dev/scsipi/ch.c

1.1      cgd /*
1.5  mycroft  *	$Id: ch.c,v 1.5 1993/12/17 08:50:45 mycroft Exp $
1.1      cgd  */
1.1      cgd
1.5  mycroft #include "ch.h"
1.1      cgd
1.5  mycroft #include <sys/types.h>
1.1      cgd #include <sys/param.h>
1.1      cgd #include <sys/systm.h>
1.1      cgd #include <sys/errno.h>
1.1      cgd #include <sys/ioctl.h>
1.1      cgd #include <sys/buf.h>
1.1      cgd #include <sys/proc.h>
1.1      cgd #include <sys/user.h>
1.1      cgd #include <sys/chio.h>
1.1      cgd
1.1      cgd #if defined(OSF)
1.1      cgd #define SECSIZE	512
1.1      cgd #endif /* defined(OSF) */
1.1      cgd
1.1      cgd #include <scsi/scsi_all.h>
1.1      cgd #include <scsi/scsi_changer.h>
1.1      cgd #include <scsi/scsiconf.h>
1.1      cgd
1.1      cgd
1.1      cgd struct  scsi_xfer ch_scsi_xfer[NCH];
1.1      cgd int     ch_xfer_block_wait[NCH];
1.1      cgd
1.1      cgd
1.1      cgd #define PAGESIZ 	4096
1.1      cgd #define STQSIZE		4
1.1      cgd #define	CH_RETRIES	4
1.1      cgd
1.1      cgd
1.1      cgd #define MODE(z)		(  (minor(z) & 0x0F) )
1.1      cgd #define UNIT(z)		(  (minor(z) >> 4) )
1.1      cgd
1.1      cgd #ifndef	MACH
1.1      cgd #define ESUCCESS 0
1.1      cgd #endif	MACH
1.1      cgd
1.1      cgd int	ch_info_valid[NCH];	/* the info about the device is valid */
1.1      cgd int	ch_initialized[NCH] ;
1.1      cgd int	ch_debug = 1;
1.1      cgd
1.1      cgd int chattach();
1.1      cgd int ch_done();
1.1      cgd struct	ch_data
1.1      cgd {
1.1      cgd 	int	flags;
1.1      cgd 	struct	scsi_switch *sc_sw;	/* address of scsi low level switch */
1.1      cgd 	int	ctlr;			/* so they know which one we want */
1.1      cgd 	int	targ;			/* our scsi target ID */
1.1      cgd 	int	lu;			/* out scsi lu */
1.1      cgd 	short	chmo;			/* Offset of first CHM */
1.1      cgd 	short	chms;			/* No. of CHM */
1.1      cgd 	short	slots;			/* No. of Storage Elements */
1.1      cgd 	short	sloto;			/* Offset of first SE */
1.1      cgd 	short	imexs;			/* No. of Import/Export Slots */
1.1      cgd 	short	imexo;			/* Offset of first IM/EX */
1.1      cgd 	short	drives;			/* No. of CTS */
1.1      cgd 	short	driveo;			/* Offset of first CTS */
1.1      cgd 	short	rot;			/* CHM can rotate */
1.1      cgd 	u_long	op_matrix;		/* possible opertaions */
1.1      cgd 	u_short lsterr;		/* details of lasterror */
1.1      cgd 	u_char	stor;			/* posible Storage locations */
1.1      cgd }ch_data[NCH];
1.1      cgd
1.1      cgd #define CH_OPEN		0x01
1.1      cgd #define CH_KNOWN	0x02
1.1      cgd
1.1      cgd static	int	next_ch_unit = 0;
1.1      cgd /***********************************************************************\
1.1      cgd * The routine called by the low level scsi routine when it discovers	*
1.1      cgd * A device suitable for this driver					*
1.1      cgd \***********************************************************************/
1.1      cgd
1.1      cgd int	chattach(ctlr,targ,lu,scsi_switch)
1.1      cgd struct	scsi_switch *scsi_switch;
1.1      cgd {
1.1      cgd 	int	unit,i,stat;
1.1      cgd 	unsigned char *tbl;
1.1      cgd
1.1      cgd 	if(scsi_debug & PRINTROUTINES) printf("chattach: ");
1.1      cgd 	/*******************************************************\
1.1      cgd 	* Check we have the resources for another drive		*
1.1      cgd 	\*******************************************************/
1.1      cgd 	unit = next_ch_unit++;
1.1      cgd 	if( unit >= NCH)
1.1      cgd 	{
1.1      cgd 		printf("Too many scsi changers..(%d > %d) reconfigure kernel",(unit + 1),NCH);
1.1      cgd 		return(0);
1.1      cgd 	}
1.1      cgd 	/*******************************************************\
1.1      cgd 	* Store information needed to contact our base driver	*
1.1      cgd 	\*******************************************************/
1.1      cgd 	ch_data[unit].sc_sw	=	scsi_switch;
1.1      cgd 	ch_data[unit].ctlr	=	ctlr;
1.1      cgd 	ch_data[unit].targ	=	targ;
1.1      cgd 	ch_data[unit].lu	=	lu;
1.1      cgd
1.1      cgd 	/*******************************************************\
1.1      cgd 	* Use the subdriver to request information regarding	*
1.1      cgd 	* the drive. We cannot use interrupts yet, so the	*
1.1      cgd 	* request must specify this.				*
1.1      cgd 	\*******************************************************/
1.1      cgd 	if((ch_mode_sense(unit,  SCSI_NOSLEEP |  SCSI_NOMASK /*| SCSI_SILENT*/)))
1.1      cgd 	{
1.1      cgd 		printf("	ch%d: scsi changer, %d slot(s) %d drive(s) %d arm(s) %d i/e-slot(s) \n",
1.1      cgd 			unit, ch_data[unit].slots, ch_data[unit].drives, ch_data[unit].chms, ch_data[unit].imexs);
1.1      cgd 		stat=CH_KNOWN;
1.1      cgd 	}
1.1      cgd 	else
1.1      cgd 	{
1.1      cgd 		printf("	ch%d: scsi changer :- offline\n", unit);
1.1      cgd 		stat=CH_OPEN;
1.1      cgd 	}
1.1      cgd 	ch_initialized[unit] = stat;
1.1      cgd
1.1      cgd 	return;
1.1      cgd
1.1      cgd }
1.1      cgd
1.1      cgd
1.1      cgd
1.1      cgd /*******************************************************\
1.1      cgd *	open the device.				*
1.1      cgd \*******************************************************/
1.1      cgd chopen(dev)
1.1      cgd {
1.1      cgd 	int errcode = 0;
1.1      cgd 	int unit,mode;
1.1      cgd
1.1      cgd 	unit = UNIT(dev);
1.1      cgd 	mode = MODE(dev);
1.1      cgd
1.1      cgd 	/*******************************************************\
1.1      cgd 	* Check the unit is legal                               *
1.1      cgd 	\*******************************************************/
1.1      cgd 	if ( unit >= NCH )
1.1      cgd 	{
1.1      cgd 		printf("ch %d  > %d\n",unit,NCH);
1.1      cgd 		errcode = ENXIO;
1.1      cgd 		return(errcode);
1.1      cgd 	}
1.1      cgd 	/*******************************************************\
1.1      cgd 	* Only allow one at a time				*
1.1      cgd 	\*******************************************************/
1.1      cgd 	if(ch_data[unit].flags & CH_OPEN)
1.1      cgd 	{
1.1      cgd 		printf("CH%d already open\n",unit);
1.1      cgd 		errcode = ENXIO;
1.1      cgd 		goto bad;
1.1      cgd 	}
1.1      cgd
1.1      cgd 	if(ch_debug||(scsi_debug & (PRINTROUTINES | TRACEOPENS)))
1.1      cgd 		printf("chopen: dev=0x%x (unit %d (of %d))\n"
1.1      cgd 				,   dev,      unit,   NCH);
1.1      cgd 	/*******************************************************\
1.1      cgd 	* Make sure the device has been initialised		*
1.1      cgd 	\*******************************************************/
1.1      cgd
1.1      cgd 	if (!ch_initialized[unit])
1.1      cgd 		return(ENXIO);
1.1      cgd 	if (ch_initialized[unit]!=CH_KNOWN) {
1.1      cgd 		if((ch_mode_sense(unit,  SCSI_NOSLEEP |  SCSI_NOMASK /*| SCSI_SILENT*/)))
1.1      cgd 		{
1.1      cgd 			ch_initialized[unit]=CH_KNOWN;
1.1      cgd 		}
1.1      cgd 	  else
1.1      cgd 		{
1.1      cgd 			printf("  ch%d: scsi changer :- offline\n", unit);
1.1      cgd 			return(ENXIO);
1.1      cgd 		}
1.1      cgd 	}
1.1      cgd 	/*******************************************************\
1.1      cgd 	* Check that it is still responding and ok.		*
1.1      cgd 	\*******************************************************/
1.1      cgd
1.1      cgd 	if(ch_debug || (scsi_debug & TRACEOPENS))
1.1      cgd 		printf("device is ");
1.1      cgd 	if (!(ch_req_sense(unit, 0)))
1.1      cgd 	{
1.1      cgd 		errcode = ENXIO;
1.1      cgd 		if(ch_debug || (scsi_debug & TRACEOPENS))
1.1      cgd 			printf("not responding\n");
1.1      cgd 		goto bad;
1.1      cgd 	}
1.1      cgd 	if(ch_debug || (scsi_debug & TRACEOPENS))
1.1      cgd 		printf("ok\n");
1.1      cgd
1.1      cgd 	if(!(ch_test_ready(unit,0)))
1.1      cgd 	{
1.1      cgd 		printf("ch%d not ready\n",unit);
1.1      cgd 		return(EIO);
1.1      cgd 	}
1.1      cgd
1.1      cgd 	ch_info_valid[unit] = TRUE;
1.1      cgd
1.1      cgd 	/*******************************************************\
1.1      cgd 	* Load the physical device parameters			*
1.1      cgd 	\*******************************************************/
1.1      cgd
1.1      cgd 	ch_data[unit].flags = CH_OPEN;
1.1      cgd 	return(errcode);
1.1      cgd bad:
1.1      cgd 	return(errcode);
1.1      cgd }
1.1      cgd
1.1      cgd /*******************************************************\
1.1      cgd * close the device.. only called if we are the LAST	*
1.1      cgd * occurence of an open device				*
1.1      cgd \*******************************************************/
1.1      cgd chclose(dev)
1.1      cgd {
1.1      cgd 	unsigned char unit,mode;
1.1      cgd
1.1      cgd 	unit = UNIT(dev);
1.1      cgd 	mode = MODE(dev);
1.1      cgd
1.1      cgd 	if(scsi_debug & TRACEOPENS)
1.1      cgd 		printf("Closing device");
1.1      cgd 	ch_data[unit].flags = 0;
1.1      cgd 	return(0);
1.1      cgd }
1.1      cgd
1.1      cgd
1.1      cgd
1.1      cgd /***************************************************************\
1.1      cgd * chstart                                                       *
1.1      cgd * This routine is also called after other non-queued requests	*
1.1      cgd * have been made of the scsi driver, to ensure that the queue	*
1.1      cgd * continues to be drained.					*
1.1      cgd \***************************************************************/
1.1      cgd /* chstart() is called at splbio */
1.1      cgd chstart(unit)
1.1      cgd {
1.1      cgd 	int			drivecount;
1.1      cgd 	register struct buf	*bp = 0;
1.1      cgd 	register struct buf	*dp;
1.1      cgd 	struct	scsi_xfer	*xs;
1.1      cgd 	int			blkno, nblk;
1.1      cgd
1.1      cgd
1.1      cgd 	if(scsi_debug & PRINTROUTINES) printf("chstart%d ",unit);
1.1      cgd 	/*******************************************************\
1.1      cgd 	* See if there is a buf to do and we are not already	*
1.1      cgd 	* doing one						*
1.1      cgd 	\*******************************************************/
1.1      cgd 	xs=&ch_scsi_xfer[unit];
1.1      cgd 	if(xs->flags & INUSE)
1.1      cgd 	{
1.1      cgd 		return;    /* unit already underway */
1.1      cgd 	}
1.1      cgd 	if(ch_xfer_block_wait[unit]) /* a special awaits, let it proceed first */
1.1      cgd 	{
1.1      cgd 		wakeup(&ch_xfer_block_wait[unit]);
1.1      cgd 		return;
1.1      cgd 	}
1.1      cgd
1.1      cgd 	return;
1.1      cgd
1.1      cgd }
1.1      cgd
1.1      cgd
1.1      cgd /*******************************************************\
1.1      cgd * This routine is called by the scsi interrupt when	*
1.1      cgd * the transfer is complete.
1.1      cgd \*******************************************************/
1.1      cgd int	ch_done(unit,xs)
1.1      cgd int	unit;
1.1      cgd struct	scsi_xfer	*xs;
1.1      cgd {
1.1      cgd 	struct	buf		*bp;
1.1      cgd 	int	retval;
1.1      cgd
1.1      cgd 	if(ch_debug||(scsi_debug & PRINTROUTINES)) printf("ch_done%d ",unit);
1.1      cgd 	if (! (xs->flags & INUSE))
1.1      cgd 		panic("scsi_xfer not in use!");
1.1      cgd 	wakeup(xs);
1.1      cgd }
1.1      cgd /*******************************************************\
1.1      cgd * Perform special action on behalf of the user		*
1.1      cgd * Knows about the internals of this device		*
1.1      cgd \*******************************************************/
1.1      cgd chioctl(dev, cmd, arg, mode)
1.1      cgd dev_t dev;
1.1      cgd int cmd;
1.1      cgd caddr_t arg;
1.1      cgd {
1.1      cgd 	/* struct ch_cmd_buf *args;*/
1.1      cgd 	union scsi_cmd *scsi_cmd;
1.1      cgd 	register i,j;
1.1      cgd 	unsigned int opri;
1.1      cgd 	int errcode = 0;
1.1      cgd 	unsigned char unit;
1.1      cgd 	int number,flags,ret;
1.1      cgd
1.1      cgd 	/*******************************************************\
1.1      cgd 	* Find the device that the user is talking about	*
1.1      cgd 	\*******************************************************/
1.1      cgd 	flags = 0;	/* give error messages, act on errors etc. */
1.1      cgd 	unit = UNIT(dev);
1.1      cgd
1.1      cgd 	switch(cmd)
1.1      cgd 	{
1.1      cgd 		case CHIOOP: {
1.1      cgd 			struct chop *ch=(struct chop *) arg;
1.1      cgd 			if (ch_debug)
1.1      cgd 				printf("[chtape_chop: %x]\n", ch->ch_op);
1.1      cgd
1.1      cgd 			 switch ((short)(ch->ch_op)) {
1.1      cgd 				case CHGETPARAM:
1.1      cgd 					ch->u.getparam.chmo=	 ch_data[unit].chmo;
1.1      cgd 					ch->u.getparam.chms=   ch_data[unit].chms;
1.1      cgd 					ch->u.getparam.sloto=  ch_data[unit].sloto;
1.1      cgd 					ch->u.getparam.slots=  ch_data[unit].slots;
1.1      cgd 					ch->u.getparam.imexo=  ch_data[unit].imexo;
1.1      cgd 					ch->u.getparam.imexs=  ch_data[unit].imexs;
1.1      cgd 					ch->u.getparam.driveo= ch_data[unit].driveo;
1.1      cgd 					ch->u.getparam.drives= ch_data[unit].drives;
1.1      cgd 					ch->u.getparam.rot=    ch_data[unit].rot;
1.1      cgd 					ch->result=0;
1.1      cgd 					return 0;
1.1      cgd 					break;
1.1      cgd 				case CHPOSITION:
1.1      cgd 				 return ch_position(unit,&ch->result,ch->u.position.chm,
1.1      cgd 						ch->u.position.to,
1.1      cgd 						flags);
1.1      cgd 				case CHMOVE:
1.1      cgd 				 return ch_move(unit,&ch->result, ch->u.position.chm,
1.1      cgd 					ch->u.move.from, ch->u.move.to,
1.1      cgd 								flags);
1.1      cgd 				case CHGETELEM:
1.1      cgd 				 return ch_getelem(unit,&ch->result, ch->u.get_elem_stat.type,
1.1      cgd 					ch->u.get_elem_stat.from, &ch->u.get_elem_stat.elem_data,
1.1      cgd 									flags);
1.1      cgd 				default:
1.1      cgd 				 return EINVAL;
1.1      cgd 		}
1.1      cgd
1.1      cgd 	 }
1.1      cgd 	default:
1.1      cgd 		return EINVAL;
1.1      cgd 	}
1.1      cgd
1.1      cgd 	return(ret?ESUCCESS:EIO);
1.1      cgd }
1.1      cgd
1.1      cgd ch_getelem(unit,stat,type,from,data,flags)
1.1      cgd int unit,from,flags;
1.1      cgd short *stat;
1.1      cgd char *data;
1.1      cgd {
1.1      cgd 	struct scsi_read_element_status scsi_cmd;
1.1      cgd 	char elbuf[32];
1.1      cgd 	int ret;
1.1      cgd
1.1      cgd 	bzero(&scsi_cmd, sizeof(scsi_cmd));
1.1      cgd 	scsi_cmd.op_code = READ_ELEMENT_STATUS;
1.1      cgd 	scsi_cmd.element_type_code=type;
1.1      cgd 	scsi_cmd.starting_element_addr[0]=(from>>8)&0xff;
1.1      cgd 	scsi_cmd.starting_element_addr[1]=from&0xff;
1.1      cgd 	scsi_cmd.number_of_elements[1]=1;
1.1      cgd 	scsi_cmd.allocation_length[2]=32;
1.1      cgd
1.1      cgd 	if ((ret=ch_scsi_cmd(unit,
1.1      cgd 			&scsi_cmd,
1.1      cgd 			sizeof(scsi_cmd),
1.1      cgd 			elbuf,
1.1      cgd 			32,
1.1      cgd 			100000,
1.1      cgd 			flags) !=ESUCCESS)) {
1.1      cgd 			*stat=ch_data[unit].lsterr;
1.1      cgd 			bcopy(elbuf+16,data,16);
1.1      cgd 			return ret;
1.1      cgd 			}
1.1      cgd 	bcopy(elbuf+16,data,16); /*Just a hack sh */
1.1      cgd 	return ret;
1.1      cgd }
1.1      cgd
1.1      cgd ch_move(unit,stat,chm,from,to,flags)
1.1      cgd int unit,chm,from,to,flags;
1.1      cgd short *stat;
1.1      cgd {
1.1      cgd 	struct scsi_move_medium scsi_cmd;
1.1      cgd 	int ret;
1.1      cgd
1.1      cgd 	bzero(&scsi_cmd, sizeof(scsi_cmd));
1.1      cgd 	scsi_cmd.op_code = MOVE_MEDIUM;
1.1      cgd 	scsi_cmd.transport_element_address[0]=(chm>>8)&0xff;
1.1      cgd 	scsi_cmd.transport_element_address[1]=chm&0xff;
1.1      cgd 	scsi_cmd.source_address[0]=(from>>8)&0xff;
1.1      cgd 	scsi_cmd.source_address[1]=from&0xff;
1.1      cgd 	scsi_cmd.destination_address[0]=(to>>8)&0xff;
1.1      cgd 	scsi_cmd.destination_address[1]=to&0xff;
1.1      cgd 	scsi_cmd.invert=(chm&CH_INVERT)?1:0;
1.1      cgd 	if ((ret=ch_scsi_cmd(unit,
1.1      cgd 			&scsi_cmd,
1.1      cgd 			sizeof(scsi_cmd),
1.1      cgd 			NULL,
1.1      cgd 			0,
1.1      cgd 			100000,
1.1      cgd 			flags) !=ESUCCESS)) {
1.1      cgd 			*stat=ch_data[unit].lsterr;
1.1      cgd 			return ret;
1.1      cgd 			}
1.1      cgd 	return ret;
1.1      cgd }
1.1      cgd
1.1      cgd ch_position(unit,stat,chm,to,flags)
1.1      cgd int unit,chm,to,flags;
1.1      cgd short *stat;
1.1      cgd {
1.1      cgd 	struct scsi_position_to_element scsi_cmd;
1.1      cgd 	int ret;
1.1      cgd
1.1      cgd 	bzero(&scsi_cmd, sizeof(scsi_cmd));
1.1      cgd 	scsi_cmd.op_code = POSITION_TO_ELEMENT;
1.1      cgd 	scsi_cmd.transport_element_address[0]=(chm>>8)&0xff;
1.1      cgd 	scsi_cmd.transport_element_address[1]=chm&0xff;
1.1      cgd 	scsi_cmd.source_address[0]=(to>>8)&0xff;
1.1      cgd 	scsi_cmd.source_address[1]=to&0xff;
1.1      cgd 	scsi_cmd.invert=(chm&CH_INVERT)?1:0;
1.1      cgd 	if ((ret=ch_scsi_cmd(unit,
1.1      cgd 			&scsi_cmd,
1.1      cgd 			sizeof(scsi_cmd),
1.1      cgd 			NULL,
1.1      cgd 			0,
1.1      cgd 			100000,
1.1      cgd 			flags) !=ESUCCESS)) {
1.1      cgd 			*stat=ch_data[unit].lsterr;
1.1      cgd 			return ret;
1.1      cgd 			}
1.1      cgd 	return ret;
1.1      cgd }
1.1      cgd
1.1      cgd /*******************************************************\
1.1      cgd * Check with the device that it is ok, (via scsi driver)*
1.1      cgd \*******************************************************/
1.1      cgd ch_req_sense(unit, flags)
1.1      cgd int	flags;
1.1      cgd {
1.1      cgd 	struct	scsi_sense_data sense;
1.1      cgd 	struct scsi_sense scsi_cmd;
1.1      cgd
1.1      cgd 	bzero(&scsi_cmd, sizeof(scsi_cmd));
1.1      cgd 	scsi_cmd.op_code = REQUEST_SENSE;
1.1      cgd 	scsi_cmd.length = sizeof(sense);
1.1      cgd
1.1      cgd 	if (ch_scsi_cmd(unit,
1.1      cgd 			&scsi_cmd,
1.1      cgd 			sizeof(struct	scsi_sense),
1.1      cgd 			&sense,
1.1      cgd 			sizeof(sense),
1.1      cgd 			100000,
1.1      cgd 			flags | SCSI_DATA_IN) != 0)
1.1      cgd 	{
1.1      cgd 		return(FALSE);
1.1      cgd 	}
1.1      cgd 	else
1.1      cgd 		return(TRUE);
1.1      cgd }
1.1      cgd
1.1      cgd /*******************************************************\
1.1      cgd * Get scsi driver to send a "are you ready" command	*
1.1      cgd \*******************************************************/
1.1      cgd ch_test_ready(unit,flags)
1.1      cgd int	unit,flags;
1.1      cgd {
1.1      cgd 	struct scsi_test_unit_ready scsi_cmd;
1.1      cgd
1.1      cgd 	bzero(&scsi_cmd, sizeof(scsi_cmd));
1.1      cgd 	scsi_cmd.op_code = TEST_UNIT_READY;
1.1      cgd
1.1      cgd 	if (ch_scsi_cmd(unit,
1.1      cgd 			&scsi_cmd,
1.1      cgd 			sizeof(struct	scsi_test_unit_ready),
1.1      cgd 			0,
1.1      cgd 			0,
1.1      cgd 			100000,
1.1      cgd 			flags) != 0) {
1.1      cgd 		return(FALSE);
1.1      cgd 	} else
1.1      cgd 		return(TRUE);
1.1      cgd }
1.1      cgd
1.1      cgd
1.1      cgd #ifdef	__STDC__
1.1      cgd #define b2tol(a)	(((unsigned)(a##_1) << 8) + (unsigned)a##_0 )
1.1      cgd #else
1.1      cgd #define b2tol(a)	(((unsigned)(a/**/_1) << 8) + (unsigned)a/**/_0 )
1.1      cgd #endif
1.1      cgd
1.1      cgd /*******************************************************\
1.1      cgd * Get the scsi driver to send a full inquiry to the	*
1.1      cgd * device and use the results to fill out the global 	*
1.1      cgd * parameter structure.					*
1.1      cgd \*******************************************************/
1.1      cgd ch_mode_sense(unit, flags)
1.1      cgd int	unit,flags;
1.1      cgd {
1.1      cgd 	struct scsi_mode_sense scsi_cmd;
1.1      cgd 	u_char scsi_sense[128];	/* Can't use scsi_mode_sense_data because of */
1.1      cgd 				/* missing block descriptor 		     */
1.1      cgd 	u_char *b;
1.1      cgd 	int i,l;
1.1      cgd
1.1      cgd 	/*******************************************************\
1.1      cgd 	* First check if we have it all loaded			*
1.1      cgd 	\*******************************************************/
1.1      cgd 	if (ch_info_valid[unit]==CH_KNOWN) return(TRUE);
1.1      cgd 	/*******************************************************\
1.1      cgd 	* First do a mode sense 				*
1.1      cgd 	\*******************************************************/
1.1      cgd 	ch_info_valid[unit] &= ~CH_KNOWN;
1.1      cgd 	for(l=1;l>=0;l--) {
1.1      cgd 		bzero(&scsi_cmd, sizeof(scsi_cmd));
1.1      cgd 		scsi_cmd.op_code = MODE_SENSE;
1.1      cgd 		scsi_cmd.dbd = l;
1.1      cgd 		scsi_cmd.page_code = 0x3f;	/* All Pages */
1.1      cgd 		scsi_cmd.length = sizeof(scsi_sense);
1.1      cgd 	/*******************************************************\
1.1      cgd 	* do the command, but we don't need the results		*
1.1      cgd 	* just print them for our interest's sake		*
1.1      cgd 	\*******************************************************/
1.1      cgd 		if (ch_scsi_cmd(unit,
1.1      cgd 			&scsi_cmd,
1.1      cgd 			sizeof(struct	scsi_mode_sense),
1.1      cgd 			&scsi_sense,
1.1      cgd 			sizeof(scsi_sense),
1.1      cgd 			5000,
1.1      cgd 			flags | SCSI_DATA_IN) == 0) {
1.1      cgd 				ch_info_valid[unit] = CH_KNOWN;
1.1      cgd 				break;
1.1      cgd 			}
1.1      cgd 	}
1.1      cgd 	if (ch_info_valid[unit]!=CH_KNOWN)   {
1.1      cgd 		if(!(flags & SCSI_SILENT))
1.1      cgd 			printf("could not mode sense for unit %d\n", unit);
1.1      cgd 		return(FALSE);
1.1      cgd 	}
1.1      cgd 	l=scsi_sense[0]-3;
1.1      cgd 	b=&scsi_sense[4];
1.1      cgd 	/*****************************\
1.1      cgd 	* To avoid alignment problems *
1.1      cgd 	\*****************************/
1.1      cgd /*FIX THIS FOR MSB */
1.1      cgd #define p2copy(valp)	 (valp[1]+ (valp[0]<<8));valp+=2
1.1      cgd #define p4copy(valp)	 (valp[3]+ (valp[2]<<8) + (valp[1]<<16) + (valp[0]<<24));valp+=4
1.1      cgd #if 0
1.1      cgd 	printf("\nmode_sense %d\n",l);
1.1      cgd 	for(i=0;i<l+4;i++) {
1.1      cgd 		printf("%x%c",scsi_sense[i],i%8==7?'\n':':');
1.1      cgd 	}
1.1      cgd 	printf("\n");
1.1      cgd #endif
1.1      cgd 	for(i=0;i<l;) {
1.1      cgd 		int pc=(*b++)&0x3f;
1.1      cgd 		int pl=*b++;
1.1      cgd 		u_char *bb=b;
1.1      cgd 		switch(pc) {
1.1      cgd 			case 0x1d:
1.1      cgd 				ch_data[unit].chmo  =p2copy(bb);
1.1      cgd 				ch_data[unit].chms  =p2copy(bb);
1.1      cgd 				ch_data[unit].sloto =p2copy(bb);
1.1      cgd 				ch_data[unit].slots =p2copy(bb);
1.1      cgd 				ch_data[unit].imexo =p2copy(bb);
1.1      cgd 				ch_data[unit].imexs =p2copy(bb);
1.1      cgd 				ch_data[unit].driveo =p2copy(bb);
1.1      cgd 				ch_data[unit].drives =p2copy(bb);
1.1      cgd 				break;
1.1      cgd 			case 0x1e:
1.1      cgd 				ch_data[unit].rot = (*b)&1;
1.1      cgd 				break;
1.1      cgd 			case 0x1f:
1.1      cgd 				ch_data[unit].stor = *b&0xf;
1.1      cgd 				bb+=2;
1.1      cgd 				ch_data[unit].stor =p4copy(bb);
1.1      cgd 				break;
1.1      cgd 			default:
1.1      cgd 				break;
1.1      cgd 		}
1.1      cgd 		b+=pl;
1.1      cgd 		i+=pl+2;
1.1      cgd 	}
1.1      cgd 	if (ch_debug)
1.1      cgd 	{
1.1      cgd 		printf("unit %d: cht(%d-%d)slot(%d-%d)imex(%d-%d)cts(%d-%d) %s rotate\n",
1.1      cgd 				unit,
1.1      cgd 				ch_data[unit].chmo,
1.1      cgd 				ch_data[unit].chms,
1.1      cgd 				ch_data[unit].sloto,
1.1      cgd 				ch_data[unit].slots,
1.1      cgd 				ch_data[unit].imexo,
1.1      cgd 				ch_data[unit].imexs,
1.1      cgd 				ch_data[unit].driveo,
1.1      cgd 				ch_data[unit].drives,
1.1      cgd 				ch_data[unit].rot?"can":"can't");
1.1      cgd 	}
1.1      cgd 	return(TRUE);
1.1      cgd }
1.1      cgd
1.1      cgd /*******************************************************\
1.1      cgd * ask the scsi driver to perform a command for us.	*
1.1      cgd * Call it through the switch table, and tell it which	*
1.1      cgd * sub-unit we want, and what target and lu we wish to	*
1.1      cgd * talk to. Also tell it where to find the command	*
1.1      cgd * how long int is.					*
1.1      cgd * Also tell it where to read/write the data, and how	*
1.1      cgd * long the data is supposed to be			*
1.1      cgd \*******************************************************/
1.1      cgd int	ch_scsi_cmd(unit,scsi_cmd,cmdlen,data_addr,datalen,timeout,flags)
1.1      cgd
1.1      cgd int	unit,flags;
1.1      cgd struct	scsi_generic *scsi_cmd;
1.1      cgd int	cmdlen;
1.1      cgd int	timeout;
1.1      cgd u_char	*data_addr;
1.1      cgd int	datalen;
1.1      cgd {
1.1      cgd 	struct	scsi_xfer *xs;
1.1      cgd 	int	retval;
1.1      cgd 	int	s;
1.1      cgd
1.1      cgd 	if(ch_debug||(scsi_debug & PRINTROUTINES)) printf("\nch_scsi_cmd%d %x",
1.1      cgd 				unit,scsi_cmd->opcode);
1.1      cgd 	if(ch_data[unit].sc_sw)	/* If we have a scsi driver */
1.1      cgd 	{
1.1      cgd
1.1      cgd 		xs = &(ch_scsi_xfer[unit]);
1.1      cgd 		if(!(flags & SCSI_NOMASK))
1.1      cgd 			s = splbio();
1.1      cgd 		ch_xfer_block_wait[unit]++;	/* there is someone waiting */
1.1      cgd 		while (xs->flags & INUSE)
1.1      cgd 		{
1.4  mycroft 			tsleep(&ch_xfer_block_wait[unit],PRIBIO+1,"cd_cmd1",0);
1.1      cgd 		}
1.1      cgd 		ch_xfer_block_wait[unit]--;
1.1      cgd 		xs->flags = INUSE;
1.1      cgd 		if(!(flags & SCSI_NOMASK))
1.1      cgd 			splx(s);
1.1      cgd
1.1      cgd 		/*******************************************************\
1.1      cgd 		* Fill out the scsi_xfer structure			*
1.1      cgd 		\*******************************************************/
1.1      cgd 		xs->flags	|=	flags;
1.1      cgd 		xs->adapter	=	ch_data[unit].ctlr;
1.1      cgd 		xs->targ	=	ch_data[unit].targ;
1.1      cgd 		xs->lu		=	ch_data[unit].lu;
1.1      cgd 		xs->retries	=	CH_RETRIES;
1.1      cgd 		xs->timeout	=	timeout;
1.1      cgd 		xs->cmd		=	scsi_cmd;
1.1      cgd 		xs->cmdlen	=	cmdlen;
1.1      cgd 		xs->data	=	data_addr;
1.1      cgd 		xs->datalen	=	datalen;
1.1      cgd 		xs->resid	=	datalen;
1.1      cgd 		xs->when_done	=	(flags & SCSI_NOMASK)
1.1      cgd 					?(int (*)())0
1.1      cgd 					:ch_done;
1.1      cgd 		xs->done_arg	=	unit;
1.1      cgd 		xs->done_arg2	=	(int)xs;
1.1      cgd retry:		xs->error	=	XS_NOERROR;
1.1      cgd 		xs->bp		=	0;
1.1      cgd 		ch_data[unit].lsterr=0;
1.1      cgd 		retval = (*(ch_data[unit].sc_sw->scsi_cmd))(xs);
1.1      cgd 		switch(retval)
1.1      cgd 		{
1.1      cgd 		case	SUCCESSFULLY_QUEUED:
1.1      cgd 			while(!(xs->flags & ITSDONE))
1.4  mycroft 				tsleep(xs,PRIBIO+1,"cd_cmd2",0);
1.1      cgd
1.1      cgd 		case	HAD_ERROR:
1.1      cgd 		case	COMPLETE:
1.1      cgd 			switch(xs->error)
1.1      cgd 			{
1.1      cgd 			case	XS_NOERROR:
1.1      cgd 				retval = ESUCCESS;
1.1      cgd 				break;
1.1      cgd 			case	XS_SENSE:
1.1      cgd 				retval = (ch_interpret_sense(unit,xs));
1.1      cgd 				break;
1.1      cgd 			case	XS_DRIVER_STUFFUP:
1.1      cgd 				retval = EIO;
1.1      cgd 				break;
1.1      cgd 			case    XS_TIMEOUT:
1.1      cgd 				if(xs->retries-- )
1.1      cgd 				{
1.1      cgd 					xs->flags &= ~ITSDONE;
1.1      cgd 					goto retry;
1.1      cgd 				}
1.1      cgd 				retval = EIO;
1.1      cgd 				break;
1.1      cgd 			case    XS_BUSY:
1.1      cgd 				if(xs->retries-- )
1.1      cgd 				{
1.1      cgd 					xs->flags &= ~ITSDONE;
1.1      cgd 					goto retry;
1.1      cgd 				}
1.1      cgd 				retval = EIO;
1.1      cgd 				break;
1.1      cgd 			default:
1.1      cgd 				retval = EIO;
1.1      cgd 				printf("st%d: unknown error category from scsi driver\n"
1.1      cgd 					,unit);
1.1      cgd 				break;
1.1      cgd 			}
1.1      cgd 			break;
1.1      cgd 		case 	TRY_AGAIN_LATER:
1.1      cgd 			if(xs->retries-- )
1.1      cgd 			{
1.1      cgd 				xs->flags &= ~ITSDONE;
1.1      cgd 				goto retry;
1.1      cgd 			}
1.1      cgd 			retval = EIO;
1.1      cgd 			break;
1.1      cgd 		default:
1.1      cgd 			retval = EIO;
1.1      cgd 		}
1.1      cgd 		xs->flags = 0;	/* it's free! */
1.1      cgd 		chstart(unit);
1.1      cgd 	}
1.1      cgd 	else
1.1      cgd 	{
1.1      cgd 		printf("chd: not set up\n",unit);
1.1      cgd 		return(EINVAL);
1.1      cgd 	}
1.1      cgd 	return(retval);
1.1      cgd }
1.1      cgd /***************************************************************\
1.1      cgd * Look at the returned sense and act on the error and detirmine	*
1.1      cgd * The unix error number to pass back... (0 = report no error)	*
1.1      cgd \***************************************************************/
1.1      cgd
1.1      cgd int	ch_interpret_sense(unit,xs)
1.1      cgd int	unit;
1.1      cgd struct	scsi_xfer	*xs;
1.1      cgd {
1.1      cgd 	struct	scsi_sense_data *sense;
1.1      cgd 	int	key;
1.1      cgd 	int	silent = xs->flags & SCSI_SILENT;
1.1      cgd
1.1      cgd 	/***************************************************************\
1.1      cgd 	* If errors are ok, report a success				*
1.1      cgd 	\***************************************************************/
1.1      cgd 	if(xs->flags & SCSI_ERR_OK) return(ESUCCESS);
1.1      cgd
1.1      cgd 	/***************************************************************\
1.1      cgd 	* Get the sense fields and work out what CLASS			*
1.1      cgd 	\***************************************************************/
1.1      cgd 	sense = &(xs->sense);
1.1      cgd 	switch(sense->error_class)
1.1      cgd 	{
1.1      cgd 	/***************************************************************\
1.1      cgd 	* If it's class 7, use the extended stuff and interpret the key	*
1.1      cgd 	\***************************************************************/
1.1      cgd 	case 7:
1.1      cgd 		{
1.1      cgd 		key=sense->ext.extended.sense_key;
1.1      cgd 		if(sense->ext.extended.ili)
1.1      cgd 			if(!silent)
1.1      cgd 			{
1.1      cgd 				printf("length error ");
1.1      cgd 			}
1.1      cgd 			if(sense->valid)
1.1      cgd 				xs->resid = ntohl(*((long *)sense->ext.extended.info));
1.1      cgd 				if(xs->bp)
1.1      cgd 				{
1.1      cgd 					xs->bp->b_flags |= B_ERROR;
1.1      cgd 					return(ESUCCESS);
1.1      cgd 				}
1.1      cgd 		if(sense->ext.extended.eom)
1.1      cgd 			if(!silent) printf("end of medium ");
1.1      cgd 		if(sense->ext.extended.filemark)
1.1      cgd 			if(!silent) printf("filemark ");
1.1      cgd 		if(ch_debug)
1.1      cgd 		{
1.1      cgd 			printf("code%x class%x valid%x\n"
1.1      cgd 					,sense->error_code
1.1      cgd 					,sense->error_class
1.1      cgd 					,sense->valid);
1.1      cgd 			printf("seg%x key%x ili%x eom%x fmark%x\n"
1.1      cgd 					,sense->ext.extended.segment
1.1      cgd 					,sense->ext.extended.sense_key
1.1      cgd 					,sense->ext.extended.ili
1.1      cgd 					,sense->ext.extended.eom
1.1      cgd 					,sense->ext.extended.filemark);
1.1      cgd 			printf("info: %x %x %x %x followed by %d extra bytes\n"
1.1      cgd 					,sense->ext.extended.info[0]
1.1      cgd 					,sense->ext.extended.info[1]
1.1      cgd 					,sense->ext.extended.info[2]
1.1      cgd 					,sense->ext.extended.info[3]
1.1      cgd 					,sense->ext.extended.extra_len);
1.1      cgd 			printf("extra: %x %x %x %x %x %x %x %x %x %x %x %x %x %x %x %x\n"
1.1      cgd 					,sense->ext.extended.extra_bytes[0]
1.1      cgd 					,sense->ext.extended.extra_bytes[1]
1.1      cgd 					,sense->ext.extended.extra_bytes[2]
1.1      cgd 					,sense->ext.extended.extra_bytes[3]
1.1      cgd 					,sense->ext.extended.extra_bytes[4]
1.1      cgd 					,sense->ext.extended.extra_bytes[5]
1.1      cgd 					,sense->ext.extended.extra_bytes[6]
1.1      cgd 					,sense->ext.extended.extra_bytes[7]
1.1      cgd 					,sense->ext.extended.extra_bytes[8]
1.1      cgd 					,sense->ext.extended.extra_bytes[9]
1.1      cgd 					,sense->ext.extended.extra_bytes[10]
1.1      cgd 					,sense->ext.extended.extra_bytes[11]
1.1      cgd 					,sense->ext.extended.extra_bytes[12]
1.1      cgd 					,sense->ext.extended.extra_bytes[13]
1.1      cgd 					,sense->ext.extended.extra_bytes[14]
1.1      cgd 					,sense->ext.extended.extra_bytes[15]);
1.1      cgd
1.1      cgd 		}
1.1      cgd 		switch(key)
1.1      cgd 		{
1.1      cgd 		case	0x0:
1.1      cgd 			return(ESUCCESS);
1.1      cgd 		case	0x1:
1.1      cgd 			if(!silent)
1.1      cgd 			{
1.1      cgd 				printf("st%d: soft error(corrected) ", unit);
1.1      cgd 				if(sense->valid)
1.1      cgd 				{
1.1      cgd 			   		printf("block no. %d (decimal)\n",
1.1      cgd 			  		(sense->ext.extended.info[0] <<24)|
1.1      cgd 			  		(sense->ext.extended.info[1] <<16)|
1.1      cgd 			  		(sense->ext.extended.info[2] <<8)|
1.1      cgd 			  		(sense->ext.extended.info[3] ));
1.1      cgd 				}
1.1      cgd 			 	else
1.1      cgd 				{
1.1      cgd 			 		printf("\n");
1.1      cgd 				}
1.1      cgd 			}
1.1      cgd 			return(ESUCCESS);
1.1      cgd 		case	0x2:
1.1      cgd 			if(!silent) printf("st%d: not ready\n ", unit);
1.1      cgd 			ch_data[unit].lsterr=(sense->ext.extended.info[12]<<8)|
1.1      cgd 								sense->ext.extended.info[13] ;
1.1      cgd 			return(ENODEV);
1.1      cgd 		case	0x3:
1.1      cgd 			if(!silent)
1.1      cgd 			{
1.1      cgd 				printf("st%d: medium error ", unit);
1.1      cgd 				if(sense->valid)
1.1      cgd 				{
1.1      cgd 			   		printf("block no. %d (decimal)\n",
1.1      cgd 			  		(sense->ext.extended.info[0] <<24)|
1.1      cgd 			  		(sense->ext.extended.info[1] <<16)|
1.1      cgd 			  		(sense->ext.extended.info[2] <<8)|
1.1      cgd 			  		(sense->ext.extended.info[3] ));
1.1      cgd 				}
1.1      cgd 			 	else
1.1      cgd 				{
1.1      cgd 			 		printf("\n");
1.1      cgd 				}
1.1      cgd 			}
1.1      cgd 			return(EIO);
1.1      cgd 		case	0x4:
1.1      cgd 			if(!silent) printf("st%d: non-media hardware failure\n ",
1.1      cgd 				unit);
1.1      cgd 			ch_data[unit].lsterr=(sense->ext.extended.info[12]<<8)|
1.1      cgd 								sense->ext.extended.info[13] ;
1.1      cgd 			return(EIO);
1.1      cgd 		case	0x5:
1.1      cgd 			if(!silent) printf("st%d: illegal request\n ", unit);
1.1      cgd 			ch_data[unit].lsterr=(sense->ext.extended.info[12]<<8)|
1.1      cgd 								sense->ext.extended.info[13] ;
1.1      cgd 			return(EINVAL);
1.1      cgd 		case	0x6:
1.2  mycroft 			if(!silent)printf("st%d: media change\n", unit);
1.1      cgd 			ch_data[unit].lsterr=(sense->ext.extended.info[12]<<8)|
1.1      cgd 								sense->ext.extended.info[13] ;
1.1      cgd 			ch_info_valid[unit] = FALSE;
1.1      cgd 			if (ch_data[unit].flags & CH_OPEN) /* TEMP!!!! */
1.1      cgd 				return(EIO);
1.1      cgd 			else
1.1      cgd 				return(ESUCCESS);
1.1      cgd 		case	0x7:
1.1      cgd 			if(!silent)
1.1      cgd 			{
1.1      cgd 				printf("st%d: attempted protection violation "
1.1      cgd 								, unit);
1.1      cgd 				if(sense->valid)
1.1      cgd 				{
1.1      cgd 			   		printf("block no. %d (decimal)\n",
1.1      cgd 			  		(sense->ext.extended.info[0] <<24)|
1.1      cgd 			  		(sense->ext.extended.info[1] <<16)|
1.1      cgd 			  		(sense->ext.extended.info[2] <<8)|
1.1      cgd 			  		(sense->ext.extended.info[3] ));
1.1      cgd 				}
1.1      cgd 			 	else
1.1      cgd 				{
1.1      cgd 			 		printf("\n");
1.1      cgd 				}
1.1      cgd 			}
1.1      cgd 			return(EACCES);
1.1      cgd 		case	0x8:
1.1      cgd 			if(!silent)
1.1      cgd 			{
1.1      cgd 				printf("st%d: block wrong state (worm)\n "
1.1      cgd 							, unit);
1.1      cgd 				if(sense->valid)
1.1      cgd 				{
1.1      cgd 			   		printf("block no. %d (decimal)\n",
1.1      cgd 			  		(sense->ext.extended.info[0] <<24)|
1.1      cgd 			  		(sense->ext.extended.info[1] <<16)|
1.1      cgd 			  		(sense->ext.extended.info[2] <<8)|
1.1      cgd 			  		(sense->ext.extended.info[3] ));
1.1      cgd 				}
1.1      cgd 			 	else
1.1      cgd 				{
1.1      cgd 			 		printf("\n");
1.1      cgd 				}
1.1      cgd 			}
1.1      cgd 			return(EIO);
1.1      cgd 		case	0x9:
1.1      cgd 			if(!silent) printf("st%d: vendor unique\n",
1.1      cgd 				unit);
1.1      cgd 			return(EIO);
1.1      cgd 		case	0xa:
1.1      cgd 			if(!silent) printf("st%d: copy aborted\n ",
1.1      cgd 				unit);
1.1      cgd 			return(EIO);
1.1      cgd 		case	0xb:
1.1      cgd 			if(!silent) printf("st%d: command aborted\n ",
1.1      cgd 				unit);
1.1      cgd 			ch_data[unit].lsterr=(sense->ext.extended.info[12]<<8)|
1.1      cgd 								sense->ext.extended.info[13] ;
1.1      cgd 			return(EIO);
1.1      cgd 		case	0xc:
1.1      cgd 			if(!silent)
1.1      cgd 			{
1.1      cgd 				printf("st%d: search returned\n ", unit);
1.1      cgd 				if(sense->valid)
1.1      cgd 				{
1.1      cgd 			   		printf("block no. %d (decimal)\n",
1.1      cgd 			  		(sense->ext.extended.info[0] <<24)|
1.1      cgd 			  		(sense->ext.extended.info[1] <<16)|
1.1      cgd 			  		(sense->ext.extended.info[2] <<8)|
1.1      cgd 			  		(sense->ext.extended.info[3] ));
1.1      cgd 				}
1.1      cgd 			 	else
1.1      cgd 				{
1.1      cgd 			 		printf("\n");
1.1      cgd 				}
1.1      cgd 			}
1.1      cgd 			return(ESUCCESS);
1.1      cgd 		case	0xd:
1.1      cgd 			if(!silent) printf("st%d: volume overflow\n ",
1.1      cgd 				unit);
1.1      cgd 			return(ENOSPC);
1.1      cgd 		case	0xe:
1.1      cgd 			if(!silent)
1.1      cgd 			{
1.1      cgd 			 	printf("st%d: verify miscompare\n ", unit);
1.1      cgd 				if(sense->valid)
1.1      cgd 				{
1.1      cgd 			   		printf("block no. %d (decimal)\n",
1.1      cgd 			  		(sense->ext.extended.info[0] <<24)|
1.1      cgd 			  		(sense->ext.extended.info[1] <<16)|
1.1      cgd 			  		(sense->ext.extended.info[2] <<8)|
1.1      cgd 			  		(sense->ext.extended.info[3] ));
1.1      cgd 				}
1.1      cgd 			 	else
1.1      cgd 				{
1.1      cgd 			 		printf("\n");
1.1      cgd 				}
1.1      cgd 			}
1.1      cgd 			return(EIO);
1.1      cgd 		case	0xf:
1.1      cgd 			if(!silent) printf("st%d: unknown error key\n ",
1.1      cgd 				unit);
1.1      cgd 			return(EIO);
1.1      cgd 		}
1.1      cgd 		break;
1.1      cgd 	}
1.1      cgd 	/***************************************************************\
1.1      cgd 	* If it's NOT class 7, just report it.				*
1.1      cgd 	\***************************************************************/
1.1      cgd 	case 0:
1.1      cgd 	case 1:
1.1      cgd 	case 2:
1.1      cgd 	case 3:
1.1      cgd 	case 4:
1.1      cgd 	case 5:
1.1      cgd 	case 6:
1.1      cgd 		{
1.1      cgd 			if(!silent) printf("st%d: error class %d code %d\n",
1.1      cgd 				unit,
1.1      cgd 				sense->error_class,
1.1      cgd 				sense->error_code);
1.1      cgd 		if(sense->valid)
1.1      cgd 			if(!silent) printf("block no. %d (decimal)\n",
1.1      cgd 			(sense->ext.unextended.blockhi <<16),
1.1      cgd 			+ (sense->ext.unextended.blockmed <<8),
1.1      cgd 			+ (sense->ext.unextended.blocklow ));
1.1      cgd 		}
1.1      cgd 		return(EIO);
1.1      cgd 	}
1.1      cgd }
1.1      cgd
1.1      cgd
1.1      cgd