dev/podulebus/sec.c

1.2  bjh21 /* $NetBSD: sec.c,v 1.2 2006/10/01 22:02:55 bjh21 Exp $ */
1.1  bjh21
1.1  bjh21 /*-
1.1  bjh21  * Copyright (c) 2000, 2001, 2006 Ben Harris
1.1  bjh21  * All rights reserved.
1.1  bjh21  *
1.1  bjh21  * Redistribution and use in source and binary forms, with or without
1.1  bjh21  * modification, are permitted provided that the following conditions
1.1  bjh21  * are met:
1.1  bjh21  * 1. Redistributions of source code must retain the above copyright
1.1  bjh21  *    notice, this list of conditions and the following disclaimer.
1.1  bjh21  * 2. Redistributions in binary form must reproduce the above copyright
1.1  bjh21  *    notice, this list of conditions and the following disclaimer in the
1.1  bjh21  *    documentation and/or other materials provided with the distribution.
1.1  bjh21  * 3. The name of the author may not be used to endorse or promote products
1.1  bjh21  *    derived from this software without specific prior written permission.
1.1  bjh21  *
1.1  bjh21  * THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR
1.1  bjh21  * IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES
1.1  bjh21  * OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED.
1.1  bjh21  * IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT,
1.1  bjh21  * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT
1.1  bjh21  * NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
1.1  bjh21  * DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
1.1  bjh21  * THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
1.1  bjh21  * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF
1.1  bjh21  * THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
1.1  bjh21  */
1.1  bjh21 /*
1.1  bjh21  * sec.c -- driver for Acorn SCSI expansion cards (AKA30, AKA31, AKA32)
1.1  bjh21  *
1.1  bjh21  * These cards are documented in:
1.1  bjh21  * Acorn Archimedes 500 series / Acorn R200 series Technical Reference Manual
1.1  bjh21  * Published by Acorn Computers Limited
1.1  bjh21  * ISBN 1 85250 086 7
1.1  bjh21  * Part number 0486,052
1.1  bjh21  * Issue 1, November 1990
1.1  bjh21  */
1.1  bjh21
1.1  bjh21 #include <sys/cdefs.h>
1.2  bjh21 __KERNEL_RCSID(0, "$NetBSD: sec.c,v 1.2 2006/10/01 22:02:55 bjh21 Exp $");
1.1  bjh21
1.1  bjh21 #include <sys/param.h>
1.1  bjh21
1.1  bjh21 #include <sys/buf.h>
1.1  bjh21 #include <sys/device.h>
1.1  bjh21 #include <sys/malloc.h>
1.1  bjh21 #include <sys/reboot.h>	/* For bootverbose */
1.1  bjh21 #include <sys/syslog.h>
1.1  bjh21 #include <sys/systm.h>
1.1  bjh21
1.1  bjh21 #include <dev/scsipi/scsi_all.h>
1.1  bjh21 #include <dev/scsipi/scsipi_all.h>
1.1  bjh21 #include <dev/scsipi/scsiconf.h>
1.1  bjh21
1.1  bjh21 #include <machine/bus.h>
1.1  bjh21
1.1  bjh21 #include <dev/ic/wd33c93reg.h>
1.1  bjh21 #include <dev/ic/wd33c93var.h>
1.1  bjh21 #include <dev/ic/nec71071reg.h>
1.1  bjh21
1.1  bjh21 #include <dev/podulebus/podulebus.h>
1.1  bjh21 #include <dev/podulebus/podules.h>
1.1  bjh21 #include <dev/podulebus/powerromreg.h>
1.1  bjh21 #include <dev/podulebus/secreg.h>
1.1  bjh21
1.1  bjh21 #include "opt_ddb.h"
1.1  bjh21
1.1  bjh21 struct sec_softc {
1.1  bjh21 	struct	wd33c93_softc sc_sbic;
1.1  bjh21 	bus_space_tag_t		sc_pod_t;
1.1  bjh21 	bus_space_handle_t	sc_pod_h;
1.1  bjh21 	bus_space_tag_t		sc_mod_t;
1.1  bjh21 	bus_space_handle_t	sc_mod_h;
1.1  bjh21 	void			*sc_ih;
1.1  bjh21 	struct		evcnt	sc_intrcnt;
1.1  bjh21 	uint8_t			sc_mpr;
1.1  bjh21
1.1  bjh21 	/* Details of the current DMA transfer */
1.1  bjh21 	boolean_t		sc_dmaactive;
1.1  bjh21 	caddr_t			sc_dmaaddr;
1.1  bjh21 	int			sc_dmaoff;
1.1  bjh21 	size_t			sc_dmalen;
1.1  bjh21 	boolean_t		sc_dmain;
1.1  bjh21 	/* Details of the current block within the above transfer */
1.1  bjh21 	size_t			sc_dmablk;
1.1  bjh21 };
1.1  bjh21
1.1  bjh21 #define SEC_DMABLK	16384
1.1  bjh21 #define SEC_NBLKS	3
1.2  bjh21 #define SEC_DMAMODE	MODE_TMODE_DMD
1.1  bjh21
1.1  bjh21 /* autoconfiguration glue */
1.1  bjh21 static int sec_match(struct device *, struct cfdata *, void *);
1.1  bjh21 static void sec_attach(struct device *, struct device *, void *);
1.1  bjh21
1.1  bjh21 /* callbacks from MI WD33C93 driver */
1.1  bjh21 static int sec_dmasetup(struct wd33c93_softc *, caddr_t *, size_t *, int,
1.1  bjh21     size_t *);
1.1  bjh21 static int sec_dmago(struct wd33c93_softc *);
1.1  bjh21 static void sec_dmastop(struct wd33c93_softc *);
1.1  bjh21 static void sec_reset(struct wd33c93_softc *);
1.1  bjh21
1.1  bjh21 static int sec_intr(void *);
1.1  bjh21 static int sec_dmatc(struct sec_softc *sc);
1.1  bjh21
1.1  bjh21 void sec_dumpdma(void *arg);
1.1  bjh21
1.1  bjh21 CFATTACH_DECL(sec, sizeof(struct sec_softc),
1.1  bjh21     sec_match, sec_attach, NULL, NULL);
1.1  bjh21
1.1  bjh21 static inline void
1.1  bjh21 sec_setpage(struct sec_softc *sc, int page)
1.1  bjh21 {
1.1  bjh21
1.1  bjh21 	sc->sc_mpr = (sc->sc_mpr & ~SEC_MPR_PAGE) | page;
1.1  bjh21 	bus_space_write_1(sc->sc_pod_t, sc->sc_pod_h, SEC_MPR, sc->sc_mpr);
1.1  bjh21 }
1.1  bjh21
1.1  bjh21 static inline void
1.1  bjh21 sec_cli(struct sec_softc *sc)
1.1  bjh21 {
1.1  bjh21
1.1  bjh21 	bus_space_write_1(sc->sc_pod_t, sc->sc_pod_h, SEC_CLRINT, 0);
1.1  bjh21 }
1.1  bjh21
1.1  bjh21 static inline void
1.1  bjh21 dmac_write(struct sec_softc *sc, int reg, uint8_t val)
1.1  bjh21 {
1.1  bjh21
1.1  bjh21 	bus_space_write_1(sc->sc_mod_t, sc->sc_mod_h,
1.1  bjh21 	    SEC_DMAC + DMAC(reg), val);
1.1  bjh21 }
1.1  bjh21
1.1  bjh21 static inline uint8_t
1.1  bjh21 dmac_read(struct sec_softc *sc, int reg)
1.1  bjh21 {
1.1  bjh21
1.1  bjh21 	return bus_space_read_1(sc->sc_mod_t, sc->sc_mod_h,
1.1  bjh21 	    SEC_DMAC + DMAC(reg));
1.1  bjh21 }
1.1  bjh21
1.1  bjh21 static int
1.1  bjh21 sec_match(struct device *parent, struct cfdata *cf, void *aux)
1.1  bjh21 {
1.1  bjh21 	struct podulebus_attach_args *pa = aux;
1.1  bjh21
1.1  bjh21 	/* Standard ROM, skipping the MCS card that used the same ID. */
1.1  bjh21 	if (pa->pa_product == PODULE_ACORN_SCSI &&
1.1  bjh21 	    strncmp(pa->pa_descr, "MCS", 3) != 0)
1.1  bjh21 		return 1;
1.1  bjh21
1.1  bjh21 	/* PowerROM */
1.1  bjh21         if (pa->pa_product == PODULE_ALSYSTEMS_SCSI &&
1.1  bjh21             podulebus_initloader(pa) == 0 &&
1.1  bjh21             podloader_callloader(pa, 0, 0) == PRID_ACORN_SCSI1)
1.1  bjh21                 return 1;
1.1  bjh21
1.1  bjh21 	return 0;
1.1  bjh21 }
1.1  bjh21
1.1  bjh21 static void
1.1  bjh21 sec_attach(struct device *parent, struct device *self, void *aux)
1.1  bjh21 {
1.1  bjh21 	struct podulebus_attach_args *pa = aux;
1.1  bjh21 	struct sec_softc *sc = device_private(self);
1.1  bjh21 	int i;
1.1  bjh21
1.1  bjh21 	/* Set up bus spaces */
1.1  bjh21 	sc->sc_pod_t = pa->pa_fast_t;
1.1  bjh21 	bus_space_map(pa->pa_fast_t, pa->pa_fast_base, 0x1000, 0,
1.1  bjh21 	    &sc->sc_pod_h);
1.1  bjh21 	sc->sc_mod_t = pa->pa_mod_t;
1.1  bjh21 	bus_space_map(pa->pa_mod_t, pa->pa_mod_base, 0x1000, 0,
1.1  bjh21 	    &sc->sc_mod_h);
1.1  bjh21
1.1  bjh21 	sc->sc_sbic.sc_regt = sc->sc_mod_t;
1.1  bjh21 	bus_space_subregion(sc->sc_mod_t, sc->sc_mod_h, SEC_SBIC,
1.1  bjh21 	    0x1000 - SEC_SBIC, &sc->sc_sbic.sc_regh);
1.1  bjh21
1.1  bjh21 	sc->sc_sbic.sc_id = 7;
1.1  bjh21 	sc->sc_sbic.sc_clkfreq = SEC_CLKFREQ;
1.2  bjh21 	sc->sc_sbic.sc_dmamode = SBIC_CTL_BURST_DMA;
1.1  bjh21
1.1  bjh21 	sc->sc_sbic.sc_adapter.adapt_request = wd33c93_scsi_request;
1.1  bjh21 	sc->sc_sbic.sc_adapter.adapt_minphys = minphys;
1.1  bjh21
1.1  bjh21 	sc->sc_sbic.sc_dmasetup = sec_dmasetup;
1.1  bjh21 	sc->sc_sbic.sc_dmago = sec_dmago;
1.1  bjh21 	sc->sc_sbic.sc_dmastop = sec_dmastop;
1.1  bjh21 	sc->sc_sbic.sc_reset = sec_reset;
1.1  bjh21
1.1  bjh21 	sc->sc_mpr = 0;
1.1  bjh21 	bus_space_write_1(sc->sc_pod_t, sc->sc_pod_h, SEC_MPR, sc->sc_mpr);
1.1  bjh21
1.1  bjh21 	for (i = 0; i < SEC_NPAGES; i++) {
1.1  bjh21 		sec_setpage(sc, i);
1.1  bjh21 		bus_space_set_region_2(sc->sc_mod_t, sc->sc_mod_h,
1.1  bjh21 				       SEC_SRAM, 0, SEC_PAGESIZE / 2);
1.1  bjh21 	}
1.1  bjh21
1.1  bjh21 	wd33c93_attach(&sc->sc_sbic);
1.1  bjh21
1.1  bjh21 	evcnt_attach_dynamic(&sc->sc_intrcnt, EVCNT_TYPE_INTR, NULL,
1.1  bjh21 	    self->dv_xname, "intr");
1.1  bjh21 	sc->sc_ih = podulebus_irq_establish(pa->pa_ih, IPL_BIO, sec_intr,
1.1  bjh21 	    sc, &sc->sc_intrcnt);
1.1  bjh21 	sec_cli(sc);
1.1  bjh21 	sc->sc_mpr |= SEC_MPR_IE;
1.1  bjh21 	bus_space_write_1(sc->sc_pod_t, sc->sc_pod_h, SEC_MPR, sc->sc_mpr);
1.1  bjh21 }
1.1  bjh21
1.1  bjh21 static void
1.1  bjh21 sec_copyin(struct sec_softc *sc, void *dest, int src, size_t size)
1.1  bjh21 {
1.1  bjh21 	uint16_t tmp, *wptr;
1.1  bjh21 	int cnt, extra_byte;
1.1  bjh21
1.1  bjh21 	KASSERT(src >= 0);
1.1  bjh21 	KASSERT(src + size <= SEC_MEMSIZE);
1.1  bjh21 	if (src % 2 != 0) {
1.1  bjh21 		/*
1.1  bjh21 		 * There's a stray byte at the start.  Read the word
1.1  bjh21 		 * containing it.
1.1  bjh21 		 */
1.1  bjh21 		sec_setpage(sc, src / SEC_PAGESIZE);
1.1  bjh21 		tmp = bus_space_read_2(sc->sc_mod_t, sc->sc_mod_h,
1.1  bjh21 		    SEC_SRAM + (src % SEC_PAGESIZE / 2));
1.1  bjh21 		*(uint8_t *)dest = tmp >> 8;
1.1  bjh21 		dest = ((uint8_t *)dest) + 1;
1.1  bjh21 		src++; size--;
1.1  bjh21 	}
1.1  bjh21 	KASSERT(src % 2 == 0);
1.1  bjh21 	KASSERT(ALIGNED_POINTER(dest, uint16_t));
1.1  bjh21 	wptr = dest;
1.1  bjh21 	extra_byte = size % 2;
1.1  bjh21 	size -= extra_byte;
1.1  bjh21 	while (size > 0) {
1.1  bjh21 		cnt = SEC_PAGESIZE - src % SEC_PAGESIZE;
1.1  bjh21 		if (cnt > size)
1.1  bjh21 			cnt = size;
1.1  bjh21 		sec_setpage(sc, src / SEC_PAGESIZE);
1.1  bjh21 		/* bus ops are in words */
1.1  bjh21 		bus_space_read_region_2(sc->sc_mod_t, sc->sc_mod_h,
1.1  bjh21 		    SEC_SRAM + src % SEC_PAGESIZE / 2, wptr, cnt / 2);
1.1  bjh21 		src += cnt;
1.1  bjh21 		wptr += cnt / 2;
1.1  bjh21 		size -= cnt;
1.1  bjh21 	}
1.1  bjh21 	if (extra_byte) {
1.1  bjh21 		sec_setpage(sc, src / SEC_PAGESIZE);
1.1  bjh21 		*(u_int8_t *)wptr =
1.1  bjh21 		    bus_space_read_2(sc->sc_mod_t, sc->sc_mod_h,
1.1  bjh21 		    SEC_SRAM + src % SEC_PAGESIZE / 2) & 0xff;
1.1  bjh21 	}
1.1  bjh21 }
1.1  bjh21
1.1  bjh21 static void
1.1  bjh21 sec_copyout(struct sec_softc *sc, const void *src, int dest, size_t size)
1.1  bjh21 {
1.1  bjh21 	int cnt, extra_byte;
1.1  bjh21 	const uint16_t *wptr;
1.1  bjh21 	uint16_t tmp;
1.1  bjh21
1.1  bjh21 	KASSERT(dest >= 0);
1.1  bjh21 	KASSERT(dest + size <= SEC_MEMSIZE);
1.1  bjh21 	if (dest % 2 != 0) {
1.1  bjh21 		/*
1.1  bjh21 		 * There's a stray byte at the start.  Read the word
1.1  bjh21 		 * containing it.
1.1  bjh21 		 */
1.1  bjh21 		sec_setpage(sc, dest / SEC_PAGESIZE);
1.1  bjh21 		tmp = bus_space_read_2(sc->sc_mod_t, sc->sc_mod_h,
1.1  bjh21 		    SEC_SRAM + (dest % SEC_PAGESIZE / 2));
1.1  bjh21 		tmp &= 0xff;
1.1  bjh21 		tmp |= *(uint8_t const *)src << 8;
1.1  bjh21 		bus_space_write_2(sc->sc_mod_t, sc->sc_mod_h,
1.1  bjh21 		    SEC_SRAM + (dest % SEC_PAGESIZE / 2), tmp);
1.1  bjh21 		src = ((uint8_t const *)src) + 1;
1.1  bjh21 		dest++; size--;
1.1  bjh21 	}
1.1  bjh21 	KASSERT(dest % 2 == 0);
1.1  bjh21 	KASSERT(ALIGNED_POINTER(src, uint16_t));
1.1  bjh21 	wptr = src;
1.1  bjh21 	extra_byte = size % 2;
1.1  bjh21 	size -= extra_byte;
1.1  bjh21 	while (size > 0) {
1.1  bjh21 		cnt = SEC_PAGESIZE - dest % SEC_PAGESIZE;
1.1  bjh21 		if (cnt > size)
1.1  bjh21 			cnt = size;
1.1  bjh21 		sec_setpage(sc, dest / SEC_PAGESIZE);
1.1  bjh21 		/* bus ops are in words */
1.1  bjh21 		bus_space_write_region_2(sc->sc_mod_t, sc->sc_mod_h,
1.1  bjh21 		    dest % SEC_PAGESIZE / 2, wptr, cnt / 2);
1.1  bjh21 		wptr += cnt / 2;
1.1  bjh21 		dest += cnt;
1.1  bjh21 		size -= cnt;
1.1  bjh21 	}
1.1  bjh21 	if (extra_byte) {
1.1  bjh21 		/*
1.1  bjh21 		 * There's a stray byte at the end.  Read the word
1.1  bjh21 		 * containing it.
1.1  bjh21 		 */
1.1  bjh21 		sec_setpage(sc, dest / SEC_PAGESIZE);
1.1  bjh21 		tmp = bus_space_read_2(sc->sc_mod_t, sc->sc_mod_h,
1.1  bjh21 		    SEC_SRAM + (dest % SEC_PAGESIZE / 2));
1.1  bjh21 		tmp &= 0xff00;
1.1  bjh21 		tmp |= *(uint8_t const *)wptr;
1.1  bjh21 		bus_space_write_2(sc->sc_mod_t, sc->sc_mod_h,
1.1  bjh21 		    SEC_SRAM + (dest % SEC_PAGESIZE / 2), tmp);
1.1  bjh21 	}
1.1  bjh21 }
1.1  bjh21
1.1  bjh21 static void
1.1  bjh21 sec_dmablk(struct sec_softc *sc, int blk)
1.1  bjh21 {
1.1  bjh21 	int off;
1.1  bjh21 	size_t len;
1.1  bjh21
1.1  bjh21 	KASSERT(blk >= 0);
1.1  bjh21 	KASSERT(blk * SEC_DMABLK < sc->sc_dmalen);
1.1  bjh21 	off = (blk % SEC_NBLKS) * SEC_DMABLK + sc->sc_dmaoff;
1.1  bjh21 	len = MIN(SEC_DMABLK, sc->sc_dmalen - (blk * SEC_DMABLK));
1.1  bjh21 	if (!sc->sc_dmain)
1.1  bjh21 		sec_copyout(sc, sc->sc_dmaaddr + (blk * SEC_DMABLK), off, len);
1.1  bjh21 	dmac_write(sc, NEC71071_ADDRLO, off & 0xff);
1.1  bjh21 	dmac_write(sc, NEC71071_ADDRMID, off >> 8);
1.1  bjh21 	dmac_write(sc, NEC71071_ADDRHI, 0);
1.1  bjh21 	/*
1.1  bjh21 	 * "Note: The number of DMA transfer cycles is actually the
1.1  bjh21 	 * value of the current count register + 1.  Therefore, when
1.1  bjh21 	 * programming the count register, specify the number of DMA
1.1  bjh21 	 * transfers minus one." -- uPD71071 datasheet
1.1  bjh21 	 */
1.1  bjh21 	dmac_write(sc, NEC71071_COUNTLO, (len - 1) & 0xff);
1.1  bjh21 	dmac_write(sc, NEC71071_COUNTHI, (len - 1) >> 8);
1.1  bjh21 }
1.1  bjh21
1.1  bjh21 static void
1.1  bjh21 sec_dmablkdone(struct sec_softc *sc, int blk)
1.1  bjh21 {
1.1  bjh21 	int off;
1.1  bjh21 	size_t len;
1.1  bjh21
1.1  bjh21 	KASSERT(blk >= 0);
1.1  bjh21 	KASSERT(blk * SEC_DMABLK < sc->sc_dmalen);
1.1  bjh21 	off = (blk % SEC_NBLKS) * SEC_DMABLK + sc->sc_dmaoff;
1.1  bjh21 	len = MIN(SEC_DMABLK, sc->sc_dmalen - (blk * SEC_DMABLK));
1.1  bjh21 	if (sc->sc_dmain)
1.1  bjh21 		sec_copyin(sc, sc->sc_dmaaddr + (blk * SEC_DMABLK), off, len);
1.1  bjh21 }
1.1  bjh21
1.1  bjh21 static int
1.1  bjh21 sec_dmasetup(struct wd33c93_softc *sc_sbic, caddr_t *addr, size_t *len,
1.1  bjh21     int datain, size_t *dmasize)
1.1  bjh21 {
1.1  bjh21 	struct sec_softc *sc = (struct sec_softc *)sc_sbic;
1.1  bjh21 	uint8_t mode;
1.1  bjh21
1.1  bjh21 	sc->sc_dmaaddr = *addr;
1.1  bjh21 	sc->sc_dmaoff = ALIGNED_POINTER(*addr, uint16_t) ? 0 : 1;
1.1  bjh21 	sc->sc_dmalen = *len;
1.1  bjh21 	sc->sc_dmain = datain;
1.1  bjh21 	sc->sc_dmablk = 0;
1.1  bjh21 	mode = SEC_DMAMODE | (datain ? MODE_TDIR_IOTM : MODE_TDIR_MTIO);
1.1  bjh21 	/* Program first block into DMAC and queue up second. */
1.1  bjh21 	dmac_write(sc, NEC71071_CHANNEL, 0);
1.1  bjh21 	sec_dmablk(sc, 0);
1.1  bjh21 	if (sc->sc_dmalen > SEC_DMABLK) {
1.1  bjh21 		dmac_write(sc, NEC71071_CHANNEL, 0 | CHANNEL_WBASE);
1.1  bjh21 		sec_dmablk(sc, 1);
1.1  bjh21 		mode |= MODE_AUTI;
1.1  bjh21 	}
1.1  bjh21 	/* Mode control register */
1.1  bjh21 	dmac_write(sc, NEC71071_MODE, mode);
1.1  bjh21 	return sc->sc_dmalen;
1.1  bjh21 }
1.1  bjh21
1.1  bjh21 static int
1.1  bjh21 sec_dmago(struct wd33c93_softc *sc_sbic)
1.1  bjh21 {
1.1  bjh21 	struct sec_softc *sc = (struct sec_softc *)sc_sbic;
1.1  bjh21
1.1  bjh21 	dmac_write(sc, NEC71071_MASK, 0xe);
1.1  bjh21 	sc->sc_dmaactive = TRUE;
1.1  bjh21 	return sc->sc_dmalen;
1.1  bjh21 }
1.1  bjh21
1.1  bjh21 static void
1.1  bjh21 sec_dmastop(struct wd33c93_softc *sc_sbic)
1.1  bjh21 {
1.1  bjh21 	struct sec_softc *sc = (struct sec_softc *)sc_sbic;
1.1  bjh21
1.1  bjh21 	dmac_write(sc, NEC71071_MASK, 0xf);
1.1  bjh21 	if (sc->sc_dmaactive)
1.1  bjh21 		sec_dmablkdone(sc, sc->sc_dmablk);
1.1  bjh21 	sc->sc_dmaactive = FALSE;
1.1  bjh21 }
1.1  bjh21
1.1  bjh21 /*
1.1  bjh21  * Reset the SCSI bus, and incidentally the SBIC and DMAC.
1.1  bjh21  */
1.1  bjh21 static void
1.1  bjh21 sec_reset(struct wd33c93_softc *sc_sbic)
1.1  bjh21 {
1.1  bjh21 	struct sec_softc *sc = (struct sec_softc *)sc_sbic;
1.1  bjh21 	uint8_t asr, csr;
1.1  bjh21
1.1  bjh21 	bus_space_write_1(sc->sc_pod_t, sc->sc_pod_h, SEC_MPR,
1.1  bjh21 	    sc->sc_mpr | SEC_MPR_UR);
1.1  bjh21 	DELAY(7);
1.1  bjh21 	bus_space_write_1(sc->sc_pod_t, sc->sc_pod_h, SEC_MPR, sc->sc_mpr);
1.1  bjh21 	/* Wait for and clear the reset-complete interrupt */
1.1  bjh21 	do
1.1  bjh21 		GET_SBIC_asr(sc_sbic, asr);
1.1  bjh21 	while (!(asr & SBIC_ASR_INT));
1.1  bjh21 	GET_SBIC_csr(sc_sbic, csr);
1.1  bjh21 	dmac_write(sc, NEC71071_DCTRL1, DCTRL1_CMP | DCTRL1_RQL);
1.1  bjh21 	dmac_write(sc, NEC71071_DCTRL2, 0);
1.1  bjh21 	sec_cli(sc);
1.1  bjh21 }
1.1  bjh21
1.1  bjh21 static int
1.1  bjh21 sec_intr(void *arg)
1.1  bjh21 {
1.1  bjh21 	struct sec_softc *sc = arg;
1.1  bjh21 	u_int8_t isr;
1.1  bjh21
1.1  bjh21 	isr = bus_space_read_1(sc->sc_pod_t, sc->sc_pod_h, SEC_ISR);
1.1  bjh21 	if (!(isr & SEC_ISR_IRQ))
1.1  bjh21 		return 0;
1.1  bjh21 	if (isr & SEC_ISR_DMAC)
1.1  bjh21 		sec_dmatc(sc);
1.1  bjh21 	if (isr & SEC_ISR_SBIC)
1.1  bjh21 		wd33c93_intr(&sc->sc_sbic);
1.1  bjh21 	return 1;
1.1  bjh21 }
1.1  bjh21
1.1  bjh21 static int
1.1  bjh21 sec_dmatc(struct sec_softc *sc)
1.1  bjh21 {
1.1  bjh21
1.1  bjh21 	sec_cli(sc);
1.1  bjh21 	/* DMAC finished block n-1 and is now working on block n */
1.1  bjh21 	sc->sc_dmablk++;
1.1  bjh21 	if (sc->sc_dmalen > (sc->sc_dmablk + 1) * SEC_DMABLK) {
1.1  bjh21 		/* Queue up another block */
1.1  bjh21 		dmac_write(sc, NEC71071_CHANNEL, 0 | CHANNEL_WBASE);
1.1  bjh21 		sec_dmablk(sc, sc->sc_dmablk + 1);
1.1  bjh21 	} else if (sc->sc_dmalen > sc->sc_dmablk * SEC_DMABLK) {
1.1  bjh21 		/* No more blocks to queue -- cancel autoinitialize mode */
1.1  bjh21 		dmac_write(sc, NEC71071_MODE, SEC_DMAMODE |
1.1  bjh21 		    (sc->sc_dmain ? MODE_TDIR_IOTM : MODE_TDIR_MTIO));
1.1  bjh21 	} else {
1.1  bjh21 		/* All blocks fully processed. */
1.1  bjh21 		sc->sc_dmaactive = FALSE;
1.1  bjh21 	}
1.1  bjh21 	sec_dmablkdone(sc, sc->sc_dmablk - 1);
1.1  bjh21 	return 1;
1.1  bjh21 }
1.1  bjh21
1.1  bjh21 #ifdef DDB
1.1  bjh21 void
1.1  bjh21 sec_dumpdma(void *arg)
1.1  bjh21 {
1.1  bjh21 	struct sec_softc *sc = arg;
1.1  bjh21
1.1  bjh21 	dmac_write(sc, NEC71071_CHANNEL, 0);
1.1  bjh21 	printf("%s: DMA state: cur count %02x%02x cur addr %02x%02x%02x ",
1.1  bjh21 	    sc->sc_sbic.sc_dev.dv_xname,
1.1  bjh21 	    dmac_read(sc, NEC71071_COUNTHI), dmac_read(sc, NEC71071_COUNTLO),
1.1  bjh21 	    dmac_read(sc, NEC71071_ADDRHI), dmac_read(sc, NEC71071_ADDRMID),
1.1  bjh21 	    dmac_read(sc, NEC71071_ADDRLO));
1.1  bjh21 	dmac_write(sc, NEC71071_CHANNEL, 0 | CHANNEL_WBASE);
1.1  bjh21 	printf("base count %02x%02x base addr %02x%02x%02x\n",
1.1  bjh21 	    dmac_read(sc, NEC71071_COUNTHI), dmac_read(sc, NEC71071_COUNTLO),
1.1  bjh21 	    dmac_read(sc, NEC71071_ADDRHI), dmac_read(sc, NEC71071_ADDRMID),
1.1  bjh21 	    dmac_read(sc, NEC71071_ADDRLO));
1.1  bjh21 	printf("%s: DMA state: dctrl %1x%02x mode %02x status %02x req %02x "
1.1  bjh21 	    "mask %02x\n",
1.1  bjh21 	    sc->sc_sbic.sc_dev.dv_xname, dmac_read(sc, NEC71071_DCTRL2),
1.1  bjh21 	    dmac_read(sc, NEC71071_DCTRL1), dmac_read(sc, NEC71071_MODE),
1.1  bjh21 	    dmac_read(sc, NEC71071_STATUS), dmac_read(sc, NEC71071_REQUEST),
1.1  bjh21 	    dmac_read(sc, NEC71071_MASK));
1.1  bjh21 	printf("%s: soft DMA state: %zd@%p%s%d\n", sc->sc_sbic.sc_dev.dv_xname,
1.1  bjh21 	    sc->sc_dmalen, sc->sc_dmaaddr, sc->sc_dmain ? "<-" : "->",
1.1  bjh21 	    sc->sc_dmaoff);
1.1  bjh21 }
1.1  bjh21
1.1  bjh21 void sec_dumpall(void); /* Call from DDB */
1.1  bjh21
1.1  bjh21 extern struct cfdriver sec_cd;
1.1  bjh21
1.1  bjh21 void sec_dumpall(void)
1.1  bjh21 {
1.1  bjh21 	int i;
1.1  bjh21
1.1  bjh21 	for (i = 0; i < sec_cd.cd_ndevs; ++i)
1.1  bjh21 		if (sec_cd.cd_devs[i])
1.1  bjh21 			sec_dumpdma(sec_cd.cd_devs[i]);
1.1  bjh21 }
1.1  bjh21 #endif