mac68k/dev/adb.c

1.4.2.1  briggs /*	$NetBSD: adb.c,v 1.4.2.1 1995/11/02 04:35:05 briggs Exp $	*/
    1.1  briggs
    1.1  briggs /*-
    1.1  briggs  * Copyright (C) 1994	Bradley A. Grantham
    1.1  briggs  * All rights reserved.
    1.1  briggs  *
    1.1  briggs  * Redistribution and use in source and binary forms, with or without
    1.1  briggs  * modification, are permitted provided that the following conditions
    1.1  briggs  * are met:
    1.1  briggs  * 1. Redistributions of source code must retain the above copyright
    1.1  briggs  *    notice, this list of conditions and the following disclaimer.
    1.1  briggs  * 2. Redistributions in binary form must reproduce the above copyright
    1.2  briggs e*    notice, this list of conditions and the following disclaimer in the
    1.1  briggs  *    documentation and/or other materials provided with the distribution.
    1.1  briggs  * 3. All advertising materials mentioning features or use of this software
    1.1  briggs  *    must display the following acknowledgement:
    1.1  briggs  *	This product includes software developed by Bradley A. Grantham.
    1.1  briggs  * 4. The name of the author may not be used to endorse or promote products
    1.1  briggs  *    derived from this software without specific prior written permission.
    1.1  briggs  *
    1.1  briggs  * THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR
    1.1  briggs  * IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES
    1.1  briggs  * OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED.
    1.1  briggs  * IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT,
    1.1  briggs  * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT
    1.1  briggs  * NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
    1.1  briggs  * DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
    1.1  briggs  * THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
    1.1  briggs  * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
    1.1  briggs  * OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
    1.1  briggs  */
    1.1  briggs
    1.1  briggs #include <sys/param.h>
    1.1  briggs #include <sys/device.h>
    1.1  briggs #include <sys/fcntl.h>
    1.1  briggs #include <sys/select.h>
    1.1  briggs #include <sys/proc.h>
    1.1  briggs #include <sys/systm.h>
    1.2  briggs
    1.1  briggs #include <machine/adbsys.h>
    1.2  briggs #include <machine/keyboard.h>
    1.2  briggs
    1.1  briggs #include "adbvar.h"
    1.1  briggs #include "../mac68k/macrom.h"
    1.1  briggs
    1.1  briggs /*
    1.2  briggs  * Function declarations.
    1.1  briggs  */
    1.2  briggs static void	adbattach __P((struct device *parent, struct device *dev, void *aux));
    1.1  briggs
    1.2  briggs /*
    1.2  briggs  * Global variables.
    1.2  briggs  */
    1.2  briggs int     adb_polling = 0;	/* Are we polling?  (Debugger mode) */
    1.1  briggs
    1.1  briggs /*
    1.2  briggs  * Local variables.
    1.1  briggs  */
    1.2  briggs
    1.2  briggs /* External keyboard translation matrix */
    1.2  briggs extern unsigned char keyboard[128][3];
    1.2  briggs
    1.2  briggs /* Event queue definitions */
    1.1  briggs #if !defined(ADB_MAX_EVENTS)
    1.1  briggs #define ADB_MAX_EVENTS 200	/* Maximum events to be kept in queue */
    1.2  briggs 				/* maybe should be higher for slower macs? */
    1.2  briggs #endif				/* !defined(ADB_MAX_EVENTS) */
    1.1  briggs static adb_event_t adb_evq[ADB_MAX_EVENTS];	/* ADB event queue */
    1.2  briggs static int adb_evq_tail = 0;	/* event queue tail */
    1.2  briggs static int adb_evq_len = 0;	/* event queue length */
    1.1  briggs
    1.2  briggs /* ADB device state information */
    1.1  briggs static int adb_isopen = 0;	/* Are we queuing events for adb_read? */
    1.1  briggs static struct selinfo adb_selinfo;	/* select() info */
    1.1  briggs static struct proc *adb_ioproc = NULL;	/* process to wakeup */
    1.1  briggs
    1.2  briggs /* Key repeat parameters */
    1.2  briggs static int adb_rptdelay = 20;	/* ticks before auto-repeat */
    1.2  briggs static int adb_rptinterval = 6;	/* ticks between auto-repeat */
    1.2  briggs static int adb_repeating = -1;	/* key that is auto-repeating */
    1.2  briggs static adb_event_t adb_rptevent;/* event to auto-repeat */
    1.1  briggs
    1.2  briggs extern int matchbyname();
    1.1  briggs
    1.2  briggs /* Driver definition. */
    1.2  briggs struct cfdriver adbcd = {
    1.2  briggs 	NULL, "adb", matchbyname, adbattach, DV_DULL, sizeof(struct device),
    1.2  briggs };
    1.1  briggs
    1.1  briggs static void
    1.1  briggs adbattach(parent, dev, aux)
    1.2  briggs 	struct device *parent, *dev;
    1.2  briggs 	void   *aux;
    1.1  briggs {
    1.1  briggs 	printf(" (ADB event device)\n");
    1.1  briggs }
    1.1  briggs
    1.2  briggs void
    1.2  briggs adb_enqevent(event)
    1.2  briggs     adb_event_t *event;
    1.1  briggs {
    1.2  briggs 	int     s;
    1.1  briggs
    1.2  briggs 	if (adb_evq_tail < 0 || adb_evq_tail >= ADB_MAX_EVENTS)
    1.1  briggs 		panic("adb: event queue tail is out of bounds");
    1.1  briggs
    1.2  briggs 	if (adb_evq_len < 0 || adb_evq_len > ADB_MAX_EVENTS)
    1.1  briggs 		panic("adb: event queue len is out of bounds");
    1.1  briggs
    1.1  briggs 	s = splhigh();
    1.1  briggs
    1.2  briggs 	if (adb_evq_len == ADB_MAX_EVENTS) {
    1.1  briggs 		splx(s);
    1.2  briggs 		return;		/* Oh, well... */
    1.1  briggs 	}
    1.1  briggs 	adb_evq[(adb_evq_len + adb_evq_tail) % ADB_MAX_EVENTS] =
    1.2  briggs 	    *event;
    1.1  briggs 	adb_evq_len++;
    1.1  briggs
    1.1  briggs 	selwakeup(&adb_selinfo);
    1.2  briggs 	if (adb_ioproc)
    1.1  briggs 		psignal(adb_ioproc, SIGIO);
    1.1  briggs
    1.1  briggs 	splx(s);
    1.1  briggs }
    1.1  briggs
    1.2  briggs void
    1.2  briggs adb_handoff(event)
    1.2  briggs     adb_event_t *event;
    1.1  briggs {
    1.2  briggs 	if (adb_isopen && !adb_polling) {
    1.1  briggs 		adb_enqevent(event);
    1.2  briggs 	} else {
    1.2  briggs 		if (event->def_addr == 2)
    1.1  briggs 			ite_intr(event);
    1.1  briggs 	}
    1.1  briggs }
    1.1  briggs
    1.1  briggs
    1.2  briggs void
    1.2  briggs adb_autorepeat(keyp)
    1.2  briggs     void *keyp;
    1.1  briggs {
    1.2  briggs 	int     key = (int) keyp;
    1.1  briggs
    1.1  briggs 	adb_rptevent.bytes[0] |= 0x80;
    1.1  briggs 	microtime(&adb_rptevent.timestamp);
    1.1  briggs 	adb_handoff(&adb_rptevent);	/* do key up */
    1.1  briggs
    1.1  briggs 	adb_rptevent.bytes[0] &= 0x7f;
    1.1  briggs 	microtime(&adb_rptevent.timestamp);
    1.1  briggs 	adb_handoff(&adb_rptevent);	/* do key down */
    1.2  briggs
    1.2  briggs 	if (adb_repeating == key) {
    1.1  briggs 		timeout(adb_autorepeat, keyp, adb_rptinterval);
    1.1  briggs 	}
    1.1  briggs }
    1.1  briggs
    1.1  briggs
    1.2  briggs void
    1.2  briggs adb_dokeyupdown(event)
    1.2  briggs     adb_event_t *event;
    1.1  briggs {
    1.2  briggs 	int     adb_key;
    1.1  briggs
    1.2  briggs 	if (event->def_addr == 2) {
    1.1  briggs 		adb_key = event->u.k.key & 0x7f;
    1.2  briggs 		if (!(event->u.k.key & 0x80) &&
    1.2  briggs 		    keyboard[event->u.k.key & 0x7f][0] != 0) {
    1.1  briggs 			/* ignore shift & control */
    1.2  briggs 			if (adb_repeating != -1) {
    1.1  briggs 				untimeout(adb_autorepeat,
    1.2  briggs 				    (void *) adb_rptevent.u.k.key);
    1.1  briggs 			}
    1.1  briggs 			adb_rptevent = *event;
    1.1  briggs 			adb_repeating = adb_key;
    1.1  briggs 			timeout(adb_autorepeat,
    1.2  briggs 			    (void *) adb_key, adb_rptdelay);
    1.2  briggs 		} else {
    1.2  briggs 			if (adb_repeating != -1) {
    1.1  briggs 				adb_repeating = -1;
    1.1  briggs 				untimeout(adb_autorepeat,
    1.2  briggs 				    (void *) adb_rptevent.u.k.key);
    1.1  briggs 			}
    1.1  briggs 			adb_rptevent = *event;
    1.1  briggs 		}
    1.1  briggs 	}
    1.1  briggs 	adb_handoff(event);
    1.1  briggs }
    1.1  briggs
    1.2  briggs static  adb_ms_buttons = 0;
    1.1  briggs
    1.2  briggs void
    1.2  briggs adb_keymaybemouse(event)
    1.2  briggs     adb_event_t *event;
    1.1  briggs {
    1.2  briggs 	static int optionkey_down = 0;
    1.1  briggs 	adb_event_t new_event;
    1.2  briggs
    1.2  briggs 	if (event->u.k.key == ADBK_KEYDOWN(ADBK_OPTION)) {
    1.1  briggs 		optionkey_down = 1;
    1.2  briggs 	} else if (event->u.k.key == ADBK_KEYUP(ADBK_OPTION)) {
    1.2  briggs 		/* key up */
    1.1  briggs 		optionkey_down = 0;
    1.2  briggs 		if (adb_ms_buttons & 0xfe) {
    1.1  briggs 			adb_ms_buttons &= 1;
    1.1  briggs 			new_event.def_addr = ADBADDR_MS;
    1.1  briggs 			new_event.u.m.buttons = adb_ms_buttons;
    1.1  briggs 			new_event.u.m.dx = new_event.u.m.dy = 0;
    1.1  briggs 			microtime(&new_event.timestamp);
    1.1  briggs 			adb_dokeyupdown(&new_event);
    1.1  briggs 		}
    1.2  briggs 	} else if (optionkey_down) {
    1.2  briggs 		if (event->u.k.key == ADBK_KEYDOWN(ADBK_LEFT)) {
    1.1  briggs 			adb_ms_buttons |= 2;	/* middle down */
    1.1  briggs 			new_event.def_addr = ADBADDR_MS;
    1.1  briggs 			new_event.u.m.buttons = adb_ms_buttons;
    1.1  briggs 			new_event.u.m.dx = new_event.u.m.dy = 0;
    1.1  briggs 			microtime(&new_event.timestamp);
    1.1  briggs 			adb_dokeyupdown(&new_event);
    1.2  briggs 		} else if (event->u.k.key == ADBK_KEYUP(ADBK_LEFT)) {
    1.1  briggs 			adb_ms_buttons &= ~2;	/* middle up */
    1.1  briggs 			new_event.def_addr = ADBADDR_MS;
    1.1  briggs 			new_event.u.m.buttons = adb_ms_buttons;
    1.1  briggs 			new_event.u.m.dx = new_event.u.m.dy = 0;
    1.1  briggs 			microtime(&new_event.timestamp);
    1.1  briggs 			adb_dokeyupdown(&new_event);
    1.2  briggs 		} else if (event->u.k.key == ADBK_KEYDOWN(ADBK_RIGHT)) {
    1.1  briggs 			adb_ms_buttons |= 4;	/* right down */
    1.1  briggs 			new_event.def_addr = ADBADDR_MS;
    1.1  briggs 			new_event.u.m.buttons = adb_ms_buttons;
    1.1  briggs 			new_event.u.m.dx = new_event.u.m.dy = 0;
    1.1  briggs 			microtime(&new_event.timestamp);
    1.1  briggs 			adb_dokeyupdown(&new_event);
    1.2  briggs 		} else if (event->u.k.key == ADBK_KEYUP(ADBK_RIGHT)) {
    1.1  briggs 			adb_ms_buttons &= ~4;	/* right up */
    1.1  briggs 			new_event.def_addr = ADBADDR_MS;
    1.1  briggs 			new_event.u.m.buttons = adb_ms_buttons;
    1.1  briggs 			new_event.u.m.dx = new_event.u.m.dy = 0;
    1.1  briggs 			microtime(&new_event.timestamp);
    1.1  briggs 			adb_dokeyupdown(&new_event);
    1.2  briggs 		} else if (ADBK_MODIFIER(event->u.k.key)) {
    1.2  briggs 		/* ctrl, shift, cmd */
    1.1  briggs 			adb_dokeyupdown(event);
    1.3  briggs 		} else if (!(event->u.k.key & 0x80)) {
    1.2  briggs 		/* key down */
    1.1  briggs 			new_event = *event;
    1.1  briggs
    1.2  briggs 			/* send option-down */
    1.2  briggs 			new_event.u.k.key = ADBK_KEYDOWN(ADBK_OPTION);
    1.1  briggs 			new_event.bytes[0] = new_event.u.k.key;
    1.1  briggs 			microtime(&new_event.timestamp);
    1.1  briggs 			adb_dokeyupdown(&new_event);
    1.1  briggs
    1.2  briggs 			/* send key-down */
    1.2  briggs 			new_event.u.k.key = event->bytes[0];
    1.1  briggs 			new_event.bytes[0] = new_event.u.k.key;
    1.1  briggs 			microtime(&new_event.timestamp);
    1.1  briggs 			adb_dokeyupdown(&new_event);
    1.1  briggs
    1.2  briggs 			/* send key-up */
    1.3  briggs 			new_event.u.k.key =
    1.3  briggs 				ADBK_KEYUP(ADBK_KEYVAL(event->bytes[0]));
    1.1  briggs 			microtime(&new_event.timestamp);
    1.1  briggs 			new_event.bytes[0] = new_event.u.k.key;
    1.3  briggs 			adb_dokeyupdown(&new_event);
    1.1  briggs
    1.2  briggs 			/* send option-up */
    1.3  briggs 			new_event.u.k.key = ADBK_KEYUP(ADBK_OPTION);
    1.1  briggs 			new_event.bytes[0] = new_event.u.k.key;
    1.1  briggs 			microtime(&new_event.timestamp);
    1.1  briggs 			adb_dokeyupdown(&new_event);
    1.2  briggs 		} else {
    1.2  briggs 			/* option-keyup -- do nothing. */
    1.1  briggs 		}
    1.2  briggs 	} else {
    1.1  briggs 		adb_dokeyupdown(event);
    1.1  briggs 	}
    1.1  briggs }
    1.1  briggs
    1.1  briggs
    1.2  briggs void
    1.2  briggs adb_processevent(event)
    1.2  briggs     adb_event_t *event;
    1.1  briggs {
    1.1  briggs 	adb_event_t new_event;
1.4.2.1  briggs 	int i, button_bit, max_byte, mask, buttons;
    1.1  briggs
    1.1  briggs 	new_event = *event;
1.4.2.1  briggs 	buttons = 0;
    1.1  briggs
    1.2  briggs 	switch (event->def_addr) {
    1.2  briggs 	case ADBADDR_KBD:
    1.2  briggs 		new_event.u.k.key = event->bytes[0];
    1.2  briggs 		new_event.bytes[1] = 0xff;
    1.2  briggs 		adb_keymaybemouse(&new_event);
    1.2  briggs 		if (event->bytes[1] != 0xff) {
    1.2  briggs 			new_event.u.k.key = event->bytes[1];
    1.2  briggs 			new_event.bytes[0] = event->bytes[1];
    1.1  briggs 			new_event.bytes[1] = 0xff;
    1.1  briggs 			adb_keymaybemouse(&new_event);
    1.2  briggs 		}
    1.2  briggs 		break;
    1.2  briggs 	case ADBADDR_MS:
    1.4  briggs 		/*
    1.4  briggs 		 * This should handle both plain ol' Apple mice and mice
    1.4  briggs 		 * that claim to support the Extended Apple Mouse Protocol.
    1.4  briggs 		 */
    1.4  briggs 		max_byte = event->byte_count;
    1.4  briggs 		button_bit = 1;
    1.4  briggs 		/* Classic Mouse Protocol (up to 2 buttons) */
    1.4  briggs 		for (i = 0; i < 2; i++, button_bit <<= 1)
    1.4  briggs 			/* 0 when button down */
    1.4  briggs 			if (!(event->bytes[i] & 0x80))
1.4.2.1  briggs 				buttons |= button_bit;
    1.4  briggs 			else
1.4.2.1  briggs 				buttons &= ~button_bit;
    1.4  briggs 		/* Extended Protocol (up to 6 more buttons) */
    1.4  briggs 		for (mask = 0x80; i < max_byte;
    1.4  briggs 		     i += (mask == 0x80), button_bit <<= 1) {
    1.4  briggs 			/* 0 when button down */
    1.4  briggs 			if (!(event->bytes[i] & mask))
1.4.2.1  briggs 				buttons |= button_bit;
    1.4  briggs 			else
1.4.2.1  briggs 				buttons &= ~button_bit;
    1.4  briggs 			mask = ((mask >> 4) & 0xf) | ((mask & 0xf) << 4);
    1.4  briggs 		}
1.4.2.1  briggs 		new_event.u.m.buttons = adb_ms_buttons | buttons;
    1.2  briggs 		new_event.u.m.dx = ((signed int) (event->bytes[1] & 0x3f)) -
    1.2  briggs 					((event->bytes[1] & 0x40) ? 64 : 0);
    1.2  briggs 		new_event.u.m.dy = ((signed int) (event->bytes[0] & 0x3f)) -
    1.2  briggs 					((event->bytes[0] & 0x40) ? 64 : 0);
    1.2  briggs 		adb_dokeyupdown(&new_event);
    1.2  briggs 		break;
    1.2  briggs 	default:		/* God only knows. */
    1.2  briggs 		adb_dokeyupdown(event);
    1.1  briggs 	}
    1.1  briggs }
    1.1  briggs
    1.1  briggs
    1.2  briggs int
    1.2  briggs adbopen(dev, flag, mode, p)
    1.2  briggs     dev_t dev;
    1.2  briggs     int flag, mode;
    1.2  briggs     struct proc *p;
    1.1  briggs {
    1.1  briggs 	register int unit;
    1.1  briggs 	int error = 0;
    1.1  briggs 	int s;
    1.2  briggs
    1.1  briggs 	unit = minor(dev);
    1.2  briggs 	if (unit != 0)
    1.2  briggs 		return (ENXIO);
    1.2  briggs
    1.1  briggs 	s = splhigh();
    1.2  briggs 	if (adb_isopen) {
    1.1  briggs 		splx(s);
    1.2  briggs 		return (EBUSY);
    1.1  briggs 	}
    1.1  briggs 	splx(s);
    1.1  briggs 	adb_evq_tail = 0;
    1.1  briggs 	adb_evq_len = 0;
    1.1  briggs 	adb_isopen = 1;
    1.1  briggs 	adb_ioproc = p;
    1.1  briggs
    1.1  briggs 	return (error);
    1.1  briggs }
    1.1  briggs
    1.1  briggs
    1.2  briggs int
    1.2  briggs adbclose(dev, flag, mode, p)
    1.2  briggs     dev_t dev;
    1.2  briggs     int flag, mode;
    1.2  briggs     struct proc *p;
    1.1  briggs {
    1.1  briggs 	adb_isopen = 0;
    1.1  briggs 	adb_ioproc = NULL;
    1.1  briggs 	return (0);
    1.1  briggs }
    1.1  briggs
    1.1  briggs
    1.2  briggs int
    1.2  briggs adbread(dev, uio, flag)
    1.2  briggs     dev_t dev;
    1.2  briggs     struct uio *uio;
    1.2  briggs     int flag;
    1.1  briggs {
    1.1  briggs 	int s, error;
    1.1  briggs 	int willfit;
    1.1  briggs 	int total;
    1.1  briggs 	int firstmove;
    1.1  briggs 	int moremove;
    1.1  briggs
    1.1  briggs 	if (uio->uio_resid < sizeof(adb_event_t))
    1.1  briggs 		return (EMSGSIZE);	/* close enough. */
    1.1  briggs
    1.1  briggs 	s = splhigh();
    1.2  briggs 	if (adb_evq_len == 0) {
    1.2  briggs 		splx(s);
    1.2  briggs 		return (0);
    1.1  briggs 	}
    1.1  briggs 	willfit = howmany(uio->uio_resid, sizeof(adb_event_t));
    1.1  briggs 	total = (adb_evq_len < willfit) ? adb_evq_len : willfit;
    1.1  briggs
    1.1  briggs 	firstmove = (adb_evq_tail + total > ADB_MAX_EVENTS)
    1.2  briggs 	    ? (ADB_MAX_EVENTS - adb_evq_tail) : total;
    1.2  briggs
    1.2  briggs 	error = uiomove((caddr_t) & adb_evq[adb_evq_tail],
    1.2  briggs 	    firstmove * sizeof(adb_event_t), uio);
    1.2  briggs 	if (error) {
    1.1  briggs 		splx(s);
    1.2  briggs 		return (error);
    1.1  briggs 	}
    1.1  briggs 	moremove = total - firstmove;
    1.1  briggs
    1.2  briggs 	if (moremove > 0) {
    1.2  briggs 		error = uiomove((caddr_t) & adb_evq[0],
    1.2  briggs 		    moremove * sizeof(adb_event_t), uio);
    1.2  briggs 		if (error) {
    1.1  briggs 			splx(s);
    1.2  briggs 			return (error);
    1.1  briggs 		}
    1.1  briggs 	}
    1.1  briggs 	adb_evq_tail = (adb_evq_tail + total) % ADB_MAX_EVENTS;
    1.1  briggs 	adb_evq_len -= total;
    1.1  briggs 	splx(s);
    1.1  briggs 	return (0);
    1.1  briggs }
    1.1  briggs
    1.2  briggs
    1.2  briggs int
    1.2  briggs adbwrite(dev, uio, flag)
    1.2  briggs     dev_t dev;
    1.2  briggs     struct uio *uio;
    1.2  briggs     int flag;
    1.1  briggs {
    1.1  briggs 	return 0;
    1.1  briggs }
    1.1  briggs
    1.1  briggs
    1.2  briggs int
    1.2  briggs adbioctl(dev, cmd, data, flag, p)
    1.2  briggs     dev_t dev;
    1.2  briggs     int cmd;
    1.2  briggs     caddr_t data;
    1.2  briggs     int flag;
    1.2  briggs     struct proc *p;
    1.2  briggs {
    1.2  briggs 	switch (cmd) {
    1.2  briggs 	case ADBIOC_DEVSINFO: {
    1.2  briggs 		adb_devinfo_t *di;
    1.2  briggs 		ADBDataBlock adbdata;
    1.2  briggs 		int totaldevs;
    1.2  briggs 		int adbaddr;
    1.2  briggs 		int i;
    1.2  briggs
    1.2  briggs 		di = (void *) data;
    1.2  briggs
    1.2  briggs 		/* Initialize to no devices */
    1.2  briggs 		for (i = 0; i < 16; i++)
    1.2  briggs 			di->dev[i].addr = -1;
    1.2  briggs
    1.2  briggs 		totaldevs = CountADBs();
    1.2  briggs 		for (i = 1; i <= totaldevs; i++) {
    1.2  briggs 			adbaddr = GetIndADB(&adbdata, i);
    1.2  briggs 			di->dev[adbaddr].addr = adbaddr;
    1.2  briggs 			di->dev[adbaddr].default_addr = adbdata.origADBAddr;
    1.2  briggs 			di->dev[adbaddr].handler_id = adbdata.devType;
    1.1  briggs 			}
    1.1  briggs
    1.2  briggs 		/* Must call ADB Manager to get devices now */
    1.2  briggs 		break;
    1.2  briggs 	}
    1.2  briggs
    1.2  briggs 	case ADBIOC_GETREPEAT:{
    1.2  briggs 		adb_rptinfo_t *ri;
    1.1  briggs
    1.2  briggs 		ri = (void *) data;
    1.2  briggs 		ri->delay_ticks = adb_rptdelay;
    1.2  briggs 		ri->interval_ticks = adb_rptinterval;
    1.2  briggs 		break;
    1.2  briggs 	}
    1.1  briggs
    1.2  briggs 	case ADBIOC_SETREPEAT:{
    1.2  briggs 		adb_rptinfo_t *ri;
    1.1  briggs
    1.2  briggs 		ri = (void *) data;
    1.2  briggs 		adb_rptdelay = ri->delay_ticks;
    1.2  briggs 		adb_rptinterval = ri->interval_ticks;
    1.2  briggs 		break;
    1.2  briggs 	}
    1.1  briggs
    1.2  briggs 	case ADBIOC_RESET:
    1.2  briggs 		adb_init();
    1.2  briggs 		break;
    1.1  briggs
    1.2  briggs 	case ADBIOC_LISTENCMD:{
    1.2  briggs 		adb_listencmd_t *lc;
    1.1  briggs
    1.2  briggs 		lc = (void *) data;
    1.2  briggs 	}
    1.1  briggs
    1.2  briggs 	default:
    1.2  briggs 		return (EINVAL);
    1.1  briggs 	}
    1.2  briggs 	return (0);
    1.1  briggs }
    1.1  briggs
    1.1  briggs
    1.2  briggs int
    1.2  briggs adbselect(dev, rw, p)
    1.2  briggs     dev_t dev;
    1.2  briggs     int rw;
    1.2  briggs     struct proc *p;
    1.1  briggs {
    1.1  briggs 	switch (rw) {
    1.2  briggs 	case FREAD:
    1.2  briggs 		/* succeed if there is something to read */
    1.2  briggs 		if (adb_evq_len > 0)
    1.2  briggs 			return (1);
    1.2  briggs 		selrecord(p, &adb_selinfo);
    1.2  briggs 		break;
    1.2  briggs
    1.2  briggs 	case FWRITE:
    1.2  briggs 		return (1);	/* always fails => never blocks */
    1.2  briggs 		break;
    1.1  briggs 	}
    1.1  briggs
    1.1  briggs 	return (0);
    1.1  briggs }