hp300/dev/ct.c

1.1  cgd /*
1.1  cgd  * Copyright (c) 1982, 1990 The Regents of the University of California.
1.1  cgd  * All rights reserved.
1.1  cgd  *
1.1  cgd  * Redistribution and use in source and binary forms, with or without
1.1  cgd  * modification, are permitted provided that the following conditions
1.1  cgd  * are met:
1.1  cgd  * 1. Redistributions of source code must retain the above copyright
1.1  cgd  *    notice, this list of conditions and the following disclaimer.
1.1  cgd  * 2. Redistributions in binary form must reproduce the above copyright
1.1  cgd  *    notice, this list of conditions and the following disclaimer in the
1.1  cgd  *    documentation and/or other materials provided with the distribution.
1.1  cgd  * 3. All advertising materials mentioning features or use of this software
1.1  cgd  *    must display the following acknowledgement:
1.1  cgd  *	This product includes software developed by the University of
1.1  cgd  *	California, Berkeley and its contributors.
1.1  cgd  * 4. Neither the name of the University nor the names of its contributors
1.1  cgd  *    may be used to endorse or promote products derived from this software
1.1  cgd  *    without specific prior written permission.
1.1  cgd  *
1.1  cgd  * THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS ``AS IS'' AND
1.1  cgd  * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
1.1  cgd  * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
1.1  cgd  * ARE DISCLAIMED.  IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE
1.1  cgd  * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
1.1  cgd  * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
1.1  cgd  * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
1.1  cgd  * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
1.1  cgd  * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
1.1  cgd  * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
1.1  cgd  * SUCH DAMAGE.
1.1  cgd  *
1.1  cgd  *	@(#)ct.c	7.3 (Berkeley) 5/4/91
1.1  cgd  */
1.1  cgd
1.1  cgd #include "ct.h"
1.1  cgd #if NCT > 0
1.1  cgd /*
1.1  cgd  * CS80 cartridge tape driver (9144, 88140, 9145)
1.1  cgd  *
1.1  cgd  * Reminder:
1.1  cgd  *	C_CC bit (character count option) when used in the CS/80 command
1.1  cgd  *	'set options' will cause the tape not to stream.
1.1  cgd  *
1.1  cgd  * TODO:
1.1  cgd  *	make filesystem compatible
1.1  cgd  *	make block mode work according to mtio(4) spec. (if possible)
1.1  cgd  *	merge with cs80 disk driver
1.1  cgd  *	finish support of 9145
1.1  cgd  */
1.1  cgd
1.1  cgd #include "param.h"
1.1  cgd #include "buf.h"
1.1  cgd #include "ioctl.h"
1.1  cgd #include "mtio.h"
1.1  cgd #include "tprintf.h"
1.1  cgd #include "proc.h"
1.1  cgd
1.1  cgd #include "ctreg.h"
1.1  cgd #include "device.h"
1.1  cgd
1.1  cgd /* number of eof marks to remember */
1.1  cgd #define EOFS	128
1.1  cgd
1.1  cgd int	ctinit(), ctstart(), ctgo(), ctintr();
1.1  cgd struct	driver ctdriver = {
1.1  cgd 	ctinit, "ct", ctstart, ctgo, ctintr,
1.1  cgd };
1.1  cgd
1.1  cgd struct	ct_softc {
1.1  cgd 	struct	hp_device *sc_hd;
1.1  cgd 	struct	ct_iocmd sc_ioc;
1.1  cgd 	struct	ct_rscmd sc_rsc;
1.1  cgd 	struct	ct_stat sc_stat;
1.1  cgd 	struct	ct_ssmcmd sc_ssmc;
1.1  cgd 	struct	ct_srcmd sc_src;
1.1  cgd 	struct	ct_soptcmd sc_soptc;
1.1  cgd 	struct	ct_ulcmd sc_ul;
1.1  cgd 	struct	ct_wfmcmd sc_wfm;
1.1  cgd 	struct	ct_clearcmd sc_clear;
1.1  cgd 	struct	buf *sc_bp;
1.1  cgd 	int	sc_blkno;
1.1  cgd 	int	sc_cmd;
1.1  cgd 	int	sc_resid;
1.1  cgd 	char	*sc_addr;
1.1  cgd 	int	sc_flags;
1.1  cgd 	short	sc_type;
1.1  cgd 	short	sc_punit;
1.1  cgd 	tpr_t	sc_tpr;
1.1  cgd 	struct	devqueue sc_dq;
1.1  cgd 	int	sc_eofp;
1.1  cgd 	int	sc_eofs[EOFS];
1.1  cgd } ct_softc[NCT];
1.1  cgd
1.1  cgd /* flags */
1.1  cgd #define	CTF_OPEN	0x01
1.1  cgd #define	CTF_ALIVE	0x02
1.1  cgd #define	CTF_WRT		0x04
1.1  cgd #define	CTF_CMD		0x08
1.1  cgd #define	CTF_IO		0x10
1.1  cgd #define	CTF_BEOF	0x20
1.1  cgd #define	CTF_AEOF	0x40
1.1  cgd #define	CTF_EOT		0x80
1.1  cgd #define	CTF_STATWAIT	0x100
1.1  cgd #define CTF_CANSTREAM	0x200
1.1  cgd #define	CTF_WRTTN	0x400
1.1  cgd
1.1  cgd struct	ctinfo {
1.1  cgd 	short	hwid;
1.1  cgd 	short	punit;
1.1  cgd 	char	*desc;
1.1  cgd } ctinfo[] = {
1.1  cgd 	CT7946ID,	1,	"7946A",
1.1  cgd 	CT7912PID,	1,	"7912P",
1.1  cgd 	CT7914PID,	1,	"7914P",
1.1  cgd 	CT9144ID,	0,	"9144",
1.1  cgd 	CT9145ID,	0,	"9145",
1.1  cgd };
1.1  cgd int	nctinfo = sizeof(ctinfo) / sizeof(ctinfo[0]);
1.1  cgd
1.1  cgd struct	buf cttab[NCT];
1.1  cgd struct	buf ctbuf[NCT];
1.1  cgd
1.1  cgd #define	CT_NOREW	4
1.1  cgd #define	CT_STREAM	8
1.1  cgd #define	UNIT(x)		(minor(x) & 3)
1.1  cgd #define	ctpunit(x)	((x) & 7)
1.1  cgd
1.1  cgd #ifdef DEBUG
1.1  cgd int ctdebug = 0;
1.1  cgd #define CDB_FILES	0x01
1.1  cgd #define CT_BSF		0x02
1.1  cgd #endif
1.1  cgd
1.1  cgd ctinit(hd)
1.1  cgd 	register struct hp_device *hd;
1.1  cgd {
1.1  cgd 	register struct ct_softc *sc = &ct_softc[hd->hp_unit];
1.1  cgd
1.1  cgd 	sc->sc_hd = hd;
1.1  cgd 	sc->sc_punit = ctpunit(hd->hp_flags);
1.1  cgd 	if (ctident(sc, hd) < 0)
1.1  cgd 		return(0);
1.1  cgd 	ctreset(sc, hd);
1.1  cgd 	sc->sc_dq.dq_ctlr = hd->hp_ctlr;
1.1  cgd 	sc->sc_dq.dq_unit = hd->hp_unit;
1.1  cgd 	sc->sc_dq.dq_slave = hd->hp_slave;
1.1  cgd 	sc->sc_dq.dq_driver = &ctdriver;
1.1  cgd 	sc->sc_flags |= CTF_ALIVE;
1.1  cgd 	return(1);
1.1  cgd }
1.1  cgd
1.1  cgd ctident(sc, hd)
1.1  cgd 	register struct ct_softc *sc;
1.1  cgd 	register struct hp_device *hd;
1.1  cgd {
1.1  cgd 	struct ct_describe desc;
1.1  cgd 	u_char stat, cmd[3];
1.1  cgd 	char name[7];
1.1  cgd 	int id, i;
1.1  cgd
1.1  cgd 	/*
1.1  cgd 	 * Read device id and verify that:
1.1  cgd 	 * 1. It is a CS80 device
1.1  cgd 	 * 2. It is one of our recognized tape devices
1.1  cgd 	 * 3. It has the proper physical unit number
1.1  cgd 	 */
1.1  cgd 	id = hpibid(hd->hp_ctlr, hd->hp_slave);
1.1  cgd 	if ((id & 0x200) == 0)
1.1  cgd 		return(-1);
1.1  cgd 	for (i = 0; i < nctinfo; i++)
1.1  cgd 		if (id == ctinfo[i].hwid)
1.1  cgd 			break;
1.1  cgd 	if (i == nctinfo || sc->sc_punit != ctinfo[i].punit)
1.1  cgd 		return(-1);
1.1  cgd 	id = i;
1.1  cgd
1.1  cgd 	/*
1.1  cgd 	 * Collect device description.
1.1  cgd 	 * Right now we only need this to differentiate 7945 from 7946.
1.1  cgd 	 * Note that we always issue the describe command to unit 0.
1.1  cgd 	 */
1.1  cgd 	cmd[0] = C_SUNIT(0);
1.1  cgd 	cmd[1] = C_SVOL(0);
1.1  cgd 	cmd[2] = C_DESC;
1.1  cgd 	hpibsend(hd->hp_ctlr, hd->hp_slave, C_CMD, cmd, sizeof(cmd));
1.1  cgd 	hpibrecv(hd->hp_ctlr, hd->hp_slave, C_EXEC, &desc, 37);
1.1  cgd 	hpibrecv(hd->hp_ctlr, hd->hp_slave, C_QSTAT, &stat, sizeof(stat));
1.1  cgd 	bzero(name, sizeof(name));
1.1  cgd 	if (!stat) {
1.1  cgd 		register int n = desc.d_name;
1.1  cgd 		for (i = 5; i >= 0; i--) {
1.1  cgd 			name[i] = (n & 0xf) + '0';
1.1  cgd 			n >>= 4;
1.1  cgd 		}
1.1  cgd 	}
1.1  cgd 	switch (ctinfo[id].hwid) {
1.1  cgd 	case CT7946ID:
1.1  cgd 		if (bcmp(name, "079450", 6) == 0)
1.1  cgd 			return(-1);		/* not really a 7946 */
1.1  cgd 		/* fall into... */
1.1  cgd 	case CT9144ID:
1.1  cgd 	case CT9145ID:
1.1  cgd 		sc->sc_type = CT9144;
1.1  cgd 		sc->sc_flags |= CTF_CANSTREAM;
1.1  cgd 		break;
1.1  cgd
1.1  cgd 	case CT7912PID:
1.1  cgd 	case CT7914PID:
1.1  cgd 		sc->sc_type = CT88140;
1.1  cgd 		break;
1.1  cgd 	}
1.1  cgd 	printf("ct%d: %s %stape\n", hd->hp_unit, ctinfo[id].desc,
1.1  cgd 	       (sc->sc_flags & CTF_CANSTREAM) ? "streaming " : " ");
1.1  cgd 	return(id);
1.1  cgd }
1.1  cgd
1.1  cgd ctreset(sc, hd)
1.1  cgd 	register struct ct_softc *sc;
1.1  cgd 	register struct hp_device *hd;
1.1  cgd {
1.1  cgd 	u_char stat;
1.1  cgd
1.1  cgd 	sc->sc_clear.unit = C_SUNIT(sc->sc_punit);
1.1  cgd 	sc->sc_clear.cmd = C_CLEAR;
1.1  cgd 	hpibsend(hd->hp_ctlr, hd->hp_slave, C_TCMD, &sc->sc_clear,
1.1  cgd 		sizeof(sc->sc_clear));
1.1  cgd 	hpibswait(hd->hp_ctlr, hd->hp_slave);
1.1  cgd 	hpibrecv(hd->hp_ctlr, hd->hp_slave, C_QSTAT, &stat, sizeof(stat));
1.1  cgd 	sc->sc_src.unit = C_SUNIT(CTCTLR);
1.1  cgd 	sc->sc_src.nop = C_NOP;
1.1  cgd 	sc->sc_src.cmd = C_SREL;
1.1  cgd 	sc->sc_src.param = C_REL;
1.1  cgd 	hpibsend(hd->hp_ctlr, hd->hp_slave, C_CMD, &sc->sc_src,
1.1  cgd 		sizeof(sc->sc_src));
1.1  cgd 	hpibswait(hd->hp_ctlr, hd->hp_slave);
1.1  cgd 	hpibrecv(hd->hp_ctlr, hd->hp_slave, C_QSTAT, &stat, sizeof(stat));
1.1  cgd 	sc->sc_ssmc.unit = C_SUNIT(sc->sc_punit);
1.1  cgd 	sc->sc_ssmc.cmd = C_SSM;
1.1  cgd 	sc->sc_ssmc.refm = REF_MASK;
1.1  cgd 	sc->sc_ssmc.fefm = FEF_MASK;
1.1  cgd 	sc->sc_ssmc.aefm = AEF_MASK;
1.1  cgd 	sc->sc_ssmc.iefm = IEF_MASK;
1.1  cgd 	hpibsend(hd->hp_ctlr, hd->hp_slave, C_CMD, &sc->sc_ssmc,
1.1  cgd 		sizeof(sc->sc_ssmc));
1.1  cgd 	hpibswait(hd->hp_ctlr, hd->hp_slave);
1.1  cgd 	hpibrecv(hd->hp_ctlr, hd->hp_slave, C_QSTAT, &stat, sizeof(stat));
1.1  cgd 	sc->sc_soptc.unit = C_SUNIT(sc->sc_punit);
1.1  cgd 	sc->sc_soptc.nop = C_NOP;
1.1  cgd 	sc->sc_soptc.cmd = C_SOPT;
1.1  cgd 	sc->sc_soptc.opt = C_SPAR;
1.1  cgd 	hpibsend(hd->hp_ctlr, hd->hp_slave, C_CMD, &sc->sc_soptc,
1.1  cgd 		sizeof(sc->sc_soptc));
1.1  cgd 	hpibswait(hd->hp_ctlr, hd->hp_slave);
1.1  cgd 	hpibrecv(hd->hp_ctlr, hd->hp_slave, C_QSTAT, &stat, sizeof(stat));
1.1  cgd }
1.1  cgd
1.1  cgd /*ARGSUSED*/
1.1  cgd ctopen(dev, flag, type, p)
1.1  cgd 	dev_t dev;
1.1  cgd 	int flag, type;
1.1  cgd 	struct proc *p;
1.1  cgd {
1.1  cgd 	register struct ct_softc *sc = &ct_softc[UNIT(dev)];
1.1  cgd 	u_char stat;
1.1  cgd 	int cc;
1.1  cgd
1.1  cgd 	if (UNIT(dev) >= NCT || (sc->sc_flags & CTF_ALIVE) == 0)
1.1  cgd 		return(ENXIO);
1.1  cgd 	if (sc->sc_flags & CTF_OPEN)
1.1  cgd 		return(EBUSY);
1.1  cgd 	sc->sc_soptc.unit = C_SUNIT(sc->sc_punit);
1.1  cgd 	sc->sc_soptc.nop = C_NOP;
1.1  cgd 	sc->sc_soptc.cmd = C_SOPT;
1.1  cgd 	if ((dev & CT_STREAM) && (sc->sc_flags & CTF_CANSTREAM))
1.1  cgd 		sc->sc_soptc.opt = C_SPAR | C_IMRPT;
1.1  cgd 	else
1.1  cgd 		sc->sc_soptc.opt = C_SPAR;
1.1  cgd 	/*
1.1  cgd 	 * Check the return of hpibsend() and hpibswait().
1.1  cgd 	 * Drive could be loading/unloading a tape. If not checked,
1.1  cgd 	 * driver hangs.
1.1  cgd 	 */
1.1  cgd 	cc = hpibsend(sc->sc_hd->hp_ctlr, sc->sc_hd->hp_slave,
1.1  cgd 	              C_CMD, &sc->sc_soptc, sizeof(sc->sc_soptc));
1.1  cgd 	if (cc != sizeof(sc->sc_soptc))
1.1  cgd 		return(EBUSY);
1.1  cgd 	hpibswait(sc->sc_hd->hp_ctlr, sc->sc_hd->hp_slave);
1.1  cgd 	cc = hpibrecv(sc->sc_hd->hp_ctlr, sc->sc_hd->hp_slave, C_QSTAT,
1.1  cgd 	              &stat, sizeof(stat));
1.1  cgd 	if (cc != sizeof(stat))
1.1  cgd 		return(EBUSY);
1.1  cgd 	sc->sc_tpr = tprintf_open(p);
1.1  cgd 	sc->sc_flags |= CTF_OPEN;
1.1  cgd 	return(0);
1.1  cgd }
1.1  cgd
1.1  cgd /*ARGSUSED*/
1.1  cgd ctclose(dev, flag)
1.1  cgd 	dev_t dev;
1.1  cgd {
1.1  cgd 	register struct ct_softc *sc = &ct_softc[UNIT(dev)];
1.1  cgd
1.1  cgd 	if ((sc->sc_flags & (CTF_WRT|CTF_WRTTN)) == (CTF_WRT|CTF_WRTTN) &&
1.1  cgd 	    (sc->sc_flags & CTF_EOT) == 0 ) { /* XXX return error if EOT ?? */
1.1  cgd 		ctcommand(dev, MTWEOF, 2);
1.1  cgd 		ctcommand(dev, MTBSR, 1);
1.1  cgd 		if (sc->sc_eofp == EOFS - 1)
1.1  cgd 			sc->sc_eofs[EOFS - 1]--;
1.1  cgd 		else
1.1  cgd 			sc->sc_eofp--;
1.1  cgd #ifdef DEBUG
1.1  cgd 		if(ctdebug & CT_BSF)
1.1  cgd 			printf("ct%d: ctclose backup eofs prt %d blk %d\n",
1.1  cgd 			       UNIT(dev), sc->sc_eofp, sc->sc_eofs[sc->sc_eofp]);
1.1  cgd #endif
1.1  cgd 	}
1.1  cgd 	if ((minor(dev) & CT_NOREW) == 0)
1.1  cgd 		ctcommand(dev, MTREW, 1);
1.1  cgd 	sc->sc_flags &= ~(CTF_OPEN | CTF_WRT | CTF_WRTTN);
1.1  cgd 	tprintf_close(sc->sc_tpr);
1.1  cgd #ifdef DEBUG
1.1  cgd 	if (ctdebug & CDB_FILES)
1.1  cgd 		printf("ctclose: flags %x\n", sc->sc_flags);
1.1  cgd #endif
1.1  cgd 	return(0);	/* XXX */
1.1  cgd }
1.1  cgd
1.1  cgd ctcommand(dev, cmd, cnt)
1.1  cgd 	dev_t dev;
1.1  cgd 	register int cnt;
1.1  cgd {
1.1  cgd 	register struct ct_softc *sc = &ct_softc[UNIT(dev)];
1.1  cgd 	register struct buf *bp = &ctbuf[UNIT(dev)];
1.1  cgd 	register struct buf *nbp = 0;
1.1  cgd
1.1  cgd 	if (cmd == MTBSF && sc->sc_eofp == EOFS - 1) {
1.1  cgd 		cnt = sc->sc_eofs[EOFS - 1] - cnt;
1.1  cgd 		ctcommand(dev, MTREW, 1);
1.1  cgd 		ctcommand(dev, MTFSF, cnt);
1.1  cgd 		cnt = 2;
1.1  cgd 		cmd = MTBSR;
1.1  cgd 	}
1.1  cgd
1.1  cgd 	if (cmd == MTBSF && sc->sc_eofp - cnt < 0) {
1.1  cgd 		cnt = 1;
1.1  cgd 		cmd = MTREW;
1.1  cgd 	}
1.1  cgd
1.1  cgd 	sc->sc_flags |= CTF_CMD;
1.1  cgd 	sc->sc_bp = bp;
1.1  cgd 	sc->sc_cmd = cmd;
1.1  cgd 	bp->b_dev = dev;
1.1  cgd 	if (cmd == MTFSF) {
1.1  cgd 		nbp = (struct buf *)geteblk(MAXBSIZE);
1.1  cgd 		bp->b_un.b_addr = nbp->b_un.b_addr;
1.1  cgd 		bp->b_bcount = MAXBSIZE;
1.1  cgd 	}
1.1  cgd again:
1.1  cgd 	bp->b_flags = B_BUSY;
1.1  cgd 	if (cmd == MTBSF) {
1.1  cgd 		sc->sc_blkno = sc->sc_eofs[sc->sc_eofp];
1.1  cgd 		sc->sc_eofp--;
1.1  cgd #ifdef DEBUG
1.1  cgd 		if (ctdebug & CT_BSF)
1.1  cgd 			printf("ct%d: backup eof pos %d blk %d\n",
1.1  cgd 			       UNIT(dev), sc->sc_eofp,
1.1  cgd 			       sc->sc_eofs[sc->sc_eofp]);
1.1  cgd #endif
1.1  cgd 	}
1.1  cgd 	ctstrategy(bp);
1.1  cgd 	iowait(bp);
1.1  cgd 	if (--cnt > 0)
1.1  cgd 		goto again;
1.1  cgd 	bp->b_flags = 0;
1.1  cgd 	sc->sc_flags &= ~CTF_CMD;
1.1  cgd 	if (nbp)
1.1  cgd 		brelse(nbp);
1.1  cgd }
1.1  cgd
1.1  cgd ctstrategy(bp)
1.1  cgd 	register struct buf *bp;
1.1  cgd {
1.1  cgd 	register struct buf *dp;
1.1  cgd 	register int s, unit;
1.1  cgd
1.1  cgd 	unit = UNIT(bp->b_dev);
1.1  cgd 	dp = &cttab[unit];
1.1  cgd 	bp->av_forw = NULL;
1.1  cgd 	s = splbio();
1.1  cgd 	if (dp->b_actf == NULL)
1.1  cgd 		dp->b_actf = bp;
1.1  cgd 	else
1.1  cgd 		dp->b_actl->av_forw = bp;
1.1  cgd 	dp->b_actl = bp;
1.1  cgd 	if (dp->b_active == 0) {
1.1  cgd 		dp->b_active = 1;
1.1  cgd 		ctustart(unit);
1.1  cgd 	}
1.1  cgd 	splx(s);
1.1  cgd }
1.1  cgd
1.1  cgd ctustart(unit)
1.1  cgd 	register int unit;
1.1  cgd {
1.1  cgd 	register struct ct_softc *sc = &ct_softc[unit];
1.1  cgd 	register struct buf *bp;
1.1  cgd
1.1  cgd 	bp = cttab[unit].b_actf;
1.1  cgd 	sc->sc_addr = bp->b_un.b_addr;
1.1  cgd 	sc->sc_resid = bp->b_bcount;
1.1  cgd 	if (hpibreq(&sc->sc_dq))
1.1  cgd 		ctstart(unit);
1.1  cgd }
1.1  cgd
1.1  cgd ctstart(unit)
1.1  cgd 	register int unit;
1.1  cgd {
1.1  cgd 	register struct ct_softc *sc = &ct_softc[unit];
1.1  cgd 	register struct buf *bp;
1.1  cgd 	register int i;
1.1  cgd
1.1  cgd 	bp = cttab[unit].b_actf;
1.1  cgd again:
1.1  cgd 	if ((sc->sc_flags & CTF_CMD) && sc->sc_bp == bp) {
1.1  cgd 		switch(sc->sc_cmd) {
1.1  cgd
1.1  cgd 		case MTFSF:
1.1  cgd 			bp->b_flags |= B_READ;
1.1  cgd 			goto mustio;
1.1  cgd
1.1  cgd 		case MTBSF:
1.1  cgd 			goto gotaddr;
1.1  cgd
1.1  cgd 		case MTOFFL:
1.1  cgd 			sc->sc_blkno = 0;
1.1  cgd 			sc->sc_ul.unit = C_SUNIT(sc->sc_punit);
1.1  cgd 			sc->sc_ul.cmd = C_UNLOAD;
1.1  cgd 			hpibsend(sc->sc_hd->hp_ctlr, sc->sc_hd->hp_slave,
1.1  cgd 				C_CMD, &sc->sc_ul, sizeof(sc->sc_ul));
1.1  cgd 			break;
1.1  cgd
1.1  cgd 		case MTWEOF:
1.1  cgd 			sc->sc_blkno++;
1.1  cgd 			sc->sc_flags |= CTF_WRT;
1.1  cgd 			sc->sc_wfm.unit = C_SUNIT(sc->sc_punit);
1.1  cgd 			sc->sc_wfm.cmd = C_WFM;
1.1  cgd 			hpibsend(sc->sc_hd->hp_ctlr, sc->sc_hd->hp_slave,
1.1  cgd 				C_CMD, &sc->sc_wfm, sizeof(sc->sc_wfm));
1.1  cgd 			ctaddeof(unit);
1.1  cgd 			break;
1.1  cgd
1.1  cgd 		case MTBSR:
1.1  cgd 			sc->sc_blkno--;
1.1  cgd 			goto gotaddr;
1.1  cgd
1.1  cgd 		case MTFSR:
1.1  cgd 			sc->sc_blkno++;
1.1  cgd 			goto gotaddr;
1.1  cgd
1.1  cgd 		case MTREW:
1.1  cgd 			sc->sc_blkno = 0;
1.1  cgd #ifdef DEBUG
1.1  cgd 			if(ctdebug & CT_BSF)
1.1  cgd 				printf("ct%d: clearing eofs\n", unit);
1.1  cgd #endif
1.1  cgd 			for (i=0; i<EOFS; i++)
1.1  cgd 				sc->sc_eofs[i] = 0;
1.1  cgd 			sc->sc_eofp = 0;
1.1  cgd
1.1  cgd gotaddr:
1.1  cgd 			sc->sc_ioc.saddr = C_SADDR;
1.1  cgd 			sc->sc_ioc.addr0 = 0;
1.1  cgd 			sc->sc_ioc.addr = sc->sc_blkno;
1.1  cgd 			sc->sc_ioc.unit = C_SUNIT(sc->sc_punit);
1.1  cgd 			sc->sc_ioc.nop2 = C_NOP;
1.1  cgd 			sc->sc_ioc.slen = C_SLEN;
1.1  cgd 			sc->sc_ioc.len = 0;
1.1  cgd 			sc->sc_ioc.nop3 = C_NOP;
1.1  cgd 			sc->sc_ioc.cmd = C_READ;
1.1  cgd 			hpibsend(sc->sc_hd->hp_ctlr, sc->sc_hd->hp_slave,
1.1  cgd 				C_CMD, &sc->sc_ioc, sizeof(sc->sc_ioc));
1.1  cgd 			break;
1.1  cgd 		}
1.1  cgd 	}
1.1  cgd 	else {
1.1  cgd mustio:
1.1  cgd 		if ((bp->b_flags & B_READ) &&
1.1  cgd 		    sc->sc_flags & (CTF_BEOF|CTF_EOT)) {
1.1  cgd #ifdef DEBUG
1.1  cgd 			if (ctdebug & CDB_FILES)
1.1  cgd 				printf("ctstart: before flags %x\n", sc->sc_flags);
1.1  cgd #endif
1.1  cgd 			if (sc->sc_flags & CTF_BEOF) {
1.1  cgd 				sc->sc_flags &= ~CTF_BEOF;
1.1  cgd 				sc->sc_flags |= CTF_AEOF;
1.1  cgd #ifdef DEBUG
1.1  cgd 				if (ctdebug & CDB_FILES)
1.1  cgd 					printf("ctstart: after flags %x\n", sc->sc_flags);
1.1  cgd #endif
1.1  cgd 			}
1.1  cgd 			bp->b_resid = bp->b_bcount;
1.1  cgd 			iodone(bp);
1.1  cgd 			hpibfree(&sc->sc_dq);
1.1  cgd 			cttab[unit].b_actf = bp = bp->av_forw;
1.1  cgd 			if (bp == NULL) {
1.1  cgd 				cttab[unit].b_active = 0;
1.1  cgd 				return;
1.1  cgd 			}
1.1  cgd 			sc->sc_addr = bp->b_un.b_addr;
1.1  cgd 			sc->sc_resid = bp->b_bcount;
1.1  cgd 			if (hpibreq(&sc->sc_dq))
1.1  cgd 				goto again;
1.1  cgd 			return;
1.1  cgd 		}
1.1  cgd 		sc->sc_flags |= CTF_IO;
1.1  cgd 		sc->sc_ioc.unit = C_SUNIT(sc->sc_punit);
1.1  cgd 		sc->sc_ioc.saddr = C_SADDR;
1.1  cgd 		sc->sc_ioc.addr0 = 0;
1.1  cgd 		sc->sc_ioc.addr = sc->sc_blkno;
1.1  cgd 		sc->sc_ioc.nop2 = C_NOP;
1.1  cgd 		sc->sc_ioc.slen = C_SLEN;
1.1  cgd 		sc->sc_ioc.len = sc->sc_resid;
1.1  cgd 		sc->sc_ioc.nop3 = C_NOP;
1.1  cgd 		if (bp->b_flags & B_READ)
1.1  cgd 			sc->sc_ioc.cmd = C_READ;
1.1  cgd 		else {
1.1  cgd 			sc->sc_ioc.cmd = C_WRITE;
1.1  cgd 			sc->sc_flags |= (CTF_WRT | CTF_WRTTN);
1.1  cgd 		}
1.1  cgd 		hpibsend(sc->sc_hd->hp_ctlr, sc->sc_hd->hp_slave, C_CMD,
1.1  cgd 			&sc->sc_ioc, sizeof(sc->sc_ioc));
1.1  cgd 	}
1.1  cgd 	hpibawait(sc->sc_hd->hp_ctlr);
1.1  cgd }
1.1  cgd
1.1  cgd ctgo(unit)
1.1  cgd 	register int unit;
1.1  cgd {
1.1  cgd 	register struct ct_softc *sc = &ct_softc[unit];
1.1  cgd 	register struct buf *bp;
1.1  cgd
1.1  cgd 	bp = cttab[unit].b_actf;
1.1  cgd 	hpibgo(sc->sc_hd->hp_ctlr, sc->sc_hd->hp_slave, C_EXEC,
1.1  cgd 		sc->sc_addr, sc->sc_resid, bp->b_flags & B_READ);
1.1  cgd }
1.1  cgd
1.1  cgd /*
1.1  cgd  * Hideous grue to handle EOF/EOT (mostly for reads)
1.1  cgd  */
1.1  cgd cteof(sc, bp)
1.1  cgd 	register struct ct_softc *sc;
1.1  cgd 	register struct buf *bp;
1.1  cgd {
1.1  cgd 	long blks;
1.1  cgd
1.1  cgd 	/*
1.1  cgd 	 * EOT on a write is an error.
1.1  cgd 	 */
1.1  cgd 	if ((bp->b_flags & B_READ) == 0) {
1.1  cgd 		bp->b_resid = bp->b_bcount;
1.1  cgd 		bp->b_flags |= B_ERROR;
1.1  cgd 		bp->b_error = ENOSPC;
1.1  cgd 		sc->sc_flags |= CTF_EOT;
1.1  cgd 		return;
1.1  cgd 	}
1.1  cgd 	/*
1.1  cgd 	 * Use returned block position to determine how many blocks
1.1  cgd 	 * we really read and update b_resid.
1.1  cgd 	 */
1.1  cgd 	blks = sc->sc_stat.c_blk - sc->sc_blkno - 1;
1.1  cgd #ifdef DEBUG
1.1  cgd 	if (ctdebug & CDB_FILES)
1.1  cgd 		printf("cteof: bc %d oblk %d nblk %d read %d, resid %d\n",
1.1  cgd 		       bp->b_bcount, sc->sc_blkno, sc->sc_stat.c_blk,
1.1  cgd 		       blks, bp->b_bcount - CTKTOB(blks));
1.1  cgd #endif
1.1  cgd 	if (blks == -1) { /* 9145 on EOF does not change sc_stat.c_blk */
1.1  cgd 		blks = 0;
1.1  cgd 		sc->sc_blkno++;
1.1  cgd 	}
1.1  cgd 	else {
1.1  cgd 		sc->sc_blkno = sc->sc_stat.c_blk;
1.1  cgd 	}
1.1  cgd 	bp->b_resid = bp->b_bcount - CTKTOB(blks);
1.1  cgd 	/*
1.1  cgd 	 * If we are at physical EOV or were after an EOF,
1.1  cgd 	 * we are now at logical EOT.
1.1  cgd 	 */
1.1  cgd 	if ((sc->sc_stat.c_aef & AEF_EOV) ||
1.1  cgd 	    (sc->sc_flags & CTF_AEOF)) {
1.1  cgd 		sc->sc_flags |= CTF_EOT;
1.1  cgd 		sc->sc_flags &= ~(CTF_AEOF|CTF_BEOF);
1.1  cgd 	}
1.1  cgd 	/*
1.1  cgd 	 * If we were before an EOF or we have just completed a FSF,
1.1  cgd 	 * we are now after EOF.
1.1  cgd 	 */
1.1  cgd 	else if ((sc->sc_flags & CTF_BEOF) ||
1.1  cgd 		 (sc->sc_flags & CTF_CMD) && sc->sc_cmd == MTFSF) {
1.1  cgd 		sc->sc_flags |= CTF_AEOF;
1.1  cgd 		sc->sc_flags &= ~CTF_BEOF;
1.1  cgd 	}
1.1  cgd 	/*
1.1  cgd 	 * Otherwise if we read something we are now before EOF
1.1  cgd 	 * (and no longer after EOF).
1.1  cgd 	 */
1.1  cgd 	else if (blks) {
1.1  cgd 		sc->sc_flags |= CTF_BEOF;
1.1  cgd 		sc->sc_flags &= ~CTF_AEOF;
1.1  cgd 	}
1.1  cgd 	/*
1.1  cgd 	 * Finally, if we didn't read anything we just passed an EOF
1.1  cgd 	 */
1.1  cgd 	else
1.1  cgd 		sc->sc_flags |= CTF_AEOF;
1.1  cgd #ifdef DEBUG
1.1  cgd 	if (ctdebug & CDB_FILES)
1.1  cgd 		printf("cteof: leaving flags %x\n", sc->sc_flags);
1.1  cgd #endif
1.1  cgd }
1.1  cgd
1.1  cgd ctintr(unit)
1.1  cgd 	register int unit;
1.1  cgd {
1.1  cgd 	register struct ct_softc *sc = &ct_softc[unit];
1.1  cgd 	register struct buf *bp;
1.1  cgd 	u_char stat;
1.1  cgd
1.1  cgd 	bp = cttab[unit].b_actf;
1.1  cgd 	if (bp == NULL) {
1.1  cgd 		printf("ct%d: bp == NULL\n", unit);
1.1  cgd 		return;
1.1  cgd 	}
1.1  cgd 	if (sc->sc_flags & CTF_IO) {
1.1  cgd 		sc->sc_flags &= ~CTF_IO;
1.1  cgd 		if (hpibustart(sc->sc_hd->hp_ctlr))
1.1  cgd 			ctgo(unit);
1.1  cgd 		return;
1.1  cgd 	}
1.1  cgd 	if ((sc->sc_flags & CTF_STATWAIT) == 0) {
1.1  cgd 		if (hpibpptest(sc->sc_hd->hp_ctlr, sc->sc_hd->hp_slave) == 0) {
1.1  cgd 			sc->sc_flags |= CTF_STATWAIT;
1.1  cgd 			hpibawait(sc->sc_hd->hp_ctlr);
1.1  cgd 			return;
1.1  cgd 		}
1.1  cgd 	} else
1.1  cgd 		sc->sc_flags &= ~CTF_STATWAIT;
1.1  cgd 	hpibrecv(sc->sc_hd->hp_ctlr, sc->sc_hd->hp_slave, C_QSTAT, &stat, 1);
1.1  cgd #ifdef DEBUG
1.1  cgd 	if (ctdebug & CDB_FILES)
1.1  cgd 		printf("ctintr: before flags %x\n", sc->sc_flags);
1.1  cgd #endif
1.1  cgd 	if (stat) {
1.1  cgd 		sc->sc_rsc.unit = C_SUNIT(sc->sc_punit);
1.1  cgd 		sc->sc_rsc.cmd = C_STATUS;
1.1  cgd 		hpibsend(sc->sc_hd->hp_ctlr, sc->sc_hd->hp_slave, C_CMD,
1.1  cgd 			&sc->sc_rsc, sizeof(sc->sc_rsc));
1.1  cgd 		hpibrecv(sc->sc_hd->hp_ctlr, sc->sc_hd->hp_slave, C_EXEC,
1.1  cgd 			&sc->sc_stat, sizeof(sc->sc_stat));
1.1  cgd 		hpibrecv(sc->sc_hd->hp_ctlr, sc->sc_hd->hp_slave, C_QSTAT,
1.1  cgd 			&stat, 1);
1.1  cgd #ifdef DEBUG
1.1  cgd 		if (ctdebug & CDB_FILES)
1.1  cgd 			printf("ctintr: return stat 0x%x, A%x F%x blk %d\n",
1.1  cgd 			       stat, sc->sc_stat.c_aef,
1.1  cgd 			       sc->sc_stat.c_fef, sc->sc_stat.c_blk);
1.1  cgd #endif
1.1  cgd 		if (stat == 0) {
1.1  cgd 			if (sc->sc_stat.c_aef & (AEF_EOF | AEF_EOV)) {
1.1  cgd 				cteof(sc, bp);
1.1  cgd 				ctaddeof(unit);
1.1  cgd 				goto done;
1.1  cgd 			}
1.1  cgd 			if (sc->sc_stat.c_fef & FEF_PF) {
1.1  cgd 				ctreset(sc, sc->sc_hd);
1.1  cgd 				ctstart(unit);
1.1  cgd 				return;
1.1  cgd 			}
1.1  cgd 			if (sc->sc_stat.c_fef & FEF_REXMT) {
1.1  cgd 				ctstart(unit);
1.1  cgd 				return;
1.1  cgd 			}
1.1  cgd 			if (sc->sc_stat.c_aef & 0x5800) {
1.1  cgd 				if (sc->sc_stat.c_aef & 0x4000)
1.1  cgd 					tprintf(sc->sc_tpr,
1.1  cgd 						"ct%d: uninitialized media\n",
1.1  cgd 						unit);
1.1  cgd 				if (sc->sc_stat.c_aef & 0x1000)
1.1  cgd 					tprintf(sc->sc_tpr,
1.1  cgd 						"ct%d: not ready\n", unit);
1.1  cgd 				if (sc->sc_stat.c_aef & 0x0800)
1.1  cgd 					tprintf(sc->sc_tpr,
1.1  cgd 						"ct%d: write protect\n", unit);
1.1  cgd 			} else {
1.1  cgd 				printf("ct%d err: v%d u%d ru%d bn%d, ",
1.1  cgd 				       unit,
1.1  cgd 				       (sc->sc_stat.c_vu>>4)&0xF,
1.1  cgd 				       sc->sc_stat.c_vu&0xF,
1.1  cgd 				       sc->sc_stat.c_pend,
1.1  cgd 				       sc->sc_stat.c_blk);
1.1  cgd 				printf("R0x%x F0x%x A0x%x I0x%x\n",
1.1  cgd 				       sc->sc_stat.c_ref,
1.1  cgd 				       sc->sc_stat.c_fef,
1.1  cgd 				       sc->sc_stat.c_aef,
1.1  cgd 				       sc->sc_stat.c_ief);
1.1  cgd 			}
1.1  cgd 		} else
1.1  cgd 			printf("ct%d: request status failed\n", unit);
1.1  cgd 		bp->b_flags |= B_ERROR;
1.1  cgd 		bp->b_error = EIO;
1.1  cgd 		goto done;
1.1  cgd 	} else
1.1  cgd 		bp->b_resid = 0;
1.1  cgd 	if (sc->sc_flags & CTF_CMD) {
1.1  cgd 		switch (sc->sc_cmd) {
1.1  cgd 		case MTFSF:
1.1  cgd 			sc->sc_flags &= ~(CTF_BEOF|CTF_AEOF);
1.1  cgd 			sc->sc_blkno += CTBTOK(sc->sc_resid);
1.1  cgd 			ctstart(unit);
1.1  cgd 			return;
1.1  cgd 		case MTBSF:
1.1  cgd 			sc->sc_flags &= ~(CTF_AEOF|CTF_BEOF|CTF_EOT);
1.1  cgd 			break;
1.1  cgd 		case MTBSR:
1.1  cgd 			sc->sc_flags &= ~CTF_BEOF;
1.1  cgd 			if (sc->sc_flags & CTF_EOT) {
1.1  cgd 				sc->sc_flags |= CTF_AEOF;
1.1  cgd 				sc->sc_flags &= ~CTF_EOT;
1.1  cgd 			} else if (sc->sc_flags & CTF_AEOF) {
1.1  cgd 				sc->sc_flags |= CTF_BEOF;
1.1  cgd 				sc->sc_flags &= ~CTF_AEOF;
1.1  cgd 			}
1.1  cgd 			break;
1.1  cgd 		case MTWEOF:
1.1  cgd 			sc->sc_flags &= ~CTF_BEOF;
1.1  cgd 			if (sc->sc_flags & (CTF_AEOF|CTF_EOT)) {
1.1  cgd 				sc->sc_flags |= CTF_EOT;
1.1  cgd 				sc->sc_flags &= ~CTF_AEOF;
1.1  cgd 			} else
1.1  cgd 				sc->sc_flags |= CTF_AEOF;
1.1  cgd 			break;
1.1  cgd 		case MTREW:
1.1  cgd 		case MTOFFL:
1.1  cgd 			sc->sc_flags &= ~(CTF_BEOF|CTF_AEOF|CTF_EOT);
1.1  cgd 			break;
1.1  cgd 		}
1.1  cgd 	} else {
1.1  cgd 		sc->sc_flags &= ~CTF_AEOF;
1.1  cgd 		sc->sc_blkno += CTBTOK(sc->sc_resid);
1.1  cgd 	}
1.1  cgd done:
1.1  cgd #ifdef DEBUG
1.1  cgd 	if (ctdebug & CDB_FILES)
1.1  cgd 		printf("ctintr: after flags %x\n", sc->sc_flags);
1.1  cgd #endif
1.1  cgd 	cttab[unit].b_actf = bp->av_forw;
1.1  cgd 	iodone(bp);
1.1  cgd 	hpibfree(&sc->sc_dq);
1.1  cgd 	if (cttab[unit].b_actf == NULL) {
1.1  cgd 		cttab[unit].b_active = 0;
1.1  cgd 		return;
1.1  cgd 	}
1.1  cgd 	ctustart(unit);
1.1  cgd }
1.1  cgd
1.1  cgd ctread(dev, uio)
1.1  cgd 	dev_t dev;
1.1  cgd 	struct uio *uio;
1.1  cgd {
1.1  cgd 	register int unit = UNIT(dev);
1.1  cgd
1.1  cgd 	return(physio(ctstrategy, &ctbuf[unit], dev, B_READ, minphys, uio));
1.1  cgd }
1.1  cgd
1.1  cgd ctwrite(dev, uio)
1.1  cgd 	dev_t dev;
1.1  cgd 	struct uio *uio;
1.1  cgd {
1.1  cgd 	register int unit = UNIT(dev);
1.1  cgd
1.1  cgd 	return(physio(ctstrategy, &ctbuf[unit], dev, B_WRITE, minphys, uio));
1.1  cgd }
1.1  cgd
1.1  cgd /*ARGSUSED*/
1.1  cgd ctioctl(dev, cmd, data, flag)
1.1  cgd 	dev_t dev;
1.1  cgd 	caddr_t data;
1.1  cgd {
1.1  cgd 	register struct mtop *op;
1.1  cgd 	register int cnt;
1.1  cgd
1.1  cgd 	switch (cmd) {
1.1  cgd
1.1  cgd 	case MTIOCTOP:
1.1  cgd 		op = (struct mtop *)data;
1.1  cgd 		switch(op->mt_op) {
1.1  cgd
1.1  cgd 		case MTWEOF:
1.1  cgd 		case MTFSF:
1.1  cgd 		case MTBSR:
1.1  cgd 		case MTBSF:
1.1  cgd 		case MTFSR:
1.1  cgd 			cnt = op->mt_count;
1.1  cgd 			break;
1.1  cgd
1.1  cgd 		case MTREW:
1.1  cgd 		case MTOFFL:
1.1  cgd 			cnt = 1;
1.1  cgd 			break;
1.1  cgd
1.1  cgd 		default:
1.1  cgd 			return(EINVAL);
1.1  cgd 		}
1.1  cgd 		ctcommand(dev, op->mt_op, cnt);
1.1  cgd 		break;
1.1  cgd
1.1  cgd 	case MTIOCGET:
1.1  cgd 		break;
1.1  cgd
1.1  cgd 	default:
1.1  cgd 		return(EINVAL);
1.1  cgd 	}
1.1  cgd 	return(0);
1.1  cgd }
1.1  cgd
1.1  cgd /*ARGSUSED*/
1.1  cgd ctdump(dev)
1.1  cgd 	dev_t dev;
1.1  cgd {
1.1  cgd 	return(ENXIO);
1.1  cgd }
1.1  cgd
1.1  cgd ctaddeof(unit)
1.1  cgd 	int unit;
1.1  cgd {
1.1  cgd 	register struct ct_softc *sc = &ct_softc[unit];
1.1  cgd
1.1  cgd 	if (sc->sc_eofp == EOFS - 1)
1.1  cgd 		sc->sc_eofs[EOFS - 1]++;
1.1  cgd 	else {
1.1  cgd 		sc->sc_eofp++;
1.1  cgd 		if (sc->sc_eofp == EOFS - 1)
1.1  cgd 			sc->sc_eofs[EOFS - 1] = EOFS;
1.1  cgd 		else
1.1  cgd 			/* save blkno */
1.1  cgd 			sc->sc_eofs[sc->sc_eofp] = sc->sc_blkno - 1;
1.1  cgd 	}
1.1  cgd #ifdef DEBUG
1.1  cgd 	if (ctdebug & CT_BSF)
1.1  cgd 		printf("ct%d: add eof pos %d blk %d\n",
1.1  cgd 		       unit, sc->sc_eofp,
1.1  cgd 		       sc->sc_eofs[sc->sc_eofp]);
1.1  cgd #endif
1.1  cgd }
1.1  cgd #endif