	rd = find_resc_def(svr_resc_def, "vmem", svr_resc_size);
	assert(rd != NULL);
	pres = find_resc_entry(at, rd);
	assert(pres != NULL);
	lp = &pres->rs_value.at_val.at_size.atsv_num;
	lnum = (mem_sum(pjob) + 1023) >> 10;	/* as KB */
	*lp = MAX(*lp, lnum);

	rd = find_resc_def(svr_resc_def, "walltime", svr_resc_size);
	assert(rd != NULL);
	pres = find_resc_entry(at, rd);
	assert(pres != NULL);
	pres->rs_value.at_val.at_long = (long)((double)(time_now - pjob->ji_qs.ji_stime) * wallfactor);

	rd = find_resc_def(svr_resc_def, "mem", svr_resc_size);
	assert(rd != NULL);
	pres = find_resc_entry(at, rd);
	assert(pres != NULL);
	lp = &pres->rs_value.at_val.at_size.atsv_num;
	lnum = (resi_sum(pjob) + 1023) >> 10;	/* as KB */
	*lp = MAX(*lp, lnum);

	return (PBSE_NONE);
}

/*
 *	Kill a task session.
 *	Call with the task pointer and a signal number.
 */
int kill_task(ptask, sig)
    task	*ptask;
    int		sig;
{
	char		*id = "kill_task";
	int		ct = 0;
	struct dirent	*dent;
	proc_stat_t	*ps;
	int		sesid;


	sesid = ptask->ti_qs.ti_sid;
	if (sesid <= 1)
		return 0;

	rewinddir(pdir);
	while ((dent = readdir(pdir)) != NULL) {
		if (!isdigit(dent->d_name[0]))
			continue;

		if ((ps = get_proc_stat(atoi(dent->d_name))) == NULL) {
			if (errno != ENOENT) {
				sprintf(log_buffer,
					"%s: get_proc_stat", dent->d_name);
				log_err(errno, id, log_buffer);
			}
			continue;
		}

		if (sesid == ps->session) {
			(void)kill(ps->pid, sig);
			++ct;
		}
	}
	return ct;
}

/*
 * Clean up everything related to polling.
 */
int mom_close_poll()
{
	char	*id = "mom_close_poll";

	DBPRT(("%s: entered\n", id))
	if (pdir) {
		if (closedir(pdir) != 0) {
			log_err(errno, id, "closedir");
			return (PBSE_SYSTEM);
		}
		pdir = NULL;
	}

	return (PBSE_NONE);
}

/*
 * mom_does_chkpnt - return 1 if mom supports checkpoint
 *			    0 if not
 */

int mom_does_chkpnt()
{
	return (0);
}

/*
 * Checkpoint the job.
 *
 *	If abort is true, kill it too.
 */

int mach_checkpoint(ptask, file, abort)
    task	*ptask;
    char	*file;
    int		abort;
{
       	return (-1);
}

/*
 * Restart the job from the checkpoint file.
 *
 *	Return -1 on error or sid if okay.
 */

long mach_restart(ptask, file)
    task	*ptask;
    char	*file;
{
	return (-1);
}

#define	dsecs(val) ( (double)(val) )

char	*
cput_job(jobid)
pid_t	jobid;
{
	char			*id = "cput_job";
	int			found = 0;
	struct dirent		*dent;
	double			cputime, addtime;
	proc_stat_t		*ps;

	cputime = 0.0;
	rewinddir(pdir);
	while ((dent = readdir(pdir)) != NULL) {
		if (!isdigit(dent->d_name[0]))
			continue;

		if ((ps = get_proc_stat(atoi(dent->d_name))) == NULL) {
			if (errno != ENOENT) {
				sprintf(log_buffer,
					"%s: get_proc_stat", dent->d_name);
				log_err(errno, id, log_buffer);
			}
			continue;
		}

		if (jobid != ps->session)
			continue;

		found = 1;
		addtime = dsecs(ps->cutime) + dsecs(ps->cstime);

		cputime += addtime;
		DBPRT(("%s: total %.2f pid %d %.2f\n", id, cputime,
				ps->pid, addtime))

	}
	if (found) {
		sprintf(ret_string, "%.2f", cputime * cputfactor);
		return ret_string;
	}

	rm_errno = RM_ERR_EXIST;
	return NULL;
}

char	*
cput_proc(pid)
pid_t	pid;
{
	char			*id = "cput_pid";
	double			cputime;
	proc_stat_t		*ps;

	cputime = 0.0;

	if ((ps = get_proc_stat(pid)) == NULL) {
		if (errno != ENOENT) {
			sprintf(log_buffer, "%d: get_proc_stat", pid);
			log_err(errno, id, log_buffer);
		}
		rm_errno = RM_ERR_SYSTEM;
		return NULL;
	}
	cputime = dsecs(ps->utime) + dsecs(ps->stime);

	sprintf(ret_string, "%.2f", cputime * cputfactor);
	return ret_string;
}


char	*
cput(attrib)
struct	rm_attribute	*attrib;
{
	char			*id = "cput";
	int			value;

	if (attrib == NULL) {
		log_err(-1, id, no_parm);
		rm_errno = RM_ERR_NOPARAM;
		return NULL;
	}
	if ((value = atoi(attrib->a_value)) == 0) {
		sprintf(log_buffer, "bad param: %s", attrib->a_value);
		log_err(-1, id, log_buffer);
		rm_errno = RM_ERR_BADPARAM;
		return NULL;
	}
	if (momgetattr(NULL)) {
		log_err(-1, id, extra_parm);
		rm_errno = RM_ERR_BADPARAM;
		return NULL;
	}

	if (strcmp(attrib->a_qualifier, "session") == 0)
		return (cput_job((pid_t)value));
	else if (strcmp(attrib->a_qualifier, "proc") == 0)
		return (cput_proc((pid_t)value));
	else {
		rm_errno = RM_ERR_BADPARAM;
		return NULL;
	}
}

char	*
mem_job(sid)
pid_t	sid;
{
	static	char	id[] = "mem_job";
	ulong			memsize;
	struct dirent		*dent;
	char			procname[100];
	int			num, i;
	proc_stat_t		*ps;

	memsize = 0;
	rewinddir(pdir);

	while ((dent = readdir(pdir)) != NULL) {
		if (!isdigit(dent->d_name[0]))
			continue;

		if ((ps = get_proc_stat(atoi(dent->d_name))) == NULL) {
			if (errno != ENOENT) {
				sprintf(log_buffer,
					"%s: get_proc_stat", dent->d_name);
				log_err(errno, id, log_buffer);
			}
			continue;
		}

		if (sid != ps->session)
			continue;
		memsize += ps->vsize;
	}

	if (memsize == 0) {
		rm_errno = RM_ERR_EXIST;
		return NULL;
	}
	else {
		sprintf(ret_string, "%lukb", memsize >> 10); /* KB */
		return ret_string;
	}
}

char	*
mem_proc(pid)
pid_t	pid;
{
	char			*id = "mem_proc";
	proc_stat_t		*ps;

	if ((ps = get_proc_stat(pid)) == NULL) {
		if (errno != ENOENT) {
			sprintf(log_buffer, "%d: get_proc_stat", pid);
			log_err(errno, id, log_buffer);
		}
		rm_errno = RM_ERR_SYSTEM;
		return NULL;
	}

	sprintf(ret_string, "%lukb", (ulong)ps->vsize >> 10); /* KB */
	return ret_string;
}

char	*
mem(attrib)
struct	rm_attribute	*attrib;
{
	char			*id = "mem";
	int			value;

	if (attrib == NULL) {
		log_err(-1, id, no_parm);
		rm_errno = RM_ERR_NOPARAM;
		return NULL;
	}
	if ((value = atoi(attrib->a_value)) == 0) {
		sprintf(log_buffer, "bad param: %s", attrib->a_value);
		log_err(-1, id, log_buffer);
		rm_errno = RM_ERR_BADPARAM;
		return NULL;
	}
	if (momgetattr(NULL)) {
		log_err(-1, id, extra_parm);
		rm_errno = RM_ERR_BADPARAM;
		return NULL;
	}

	if (strcmp(attrib->a_qualifier, "session") == 0)
		return (mem_job((pid_t)value));
	else if (strcmp(attrib->a_qualifier, "proc") == 0)
		return (mem_proc((pid_t)value));
	else {
		rm_errno = RM_ERR_BADPARAM;
		return NULL;
	}
}

static char	*
resi_job(jobid)
pid_t	jobid;
{
	char			*id = "resi_job";
	ulong			resisize;
	int			fd;
	int			found = 0;
	char			procname[100];
	struct dirent		*dent;
	proc_stat_t		*ps;

	resisize = 0;
	rewinddir(pdir);
	while ((dent = readdir(pdir)) != NULL) {
		if (!isdigit(dent->d_name[0]))
			continue;

		if ((ps = get_proc_stat(atoi(dent->d_name))) == NULL) {
			if (errno != ENOENT) {