next68k/dev/esp.c

1.36  jdolecek /*	$NetBSD: esp.c,v 1.36 2002/05/20 18:03:03 jdolecek Exp $	*/
 1.1       dbj
 1.1       dbj /*-
 1.5   mycroft  * Copyright (c) 1997, 1998 The NetBSD Foundation, Inc.
 1.1       dbj  * All rights reserved.
 1.1       dbj  *
 1.1       dbj  * This code is derived from software contributed to The NetBSD Foundation
 1.6   mycroft  * by Charles M. Hannum and by Jason R. Thorpe of the Numerical Aerospace
 1.6   mycroft  * Simulation Facility, NASA Ames Research Center.
 1.1       dbj  *
 1.1       dbj  * Redistribution and use in source and binary forms, with or without
 1.1       dbj  * modification, are permitted provided that the following conditions
 1.1       dbj  * are met:
 1.1       dbj  * 1. Redistributions of source code must retain the above copyright
 1.1       dbj  *    notice, this list of conditions and the following disclaimer.
 1.1       dbj  * 2. Redistributions in binary form must reproduce the above copyright
 1.1       dbj  *    notice, this list of conditions and the following disclaimer in the
 1.1       dbj  *    documentation and/or other materials provided with the distribution.
 1.1       dbj  * 3. All advertising materials mentioning features or use of this software
 1.1       dbj  *    must display the following acknowledgement:
 1.1       dbj  *	This product includes software developed by the NetBSD
 1.1       dbj  *	Foundation, Inc. and its contributors.
 1.1       dbj  * 4. Neither the name of The NetBSD Foundation nor the names of its
 1.1       dbj  *    contributors may be used to endorse or promote products derived
 1.1       dbj  *    from this software without specific prior written permission.
 1.1       dbj  *
 1.1       dbj  * THIS SOFTWARE IS PROVIDED BY THE NETBSD FOUNDATION, INC. AND CONTRIBUTORS
 1.1       dbj  * ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED
 1.1       dbj  * TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
 1.1       dbj  * PURPOSE ARE DISCLAIMED.  IN NO EVENT SHALL THE FOUNDATION OR CONTRIBUTORS
 1.1       dbj  * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
 1.1       dbj  * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
 1.1       dbj  * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
 1.1       dbj  * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
 1.1       dbj  * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
 1.1       dbj  * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
 1.1       dbj  * POSSIBILITY OF SUCH DAMAGE.
 1.1       dbj  */
 1.1       dbj
 1.1       dbj /*
 1.1       dbj  * Copyright (c) 1994 Peter Galbavy
 1.1       dbj  * All rights reserved.
 1.1       dbj  *
 1.1       dbj  * Redistribution and use in source and binary forms, with or without
 1.1       dbj  * modification, are permitted provided that the following conditions
 1.1       dbj  * are met:
 1.1       dbj  * 1. Redistributions of source code must retain the above copyright
 1.1       dbj  *    notice, this list of conditions and the following disclaimer.
 1.1       dbj  * 2. Redistributions in binary form must reproduce the above copyright
 1.1       dbj  *    notice, this list of conditions and the following disclaimer in the
 1.1       dbj  *    documentation and/or other materials provided with the distribution.
 1.1       dbj  * 3. All advertising materials mentioning features or use of this software
 1.1       dbj  *    must display the following acknowledgement:
 1.1       dbj  *	This product includes software developed by Peter Galbavy
 1.1       dbj  * 4. The name of the author may not be used to endorse or promote products
 1.1       dbj  *    derived from this software without specific prior written permission.
 1.1       dbj  *
 1.1       dbj  * THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR
 1.1       dbj  * IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
 1.1       dbj  * WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
 1.1       dbj  * DISCLAIMED.  IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT,
 1.1       dbj  * INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
 1.1       dbj  * (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR
 1.1       dbj  * SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
 1.1       dbj  * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT,
 1.1       dbj  * STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN
 1.1       dbj  * ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
 1.1       dbj  * POSSIBILITY OF SUCH DAMAGE.
 1.1       dbj  */
 1.1       dbj
 1.1       dbj /*
 1.1       dbj  * Based on aic6360 by Jarle Greipsland
 1.1       dbj  *
 1.1       dbj  * Acknowledgements: Many of the algorithms used in this driver are
 1.1       dbj  * inspired by the work of Julian Elischer (julian (at) tfs.com) and
 1.1       dbj  * Charles Hannum (mycroft (at) duality.gnu.ai.mit.edu).  Thanks a million!
 1.1       dbj  */
 1.1       dbj
 1.1       dbj /*
 1.1       dbj  * Grabbed from the sparc port at revision 1.73 for the NeXT.
 1.1       dbj  * Darrin B. Jewell <dbj (at) netbsd.org>  Sat Jul  4 15:41:32 1998
 1.1       dbj  */
 1.1       dbj
 1.1       dbj #include <sys/types.h>
 1.1       dbj #include <sys/param.h>
 1.1       dbj #include <sys/systm.h>
 1.1       dbj #include <sys/kernel.h>
 1.1       dbj #include <sys/errno.h>
 1.1       dbj #include <sys/ioctl.h>
 1.1       dbj #include <sys/device.h>
 1.1       dbj #include <sys/buf.h>
 1.1       dbj #include <sys/proc.h>
 1.1       dbj #include <sys/user.h>
 1.1       dbj #include <sys/queue.h>
 1.1       dbj
 1.1       dbj #include <dev/scsipi/scsi_all.h>
 1.1       dbj #include <dev/scsipi/scsipi_all.h>
 1.1       dbj #include <dev/scsipi/scsiconf.h>
 1.1       dbj #include <dev/scsipi/scsi_message.h>
 1.1       dbj
 1.1       dbj #include <machine/bus.h>
 1.1       dbj #include <machine/autoconf.h>
 1.1       dbj #include <machine/cpu.h>
 1.1       dbj
 1.1       dbj #include <dev/ic/ncr53c9xreg.h>
 1.1       dbj #include <dev/ic/ncr53c9xvar.h>
 1.1       dbj
 1.1       dbj #include <next68k/next68k/isr.h>
 1.1       dbj
 1.1       dbj #include <next68k/dev/nextdmareg.h>
 1.1       dbj #include <next68k/dev/nextdmavar.h>
 1.1       dbj
 1.1       dbj #include "espreg.h"
 1.1       dbj #include "espvar.h"
 1.1       dbj
1.20       dbj #ifdef DEBUG
 1.4       dbj #define ESP_DEBUG
 1.4       dbj #endif
 1.4       dbj
 1.4       dbj #ifdef ESP_DEBUG
1.10       dbj int esp_debug = 0;
1.10       dbj #define DPRINTF(x) if (esp_debug) printf x;
 1.4       dbj #else
 1.4       dbj #define DPRINTF(x)
 1.4       dbj #endif
 1.4       dbj
 1.4       dbj
 1.1       dbj void	espattach_intio	__P((struct device *, struct device *, void *));
 1.1       dbj int	espmatch_intio	__P((struct device *, struct cfdata *, void *));
 1.1       dbj
 1.2       dbj /* DMA callbacks */
 1.2       dbj bus_dmamap_t esp_dmacb_continue __P((void *arg));
 1.2       dbj void esp_dmacb_completed __P((bus_dmamap_t map, void *arg));
 1.2       dbj void esp_dmacb_shutdown __P((void *arg));
 1.2       dbj
1.20       dbj #ifdef ESP_DEBUG
1.20       dbj char esp_dma_dump[5*1024] = "";
1.20       dbj struct ncr53c9x_softc *esp_debug_sc = 0;
1.20       dbj void esp_dma_store __P((struct ncr53c9x_softc *sc));
1.20       dbj void esp_dma_print __P((struct ncr53c9x_softc *sc));
1.22       dbj int esp_dma_nest = 0;
1.20       dbj #endif
1.20       dbj
1.20       dbj
 1.1       dbj /* Linkup to the rest of the kernel */
 1.1       dbj struct cfattach esp_ca = {
 1.1       dbj 	sizeof(struct esp_softc), espmatch_intio, espattach_intio
 1.1       dbj };
 1.1       dbj
 1.1       dbj /*
 1.1       dbj  * Functions and the switch for the MI code.
 1.1       dbj  */
 1.1       dbj u_char	esp_read_reg __P((struct ncr53c9x_softc *, int));
 1.1       dbj void	esp_write_reg __P((struct ncr53c9x_softc *, int, u_char));
 1.1       dbj int	esp_dma_isintr __P((struct ncr53c9x_softc *));
 1.1       dbj void	esp_dma_reset __P((struct ncr53c9x_softc *));
 1.1       dbj int	esp_dma_intr __P((struct ncr53c9x_softc *));
 1.1       dbj int	esp_dma_setup __P((struct ncr53c9x_softc *, caddr_t *,
 1.1       dbj 	    size_t *, int, size_t *));
 1.1       dbj void	esp_dma_go __P((struct ncr53c9x_softc *));
 1.1       dbj void	esp_dma_stop __P((struct ncr53c9x_softc *));
 1.1       dbj int	esp_dma_isactive __P((struct ncr53c9x_softc *));
 1.1       dbj
 1.1       dbj struct ncr53c9x_glue esp_glue = {
 1.1       dbj 	esp_read_reg,
 1.1       dbj 	esp_write_reg,
 1.1       dbj 	esp_dma_isintr,
 1.1       dbj 	esp_dma_reset,
 1.1       dbj 	esp_dma_intr,
 1.1       dbj 	esp_dma_setup,
 1.1       dbj 	esp_dma_go,
 1.1       dbj 	esp_dma_stop,
 1.1       dbj 	esp_dma_isactive,
 1.1       dbj 	NULL,			/* gl_clear_latched_intr */
 1.1       dbj };
 1.1       dbj
1.11       dbj #ifdef ESP_DEBUG
1.11       dbj #define XCHR(x) "0123456789abcdef"[(x) & 0xf]
1.11       dbj static void
1.11       dbj esp_hex_dump(unsigned char *pkt, size_t len)
1.11       dbj {
1.11       dbj 	size_t i, j;
1.11       dbj
1.31       dbj 	printf("00000000  ");
1.11       dbj 	for(i=0; i<len; i++) {
1.11       dbj 		printf("%c%c ", XCHR(pkt[i]>>4), XCHR(pkt[i]));
1.24       dbj 		if ((i+1) % 16 == 8) {
1.24       dbj 			printf(" ");
1.24       dbj 		}
1.11       dbj 		if ((i+1) % 16 == 0) {
1.24       dbj 			printf(" %c", '|');
1.24       dbj 			for(j=0; j<16; j++) {
1.11       dbj 				printf("%c", pkt[i-15+j]>=32 && pkt[i-15+j]<127?pkt[i-15+j]:'.');
1.24       dbj 			}
1.24       dbj 			printf("%c\n%c%c%c%c%c%c%c%c  ", '|',
1.24       dbj 					XCHR((i+1)>>28),XCHR((i+1)>>24),XCHR((i+1)>>20),XCHR((i+1)>>16),
1.24       dbj 					XCHR((i+1)>>12), XCHR((i+1)>>8), XCHR((i+1)>>4), XCHR(i+1));
1.11       dbj 		}
1.11       dbj 	}
1.11       dbj 	printf("\n");
1.11       dbj }
1.11       dbj #endif
1.11       dbj
 1.1       dbj int
 1.1       dbj espmatch_intio(parent, cf, aux)
 1.1       dbj 	struct device *parent;
 1.1       dbj 	struct cfdata *cf;
 1.1       dbj 	void *aux;
 1.1       dbj {
 1.1       dbj   /* should probably probe here */
 1.1       dbj   /* Should also probably set up data from config */
 1.1       dbj
 1.3       dbj 	return(1);
 1.1       dbj }
 1.1       dbj
 1.1       dbj void
 1.1       dbj espattach_intio(parent, self, aux)
 1.1       dbj 	struct device *parent, *self;
 1.1       dbj 	void *aux;
 1.1       dbj {
 1.1       dbj 	struct esp_softc *esc = (void *)self;
 1.1       dbj 	struct ncr53c9x_softc *sc = &esc->sc_ncr53c9x;
 1.1       dbj
1.20       dbj #ifdef ESP_DEBUG
1.20       dbj 	esp_debug_sc = sc;
1.20       dbj #endif
1.20       dbj
 1.1       dbj 	esc->sc_bst = NEXT68K_INTIO_BUS_SPACE;
 1.1       dbj 	if (bus_space_map(esc->sc_bst, NEXT_P_SCSI,
 1.1       dbj 			ESP_DEVICE_SIZE, 0, &esc->sc_bsh)) {
 1.3       dbj     panic("\n%s: can't map ncr53c90 registers",
 1.1       dbj 				sc->sc_dev.dv_xname);
 1.1       dbj 	}
 1.1       dbj
 1.1       dbj 	sc->sc_id = 7;
 1.1       dbj 	sc->sc_freq = 20;							/* Mhz */
 1.1       dbj
 1.1       dbj 	/*
 1.1       dbj 	 * Set up glue for MI code early; we use some of it here.
 1.1       dbj 	 */
 1.1       dbj 	sc->sc_glue = &esp_glue;
 1.1       dbj
 1.1       dbj 	/*
 1.1       dbj 	 * XXX More of this should be in ncr53c9x_attach(), but
 1.1       dbj 	 * XXX should we really poke around the chip that much in
 1.1       dbj 	 * XXX the MI code?  Think about this more...
 1.1       dbj 	 */
 1.1       dbj
 1.1       dbj 	/*
 1.1       dbj 	 * It is necessary to try to load the 2nd config register here,
 1.1       dbj 	 * to find out what rev the esp chip is, else the ncr53c9x_reset
 1.1       dbj 	 * will not set up the defaults correctly.
 1.1       dbj 	 */
 1.1       dbj 	sc->sc_cfg1 = sc->sc_id | NCRCFG1_PARENB;
 1.1       dbj 	sc->sc_cfg2 = NCRCFG2_SCSI2 | NCRCFG2_RPE;
 1.1       dbj 	sc->sc_cfg3 = NCRCFG3_CDB;
 1.1       dbj 	NCR_WRITE_REG(sc, NCR_CFG2, sc->sc_cfg2);
 1.1       dbj
 1.1       dbj 	if ((NCR_READ_REG(sc, NCR_CFG2) & ~NCRCFG2_RSVD) !=
 1.1       dbj 	    (NCRCFG2_SCSI2 | NCRCFG2_RPE)) {
 1.1       dbj 		sc->sc_rev = NCR_VARIANT_ESP100;
 1.1       dbj 	} else {
 1.1       dbj 		sc->sc_cfg2 = NCRCFG2_SCSI2;
 1.1       dbj 		NCR_WRITE_REG(sc, NCR_CFG2, sc->sc_cfg2);
 1.1       dbj 		sc->sc_cfg3 = 0;
 1.1       dbj 		NCR_WRITE_REG(sc, NCR_CFG3, sc->sc_cfg3);
 1.1       dbj 		sc->sc_cfg3 = (NCRCFG3_CDB | NCRCFG3_FCLK);
 1.1       dbj 		NCR_WRITE_REG(sc, NCR_CFG3, sc->sc_cfg3);
 1.1       dbj 		if (NCR_READ_REG(sc, NCR_CFG3) !=
 1.1       dbj 		    (NCRCFG3_CDB | NCRCFG3_FCLK)) {
 1.1       dbj 			sc->sc_rev = NCR_VARIANT_ESP100A;
 1.1       dbj 		} else {
 1.1       dbj 			/* NCRCFG2_FE enables > 64K transfers */
 1.1       dbj 			sc->sc_cfg2 |= NCRCFG2_FE;
 1.1       dbj 			sc->sc_cfg3 = 0;
 1.1       dbj 			NCR_WRITE_REG(sc, NCR_CFG3, sc->sc_cfg3);
 1.1       dbj 			sc->sc_rev = NCR_VARIANT_ESP200;
 1.1       dbj 		}
 1.1       dbj 	}
 1.1       dbj
 1.1       dbj 	/*
 1.1       dbj 	 * XXX minsync and maxxfer _should_ be set up in MI code,
 1.1       dbj 	 * XXX but it appears to have some dependency on what sort
 1.1       dbj 	 * XXX of DMA we're hooked up to, etc.
 1.1       dbj 	 */
 1.1       dbj
 1.1       dbj 	/*
 1.1       dbj 	 * This is the value used to start sync negotiations
 1.1       dbj 	 * Note that the NCR register "SYNCTP" is programmed
 1.1       dbj 	 * in "clocks per byte", and has a minimum value of 4.
 1.1       dbj 	 * The SCSI period used in negotiation is one-fourth
 1.1       dbj 	 * of the time (in nanoseconds) needed to transfer one byte.
 1.1       dbj 	 * Since the chip's clock is given in MHz, we have the following
 1.1       dbj 	 * formula: 4 * period = (1000 / freq) * 4
 1.1       dbj 	 */
 1.1       dbj 	sc->sc_minsync = 1000 / sc->sc_freq;
 1.1       dbj
 1.1       dbj 	/*
 1.1       dbj 	 * Alas, we must now modify the value a bit, because it's
 1.1       dbj 	 * only valid when can switch on FASTCLK and FASTSCSI bits
 1.1       dbj 	 * in config register 3...
 1.1       dbj 	 */
 1.1       dbj 	switch (sc->sc_rev) {
 1.1       dbj 	case NCR_VARIANT_ESP100:
 1.1       dbj 		sc->sc_maxxfer = 64 * 1024;
 1.1       dbj 		sc->sc_minsync = 0;	/* No synch on old chip? */
 1.1       dbj 		break;
 1.1       dbj
 1.1       dbj 	case NCR_VARIANT_ESP100A:
 1.1       dbj 		sc->sc_maxxfer = 64 * 1024;
 1.1       dbj 		/* Min clocks/byte is 5 */
 1.1       dbj 		sc->sc_minsync = ncr53c9x_cpb2stp(sc, 5);
 1.1       dbj 		break;
 1.1       dbj
 1.1       dbj 	case NCR_VARIANT_ESP200:
 1.1       dbj 		sc->sc_maxxfer = 16 * 1024 * 1024;
 1.1       dbj 		/* XXX - do actually set FAST* bits */
 1.1       dbj 		break;
 1.1       dbj 	}
 1.1       dbj
 1.3       dbj 	/* @@@ Some ESP_DCTL bits probably need setting */
 1.3       dbj 	NCR_WRITE_REG(sc, ESP_DCTL,
 1.3       dbj 			ESPDCTL_20MHZ | ESPDCTL_INTENB | ESPDCTL_RESET);
 1.3       dbj 	DELAY(10);
1.22       dbj 	DPRINTF(("esp dctl is 0x%02x\n",NCR_READ_REG(sc,ESP_DCTL)));
 1.3       dbj 	NCR_WRITE_REG(sc, ESP_DCTL, ESPDCTL_20MHZ | ESPDCTL_INTENB);
 1.3       dbj 	DELAY(10);
1.22       dbj 	DPRINTF(("esp dctl is 0x%02x\n",NCR_READ_REG(sc,ESP_DCTL)));
 1.3       dbj
 1.3       dbj 	/* Set up SCSI DMA */
 1.3       dbj 	{
 1.3       dbj 		esc->sc_scsi_dma.nd_bst = NEXT68K_INTIO_BUS_SPACE;
 1.3       dbj
 1.3       dbj 		if (bus_space_map(esc->sc_scsi_dma.nd_bst, NEXT_P_SCSI_CSR,
1.30       dbj 				DD_SIZE,0, &esc->sc_scsi_dma.nd_bsh)) {
 1.3       dbj 			panic("\n%s: can't map scsi DMA registers",
 1.3       dbj 					sc->sc_dev.dv_xname);
 1.3       dbj 		}
 1.3       dbj
 1.3       dbj 		esc->sc_scsi_dma.nd_intr = NEXT_I_SCSI_DMA;
 1.3       dbj 		esc->sc_scsi_dma.nd_shutdown_cb  = &esp_dmacb_shutdown;
 1.3       dbj 		esc->sc_scsi_dma.nd_continue_cb  = &esp_dmacb_continue;
 1.3       dbj 		esc->sc_scsi_dma.nd_completed_cb = &esp_dmacb_completed;
 1.3       dbj 		esc->sc_scsi_dma.nd_cb_arg       = sc;
 1.3       dbj 		nextdma_config(&esc->sc_scsi_dma);
 1.3       dbj 		nextdma_init(&esc->sc_scsi_dma);
 1.3       dbj
1.18       dbj #if 0
1.18       dbj 		/* Turn on target selection using the `dma' method */
1.29    petrov 		sc->sc_features |= NCR_F_DMASELECT;
1.18       dbj #endif
1.18       dbj
1.18       dbj 		esc->sc_datain = -1;
1.18       dbj 		esc->sc_dmaaddr = 0;
1.18       dbj 		esc->sc_dmalen  = 0;
1.20       dbj 		esc->sc_dmasize = 0;
1.18       dbj
1.18       dbj 		esc->sc_loaded = 0;
1.18       dbj
1.18       dbj 		esc->sc_begin = 0;
1.18       dbj 		esc->sc_begin_size = 0;
1.18       dbj
 1.3       dbj 		{
 1.3       dbj 			int error;
 1.3       dbj 			if ((error = bus_dmamap_create(esc->sc_scsi_dma.nd_dmat,
1.34       dbj 					sc->sc_maxxfer, sc->sc_maxxfer/NBPG+1, sc->sc_maxxfer,
1.18       dbj 					0, BUS_DMA_ALLOCNOW, &esc->sc_main_dmamap)) != 0) {
1.18       dbj 				panic("%s: can't create main i/o DMA map, error = %d",
 1.3       dbj 						sc->sc_dev.dv_xname,error);
 1.3       dbj 			}
 1.3       dbj 		}
1.18       dbj 		esc->sc_main = 0;
1.18       dbj 		esc->sc_main_size = 0;
1.14       dbj
1.14       dbj 		{
1.14       dbj 			int error;
1.14       dbj 			if ((error = bus_dmamap_create(esc->sc_scsi_dma.nd_dmat,
1.19       dbj 					ESP_DMA_TAILBUFSIZE,
1.19       dbj 					1, ESP_DMA_TAILBUFSIZE,
1.14       dbj 					0, BUS_DMA_ALLOCNOW, &esc->sc_tail_dmamap)) != 0) {
1.14       dbj 				panic("%s: can't create tail i/o DMA map, error = %d",
1.14       dbj 						sc->sc_dev.dv_xname,error);
1.14       dbj 			}
1.14       dbj 		}
1.18       dbj 		esc->sc_tail = 0;
1.18       dbj 		esc->sc_tail_size = 0;
1.18       dbj
 1.3       dbj 	}
 1.1       dbj
 1.3       dbj 	/* Establish interrupt channel */
1.27  nisimura 	isrlink_autovec(ncr53c9x_intr, sc, NEXT_I_IPL(NEXT_I_SCSI), 0);
 1.3       dbj 	INTR_ENABLE(NEXT_I_SCSI);
 1.4       dbj
 1.4       dbj 	/* register interrupt stats */
1.26       cgd 	evcnt_attach_dynamic(&sc->sc_intrcnt, EVCNT_TYPE_INTR, NULL,
1.26       cgd 	    sc->sc_dev.dv_xname, "intr");
 1.4       dbj
 1.4       dbj 	/* Do the common parts of attachment. */
1.36  jdolecek 	sc->sc_adapter.adapt_minphys = minphys;
1.36  jdolecek 	sc->sc_adapter.adapt_request = ncr53c9x_scsipi_request;
1.35       chs 	ncr53c9x_attach(sc);
 1.1       dbj }
 1.1       dbj
 1.1       dbj /*
 1.1       dbj  * Glue functions.
 1.1       dbj  */
 1.1       dbj
 1.1       dbj u_char
 1.1       dbj esp_read_reg(sc, reg)
 1.1       dbj 	struct ncr53c9x_softc *sc;
 1.1       dbj 	int reg;
 1.1       dbj {
 1.1       dbj 	struct esp_softc *esc = (struct esp_softc *)sc;
 1.1       dbj
 1.1       dbj 	return(bus_space_read_1(esc->sc_bst, esc->sc_bsh, reg));
 1.1       dbj }
 1.1       dbj
 1.1       dbj void
 1.1       dbj esp_write_reg(sc, reg, val)
 1.1       dbj 	struct ncr53c9x_softc *sc;
 1.1       dbj 	int reg;
 1.1       dbj 	u_char val;
 1.1       dbj {
 1.1       dbj 	struct esp_softc *esc = (struct esp_softc *)sc;
 1.1       dbj
 1.1       dbj 	bus_space_write_1(esc->sc_bst, esc->sc_bsh, reg, val);
 1.1       dbj }
 1.1       dbj
 1.1       dbj int
 1.1       dbj esp_dma_isintr(sc)
 1.1       dbj 	struct ncr53c9x_softc *sc;
 1.1       dbj {
 1.4       dbj 	struct esp_softc *esc = (struct esp_softc *)sc;
 1.4       dbj
 1.4       dbj 	int r = (INTR_OCCURRED(NEXT_I_SCSI));
 1.4       dbj
 1.4       dbj 	if (r) {
1.13       dbj
1.20       dbj 		{
1.23       dbj 			int flushcount;
1.20       dbj 			int s;
1.20       dbj 			s = spldma();
1.20       dbj
1.23       dbj 			flushcount = 0;
1.23       dbj
1.22       dbj #ifdef ESP_DEBUG
1.22       dbj 			esp_dma_nest++;
1.28        tv
1.28        tv 			if (esp_debug) {
1.28        tv 				char sbuf[256];
1.28        tv
1.28        tv 				bitmask_snprintf((*(volatile u_long *)IIOV(NEXT_P_INTRSTAT)),
1.28        tv 						 NEXT_INTR_BITS, sbuf, sizeof(sbuf));
1.28        tv 				printf("esp_dma_isintr = 0x%s\n", sbuf);
1.28        tv 			}
1.22       dbj #endif
1.22       dbj
1.20       dbj 			while (esp_dma_isactive(sc)) {
1.23       dbj 				flushcount++;
1.17       dbj
1.17       dbj #ifdef DIAGNOSTIC
1.20       dbj 				r = (INTR_OCCURRED(NEXT_I_SCSI));
1.20       dbj 				if (!r) panic("esp intr enabled but dma failed to flush");
1.17       dbj #endif
1.23       dbj #ifdef DIAGNOSTIC
1.23       dbj #if 0
1.23       dbj 				if ((esc->sc_loaded & (ESP_LOADED_TAIL/* |ESP_UNLOADED_MAIN */))
1.23       dbj 						!= (ESP_LOADED_TAIL /* |ESP_UNLOADED_MAIN */)) {
1.23       dbj 					if (esc->sc_datain) {
1.23       dbj 						NCR_WRITE_REG(sc, ESP_DCTL,
1.23       dbj 								ESPDCTL_20MHZ | ESPDCTL_INTENB | ESPDCTL_DMARD);
1.23       dbj 					} else {
1.23       dbj 						NCR_WRITE_REG(sc, ESP_DCTL,
1.23       dbj 								ESPDCTL_20MHZ | ESPDCTL_INTENB);
1.23       dbj 					}
1.23       dbj 					next_dma_print(&esc->sc_scsi_dma);
1.23       dbj 					esp_dma_print(sc);
1.23       dbj 					printf("%s: unexpected flush: tc=0x%06x\n",
1.23       dbj 							sc->sc_dev.dv_xname,
1.23       dbj 							(((sc->sc_cfg2 & NCRCFG2_FE)
1.23       dbj 									? NCR_READ_REG(sc, NCR_TCH) : 0)<<16)|
1.23       dbj 							(NCR_READ_REG(sc, NCR_TCM)<<8)|
1.23       dbj 							NCR_READ_REG(sc, NCR_TCL));
1.23       dbj 					ncr53c9x_readregs(sc);
1.23       dbj 					printf("%s: readregs[intr=%02x,stat=%02x,step=%02x]\n",
1.23       dbj 							sc->sc_dev.dv_xname,
1.23       dbj 							sc->sc_espintr, sc->sc_espstat, sc->sc_espstep);
1.23       dbj 					panic("%s: flushing flushing non-tail dma\n",
1.23       dbj 							sc->sc_dev.dv_xname);
1.23       dbj 				}
1.23       dbj #endif
1.23       dbj #endif
1.23       dbj 				DPRINTF(("%s: flushing dma, count = %d\n", sc->sc_dev.dv_xname,flushcount));
1.20       dbj 				if (esc->sc_datain) {
1.20       dbj 					NCR_WRITE_REG(sc, ESP_DCTL,
1.20       dbj 							ESPDCTL_20MHZ | ESPDCTL_INTENB | ESPDCTL_DMAMOD | ESPDCTL_DMARD | ESPDCTL_FLUSH);
1.22       dbj 					DPRINTF(("esp dctl is 0x%02x\n",NCR_READ_REG(sc,ESP_DCTL)));
1.20       dbj 					NCR_WRITE_REG(sc, ESP_DCTL,
1.20       dbj 							ESPDCTL_20MHZ | ESPDCTL_INTENB | ESPDCTL_DMAMOD | ESPDCTL_DMARD);
1.20       dbj 				} else {
1.20       dbj 					NCR_WRITE_REG(sc, ESP_DCTL,
1.20       dbj 							ESPDCTL_20MHZ | ESPDCTL_INTENB | ESPDCTL_DMAMOD | ESPDCTL_FLUSH);
1.22       dbj 					DPRINTF(("esp dctl is 0x%02x\n",NCR_READ_REG(sc,ESP_DCTL)));
1.20       dbj 					NCR_WRITE_REG(sc, ESP_DCTL,
1.20       dbj 							ESPDCTL_20MHZ | ESPDCTL_INTENB | ESPDCTL_DMAMOD);
1.20       dbj 				}
1.22       dbj 				DPRINTF(("esp dctl is 0x%02x\n",NCR_READ_REG(sc,ESP_DCTL)));
1.20       dbj
1.20       dbj 				{
1.20       dbj 					int nr;
1.20       dbj 					nr = nextdma_intr(&esc->sc_scsi_dma);
1.20       dbj 					if (nr) {
1.20       dbj 						DPRINTF(("nextma_intr = %d\n",nr));
1.23       dbj #ifdef DIAGNOSTIC
1.31       dbj 						if (flushcount > 4) {
1.23       dbj 							printf("%s: unexpected flushcount %d\n",sc->sc_dev.dv_xname,flushcount);
1.23       dbj 						}
1.23       dbj #endif
1.23       dbj #ifdef DIAGNOSTIC
1.23       dbj #if 0
1.23       dbj 						if (esp_dma_isactive(sc)) {
1.23       dbj 							esp_dma_print(sc);
1.23       dbj 							printf("%s: dma still active after a flush with count %d\n",
1.23       dbj 									sc->sc_dev.dv_xname,flushcount);
1.23       dbj
1.23       dbj 						}
1.23       dbj #endif
1.23       dbj #endif
1.23       dbj 						flushcount = 0;
1.20       dbj 					}
1.16       dbj 				}
1.16       dbj 			}
1.20       dbj
1.22       dbj #ifdef ESP_DEBUG
1.22       dbj 			esp_dma_nest--;
1.22       dbj #endif
1.22       dbj
1.20       dbj 			splx(s);
1.13       dbj 		}
1.13       dbj
1.20       dbj #ifdef DIAGNOSTIC
1.20       dbj 		r = (INTR_OCCURRED(NEXT_I_SCSI));
1.20       dbj 		if (!r) panic("esp intr not enabled after dma flush");
1.20       dbj #endif
1.20       dbj
1.13       dbj 		/* Clear the DMAMOD bit in the DCTL register, since if this
1.13       dbj 		 * routine returns true, then the ncr53c9x_intr handler will
1.13       dbj 		 * be called and needs access to the scsi registers.
1.13       dbj 		 */
1.13       dbj 		if (esc->sc_datain) {
1.13       dbj 			NCR_WRITE_REG(sc, ESP_DCTL,
1.13       dbj 					ESPDCTL_20MHZ | ESPDCTL_INTENB | ESPDCTL_DMARD);
1.13       dbj 		} else {
1.13       dbj 			NCR_WRITE_REG(sc, ESP_DCTL,
1.13       dbj 					ESPDCTL_20MHZ | ESPDCTL_INTENB);
1.13       dbj 		}
1.22       dbj 		DPRINTF(("esp dctl is 0x%02x\n",NCR_READ_REG(sc,ESP_DCTL)));
1.13       dbj
 1.4       dbj 	}
 1.4       dbj
 1.4       dbj 	return (r);
 1.1       dbj }
 1.1       dbj
 1.1       dbj void
 1.1       dbj esp_dma_reset(sc)
 1.1       dbj 	struct ncr53c9x_softc *sc;
 1.1       dbj {
 1.1       dbj 	struct esp_softc *esc = (struct esp_softc *)sc;
 1.3       dbj
1.13       dbj 	DPRINTF(("esp dma reset\n"));
1.13       dbj
1.13       dbj #ifdef ESP_DEBUG
1.13       dbj 	if (esp_debug) {
1.28        tv 		char sbuf[256];
1.28        tv
1.28        tv 		bitmask_snprintf((*(volatile u_long *)IIOV(NEXT_P_INTRSTAT)),
1.28        tv 				 NEXT_INTR_BITS, sbuf, sizeof(sbuf));
1.28        tv 		printf("  *intrstat = 0x%s\n", sbuf);
1.28        tv
1.28        tv 		bitmask_snprintf((*(volatile u_long *)IIOV(NEXT_P_INTRMASK)),
1.28        tv 				 NEXT_INTR_BITS, sbuf, sizeof(sbuf));
1.28        tv 		printf("  *intrmask = 0x%s\n", sbuf);
1.13       dbj 	}
1.13       dbj #endif
1.13       dbj
1.13       dbj 	/* Clear the DMAMOD bit in the DCTL register: */
1.18       dbj 	NCR_WRITE_REG(sc, ESP_DCTL,
1.18       dbj 			ESPDCTL_20MHZ | ESPDCTL_INTENB);
1.22       dbj 	DPRINTF(("esp dctl is 0x%02x\n",NCR_READ_REG(sc,ESP_DCTL)));
1.13       dbj
 1.4       dbj 	nextdma_reset(&esc->sc_scsi_dma);
 1.4       dbj
1.18       dbj 	esc->sc_datain = -1;
1.18       dbj 	esc->sc_dmaaddr = 0;
1.18       dbj 	esc->sc_dmalen  = 0;
1.20       dbj 	esc->sc_dmasize = 0;
1.18       dbj
1.18       dbj 	esc->sc_loaded = 0;
1.18       dbj
1.18       dbj 	esc->sc_begin = 0;
1.18       dbj 	esc->sc_begin_size = 0;
1.13       dbj
1.18       dbj 	if (esc->sc_main_dmamap->dm_mapsize) {
1.18       dbj 		bus_dmamap_unload(esc->sc_scsi_dma.nd_dmat, esc->sc_main_dmamap);
1.13       dbj 	}
1.18       dbj 	esc->sc_main = 0;
1.18       dbj 	esc->sc_main_size = 0;
1.13       dbj
1.18       dbj 	if (esc->sc_tail_dmamap->dm_mapsize) {
1.18       dbj 		bus_dmamap_unload(esc->sc_scsi_dma.nd_dmat, esc->sc_tail_dmamap);
1.18       dbj 	}
1.18       dbj 	esc->sc_tail = 0;
1.18       dbj 	esc->sc_tail_size = 0;
 1.1       dbj }
 1.1       dbj
 1.1       dbj int
 1.1       dbj esp_dma_intr(sc)
 1.1       dbj 	struct ncr53c9x_softc *sc;
 1.1       dbj {
1.18       dbj #ifdef DIAGNOSTIC
1.18       dbj 	panic("%s: esp_dma_intr shouldn't be invoked.\n", sc->sc_dev.dv_xname);
1.11       dbj #endif
1.11       dbj
1.18       dbj 	return -1;
 1.1       dbj }
 1.1       dbj
1.19       dbj /* it appears that:
1.19       dbj  * addr and len arguments to this need to be kept up to date
1.19       dbj  * with the status of the transfter.
1.19       dbj  * the dmasize of this is the actual length of the transfer
1.19       dbj  * request, which is guaranteed to be less than maxxfer.
1.19       dbj  * (len may be > maxxfer)
1.19       dbj  */
1.19       dbj
 1.1       dbj int
 1.1       dbj esp_dma_setup(sc, addr, len, datain, dmasize)
 1.1       dbj 	struct ncr53c9x_softc *sc;
 1.1       dbj 	caddr_t *addr;
 1.1       dbj 	size_t *len;
 1.1       dbj 	int datain;
 1.1       dbj 	size_t *dmasize;
 1.1       dbj {
 1.1       dbj 	struct esp_softc *esc = (struct esp_softc *)sc;
 1.2       dbj
1.11       dbj #ifdef DIAGNOSTIC
1.20       dbj #ifdef ESP_DEBUG
1.11       dbj 	/* if this is a read DMA, pre-fill the buffer with 0xdeadbeef
1.11       dbj 	 * to identify bogus reads
1.11       dbj 	 */
1.11       dbj 	if (datain) {
1.14       dbj 		int *v = (int *)(*addr);
1.11       dbj 		int i;
1.14       dbj 		for(i=0;i<((*len)/4);i++) v[i] = 0xdeadbeef;
1.18       dbj 		v = (int *)(&(esc->sc_tailbuf[0]));
1.18       dbj 		for(i=0;i<((sizeof(esc->sc_tailbuf)/4));i++) v[i] = 0xdeaffeed;
1.23       dbj 	} else {
1.23       dbj 		int *v;
1.23       dbj 		int i;
1.23       dbj 		v = (int *)(&(esc->sc_tailbuf[0]));
1.23       dbj 		for(i=0;i<((sizeof(esc->sc_tailbuf)/4));i++) v[i] = 0xfeeb1eed;
1.11       dbj 	}
1.20       dbj #endif
1.11       dbj #endif
1.11       dbj
1.35       chs 	DPRINTF(("esp_dma_setup(%p,0x%08x,0x%08x)\n",*addr,*len,*dmasize));
1.11       dbj
1.24       dbj #if 0
1.12       dbj #ifdef DIAGNOSTIC /* @@@ this is ok sometimes. verify that we handle it ok
1.12       dbj 									 * and then remove this check
1.12       dbj 									 */
1.14       dbj 	if (*len != *dmasize) {
1.23       dbj 		panic("esp dmalen 0x%lx != size 0x%lx",*len,*dmasize);
1.11       dbj 	}
1.11       dbj #endif
1.24       dbj #endif
 1.4       dbj
 1.2       dbj #ifdef DIAGNOSTIC
 1.3       dbj 	if ((esc->sc_datain != -1) ||
1.18       dbj 			(esc->sc_main_dmamap->dm_mapsize != 0) ||
1.20       dbj 			(esc->sc_tail_dmamap->dm_mapsize != 0) ||
1.20       dbj 			(esc->sc_dmasize != 0)) {
 1.3       dbj 		panic("%s: map already loaded in esp_dma_setup\n"
1.35       chs 				"\tdatain = %d\n\tmain_mapsize=%ld\n\tail_mapsize=%ld\n\tdmasize = %d",
1.18       dbj 				sc->sc_dev.dv_xname, esc->sc_datain,
1.20       dbj 				esc->sc_main_dmamap->dm_mapsize,
1.20       dbj 				esc->sc_tail_dmamap->dm_mapsize,
1.20       dbj 				esc->sc_dmasize);
 1.2       dbj 	}
 1.2       dbj #endif
 1.2       dbj
1.20       dbj 	/* we are sometimes asked to dma zero  bytes, that's easy */
1.24       dbj 	if (*dmasize <= 0) {
1.20       dbj 		return(0);
1.20       dbj 	}
1.20       dbj
1.14       dbj 	/* Save these in case we have to abort DMA */
1.14       dbj 	esc->sc_datain   = datain;
1.14       dbj 	esc->sc_dmaaddr  = addr;
1.14       dbj 	esc->sc_dmalen   = len;
1.14       dbj 	esc->sc_dmasize  = *dmasize;
1.14       dbj
1.18       dbj 	esc->sc_loaded = 0;
1.18       dbj
1.23       dbj #define DMA_SCSI_ALIGNMENT 16
1.23       dbj #define DMA_SCSI_ALIGN(type, addr)	\
1.23       dbj 	((type)(((unsigned)(addr)+DMA_SCSI_ALIGNMENT-1) \
1.23       dbj 		&~(DMA_SCSI_ALIGNMENT-1)))
1.23       dbj #define DMA_SCSI_ALIGNED(addr) \
1.23       dbj 	(((unsigned)(addr)&(DMA_SCSI_ALIGNMENT-1))==0)
1.23       dbj
 1.2       dbj 	{
1.18       dbj 		size_t slop_bgn_size; /* # bytes to be fifo'd at beginning */
1.18       dbj 		size_t slop_end_size; /* # bytes to be transferred in tail buffer */
1.18       dbj
 1.3       dbj 		{
1.13       dbj 			u_long bgn = (u_long)(*esc->sc_dmaaddr);
1.13       dbj 			u_long end = (u_long)(*esc->sc_dmaaddr+esc->sc_dmasize);
 1.3       dbj
1.23       dbj 			slop_bgn_size = DMA_SCSI_ALIGNMENT-(bgn % DMA_SCSI_ALIGNMENT);
1.23       dbj 			if (slop_bgn_size == DMA_SCSI_ALIGNMENT) slop_bgn_size = 0;
1.19       dbj 			slop_end_size = (end % DMA_ENDALIGNMENT);
 1.3       dbj 		}
 1.3       dbj
1.23       dbj 		/* Force a minimum slop end size. This ensures that write
1.23       dbj 		 * requests will overrun, as required to get completion interrupts.
1.23       dbj 		 * In addition, since the tail buffer is guaranteed to be mapped
1.23       dbj 		 * in a single dma segment, the overrun won't accidentally
1.23       dbj 		 * end up in its own segment.
1.23       dbj 		 */
1.23       dbj 		if (!esc->sc_datain) {
1.24       dbj #if 0
1.23       dbj 			slop_end_size += ESP_DMA_MAXTAIL;
1.24       dbj #else
1.24       dbj 			slop_end_size += 0x10;
1.24       dbj #endif
1.23       dbj 		}
1.23       dbj
1.10       dbj 		/* Check to make sure we haven't counted extra slop
1.14       dbj 		 * as would happen for a very short dma buffer, also
1.14       dbj 		 * for short buffers, just stuff the entire thing in the tail
1.14       dbj 		 */
1.18       dbj 		if ((slop_bgn_size+slop_end_size >= esc->sc_dmasize)
1.20       dbj #if 0
1.18       dbj 				|| (esc->sc_dmasize <= ESP_DMA_MAXTAIL)
1.18       dbj #endif
1.18       dbj 				)
1.18       dbj 		{
1.14       dbj  			slop_bgn_size = 0;
1.14       dbj 			slop_end_size = esc->sc_dmasize;
1.18       dbj 		}
1.14       dbj
1.18       dbj 		/* initialize the fifo buffer */
1.18       dbj 		if (slop_bgn_size) {
1.18       dbj 			esc->sc_begin = *esc->sc_dmaaddr;
1.18       dbj 			esc->sc_begin_size = slop_bgn_size;
1.18       dbj 		} else {
1.18       dbj 			esc->sc_begin = 0;
1.18       dbj 			esc->sc_begin_size = 0;
1.18       dbj 		}
1.18       dbj
1.18       dbj 		/* Load the normal DMA map */
1.18       dbj 		{
1.18       dbj 			esc->sc_main      = *esc->sc_dmaaddr+slop_bgn_size;
1.18       dbj 			esc->sc_main_size = (esc->sc_dmasize)-(slop_end_size+slop_bgn_size);
1.18       dbj
1.18       dbj 			if (esc->sc_main_size) {
1.18       dbj 				int error;
1.18       dbj 				error = bus_dmamap_load(esc->sc_scsi_dma.nd_dmat,
1.18       dbj 						esc->sc_main_dmamap,
1.18       dbj 						esc->sc_main, esc->sc_main_size,
1.18       dbj 						NULL, BUS_DMA_NOWAIT);
1.18       dbj 				if (error) {
1.34       dbj #ifdef ESP_DEBUG
1.35       chs 					printf("%s: esc->sc_main_dmamap->_dm_size = %ld\n",
1.34       dbj 							sc->sc_dev.dv_xname,esc->sc_main_dmamap->_dm_size);
1.34       dbj 					printf("%s: esc->sc_main_dmamap->_dm_segcnt = %d\n",
1.34       dbj 							sc->sc_dev.dv_xname,esc->sc_main_dmamap->_dm_segcnt);
1.35       chs 					printf("%s: esc->sc_main_dmamap->_dm_maxsegsz = %ld\n",
1.34       dbj 							sc->sc_dev.dv_xname,esc->sc_main_dmamap->_dm_maxsegsz);
1.35       chs 					printf("%s: esc->sc_main_dmamap->_dm_boundary = %ld\n",
1.34       dbj 							sc->sc_dev.dv_xname,esc->sc_main_dmamap->_dm_boundary);
1.34       dbj 					esp_dma_print(sc);
1.34       dbj #endif
1.35       chs 					panic("%s: can't load main dma map. error = %d, addr=%p, size=0x%08x",
1.18       dbj 							sc->sc_dev.dv_xname, error,esc->sc_main,esc->sc_main_size);
1.18       dbj 				}
1.23       dbj #if 0
1.19       dbj 				bus_dmamap_sync(esc->sc_scsi_dma.nd_dmat, esc->sc_main_dmamap,
1.19       dbj 						0, esc->sc_main_dmamap->dm_mapsize,
1.19       dbj 						(esc->sc_datain ? BUS_DMASYNC_PREREAD : BUS_DMASYNC_PREWRITE));
1.34       dbj 				esc->sc_main_dmamap->dm_xfer_len = 0;
1.23       dbj #endif
1.18       dbj 			} else {
1.18       dbj 				esc->sc_main = 0;
1.18       dbj 			}
1.14       dbj 		}
 1.3       dbj
1.18       dbj 		/* Load the tail DMA map */
1.18       dbj 		if (slop_end_size) {
1.18       dbj 			esc->sc_tail      = DMA_ENDALIGN(caddr_t,esc->sc_tailbuf+slop_end_size)-slop_end_size;
1.18       dbj 			/* If the beginning of the tail is not correctly aligned,
1.18       dbj 			 * we have no choice but to align the start, which might then unalign the end.
1.18       dbj 			 */
1.23       dbj 			esc->sc_tail      = DMA_SCSI_ALIGN(caddr_t,esc->sc_tail);
1.18       dbj 			/* So therefore, we change the tail size to be end aligned again. */
1.18       dbj 			esc->sc_tail_size = DMA_ENDALIGN(caddr_t,esc->sc_tail+slop_end_size)-esc->sc_tail;
1.19       dbj
1.19       dbj 			/* @@@ next dma overrun lossage */
1.20       dbj 			if (!esc->sc_datain) {
1.21       dbj 				esc->sc_tail_size += ESP_DMA_OVERRUN;
1.20       dbj 			}
1.20       dbj
1.18       dbj 			{
1.18       dbj 				int error;
1.18       dbj 				error = bus_dmamap_load(esc->sc_scsi_dma.nd_dmat,
1.18       dbj 						esc->sc_tail_dmamap,
1.18       dbj 						esc->sc_tail, esc->sc_tail_size,
1.18       dbj 						NULL, BUS_DMA_NOWAIT);
1.18       dbj 				if (error) {
1.35       chs 					panic("%s: can't load tail dma map. error = %d, addr=%p, size=0x%08x",
1.18       dbj 							sc->sc_dev.dv_xname, error,esc->sc_tail,esc->sc_tail_size);
1.18       dbj 				}
1.23       dbj #if 0
1.19       dbj 				bus_dmamap_sync(esc->sc_scsi_dma.nd_dmat, esc->sc_tail_dmamap,
1.19       dbj 						0, esc->sc_tail_dmamap->dm_mapsize,
1.19       dbj 						(esc->sc_datain ? BUS_DMASYNC_PREREAD : BUS_DMASYNC_PREWRITE));
1.34       dbj 				esc->sc_tail_dmamap->dm_xfer_len = 0;
1.23       dbj #endif
 1.3       dbj 			}
 1.3       dbj 		}
 1.2       dbj 	}
 1.2       dbj
 1.1       dbj 	return (0);
 1.1       dbj }
 1.1       dbj
1.20       dbj #ifdef ESP_DEBUG
1.20       dbj /* For debugging */
 1.1       dbj void
1.20       dbj esp_dma_store(sc)
 1.1       dbj 	struct ncr53c9x_softc *sc;
 1.1       dbj {
 1.1       dbj 	struct esp_softc *esc = (struct esp_softc *)sc;
1.20       dbj 	char *p = &esp_dma_dump[0];
1.20       dbj
1.20       dbj 	p += sprintf(p,"%s: sc_datain=%d\n",sc->sc_dev.dv_xname,esc->sc_datain);
1.20       dbj 	p += sprintf(p,"%s: sc_loaded=0x%08x\n",sc->sc_dev.dv_xname,esc->sc_loaded);
 1.3       dbj
1.20       dbj 	if (esc->sc_dmaaddr) {
1.35       chs 		p += sprintf(p,"%s: sc_dmaaddr=%p\n",sc->sc_dev.dv_xname,*esc->sc_dmaaddr);
1.20       dbj 	} else {
1.20       dbj 		p += sprintf(p,"%s: sc_dmaaddr=NULL\n",sc->sc_dev.dv_xname);
1.20       dbj 	}
1.20       dbj 	if (esc->sc_dmalen) {
1.35       chs 		p += sprintf(p,"%s: sc_dmalen=0x%08x\n",sc->sc_dev.dv_xname,*esc->sc_dmalen);
1.20       dbj 	} else {
1.20       dbj 		p += sprintf(p,"%s: sc_dmalen=NULL\n",sc->sc_dev.dv_xname);
1.20       dbj 	}
1.20       dbj 	p += sprintf(p,"%s: sc_dmasize=0x%08x\n",sc->sc_dev.dv_xname,esc->sc_dmasize);
1.19       dbj
1.35       chs 	p += sprintf(p,"%s: sc_begin = %p, sc_begin_size = 0x%08x\n",
1.20       dbj 			sc->sc_dev.dv_xname, esc->sc_begin, esc->sc_begin_size);
1.35       chs 	p += sprintf(p,"%s: sc_main = %p, sc_main_size = 0x%08x\n",
1.20       dbj 			sc->sc_dev.dv_xname, esc->sc_main, esc->sc_main_size);
1.19       dbj 	{
1.19       dbj 		int i;
1.19       dbj 		bus_dmamap_t map = esc->sc_main_dmamap;
1.35       chs 		p += sprintf(p,"%s: sc_main_dmamap. mapsize = 0x%08lx, nsegs = %d\n",
1.20       dbj 				sc->sc_dev.dv_xname, map->dm_mapsize, map->dm_nsegs);
1.19       dbj 		for(i=0;i<map->dm_nsegs;i++) {
1.35       chs 			p += sprintf(p,"%s: map->dm_segs[%d].ds_addr = 0x%08lx, len = 0x%08lx\n",
1.20       dbj 			sc->sc_dev.dv_xname, i, map->dm_segs[i].ds_addr, map->dm_segs[i].ds_len);
1.19       dbj 		}
1.19       dbj 	}
1.35       chs 	p += sprintf(p,"%s: sc_tail = %p, sc_tail_size = 0x%08x\n",
1.20       dbj 			sc->sc_dev.dv_xname, esc->sc_tail, esc->sc_tail_size);
1.19       dbj 	{
1.19       dbj 		int i;
1.19       dbj 		bus_dmamap_t map = esc->sc_tail_dmamap;
1.35       chs 		p += sprintf(p,"%s: sc_tail_dmamap. mapsize = 0x%08lx, nsegs = %d\n",
1.20       dbj 				sc->sc_dev.dv_xname, map->dm_mapsize, map->dm_nsegs);
1.19       dbj 		for(i=0;i<map->dm_nsegs;i++) {
1.35       chs 			p += sprintf(p,"%s: map->dm_segs[%d].ds_addr = 0x%08lx, len = 0x%08lx\n",
1.20       dbj 			sc->sc_dev.dv_xname, i, map->dm_segs[i].ds_addr, map->dm_segs[i].ds_len);
1.19       dbj 		}
1.19       dbj 	}
1.20       dbj }
1.20       dbj
1.20       dbj void
1.20       dbj esp_dma_print(sc)
1.20       dbj 	struct ncr53c9x_softc *sc;
1.20       dbj {
1.20       dbj 	esp_dma_store(sc);
1.20       dbj 	printf("%s",esp_dma_dump);
1.20       dbj }
1.20       dbj #endif
1.20       dbj
1.20       dbj void
1.20       dbj esp_dma_go(sc)
1.20       dbj 	struct ncr53c9x_softc *sc;
1.20       dbj {
1.20       dbj 	struct esp_softc *esc = (struct esp_softc *)sc;
1.20       dbj
1.20       dbj 	DPRINTF(("%s: esp_dma_go(datain = %d)\n",
1.20       dbj 			sc->sc_dev.dv_xname, esc->sc_datain));
1.20       dbj
1.20       dbj #ifdef ESP_DEBUG
1.20       dbj 	if (esp_debug) esp_dma_print(sc);
1.20       dbj 	else esp_dma_store(sc);
1.19       dbj #endif
 1.4       dbj
1.20       dbj #ifdef ESP_DEBUG
1.11       dbj 	{
1.11       dbj 		int n = NCR_READ_REG(sc, NCR_FFLAG);
1.20       dbj 		DPRINTF(("%s: fifo size = %d, seq = 0x%x\n",
1.20       dbj 				sc->sc_dev.dv_xname,
1.20       dbj 				n & NCRFIFO_FF, (n & NCRFIFO_SS)>>5));
 1.4       dbj 	}
1.11       dbj #endif
 1.4       dbj
1.23       dbj 	/* zero length dma transfers are boring */
1.20       dbj 	if (esc->sc_dmasize == 0) {
1.20       dbj 		return;
1.20       dbj 	}
1.20       dbj
1.18       dbj #if defined(DIAGNOSTIC)
1.18       dbj   if ((esc->sc_begin_size == 0) &&
1.18       dbj 			(esc->sc_main_dmamap->dm_mapsize == 0) &&
1.18       dbj 			(esc->sc_tail_dmamap->dm_mapsize == 0)) {
1.20       dbj 		esp_dma_print(sc);
1.18       dbj 		panic("%s: No DMA requested!",sc->sc_dev.dv_xname);
1.18       dbj 	}
1.18       dbj #endif
1.18       dbj
1.18       dbj 	/* Stuff the fifo with the begin buffer */
1.18       dbj 	if (esc->sc_datain) {
 1.4       dbj 		int i;
1.23       dbj 		DPRINTF(("%s: FIFO read of %d bytes:",
1.23       dbj 				sc->sc_dev.dv_xname,esc->sc_begin_size));
1.18       dbj 		for(i=0;i<esc->sc_begin_size;i++) {
1.24       dbj 			esc->sc_begin[i]=NCR_READ_REG(sc, NCR_FIFO);
1.24       dbj 			DPRINTF((" %02x",esc->sc_begin[i]&0xff));
 1.4       dbj 		}
1.23       dbj 		DPRINTF(("\n"));
 1.4       dbj 	} else {
 1.4       dbj 		int i;
1.23       dbj 		DPRINTF(("%s: FIFO write of %d bytes:",
1.23       dbj 				sc->sc_dev.dv_xname,esc->sc_begin_size));
1.18       dbj 		for(i=0;i<esc->sc_begin_size;i++) {
1.18       dbj 			NCR_WRITE_REG(sc, NCR_FIFO, esc->sc_begin[i]);
1.24       dbj 			DPRINTF((" %02x",esc->sc_begin[i]&0xff));
 1.4       dbj 		}
1.23       dbj 		DPRINTF(("\n"));
1.11       dbj 	}
 1.4       dbj
1.14       dbj 	/* if we are a dma write cycle, copy the end slop */
1.14       dbj 	if (esc->sc_datain == 0) {
1.18       dbj 		memcpy(esc->sc_tail,
1.18       dbj 				(*esc->sc_dmaaddr+esc->sc_begin_size+esc->sc_main_size),
1.18       dbj 				(esc->sc_dmasize-(esc->sc_begin_size+esc->sc_main_size)));
1.14       dbj 	}
1.17       dbj
1.23       dbj 	if (esc->sc_main_dmamap->dm_mapsize) {
1.23       dbj 		bus_dmamap_sync(esc->sc_scsi_dma.nd_dmat, esc->sc_main_dmamap,
1.23       dbj 				0, esc->sc_main_dmamap->dm_mapsize,
1.23       dbj 				(esc->sc_datain ? BUS_DMASYNC_PREREAD : BUS_DMASYNC_PREWRITE));
1.34       dbj 		esc->sc_main_dmamap->dm_xfer_len = 0;
1.23       dbj 	}
1.23       dbj
1.23       dbj 	if (esc->sc_tail_dmamap->dm_mapsize) {
1.23       dbj 		bus_dmamap_sync(esc->sc_scsi_dma.nd_dmat, esc->sc_tail_dmamap,
1.23       dbj 				0, esc->sc_tail_dmamap->dm_mapsize,
1.23       dbj 				(esc->sc_datain ? BUS_DMASYNC_PREREAD : BUS_DMASYNC_PREWRITE));
1.34       dbj 		esc->sc_tail_dmamap->dm_xfer_len = 0;
1.23       dbj 	}
1.23       dbj
1.14       dbj 	nextdma_start(&esc->sc_scsi_dma,
1.25       dbj 			(esc->sc_datain ? DMACSR_SETREAD : DMACSR_SETWRITE));
1.12       dbj
1.14       dbj 	if (esc->sc_datain) {
1.14       dbj 		NCR_WRITE_REG(sc, ESP_DCTL,
1.14       dbj 				ESPDCTL_20MHZ | ESPDCTL_INTENB | ESPDCTL_DMAMOD | ESPDCTL_DMARD);
 1.3       dbj 	} else {
1.14       dbj 		NCR_WRITE_REG(sc, ESP_DCTL,
1.14       dbj 				ESPDCTL_20MHZ | ESPDCTL_INTENB | ESPDCTL_DMAMOD);
 1.3       dbj 	}
1.22       dbj 	DPRINTF(("esp dctl is 0x%02x\n",NCR_READ_REG(sc,ESP_DCTL)));
 1.1       dbj }
 1.1       dbj
 1.1       dbj void
 1.1       dbj esp_dma_stop(sc)
 1.1       dbj 	struct ncr53c9x_softc *sc;
 1.1       dbj {
1.34       dbj 	struct esp_softc *esc = (struct esp_softc *)sc;
1.34       dbj 	next_dma_print(&esc->sc_scsi_dma);
1.34       dbj 	esp_dma_print(sc);
1.34       dbj 	panic("%s: stop not yet implemented\n",sc->sc_dev.dv_xname);
 1.1       dbj }
 1.1       dbj
 1.1       dbj int
 1.1       dbj esp_dma_isactive(sc)
 1.1       dbj 	struct ncr53c9x_softc *sc;
 1.1       dbj {
 1.1       dbj 	struct esp_softc *esc = (struct esp_softc *)sc;
1.11       dbj 	int r = !nextdma_finished(&esc->sc_scsi_dma);
1.11       dbj 	DPRINTF(("esp_dma_isactive = %d\n",r));
1.11       dbj 	return(r);
 1.2       dbj }
 1.2       dbj
 1.2       dbj /****************************************************************/
 1.2       dbj
 1.2       dbj /* Internal dma callback routines */
 1.2       dbj bus_dmamap_t
 1.2       dbj esp_dmacb_continue(arg)
 1.2       dbj 	void *arg;
 1.2       dbj {
 1.2       dbj 	struct ncr53c9x_softc *sc = (struct ncr53c9x_softc *)arg;
 1.2       dbj 	struct esp_softc *esc = (struct esp_softc *)sc;
 1.2       dbj
1.18       dbj 	DPRINTF(("%s: dma continue\n",sc->sc_dev.dv_xname));
 1.4       dbj
 1.2       dbj #ifdef DIAGNOSTIC
 1.2       dbj 	if ((esc->sc_datain < 0) || (esc->sc_datain > 1)) {
 1.2       dbj 		panic("%s: map not loaded in dma continue callback, datain = %d",
 1.2       dbj 				sc->sc_dev.dv_xname,esc->sc_datain);
 1.2       dbj 	}
 1.2       dbj #endif
1.18       dbj
1.18       dbj 	if ((!(esc->sc_loaded & ESP_LOADED_MAIN)) &&
1.18       dbj 			(esc->sc_main_dmamap->dm_mapsize)) {
1.18       dbj 			DPRINTF(("%s: Loading main map\n",sc->sc_dev.dv_xname));
1.19       dbj #if 0
1.18       dbj 			bus_dmamap_sync(esc->sc_scsi_dma.nd_dmat, esc->sc_main_dmamap,
1.18       dbj 					0, esc->sc_main_dmamap->dm_mapsize,
1.14       dbj 					(esc->sc_datain ? BUS_DMASYNC_PREREAD : BUS_DMASYNC_PREWRITE));
1.34       dbj 			esc->sc_main_dmamap->dm_xfer_len = 0;
1.19       dbj #endif
1.18       dbj 			esc->sc_loaded |= ESP_LOADED_MAIN;
1.18       dbj 			return(esc->sc_main_dmamap);
1.18       dbj 	}
1.18       dbj
1.18       dbj 	if ((!(esc->sc_loaded & ESP_LOADED_TAIL)) &&
1.18       dbj 			(esc->sc_tail_dmamap->dm_mapsize)) {
1.18       dbj 			DPRINTF(("%s: Loading tail map\n",sc->sc_dev.dv_xname));
1.19       dbj #if 0
1.14       dbj 			bus_dmamap_sync(esc->sc_scsi_dma.nd_dmat, esc->sc_tail_dmamap,
1.14       dbj 					0, esc->sc_tail_dmamap->dm_mapsize,
1.14       dbj 					(esc->sc_datain ? BUS_DMASYNC_PREREAD : BUS_DMASYNC_PREWRITE));
1.34       dbj 			esc->sc_tail_dmamap->dm_xfer_len = 0;
1.19       dbj #endif
1.18       dbj 			esc->sc_loaded |= ESP_LOADED_TAIL;
1.14       dbj 			return(esc->sc_tail_dmamap);
1.10       dbj 	}
1.18       dbj
1.18       dbj 	DPRINTF(("%s: not loading map\n",sc->sc_dev.dv_xname));
1.18       dbj 	return(0);
 1.2       dbj }
 1.2       dbj
1.14       dbj
 1.2       dbj void
 1.2       dbj esp_dmacb_completed(map, arg)
 1.2       dbj 	bus_dmamap_t map;
 1.2       dbj 	void *arg;
 1.2       dbj {
 1.2       dbj 	struct ncr53c9x_softc *sc = (struct ncr53c9x_softc *)arg;
 1.2       dbj 	struct esp_softc *esc = (struct esp_softc *)sc;
 1.2       dbj
1.20       dbj 	DPRINTF(("%s: dma completed\n",sc->sc_dev.dv_xname));
 1.4       dbj
 1.2       dbj #ifdef DIAGNOSTIC
1.14       dbj 	if ((esc->sc_datain < 0) || (esc->sc_datain > 1)) {
1.18       dbj 		panic("%s: invalid dma direction in completed callback, datain = %d",
1.18       dbj 				sc->sc_dev.dv_xname,esc->sc_datain);
1.32       dbj 	}
1.32       dbj #endif
1.32       dbj
1.34       dbj #if defined(DIAGNOSTIC) && 0
1.32       dbj 	{
1.32       dbj 		int i;
1.32       dbj 		for(i=0;i<map->dm_nsegs;i++) {
1.33       dbj 			if (map->dm_xfer_len != map->dm_mapsize) {
1.32       dbj 				printf("%s: map->dm_mapsize = %d\n", sc->sc_dev.dv_xname,map->dm_mapsize);
1.32       dbj 				printf("%s: map->dm_nsegs = %d\n", sc->sc_dev.dv_xname,map->dm_nsegs);
1.33       dbj 				printf("%s: map->dm_xfer_len = %d\n", sc->sc_dev.dv_xname,map->dm_xfer_len);
1.32       dbj 				for(i=0;i<map->dm_nsegs;i++) {
1.32       dbj 					printf("%s: map->dm_segs[%d].ds_addr = 0x%08lx\n",
1.32       dbj 							sc->sc_dev.dv_xname,i,map->dm_segs[i].ds_addr);
1.32       dbj 					printf("%s: map->dm_segs[%d].ds_len = %d\n",
1.32       dbj 							sc->sc_dev.dv_xname,i,map->dm_segs[i].ds_len);
1.32       dbj 				}
1.32       dbj 				panic("%s: incomplete dma transfer\n",sc->sc_dev.dv_xname);
1.32       dbj 			}
1.32       dbj 		}
 1.2       dbj 	}
1.23       dbj #endif
1.23       dbj
1.23       dbj 	if (map == esc->sc_main_dmamap) {
1.23       dbj #ifdef DIAGNOSTIC
1.23       dbj 		if ((esc->sc_loaded & ESP_UNLOADED_MAIN) ||
1.23       dbj 				!(esc->sc_loaded & ESP_LOADED_MAIN)) {
1.23       dbj 			panic("%s: unexpected completed call for main map\n",sc->sc_dev.dv_xname);
1.23       dbj 		}
1.23       dbj #endif
1.23       dbj 		esc->sc_loaded |= ESP_UNLOADED_MAIN;
1.23       dbj 	} else if (map == esc->sc_tail_dmamap) {
1.23       dbj #ifdef DIAGNOSTIC
1.23       dbj 		if ((esc->sc_loaded & ESP_UNLOADED_TAIL) ||
1.23       dbj 				!(esc->sc_loaded & ESP_LOADED_TAIL)) {
1.23       dbj 			panic("%s: unexpected completed call for tail map\n",sc->sc_dev.dv_xname);
1.23       dbj 		}
1.23       dbj #endif
1.23       dbj 		esc->sc_loaded |= ESP_UNLOADED_TAIL;
1.23       dbj 	}
1.23       dbj #ifdef DIAGNOSTIC
1.23       dbj 	 else {
1.14       dbj 		panic("%s: unexpected completed map", sc->sc_dev.dv_xname);
 1.2       dbj 	}
 1.2       dbj #endif
 1.2       dbj
1.23       dbj #ifdef ESP_DEBUG
1.23       dbj 	if (esp_debug) {
1.23       dbj 		if (map == esc->sc_main_dmamap) {
1.23       dbj 			printf("%s: completed main map\n",sc->sc_dev.dv_xname);
1.23       dbj 		} else if (map == esc->sc_tail_dmamap) {
1.23       dbj 			printf("%s: completed tail map\n",sc->sc_dev.dv_xname);
1.23       dbj 		}
1.23       dbj 	}
1.23       dbj #endif
1.22       dbj
1.22       dbj #if 0
1.22       dbj 	if ((map == esc->sc_tail_dmamap) ||
1.22       dbj 			((esc->sc_tail_size == 0) && (map == esc->sc_main_dmamap))) {
1.22       dbj
1.22       dbj 		/* Clear the DMAMOD bit in the DCTL register to give control
1.22       dbj 		 * back to the scsi chip.
1.22       dbj 		 */
1.22       dbj 		if (esc->sc_datain) {
1.22       dbj 			NCR_WRITE_REG(sc, ESP_DCTL,
1.22       dbj 					ESPDCTL_20MHZ | ESPDCTL_INTENB | ESPDCTL_DMARD);
1.22       dbj 		} else {
1.22       dbj 			NCR_WRITE_REG(sc, ESP_DCTL,
1.22       dbj 					ESPDCTL_20MHZ | ESPDCTL_INTENB);
1.22       dbj 		}
1.22       dbj 		DPRINTF(("esp dctl is 0x%02x\n",NCR_READ_REG(sc,ESP_DCTL)));
1.22       dbj 	}
1.22       dbj #endif
1.22       dbj
1.22       dbj
1.19       dbj #if 0
1.14       dbj 	bus_dmamap_sync(esc->sc_scsi_dma.nd_dmat, map,
1.14       dbj 			0, map->dm_mapsize,
 1.2       dbj 			(esc->sc_datain ? BUS_DMASYNC_POSTREAD : BUS_DMASYNC_POSTWRITE));
1.19       dbj #endif
1.13       dbj
 1.2       dbj }
 1.2       dbj
 1.2       dbj void
 1.2       dbj esp_dmacb_shutdown(arg)
 1.2       dbj 	void *arg;
 1.2       dbj {
 1.2       dbj 	struct ncr53c9x_softc *sc = (struct ncr53c9x_softc *)arg;
 1.2       dbj 	struct esp_softc *esc = (struct esp_softc *)sc;
1.34       dbj 	bus_size_t xfer_len = 0;
 1.2       dbj
1.20       dbj 	DPRINTF(("%s: dma shutdown\n",sc->sc_dev.dv_xname));
 1.4       dbj
1.22       dbj #if 0
1.22       dbj 	{
1.22       dbj 		/* Clear the DMAMOD bit in the DCTL register to give control
1.22       dbj 		 * back to the scsi chip.
1.22       dbj 		 */
1.22       dbj 		if (esc->sc_datain) {
1.22       dbj 			NCR_WRITE_REG(sc, ESP_DCTL,
1.22       dbj 					ESPDCTL_20MHZ | ESPDCTL_INTENB | ESPDCTL_DMARD);
1.22       dbj 		} else {
1.22       dbj 			NCR_WRITE_REG(sc, ESP_DCTL,
1.22       dbj 					ESPDCTL_20MHZ | ESPDCTL_INTENB);
1.22       dbj 		}
1.22       dbj 		DPRINTF(("esp dctl is 0x%02x\n",NCR_READ_REG(sc,ESP_DCTL)));
1.22       dbj 	}
1.22       dbj #endif
1.22       dbj
1.22       dbj 	DPRINTF(("%s: esp_dma_nest == %d\n",sc->sc_dev.dv_xname,esp_dma_nest));
1.22       dbj
1.13       dbj 	/* Stuff the end slop into fifo */
 1.3       dbj
1.14       dbj #ifdef ESP_DEBUG
1.14       dbj 	if (esp_debug) {
1.14       dbj
1.13       dbj 		int n = NCR_READ_REG(sc, NCR_FFLAG);
1.20       dbj 		DPRINTF(("%s: fifo size = %d, seq = 0x%x\n",
1.20       dbj 				sc->sc_dev.dv_xname,n & NCRFIFO_FF, (n & NCRFIFO_SS)>>5));
1.13       dbj 	}
1.13       dbj #endif
1.12       dbj
1.34       dbj 	xfer_len += esc->sc_begin_size;
1.34       dbj
1.22       dbj 	if (esc->sc_main_dmamap->dm_mapsize) {
1.34       dbj 		xfer_len += esc->sc_main_dmamap->dm_xfer_len;
1.22       dbj 		bus_dmamap_sync(esc->sc_scsi_dma.nd_dmat, esc->sc_main_dmamap,
1.22       dbj 			0, esc->sc_main_dmamap->dm_mapsize,
1.22       dbj 				(esc->sc_datain ? BUS_DMASYNC_POSTREAD : BUS_DMASYNC_POSTWRITE));
1.22       dbj 		bus_dmamap_unload(esc->sc_scsi_dma.nd_dmat, esc->sc_main_dmamap);
1.22       dbj 	}
1.22       dbj
1.22       dbj 	if (esc->sc_tail_dmamap->dm_mapsize) {
1.34       dbj 		xfer_len += esc->sc_tail_dmamap->dm_xfer_len;
1.22       dbj 		bus_dmamap_sync(esc->sc_scsi_dma.nd_dmat, esc->sc_tail_dmamap,
1.22       dbj 			0, esc->sc_tail_dmamap->dm_mapsize,
1.22       dbj 				(esc->sc_datain ? BUS_DMASYNC_POSTREAD : BUS_DMASYNC_POSTWRITE));
1.22       dbj 		bus_dmamap_unload(esc->sc_scsi_dma.nd_dmat, esc->sc_tail_dmamap);
1.22       dbj 	}
1.22       dbj
1.34       dbj 	/* truncate in case tail overran */
1.34       dbj 	if (xfer_len > esc->sc_dmasize) {
1.34       dbj 		xfer_len = esc->sc_dmasize;
1.34       dbj 	}
1.34       dbj
1.22       dbj 	/* copy the tail dma buffer data for read transfers */
1.18       dbj 	if (esc->sc_datain == 1) {
1.18       dbj 		memcpy((*esc->sc_dmaaddr+esc->sc_begin_size+esc->sc_main_size),
1.18       dbj 				esc->sc_tail,
1.18       dbj 				(esc->sc_dmasize-(esc->sc_begin_size+esc->sc_main_size)));
 1.4       dbj 	}
1.13       dbj
1.18       dbj #ifdef ESP_DEBUG
1.18       dbj 	if (esp_debug) {
1.35       chs 		printf("%s: dma_shutdown: addr=%p,len=0x%08x,size=0x%08x\n",
1.18       dbj 				sc->sc_dev.dv_xname,
1.18       dbj 				*esc->sc_dmaaddr, *esc->sc_dmalen, esc->sc_dmasize);
1.24       dbj 		if (esp_debug > 10) {
1.24       dbj 			esp_hex_dump(*(esc->sc_dmaaddr),esc->sc_dmasize);
1.35       chs 			printf("%s: tail=%p,tailbuf=%p,tail_size=0x%08x\n",
1.24       dbj 					sc->sc_dev.dv_xname,
1.24       dbj 					esc->sc_tail, &(esc->sc_tailbuf[0]), esc->sc_tail_size);
1.24       dbj 			esp_hex_dump(&(esc->sc_tailbuf[0]),sizeof(esc->sc_tailbuf));
1.24       dbj 		}
1.13       dbj 	}
1.11       dbj #endif
 1.3       dbj
1.34       dbj #if 0
1.34       dbj 	KASSERT(xfer_len == esc->sc_dmasize);
1.34       dbj #endif
1.34       dbj
1.34       dbj 	*(esc->sc_dmaaddr) += xfer_len;
1.34       dbj 	*(esc->sc_dmalen)  -= xfer_len;
1.22       dbj
1.18       dbj 	esc->sc_main = 0;
1.18       dbj 	esc->sc_main_size = 0;
1.14       dbj 	esc->sc_tail = 0;
1.14       dbj 	esc->sc_tail_size = 0;
1.19       dbj
1.19       dbj 	esc->sc_datain = -1;
1.19       dbj 	esc->sc_dmaaddr = 0;
1.19       dbj 	esc->sc_dmalen  = 0;
1.20       dbj 	esc->sc_dmasize = 0;
1.19       dbj
1.19       dbj 	esc->sc_loaded = 0;
1.19       dbj
1.19       dbj 	esc->sc_begin = 0;
1.19       dbj 	esc->sc_begin_size = 0;
1.20       dbj
1.20       dbj #ifdef ESP_DEBUG
1.20       dbj 	if (esp_debug) {
1.28        tv 		char sbuf[256];
1.28        tv
1.28        tv 		bitmask_snprintf((*(volatile u_long *)IIOV(NEXT_P_INTRSTAT)),
1.28        tv 				 NEXT_INTR_BITS, sbuf, sizeof(sbuf));
1.28        tv 		printf("  *intrstat = 0x%s\n", sbuf);
1.28        tv
1.28        tv 		bitmask_snprintf((*(volatile u_long *)IIOV(NEXT_P_INTRMASK)),
1.28        tv 				 NEXT_INTR_BITS, sbuf, sizeof(sbuf));
1.28        tv 		printf("  *intrmask = 0x%s\n", sbuf);
1.20       dbj 	}
1.20       dbj #endif
 1.1       dbj }