dev/qbus/rf.c

1.26  dholland /*	$NetBSD: rf.c,v 1.26 2014/03/16 05:20:29 dholland Exp $	*/
 1.1     ragge /*
 1.1     ragge  * Copyright (c) 2002 Jochen Kunz.
 1.1     ragge  * All rights reserved.
 1.1     ragge  *
 1.1     ragge  * Redistribution and use in source and binary forms, with or without
 1.1     ragge  * modification, are permitted provided that the following conditions
 1.1     ragge  * are met:
 1.1     ragge  * 1. Redistributions of source code must retain the above copyright
 1.1     ragge  *    notice, this list of conditions and the following disclaimer.
 1.1     ragge  * 2. Redistributions in binary form must reproduce the above copyright
 1.1     ragge  *    notice, this list of conditions and the following disclaimer in the
 1.1     ragge  *    documentation and/or other materials provided with the distribution.
 1.1     ragge  * 3. The name of Jochen Kunz may not be used to endorse or promote
 1.1     ragge  *    products derived from this software without specific prior
 1.1     ragge  *    written permission.
 1.1     ragge  *
 1.1     ragge  * THIS SOFTWARE IS PROVIDED BY JOCHEN KUNZ
 1.1     ragge  * ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED
 1.1     ragge  * TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
 1.1     ragge  * PURPOSE ARE DISCLAIMED.  IN NO EVENT SHALL JOCHEN KUNZ
 1.1     ragge  * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
 1.1     ragge  * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
 1.1     ragge  * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
 1.1     ragge  * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
 1.1     ragge  * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
 1.1     ragge  * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
 1.1     ragge  * POSSIBILITY OF SUCH DAMAGE.
 1.1     ragge  */
 1.1     ragge
 1.1     ragge /*
 1.1     ragge TODO:
 1.1     ragge - Better LBN bound checking, block padding for SD disks.
 1.6       wiz - Formatting / "Set Density"
 1.6       wiz - Better error handling / detailed error reason reportnig.
 1.1     ragge */
 1.3     lukem
 1.3     lukem #include <sys/cdefs.h>
1.26  dholland __KERNEL_RCSID(0, "$NetBSD: rf.c,v 1.26 2014/03/16 05:20:29 dholland Exp $");
 1.1     ragge
 1.1     ragge /* autoconfig stuff */
 1.1     ragge #include <sys/param.h>
 1.1     ragge #include <sys/device.h>
 1.1     ragge #include <sys/conf.h>
 1.1     ragge #include "locators.h"
 1.1     ragge #include "ioconf.h"
 1.1     ragge
 1.1     ragge /* bus_space / bus_dma */
1.17        ad #include <sys/bus.h>
 1.1     ragge
 1.1     ragge /* UniBus / QBus specific stuff */
 1.1     ragge #include <dev/qbus/ubavar.h>
 1.1     ragge
 1.1     ragge /* disk interface */
 1.1     ragge #include <sys/types.h>
 1.1     ragge #include <sys/disklabel.h>
 1.1     ragge #include <sys/disk.h>
 1.1     ragge
 1.1     ragge /* general system data and functions */
 1.1     ragge #include <sys/systm.h>
 1.1     ragge #include <sys/ioctl.h>
 1.1     ragge #include <sys/ioccom.h>
 1.1     ragge
 1.1     ragge /* physio / buffer handling */
 1.1     ragge #include <sys/buf.h>
 1.7      yamt #include <sys/bufq.h>
 1.1     ragge
 1.1     ragge /* tsleep / sleep / wakeup */
 1.1     ragge #include <sys/proc.h>
 1.1     ragge /* hz for above */
 1.1     ragge #include <sys/kernel.h>
 1.1     ragge
 1.1     ragge /* bitdefinitions for RX211 */
 1.1     ragge #include <dev/qbus/rfreg.h>
 1.1     ragge
 1.1     ragge
 1.1     ragge #define	RFS_DENS	0x0001		/* single or double density */
 1.1     ragge #define	RFS_AD		0x0002		/* density auto detect */
 1.1     ragge #define	RFS_NOTINIT	0x0000		/* not initialized */
 1.1     ragge #define	RFS_PROBING	0x0010		/* density detect / verify started */
 1.1     ragge #define	RFS_FBUF	0x0020		/* Fill Buffer */
 1.1     ragge #define	RFS_EBUF	0x0030		/* Empty Buffer */
 1.1     ragge #define	RFS_WSEC	0x0040		/* Write Sector */
 1.1     ragge #define	RFS_RSEC	0x0050		/* Read Sector */
 1.1     ragge #define	RFS_SMD		0x0060		/* Set Media Density */
 1.1     ragge #define	RFS_RSTAT	0x0070		/* Read Status */
 1.1     ragge #define	RFS_WDDS	0x0080		/* Write Deleted Data Sector */
 1.1     ragge #define	RFS_REC		0x0090		/* Read Error Code */
 1.1     ragge #define	RFS_IDLE	0x00a0		/* controller is idle */
 1.1     ragge #define	RFS_CMDS	0x00f0		/* command mask */
 1.4     ragge #define	RFS_OPEN_A	0x0100		/* partition a open */
 1.4     ragge #define	RFS_OPEN_B	0x0200		/* partition b open */
 1.4     ragge #define	RFS_OPEN_C	0x0400		/* partition c open */
 1.4     ragge #define	RFS_OPEN_MASK	0x0f00		/* mask for open partitions */
 1.4     ragge #define RFS_OPEN_SHIFT	8		/* to shift 1 to get RFS_OPEN_A */
 1.1     ragge #define	RFS_SETCMD(rf, state)	((rf) = ((rf) & ~RFS_CMDS) | (state))
 1.1     ragge
 1.1     ragge
 1.1     ragge
 1.1     ragge /* autoconfig stuff */
1.19      matt static int rfc_match(device_t, cfdata_t, void *);
1.19      matt static void rfc_attach(device_t, device_t, void *);
1.19      matt static int rf_match(device_t, cfdata_t, void *);
1.19      matt static void rf_attach(device_t, device_t, void *);
 1.1     ragge static int rf_print(void *, const char *);
 1.1     ragge
 1.6       wiz /* device interface functions / interface to disk(9) */
 1.1     ragge dev_type_open(rfopen);
 1.1     ragge dev_type_close(rfclose);
 1.1     ragge dev_type_read(rfread);
 1.1     ragge dev_type_write(rfwrite);
 1.1     ragge dev_type_ioctl(rfioctl);
 1.1     ragge dev_type_strategy(rfstrategy);
 1.1     ragge dev_type_dump(rfdump);
 1.1     ragge dev_type_size(rfsize);
 1.1     ragge
 1.1     ragge
 1.1     ragge /* Entries in block and character major device number switch table. */
 1.1     ragge const struct bdevsw rf_bdevsw = {
1.26  dholland 	.d_open = rfopen,
1.26  dholland 	.d_close = rfclose,
1.26  dholland 	.d_strategy = rfstrategy,
1.26  dholland 	.d_ioctl = rfioctl,
1.26  dholland 	.d_dump = rfdump,
1.26  dholland 	.d_psize = rfsize,
1.26  dholland 	.d_flag = D_DISK
 1.1     ragge };
 1.1     ragge
 1.1     ragge const struct cdevsw rf_cdevsw = {
1.26  dholland 	.d_open = rfopen,
1.26  dholland 	.d_close = rfclose,
1.26  dholland 	.d_read = rfread,
1.26  dholland 	.d_write = rfwrite,
1.26  dholland 	.d_ioctl = rfioctl,
1.26  dholland 	.d_stop = nostop,
1.26  dholland 	.d_tty = notty,
1.26  dholland 	.d_poll = nopoll,
1.26  dholland 	.d_mmap = nommap,
1.26  dholland 	.d_kqfilter = nokqfilter,
1.26  dholland 	.d_flag = D_DISK
 1.1     ragge };
 1.1     ragge
 1.1     ragge
 1.1     ragge
 1.1     ragge struct rfc_softc {
1.19      matt 	device_t sc_dev;		/* common device data */
1.19      matt 	device_t sc_childs[2];		/* child devices */
 1.1     ragge 	struct evcnt sc_intr_count;	/* Interrupt counter for statistics */
 1.1     ragge 	struct buf *sc_curbuf;		/* buf that is currently in work */
 1.6       wiz 	bus_space_tag_t sc_iot;		/* bus_space I/O tag */
 1.6       wiz 	bus_space_handle_t sc_ioh;	/* bus_space I/O handle */
 1.1     ragge 	bus_dma_tag_t sc_dmat;		/* bus_dma DMA tag */
 1.1     ragge 	bus_dmamap_t sc_dmam;		/* bus_dma DMA map */
1.13  christos 	void *sc_bufidx;		/* current position in buffer data */
 1.1     ragge 	int sc_curchild;		/* child whos bufq is in work */
 1.1     ragge 	int sc_bytesleft;		/* bytes left to transfer */
 1.1     ragge 	u_int8_t type;			/* controller type, 1 or 2 */
 1.1     ragge };
 1.1     ragge
 1.1     ragge
 1.1     ragge
1.19      matt CFATTACH_DECL_NEW(
 1.1     ragge 	rfc,
 1.1     ragge 	sizeof(struct rfc_softc),
 1.1     ragge 	rfc_match,
 1.1     ragge 	rfc_attach,
 1.1     ragge 	NULL,
 1.8    simonb 	NULL
 1.1     ragge );
 1.1     ragge
 1.1     ragge
 1.1     ragge
 1.1     ragge struct rf_softc {
1.19      matt 	device_t sc_dev;		/* common device data */
 1.1     ragge 	struct disk sc_disk;		/* common disk device data */
1.19      matt 	struct rfc_softc *sc_rfc;	/* our parent */
 1.9      yamt 	struct bufq_state *sc_bufq;	/* queue of pending transfers */
 1.1     ragge 	int sc_state;			/* state of drive */
 1.1     ragge 	u_int8_t sc_dnum;		/* drive number, 0 or 1 */
 1.1     ragge };
 1.1     ragge
 1.1     ragge
 1.1     ragge
1.19      matt CFATTACH_DECL_NEW(
 1.1     ragge 	rf,
 1.1     ragge 	sizeof(struct rf_softc),
 1.1     ragge 	rf_match,
 1.1     ragge 	rf_attach,
 1.1     ragge 	NULL,
 1.1     ragge 	NULL
 1.1     ragge );
 1.1     ragge
 1.1     ragge
 1.1     ragge
 1.1     ragge struct rfc_attach_args {
 1.1     ragge 	u_int8_t type;		/* controller type, 1 or 2 */
 1.1     ragge 	u_int8_t dnum;		/* drive number, 0 or 1 */
 1.1     ragge };
 1.1     ragge
 1.1     ragge
 1.1     ragge
1.19      matt const struct dkdriver rfdkdriver = {
 1.1     ragge 	rfstrategy
 1.1     ragge };
 1.1     ragge
 1.1     ragge
 1.1     ragge
 1.1     ragge /* helper functions */
 1.1     ragge int rfc_sendcmd(struct rfc_softc *, int, int, int);
 1.4     ragge struct rf_softc* get_new_buf( struct rfc_softc *);
 1.1     ragge static void rfc_intr(void *);
 1.1     ragge
 1.1     ragge
 1.1     ragge
 1.1     ragge /*
 1.1     ragge  * Issue a reset command to the controller and look for the bits in
 1.1     ragge  * RX2CS and RX2ES.
 1.1     ragge  * RX2CS_RX02 and / or RX2CS_DD can be set,
 1.1     ragge  * RX2ES has to be set, all other bits must be 0
 1.1     ragge  */
 1.1     ragge int
1.19      matt rfc_match(device_t parent, cfdata_t match, void *aux)
 1.1     ragge {
 1.1     ragge 	struct uba_attach_args *ua = aux;
 1.1     ragge 	int i;
 1.1     ragge
 1.1     ragge 	/* Issue reset command. */
 1.1     ragge 	bus_space_write_2(ua->ua_iot, ua->ua_ioh, RX2CS, RX2CS_INIT);
 1.1     ragge 	/* Wait for the controller to become ready, that is when
 1.1     ragge 	 * RX2CS_DONE, RX2ES_RDY and RX2ES_ID are set. */
 1.1     ragge 	for (i = 0 ; i < 20 ; i++) {
 1.1     ragge 		if ((bus_space_read_2(ua->ua_iot, ua->ua_ioh, RX2CS)
 1.1     ragge 		    & RX2CS_DONE) != 0
 1.1     ragge 		    && (bus_space_read_2(ua->ua_iot, ua->ua_ioh, RX2ES)
 1.1     ragge 		    & (RX2ES_RDY | RX2ES_ID)) != 0)
 1.1     ragge 			break;
 1.1     ragge 		DELAY(100000);	/* wait 100ms */
 1.1     ragge 	}
 1.1     ragge 	/*
 1.1     ragge 	 * Give up if the timeout has elapsed
 1.1     ragge 	 * and the controller is not ready.
 1.1     ragge 	 */
 1.1     ragge 	if (i >= 20)
 1.1     ragge 		return(0);
 1.1     ragge 	/*
 1.1     ragge 	 * Issue a Read Status command with interrupt enabled.
 1.1     ragge 	 * The uba(4) driver wants to catch the interrupt to get the
 1.1     ragge 	 * interrupt vector and level of the device
 1.1     ragge 	 */
 1.1     ragge 	bus_space_write_2(ua->ua_iot, ua->ua_ioh, RX2CS,
 1.1     ragge 	    RX2CS_RSTAT | RX2CS_IE);
 1.1     ragge 	/*
 1.1     ragge 	 * Wait for command to finish, ignore errors and
 1.1     ragge 	 * abort if the controller does not respond within the timeout
 1.1     ragge 	 */
 1.1     ragge 	for (i = 0 ; i < 20 ; i++) {
 1.1     ragge 		if ((bus_space_read_2(ua->ua_iot, ua->ua_ioh, RX2CS)
 1.1     ragge 		    & (RX2CS_DONE | RX2CS_IE)) != 0
 1.1     ragge 		    && (bus_space_read_2(ua->ua_iot, ua->ua_ioh, RX2ES)
 1.1     ragge 		    & RX2ES_RDY) != 0 )
 1.1     ragge 			return(1);
 1.1     ragge 		DELAY(100000);	/* wait 100ms */
 1.1     ragge 	}
 1.1     ragge 	return(0);
 1.1     ragge }
 1.1     ragge
 1.1     ragge
 1.1     ragge
 1.1     ragge /* #define RX02_PROBE 1 */
 1.1     ragge #ifdef RX02_PROBE
 1.1     ragge /*
 1.1     ragge  * Probe the density of an inserted floppy disk.
 1.1     ragge  * This is done by reading a sector from disk.
 1.1     ragge  * Return -1 on error, 0 on SD and 1 on DD.
 1.1     ragge  */
 1.1     ragge int rfcprobedens(struct rfc_softc *, int);
 1.1     ragge int
 1.1     ragge rfcprobedens(struct rfc_softc *rfc_sc, int dnum)
 1.1     ragge {
 1.1     ragge 	int dens_flag;
 1.1     ragge 	int i;
 1.1     ragge
 1.1     ragge 	dens_flag = 0;
 1.1     ragge 	do {
 1.1     ragge 		bus_space_write_2(rfc_sc->sc_iot, rfc_sc->sc_ioh, RX2CS,
 1.1     ragge 		    RX2CS_RSEC | (dens_flag == 0 ? 0 : RX2CS_DD)
 1.1     ragge 		    | (dnum == 0 ? 0 : RX2CS_US));
 1.1     ragge 		/*
 1.1     ragge 		 * Transfer request set?
 1.1     ragge 		 * Wait 50us, the controller needs this time to setle
 1.1     ragge 		 */
 1.1     ragge 		DELAY(50);
 1.1     ragge 		if ((bus_space_read_2(rfc_sc->sc_iot, rfc_sc->sc_ioh, RX2CS)
 1.1     ragge 		    & RX2CS_TR) == 0) {
 1.1     ragge 			printf("%s: did not respond to Read Sector CMD(1)\n",
1.19      matt 			    device_xname(rfc_sc->sc_dev));
 1.1     ragge 			return(-1);
 1.1     ragge 		}
 1.1     ragge 		bus_space_write_2(rfc_sc->sc_iot, rfc_sc->sc_ioh, RX2SA, 1);
 1.1     ragge 		/* Wait 50us, the controller needs this time to setle */
 1.1     ragge 		DELAY(50);
 1.1     ragge 		if ((bus_space_read_2(rfc_sc->sc_iot, rfc_sc->sc_ioh, RX2CS)
 1.1     ragge 		    & RX2CS_TR) == 0) {
 1.1     ragge 			printf("%s: did not respond to Read Sector CMD(2)\n",
1.19      matt 			    device_xname(rfc_sc->sc_dev));
 1.1     ragge 			return(-1);
 1.1     ragge 		}
 1.1     ragge 		bus_space_write_2(rfc_sc->sc_iot, rfc_sc->sc_ioh, RX2TA, 1);
 1.1     ragge 		/* Wait for the command to finish */
 1.1     ragge 		for (i = 0 ; i < 200 ; i++) {
 1.1     ragge 			if ((bus_space_read_2(rfc_sc->sc_iot, rfc_sc->sc_ioh,
 1.1     ragge 			    RX2CS) & RX2CS_DONE) != 0)
 1.1     ragge 				break;
 1.1     ragge 			DELAY(10000);	/* wait 10ms */
 1.1     ragge 		}
 1.1     ragge 		if (i >= 200) {
 1.1     ragge 			printf("%s: did not respond to Read Sector CMD(3)\n",
1.19      matt 			    device_xname(rfc_sc->sc_dev));
 1.1     ragge 			return(-1);
 1.1     ragge 		}
 1.1     ragge 		if ((bus_space_read_2(rfc_sc->sc_iot, rfc_sc->sc_ioh, RX2CS)
 1.1     ragge 		    & RX2CS_ERR) == 0)
 1.1     ragge 			return(dens_flag);
 1.1     ragge 	} while (rfc_sc->type == 2 && dens_flag++ == 0);
 1.1     ragge 	return(-1);
 1.1     ragge }
 1.1     ragge #endif /* RX02_PROBE */
 1.1     ragge
 1.1     ragge
 1.1     ragge
 1.1     ragge void
1.19      matt rfc_attach(device_t parent, device_t self, void *aux)
 1.1     ragge {
1.12   thorpej 	struct rfc_softc *rfc_sc = device_private(self);
 1.1     ragge 	struct uba_attach_args *ua = aux;
 1.1     ragge 	struct rfc_attach_args rfc_aa;
 1.1     ragge 	int i;
 1.1     ragge
1.19      matt 	rfc_sc->sc_dev = self;
 1.1     ragge 	rfc_sc->sc_iot = ua->ua_iot;
 1.1     ragge 	rfc_sc->sc_ioh = ua->ua_ioh;
 1.1     ragge 	rfc_sc->sc_dmat = ua->ua_dmat;
 1.1     ragge 	rfc_sc->sc_curbuf = NULL;
 1.1     ragge 	/* Tell the QBus busdriver about our interrupt handler. */
 1.1     ragge 	uba_intr_establish(ua->ua_icookie, ua->ua_cvec, rfc_intr, rfc_sc,
 1.1     ragge 	    &rfc_sc->sc_intr_count);
 1.1     ragge 	/* Attach to the interrupt counter, see evcnt(9) */
 1.1     ragge 	evcnt_attach_dynamic(&rfc_sc->sc_intr_count, EVCNT_TYPE_INTR,
1.19      matt 	    ua->ua_evcnt, device_xname(rfc_sc->sc_dev), "intr");
 1.1     ragge 	/* get a bus_dma(9) handle */
 1.1     ragge 	i = bus_dmamap_create(rfc_sc->sc_dmat, RX2_BYTE_DD, 1, RX2_BYTE_DD, 0,
 1.1     ragge 	    BUS_DMA_ALLOCNOW, &rfc_sc->sc_dmam);
 1.1     ragge 	if (i != 0) {
 1.4     ragge 		printf("rfc_attach: Error creating bus dma map: %d\n", i);
 1.1     ragge 		return;
 1.1     ragge 	}
 1.1     ragge
 1.1     ragge 	/* Issue reset command. */
 1.1     ragge 	bus_space_write_2(rfc_sc->sc_iot, rfc_sc->sc_ioh, RX2CS, RX2CS_INIT);
 1.1     ragge 	/*
 1.1     ragge 	 * Wait for the controller to become ready, that is when
 1.1     ragge 	 * RX2CS_DONE, RX2ES_RDY and RX2ES_ID are set.
 1.1     ragge 	 */
 1.1     ragge 	for (i = 0 ; i < 20 ; i++) {
 1.1     ragge 		if ((bus_space_read_2(rfc_sc->sc_iot, rfc_sc->sc_ioh, RX2CS)
 1.1     ragge 		    & RX2CS_DONE) != 0
 1.1     ragge 		    && (bus_space_read_2(rfc_sc->sc_iot, rfc_sc->sc_ioh, RX2ES)
 1.1     ragge 		    & (RX2ES_RDY | RX2ES_ID)) != 0)
 1.1     ragge 			break;
 1.1     ragge 		DELAY(100000);	/* wait 100ms */
 1.1     ragge 	}
 1.1     ragge 	/*
 1.1     ragge 	 * Give up if the timeout has elapsed
 1.1     ragge 	 * and the controller is not ready.
 1.1     ragge 	 */
 1.1     ragge 	if (i >= 20) {
 1.1     ragge 		printf(": did not respond to INIT CMD\n");
 1.1     ragge 		return;
 1.1     ragge 	}
 1.1     ragge 	/* Is ths a RX01 or a RX02? */
 1.1     ragge 	if ((bus_space_read_2(rfc_sc->sc_iot, rfc_sc->sc_ioh, RX2CS)
 1.1     ragge 	    & RX2CS_RX02) != 0) {
 1.1     ragge 		rfc_sc->type = 2;
 1.1     ragge 		rfc_aa.type = 2;
 1.1     ragge 	} else {
 1.1     ragge 		rfc_sc->type = 1;
 1.1     ragge 		rfc_aa.type = 1;
 1.1     ragge 	}
 1.1     ragge 	printf(": RX0%d\n", rfc_sc->type);
 1.1     ragge
 1.1     ragge #ifndef RX02_PROBE
 1.1     ragge 	/*
 1.1     ragge 	 * Bouth disk drievs and the controller are one physical unit.
 1.1     ragge 	 * If we found the controller, there will be bouth disk drievs.
 1.1     ragge 	 * So attach them.
 1.1     ragge 	 */
 1.1     ragge 	rfc_aa.dnum = 0;
1.19      matt 	rfc_sc->sc_childs[0] = config_found(rfc_sc->sc_dev, &rfc_aa, rf_print);
 1.1     ragge 	rfc_aa.dnum = 1;
1.19      matt 	rfc_sc->sc_childs[1] = config_found(rfc_sc->sc_dev, &rfc_aa, rf_print);
 1.1     ragge #else /* RX02_PROBE */
 1.1     ragge 	/*
 1.1     ragge 	 * There are clones of the DEC RX system with standard shugart
 1.1     ragge 	 * interface. In this case we can not be sure that there are
 1.1     ragge 	 * bouth disk drievs. So we want to do a detection of attached
 1.1     ragge 	 * drives. This is done by reading a sector from disk. This means
 1.6       wiz 	 * that there must be a formatted disk in the drive at boot time.
 1.6       wiz 	 * This is bad, but I did not find another way to detect the
 1.1     ragge 	 * (non)existence of a floppy drive.
 1.1     ragge 	 */
 1.1     ragge 	if (rfcprobedens(rfc_sc, 0) >= 0) {
 1.1     ragge 		rfc_aa.dnum = 0;
1.25       chs 		rfc_sc->sc_childs[0] = config_found(rfc_sc->sc_dev, &rfc_aa,
 1.1     ragge 		    rf_print);
 1.1     ragge 	} else
 1.1     ragge 		rfc_sc->sc_childs[0] = NULL;
 1.1     ragge 	if (rfcprobedens(rfc_sc, 1) >= 0) {
 1.1     ragge 		rfc_aa.dnum = 1;
1.25       chs 		rfc_sc->sc_childs[1] = config_found(rfc_sc->sc_dev, &rfc_aa,
 1.1     ragge 		    rf_print);
 1.1     ragge 	} else
 1.1     ragge 		rfc_sc->sc_childs[1] = NULL;
 1.1     ragge #endif /* RX02_PROBE */
 1.1     ragge 	return;
 1.1     ragge }
 1.1     ragge
 1.1     ragge
 1.1     ragge
 1.1     ragge int
1.19      matt rf_match(device_t parent, cfdata_t match, void *aux)
 1.1     ragge {
 1.1     ragge 	struct rfc_attach_args *rfc_aa = aux;
 1.1     ragge
 1.1     ragge 	/*
 1.1     ragge 	 * Only attach if the locator is wildcarded or
 1.1     ragge 	 * if the specified locator addresses the current device.
 1.1     ragge 	 */
 1.1     ragge 	if (match->cf_loc[RFCCF_DRIVE] == RFCCF_DRIVE_DEFAULT ||
 1.1     ragge 	    match->cf_loc[RFCCF_DRIVE] == rfc_aa->dnum)
 1.1     ragge 		return(1);
 1.1     ragge 	return(0);
 1.1     ragge }
 1.1     ragge
 1.1     ragge
 1.1     ragge
 1.1     ragge void
1.19      matt rf_attach(device_t parent, device_t self, void *aux)
 1.1     ragge {
1.12   thorpej 	struct rf_softc *rf_sc = device_private(self);
1.19      matt 	struct rfc_softc *rfc_sc = device_private(parent);
 1.1     ragge 	struct rfc_attach_args *rfc_aa = (struct rfc_attach_args *)aux;
 1.1     ragge 	struct disklabel *dl;
 1.1     ragge
1.19      matt 	rf_sc->sc_dev = self;
1.19      matt 	rf_sc->sc_rfc = rfc_sc;
 1.1     ragge 	rf_sc->sc_dnum = rfc_aa->dnum;
 1.1     ragge 	rf_sc->sc_state = 0;
1.19      matt 	disk_init(&rf_sc->sc_disk, device_xname(rf_sc->sc_dev), &rfdkdriver);
 1.1     ragge 	disk_attach(&rf_sc->sc_disk);
 1.1     ragge 	dl = rf_sc->sc_disk.dk_label;
 1.1     ragge 	dl->d_type = DTYPE_FLOPPY;		/* drive type */
 1.1     ragge 	dl->d_magic = DISKMAGIC;		/* the magic number */
 1.1     ragge 	dl->d_magic2 = DISKMAGIC;
 1.1     ragge 	dl->d_typename[0] = 'R';
 1.1     ragge 	dl->d_typename[1] = 'X';
 1.1     ragge 	dl->d_typename[2] = '0';
 1.1     ragge 	dl->d_typename[3] = rfc_sc->type == 1 ? '1' : '2';	/* type name */
 1.1     ragge 	dl->d_typename[4] = '\0';
 1.1     ragge 	dl->d_secsize = DEV_BSIZE;		/* bytes per sector */
 1.1     ragge 	/*
 1.1     ragge 	 * Fill in some values to have a initialized data structure. Some
 1.1     ragge 	 * values will be reset by rfopen() depending on the actual density.
 1.1     ragge 	 */
 1.1     ragge 	dl->d_nsectors = RX2_SECTORS;		/* sectors per track */
 1.1     ragge 	dl->d_ntracks = 1;								/* tracks per cylinder */
 1.1     ragge 	dl->d_ncylinders = RX2_TRACKS;		/* cylinders per unit */
 1.1     ragge 	dl->d_secpercyl = RX2_SECTORS;		/* sectors per cylinder */
 1.8    simonb 	dl->d_secperunit = RX2_SECTORS * RX2_TRACKS;	/* sectors per unit */
 1.1     ragge 	dl->d_rpm = 360;			/* rotational speed */
 1.1     ragge 	dl->d_interleave = 1;			/* hardware sector interleave */
 1.1     ragge 	/* number of partitions in following */
 1.1     ragge 	dl->d_npartitions = MAXPARTITIONS;
 1.1     ragge 	dl->d_bbsize = 0;		/* size of boot area at sn0, bytes */
 1.1     ragge 	dl->d_sbsize = 0;		/* max size of fs superblock, bytes */
 1.1     ragge 	/* number of sectors in partition */
 1.1     ragge 	dl->d_partitions[0].p_size = 501;
 1.1     ragge 	dl->d_partitions[0].p_offset = 0;	/* starting sector */
 1.1     ragge 	dl->d_partitions[0].p_fsize = 0;	/* fs basic fragment size */
 1.1     ragge 	dl->d_partitions[0].p_fstype = 0;	/* fs type */
 1.1     ragge 	dl->d_partitions[0].p_frag = 0;		/* fs fragments per block */
 1.1     ragge 	dl->d_partitions[1].p_size = RX2_SECTORS * RX2_TRACKS / 2;
 1.1     ragge 	dl->d_partitions[1].p_offset = 0;	/* starting sector */
 1.1     ragge 	dl->d_partitions[1].p_fsize = 0;	/* fs basic fragment size */
 1.1     ragge 	dl->d_partitions[1].p_fstype = 0;	/* fs type */
 1.1     ragge 	dl->d_partitions[1].p_frag = 0;		/* fs fragments per block */
 1.1     ragge 	dl->d_partitions[2].p_size = RX2_SECTORS * RX2_TRACKS;
 1.1     ragge 	dl->d_partitions[2].p_offset = 0;	/* starting sector */
 1.1     ragge 	dl->d_partitions[2].p_fsize = 0;	/* fs basic fragment size */
 1.1     ragge 	dl->d_partitions[2].p_fstype = 0;	/* fs type */
 1.1     ragge 	dl->d_partitions[2].p_frag = 0;		/* fs fragments per block */
 1.9      yamt 	bufq_alloc(&rf_sc->sc_bufq, "disksort", BUFQ_SORT_CYLINDER);
 1.1     ragge 	printf("\n");
 1.1     ragge 	return;
 1.1     ragge }
 1.1     ragge
 1.1     ragge
 1.1     ragge
 1.1     ragge int
 1.1     ragge rf_print(void *aux, const char *name)
 1.1     ragge {
 1.1     ragge 	struct rfc_attach_args *rfc_aa = aux;
 1.1     ragge
 1.1     ragge 	if (name != NULL)
 1.1     ragge 		aprint_normal("RX0%d at %s", rfc_aa->type, name);
 1.1     ragge 	aprint_normal(" drive %d", rfc_aa->dnum);
 1.1     ragge 	return(UNCONF);
 1.1     ragge }
 1.1     ragge
 1.1     ragge
 1.1     ragge
 1.1     ragge /* Send a command to the controller */
 1.1     ragge int
 1.1     ragge rfc_sendcmd(struct rfc_softc *rfc_sc, int cmd, int data1, int data2)
 1.1     ragge {
 1.1     ragge
 1.1     ragge 	/* Write command to CSR. */
 1.1     ragge 	bus_space_write_2(rfc_sc->sc_iot, rfc_sc->sc_ioh, RX2CS, cmd);
 1.1     ragge 	/* Wait 50us, the controller needs this time to setle. */
 1.1     ragge 	DELAY(50);
 1.1     ragge 	/* Write parameter 1 to DBR */
 1.1     ragge 	if ((cmd & RX2CS_FC) != RX2CS_RSTAT) {
 1.1     ragge 		/* Transfer request set? */
 1.1     ragge 		if ((bus_space_read_2(rfc_sc->sc_iot, rfc_sc->sc_ioh, RX2CS)
 1.1     ragge 		    & RX2CS_TR) == 0) {
 1.1     ragge 			printf("%s: did not respond to CMD %x (1)\n",
1.19      matt 			    device_xname(rfc_sc->sc_dev), cmd);
 1.1     ragge 			return(-1);
 1.1     ragge 		}
 1.1     ragge 		bus_space_write_2(rfc_sc->sc_iot, rfc_sc->sc_ioh, RX2DB,
 1.1     ragge 		    data1);
 1.1     ragge 	}
 1.1     ragge 	/* Write parameter 2 to DBR */
 1.1     ragge 	if ((cmd & RX2CS_FC) <= RX2CS_RSEC || (cmd & RX2CS_FC) == RX2CS_WDDS) {
 1.1     ragge 		/* Wait 50us, the controller needs this time to setle. */
 1.1     ragge 		DELAY(50);
 1.1     ragge 		/* Transfer request set? */
 1.1     ragge 		if ((bus_space_read_2(rfc_sc->sc_iot, rfc_sc->sc_ioh, RX2CS)
 1.1     ragge 		    & RX2CS_TR) == 0) {
 1.1     ragge 			printf("%s: did not respond to CMD %x (2)\n",
1.19      matt 			    device_xname(rfc_sc->sc_dev), cmd);
 1.1     ragge 			return(-1);
 1.1     ragge 		}
 1.1     ragge 		bus_space_write_2(rfc_sc->sc_iot, rfc_sc->sc_ioh, RX2DB,
 1.1     ragge 		    data2);
 1.1     ragge 	}
 1.1     ragge 	return(1);
 1.1     ragge }
 1.1     ragge
 1.1     ragge
 1.1     ragge
 1.1     ragge void
 1.1     ragge rfstrategy(struct buf *buf)
 1.1     ragge {
 1.1     ragge 	struct rf_softc *rf_sc;
 1.1     ragge 	struct rfc_softc *rfc_sc;
1.19      matt 	int s;
 1.1     ragge
1.19      matt 	if ((rf_sc = device_lookup_private(&rf_cd, DISKUNIT(buf->b_dev))) == NULL) {
 1.1     ragge 		buf->b_error = ENXIO;
 1.1     ragge 		biodone(buf);
 1.1     ragge 		return;
 1.1     ragge 	}
1.19      matt 	rfc_sc = rf_sc->sc_rfc;
 1.6       wiz 	/* We are going to operate on a non-open dev? PANIC! */
1.19      matt 	if ((rf_sc->sc_state & (1 << (DISKPART(buf->b_dev) + RFS_OPEN_SHIFT)))
 1.4     ragge 	    == 0)
 1.4     ragge 		panic("rfstrategy: can not operate on non-open drive %s "
1.24    cegger 		    "partition %"PRIu32, device_xname(rf_sc->sc_dev),
 1.4     ragge 		    DISKPART(buf->b_dev));
 1.1     ragge 	if (buf->b_bcount == 0) {
 1.1     ragge 		biodone(buf);
 1.1     ragge 		return;
 1.1     ragge 	}
 1.1     ragge 	/*
1.23      yamt 	 * bufq_put() operates on b_rawblkno. rfstrategy() gets
 1.1     ragge 	 * only b_blkno that is partition relative. As a floppy does not
 1.1     ragge 	 * have partitions b_rawblkno == b_blkno.
 1.1     ragge 	 */
 1.1     ragge 	buf->b_rawblkno = buf->b_blkno;
 1.1     ragge 	/*
 1.1     ragge 	 * from sys/kern/subr_disk.c:
 1.1     ragge 	 * Seek sort for disks.  We depend on the driver which calls us using
 1.1     ragge 	 * b_resid as the current cylinder number.
 1.1     ragge 	 */
1.19      matt 	s = splbio();
 1.1     ragge 	if (rfc_sc->sc_curbuf == NULL) {
 1.1     ragge 		rfc_sc->sc_curchild = rf_sc->sc_dnum;
 1.1     ragge 		rfc_sc->sc_curbuf = buf;
1.18     joerg 		rfc_sc->sc_bufidx = buf->b_data;
 1.1     ragge 		rfc_sc->sc_bytesleft = buf->b_bcount;
 1.1     ragge 		rfc_intr(rfc_sc);
 1.1     ragge 	} else {
 1.1     ragge 		buf->b_resid = buf->b_blkno / RX2_SECTORS;
1.23      yamt 		bufq_put(rf_sc->sc_bufq, buf);
 1.4     ragge 		buf->b_resid = 0;
 1.1     ragge 	}
1.19      matt 	splx(s);
 1.1     ragge }
 1.1     ragge
 1.4     ragge /*
 1.6       wiz  * Look if there is another buffer in the bufferqueue of this drive
 1.4     ragge  * and start to process it if there is one.
 1.4     ragge  * If the bufferqueue is empty, look at the bufferqueue of the other drive
 1.8    simonb  * that is attached to this controller.
 1.8    simonb  * Start procesing the bufferqueue of the other drive if it isn't empty.
 1.8    simonb  * Return a pointer to the softc structure of the drive that is now
 1.4     ragge  * ready to process a buffer or NULL if there is no buffer in either queues.
 1.4     ragge  */
 1.4     ragge struct rf_softc*
 1.8    simonb get_new_buf( struct rfc_softc *rfc_sc)
 1.4     ragge {
 1.4     ragge 	struct rf_softc *rf_sc;
 1.4     ragge 	struct rf_softc *other_drive;
 1.4     ragge
1.20     jkunz 	rf_sc = device_private(rfc_sc->sc_childs[rfc_sc->sc_curchild]);
1.23      yamt 	rfc_sc->sc_curbuf = bufq_get(rf_sc->sc_bufq);
 1.4     ragge 	if (rfc_sc->sc_curbuf != NULL) {
1.18     joerg 		rfc_sc->sc_bufidx = rfc_sc->sc_curbuf->b_data;
 1.4     ragge 		rfc_sc->sc_bytesleft = rfc_sc->sc_curbuf->b_bcount;
 1.4     ragge 	} else {
 1.4     ragge 		RFS_SETCMD(rf_sc->sc_state, RFS_IDLE);
1.20     jkunz 		other_drive = device_private(
1.20     jkunz 		    rfc_sc->sc_childs[ rfc_sc->sc_curchild == 0 ? 1 : 0]);
 1.8    simonb 		if (other_drive != NULL
1.23      yamt 		    && bufq_peek(other_drive->sc_bufq) != NULL) {
 1.4     ragge 			rfc_sc->sc_curchild = rfc_sc->sc_curchild == 0 ? 1 : 0;
 1.4     ragge 			rf_sc = other_drive;
1.23      yamt 			rfc_sc->sc_curbuf = bufq_get(rf_sc->sc_bufq);
1.18     joerg 			rfc_sc->sc_bufidx = rfc_sc->sc_curbuf->b_data;
 1.4     ragge 			rfc_sc->sc_bytesleft = rfc_sc->sc_curbuf->b_bcount;
 1.4     ragge 		} else
 1.4     ragge 			return(NULL);
 1.4     ragge 	}
 1.4     ragge 	return(rf_sc);
 1.4     ragge }
 1.4     ragge
 1.4     ragge
 1.4     ragge
 1.1     ragge void
 1.1     ragge rfc_intr(void *intarg)
 1.1     ragge {
 1.1     ragge 	struct rfc_softc *rfc_sc = intarg;
 1.1     ragge 	struct rf_softc *rf_sc;
 1.1     ragge 	int i;
 1.1     ragge
1.20     jkunz 	rf_sc = device_private(rfc_sc->sc_childs[rfc_sc->sc_curchild]);
1.21       dsl 	for (;;) {
 1.4     ragge 		/*
 1.4     ragge 		 * First clean up from previous command...
 1.4     ragge 		 */
 1.4     ragge 		switch (rf_sc->sc_state & RFS_CMDS) {
 1.4     ragge 		case RFS_PROBING:	/* density detect / verify started */
 1.4     ragge 			disk_unbusy(&rf_sc->sc_disk, 0, 1);
 1.4     ragge 			if ((bus_space_read_2(rfc_sc->sc_iot, rfc_sc->sc_ioh,
 1.4     ragge 			    RX2CS) & RX2CS_ERR) == 0) {
 1.4     ragge 				RFS_SETCMD(rf_sc->sc_state, RFS_IDLE);
 1.4     ragge 				wakeup(rf_sc);
 1.4     ragge 			} else {
 1.4     ragge 				if (rfc_sc->type == 2
 1.4     ragge 				    && (rf_sc->sc_state & RFS_DENS) == 0
 1.4     ragge 				    && (rf_sc->sc_state & RFS_AD) != 0) {
 1.4     ragge 					/* retry at DD */
 1.4     ragge 					rf_sc->sc_state |= RFS_DENS;
 1.4     ragge 					disk_busy(&rf_sc->sc_disk);
 1.8    simonb 					if (rfc_sendcmd(rfc_sc, RX2CS_RSEC
 1.8    simonb 					    | RX2CS_IE | RX2CS_DD |
 1.8    simonb 					    (rf_sc->sc_dnum == 0 ? 0 :
 1.4     ragge 					    RX2CS_US), 1, 1) < 0) {
 1.8    simonb 						disk_unbusy(&rf_sc->sc_disk,
 1.4     ragge 						    0, 1);
 1.4     ragge 						RFS_SETCMD(rf_sc->sc_state,
 1.4     ragge 						    RFS_NOTINIT);
 1.4     ragge 						wakeup(rf_sc);
 1.4     ragge 					}
 1.4     ragge 				} else {
 1.4     ragge 					printf("%s: density error.\n",
1.19      matt 					    device_xname(rf_sc->sc_dev));
 1.4     ragge 					RFS_SETCMD(rf_sc->sc_state,RFS_NOTINIT);
 1.1     ragge 					wakeup(rf_sc);
 1.1     ragge 				}
 1.4     ragge 			}
 1.4     ragge 			return;
 1.4     ragge 		case RFS_IDLE:	/* controller is idle */
 1.4     ragge 			if (rfc_sc->sc_curbuf->b_bcount
 1.4     ragge 			    % ((rf_sc->sc_state & RFS_DENS) == 0
 1.4     ragge 			    ? RX2_BYTE_SD : RX2_BYTE_DD) != 0) {
 1.4     ragge 				/*
 1.8    simonb 				 * can only handle blocks that are a multiple
 1.4     ragge 				 * of the physical block size
 1.4     ragge 				 */
1.15        ad 				rfc_sc->sc_curbuf->b_error = EIO;
 1.1     ragge 			}
 1.4     ragge 			RFS_SETCMD(rf_sc->sc_state, (rfc_sc->sc_curbuf->b_flags
 1.4     ragge 			    & B_READ) != 0 ? RFS_RSEC : RFS_FBUF);
 1.1     ragge 			break;
 1.4     ragge 		case RFS_RSEC:	/* Read Sector */
 1.4     ragge 			disk_unbusy(&rf_sc->sc_disk, 0, 1);
 1.4     ragge 			/* check for errors */
 1.8    simonb 			if ((bus_space_read_2(rfc_sc->sc_iot, rfc_sc->sc_ioh,
 1.4     ragge 			    RX2CS) & RX2CS_ERR) != 0) {
 1.4     ragge 				/* should do more verbose error reporting */
 1.8    simonb 				printf("rfc_intr: Error reading secotr: %x\n",
 1.4     ragge 				    bus_space_read_2(rfc_sc->sc_iot,
 1.4     ragge 				    rfc_sc->sc_ioh, RX2ES) );
1.15        ad 				rfc_sc->sc_curbuf->b_error = EIO;
 1.4     ragge 			}
 1.4     ragge 			RFS_SETCMD(rf_sc->sc_state, RFS_EBUF);
 1.1     ragge 			break;
 1.4     ragge 		case RFS_WSEC:	/* Write Sector */
 1.4     ragge 			i = (rf_sc->sc_state & RFS_DENS) == 0
 1.4     ragge 				? RX2_BYTE_SD : RX2_BYTE_DD;
 1.4     ragge 			disk_unbusy(&rf_sc->sc_disk, i, 0);
 1.4     ragge 			/* check for errors */
 1.8    simonb 			if ((bus_space_read_2(rfc_sc->sc_iot, rfc_sc->sc_ioh,
 1.4     ragge 			    RX2CS) & RX2CS_ERR) != 0) {
 1.4     ragge 				/* should do more verbose error reporting */
 1.4     ragge 				printf("rfc_intr: Error writing secotr: %x\n",
 1.4     ragge 				    bus_space_read_2(rfc_sc->sc_iot,
 1.4     ragge 				    rfc_sc->sc_ioh, RX2ES) );
1.15        ad 				rfc_sc->sc_curbuf->b_error = EIO;
 1.4     ragge 				break;
 1.4     ragge 			}
 1.4     ragge 			if (rfc_sc->sc_bytesleft > i) {
 1.4     ragge 				rfc_sc->sc_bytesleft -= i;
1.14        he 				rfc_sc->sc_bufidx =
1.14        he 				    (char *)rfc_sc->sc_bufidx + i;
 1.1     ragge 			} else {
 1.4     ragge 				biodone(rfc_sc->sc_curbuf);
 1.4     ragge 				rf_sc = get_new_buf( rfc_sc);
 1.4     ragge 				if (rf_sc == NULL)
 1.1     ragge 					return;
 1.1     ragge 			}
 1.4     ragge 			RFS_SETCMD(rf_sc->sc_state,
 1.4     ragge 			    (rfc_sc->sc_curbuf->b_flags & B_READ) != 0
 1.4     ragge 			    ? RFS_RSEC : RFS_FBUF);
 1.4     ragge 			break;
 1.4     ragge 		case RFS_FBUF:	/* Fill Buffer */
 1.4     ragge 			disk_unbusy(&rf_sc->sc_disk, 0, 0);
 1.4     ragge 			bus_dmamap_unload(rfc_sc->sc_dmat, rfc_sc->sc_dmam);
 1.4     ragge 			/* check for errors */
 1.8    simonb 			if ((bus_space_read_2(rfc_sc->sc_iot, rfc_sc->sc_ioh,
 1.4     ragge 			    RX2CS) & RX2CS_ERR) != 0) {
 1.4     ragge 				/* should do more verbose error reporting */
 1.4     ragge 				printf("rfc_intr: Error while DMA: %x\n",
 1.4     ragge 				    bus_space_read_2(rfc_sc->sc_iot,
 1.4     ragge 				    rfc_sc->sc_ioh, RX2ES));
1.15        ad 				rfc_sc->sc_curbuf->b_error = EIO;
 1.4     ragge 			}
 1.4     ragge 			RFS_SETCMD(rf_sc->sc_state, RFS_WSEC);
 1.4     ragge 			break;
 1.4     ragge 		case RFS_EBUF:	/* Empty Buffer */
 1.4     ragge 			i = (rf_sc->sc_state & RFS_DENS) == 0
 1.4     ragge 			    ? RX2_BYTE_SD : RX2_BYTE_DD;
 1.4     ragge 			disk_unbusy(&rf_sc->sc_disk, i, 1);
 1.4     ragge 			bus_dmamap_unload(rfc_sc->sc_dmat, rfc_sc->sc_dmam);
 1.4     ragge 			/* check for errors */
 1.8    simonb 			if ((bus_space_read_2(rfc_sc->sc_iot, rfc_sc->sc_ioh,
 1.4     ragge 			    RX2CS) & RX2CS_ERR) != 0) {
 1.4     ragge 				/* should do more verbose error reporting */
 1.4     ragge 				printf("rfc_intr: Error while DMA: %x\n",
 1.4     ragge 				    bus_space_read_2(rfc_sc->sc_iot,
 1.4     ragge 				    rfc_sc->sc_ioh, RX2ES));
1.15        ad 				rfc_sc->sc_curbuf->b_error = EIO;
 1.4     ragge 				break;
 1.4     ragge 			}
 1.4     ragge 			if (rfc_sc->sc_bytesleft > i) {
 1.4     ragge 				rfc_sc->sc_bytesleft -= i;
1.14        he 				rfc_sc->sc_bufidx =
1.14        he 				    (char *)rfc_sc->sc_bufidx + i;
 1.1     ragge 			} else {
 1.4     ragge 				biodone(rfc_sc->sc_curbuf);
 1.4     ragge 				rf_sc = get_new_buf( rfc_sc);
 1.4     ragge 				if (rf_sc == NULL)
 1.1     ragge 					return;
 1.1     ragge 			}
 1.4     ragge 			RFS_SETCMD(rf_sc->sc_state,
 1.4     ragge 			    (rfc_sc->sc_curbuf->b_flags & B_READ) != 0
 1.4     ragge 			    ? RFS_RSEC : RFS_FBUF);
 1.4     ragge 			break;
 1.4     ragge 		case RFS_NOTINIT: /* Device is not open */
 1.4     ragge 		case RFS_SMD:	/* Set Media Density */
 1.4     ragge 		case RFS_RSTAT:	/* Read Status */
 1.4     ragge 		case RFS_WDDS:	/* Write Deleted Data Sector */
 1.4     ragge 		case RFS_REC:	/* Read Error Code */
 1.4     ragge 		default:
1.20     jkunz 			panic("Impossible state in rfc_intr(1): 0x%x\n",
1.20     jkunz 			    rf_sc->sc_state & RFS_CMDS);
 1.1     ragge 		}
 1.1     ragge
1.15        ad 		if (rfc_sc->sc_curbuf->b_error != 0) {
 1.8    simonb 			/*
 1.8    simonb 			 * An error occurred while processing this buffer.
 1.4     ragge 			 * Finish it and try to get a new buffer to process.
 1.4     ragge 			 * Return if there are no buffers in the queues.
 1.4     ragge 			 * This loops until the queues are empty or a new
 1.4     ragge 			 * action was successfully scheduled.
 1.4     ragge 			 */
 1.4     ragge 			rfc_sc->sc_curbuf->b_resid = rfc_sc->sc_bytesleft;
 1.4     ragge 			rfc_sc->sc_curbuf->b_error = EIO;
 1.4     ragge 			biodone(rfc_sc->sc_curbuf);
 1.4     ragge 			rf_sc = get_new_buf( rfc_sc);
 1.4     ragge 			if (rf_sc == NULL)
 1.4     ragge 				return;
 1.4     ragge 			continue;
 1.4     ragge 		}
 1.1     ragge
 1.4     ragge 		/*
 1.4     ragge 		 * ... then initiate next command.
 1.4     ragge 		 */
 1.4     ragge 		switch (rf_sc->sc_state & RFS_CMDS) {
 1.4     ragge 		case RFS_EBUF:	/* Empty Buffer */
 1.4     ragge 			i = bus_dmamap_load(rfc_sc->sc_dmat, rfc_sc->sc_dmam,
 1.4     ragge 			    rfc_sc->sc_bufidx, (rf_sc->sc_state & RFS_DENS) == 0
 1.8    simonb 			    ? RX2_BYTE_SD : RX2_BYTE_DD,
 1.4     ragge 			    rfc_sc->sc_curbuf->b_proc, BUS_DMA_NOWAIT);
 1.4     ragge 			if (i != 0) {
 1.4     ragge 				printf("rfc_intr: Error loading dmamap: %d\n",
 1.4     ragge 				i);
1.15        ad 				rfc_sc->sc_curbuf->b_error = EIO;
 1.4     ragge 				break;
 1.4     ragge 			}
 1.4     ragge 			disk_busy(&rf_sc->sc_disk);
 1.4     ragge 			if (rfc_sendcmd(rfc_sc, RX2CS_EBUF | RX2CS_IE
 1.4     ragge 			    | ((rf_sc->sc_state & RFS_DENS) == 0 ? 0 : RX2CS_DD)
 1.4     ragge 			    | (rf_sc->sc_dnum == 0 ? 0 : RX2CS_US)
 1.8    simonb 			    | ((rfc_sc->sc_dmam->dm_segs[0].ds_addr
 1.4     ragge 			    & 0x30000) >>4), ((rf_sc->sc_state & RFS_DENS) == 0
 1.4     ragge 			    ? RX2_BYTE_SD : RX2_BYTE_DD) / 2,
 1.4     ragge 			    rfc_sc->sc_dmam->dm_segs[0].ds_addr & 0xffff) < 0) {
 1.4     ragge 				disk_unbusy(&rf_sc->sc_disk, 0, 1);
1.15        ad 				rfc_sc->sc_curbuf->b_error = EIO;
 1.8    simonb 				bus_dmamap_unload(rfc_sc->sc_dmat,
 1.4     ragge 				rfc_sc->sc_dmam);
 1.4     ragge 			}
 1.4     ragge 			break;
 1.4     ragge 		case RFS_FBUF:	/* Fill Buffer */
 1.4     ragge 			i = bus_dmamap_load(rfc_sc->sc_dmat, rfc_sc->sc_dmam,
 1.4     ragge 			    rfc_sc->sc_bufidx, (rf_sc->sc_state & RFS_DENS) == 0
 1.4     ragge 			    ? RX2_BYTE_SD : RX2_BYTE_DD,
 1.4     ragge 			    rfc_sc->sc_curbuf->b_proc, BUS_DMA_NOWAIT);
 1.4     ragge 			if (i != 0) {
 1.8    simonb 				printf("rfc_intr: Error loading dmamap: %d\n",
 1.4     ragge 				    i);
1.15        ad 				rfc_sc->sc_curbuf->b_error = EIO;
 1.4     ragge 				break;
 1.4     ragge 			}
 1.4     ragge 			disk_busy(&rf_sc->sc_disk);
 1.4     ragge 			if (rfc_sendcmd(rfc_sc, RX2CS_FBUF | RX2CS_IE
 1.4     ragge 			    | ((rf_sc->sc_state & RFS_DENS) == 0 ? 0 : RX2CS_DD)
 1.4     ragge 			    | (rf_sc->sc_dnum == 0 ? 0 : RX2CS_US)
 1.8    simonb 			    | ((rfc_sc->sc_dmam->dm_segs[0].ds_addr
 1.4     ragge 			    & 0x30000)>>4), ((rf_sc->sc_state & RFS_DENS) == 0
 1.4     ragge 			    ? RX2_BYTE_SD : RX2_BYTE_DD) / 2,
 1.4     ragge 			    rfc_sc->sc_dmam->dm_segs[0].ds_addr & 0xffff) < 0) {
 1.4     ragge 				disk_unbusy(&rf_sc->sc_disk, 0, 0);
1.15        ad 				rfc_sc->sc_curbuf->b_error = EIO;
 1.8    simonb 				bus_dmamap_unload(rfc_sc->sc_dmat,
 1.4     ragge 				    rfc_sc->sc_dmam);
 1.4     ragge 			}
 1.4     ragge 			break;
 1.4     ragge 		case RFS_WSEC:	/* Write Sector */
 1.4     ragge 			i = (rfc_sc->sc_curbuf->b_bcount - rfc_sc->sc_bytesleft
 1.4     ragge 			    + rfc_sc->sc_curbuf->b_blkno * DEV_BSIZE) /
 1.4     ragge 			    ((rf_sc->sc_state & RFS_DENS) == 0
 1.4     ragge 			    ? RX2_BYTE_SD : RX2_BYTE_DD);
 1.4     ragge 			if (i > RX2_TRACKS * RX2_SECTORS) {
1.15        ad 				rfc_sc->sc_curbuf->b_error = EIO;
 1.4     ragge 				break;
 1.4     ragge 			}
 1.4     ragge 			disk_busy(&rf_sc->sc_disk);
 1.4     ragge 			if (rfc_sendcmd(rfc_sc, RX2CS_WSEC | RX2CS_IE
 1.4     ragge 			    | (rf_sc->sc_dnum == 0 ? 0 : RX2CS_US)
 1.4     ragge 			    | ((rf_sc->sc_state& RFS_DENS) == 0 ? 0 : RX2CS_DD),
 1.4     ragge 			    i % RX2_SECTORS + 1, i / RX2_SECTORS) < 0) {
 1.4     ragge 				disk_unbusy(&rf_sc->sc_disk, 0, 0);
1.15        ad 				rfc_sc->sc_curbuf->b_error = EIO;
 1.4     ragge 			}
 1.1     ragge 			break;
 1.4     ragge 		case RFS_RSEC:	/* Read Sector */
 1.4     ragge 			i = (rfc_sc->sc_curbuf->b_bcount - rfc_sc->sc_bytesleft
 1.4     ragge 			    + rfc_sc->sc_curbuf->b_blkno * DEV_BSIZE) /
 1.4     ragge 			    ((rf_sc->sc_state & RFS_DENS) == 0
 1.4     ragge 			    ? RX2_BYTE_SD : RX2_BYTE_DD);
 1.4     ragge 			if (i > RX2_TRACKS * RX2_SECTORS) {
1.15        ad 				rfc_sc->sc_curbuf->b_error = EIO;
 1.4     ragge 				break;
 1.4     ragge 			}
 1.4     ragge 			disk_busy(&rf_sc->sc_disk);
 1.4     ragge 			if (rfc_sendcmd(rfc_sc, RX2CS_RSEC | RX2CS_IE
 1.4     ragge 			    | (rf_sc->sc_dnum == 0 ? 0 : RX2CS_US)
 1.4     ragge 			    | ((rf_sc->sc_state& RFS_DENS) == 0 ? 0 : RX2CS_DD),
 1.4     ragge 			    i % RX2_SECTORS + 1, i / RX2_SECTORS) < 0) {
 1.4     ragge 				disk_unbusy(&rf_sc->sc_disk, 0, 1);
1.15        ad 				rfc_sc->sc_curbuf->b_error = EIO;
 1.4     ragge 			}
 1.1     ragge 			break;
 1.4     ragge 		case RFS_NOTINIT: /* Device is not open */
 1.4     ragge 		case RFS_PROBING: /* density detect / verify started */
 1.4     ragge 		case RFS_IDLE:	/* controller is idle */
 1.4     ragge 		case RFS_SMD:	/* Set Media Density */
 1.4     ragge 		case RFS_RSTAT:	/* Read Status */
 1.4     ragge 		case RFS_WDDS:	/* Write Deleted Data Sector */
 1.4     ragge 		case RFS_REC:	/* Read Error Code */
 1.4     ragge 		default:
1.20     jkunz 			panic("Impossible state in rfc_intr(2): 0x%x\n",
1.20     jkunz 			    rf_sc->sc_state & RFS_CMDS);
 1.1     ragge 		}
 1.4     ragge
1.15        ad 		if (rfc_sc->sc_curbuf->b_error != 0) {
 1.8    simonb 			/*
 1.8    simonb 			 * An error occurred while processing this buffer.
 1.4     ragge 			 * Finish it and try to get a new buffer to process.
 1.4     ragge 			 * Return if there are no buffers in the queues.
 1.4     ragge 			 * This loops until the queues are empty or a new
 1.4     ragge 			 * action was successfully scheduled.
 1.4     ragge 			 */
 1.1     ragge 			rfc_sc->sc_curbuf->b_resid = rfc_sc->sc_bytesleft;
 1.4     ragge 			rfc_sc->sc_curbuf->b_error = EIO;
 1.4     ragge 			biodone(rfc_sc->sc_curbuf);
 1.4     ragge 			rf_sc = get_new_buf( rfc_sc);
 1.4     ragge 			if (rf_sc == NULL)
 1.4     ragge 				return;
 1.4     ragge 			continue;
 1.1     ragge 		}
1.21       dsl 		break;
1.21       dsl 	}
 1.1     ragge 	return;
 1.1     ragge }
 1.1     ragge
 1.1     ragge
 1.1     ragge
 1.1     ragge int
1.13  christos rfdump(dev_t dev, daddr_t blkno, void *va, size_t size)
 1.1     ragge {
 1.1     ragge
 1.1     ragge 	/* A 0.5MB floppy is much to small to take a system dump... */
 1.1     ragge 	return(ENXIO);
 1.1     ragge }
 1.1     ragge
 1.1     ragge
 1.1     ragge
 1.1     ragge int
 1.1     ragge rfsize(dev_t dev)
 1.1     ragge {
 1.1     ragge
 1.1     ragge 	return(-1);
 1.1     ragge }
 1.1     ragge
 1.1     ragge
 1.1     ragge
 1.1     ragge int
1.10  christos rfopen(dev_t dev, int oflags, int devtype, struct lwp *l)
 1.1     ragge {
 1.1     ragge 	struct rf_softc *rf_sc;
 1.1     ragge 	struct rfc_softc *rfc_sc;
 1.1     ragge 	struct disklabel *dl;
 1.1     ragge
1.19      matt 	if ((rf_sc = device_lookup_private(&rf_cd, DISKUNIT(dev))) == NULL)
1.19      matt 		return ENXIO;
1.19      matt
1.19      matt 	rfc_sc = rf_sc->sc_rfc;
 1.1     ragge 	dl = rf_sc->sc_disk.dk_label;
 1.1     ragge 	switch (DISKPART(dev)) {
 1.1     ragge 		case 0:			/* Part. a is single density. */
 1.6       wiz 			/* opening in single and double density is senseless */
 1.8    simonb 			if ((rf_sc->sc_state & RFS_OPEN_B) != 0 )
 1.4     ragge 				return(ENXIO);
 1.1     ragge 			rf_sc->sc_state &= ~RFS_DENS;
 1.1     ragge 			rf_sc->sc_state &= ~RFS_AD;
 1.4     ragge 			rf_sc->sc_state |= RFS_OPEN_A;
 1.1     ragge 		break;
 1.1     ragge 		case 1:			/* Part. b is double density. */
 1.1     ragge 			/*
 1.8    simonb 			 * Opening a single density only drive in double
 1.8    simonb 			 * density or simultaneous opening in single and
 1.6       wiz 			 * double density is senseless.
 1.1     ragge 			 */
 1.8    simonb 			if (rfc_sc->type == 1
 1.8    simonb 			    || (rf_sc->sc_state & RFS_OPEN_A) != 0 )
 1.8    simonb 				return(ENXIO);
 1.1     ragge 			rf_sc->sc_state |= RFS_DENS;
 1.1     ragge 			rf_sc->sc_state &= ~RFS_AD;
 1.4     ragge 			rf_sc->sc_state |= RFS_OPEN_B;
 1.1     ragge 		break;
 1.1     ragge 		case 2:			/* Part. c is auto density. */
 1.1     ragge 			rf_sc->sc_state |= RFS_AD;
 1.4     ragge 			rf_sc->sc_state |= RFS_OPEN_C;
 1.1     ragge 		break;
 1.1     ragge 		default:
 1.1     ragge 			return(ENXIO);
 1.1     ragge 		break;
 1.1     ragge 	}
 1.1     ragge 	if ((rf_sc->sc_state & RFS_CMDS) == RFS_NOTINIT) {
 1.1     ragge 		rfc_sc->sc_curchild = rf_sc->sc_dnum;
 1.1     ragge 		/*
 1.1     ragge 		 * Controller is idle and density is not detected.
 1.1     ragge 		 * Start a density probe by issuing a read sector command
 1.1     ragge 		 * and sleep until the density probe finished.
 1.6       wiz 		 * Due to this it is imposible to open unformatted media.
 1.1     ragge 		 * As the RX02/02 is not able to format its own media,
 1.6       wiz 		 * media must be purchased preformatted. fsck DEC makreting!
 1.1     ragge 		 */
 1.1     ragge 		RFS_SETCMD(rf_sc->sc_state, RFS_PROBING);
 1.1     ragge 		disk_busy(&rf_sc->sc_disk);
 1.1     ragge 		if (rfc_sendcmd(rfc_sc, RX2CS_RSEC | RX2CS_IE
 1.1     ragge 		    | (rf_sc->sc_dnum == 0 ? 0 : RX2CS_US)
 1.1     ragge 		    | ((rf_sc->sc_state & RFS_DENS) == 0 ? 0 : RX2CS_DD),
 1.1     ragge 		    1, 1) < 0) {
 1.1     ragge 			rf_sc->sc_state = 0;
 1.1     ragge 			return(ENXIO);
 1.1     ragge 		}
 1.1     ragge 		/* wait max. 2 sec for density probe to finish */
 1.1     ragge 		if (tsleep(rf_sc, PRIBIO | PCATCH, "density probe", 2 * hz)
 1.1     ragge 		    != 0 || (rf_sc->sc_state & RFS_CMDS) == RFS_NOTINIT) {
 1.6       wiz 			/* timeout elapsed and / or something went wrong */
 1.1     ragge 			rf_sc->sc_state = 0;
 1.1     ragge 			return(ENXIO);
 1.1     ragge 		}
 1.1     ragge 	}
 1.1     ragge 	/* disklabel. We use different fake geometries for SD and DD. */
 1.1     ragge 	if ((rf_sc->sc_state & RFS_DENS) == 0) {
 1.1     ragge 		dl->d_nsectors = 10;		/* sectors per track */
 1.1     ragge 		dl->d_secpercyl = 10;		/* sectors per cylinder */
 1.1     ragge 		dl->d_ncylinders = 50;		/* cylinders per unit */
 1.1     ragge 		dl->d_secperunit = 501; /* sectors per unit */
 1.1     ragge 		/* number of sectors in partition */
 1.1     ragge 		dl->d_partitions[2].p_size = 500;
 1.1     ragge 	} else {
 1.1     ragge 		dl->d_nsectors = RX2_SECTORS / 2;  /* sectors per track */
 1.1     ragge 		dl->d_secpercyl = RX2_SECTORS / 2; /* sectors per cylinder */
 1.8    simonb 		dl->d_ncylinders = RX2_TRACKS;	   /* cylinders per unit */
 1.1     ragge 		/* sectors per unit */
 1.1     ragge 		dl->d_secperunit = RX2_SECTORS * RX2_TRACKS / 2;
 1.1     ragge 		/* number of sectors in partition */
 1.1     ragge 		dl->d_partitions[2].p_size = RX2_SECTORS * RX2_TRACKS / 2;
 1.1     ragge 	}
 1.1     ragge 	return(0);
 1.1     ragge }
 1.1     ragge
 1.1     ragge
 1.1     ragge
 1.1     ragge int
1.10  christos rfclose(dev_t dev, int fflag, int devtype, struct lwp *l)
 1.1     ragge {
1.20     jkunz 	struct rf_softc *rf_sc = device_lookup_private(&rf_cd, DISKUNIT(dev));
 1.1     ragge
 1.4     ragge 	if ((rf_sc->sc_state & 1 << (DISKPART(dev) + RFS_OPEN_SHIFT)) == 0)
 1.6       wiz 		panic("rfclose: can not close non-open drive %s "
1.24    cegger 		    "partition %"PRIu32, device_xname(rf_sc->sc_dev), DISKPART(dev));
 1.8    simonb 	else
 1.4     ragge 		rf_sc->sc_state &= ~(1 << (DISKPART(dev) + RFS_OPEN_SHIFT));
 1.4     ragge 	if ((rf_sc->sc_state & RFS_OPEN_MASK) == 0)
 1.4     ragge 		rf_sc->sc_state = 0;
 1.1     ragge 	return(0);
 1.1     ragge }
 1.1     ragge
 1.1     ragge
 1.1     ragge
 1.1     ragge int
 1.1     ragge rfread(dev_t dev, struct uio *uio, int ioflag)
 1.1     ragge {
 1.1     ragge
 1.1     ragge 	return(physio(rfstrategy, NULL, dev, B_READ, minphys, uio));
 1.1     ragge }
 1.1     ragge
 1.1     ragge
 1.1     ragge
 1.1     ragge int
 1.1     ragge rfwrite(dev_t dev, struct uio *uio, int ioflag)
 1.1     ragge {
 1.1     ragge
 1.1     ragge 	return(physio(rfstrategy, NULL, dev, B_WRITE, minphys, uio));
 1.1     ragge }
 1.1     ragge
 1.1     ragge
 1.1     ragge
 1.1     ragge int
1.13  christos rfioctl(dev_t dev, u_long cmd, void *data, int fflag, struct lwp *l)
 1.1     ragge {
1.20     jkunz 	struct rf_softc *rf_sc = device_lookup_private(&rf_cd, DISKUNIT(dev));
 1.1     ragge
 1.6       wiz 	/* We are going to operate on a non-open dev? PANIC! */
 1.4     ragge 	if ((rf_sc->sc_state & 1 << (DISKPART(dev) + RFS_OPEN_SHIFT)) == 0)
 1.4     ragge 		panic("rfioctl: can not operate on non-open drive %s "
1.24    cegger 		    "partition %"PRIu32, device_xname(rf_sc->sc_dev), DISKPART(dev));
 1.1     ragge 	switch (cmd) {
 1.1     ragge 	/* get and set disklabel; DIOCGPART used internally */
 1.1     ragge 	case DIOCGDINFO: /* get */
 1.1     ragge 		memcpy(data, rf_sc->sc_disk.dk_label,
 1.1     ragge 		    sizeof(struct disklabel));
 1.1     ragge 		return(0);
 1.1     ragge 	case DIOCSDINFO: /* set */
 1.1     ragge 		return(0);
 1.1     ragge 	case DIOCWDINFO: /* set, update disk */
 1.1     ragge 		return(0);
 1.1     ragge 	case DIOCGPART:  /* get partition */
 1.1     ragge 		((struct partinfo *)data)->disklab = rf_sc->sc_disk.dk_label;
 1.1     ragge 		((struct partinfo *)data)->part =
 1.1     ragge 		    &rf_sc->sc_disk.dk_label->d_partitions[DISKPART(dev)];
 1.1     ragge 		return(0);
 1.1     ragge
 1.1     ragge 	/* do format operation, read or write */
 1.1     ragge 	case DIOCRFORMAT:
 1.1     ragge 	break;
 1.1     ragge 	case DIOCWFORMAT:
 1.1     ragge 	break;
 1.1     ragge
 1.1     ragge 	case DIOCSSTEP: /* set step rate */
 1.1     ragge 	break;
 1.1     ragge 	case DIOCSRETRIES: /* set # of retries */
 1.1     ragge 	break;
 1.1     ragge 	case DIOCKLABEL: /* keep/drop label on close? */
 1.1     ragge 	break;
 1.1     ragge 	case DIOCWLABEL: /* write en/disable label */
 1.1     ragge 	break;
 1.1     ragge
 1.1     ragge /*	case DIOCSBAD: / * set kernel dkbad */
 1.1     ragge 	break; /* */
 1.1     ragge 	case DIOCEJECT: /* eject removable disk */
 1.1     ragge 	break;
 1.1     ragge 	case ODIOCEJECT: /* eject removable disk */
 1.1     ragge 	break;
 1.1     ragge 	case DIOCLOCK: /* lock/unlock pack */
 1.1     ragge 	break;
 1.1     ragge
 1.1     ragge 	/* get default label, clear label */
 1.1     ragge 	case DIOCGDEFLABEL:
 1.1     ragge 	break;
 1.1     ragge 	case DIOCCLRLABEL:
 1.1     ragge 	break;
 1.1     ragge 	default:
 1.1     ragge 		return(ENOTTY);
 1.1     ragge 	}
 1.1     ragge
 1.1     ragge 	return(ENOTTY);
 1.1     ragge }