sys/kern/subr_autoconf.c

1.1    glass /*
1.1    glass  * Copyright (c) 1992 Regents of the University of California.
1.1    glass  * All rights reserved.
1.1    glass  *
1.1    glass  * This software was developed by the Computer Systems Engineering group
1.1    glass  * at Lawrence Berkeley Laboratory under DARPA contract BG 91-66 and
1.1    glass  * contributed to Berkeley.
1.1    glass  *
1.1    glass  * All advertising materials mentioning features or use of this software
1.1    glass  * must display the following acknowledgement:
1.1    glass  *	This product includes software developed by the University of
1.1    glass  *	California, Lawrence Berkeley Laboratories.
1.1    glass  *
1.1    glass  * %sccs.include.redist.c%
1.1    glass  *
1.1    glass  *	%W% (Berkeley) %G%
1.1    glass  *
1.4  mycroft  * from: $Header: /tank/opengrok/rsync2/NetBSD/src/sys/kern/subr_autoconf.c,v 1.4 1993/12/18 04:21:24 mycroft Exp $ (LBL)
1.1    glass  */
1.1    glass
1.4  mycroft #include <sys/param.h>
1.4  mycroft #include <sys/device.h>
1.4  mycroft #include <sys/malloc.h>
1.1    glass
1.1    glass /*
1.1    glass  * Autoconfiguration subroutines.
1.1    glass  */
1.1    glass
1.1    glass /*
1.1    glass  * ioconf.c exports exactly two names: cfdata and cfroots.  All system
1.1    glass  * devices and drivers are found via these tables.
1.1    glass  */
1.1    glass extern struct cfdata cfdata[];
1.1    glass extern short cfroots[];
1.1    glass
1.1    glass #define	ROOT ((struct device *)NULL)
1.1    glass
1.1    glass struct matchinfo {
1.1    glass 	cfmatch_t fn;
1.1    glass 	struct	device *parent;
1.1    glass 	void	*aux;
1.1    glass 	struct	cfdata *match;
1.1    glass 	int	pri;
1.1    glass };
1.1    glass
1.1    glass /*
1.1    glass  * Apply the matching function and choose the best.  This is used
1.1    glass  * a few times and we want to keep the code small.
1.1    glass  */
1.1    glass static void
1.1    glass mapply(m, cf)
1.1    glass 	register struct matchinfo *m;
1.1    glass 	register struct cfdata *cf;
1.1    glass {
1.1    glass 	register int pri;
1.1    glass
1.1    glass 	if (m->fn != NULL)
1.1    glass 		pri = (*m->fn)(m->parent, cf, m->aux);
1.3    glass 	else {
1.3    glass 	        if (!cf->cf_driver->cd_match) {
1.3    glass 		    printf("mapply: no match function for '%s' device\n",
1.3    glass 			   cf->cf_driver->cd_name);
1.3    glass 		    panic("mapply: not match function\n");
1.3    glass 		}
1.1    glass 		pri = (*cf->cf_driver->cd_match)(m->parent, cf, m->aux);
1.3    glass 	}
1.1    glass 	if (pri > m->pri) {
1.1    glass 		m->match = cf;
1.1    glass 		m->pri = pri;
1.1    glass 	}
1.1    glass }
1.1    glass
1.1    glass /*
1.1    glass  * Iterate over all potential children of some device, calling the given
1.1    glass  * function (default being the child's match function) for each one.
1.1    glass  * Nonzero returns are matches; the highest value returned is considered
1.1    glass  * the best match.  Return the `found child' if we got a match, or NULL
1.1    glass  * otherwise.  The `aux' pointer is simply passed on through.
1.1    glass  *
1.1    glass  * Note that this function is designed so that it can be used to apply
1.1    glass  * an arbitrary function to all potential children (its return value
1.1    glass  * can be ignored).
1.1    glass  */
1.1    glass struct cfdata *
1.1    glass config_search(fn, parent, aux)
1.1    glass 	cfmatch_t fn;
1.1    glass 	register struct device *parent;
1.1    glass 	void *aux;
1.1    glass {
1.1    glass 	register struct cfdata *cf;
1.1    glass 	register short *p;
1.1    glass 	struct matchinfo m;
1.1    glass
1.1    glass 	m.fn = fn;
1.1    glass 	m.parent = parent;
1.1    glass 	m.aux = aux;
1.1    glass 	m.match = NULL;
1.1    glass 	m.pri = 0;
1.1    glass 	for (cf = cfdata; cf->cf_driver; cf++) {
1.1    glass 		/*
1.1    glass 		 * Skip cf if no longer eligible, otherwise scan through
1.1    glass 		 * parents for one matching `parent', and try match function.
1.1    glass 		 */
1.1    glass 		if (cf->cf_fstate == FSTATE_FOUND)
1.1    glass 			continue;
1.1    glass 		for (p = cf->cf_parents; *p >= 0; p++)
1.1    glass 			if (parent->dv_cfdata == &cfdata[*p])
1.1    glass 				mapply(&m, cf);
1.1    glass 	}
1.1    glass 	return (m.match);
1.1    glass }
1.1    glass
1.1    glass /*
1.1    glass  * Find the given root device.
1.1    glass  * This is much like config_search, but there is no parent.
1.1    glass  */
1.1    glass struct cfdata *
1.1    glass config_rootsearch(fn, rootname, aux)
1.1    glass 	register cfmatch_t fn;
1.1    glass 	register char *rootname;
1.1    glass 	register void *aux;
1.1    glass {
1.1    glass 	register struct cfdata *cf;
1.1    glass 	register short *p;
1.1    glass 	struct matchinfo m;
1.1    glass
1.1    glass 	m.fn = fn;
1.1    glass 	m.parent = ROOT;
1.1    glass 	m.aux = aux;
1.1    glass 	m.match = NULL;
1.1    glass 	m.pri = 0;
1.1    glass 	/*
1.1    glass 	 * Look at root entries for matching name.  We do not bother
1.1    glass 	 * with found-state here since only one root should ever be
1.1    glass 	 * searched (and it must be done first).
1.1    glass 	 */
1.1    glass 	for (p = cfroots; *p >= 0; p++) {
1.1    glass 		cf = &cfdata[*p];
1.1    glass 		if (strcmp(cf->cf_driver->cd_name, rootname) == 0)
1.1    glass 			mapply(&m, cf);
1.1    glass 	}
1.1    glass 	return (m.match);
1.1    glass }
1.1    glass
1.1    glass static char *msgs[3] = { "", " not configured\n", " unsupported\n" };
1.1    glass
1.1    glass /*
1.1    glass  * The given `aux' argument describes a device that has been found
1.1    glass  * on the given parent, but not necessarily configured.  Locate the
1.1    glass  * configuration data for that device (using the cd_match configuration
1.1    glass  * driver function) and attach it, and return true.  If the device was
1.1    glass  * not configured, call the given `print' function and return 0.
1.1    glass  */
1.1    glass int
1.1    glass config_found(parent, aux, print)
1.1    glass 	struct device *parent;
1.1    glass 	void *aux;
1.1    glass 	cfprint_t print;
1.1    glass {
1.1    glass 	struct cfdata *cf;
1.1    glass
1.1    glass 	if ((cf = config_search((cfmatch_t)NULL, parent, aux)) != NULL) {
1.1    glass 		config_attach(parent, cf, aux, print);
1.1    glass 		return (1);
1.1    glass 	}
1.3    glass 	if (print)
1.3    glass 	    printf(msgs[(*print)(aux, parent->dv_xname)]);
1.1    glass 	return (0);
1.1    glass }
1.1    glass
1.1    glass /*
1.1    glass  * As above, but for root devices.
1.1    glass  */
1.1    glass int
1.1    glass config_rootfound(rootname, aux)
1.1    glass 	char *rootname;
1.1    glass 	void *aux;
1.1    glass {
1.1    glass 	struct cfdata *cf;
1.1    glass
1.1    glass 	if ((cf = config_rootsearch((cfmatch_t)NULL, rootname, aux)) != NULL) {
1.1    glass 		config_attach(ROOT, cf, aux, (cfprint_t)NULL);
1.1    glass 		return (1);
1.1    glass 	}
1.1    glass 	printf("root device %s not configured\n", rootname);
1.1    glass 	return (0);
1.1    glass }
1.1    glass
1.1    glass /* just like sprintf(buf, "%d") except that it works from the end */
1.1    glass static char *
1.1    glass number(ep, n)
1.1    glass 	register char *ep;
1.1    glass 	register int n;
1.1    glass {
1.1    glass
1.1    glass 	*--ep = 0;
1.1    glass 	while (n >= 10) {
1.1    glass 		*--ep = (n % 10) + '0';
1.1    glass 		n /= 10;
1.1    glass 	}
1.1    glass 	*--ep = n + '0';
1.1    glass 	return (ep);
1.1    glass }
1.1    glass
1.1    glass /*
1.1    glass  * Attach a found device.  Allocates memory for device variables.
1.1    glass  */
1.1    glass void
1.1    glass config_attach(parent, cf, aux, print)
1.1    glass 	register struct device *parent;
1.1    glass 	register struct cfdata *cf;
1.1    glass 	register void *aux;
1.1    glass 	cfprint_t print;
1.1    glass {
1.1    glass 	register struct device *dev;
1.1    glass 	register struct cfdriver *cd;
1.1    glass 	register size_t lname, lunit;
1.1    glass 	register char *xunit;
1.1    glass 	int myunit;
1.1    glass 	char num[10];
1.1    glass 	static struct device **nextp = &alldevs;
1.1    glass
1.1    glass 	cd = cf->cf_driver;
1.1    glass 	if (cd->cd_devsize < sizeof(struct device))
1.1    glass 		panic("config_attach");
1.1    glass 	myunit = cf->cf_unit;
1.1    glass 	if (cf->cf_fstate == FSTATE_NOTFOUND)
1.1    glass 		cf->cf_fstate = FSTATE_FOUND;
1.1    glass 	else
1.1    glass 		cf->cf_unit++;
1.1    glass
1.1    glass 	/* compute length of name and decimal expansion of unit number */
1.1    glass 	lname = strlen(cd->cd_name);
1.1    glass 	xunit = number(&num[sizeof num], myunit);
1.1    glass 	lunit = &num[sizeof num] - xunit;
1.1    glass 	if (lname + lunit >= sizeof(dev->dv_xname))
1.1    glass 		panic("config_attach: device name too long");
1.1    glass
1.1    glass 	/* get memory for all device vars */
1.3    glass 	dev = (struct device *)malloc(cd->cd_devsize, M_DEVBUF, M_NOWAIT);
1.3    glass 	if (!dev)
1.3    glass 	    panic("config_attach: memory allocation for device softc failed");
1.1    glass 	bzero(dev, cd->cd_devsize);
1.1    glass 	*nextp = dev;			/* link up */
1.1    glass 	nextp = &dev->dv_next;
1.1    glass 	dev->dv_class = cd->cd_class;
1.1    glass 	dev->dv_cfdata = cf;
1.1    glass 	dev->dv_unit = myunit;
1.1    glass 	bcopy(cd->cd_name, dev->dv_xname, lname);
1.1    glass 	bcopy(xunit, dev->dv_xname + lname, lunit);
1.1    glass 	dev->dv_parent = parent;
1.1    glass 	if (parent == ROOT)
1.1    glass 		printf("%s (root)", dev->dv_xname);
1.1    glass 	else {
1.1    glass 		printf("%s at %s", dev->dv_xname, parent->dv_xname);
1.3    glass 		if (print)
1.3    glass 		    (void) (*print)(aux, (char *)0);
1.1    glass 	}
1.1    glass
1.1    glass 	/* put this device in the devices array */
1.1    glass 	if (dev->dv_unit >= cd->cd_ndevs) {
1.1    glass 		/*
1.1    glass 		 * Need to expand the array.
1.1    glass 		 */
1.1    glass 		int old = cd->cd_ndevs, oldbytes, new, newbytes;
1.1    glass 		void **nsp;
1.1    glass
1.1    glass 		if (old == 0) {
1.3    glass 			nsp = malloc(MINALLOCSIZE, M_DEVBUF, M_NOWAIT);
1.3    glass 			if (!nsp)
1.3    glass 			    panic("config_attach: expanding dev array");
1.1    glass 			bzero(nsp, MINALLOCSIZE);
1.1    glass 			cd->cd_ndevs = MINALLOCSIZE / sizeof(void *);
1.1    glass 		} else {
1.1    glass 			new = cd->cd_ndevs;
1.1    glass 			do {
1.1    glass 				new *= 2;
1.1    glass 			} while (new <= dev->dv_unit);
1.1    glass 			cd->cd_ndevs = new;
1.1    glass 			oldbytes = old * sizeof(void *);
1.1    glass 			newbytes = new * sizeof(void *);
1.3    glass 			nsp = malloc(newbytes, M_DEVBUF, M_NOWAIT);
1.3    glass 			if (!nsp)
1.3    glass 			    panic("config_attach: expanding dev array (2)");
1.1    glass 			bcopy(cd->cd_devs, nsp, oldbytes);
1.1    glass 			bzero(&nsp[old], newbytes - oldbytes);
1.1    glass 			free(cd->cd_devs, M_DEVBUF);
1.1    glass 		}
1.1    glass 		cd->cd_devs = nsp;
1.1    glass 	}
1.1    glass 	if (cd->cd_devs[dev->dv_unit])
1.1    glass 		panic("config_attach: duplicate %s", dev->dv_xname);
1.1    glass 	cd->cd_devs[dev->dv_unit] = dev;
1.1    glass
1.1    glass 	/*
1.1    glass 	 * Before attaching, clobber any unfound devices that are
1.1    glass 	 * otherwise identical.
1.1    glass 	 */
1.1    glass 	for (cf = cfdata; cf->cf_driver; cf++)
1.1    glass 		if (cf->cf_driver == cd && cf->cf_unit == dev->dv_unit &&
1.1    glass 		    cf->cf_fstate == FSTATE_NOTFOUND)
1.1    glass 			cf->cf_fstate = FSTATE_FOUND;
1.1    glass 	(*cd->cd_attach)(parent, dev, aux);
1.1    glass }
1.1    glass
1.1    glass /*
1.1    glass  * Attach an event.  These must come from initially-zero space (see
1.1    glass  * commented-out assignments below), but that occurs naturally for
1.1    glass  * device instance variables.
1.1    glass  */
1.1    glass void
1.1    glass evcnt_attach(dev, name, ev)
1.1    glass 	struct device *dev;
1.1    glass 	const char *name;
1.1    glass 	struct evcnt *ev;
1.1    glass {
1.1    glass 	static struct evcnt **nextp = &allevents;
1.1    glass
1.1    glass #ifdef DIAGNOSTIC
1.1    glass 	if (strlen(name) >= sizeof(ev->ev_name))
1.1    glass 		panic("evcnt_attach");
1.1    glass #endif
1.1    glass 	/* ev->ev_next = NULL; */
1.1    glass 	ev->ev_dev = dev;
1.1    glass 	/* ev->ev_count = 0; */
1.1    glass 	strcpy(ev->ev_name, name);
1.1    glass 	*nextp = ev;
1.1    glass 	nextp = &ev->ev_next;
1.1    glass }