sun3/dev/zs.c

1.1  glass /*
1.9    gwr  * Copyright (c) 1994 Gordon W. Ross
1.1  glass  * Copyright (c) 1992, 1993
1.1  glass  *	The Regents of the University of California.  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 Laboratory.
1.1  glass  *
1.1  glass  * Redistribution and use in source and binary forms, with or without
1.1  glass  * modification, are permitted provided that the following conditions
1.1  glass  * are met:
1.1  glass  * 1. Redistributions of source code must retain the above copyright
1.1  glass  *    notice, this list of conditions and the following disclaimer.
1.1  glass  * 2. Redistributions in binary form must reproduce the above copyright
1.1  glass  *    notice, this list of conditions and the following disclaimer in the
1.1  glass  *    documentation and/or other materials provided with the distribution.
1.1  glass  * 3. 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, Berkeley and its contributors.
1.1  glass  * 4. Neither the name of the University nor the names of its contributors
1.1  glass  *    may be used to endorse or promote products derived from this software
1.1  glass  *    without specific prior written permission.
1.1  glass  *
1.1  glass  * THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS ``AS IS'' AND
1.1  glass  * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
1.1  glass  * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
1.1  glass  * ARE DISCLAIMED.  IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE
1.1  glass  * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
1.1  glass  * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
1.1  glass  * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
1.1  glass  * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
1.1  glass  * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
1.1  glass  * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
1.1  glass  * SUCH DAMAGE.
1.1  glass  *
1.1  glass  *	@(#)zs.c	8.1 (Berkeley) 7/19/93
1.1  glass  *
1.9    gwr  * $Id: zs.c,v 1.9 1994/09/20 16:21:48 gwr Exp $
1.1  glass  */
1.1  glass
1.1  glass /*
1.1  glass  * Zilog Z8530 (ZSCC) driver.
1.1  glass  *
1.1  glass  * Runs two tty ports (ttya and ttyb) on zs0,
1.1  glass  * and runs a keyboard and mouse on zs1.
1.1  glass  *
1.1  glass  * This driver knows far too much about chip to usage mappings.
1.1  glass  */
1.1  glass #define	NZS	2		/* XXX */
1.1  glass
1.5    gwr #include <sys/param.h>
1.1  glass #include <sys/systm.h>
1.1  glass #include <sys/proc.h>
1.1  glass #include <sys/device.h>
1.1  glass #include <sys/conf.h>
1.1  glass #include <sys/file.h>
1.1  glass #include <sys/ioctl.h>
1.1  glass #include <sys/tty.h>
1.1  glass #include <sys/time.h>
1.1  glass #include <sys/kernel.h>
1.1  glass #include <sys/syslog.h>
1.1  glass
1.1  glass #include <machine/autoconf.h>
1.1  glass #include <machine/cpu.h>
1.1  glass #include <machine/obio.h>
1.3    gwr #include <machine/mon.h>
1.3    gwr #include <machine/eeprom.h>
1.3    gwr
1.3    gwr #include <dev/cons.h>
1.1  glass
1.1  glass #include "kbd.h"
1.1  glass #include "zsreg.h"
1.1  glass #include "zsvar.h"
1.1  glass
1.1  glass #ifdef KGDB
1.1  glass #include <machine/remote-sl.h>
1.1  glass #endif
1.1  glass
1.1  glass #define	ZSMAJOR	12		/* XXX */
1.1  glass
1.1  glass #define	ZS_KBD		2	/* XXX */
1.1  glass #define	ZS_MOUSE	3	/* XXX */
1.1  glass
1.2  glass /* The Sun3 provides a 4.9152 MHz clock to the ZS chips. */
1.2  glass #define PCLK	(9600 * 512)	/* PCLK pin input clock rate */
1.2  glass
1.2  glass /*
1.2  glass  * Select software interrupt levels.
1.2  glass  */
1.2  glass #define ZSSOFT_PRI	2	/* XXX - Want TTY_PRI */
1.2  glass #define ZSHARD_PRI	6	/* Wired on the CPU board... */
1.1  glass
1.1  glass /*
1.1  glass  * Software state per found chip.  This would be called `zs_softc',
1.1  glass  * but the previous driver had a rather different zs_softc....
1.1  glass  */
1.1  glass struct zsinfo {
1.1  glass 	struct	device zi_dev;		/* base device */
1.1  glass 	volatile struct zsdevice *zi_zs;/* chip registers */
1.1  glass 	struct	zs_chanstate zi_cs[2];	/* channel A and B software state */
1.1  glass };
1.1  glass
1.1  glass struct tty *zs_tty[NZS * 2];		/* XXX should be dynamic */
1.1  glass
1.1  glass /* Definition of the driver for autoconfig. */
1.2  glass static int	zsmatch(struct device *, struct cfdata *, void *);
1.2  glass static void	zsattach(struct device *, struct device *, void *);
1.1  glass struct cfdriver zscd =
1.1  glass     { NULL, "zs", zsmatch, zsattach, DV_TTY, sizeof(struct zsinfo) };
1.1  glass
1.1  glass /* Interrupt handlers. */
1.2  glass static int	zshard(int);
1.2  glass static int	zssoft(int);
1.1  glass
1.1  glass struct zs_chanstate *zslist;
1.1  glass
1.1  glass /* Routines called from other code. */
1.2  glass int zsopen(dev_t, int, int, struct proc *);
1.2  glass int zsclose(dev_t, int, int, struct proc *);
1.2  glass static void	zsiopen(struct tty *);
1.2  glass static void	zsiclose(struct tty *);
1.2  glass static void	zsstart(struct tty *);
1.2  glass void		zsstop(struct tty *, int);
1.2  glass static int	zsparam(struct tty *, struct termios *);
1.1  glass
1.1  glass /* Routines purely local to this driver. */
1.2  glass static int	zs_getspeed(volatile struct zschan *);
1.2  glass static void	zs_reset(volatile struct zschan *, int, int);
1.2  glass static void	zs_modem(struct zs_chanstate *, int);
1.2  glass static void	zs_loadchannelregs(volatile struct zschan *, u_char *);
1.2  glass static u_char zs_read(volatile struct zschan *, u_char);
1.2  glass static u_char zs_write(volatile struct zschan *, u_char, u_char);
1.1  glass
1.1  glass /* Console stuff. */
1.1  glass static volatile struct zschan *zs_conschan;
1.1  glass
1.1  glass #ifdef KGDB
1.1  glass /* KGDB stuff.  Must reboot to change zs_kgdbunit. */
1.1  glass extern int kgdb_dev, kgdb_rate;
1.1  glass static int zs_kgdb_savedspeed;
1.2  glass static void zs_checkkgdb(int, struct zs_chanstate *, struct tty *);
1.1  glass #endif
1.1  glass
1.1  glass /*
1.1  glass  * Console keyboard L1-A processing is done in the hardware interrupt code,
1.1  glass  * so we need to duplicate some of the console keyboard decode state.  (We
1.1  glass  * must not use the regular state as the hardware code keeps ahead of the
1.1  glass  * software state: the software state tracks the most recent ring input but
1.1  glass  * the hardware state tracks the most recent ZSCC input.)  See also kbd.h.
1.1  glass  */
1.1  glass static struct conk_state {	/* console keyboard state */
1.1  glass 	char	conk_id;	/* true => ID coming up (console only) */
1.1  glass 	char	conk_l1;	/* true => L1 pressed (console only) */
1.1  glass } zsconk_state;
1.1  glass
1.1  glass int zshardscope;
1.1  glass int zsshortcuts;		/* number of "shortcut" software interrupts */
1.1  glass
1.9    gwr static volatile struct zsdevice *zsaddr[NZS];	/* XXX, but saves work */
1.9    gwr
1.9    gwr /* Find PROM mappings (for console support). */
1.9    gwr void zs_init()
1.9    gwr {
1.9    gwr 	if (zsaddr[0] == NULL)
1.9    gwr 		zsaddr[0] = (struct zsdevice *)
1.9    gwr 			obio_find_mapping(OBIO_ZS, OBIO_ZS_SIZE);
1.9    gwr 	if (zsaddr[1] == NULL)
1.9    gwr 		zsaddr[1] = (struct zsdevice *)
1.9    gwr 			obio_find_mapping(OBIO_KEYBD_MS, OBIO_ZS_SIZE);
1.9    gwr }
1.9    gwr
1.1  glass /*
1.1  glass  * Match slave number to zs unit number, so that misconfiguration will
1.1  glass  * not set up the keyboard as ttya, etc.
1.1  glass  */
1.1  glass static int
1.1  glass zsmatch(struct device *parent, struct cfdata *cf, void *aux)
1.1  glass {
1.2  glass 	struct obio_cf_loc *obio_loc;
1.2  glass 	caddr_t zs_addr;
1.1  glass
1.2  glass 	obio_loc = (struct obio_cf_loc *) CFDATA_LOC(cf);
1.2  glass 	zs_addr = (caddr_t) obio_loc->obio_addr;
1.2  glass 	return !obio_probe_byte(zs_addr);
1.1  glass }
1.1  glass
1.1  glass /*
1.1  glass  * Attach a found zs.
1.1  glass  *
1.1  glass  * USE ROM PROPERTIES port-a-ignore-cd AND port-b-ignore-cd FOR
1.1  glass  * SOFT CARRIER, AND keyboard PROPERTY FOR KEYBOARD/MOUSE?
1.1  glass  */
1.1  glass static void
1.1  glass zsattach(struct device *parent, struct device *dev, void *aux)
1.1  glass {
1.2  glass 	struct obio_cf_loc *obio_loc = OBIO_LOC(dev);
1.1  glass 	register int zs = dev->dv_unit, unit;
1.1  glass 	register struct zsinfo *zi;
1.1  glass 	register struct zs_chanstate *cs;
1.1  glass 	register volatile struct zsdevice *addr;
1.1  glass 	register struct tty *tp, *ctp;
1.9    gwr 	int softcar, obio_addr;
1.2  glass 	static int didintr;
1.2  glass
1.9    gwr 	obio_addr = obio_loc->obio_addr;
1.2  glass 	obio_print(obio_addr, ZSSOFT_PRI);
1.2  glass 	printf(" hwpri %d\n", ZSHARD_PRI);
1.1  glass
1.9    gwr 	if (zsaddr[zs] == NULL) {
1.9    gwr 		zsaddr[zs] = (struct zsdevice *)
1.9    gwr 			obio_alloc(obio_addr, OBIO_ZS_SIZE);
1.3    gwr 	}
1.9    gwr 	addr = zsaddr[zs];
1.1  glass
1.1  glass 	if (!didintr) {
1.2  glass 		didintr = 1;
1.2  glass 		isr_add(ZSSOFT_PRI, zssoft, 0);
1.2  glass 		isr_add(ZSHARD_PRI, zshard, 0);
1.1  glass 	}
1.2  glass
1.1  glass 	zi = (struct zsinfo *)dev;
1.1  glass 	zi->zi_zs = addr;
1.1  glass 	unit = zs * 2;
1.1  glass 	cs = zi->zi_cs;
1.1  glass
1.1  glass 	if(!zs_tty[unit])
1.1  glass 		zs_tty[unit] = ttymalloc();
1.1  glass 	tp = zs_tty[unit];
1.1  glass 	if(!zs_tty[unit+1])
1.1  glass 		zs_tty[unit+1] = ttymalloc();
1.2  glass
1.1  glass 	if (unit == 0) {
1.1  glass 		softcar = 0;
1.1  glass 	} else
1.1  glass 		softcar = dev->dv_cfdata->cf_flags;
1.1  glass
1.1  glass 	/* link into interrupt list with order (A,B) (B=A+1) */
1.1  glass 	cs[0].cs_next = &cs[1];
1.1  glass 	cs[1].cs_next = zslist;
1.1  glass 	zslist = cs;
1.1  glass
1.1  glass 	cs->cs_unit = unit;
1.6    gwr 	cs->cs_zc = &addr->zs_chan[CHAN_A];
1.2  glass 	cs->cs_speed = zs_getspeed(cs->cs_zc);
1.2  glass #ifdef	DEBUG
1.3    gwr 	mon_printf("zs%da speed %d ",  zs, cs->cs_speed);
1.2  glass #endif
1.1  glass 	cs->cs_softcar = softcar & 1;
1.2  glass #if 0
1.2  glass 	/* XXX - Drop carrier here? -gwr */
1.2  glass 	zs_modem(cs, cs->cs_softcar ? 1 : 0);
1.2  glass #endif
1.3    gwr 	cs->cs_ttyp = tp;
1.1  glass 	tp->t_dev = makedev(ZSMAJOR, unit);
1.1  glass 	tp->t_oproc = zsstart;
1.1  glass 	tp->t_param = zsparam;
1.3    gwr 	if (cs->cs_zc == zs_conschan) {
1.3    gwr 		/* This unit is the console. */
1.3    gwr 		cs->cs_consio = 1;
1.3    gwr 		cs->cs_brkabort = 1;
1.3    gwr 		cs->cs_softcar = 1;
1.3    gwr 	} else {
1.3    gwr 		/* Can not run kgdb on the console? */
1.1  glass #ifdef KGDB
1.1  glass 		zs_checkkgdb(unit, cs, tp);
1.1  glass #endif
1.3    gwr 	}
1.1  glass 	if (unit == ZS_KBD) {
1.1  glass 		/*
1.1  glass 		 * Keyboard: tell /dev/kbd driver how to talk to us.
1.1  glass 		 */
1.1  glass 		tp->t_ispeed = tp->t_ospeed = cs->cs_speed;
1.1  glass 		tp->t_cflag = CS8;
1.1  glass 		kbd_serial(tp, zsiopen, zsiclose);
1.1  glass 		cs->cs_conk = 1;		/* do L1-A processing */
1.1  glass 	}
1.1  glass 	unit++;
1.1  glass 	cs++;
1.1  glass 	tp = zs_tty[unit];
1.2  glass
1.1  glass 	cs->cs_unit = unit;
1.2  glass 	cs->cs_zc = &addr->zs_chan[CHAN_B];
1.2  glass 	cs->cs_speed = zs_getspeed(cs->cs_zc);
1.2  glass #ifdef	DEBUG
1.3    gwr 	mon_printf("zs%db speed %d\n", zs, cs->cs_speed);
1.2  glass #endif
1.1  glass 	cs->cs_softcar = softcar & 2;
1.2  glass #if 0
1.2  glass 	/* XXX - Drop carrier here? -gwr */
1.2  glass 	zs_modem(cs, cs->cs_softcar ? 1 : 0);
1.2  glass #endif
1.3    gwr 	cs->cs_ttyp = tp;
1.1  glass 	tp->t_dev = makedev(ZSMAJOR, unit);
1.1  glass 	tp->t_oproc = zsstart;
1.1  glass 	tp->t_param = zsparam;
1.3    gwr 	if (cs->cs_zc == zs_conschan) {
1.3    gwr 		/* This unit is the console. */
1.3    gwr 		cs->cs_consio = 1;
1.3    gwr 		cs->cs_brkabort = 1;
1.3    gwr 		cs->cs_softcar = 1;
1.3    gwr 	} else {
1.3    gwr 		/* Can not run kgdb on the console? */
1.1  glass #ifdef KGDB
1.1  glass 		zs_checkkgdb(unit, cs, tp);
1.1  glass #endif
1.3    gwr 	}
1.1  glass 	if (unit == ZS_MOUSE) {
1.1  glass 		/*
1.1  glass 		 * Mouse: tell /dev/mouse driver how to talk to us.
1.1  glass 		 */
1.1  glass 		tp->t_ispeed = tp->t_ospeed = cs->cs_speed;
1.1  glass 		tp->t_cflag = CS8;
1.1  glass 		ms_serial(tp, zsiopen, zsiclose);
1.1  glass 	}
1.1  glass }
1.1  glass
1.1  glass /*
1.1  glass  * Put a channel in a known state.  Interrupts may be left disabled
1.1  glass  * or enabled, as desired.
1.1  glass  */
1.1  glass static void
1.1  glass zs_reset(zc, inten, speed)
1.1  glass 	volatile struct zschan *zc;
1.1  glass 	int inten, speed;
1.1  glass {
1.1  glass 	int tconst;
1.1  glass 	static u_char reg[16] = {
1.1  glass 		0,
1.1  glass 		0,
1.1  glass 		0,
1.1  glass 		ZSWR3_RX_8 | ZSWR3_RX_ENABLE,
1.1  glass 		ZSWR4_CLK_X16 | ZSWR4_ONESB | ZSWR4_EVENP,
1.1  glass 		ZSWR5_TX_8 | ZSWR5_TX_ENABLE,
1.1  glass 		0,
1.1  glass 		0,
1.1  glass 		0,
1.1  glass 		0,
1.1  glass 		ZSWR10_NRZ,
1.1  glass 		ZSWR11_TXCLK_BAUD | ZSWR11_RXCLK_BAUD,
1.1  glass 		0,
1.1  glass 		0,
1.1  glass 		ZSWR14_BAUD_FROM_PCLK | ZSWR14_BAUD_ENA,
1.1  glass 		ZSWR15_BREAK_IE | ZSWR15_DCD_IE,
1.1  glass 	};
1.1  glass
1.1  glass 	reg[9] = inten ? ZSWR9_MASTER_IE | ZSWR9_NO_VECTOR : ZSWR9_NO_VECTOR;
1.1  glass 	tconst = BPS_TO_TCONST(PCLK / 16, speed);
1.1  glass 	reg[12] = tconst;
1.1  glass 	reg[13] = tconst >> 8;
1.1  glass 	zs_loadchannelregs(zc, reg);
1.1  glass }
1.1  glass
1.3    gwr /*
1.3    gwr  * Console support
1.3    gwr  */
1.2  glass
1.3    gwr /*
1.3    gwr  * Used by the kd driver to find out if it can work.
1.3    gwr  */
1.2  glass int
1.3    gwr zscnprobe_kbd()
1.2  glass {
1.9    gwr 	if (zsaddr[1] == NULL) {
1.3    gwr 		mon_printf("zscnprobe_kbd: zs1 not yet mapped\n");
1.3    gwr 		return CN_DEAD;
1.3    gwr 	}
1.3    gwr 	return CN_INTERNAL;
1.3    gwr }
1.3    gwr
1.3    gwr /*
1.3    gwr  * This is the console probe routine for ttya and ttyb.
1.3    gwr  */
1.3    gwr static int
1.3    gwr zscnprobe(struct consdev *cn, int unit)
1.3    gwr {
1.3    gwr 	int maj, eeCons;
1.3    gwr
1.9    gwr 	if (zsaddr[0] == NULL) {
1.9    gwr 		mon_printf("zscnprobe: zs0 not mapped\n");
1.3    gwr 		cn->cn_pri = CN_DEAD;
1.3    gwr 		return 0;
1.3    gwr 	}
1.3    gwr 	/* XXX - Also try to make sure it exists? */
1.2  glass
1.2  glass 	/* locate the major number */
1.2  glass 	for (maj = 0; maj < nchrdev; maj++)
1.2  glass 		if (cdevsw[maj].d_open == zsopen)
1.2  glass 			break;
1.3    gwr
1.3    gwr 	cn->cn_dev = makedev(maj, unit);
1.3    gwr
1.3    gwr 	/* Use EEPROM console setting to decide "remote" console. */
1.9    gwr 	eeCons = ee_get_byte(EE_CONS_OFFSET, 0);
1.2  glass
1.3    gwr 	/* Hack: EE_CONS_TTYA + 1 == EE_CONS_TTYB */
1.3    gwr 	if (eeCons == (EE_CONS_TTYA + unit)) {
1.3    gwr 		cn->cn_pri = CN_REMOTE;
1.3    gwr 	} else {
1.3    gwr 		cn->cn_pri = CN_NORMAL;
1.3    gwr 	}
1.2  glass 	return (0);
1.2  glass }
1.2  glass
1.3    gwr /* This is the constab entry for TTYA. */
1.2  glass int
1.3    gwr zscnprobe_a(struct consdev *cn)
1.2  glass {
1.3    gwr 	return (zscnprobe(cn, 0));
1.3    gwr }
1.2  glass
1.3    gwr /* This is the constab entry for TTYB. */
1.3    gwr int
1.3    gwr zscnprobe_b(struct consdev *cn)
1.3    gwr {
1.3    gwr 	return (zscnprobe(cn, 1));
1.2  glass }
1.2  glass
1.3    gwr /* Attach as console.  Also set zs_conschan */
1.3    gwr int
1.3    gwr zscninit(struct consdev *cn)
1.1  glass {
1.3    gwr 	int unit;
1.1  glass 	volatile struct zsdevice *addr;
1.1  glass
1.3    gwr 	unit = minor(cn->cn_dev) & 1;
1.9    gwr 	addr = zsaddr[0];
1.3    gwr 	zs_conschan = ((unit == 0) ?
1.3    gwr 				   &addr->zs_chan[CHAN_A] :
1.3    gwr 				   &addr->zs_chan[CHAN_B] );
1.3    gwr
1.3    gwr 	mon_printf("console on zs0 (tty%c)\n", unit + 'a');
1.1  glass }
1.3    gwr
1.1  glass
1.2  glass /*
1.2  glass  * Polled console input putchar.
1.2  glass  */
1.2  glass int
1.4    gwr zscngetc(dev)
1.4    gwr 	dev_t dev;
1.2  glass {
1.2  glass 	register volatile struct zschan *zc = zs_conschan;
1.2  glass 	register int s, c;
1.2  glass
1.2  glass 	if (zc == NULL)
1.2  glass 		return (0);
1.2  glass
1.2  glass 	s = splhigh();
1.9    gwr
1.9    gwr 	/* Wait for a character to arrive. */
1.2  glass 	while ((zc->zc_csr & ZSRR0_RX_READY) == 0)
1.3    gwr 		ZS_DELAY();
1.3    gwr 	ZS_DELAY();
1.9    gwr
1.2  glass 	c = zc->zc_data;
1.9    gwr 	ZS_DELAY();
1.9    gwr
1.2  glass 	splx(s);
1.2  glass 	return (c);
1.2  glass }
1.1  glass
1.1  glass /*
1.1  glass  * Polled console output putchar.
1.1  glass  */
1.2  glass int
1.4    gwr zscnputc(dev, c)
1.4    gwr 	dev_t dev;
1.1  glass 	int c;
1.1  glass {
1.1  glass 	register volatile struct zschan *zc = zs_conschan;
1.1  glass 	register int s;
1.1  glass
1.4    gwr 	if (zc == NULL) {
1.4    gwr 		s = splhigh();
1.4    gwr 		mon_putchar(c);
1.4    gwr 		splx(s);
1.2  glass 		return (0);
1.4    gwr 	}
1.9    gwr 	s = splhigh();
1.2  glass
1.9    gwr 	/* Wait for transmitter to become ready. */
1.1  glass 	while ((zc->zc_csr & ZSRR0_TX_READY) == 0)
1.3    gwr 		ZS_DELAY();
1.3    gwr 	ZS_DELAY();
1.9    gwr
1.1  glass 	zc->zc_data = c;
1.3    gwr 	ZS_DELAY();
1.1  glass 	splx(s);
1.1  glass }
1.2  glass
1.1  glass #ifdef KGDB
1.1  glass /*
1.1  glass  * The kgdb zs port, if any, was altered at boot time (see zs_kgdb_init).
1.1  glass  * Pick up the current speed and character size and restore the original
1.1  glass  * speed.
1.1  glass  */
1.1  glass static void
1.1  glass zs_checkkgdb(int unit, struct zs_chanstate *cs, struct tty *tp)
1.1  glass {
1.1  glass
1.1  glass 	if (kgdb_dev == makedev(ZSMAJOR, unit)) {
1.1  glass 		tp->t_ispeed = tp->t_ospeed = kgdb_rate;
1.1  glass 		tp->t_cflag = CS8;
1.1  glass 		cs->cs_kgdb = 1;
1.1  glass 		cs->cs_speed = zs_kgdb_savedspeed;
1.1  glass 		(void) zsparam(tp, &tp->t_termios);
1.1  glass 	}
1.1  glass }
1.1  glass #endif
1.1  glass
1.1  glass /*
1.1  glass  * Compute the current baud rate given a ZSCC channel.
1.1  glass  */
1.1  glass static int
1.1  glass zs_getspeed(zc)
1.1  glass 	register volatile struct zschan *zc;
1.1  glass {
1.1  glass 	register int tconst;
1.1  glass
1.1  glass 	tconst = ZS_READ(zc, 12);
1.1  glass 	tconst |= ZS_READ(zc, 13) << 8;
1.1  glass 	return (TCONST_TO_BPS(PCLK / 16, tconst));
1.1  glass }
1.1  glass
1.1  glass
1.1  glass /*
1.1  glass  * Do an internal open.
1.1  glass  */
1.1  glass static void
1.1  glass zsiopen(struct tty *tp)
1.1  glass {
1.1  glass
1.1  glass 	(void) zsparam(tp, &tp->t_termios);
1.1  glass 	ttsetwater(tp);
1.1  glass 	tp->t_state = TS_ISOPEN | TS_CARR_ON;
1.1  glass }
1.1  glass
1.1  glass /*
1.1  glass  * Do an internal close.  Eventually we should shut off the chip when both
1.1  glass  * ports on it are closed.
1.1  glass  */
1.1  glass static void
1.1  glass zsiclose(struct tty *tp)
1.1  glass {
1.1  glass
1.1  glass 	ttylclose(tp, 0);	/* ??? */
1.1  glass 	ttyclose(tp);		/* ??? */
1.1  glass 	tp->t_state = 0;
1.1  glass }
1.1  glass
1.1  glass
1.1  glass /*
1.1  glass  * Open a zs serial port.  This interface may not be used to open
1.1  glass  * the keyboard and mouse ports. (XXX)
1.1  glass  */
1.1  glass int
1.1  glass zsopen(dev_t dev, int flags, int mode, struct proc *p)
1.1  glass {
1.1  glass 	register struct tty *tp;
1.1  glass 	register struct zs_chanstate *cs;
1.1  glass 	struct zsinfo *zi;
1.1  glass 	int unit = minor(dev), zs = unit >> 1, error, s;
1.1  glass
1.2  glass #ifdef	DEBUG
1.3    gwr 	mon_printf("zs_open\n");
1.2  glass #endif
1.1  glass 	if (zs >= zscd.cd_ndevs || (zi = zscd.cd_devs[zs]) == NULL ||
1.1  glass 	    unit == ZS_KBD || unit == ZS_MOUSE)
1.1  glass 		return (ENXIO);
1.1  glass 	cs = &zi->zi_cs[unit & 1];
1.3    gwr #if 0
1.3    gwr 	/* The kd driver avoids the need for this hack. */
1.1  glass 	if (cs->cs_consio)
1.1  glass 		return (ENXIO);		/* ??? */
1.3    gwr #endif
1.1  glass 	tp = cs->cs_ttyp;
1.1  glass 	s = spltty();
1.1  glass 	if ((tp->t_state & TS_ISOPEN) == 0) {
1.1  glass 		ttychars(tp);
1.1  glass 		if (tp->t_ispeed == 0) {
1.1  glass 			tp->t_iflag = TTYDEF_IFLAG;
1.1  glass 			tp->t_oflag = TTYDEF_OFLAG;
1.8    gwr #if 0
1.1  glass 			tp->t_cflag = TTYDEF_CFLAG;
1.8    gwr #else
1.8    gwr 			/* Make default same as PROM uses. */
1.8    gwr 			tp->t_cflag = (CREAD | CS8 | HUPCL);
1.8    gwr #endif
1.1  glass 			tp->t_lflag = TTYDEF_LFLAG;
1.1  glass 			tp->t_ispeed = tp->t_ospeed = cs->cs_speed;
1.1  glass 		}
1.1  glass 		(void) zsparam(tp, &tp->t_termios);
1.1  glass 		ttsetwater(tp);
1.1  glass 	} else if (tp->t_state & TS_XCLUDE && p->p_ucred->cr_uid != 0) {
1.1  glass 		splx(s);
1.1  glass 		return (EBUSY);
1.1  glass 	}
1.1  glass 	error = 0;
1.3    gwr #ifdef	DEBUG
1.3    gwr 	mon_printf("wait for carrier...\n");
1.3    gwr #endif
1.1  glass 	for (;;) {
1.1  glass 		/* loop, turning on the device, until carrier present */
1.1  glass 		zs_modem(cs, 1);
1.2  glass 		/* May never get status intr if carrier already on. -gwr */
1.2  glass 		if (cs->cs_zc->zc_csr & ZSRR0_DCD)
1.2  glass 			tp->t_state |= TS_CARR_ON;
1.1  glass 		if (cs->cs_softcar)
1.1  glass 			tp->t_state |= TS_CARR_ON;
1.1  glass 		if (flags & O_NONBLOCK || tp->t_cflag & CLOCAL ||
1.1  glass 		    tp->t_state & TS_CARR_ON)
1.1  glass 			break;
1.1  glass 		tp->t_state |= TS_WOPEN;
1.1  glass 		if (error = ttysleep(tp, (caddr_t)&tp->t_rawq, TTIPRI | PCATCH,
1.1  glass 		    ttopen, 0))
1.1  glass 			break;
1.1  glass 	}
1.3    gwr #ifdef	DEBUG
1.3    gwr 	mon_printf("...carrier %s\n",
1.3    gwr 			   (tp->t_state & TS_CARR_ON) ? "on" : "off");
1.3    gwr #endif
1.1  glass 	splx(s);
1.1  glass 	if (error == 0)
1.1  glass 		error = linesw[tp->t_line].l_open(dev, tp);
1.1  glass 	if (error)
1.1  glass 		zs_modem(cs, 0);
1.1  glass 	return (error);
1.1  glass }
1.1  glass
1.1  glass /*
1.1  glass  * Close a zs serial port.
1.1  glass  */
1.1  glass int
1.1  glass zsclose(dev_t dev, int flags, int mode, struct proc *p)
1.1  glass {
1.1  glass 	register struct zs_chanstate *cs;
1.1  glass 	register struct tty *tp;
1.1  glass 	struct zsinfo *zi;
1.1  glass 	int unit = minor(dev), s;
1.1  glass
1.3    gwr #ifdef	DEBUG
1.3    gwr 	mon_printf("zs_close\n");
1.3    gwr #endif
1.1  glass 	zi = zscd.cd_devs[unit >> 1];
1.1  glass 	cs = &zi->zi_cs[unit & 1];
1.1  glass 	tp = cs->cs_ttyp;
1.1  glass 	linesw[tp->t_line].l_close(tp, flags);
1.1  glass 	if (tp->t_cflag & HUPCL || tp->t_state & TS_WOPEN ||
1.1  glass 	    (tp->t_state & TS_ISOPEN) == 0) {
1.1  glass 		zs_modem(cs, 0);
1.1  glass 		/* hold low for 1 second */
1.1  glass 		(void) tsleep((caddr_t)cs, TTIPRI, ttclos, hz);
1.1  glass 	}
1.6    gwr 	if (cs->cs_creg[5] & ZSWR5_BREAK)
1.6    gwr 	{
1.6    gwr 		s = splzs();
1.6    gwr 		cs->cs_preg[5] &= ~ZSWR5_BREAK;
1.6    gwr 		cs->cs_creg[5] &= ~ZSWR5_BREAK;
1.6    gwr 		ZS_WRITE(cs->cs_zc, 5, cs->cs_creg[5]);
1.6    gwr 		splx(s);
1.6    gwr 	}
1.1  glass 	ttyclose(tp);
1.1  glass #ifdef KGDB
1.1  glass 	/* Reset the speed if we're doing kgdb on this port */
1.1  glass 	if (cs->cs_kgdb) {
1.1  glass 		tp->t_ispeed = tp->t_ospeed = kgdb_rate;
1.1  glass 		(void) zsparam(tp, &tp->t_termios);
1.1  glass 	}
1.1  glass #endif
1.1  glass 	return (0);
1.1  glass }
1.1  glass
1.1  glass /*
1.1  glass  * Read/write zs serial port.
1.1  glass  */
1.1  glass int
1.1  glass zsread(dev_t dev, struct uio *uio, int flags)
1.1  glass {
1.1  glass 	register struct tty *tp = zs_tty[minor(dev)];
1.1  glass
1.1  glass 	return (linesw[tp->t_line].l_read(tp, uio, flags));
1.1  glass }
1.1  glass
1.1  glass int
1.1  glass zswrite(dev_t dev, struct uio *uio, int flags)
1.1  glass {
1.1  glass 	register struct tty *tp = zs_tty[minor(dev)];
1.1  glass
1.1  glass 	return (linesw[tp->t_line].l_write(tp, uio, flags));
1.1  glass }
1.1  glass
1.1  glass /*
1.1  glass  * ZS hardware interrupt.  Scan all ZS channels.  NB: we know here that
1.1  glass  * channels are kept in (A,B) pairs.
1.1  glass  *
1.1  glass  * Do just a little, then get out; set a software interrupt if more
1.1  glass  * work is needed.
1.1  glass  *
1.1  glass  * We deliberately ignore the vectoring Zilog gives us, and match up
1.1  glass  * only the number of `reset interrupt under service' operations, not
1.1  glass  * the order.
1.1  glass  */
1.1  glass /* ARGSUSED */
1.1  glass int
1.1  glass zshard(int intrarg)
1.1  glass {
1.1  glass 	register struct zs_chanstate *a;
1.1  glass #define	b (a + 1)
1.1  glass 	register volatile struct zschan *zc;
1.1  glass 	register int rr3, intflags = 0, v, i;
1.1  glass 	static int zsrint(struct zs_chanstate *, volatile struct zschan *);
1.1  glass 	static int zsxint(struct zs_chanstate *, volatile struct zschan *);
1.1  glass 	static int zssint(struct zs_chanstate *, volatile struct zschan *);
1.1  glass
1.1  glass 	for (a = zslist; a != NULL; a = b->cs_next) {
1.1  glass 		rr3 = ZS_READ(a->cs_zc, 3);
1.3    gwr
1.3    gwr 		/* XXX - This should loop to empty the on-chip fifo. */
1.1  glass 		if (rr3 & (ZSRR3_IP_A_RX|ZSRR3_IP_A_TX|ZSRR3_IP_A_STAT)) {
1.1  glass 			intflags |= 2;
1.1  glass 			zc = a->cs_zc;
1.1  glass 			i = a->cs_rbput;
1.1  glass 			if (rr3 & ZSRR3_IP_A_RX && (v = zsrint(a, zc)) != 0) {
1.1  glass 				a->cs_rbuf[i++ & ZLRB_RING_MASK] = v;
1.1  glass 				intflags |= 1;
1.1  glass 			}
1.1  glass 			if (rr3 & ZSRR3_IP_A_TX && (v = zsxint(a, zc)) != 0) {
1.1  glass 				a->cs_rbuf[i++ & ZLRB_RING_MASK] = v;
1.1  glass 				intflags |= 1;
1.1  glass 			}
1.1  glass 			if (rr3 & ZSRR3_IP_A_STAT && (v = zssint(a, zc)) != 0) {
1.1  glass 				a->cs_rbuf[i++ & ZLRB_RING_MASK] = v;
1.1  glass 				intflags |= 1;
1.1  glass 			}
1.1  glass 			a->cs_rbput = i;
1.1  glass 		}
1.3    gwr
1.3    gwr 		/* XXX - This should loop to empty the on-chip fifo. */
1.1  glass 		if (rr3 & (ZSRR3_IP_B_RX|ZSRR3_IP_B_TX|ZSRR3_IP_B_STAT)) {
1.1  glass 			intflags |= 2;
1.1  glass 			zc = b->cs_zc;
1.1  glass 			i = b->cs_rbput;
1.1  glass 			if (rr3 & ZSRR3_IP_B_RX && (v = zsrint(b, zc)) != 0) {
1.1  glass 				b->cs_rbuf[i++ & ZLRB_RING_MASK] = v;
1.1  glass 				intflags |= 1;
1.1  glass 			}
1.1  glass 			if (rr3 & ZSRR3_IP_B_TX && (v = zsxint(b, zc)) != 0) {
1.1  glass 				b->cs_rbuf[i++ & ZLRB_RING_MASK] = v;
1.1  glass 				intflags |= 1;
1.1  glass 			}
1.1  glass 			if (rr3 & ZSRR3_IP_B_STAT && (v = zssint(b, zc)) != 0) {
1.1  glass 				b->cs_rbuf[i++ & ZLRB_RING_MASK] = v;
1.1  glass 				intflags |= 1;
1.1  glass 			}
1.1  glass 			b->cs_rbput = i;
1.1  glass 		}
1.1  glass 	}
1.1  glass #undef b
1.1  glass 	if (intflags & 1) {
1.2  glass 	    isr_soft_request(ZSSOFT_PRI);
1.1  glass 	}
1.1  glass 	return (intflags & 2);
1.1  glass }
1.1  glass
1.1  glass static int
1.1  glass zsrint(register struct zs_chanstate *cs, register volatile struct zschan *zc)
1.1  glass {
1.1  glass 	register int c = zc->zc_data;
1.1  glass
1.1  glass 	if (cs->cs_conk) {
1.1  glass 		register struct conk_state *conk = &zsconk_state;
1.1  glass
1.1  glass 		/*
1.1  glass 		 * Check here for console abort function, so that we
1.1  glass 		 * can abort even when interrupts are locking up the
1.1  glass 		 * machine.
1.1  glass 		 */
1.1  glass 		if (c == KBD_RESET) {
1.1  glass 			conk->conk_id = 1;	/* ignore next byte */
1.1  glass 			conk->conk_l1 = 0;
1.1  glass 		} else if (conk->conk_id)
1.1  glass 			conk->conk_id = 0;	/* stop ignoring bytes */
1.1  glass 		else if (c == KBD_L1)
1.1  glass 			conk->conk_l1 = 1;	/* L1 went down */
1.1  glass 		else if (c == (KBD_L1|KBD_UP))
1.1  glass 			conk->conk_l1 = 0;	/* L1 went up */
1.1  glass 		else if (c == KBD_A && conk->conk_l1) {
1.1  glass 			zsabort();
1.1  glass 			conk->conk_l1 = 0;	/* we never see the up */
1.1  glass 			goto clearit;		/* eat the A after L1-A */
1.1  glass 		}
1.1  glass 	}
1.1  glass #ifdef KGDB
1.1  glass 	if (c == FRAME_START && cs->cs_kgdb &&
1.1  glass 	    (cs->cs_ttyp->t_state & TS_ISOPEN) == 0) {
1.1  glass 		zskgdb(cs->cs_unit);
1.1  glass 		goto clearit;
1.1  glass 	}
1.1  glass #endif
1.1  glass 	/* compose receive character and status */
1.1  glass 	c <<= 8;
1.1  glass 	c |= ZS_READ(zc, 1);
1.1  glass
1.1  glass 	/* clear receive error & interrupt condition */
1.1  glass 	zc->zc_csr = ZSWR0_RESET_ERRORS;
1.1  glass 	zc->zc_csr = ZSWR0_CLR_INTR;
1.1  glass
1.1  glass 	return (ZRING_MAKE(ZRING_RINT, c));
1.1  glass
1.1  glass clearit:
1.1  glass 	zc->zc_csr = ZSWR0_RESET_ERRORS;
1.1  glass 	zc->zc_csr = ZSWR0_CLR_INTR;
1.1  glass 	return (0);
1.1  glass }
1.1  glass
1.1  glass static int
1.1  glass zsxint(register struct zs_chanstate *cs, register volatile struct zschan *zc)
1.1  glass {
1.1  glass 	register int i = cs->cs_tbc;
1.1  glass
1.1  glass 	if (i == 0) {
1.1  glass 		zc->zc_csr = ZSWR0_RESET_TXINT;
1.1  glass 		zc->zc_csr = ZSWR0_CLR_INTR;
1.1  glass 		return (ZRING_MAKE(ZRING_XINT, 0));
1.1  glass 	}
1.1  glass 	cs->cs_tbc = i - 1;
1.1  glass 	zc->zc_data = *cs->cs_tba++;
1.1  glass 	zc->zc_csr = ZSWR0_CLR_INTR;
1.1  glass 	return (0);
1.1  glass }
1.1  glass
1.1  glass static int
1.1  glass zssint(register struct zs_chanstate *cs, register volatile struct zschan *zc)
1.1  glass {
1.1  glass 	register int rr0;
1.1  glass
1.1  glass 	rr0 = zc->zc_csr;
1.1  glass 	zc->zc_csr = ZSWR0_RESET_STATUS;
1.1  glass 	zc->zc_csr = ZSWR0_CLR_INTR;
1.1  glass 	/*
1.1  glass 	 * The chip's hardware flow control is, as noted in zsreg.h,
1.1  glass 	 * busted---if the DCD line goes low the chip shuts off the
1.1  glass 	 * receiver (!).  If we want hardware CTS flow control but do
1.1  glass 	 * not have it, and carrier is now on, turn HFC on; if we have
1.1  glass 	 * HFC now but carrier has gone low, turn it off.
1.1  glass 	 */
1.1  glass 	if (rr0 & ZSRR0_DCD) {
1.1  glass 		if (cs->cs_ttyp->t_cflag & CCTS_OFLOW &&
1.1  glass 		    (cs->cs_creg[3] & ZSWR3_HFC) == 0) {
1.1  glass 			cs->cs_creg[3] |= ZSWR3_HFC;
1.1  glass 			ZS_WRITE(zc, 3, cs->cs_creg[3]);
1.1  glass 		}
1.1  glass 	} else {
1.1  glass 		if (cs->cs_creg[3] & ZSWR3_HFC) {
1.1  glass 			cs->cs_creg[3] &= ~ZSWR3_HFC;
1.1  glass 			ZS_WRITE(zc, 3, cs->cs_creg[3]);
1.1  glass 		}
1.1  glass 	}
1.1  glass 	if ((rr0 & ZSRR0_BREAK) && cs->cs_brkabort) {
1.3    gwr 		/* Wait for end of break to avoid PROM abort. */
1.3    gwr 		while (zc->zc_csr & ZSRR0_BREAK)
1.3    gwr 			ZS_DELAY();
1.1  glass 		zsabort();
1.1  glass 		return (0);
1.1  glass 	}
1.1  glass 	return (ZRING_MAKE(ZRING_SINT, rr0));
1.1  glass }
1.1  glass
1.1  glass zsabort()
1.1  glass {
1.3    gwr #ifdef DDB
1.3    gwr 	Debugger();
1.3    gwr #else
1.1  glass 	printf("stopping on keyboard abort\n");
1.3    gwr 	sun3_rom_abort();
1.3    gwr #endif
1.1  glass }
1.1  glass
1.1  glass #ifdef KGDB
1.1  glass /*
1.1  glass  * KGDB framing character received: enter kernel debugger.  This probably
1.1  glass  * should time out after a few seconds to avoid hanging on spurious input.
1.1  glass  */
1.1  glass zskgdb(int unit)
1.1  glass {
1.1  glass
1.1  glass 	printf("zs%d%c: kgdb interrupt\n", unit >> 1, (unit & 1) + 'a');
1.1  glass 	kgdb_connect(1);
1.1  glass }
1.1  glass #endif
1.1  glass
1.1  glass /*
1.1  glass  * Print out a ring or fifo overrun error message.
1.1  glass  */
1.1  glass static void
1.1  glass zsoverrun(int unit, long *ptime, char *what)
1.1  glass {
1.1  glass
1.1  glass 	if (*ptime != time.tv_sec) {
1.1  glass 		*ptime = time.tv_sec;
1.1  glass 		log(LOG_WARNING, "zs%d%c: %s overrun\n", unit >> 1,
1.1  glass 		    (unit & 1) + 'a', what);
1.1  glass 	}
1.1  glass }
1.1  glass
1.1  glass /*
1.1  glass  * ZS software interrupt.  Scan all channels for deferred interrupts.
1.1  glass  */
1.1  glass int
1.1  glass zssoft(int arg)
1.1  glass {
1.1  glass 	register struct zs_chanstate *cs;
1.1  glass 	register volatile struct zschan *zc;
1.1  glass 	register struct linesw *line;
1.1  glass 	register struct tty *tp;
1.1  glass 	register int get, n, c, cc, unit, s;
1.1  glass
1.2  glass 	isr_soft_clear(ZSSOFT_PRI);
1.2  glass
1.1  glass 	for (cs = zslist; cs != NULL; cs = cs->cs_next) {
1.1  glass 		get = cs->cs_rbget;
1.1  glass again:
1.1  glass 		n = cs->cs_rbput;	/* atomic */
1.1  glass 		if (get == n)		/* nothing more on this line */
1.1  glass 			continue;
1.1  glass 		unit = cs->cs_unit;	/* set up to handle interrupts */
1.1  glass 		zc = cs->cs_zc;
1.1  glass 		tp = cs->cs_ttyp;
1.1  glass 		line = &linesw[tp->t_line];
1.1  glass 		/*
1.1  glass 		 * Compute the number of interrupts in the receive ring.
1.1  glass 		 * If the count is overlarge, we lost some events, and
1.1  glass 		 * must advance to the first valid one.  It may get
1.1  glass 		 * overwritten if more data are arriving, but this is
1.1  glass 		 * too expensive to check and gains nothing (we already
1.1  glass 		 * lost out; all we can do at this point is trade one
1.1  glass 		 * kind of loss for another).
1.1  glass 		 */
1.1  glass 		n -= get;
1.1  glass 		if (n > ZLRB_RING_SIZE) {
1.1  glass 			zsoverrun(unit, &cs->cs_rotime, "ring");
1.1  glass 			get += n - ZLRB_RING_SIZE;
1.1  glass 			n = ZLRB_RING_SIZE;
1.1  glass 		}
1.1  glass 		while (--n >= 0) {
1.1  glass 			/* race to keep ahead of incoming interrupts */
1.1  glass 			c = cs->cs_rbuf[get++ & ZLRB_RING_MASK];
1.1  glass 			switch (ZRING_TYPE(c)) {
1.1  glass
1.1  glass 			case ZRING_RINT:
1.1  glass 				c = ZRING_VALUE(c);
1.1  glass 				if (c & ZSRR1_DO)
1.1  glass 					zsoverrun(unit, &cs->cs_fotime, "fifo");
1.1  glass 				cc = c >> 8;
1.1  glass 				if (c & ZSRR1_FE)
1.1  glass 					cc |= TTY_FE;
1.1  glass 				if (c & ZSRR1_PE)
1.1  glass 					cc |= TTY_PE;
1.1  glass 				/*
1.1  glass 				 * this should be done through
1.1  glass 				 * bstreams	XXX gag choke
1.1  glass 				 */
1.1  glass 				if (unit == ZS_KBD)
1.1  glass 					kbd_rint(cc);
1.1  glass 				else if (unit == ZS_MOUSE)
1.1  glass 					ms_rint(cc);
1.1  glass 				else
1.1  glass 					line->l_rint(cc, tp);
1.1  glass 				break;
1.1  glass
1.1  glass 			case ZRING_XINT:
1.1  glass 				/*
1.1  glass 				 * Transmit done: change registers and resume,
1.1  glass 				 * or clear BUSY.
1.1  glass 				 */
1.1  glass 				if (cs->cs_heldchange) {
1.1  glass 					s = splzs();
1.1  glass 					c = zc->zc_csr;
1.1  glass 					if ((c & ZSRR0_DCD) == 0)
1.1  glass 						cs->cs_preg[3] &= ~ZSWR3_HFC;
1.1  glass 					bcopy((caddr_t)cs->cs_preg,
1.1  glass 					    (caddr_t)cs->cs_creg, 16);
1.1  glass 					zs_loadchannelregs(zc, cs->cs_creg);
1.1  glass 					splx(s);
1.1  glass 					cs->cs_heldchange = 0;
1.1  glass 					if (cs->cs_heldtbc &&
1.1  glass 					    (tp->t_state & TS_TTSTOP) == 0) {
1.1  glass 						cs->cs_tbc = cs->cs_heldtbc - 1;
1.1  glass 						zc->zc_data = *cs->cs_tba++;
1.1  glass 						goto again;
1.1  glass 					}
1.1  glass 				}
1.1  glass 				tp->t_state &= ~TS_BUSY;
1.1  glass 				if (tp->t_state & TS_FLUSH)
1.1  glass 					tp->t_state &= ~TS_FLUSH;
1.1  glass 				else
1.7  glass 					ndflush(&tp->t_outq, cs->cs_tba -
1.7  glass 						(caddr_t) tp->t_outq.c_cf);
1.1  glass 				line->l_start(tp);
1.1  glass 				break;
1.1  glass
1.1  glass 			case ZRING_SINT:
1.1  glass 				/*
1.1  glass 				 * Status line change.  HFC bit is run in
1.1  glass 				 * hardware interrupt, to avoid locking
1.1  glass 				 * at splzs here.
1.1  glass 				 */
1.1  glass 				c = ZRING_VALUE(c);
1.1  glass 				if ((c ^ cs->cs_rr0) & ZSRR0_DCD) {
1.1  glass 					cc = (c & ZSRR0_DCD) != 0;
1.1  glass 					if (line->l_modem(tp, cc) == 0)
1.1  glass 						zs_modem(cs, cc);
1.1  glass 				}
1.1  glass 				cs->cs_rr0 = c;
1.1  glass 				break;
1.1  glass
1.1  glass 			default:
1.1  glass 				log(LOG_ERR, "zs%d%c: bad ZRING_TYPE (%x)\n",
1.1  glass 				    unit >> 1, (unit & 1) + 'a', c);
1.1  glass 				break;
1.1  glass 			}
1.1  glass 		}
1.1  glass 		cs->cs_rbget = get;
1.1  glass 		goto again;
1.1  glass 	}
1.1  glass 	return (1);
1.1  glass }
1.1  glass
1.1  glass int
1.1  glass zsioctl(dev_t dev, int cmd, caddr_t data, int flag, struct proc *p)
1.1  glass {
1.1  glass 	int unit = minor(dev);
1.1  glass 	struct zsinfo *zi = zscd.cd_devs[unit >> 1];
1.6    gwr 	register struct zs_chanstate *cs = &zi->zi_cs[unit & 1];
1.6    gwr 	register struct tty *tp = cs->cs_ttyp;
1.6    gwr 	register int error, s;
1.1  glass
1.2  glass 	error = linesw[tp->t_line].l_ioctl(tp, cmd, data, flag, p);
1.1  glass 	if (error >= 0)
1.1  glass 		return (error);
1.2  glass 	error = ttioctl(tp, cmd, data, flag, p);
1.1  glass 	if (error >= 0)
1.1  glass 		return (error);
1.1  glass
1.1  glass 	switch (cmd) {
1.1  glass
1.1  glass 	case TIOCSBRK:
1.6    gwr 		{
1.6    gwr 			s = splzs();
1.6    gwr 			cs->cs_preg[5] |= ZSWR5_BREAK;
1.6    gwr 			cs->cs_creg[5] |= ZSWR5_BREAK;
1.6    gwr 			ZS_WRITE(cs->cs_zc, 5, cs->cs_creg[5]);
1.6    gwr 			splx(s);
1.6    gwr 			break;
1.6    gwr 		}
1.1  glass
1.1  glass 	case TIOCCBRK:
1.6    gwr 		{
1.6    gwr 			s = splzs();
1.6    gwr 			cs->cs_preg[5] &= ~ZSWR5_BREAK;
1.6    gwr 			cs->cs_creg[5] &= ~ZSWR5_BREAK;
1.6    gwr 			ZS_WRITE(cs->cs_zc, 5, cs->cs_creg[5]);
1.6    gwr 			splx(s);
1.6    gwr 			break;
1.6    gwr 		}
1.1  glass
1.1  glass 	case TIOCSDTR:
1.1  glass
1.1  glass 	case TIOCCDTR:
1.1  glass
1.1  glass 	case TIOCMSET:
1.1  glass
1.1  glass 	case TIOCMBIS:
1.1  glass
1.1  glass 	case TIOCMBIC:
1.1  glass
1.1  glass 	case TIOCMGET:
1.1  glass
1.1  glass 	default:
1.1  glass 		return (ENOTTY);
1.1  glass 	}
1.1  glass 	return (0);
1.1  glass }
1.1  glass
1.1  glass /*
1.1  glass  * Start or restart transmission.
1.1  glass  */
1.1  glass static void
1.1  glass zsstart(register struct tty *tp)
1.1  glass {
1.1  glass 	register struct zs_chanstate *cs;
1.1  glass 	register int s, nch;
1.1  glass 	int unit = minor(tp->t_dev);
1.1  glass 	struct zsinfo *zi = zscd.cd_devs[unit >> 1];
1.1  glass
1.1  glass 	cs = &zi->zi_cs[unit & 1];
1.1  glass 	s = spltty();
1.1  glass
1.1  glass 	/*
1.1  glass 	 * If currently active or delaying, no need to do anything.
1.1  glass 	 */
1.1  glass 	if (tp->t_state & (TS_TIMEOUT | TS_BUSY | TS_TTSTOP))
1.1  glass 		goto out;
1.1  glass
1.1  glass 	/*
1.1  glass 	 * If there are sleepers, and output has drained below low
1.1  glass 	 * water mark, awaken.
1.1  glass 	 */
1.1  glass 	if (tp->t_outq.c_cc <= tp->t_lowat) {
1.1  glass 		if (tp->t_state & TS_ASLEEP) {
1.1  glass 			tp->t_state &= ~TS_ASLEEP;
1.1  glass 			wakeup((caddr_t)&tp->t_outq);
1.1  glass 		}
1.1  glass 		selwakeup(&tp->t_wsel);
1.1  glass 	}
1.1  glass
1.1  glass 	nch = ndqb(&tp->t_outq, 0);	/* XXX */
1.1  glass 	if (nch) {
1.1  glass 		register char *p = tp->t_outq.c_cf;
1.1  glass
1.1  glass 		/* mark busy, enable tx done interrupts, & send first byte */
1.1  glass 		tp->t_state |= TS_BUSY;
1.1  glass 		(void) splzs();
1.1  glass 		cs->cs_preg[1] |= ZSWR1_TIE;
1.1  glass 		cs->cs_creg[1] |= ZSWR1_TIE;
1.1  glass 		ZS_WRITE(cs->cs_zc, 1, cs->cs_creg[1]);
1.1  glass 		cs->cs_zc->zc_data = *p;
1.1  glass 		cs->cs_tba = p + 1;
1.1  glass 		cs->cs_tbc = nch - 1;
1.1  glass 	} else {
1.1  glass 		/*
1.1  glass 		 * Nothing to send, turn off transmit done interrupts.
1.1  glass 		 * This is useful if something is doing polled output.
1.1  glass 		 */
1.1  glass 		(void) splzs();
1.1  glass 		cs->cs_preg[1] &= ~ZSWR1_TIE;
1.1  glass 		cs->cs_creg[1] &= ~ZSWR1_TIE;
1.1  glass 		ZS_WRITE(cs->cs_zc, 1, cs->cs_creg[1]);
1.1  glass 	}
1.1  glass out:
1.1  glass 	splx(s);
1.1  glass }
1.1  glass
1.1  glass /*
1.1  glass  * Stop output, e.g., for ^S or output flush.
1.1  glass  */
1.1  glass void
1.1  glass zsstop(register struct tty *tp, int flag)
1.1  glass {
1.1  glass 	register struct zs_chanstate *cs;
1.1  glass 	register int s, unit = minor(tp->t_dev);
1.1  glass 	struct zsinfo *zi = zscd.cd_devs[unit >> 1];
1.1  glass
1.1  glass 	cs = &zi->zi_cs[unit & 1];
1.1  glass 	s = splzs();
1.1  glass 	if (tp->t_state & TS_BUSY) {
1.1  glass 		/*
1.1  glass 		 * Device is transmitting; must stop it.
1.1  glass 		 */
1.1  glass 		cs->cs_tbc = 0;
1.1  glass 		if ((tp->t_state & TS_TTSTOP) == 0)
1.1  glass 			tp->t_state |= TS_FLUSH;
1.1  glass 	}
1.1  glass 	splx(s);
1.1  glass }
1.1  glass
1.1  glass /*
1.1  glass  * Set ZS tty parameters from termios.
1.1  glass  *
1.1  glass  * This routine makes use of the fact that only registers
1.1  glass  * 1, 3, 4, 5, 9, 10, 11, 12, 13, 14, and 15 are written.
1.1  glass  */
1.1  glass static int
1.1  glass zsparam(register struct tty *tp, register struct termios *t)
1.1  glass {
1.1  glass 	int unit = minor(tp->t_dev);
1.1  glass 	struct zsinfo *zi = zscd.cd_devs[unit >> 1];
1.1  glass 	register struct zs_chanstate *cs = &zi->zi_cs[unit & 1];
1.1  glass 	register int tmp, tmp5, cflag, s;
1.1  glass
1.1  glass 	/*
1.1  glass 	 * Because PCLK is only run at 4.9 MHz, the fastest we
1.1  glass 	 * can go is 51200 baud (this corresponds to TC=1).
1.1  glass 	 * This is somewhat unfortunate as there is no real
1.1  glass 	 * reason we should not be able to handle higher rates.
1.1  glass 	 */
1.1  glass 	tmp = t->c_ospeed;
1.1  glass 	if (tmp < 0 || (t->c_ispeed && t->c_ispeed != tmp))
1.1  glass 		return (EINVAL);
1.1  glass 	if (tmp == 0) {
1.1  glass 		/* stty 0 => drop DTR and RTS */
1.1  glass 		zs_modem(cs, 0);
1.1  glass 		return (0);
1.1  glass 	}
1.1  glass 	tmp = BPS_TO_TCONST(PCLK / 16, tmp);
1.1  glass 	if (tmp < 2)
1.1  glass 		return (EINVAL);
1.1  glass
1.1  glass 	cflag = t->c_cflag;
1.1  glass 	tp->t_ispeed = tp->t_ospeed = TCONST_TO_BPS(PCLK / 16, tmp);
1.1  glass 	tp->t_cflag = cflag;
1.1  glass
1.1  glass 	/*
1.1  glass 	 * Block interrupts so that state will not
1.1  glass 	 * be altered until we are done setting it up.
1.1  glass 	 */
1.1  glass 	s = splzs();
1.1  glass 	cs->cs_preg[12] = tmp;
1.1  glass 	cs->cs_preg[13] = tmp >> 8;
1.1  glass 	cs->cs_preg[1] = ZSWR1_RIE | ZSWR1_TIE | ZSWR1_SIE;
1.1  glass 	switch (cflag & CSIZE) {
1.1  glass 	case CS5:
1.1  glass 		tmp = ZSWR3_RX_5;
1.1  glass 		tmp5 = ZSWR5_TX_5;
1.1  glass 		break;
1.1  glass 	case CS6:
1.1  glass 		tmp = ZSWR3_RX_6;
1.1  glass 		tmp5 = ZSWR5_TX_6;
1.1  glass 		break;
1.1  glass 	case CS7:
1.1  glass 		tmp = ZSWR3_RX_7;
1.1  glass 		tmp5 = ZSWR5_TX_7;
1.1  glass 		break;
1.1  glass 	case CS8:
1.1  glass 	default:
1.1  glass 		tmp = ZSWR3_RX_8;
1.1  glass 		tmp5 = ZSWR5_TX_8;
1.1  glass 		break;
1.1  glass 	}
1.1  glass
1.1  glass 	/*
1.1  glass 	 * Output hardware flow control on the chip is horrendous: if
1.1  glass 	 * carrier detect drops, the receiver is disabled.  Hence we
1.1  glass 	 * can only do this when the carrier is on.
1.1  glass 	 */
1.1  glass 	if (cflag & CCTS_OFLOW && cs->cs_zc->zc_csr & ZSRR0_DCD)
1.1  glass 		tmp |= ZSWR3_HFC | ZSWR3_RX_ENABLE;
1.1  glass 	else
1.1  glass 		tmp |= ZSWR3_RX_ENABLE;
1.1  glass 	cs->cs_preg[3] = tmp;
1.1  glass 	cs->cs_preg[5] = tmp5 | ZSWR5_TX_ENABLE | ZSWR5_DTR | ZSWR5_RTS;
1.1  glass
1.1  glass 	tmp = ZSWR4_CLK_X16 | (cflag & CSTOPB ? ZSWR4_TWOSB : ZSWR4_ONESB);
1.1  glass 	if ((cflag & PARODD) == 0)
1.1  glass 		tmp |= ZSWR4_EVENP;
1.1  glass 	if (cflag & PARENB)
1.1  glass 		tmp |= ZSWR4_PARENB;
1.1  glass 	cs->cs_preg[4] = tmp;
1.1  glass 	cs->cs_preg[9] = ZSWR9_MASTER_IE | ZSWR9_NO_VECTOR;
1.1  glass 	cs->cs_preg[10] = ZSWR10_NRZ;
1.1  glass 	cs->cs_preg[11] = ZSWR11_TXCLK_BAUD | ZSWR11_RXCLK_BAUD;
1.1  glass 	cs->cs_preg[14] = ZSWR14_BAUD_FROM_PCLK | ZSWR14_BAUD_ENA;
1.1  glass 	cs->cs_preg[15] = ZSWR15_BREAK_IE | ZSWR15_DCD_IE;
1.1  glass
1.1  glass 	/*
1.1  glass 	 * If nothing is being transmitted, set up new current values,
1.1  glass 	 * else mark them as pending.
1.1  glass 	 */
1.1  glass 	if (cs->cs_heldchange == 0) {
1.1  glass 		if (cs->cs_ttyp->t_state & TS_BUSY) {
1.1  glass 			cs->cs_heldtbc = cs->cs_tbc;
1.1  glass 			cs->cs_tbc = 0;
1.1  glass 			cs->cs_heldchange = 1;
1.1  glass 		} else {
1.1  glass 			bcopy((caddr_t)cs->cs_preg, (caddr_t)cs->cs_creg, 16);
1.1  glass 			zs_loadchannelregs(cs->cs_zc, cs->cs_creg);
1.1  glass 		}
1.1  glass 	}
1.1  glass 	splx(s);
1.1  glass 	return (0);
1.1  glass }
1.1  glass
1.1  glass /*
1.1  glass  * Raise or lower modem control (DTR/RTS) signals.  If a character is
1.1  glass  * in transmission, the change is deferred.
1.1  glass  */
1.1  glass static void
1.1  glass zs_modem(struct zs_chanstate *cs, int onoff)
1.1  glass {
1.1  glass 	int s, bis, and;
1.1  glass
1.1  glass 	if (onoff) {
1.1  glass 		bis = ZSWR5_DTR | ZSWR5_RTS;
1.1  glass 		and = ~0;
1.1  glass 	} else {
1.1  glass 		bis = 0;
1.1  glass 		and = ~(ZSWR5_DTR | ZSWR5_RTS);
1.1  glass 	}
1.1  glass 	s = splzs();
1.1  glass 	cs->cs_preg[5] = (cs->cs_preg[5] | bis) & and;
1.1  glass 	if (cs->cs_heldchange == 0) {
1.1  glass 		if (cs->cs_ttyp->t_state & TS_BUSY) {
1.1  glass 			cs->cs_heldtbc = cs->cs_tbc;
1.1  glass 			cs->cs_tbc = 0;
1.1  glass 			cs->cs_heldchange = 1;
1.1  glass 		} else {
1.1  glass 			cs->cs_creg[5] = (cs->cs_creg[5] | bis) & and;
1.1  glass 			ZS_WRITE(cs->cs_zc, 5, cs->cs_creg[5]);
1.1  glass 		}
1.1  glass 	}
1.1  glass 	splx(s);
1.1  glass }
1.1  glass
1.1  glass /*
1.1  glass  * Write the given register set to the given zs channel in the proper order.
1.1  glass  * The channel must not be transmitting at the time.  The receiver will
1.1  glass  * be disabled for the time it takes to write all the registers.
1.1  glass  */
1.1  glass static void
1.1  glass zs_loadchannelregs(volatile struct zschan *zc, u_char *reg)
1.1  glass {
1.1  glass 	int i;
1.1  glass
1.1  glass 	zc->zc_csr = ZSM_RESET_ERR;	/* reset error condition */
1.1  glass 	i = zc->zc_data;		/* drain fifo */
1.1  glass 	i = zc->zc_data;
1.1  glass 	i = zc->zc_data;
1.1  glass 	ZS_WRITE(zc, 4, reg[4]);
1.1  glass 	ZS_WRITE(zc, 10, reg[10]);
1.1  glass 	ZS_WRITE(zc, 3, reg[3] & ~ZSWR3_RX_ENABLE);
1.1  glass 	ZS_WRITE(zc, 5, reg[5] & ~ZSWR5_TX_ENABLE);
1.1  glass 	ZS_WRITE(zc, 1, reg[1]);
1.1  glass 	ZS_WRITE(zc, 9, reg[9]);
1.1  glass 	ZS_WRITE(zc, 11, reg[11]);
1.1  glass 	ZS_WRITE(zc, 12, reg[12]);
1.1  glass 	ZS_WRITE(zc, 13, reg[13]);
1.1  glass 	ZS_WRITE(zc, 14, reg[14]);
1.1  glass 	ZS_WRITE(zc, 15, reg[15]);
1.1  glass 	ZS_WRITE(zc, 3, reg[3]);
1.1  glass 	ZS_WRITE(zc, 5, reg[5]);
1.1  glass }
1.1  glass
1.2  glass static u_char
1.2  glass zs_read(zc, reg)
1.2  glass 	volatile struct zschan *zc;
1.2  glass 	u_char reg;
1.2  glass {
1.2  glass 	u_char val;
1.2  glass
1.2  glass 	zc->zc_csr = reg;
1.3    gwr 	ZS_DELAY();
1.2  glass 	val = zc->zc_csr;
1.3    gwr 	ZS_DELAY();
1.2  glass 	return val;
1.2  glass }
1.2  glass
1.2  glass static u_char
1.2  glass zs_write(zc, reg, val)
1.2  glass 	volatile struct zschan *zc;
1.2  glass 	u_char reg, val;
1.2  glass {
1.2  glass 	zc->zc_csr = reg;
1.3    gwr 	ZS_DELAY();
1.2  glass 	zc->zc_csr = val;
1.3    gwr 	ZS_DELAY();
1.2  glass 	return val;
1.2  glass }
1.2  glass
1.1  glass #ifdef KGDB
1.1  glass /*
1.1  glass  * Get a character from the given kgdb channel.  Called at splhigh().
1.9    gwr  * XXX - Add delays, or combine with zscngetc()...
1.1  glass  */
1.1  glass static int
1.1  glass zs_kgdb_getc(void *arg)
1.1  glass {
1.1  glass 	register volatile struct zschan *zc = (volatile struct zschan *)arg;
1.1  glass
1.1  glass 	while ((zc->zc_csr & ZSRR0_RX_READY) == 0)
1.1  glass 		continue;
1.1  glass 	return (zc->zc_data);
1.1  glass }
1.1  glass
1.1  glass /*
1.1  glass  * Put a character to the given kgdb channel.  Called at splhigh().
1.1  glass  */
1.1  glass static void
1.1  glass zs_kgdb_putc(void *arg, int c)
1.1  glass {
1.1  glass 	register volatile struct zschan *zc = (volatile struct zschan *)arg;
1.1  glass
1.1  glass 	while ((zc->zc_csr & ZSRR0_TX_READY) == 0)
1.1  glass 		continue;
1.1  glass 	zc->zc_data = c;
1.1  glass }
1.1  glass
1.1  glass /*
1.1  glass  * Set up for kgdb; called at boot time before configuration.
1.1  glass  * KGDB interrupts will be enabled later when zs0 is configured.
1.1  glass  */
1.1  glass void
1.1  glass zs_kgdb_init()
1.1  glass {
1.1  glass 	volatile struct zsdevice *addr;
1.1  glass 	volatile struct zschan *zc;
1.1  glass 	int unit, zs;
1.1  glass
1.1  glass 	if (major(kgdb_dev) != ZSMAJOR)
1.1  glass 		return;
1.1  glass 	unit = minor(kgdb_dev);
1.1  glass 	/*
1.1  glass 	 * Unit must be 0 or 1 (zs0).
1.1  glass 	 */
1.1  glass 	if ((unsigned)unit >= ZS_KBD) {
1.1  glass 		printf("zs_kgdb_init: bad minor dev %d\n", unit);
1.1  glass 		return;
1.1  glass 	}
1.1  glass 	zs = unit >> 1;
1.1  glass 	unit &= 1;
1.9    gwr
1.9    gwr 	if (zsaddr[0] == NULL)
1.3    gwr 		panic("kbdb_attach: zs0 not yet mapped");
1.9    gwr 	addr = zsaddr[0];
1.3    gwr
1.1  glass 	zc = unit == 0 ? &addr->zs_chan[CHAN_A] : &addr->zs_chan[CHAN_B];
1.1  glass 	zs_kgdb_savedspeed = zs_getspeed(zc);
1.1  glass 	printf("zs_kgdb_init: attaching zs%d%c at %d baud\n",
1.1  glass 	    zs, unit + 'a', kgdb_rate);
1.1  glass 	zs_reset(zc, 1, kgdb_rate);
1.1  glass 	kgdb_attach(zs_kgdb_getc, zs_kgdb_putc, (void *)zc);
1.1  glass }
1.1  glass #endif /* KGDB */