dev/ic/sunscpal.c

1.21.48.1       mjf /*	$NetBSD: sunscpal.c,v 1.21.48.3 2009/01/17 13:28:56 mjf Exp $	*/
      1.1  fredette
      1.1  fredette /*
      1.1  fredette  * Copyright (c) 2001 Matthew Fredette
      1.1  fredette  * Copyright (c) 1995 David Jones, Gordon W. Ross
      1.1  fredette  * Copyright (c) 1994 Jarle Greipsland
      1.1  fredette  * All rights reserved.
      1.1  fredette  *
      1.1  fredette  * Redistribution and use in source and binary forms, with or without
      1.1  fredette  * modification, are permitted provided that the following conditions
      1.1  fredette  * are met:
      1.1  fredette  * 1. Redistributions of source code must retain the above copyright
      1.1  fredette  *    notice, this list of conditions and the following disclaimer.
      1.1  fredette  * 2. Redistributions in binary form must reproduce the above copyright
      1.1  fredette  *    notice, this list of conditions and the following disclaimer in the
      1.1  fredette  *    documentation and/or other materials provided with the distribution.
      1.1  fredette  * 3. The name of the authors may not be used to endorse or promote products
      1.1  fredette  *    derived from this software without specific prior written permission.
      1.1  fredette  * 4. All advertising materials mentioning features or use of this software
      1.1  fredette  *    must display the following acknowledgement:
      1.1  fredette  *      This product includes software developed by
      1.1  fredette  *      David Jones and Gordon Ross
      1.1  fredette  *
      1.1  fredette  * THIS SOFTWARE IS PROVIDED BY THE AUTHORS ``AS IS'' AND ANY EXPRESS OR
      1.1  fredette  * IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES
      1.1  fredette  * OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED.
      1.1  fredette  * IN NO EVENT SHALL THE AUTHORS BE LIABLE FOR ANY DIRECT, INDIRECT,
      1.1  fredette  * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT
      1.1  fredette  * NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
      1.1  fredette  * DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
      1.1  fredette  * THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
      1.1  fredette  * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF
      1.1  fredette  * THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
      1.1  fredette  */
      1.1  fredette
      1.1  fredette /*
      1.1  fredette  * This is a machine-independent driver for the Sun "sc"
      1.1  fredette  * SCSI Bus Controller (SBC).
      1.1  fredette  *
      1.1  fredette  * This code should work with any memory-mapped card,
      1.1  fredette  * and can be shared by multiple adapters that address
      1.1  fredette  * the card with different register offset spacings.
      1.1  fredette  * (This can happen on the atari, for example.)
      1.1  fredette  *
      1.1  fredette  * Credits, history:
      1.1  fredette  *
      1.1  fredette  * Matthew Fredette completely copied revision 1.38 of
      1.1  fredette  * ncr5380sbc.c, and then heavily modified it to match
      1.1  fredette  * the Sun sc PAL.  The remaining credits are for
      1.1  fredette  * ncr5380sbc.c:
      1.1  fredette  *
      1.1  fredette  * David Jones is the author of most of the code that now
      1.1  fredette  * appears in this file, and was the architect of the
      1.1  fredette  * current overall structure (MI/MD code separation, etc.)
      1.1  fredette  *
      1.1  fredette  * Gordon Ross integrated the message phase code, added lots of
      1.1  fredette  * comments about what happens when and why (re. SCSI spec.),
      1.1  fredette  * debugged some reentrance problems, and added several new
      1.1  fredette  * "hooks" needed for the Sun3 "si" adapters.
      1.1  fredette  *
      1.1  fredette  * The message in/out code was taken nearly verbatim from
      1.1  fredette  * the aic6360 driver by Jarle Greipsland.
      1.1  fredette  *
      1.1  fredette  * Several other NCR5380 drivers were used for reference
      1.1  fredette  * while developing this driver, including work by:
      1.1  fredette  *   The Alice Group (mac68k port) namely:
      1.1  fredette  *       Allen K. Briggs, Chris P. Caputo, Michael L. Finch,
      1.1  fredette  *       Bradley A. Grantham, and Lawrence A. Kesteloot
      1.1  fredette  *   Michael L. Hitch (amiga drivers: sci.c)
      1.1  fredette  *   Leo Weppelman (atari driver: ncr5380.c)
      1.1  fredette  * There are others too.  Thanks, everyone.
      1.1  fredette  *
      1.1  fredette  * Transliteration to bus_space() performed 9/17/98 by
      1.1  fredette  * John Ruschmeyer (jruschme (at) exit109.com) for i386 'nca' driver.
      1.1  fredette  * Thank you all.
      1.1  fredette  */
      1.9     lukem
      1.9     lukem #include <sys/cdefs.h>
1.21.48.1       mjf __KERNEL_RCSID(0, "$NetBSD: sunscpal.c,v 1.21.48.3 2009/01/17 13:28:56 mjf Exp $");
      1.1  fredette
      1.1  fredette #include "opt_ddb.h"
      1.1  fredette
      1.1  fredette #include <sys/param.h>
      1.1  fredette #include <sys/systm.h>
      1.1  fredette #include <sys/kernel.h>
      1.1  fredette #include <sys/errno.h>
      1.1  fredette #include <sys/malloc.h>
      1.1  fredette #include <sys/device.h>
      1.1  fredette #include <sys/buf.h>
      1.1  fredette #include <sys/proc.h>
      1.1  fredette #include <sys/user.h>
      1.1  fredette
      1.1  fredette #include <dev/scsipi/scsi_all.h>
      1.1  fredette #include <dev/scsipi/scsipi_all.h>
      1.1  fredette #include <dev/scsipi/scsipi_debug.h>
      1.1  fredette #include <dev/scsipi/scsi_message.h>
      1.1  fredette #include <dev/scsipi/scsiconf.h>
      1.1  fredette
      1.1  fredette #ifdef DDB
      1.1  fredette #include <ddb/db_output.h>
      1.1  fredette #endif
      1.1  fredette
      1.1  fredette #include <dev/ic/sunscpalreg.h>
      1.1  fredette #include <dev/ic/sunscpalvar.h>
      1.1  fredette
     1.16     perry static void	sunscpal_reset_scsibus(struct sunscpal_softc *);
     1.16     perry static void	sunscpal_sched(struct sunscpal_softc *);
     1.16     perry static void	sunscpal_done(struct sunscpal_softc *);
      1.1  fredette
1.21.48.2       mjf static int	sunscpal_select(struct sunscpal_softc *, struct sunscpal_req *);
     1.16     perry static void	sunscpal_reselect(struct sunscpal_softc *);
      1.1  fredette
     1.16     perry static int	sunscpal_msg_in(struct sunscpal_softc *);
     1.16     perry static int	sunscpal_msg_out(struct sunscpal_softc *);
     1.16     perry static int	sunscpal_data_xfer(struct sunscpal_softc *, int);
     1.16     perry static int	sunscpal_command(struct sunscpal_softc *);
     1.16     perry static int	sunscpal_status(struct sunscpal_softc *);
     1.16     perry static void	sunscpal_machine(struct sunscpal_softc *);
      1.1  fredette
     1.16     perry void	sunscpal_abort(struct sunscpal_softc *);
     1.16     perry void	sunscpal_cmd_timeout(void *);
      1.1  fredette /*
      1.5       wiz  * Action flags returned by the info_transfer functions:
      1.1  fredette  * (These determine what happens next.)
      1.1  fredette  */
      1.1  fredette #define ACT_CONTINUE	0x00	/* No flags: expect another phase */
      1.1  fredette #define ACT_DISCONNECT	0x01	/* Target is disconnecting */
      1.1  fredette #define ACT_CMD_DONE	0x02	/* Need to call scsipi_done() */
      1.1  fredette #define ACT_RESET_BUS	0x04	/* Need bus reset (cmd timeout) */
      1.1  fredette #define ACT_WAIT_DMA	0x10	/* Wait for DMA to complete */
      1.1  fredette
      1.1  fredette /*****************************************************************
      1.1  fredette  * Debugging stuff
      1.1  fredette  *****************************************************************/
      1.1  fredette
      1.1  fredette #ifndef DDB
      1.1  fredette /* This is used only in recoverable places. */
      1.1  fredette #ifndef Debugger
      1.1  fredette #define Debugger() printf("Debug: sunscpal.c:%d\n", __LINE__)
      1.1  fredette #endif
      1.1  fredette #endif
      1.1  fredette
      1.1  fredette #ifdef	SUNSCPAL_DEBUG
      1.1  fredette
      1.1  fredette #define	SUNSCPAL_DBG_BREAK	1
      1.1  fredette #define	SUNSCPAL_DBG_CMDS	2
      1.1  fredette #define	SUNSCPAL_DBG_DMA	4
      1.1  fredette int sunscpal_debug = 0;
      1.1  fredette #define	SUNSCPAL_BREAK() \
      1.1  fredette 	do { if (sunscpal_debug & SUNSCPAL_DBG_BREAK) Debugger(); } while (0)
     1.16     perry static void sunscpal_show_scsi_cmd(struct scsipi_xfer *);
      1.1  fredette #ifdef DDB
     1.16     perry void	sunscpal_clear_trace(void);
     1.16     perry void	sunscpal_show_trace(void);
     1.16     perry void	sunscpal_show_req(struct sunscpal_req *);
     1.16     perry void	sunscpal_show_state(void);
      1.1  fredette #endif	/* DDB */
      1.1  fredette #else	/* SUNSCPAL_DEBUG */
      1.1  fredette
      1.1  fredette #define	SUNSCPAL_BREAK() 		/* nada */
      1.1  fredette #define sunscpal_show_scsi_cmd(xs) /* nada */
      1.1  fredette
      1.1  fredette #endif	/* SUNSCPAL_DEBUG */
      1.1  fredette
     1.18   tsutsui static const char *
      1.1  fredette phase_names[8] = {
      1.1  fredette 	"DATA_OUT",
      1.1  fredette 	"DATA_IN",
      1.1  fredette 	"COMMAND",
      1.1  fredette 	"STATUS",
      1.1  fredette 	"UNSPEC1",
      1.1  fredette 	"UNSPEC2",
      1.1  fredette 	"MSG_OUT",
      1.1  fredette 	"MSG_IN",
      1.1  fredette };
      1.1  fredette
      1.1  fredette #ifdef SUNSCPAL_USE_BUS_DMA
     1.16     perry static void sunscpal_dma_alloc(struct sunscpal_softc *);
     1.16     perry static void sunscpal_dma_free(struct sunscpal_softc *);
     1.16     perry static void sunscpal_dma_setup(struct sunscpal_softc *);
      1.1  fredette #else
      1.1  fredette #define sunscpal_dma_alloc(sc) (*sc->sc_dma_alloc)(sc)
      1.1  fredette #define sunscpal_dma_free(sc) (*sc->sc_dma_free)(sc)
      1.1  fredette #define sunscpal_dma_setup(sc) (*sc->sc_dma_setup)(sc)
      1.1  fredette #endif
     1.16     perry static void sunscpal_minphys(struct buf *);
      1.1  fredette
      1.1  fredette /*****************************************************************
      1.1  fredette  * Actual chip control
      1.1  fredette  *****************************************************************/
      1.1  fredette
      1.1  fredette /*
      1.1  fredette  * XXX: These timeouts might need to be tuned...
      1.1  fredette  */
      1.1  fredette
      1.1  fredette /* This one is used when waiting for a phase change. (X100uS.) */
      1.1  fredette int sunscpal_wait_phase_timo = 1000 * 10 * 300;	/* 5 min. */
      1.1  fredette
      1.1  fredette /* These are used in the following inline functions. */
      1.1  fredette int sunscpal_wait_req_timo = 1000 * 50;	/* X2 = 100 mS. */
      1.1  fredette int sunscpal_wait_nrq_timo = 1000 * 25;	/* X2 =  50 mS. */
      1.1  fredette
     1.20     perry static inline int sunscpal_wait_req(struct sunscpal_softc *);
     1.20     perry static inline int sunscpal_wait_not_req(struct sunscpal_softc *);
     1.20     perry static inline void sunscpal_sched_msgout(struct sunscpal_softc *, int);
      1.1  fredette
      1.1  fredette /* Return zero on success. */
1.21.48.2       mjf static inline int sunscpal_wait_req(struct sunscpal_softc *sc)
      1.1  fredette {
      1.1  fredette 	int timo = sunscpal_wait_req_timo;
1.21.48.2       mjf
      1.1  fredette 	for (;;) {
      1.1  fredette 		if (SUNSCPAL_READ_2(sc, sunscpal_icr) & SUNSCPAL_ICR_REQUEST) {
      1.1  fredette 			timo = 0;	/* return 0 */
      1.1  fredette 			break;
      1.1  fredette 		}
      1.1  fredette 		if (--timo < 0)
      1.1  fredette 			break;	/* return -1 */
      1.1  fredette 		delay(2);
      1.1  fredette 	}
1.21.48.2       mjf 	return timo;
      1.1  fredette }
      1.1  fredette
      1.1  fredette /* Return zero on success. */
1.21.48.2       mjf static inline int sunscpal_wait_not_req(struct sunscpal_softc *sc)
      1.1  fredette {
      1.1  fredette 	int timo = sunscpal_wait_nrq_timo;
1.21.48.2       mjf
      1.1  fredette 	for (;;) {
1.21.48.2       mjf 		if ((SUNSCPAL_READ_2(sc, sunscpal_icr) &
1.21.48.2       mjf 		    SUNSCPAL_ICR_REQUEST) == 0) {
      1.1  fredette 			timo = 0;	/* return 0 */
      1.1  fredette 			break;
      1.1  fredette 		}
      1.1  fredette 		if (--timo < 0)
      1.1  fredette 			break;	/* return -1 */
      1.1  fredette 		delay(2);
      1.1  fredette 	}
1.21.48.2       mjf 	return timo;
      1.1  fredette }
      1.1  fredette
      1.1  fredette /*
      1.1  fredette  * These functions control DMA functions in the chipset independent of
      1.1  fredette  * the host DMA implementation.
      1.1  fredette  */
     1.16     perry static void sunscpal_dma_start(struct sunscpal_softc *);
     1.16     perry static void sunscpal_dma_poll(struct sunscpal_softc *);
     1.16     perry static void sunscpal_dma_stop(struct sunscpal_softc *);
      1.1  fredette
      1.1  fredette static void
1.21.48.2       mjf sunscpal_dma_start(struct sunscpal_softc *sc)
      1.1  fredette {
      1.1  fredette 	struct sunscpal_req *sr = sc->sc_current;
      1.1  fredette 	int xlen;
1.21.48.2       mjf 	uint16_t icr;
      1.1  fredette
      1.1  fredette 	xlen = sc->sc_reqlen;
      1.1  fredette
      1.1  fredette 	/* Let'er rip! */
      1.1  fredette 	icr = SUNSCPAL_READ_2(sc, sunscpal_icr);
      1.1  fredette 	icr |= SUNSCPAL_ICR_DMA_ENABLE |
     1.17     perry 	    ((xlen & 1) ? 0 : SUNSCPAL_ICR_WORD_MODE) |
      1.1  fredette 	    ((sr->sr_flags & SR_IMMED) ? 0 : SUNSCPAL_ICR_INTERRUPT_ENABLE);
      1.1  fredette 	SUNSCPAL_WRITE_2(sc, sunscpal_icr, icr);
      1.1  fredette
      1.1  fredette 	sc->sc_state |= SUNSCPAL_DOINGDMA;
      1.1  fredette
      1.1  fredette #ifdef	SUNSCPAL_DEBUG
      1.1  fredette 	if (sunscpal_debug & SUNSCPAL_DBG_DMA) {
1.21.48.2       mjf 		printf("%s: started, flags=0x%x\n",
1.21.48.2       mjf 		    __func__, sc->sc_state);
      1.1  fredette 	}
      1.1  fredette #endif
      1.1  fredette }
      1.1  fredette
      1.1  fredette #define	ICR_MASK (SUNSCPAL_ICR_PARITY_ERROR | SUNSCPAL_ICR_BUS_ERROR | SUNSCPAL_ICR_INTERRUPT_REQUEST)
      1.1  fredette #define	POLL_TIMO	50000	/* X100 = 5 sec. */
      1.1  fredette
      1.1  fredette /*
      1.1  fredette  * Poll (spin-wait) for DMA completion.
      1.1  fredette  * Called right after xx_dma_start(), and
      1.1  fredette  * xx_dma_stop() will be called next.
      1.1  fredette  */
      1.1  fredette static void
1.21.48.2       mjf sunscpal_dma_poll(struct sunscpal_softc *sc)
      1.1  fredette {
      1.1  fredette 	struct sunscpal_req *sr = sc->sc_current;
      1.1  fredette 	int tmo;
      1.1  fredette
      1.1  fredette 	/* Make sure DMA started successfully. */
      1.1  fredette 	if (sc->sc_state & SUNSCPAL_ABORTING)
      1.1  fredette 		return;
      1.1  fredette
     1.14       wiz 	/* Wait for any "DMA complete" or error bits. */
      1.1  fredette 	tmo = POLL_TIMO;
      1.1  fredette 	for (;;) {
      1.1  fredette 		if (SUNSCPAL_READ_2(sc, sunscpal_icr) & ICR_MASK)
      1.1  fredette 			break;
      1.1  fredette 		if (--tmo <= 0) {
      1.1  fredette 			printf("sc: DMA timeout (while polling)\n");
      1.1  fredette 			/* Indicate timeout as MI code would. */
      1.1  fredette 			sr->sr_flags |= SR_OVERDUE;
      1.1  fredette 			break;
      1.1  fredette 		}
      1.1  fredette 		delay(100);
      1.1  fredette 	}
1.21.48.2       mjf 	SUNSCPAL_TRACE("sunscpal_dma_poll: waited %d\n", POLL_TIMO - tmo);
      1.1  fredette
      1.1  fredette #ifdef	SUNSCPAL_DEBUG
      1.1  fredette 	if (sunscpal_debug & SUNSCPAL_DBG_DMA) {
      1.6  fredette 		char buffer[64];
1.21.48.3       mjf 		snprintb(buffer, sizeof(buffer),
1.21.48.3       mjf 		    SUNSCPAL_READ_2(sc, sunscpal_icr), SUNSCPAL_ICR_BITS);
1.21.48.2       mjf 		printf("%s: done, icr=%s\n", __func__, buffer);
      1.1  fredette 	}
      1.1  fredette #endif
      1.1  fredette }
      1.1  fredette
      1.1  fredette static void
1.21.48.2       mjf sunscpal_dma_stop(struct sunscpal_softc *sc)
      1.1  fredette {
      1.1  fredette 	struct sunscpal_req *sr = sc->sc_current;
      1.1  fredette 	struct scsipi_xfer *xs = sr->sr_xs;
      1.1  fredette 	int resid, ntrans;
1.21.48.2       mjf 	uint16_t icr;
      1.1  fredette
      1.1  fredette 	if ((sc->sc_state & SUNSCPAL_DOINGDMA) == 0) {
      1.1  fredette #ifdef	DEBUG
1.21.48.2       mjf 		printf("%s: DMA not running\n", __func__);
      1.1  fredette #endif
      1.1  fredette 		return;
      1.1  fredette 	}
      1.1  fredette 	sc->sc_state &= ~SUNSCPAL_DOINGDMA;
      1.1  fredette
      1.1  fredette 	/* First, halt the DMA engine. */
      1.1  fredette 	icr = SUNSCPAL_READ_2(sc, sunscpal_icr);
1.21.48.2       mjf 	icr &= ~(SUNSCPAL_ICR_DMA_ENABLE | SUNSCPAL_ICR_WORD_MODE |
1.21.48.2       mjf 	    SUNSCPAL_ICR_INTERRUPT_ENABLE);
      1.1  fredette 	SUNSCPAL_WRITE_2(sc, sunscpal_icr, icr);
      1.1  fredette
      1.1  fredette #ifdef	SUNSCPAL_USE_BUS_DMA
      1.1  fredette 	/*
     1.17     perry 	 * XXX - this function is supposed to be independent of
      1.1  fredette 	 * the host's DMA implementation.
      1.1  fredette 	 */
      1.1  fredette  {
      1.1  fredette 	 sunscpal_dma_handle_t dh = sr->sr_dma_hand;
     1.17     perry
      1.1  fredette 	 /* sync the DMA map: */
     1.17     perry 	 bus_dmamap_sync(sc->sunscpal_dmat, dh->dh_dmamap, 0, dh->dh_maplen,
1.21.48.2       mjf 	     ((xs->xs_control & XS_CTL_DATA_OUT) == 0 ?
1.21.48.2       mjf 	    BUS_DMASYNC_POSTREAD : BUS_DMASYNC_POSTWRITE));
      1.1  fredette  }
      1.1  fredette #endif /* SUNSCPAL_USE_BUS_DMA */
      1.1  fredette
      1.1  fredette
      1.1  fredette 	if (icr & (SUNSCPAL_ICR_BUS_ERROR)) {
      1.6  fredette 		char buffer[64];
1.21.48.3       mjf 		snprintb(buffer, sizeof(buffer), SUNSCPAL_ICR_BITS, icr);
      1.6  fredette 		printf("sc: DMA error, icr=%s, reset\n", buffer);
      1.1  fredette 		sr->sr_xs->error = XS_DRIVER_STUFFUP;
      1.1  fredette 		sc->sc_state |= SUNSCPAL_ABORTING;
      1.1  fredette 		goto out;
      1.1  fredette 	}
      1.1  fredette
      1.1  fredette 	/* Note that timeout may have set the error flag. */
      1.1  fredette 	if (sc->sc_state & SUNSCPAL_ABORTING)
      1.1  fredette 		goto out;
      1.1  fredette
      1.1  fredette 	/* XXX: Wait for DMA to actually finish? */
      1.1  fredette
      1.1  fredette 	/*
      1.1  fredette 	 * Now try to figure out how much actually transferred
      1.1  fredette 	 */
      1.1  fredette
1.21.48.2       mjf 	resid = SUNSCPAL_DMA_COUNT_FLIP(SUNSCPAL_READ_2(sc,
1.21.48.2       mjf 	    sunscpal_dma_count));
      1.1  fredette 	ntrans = sc->sc_reqlen - resid;
      1.1  fredette
      1.1  fredette #ifdef	SUNSCPAL_DEBUG
      1.1  fredette 	if (sunscpal_debug & SUNSCPAL_DBG_DMA) {
1.21.48.2       mjf 		printf("%s: resid=0x%x ntrans=0x%x\n",
1.21.48.2       mjf 		    __func__, resid, ntrans);
      1.1  fredette 	}
      1.1  fredette #endif
      1.1  fredette
      1.1  fredette 	if (ntrans < sc->sc_min_dma_len) {
      1.1  fredette 		printf("sc: DMA count: 0x%x\n", resid);
      1.1  fredette 		sc->sc_state |= SUNSCPAL_ABORTING;
      1.1  fredette 		goto out;
      1.1  fredette 	}
      1.1  fredette 	if (ntrans > sc->sc_datalen)
1.21.48.2       mjf 		panic("%s: excess transfer", __func__);
      1.1  fredette
      1.1  fredette 	/* Adjust data pointer */
      1.1  fredette 	sc->sc_dataptr += ntrans;
      1.1  fredette 	sc->sc_datalen -= ntrans;
      1.1  fredette
      1.1  fredette 	/*
      1.1  fredette 	 * After a read, we may need to clean-up
      1.1  fredette 	 * "Left-over bytes" (yuck!)
      1.1  fredette 	 */
      1.1  fredette 	if (((xs->xs_control & XS_CTL_DATA_OUT) == 0) &&
1.21.48.2       mjf 	    ((icr & SUNSCPAL_ICR_ODD_LENGTH) != 0)) {
      1.1  fredette #ifdef DEBUG
      1.1  fredette 		printf("sc: Got Left-over bytes!\n");
      1.1  fredette #endif
      1.1  fredette 		*(sc->sc_dataptr++) = SUNSCPAL_READ_1(sc, sunscpal_data);
      1.1  fredette 		sc->sc_datalen--;
      1.1  fredette 	}
      1.1  fredette
1.21.48.2       mjf  out:
      1.1  fredette 	SUNSCPAL_WRITE_2(sc, sunscpal_dma_count, SUNSCPAL_DMA_COUNT_FLIP(0));
      1.1  fredette
      1.1  fredette }
      1.1  fredette
      1.1  fredette /* Ask the target for a MSG_OUT phase. */
     1.20     perry static inline void
1.21.48.2       mjf sunscpal_sched_msgout(struct sunscpal_softc *sc, int msg_code)
      1.1  fredette {
     1.17     perry 	/*
      1.1  fredette 	 * This controller does not allow you to assert ATN, which
      1.1  fredette 	 * will eventually leave us with no option other than to reset
      1.1  fredette 	 * the bus.  We keep this function as a placeholder, though,
      1.1  fredette 	 * and this printf will eventually go away or get #ifdef'ed:
      1.1  fredette 	 */
1.21.48.2       mjf 	printf("%s: trying to schedule 0x%0x\n", __func__, msg_code);
      1.1  fredette 	sc->sc_msgpriq |= msg_code;
      1.1  fredette }
      1.1  fredette
      1.1  fredette int
1.21.48.2       mjf sunscpal_pio_out(struct sunscpal_softc *sc, int phase, int count, uint8_t *data)
      1.1  fredette {
      1.1  fredette 	int resid;
      1.1  fredette
      1.1  fredette 	resid = count;
      1.1  fredette 	while (resid > 0) {
      1.1  fredette 		if (!SUNSCPAL_BUSY(sc)) {
      1.1  fredette 			SUNSCPAL_TRACE("pio_out: lost BSY, resid=%d\n", resid);
      1.1  fredette 			break;
      1.1  fredette 		}
      1.1  fredette 		if (sunscpal_wait_req(sc)) {
      1.1  fredette 			SUNSCPAL_TRACE("pio_out: no REQ, resid=%d\n", resid);
      1.1  fredette 			break;
      1.1  fredette 		}
1.21.48.2       mjf 		if (SUNSCPAL_BUS_PHASE(SUNSCPAL_READ_2(sc, sunscpal_icr)) !=
1.21.48.2       mjf 		    phase)
      1.1  fredette 			break;
      1.1  fredette
      1.1  fredette 		/* Put the data on the bus. */
      1.1  fredette 		if (data) {
      1.1  fredette 			SUNSCPAL_BYTE_WRITE(sc, phase, *data++);
      1.1  fredette 		} else {
      1.1  fredette 			SUNSCPAL_BYTE_WRITE(sc, phase, 0);
      1.1  fredette 		}
      1.1  fredette
      1.1  fredette 		--resid;
      1.1  fredette 	}
      1.1  fredette
1.21.48.2       mjf 	return count - resid;
      1.1  fredette }
      1.1  fredette
      1.1  fredette
      1.1  fredette int
1.21.48.2       mjf sunscpal_pio_in(struct sunscpal_softc *sc, int phase, int count, uint8_t *data)
      1.1  fredette {
      1.1  fredette 	int resid;
      1.1  fredette
      1.1  fredette 	resid = count;
      1.1  fredette 	while (resid > 0) {
      1.1  fredette 		if (!SUNSCPAL_BUSY(sc)) {
      1.1  fredette 			SUNSCPAL_TRACE("pio_in: lost BSY, resid=%d\n", resid);
      1.1  fredette 			break;
      1.1  fredette 		}
      1.1  fredette 		if (sunscpal_wait_req(sc)) {
      1.1  fredette 			SUNSCPAL_TRACE("pio_in: no REQ, resid=%d\n", resid);
      1.1  fredette 			break;
      1.1  fredette 		}
      1.1  fredette 		/* A phase change is not valid until AFTER REQ rises! */
1.21.48.2       mjf 		if (SUNSCPAL_BUS_PHASE(SUNSCPAL_READ_2(sc, sunscpal_icr)) !=
1.21.48.2       mjf 		    phase)
      1.1  fredette 			break;
      1.1  fredette
      1.1  fredette 		/* Read the data bus. */
      1.1  fredette 		if (data)
      1.1  fredette 			*data++ = SUNSCPAL_BYTE_READ(sc, phase);
      1.1  fredette 		else
1.21.48.2       mjf 			(void)SUNSCPAL_BYTE_READ(sc, phase);
      1.1  fredette
      1.1  fredette 		--resid;
      1.1  fredette 	}
      1.1  fredette
1.21.48.2       mjf 	return count - resid;
      1.1  fredette }
      1.1  fredette
      1.1  fredette
      1.1  fredette void
1.21.48.2       mjf sunscpal_init(struct sunscpal_softc *sc)
      1.1  fredette {
      1.1  fredette 	int i, j;
      1.1  fredette
      1.1  fredette #ifdef	SUNSCPAL_DEBUG
      1.1  fredette 	sunscpal_debug_sc = sc;
      1.1  fredette #endif
      1.1  fredette
      1.1  fredette 	for (i = 0; i < SUNSCPAL_OPENINGS; i++)
      1.1  fredette 		sc->sc_ring[i].sr_xs = NULL;
      1.1  fredette 	for (i = 0; i < 8; i++)
      1.1  fredette 		for (j = 0; j < 8; j++)
      1.1  fredette 			sc->sc_matrix[i][j] = NULL;
      1.1  fredette
      1.1  fredette 	sc->sc_prevphase = SUNSCPAL_PHASE_INVALID;
      1.1  fredette 	sc->sc_state = SUNSCPAL_IDLE;
      1.1  fredette
      1.1  fredette 	SUNSCPAL_WRITE_2(sc, sunscpal_icr, 0);
      1.1  fredette 	SUNSCPAL_WRITE_2(sc, sunscpal_dma_addr_h, 0);
      1.1  fredette 	SUNSCPAL_WRITE_2(sc, sunscpal_dma_addr_l, 0);
      1.1  fredette 	SUNSCPAL_WRITE_2(sc, sunscpal_dma_count, SUNSCPAL_DMA_COUNT_FLIP(0));
      1.1  fredette
      1.1  fredette 	SUNSCPAL_CLR_INTR(sc);
      1.1  fredette
      1.1  fredette 	/* Another hack (Er.. hook!) for anything that needs it: */
      1.1  fredette 	if (sc->sc_intr_on) {
      1.1  fredette 		SUNSCPAL_TRACE("init: intr ON\n", 0);
      1.1  fredette 		sc->sc_intr_on(sc);
      1.1  fredette 	}
      1.1  fredette }
      1.1  fredette
      1.1  fredette
      1.1  fredette static void
1.21.48.2       mjf sunscpal_reset_scsibus(struct sunscpal_softc *sc)
      1.1  fredette {
      1.1  fredette
1.21.48.2       mjf 	SUNSCPAL_TRACE("reset_scsibus, cur=0x%x\n", (long)sc->sc_current);
      1.1  fredette
      1.1  fredette 	SUNSCPAL_WRITE_2(sc, sunscpal_icr, SUNSCPAL_ICR_RESET);
      1.1  fredette 	delay(500);
      1.1  fredette 	SUNSCPAL_WRITE_2(sc, sunscpal_icr, 0);
      1.1  fredette
      1.1  fredette 	SUNSCPAL_CLR_INTR(sc);
      1.1  fredette 	/* XXX - Need long delay here! */
      1.1  fredette 	delay(100000);
      1.1  fredette
      1.1  fredette 	/* XXX - Need to cancel disconnected requests. */
      1.1  fredette }
      1.1  fredette
      1.1  fredette
      1.1  fredette /*
      1.1  fredette  * Interrupt handler for the SCSI Bus Controller (SBC)
      1.1  fredette  * This may also called for a DMA timeout (at splbio).
      1.1  fredette  */
      1.1  fredette int
1.21.48.2       mjf sunscpal_intr(void *arg)
      1.1  fredette {
      1.1  fredette 	struct sunscpal_softc *sc = arg;
      1.1  fredette 	int claimed = 0;
      1.1  fredette
      1.1  fredette 	/*
      1.1  fredette 	 * Do not touch SBC regs here unless sc_current == NULL
      1.1  fredette 	 * or it will complain about "register conflict" errors.
      1.1  fredette 	 * Instead, just let sunscpal_machine() deal with it.
      1.1  fredette 	 */
      1.1  fredette 	SUNSCPAL_TRACE("intr: top, state=%d\n", sc->sc_state);
      1.1  fredette
      1.1  fredette 	if (sc->sc_state == SUNSCPAL_IDLE) {
      1.1  fredette 		/*
      1.1  fredette 		 * Might be reselect.  sunscpal_reselect() will check,
      1.1  fredette 		 * and set up the connection if so.  This will verify
      1.1  fredette 		 * that sc_current == NULL at the beginning...
      1.1  fredette 		 */
      1.1  fredette
      1.1  fredette 		/* Another hack (Er.. hook!) for anything that needs it: */
      1.1  fredette 		if (sc->sc_intr_off) {
      1.1  fredette 			SUNSCPAL_TRACE("intr: for reselect, intr off\n", 0);
      1.1  fredette 		    sc->sc_intr_off(sc);
      1.1  fredette 		}
      1.1  fredette
      1.1  fredette 		sunscpal_reselect(sc);
      1.1  fredette 	}
      1.1  fredette
      1.1  fredette 	/*
      1.1  fredette 	 * The remaining documented interrupt causes are a DMA complete
      1.1  fredette 	 * condition.
      1.1  fredette 	 *
     1.17     perry 	 * The procedure is to let sunscpal_machine() figure out what
      1.1  fredette 	 * to do next.
      1.1  fredette 	 */
      1.1  fredette 	if (sc->sc_state & SUNSCPAL_WORKING) {
      1.1  fredette 		SUNSCPAL_TRACE("intr: call machine, cur=0x%x\n",
1.21.48.2       mjf 		    (long)sc->sc_current);
      1.1  fredette 		/* This will usually free-up the nexus. */
      1.1  fredette 		sunscpal_machine(sc);
      1.1  fredette 		SUNSCPAL_TRACE("intr: machine done, cur=0x%x\n",
1.21.48.2       mjf 		    (long)sc->sc_current);
      1.1  fredette 		claimed = 1;
      1.1  fredette 	}
      1.1  fredette
      1.1  fredette 	/* Maybe we can run some commands now... */
      1.1  fredette 	if (sc->sc_state == SUNSCPAL_IDLE) {
      1.1  fredette 		SUNSCPAL_TRACE("intr: call sched, cur=0x%x\n",
1.21.48.2       mjf 		    (long)sc->sc_current);
      1.1  fredette 		sunscpal_sched(sc);
      1.1  fredette 		SUNSCPAL_TRACE("intr: sched done, cur=0x%x\n",
1.21.48.2       mjf 		    (long)sc->sc_current);
      1.1  fredette 	}
      1.1  fredette
      1.1  fredette 	return claimed;
      1.1  fredette }
      1.1  fredette
      1.1  fredette
      1.1  fredette /*
      1.1  fredette  * Abort the current command (i.e. due to timeout)
      1.1  fredette  */
      1.1  fredette void
1.21.48.2       mjf sunscpal_abort(struct sunscpal_softc *sc)
      1.1  fredette {
      1.1  fredette
      1.1  fredette 	/*
      1.1  fredette 	 * Finish it now.  If DMA is in progress, we
      1.1  fredette 	 * can not call sunscpal_sched_msgout() because
      1.1  fredette 	 * that hits the SBC (avoid DMA conflict).
      1.1  fredette 	 */
      1.1  fredette
      1.1  fredette 	/* Another hack (Er.. hook!) for anything that needs it: */
      1.1  fredette 	if (sc->sc_intr_off) {
      1.1  fredette 		SUNSCPAL_TRACE("abort: intr off\n", 0);
      1.1  fredette 		sc->sc_intr_off(sc);
      1.1  fredette 	}
      1.1  fredette
      1.1  fredette 	sc->sc_state |= SUNSCPAL_ABORTING;
      1.1  fredette 	if ((sc->sc_state & SUNSCPAL_DOINGDMA) == 0) {
      1.1  fredette 		sunscpal_sched_msgout(sc, SEND_ABORT);
      1.1  fredette 	}
      1.1  fredette 	SUNSCPAL_TRACE("abort: call machine, cur=0x%x\n",
1.21.48.2       mjf 	    (long)sc->sc_current);
      1.1  fredette 	sunscpal_machine(sc);
      1.1  fredette 	SUNSCPAL_TRACE("abort: machine done, cur=0x%x\n",
1.21.48.2       mjf 	    (long)sc->sc_current);
      1.1  fredette
      1.1  fredette 	/* Another hack (Er.. hook!) for anything that needs it: */
      1.1  fredette 	if (sc->sc_intr_on) {
      1.1  fredette 		SUNSCPAL_TRACE("abort: intr ON\n", 0);
1.21.48.2       mjf 		sc->sc_intr_on(sc);
      1.1  fredette 	}
      1.1  fredette }
      1.1  fredette
      1.1  fredette /*
      1.1  fredette  * Timeout handler, scheduled for each SCSI command.
      1.1  fredette  */
      1.1  fredette void
1.21.48.2       mjf sunscpal_cmd_timeout(void *arg)
      1.1  fredette {
      1.1  fredette 	struct sunscpal_req *sr = arg;
      1.1  fredette 	struct scsipi_xfer *xs;
      1.2    bouyer 	struct scsipi_periph *periph;
      1.1  fredette 	struct sunscpal_softc *sc;
      1.1  fredette 	int s;
      1.1  fredette
      1.1  fredette 	s = splbio();
      1.1  fredette
      1.1  fredette 	/* Get all our variables... */
      1.1  fredette 	xs = sr->sr_xs;
      1.1  fredette 	if (xs == NULL) {
1.21.48.2       mjf 		printf("%s: no scsipi_xfer\n", __func__);
      1.1  fredette 		goto out;
      1.1  fredette 	}
      1.2    bouyer 	periph = xs->xs_periph;
1.21.48.2       mjf 	sc = device_private(periph->periph_channel->chan_adapter->adapt_dev);
      1.1  fredette
      1.1  fredette 	printf("%s: cmd timeout, targ=%d, lun=%d\n",
1.21.48.2       mjf 	    device_xname(sc->sc_dev),
      1.1  fredette 	    sr->sr_target, sr->sr_lun);
      1.1  fredette
      1.1  fredette 	/*
      1.1  fredette 	 * Mark the overdue job as failed, and arrange for
      1.1  fredette 	 * sunscpal_machine to terminate it.  If the victim
      1.1  fredette 	 * is the current job, call sunscpal_machine() now.
      1.1  fredette 	 * Otherwise arrange for sunscpal_sched() to do it.
      1.1  fredette 	 */
      1.1  fredette 	sr->sr_flags |= SR_OVERDUE;
      1.1  fredette 	if (sc->sc_current == sr) {
1.21.48.2       mjf 		SUNSCPAL_TRACE("cmd_tmo: call abort, sr=0x%x\n", (long)sr);
      1.1  fredette 		sunscpal_abort(sc);
      1.1  fredette 	} else {
      1.1  fredette 		/*
      1.1  fredette 		 * The driver may be idle, or busy with another job.
      1.1  fredette 		 * Arrange for sunscpal_sched() to do the deed.
      1.1  fredette 		 */
      1.1  fredette 		SUNSCPAL_TRACE("cmd_tmo: clear matrix, t/l=0x%02x\n",
1.21.48.2       mjf 		    (sr->sr_target << 4) | sr->sr_lun);
      1.1  fredette 		sc->sc_matrix[sr->sr_target][sr->sr_lun] = NULL;
      1.1  fredette 	}
      1.1  fredette
      1.1  fredette 	/*
      1.1  fredette 	 * We may have aborted the current job, or may have
      1.1  fredette 	 * already been idle. In either case, we should now
      1.1  fredette 	 * be idle, so try to start another job.
      1.1  fredette 	 */
      1.1  fredette 	if (sc->sc_state == SUNSCPAL_IDLE) {
      1.1  fredette 		SUNSCPAL_TRACE("cmd_tmo: call sched, cur=0x%x\n",
1.21.48.2       mjf 		    (long)sc->sc_current);
      1.1  fredette 		sunscpal_sched(sc);
      1.1  fredette 		SUNSCPAL_TRACE("cmd_tmo: sched done, cur=0x%x\n",
1.21.48.2       mjf 		    (long)sc->sc_current);
      1.1  fredette 	}
      1.1  fredette
1.21.48.2       mjf  out:
      1.1  fredette 	splx(s);
      1.1  fredette }
      1.1  fredette
      1.1  fredette
      1.1  fredette /*****************************************************************
      1.1  fredette  * Interface to higher level
      1.1  fredette  *****************************************************************/
      1.1  fredette
      1.1  fredette
      1.1  fredette /*
      1.1  fredette  * Enter a new SCSI command into the "issue" queue, and
      1.1  fredette  * if there is work to do, start it going.
      1.1  fredette  *
      1.1  fredette  * WARNING:  This can be called recursively!
      1.1  fredette  * (see comment in sunscpal_done)
      1.1  fredette  */
      1.2    bouyer void
1.21.48.2       mjf sunscpal_scsipi_request(struct scsipi_channel *chan, scsipi_adapter_req_t req,
1.21.48.2       mjf     void *arg)
      1.2    bouyer {
      1.1  fredette 	struct scsipi_xfer *xs;
      1.2    bouyer 	struct scsipi_periph *periph;
1.21.48.2       mjf 	struct sunscpal_softc *sc;
1.21.48.2       mjf 	struct sunscpal_req *sr;
      1.2    bouyer 	int s, i, flags;
      1.1  fredette
1.21.48.2       mjf 	sc = device_private(chan->chan_adapter->adapt_dev);
1.21.48.2       mjf
      1.2    bouyer 	switch (req) {
      1.2    bouyer 	case ADAPTER_REQ_RUN_XFER:
      1.2    bouyer 		xs = arg;
      1.2    bouyer 		periph = xs->xs_periph;
      1.2    bouyer 		flags = xs->xs_control;
      1.1  fredette
      1.2    bouyer 		if (flags & XS_CTL_DATA_UIO)
      1.2    bouyer 			panic("sunscpal: scsi data uio requested");
      1.1  fredette
      1.2    bouyer 		s = splbio();
      1.1  fredette
      1.2    bouyer 		if (flags & XS_CTL_POLL) {
      1.2    bouyer 			/* Terminate any current command. */
      1.2    bouyer 			sr = sc->sc_current;
1.21.48.2       mjf 			if (sr != NULL) {
1.21.48.2       mjf 				printf("%s: polled request aborting %d/%d\n",
1.21.48.2       mjf 				    device_xname(sc->sc_dev), sr->sr_target,
1.21.48.2       mjf 				    sr->sr_lun);
      1.2    bouyer 				sunscpal_abort(sc);
      1.2    bouyer 			}
      1.2    bouyer 			if (sc->sc_state != SUNSCPAL_IDLE) {
1.21.48.2       mjf 				panic("%s: polled request, abort failed",
1.21.48.2       mjf 				    __func__);
      1.2    bouyer 			}
      1.1  fredette 		}
      1.1  fredette
      1.2    bouyer 		/*
      1.2    bouyer 		 * Find lowest empty slot in ring buffer.
      1.2    bouyer 		 * XXX: What about "fairness" and cmd order?
      1.2    bouyer 		 */
      1.2    bouyer 		for (i = 0; i < SUNSCPAL_OPENINGS; i++)
      1.2    bouyer 			if (sc->sc_ring[i].sr_xs == NULL)
      1.2    bouyer 				goto new;
      1.1  fredette
      1.2    bouyer 		xs->error = XS_RESOURCE_SHORTAGE;
      1.2    bouyer 		SUNSCPAL_TRACE("scsipi_cmd: no openings, rv=%d\n", rv);
      1.2    bouyer 		goto out;
      1.1  fredette
1.21.48.2       mjf  new:
      1.2    bouyer 		/* Create queue entry */
      1.2    bouyer 		sr = &sc->sc_ring[i];
      1.2    bouyer 		sr->sr_xs = xs;
      1.2    bouyer 		sr->sr_target = xs->xs_periph->periph_target;
      1.2    bouyer 		sr->sr_lun = xs->xs_periph->periph_lun;
      1.2    bouyer 		sr->sr_dma_hand = NULL;
      1.2    bouyer 		sr->sr_dataptr = xs->data;
      1.2    bouyer 		sr->sr_datalen = xs->datalen;
      1.2    bouyer 		sr->sr_flags = (flags & XS_CTL_POLL) ? SR_IMMED : 0;
      1.2    bouyer 		sr->sr_status = -1;	/* no value */
      1.2    bouyer 		sc->sc_ncmds++;
      1.2    bouyer
      1.2    bouyer 		SUNSCPAL_TRACE("scsipi_cmd: new sr=0x%x\n", (long)sr);
      1.2    bouyer
      1.2    bouyer 		if (flags & XS_CTL_POLL) {
      1.2    bouyer 			/* Force this new command to be next. */
      1.2    bouyer 			sc->sc_rr = i;
      1.2    bouyer 		}
      1.1  fredette
      1.2    bouyer 		/*
      1.2    bouyer 		 * If we were idle, run some commands...
      1.2    bouyer 		 */
      1.2    bouyer 		if (sc->sc_state == SUNSCPAL_IDLE) {
      1.2    bouyer 			SUNSCPAL_TRACE("scsipi_cmd: call sched, cur=0x%x\n",
1.21.48.2       mjf 			    (long)sc->sc_current);
      1.2    bouyer 			sunscpal_sched(sc);
      1.2    bouyer 			SUNSCPAL_TRACE("scsipi_cmd: sched done, cur=0x%x\n",
1.21.48.2       mjf 			    (long)sc->sc_current);
      1.2    bouyer 		}
      1.1  fredette
      1.2    bouyer 		if (flags & XS_CTL_POLL) {
      1.2    bouyer 			/* Make sure sunscpal_sched() finished it. */
      1.2    bouyer 			if ((xs->xs_status & XS_STS_DONE) == 0)
1.21.48.2       mjf 				panic("%s: poll didn't finish", __func__);
      1.2    bouyer 		}
      1.1  fredette
1.21.48.2       mjf  out:
      1.2    bouyer 		splx(s);
      1.2    bouyer 		return;
      1.7  fredette
      1.2    bouyer 	case ADAPTER_REQ_GROW_RESOURCES:
      1.7  fredette 		/* XXX Not supported. */
      1.7  fredette 		return;
      1.7  fredette
      1.2    bouyer 	case ADAPTER_REQ_SET_XFER_MODE:
      1.7  fredette 	    {
      1.7  fredette 		/*
      1.7  fredette 		 * We don't support Sync, Wide, or Tagged Queueing.
      1.7  fredette 		 * Just callback now, to report this.
      1.7  fredette 		 */
      1.7  fredette 		struct scsipi_xfer_mode *xm = arg;
      1.7  fredette
      1.7  fredette 		xm->xm_mode = 0;
      1.7  fredette 		xm->xm_period = 0;
      1.7  fredette 		xm->xm_offset = 0;
      1.7  fredette 		scsipi_async_event(chan, ASYNC_EVENT_XFER_MODE, xm);
      1.2    bouyer 		return;
      1.7  fredette 	    }
      1.2    bouyer 	}
      1.1  fredette }
      1.1  fredette
      1.1  fredette
      1.1  fredette /*
      1.1  fredette  * POST PROCESSING OF SCSI_CMD (usually current)
      1.1  fredette  * Called by sunscpal_sched(), sunscpal_machine()
      1.1  fredette  */
      1.1  fredette static void
1.21.48.2       mjf sunscpal_done(struct sunscpal_softc *sc)
      1.1  fredette {
      1.1  fredette 	struct	sunscpal_req *sr;
      1.1  fredette 	struct	scsipi_xfer *xs;
      1.1  fredette
      1.1  fredette #ifdef	DIAGNOSTIC
      1.1  fredette 	if (sc->sc_state == SUNSCPAL_IDLE)
1.21.48.2       mjf 		panic("%s: state=idle", __func__);
      1.1  fredette 	if (sc->sc_current == NULL)
1.21.48.2       mjf 		panic("%s: current=0", __func__);
      1.1  fredette #endif
      1.1  fredette
      1.1  fredette 	sr = sc->sc_current;
      1.1  fredette 	xs = sr->sr_xs;
      1.1  fredette
1.21.48.2       mjf 	SUNSCPAL_TRACE("done: top, cur=0x%x\n", (long)sc->sc_current);
      1.1  fredette
      1.1  fredette 	/*
      1.1  fredette 	 * Clean up DMA resources for this command.
      1.1  fredette 	 */
      1.1  fredette 	if (sr->sr_dma_hand) {
      1.1  fredette 		SUNSCPAL_TRACE("done: dma_free, dh=0x%x\n",
1.21.48.2       mjf 		    (long)sr->sr_dma_hand);
      1.1  fredette 		sunscpal_dma_free(sc);
      1.1  fredette 	}
      1.1  fredette #ifdef	DIAGNOSTIC
      1.1  fredette 	if (sr->sr_dma_hand)
1.21.48.2       mjf 		panic("%s: DMA free did not", __func__);
      1.1  fredette #endif
      1.1  fredette
      1.1  fredette 	if (sc->sc_state & SUNSCPAL_ABORTING) {
      1.1  fredette 		SUNSCPAL_TRACE("done: aborting, error=%d\n", xs->error);
      1.1  fredette 		if (xs->error == XS_NOERROR)
      1.1  fredette 			xs->error = XS_TIMEOUT;
      1.1  fredette 	}
      1.1  fredette
1.21.48.2       mjf 	SUNSCPAL_TRACE("done: check error=%d\n", (long)xs->error);
      1.1  fredette
      1.1  fredette 	/* If error is already set, ignore sr_status value. */
      1.1  fredette 	if (xs->error != XS_NOERROR)
      1.1  fredette 		goto finish;
      1.1  fredette
      1.1  fredette 	SUNSCPAL_TRACE("done: check status=%d\n", sr->sr_status);
      1.1  fredette
      1.2    bouyer 	xs->status = sr->sr_status;
      1.1  fredette 	switch (sr->sr_status) {
      1.1  fredette 	case SCSI_OK:	/* 0 */
      1.1  fredette 		break;
      1.1  fredette
      1.1  fredette 	case SCSI_CHECK:
      1.1  fredette 	case SCSI_BUSY:
      1.1  fredette 		xs->error = XS_BUSY;
      1.1  fredette 		break;
      1.1  fredette
      1.1  fredette 	case -1:
      1.1  fredette 		/* This is our "impossible" initial value. */
      1.1  fredette 		/* fallthrough */
      1.1  fredette 	default:
      1.1  fredette 		printf("%s: target %d, bad status=%d\n",
1.21.48.2       mjf 		    device_xname(sc->sc_dev), sr->sr_target, sr->sr_status);
      1.1  fredette 		xs->error = XS_DRIVER_STUFFUP;
      1.1  fredette 		break;
      1.1  fredette 	}
      1.1  fredette
1.21.48.2       mjf  finish:
      1.1  fredette
      1.1  fredette 	SUNSCPAL_TRACE("done: finish, error=%d\n", xs->error);
      1.1  fredette
      1.1  fredette 	/*
      1.1  fredette 	 * Dequeue the finished command, but don't clear sc_state until
      1.1  fredette 	 * after the call to scsipi_done(), because that may call back to
      1.1  fredette 	 * sunscpal_scsi_cmd() - unwanted recursion!
      1.1  fredette 	 *
      1.1  fredette 	 * Keeping sc->sc_state != idle terminates the recursion.
      1.1  fredette 	 */
      1.1  fredette #ifdef	DIAGNOSTIC
      1.1  fredette 	if ((sc->sc_state & SUNSCPAL_WORKING) == 0)
1.21.48.2       mjf 		panic("%s: bad state", __func__);
      1.1  fredette #endif
      1.1  fredette
      1.1  fredette 	/* Clear our pointers to the request. */
      1.1  fredette 	sc->sc_current = NULL;
      1.1  fredette 	sc->sc_matrix[sr->sr_target][sr->sr_lun] = NULL;
      1.1  fredette 	callout_stop(&sr->sr_xs->xs_callout);
      1.1  fredette
      1.1  fredette 	/* Make the request free. */
      1.1  fredette 	sr->sr_xs = NULL;
      1.1  fredette 	sc->sc_ncmds--;
      1.1  fredette
      1.1  fredette 	/* Tell common SCSI code it is done. */
      1.1  fredette 	scsipi_done(xs);
      1.1  fredette
      1.1  fredette 	sc->sc_state = SUNSCPAL_IDLE;
      1.1  fredette 	/* Now sunscpal_sched() may be called again. */
      1.1  fredette }
      1.1  fredette
      1.1  fredette
      1.1  fredette /*
      1.1  fredette  * Schedule a SCSI operation.  This routine should return
      1.1  fredette  * only after it achieves one of the following conditions:
      1.1  fredette  *  	Busy (sc->sc_state != SUNSCPAL_IDLE)
      1.1  fredette  *  	No more work can be started.
      1.1  fredette  */
      1.1  fredette static void
1.21.48.2       mjf sunscpal_sched(struct sunscpal_softc *sc)
      1.1  fredette {
      1.1  fredette 	struct sunscpal_req	*sr;
      1.1  fredette 	struct scsipi_xfer *xs;
      1.1  fredette 	int	target = 0, lun = 0;
      1.1  fredette 	int	error, i;
      1.1  fredette
      1.1  fredette 	/* Another hack (Er.. hook!) for anything that needs it: */
      1.1  fredette 	if (sc->sc_intr_off) {
      1.1  fredette 		SUNSCPAL_TRACE("sched: top, intr off\n", 0);
1.21.48.2       mjf 		sc->sc_intr_off(sc);
      1.1  fredette 	}
      1.1  fredette
1.21.48.2       mjf  next_job:
      1.1  fredette 	/*
      1.1  fredette 	 * Grab the next job from queue.  Must be idle.
      1.1  fredette 	 */
      1.1  fredette #ifdef	DIAGNOSTIC
      1.1  fredette 	if (sc->sc_state != SUNSCPAL_IDLE)
1.21.48.2       mjf 		panic("%s: not idle", __func__);
      1.1  fredette 	if (sc->sc_current)
1.21.48.2       mjf 		panic("%s: current set", __func__);
      1.1  fredette #endif
      1.1  fredette
      1.1  fredette 	/*
      1.1  fredette 	 * Always start the search where we last looked.
      1.1  fredette 	 */
      1.1  fredette 	i = sc->sc_rr;
      1.1  fredette 	sr = NULL;
      1.1  fredette 	do {
      1.1  fredette 		if (sc->sc_ring[i].sr_xs) {
      1.1  fredette 			target = sc->sc_ring[i].sr_target;
      1.1  fredette 			lun = sc->sc_ring[i].sr_lun;
      1.1  fredette 			if (sc->sc_matrix[target][lun] == NULL) {
      1.1  fredette 				/*
      1.1  fredette 				 * Do not mark the  target/LUN busy yet,
      1.1  fredette 				 * because reselect may cause some other
      1.1  fredette 				 * job to become the current one, so we
      1.1  fredette 				 * might not actually start this job.
      1.1  fredette 				 * Instead, set sc_matrix later on.
      1.1  fredette 				 */
      1.1  fredette 				sc->sc_rr = i;
      1.1  fredette 				sr = &sc->sc_ring[i];
      1.1  fredette 				break;
      1.1  fredette 			}
      1.1  fredette 		}
      1.1  fredette 		i++;
      1.1  fredette 		if (i == SUNSCPAL_OPENINGS)
      1.1  fredette 			i = 0;
      1.1  fredette 	} while (i != sc->sc_rr);
      1.1  fredette
      1.1  fredette 	if (sr == NULL) {
      1.1  fredette 		SUNSCPAL_TRACE("sched: no work, cur=0x%x\n",
1.21.48.2       mjf 		    (long)sc->sc_current);
      1.1  fredette
      1.1  fredette 		/* Another hack (Er.. hook!) for anything that needs it: */
      1.1  fredette 		if (sc->sc_intr_on) {
      1.1  fredette 			SUNSCPAL_TRACE("sched: ret, intr ON\n", 0);
1.21.48.2       mjf 			sc->sc_intr_on(sc);
      1.1  fredette 		}
      1.1  fredette
      1.1  fredette 		return;		/* No more work to do. */
      1.1  fredette 	}
      1.1  fredette
      1.1  fredette 	SUNSCPAL_TRACE("sched: select for t/l=0x%02x\n",
1.21.48.2       mjf 	    (sr->sr_target << 4) | sr->sr_lun);
      1.1  fredette
      1.1  fredette 	sc->sc_state = SUNSCPAL_WORKING;
      1.1  fredette 	error = sunscpal_select(sc, sr);
      1.1  fredette 	if (sc->sc_current) {
      1.1  fredette 		/* Lost the race!  reselected out from under us! */
      1.1  fredette 		/* Work with the reselected job. */
      1.1  fredette 		if (sr->sr_flags & SR_IMMED) {
      1.1  fredette 			printf("%s: reselected while polling (abort)\n",
1.21.48.2       mjf 			    device_xname(sc->sc_dev));
      1.1  fredette 			/* Abort the reselected job. */
      1.1  fredette 			sc->sc_state |= SUNSCPAL_ABORTING;
      1.1  fredette 			sc->sc_msgpriq |= SEND_ABORT;
      1.1  fredette 		}
      1.1  fredette 		sr = sc->sc_current;
      1.1  fredette 		xs = sr->sr_xs;
      1.1  fredette 		SUNSCPAL_TRACE("sched: reselect, new sr=0x%x\n", (long)sr);
      1.1  fredette 		goto have_nexus;
      1.1  fredette 	}
      1.1  fredette
      1.1  fredette 	/* Normal selection result.  Target/LUN is now busy. */
      1.1  fredette 	sc->sc_matrix[target][lun] = sr;
      1.1  fredette 	sc->sc_current = sr;	/* connected */
      1.1  fredette 	xs = sr->sr_xs;
      1.1  fredette
      1.1  fredette 	/*
      1.1  fredette 	 * Initialize pointers, etc. for this job
      1.1  fredette 	 */
      1.1  fredette 	sc->sc_dataptr  = sr->sr_dataptr;
      1.1  fredette 	sc->sc_datalen  = sr->sr_datalen;
      1.1  fredette 	sc->sc_prevphase = SUNSCPAL_PHASE_INVALID;
      1.1  fredette 	sc->sc_msgpriq = SEND_IDENTIFY;
      1.1  fredette 	sc->sc_msgoutq = 0;
      1.1  fredette 	sc->sc_msgout  = 0;
      1.1  fredette
      1.1  fredette 	SUNSCPAL_TRACE("sched: select rv=%d\n", error);
      1.1  fredette
      1.1  fredette 	switch (error) {
      1.1  fredette 	case XS_NOERROR:
      1.1  fredette 		break;
      1.1  fredette
      1.1  fredette 	case XS_BUSY:
      1.1  fredette 		/* XXX - Reset and try again. */
      1.1  fredette 		printf("%s: select found SCSI bus busy, resetting...\n",
1.21.48.2       mjf 		    device_xname(sc->sc_dev));
      1.1  fredette 		sunscpal_reset_scsibus(sc);
      1.1  fredette 		/* fallthrough */
      1.1  fredette 	case XS_SELTIMEOUT:
      1.1  fredette 	default:
      1.1  fredette 		xs->error = error;	/* from select */
      1.1  fredette 		SUNSCPAL_TRACE("sched: call done, sr=0x%x\n", (long)sr);
      1.1  fredette 		sunscpal_done(sc);
      1.1  fredette
      1.1  fredette 		/* Paranoia: clear everything. */
      1.1  fredette 		sc->sc_dataptr = NULL;
      1.1  fredette 		sc->sc_datalen = 0;
      1.1  fredette 		sc->sc_prevphase = SUNSCPAL_PHASE_INVALID;
      1.1  fredette 		sc->sc_msgpriq = 0;
      1.1  fredette 		sc->sc_msgoutq = 0;
      1.1  fredette 		sc->sc_msgout  = 0;
      1.1  fredette
      1.1  fredette 		goto next_job;
      1.1  fredette 	}
      1.1  fredette
      1.1  fredette 	/*
      1.1  fredette 	 * Selection was successful.  Normally, this means
      1.1  fredette 	 * we are starting a new command.  However, this
      1.1  fredette 	 * might be the termination of an overdue job.
      1.1  fredette 	 */
      1.1  fredette 	if (sr->sr_flags & SR_OVERDUE) {
      1.1  fredette 		SUNSCPAL_TRACE("sched: overdue, sr=0x%x\n", (long)sr);
      1.1  fredette 		sc->sc_state |= SUNSCPAL_ABORTING;
      1.1  fredette 		sc->sc_msgpriq |= SEND_ABORT;
      1.1  fredette 		goto have_nexus;
      1.1  fredette 	}
      1.1  fredette
      1.1  fredette 	/*
      1.1  fredette 	 * OK, we are starting a new command.
      1.1  fredette 	 * Initialize and allocate resources for the new command.
      1.1  fredette 	 * Device reset is special (only uses MSG_OUT phase).
      1.1  fredette 	 * Normal commands start in MSG_OUT phase where we will
      1.1  fredette 	 * send and IDENDIFY message, and then expect CMD phase.
      1.1  fredette 	 */
      1.1  fredette #ifdef	SUNSCPAL_DEBUG
      1.1  fredette 	if (sunscpal_debug & SUNSCPAL_DBG_CMDS) {
1.21.48.2       mjf 		printf("%s: begin, target=%d, LUN=%d\n", __func__,
      1.2    bouyer 		    xs->xs_periph->periph_target, xs->xs_periph->periph_lun);
      1.1  fredette 		sunscpal_show_scsi_cmd(xs);
      1.1  fredette 	}
      1.1  fredette #endif
      1.1  fredette 	if (xs->xs_control & XS_CTL_RESET) {
      1.1  fredette 		SUNSCPAL_TRACE("sched: cmd=reset, sr=0x%x\n", (long)sr);
      1.1  fredette 		/* Not an error, so do not set SUNSCPAL_ABORTING */
      1.1  fredette 		sc->sc_msgpriq |= SEND_DEV_RESET;
      1.1  fredette 		goto have_nexus;
      1.1  fredette 	}
      1.1  fredette
      1.1  fredette #ifdef	DIAGNOSTIC
      1.1  fredette 	if ((xs->xs_control & (XS_CTL_DATA_IN | XS_CTL_DATA_OUT)) == 0) {
      1.1  fredette 		if (sc->sc_dataptr) {
      1.1  fredette 			printf("%s: ptr but no data in/out flags?\n",
1.21.48.2       mjf 			    device_xname(sc->sc_dev));
      1.1  fredette 			SUNSCPAL_BREAK();
      1.1  fredette 			sc->sc_dataptr = NULL;
      1.1  fredette 		}
      1.1  fredette 	}
      1.1  fredette #endif
      1.1  fredette
      1.1  fredette 	/* Allocate DMA space (maybe) */
      1.1  fredette 	if (sc->sc_dataptr && (sc->sc_flags & SUNSCPAL_DISABLE_DMA) == 0 &&
      1.1  fredette 		(sc->sc_datalen >= sc->sc_min_dma_len))
      1.1  fredette 	{
      1.1  fredette 		SUNSCPAL_TRACE("sched: dma_alloc, len=%d\n", sc->sc_datalen);
      1.1  fredette 		sunscpal_dma_alloc(sc);
      1.1  fredette 	}
      1.1  fredette
      1.1  fredette 	/*
      1.1  fredette 	 * Initialization hook called just after select,
      1.1  fredette 	 * at the beginning of COMMAND phase.
      1.1  fredette 	 * (but AFTER the DMA allocation is done)
      1.1  fredette 	 *
      1.1  fredette 	 * We need to set up the DMA engine BEFORE the target puts
      1.1  fredette 	 * the SCSI bus into any DATA phase.
      1.1  fredette 	 */
      1.1  fredette 	if (sr->sr_dma_hand) {
      1.1  fredette 		SUNSCPAL_TRACE("sched: dma_setup, dh=0x%x\n",
1.21.48.2       mjf 		    (long) sr->sr_dma_hand);
      1.1  fredette 	    sunscpal_dma_setup(sc);
      1.1  fredette 	}
      1.1  fredette
      1.1  fredette 	/*
      1.1  fredette 	 * Schedule a timeout for the job we are starting.
      1.1  fredette 	 */
      1.1  fredette 	if ((sr->sr_flags & SR_IMMED) == 0) {
     1.12    bouyer 		i = mstohz(xs->timeout);
      1.1  fredette 		SUNSCPAL_TRACE("sched: set timeout=%d\n", i);
      1.1  fredette 		callout_reset(&sr->sr_xs->xs_callout, i,
      1.1  fredette 		    sunscpal_cmd_timeout, sr);
      1.1  fredette 	}
      1.1  fredette
1.21.48.2       mjf  have_nexus:
      1.1  fredette
      1.1  fredette 	SUNSCPAL_TRACE("sched: call machine, cur=0x%x\n",
1.21.48.2       mjf 	    (long)sc->sc_current);
      1.1  fredette 	sunscpal_machine(sc);
      1.1  fredette 	SUNSCPAL_TRACE("sched: machine done, cur=0x%x\n",
1.21.48.2       mjf 	    (long)sc->sc_current);
      1.1  fredette
      1.1  fredette 	/*
      1.1  fredette 	 * What state did sunscpal_machine() leave us in?
      1.1  fredette 	 * Hopefully it sometimes completes a job...
      1.1  fredette 	 */
      1.1  fredette 	if (sc->sc_state == SUNSCPAL_IDLE)
      1.1  fredette 		goto next_job;
      1.1  fredette
      1.1  fredette 	return; 	/* Have work in progress. */
      1.1  fredette }
      1.1  fredette
      1.1  fredette
      1.1  fredette /*
      1.1  fredette  *  Reselect handler: checks for reselection, and if we are being
      1.1  fredette  *	reselected, it sets up sc->sc_current.
      1.1  fredette  *
      1.1  fredette  *  We are reselected when:
      1.1  fredette  *	SEL is TRUE
      1.1  fredette  *	IO  is TRUE
      1.1  fredette  *	BSY is FALSE
      1.1  fredette  */
      1.1  fredette void
1.21.48.2       mjf sunscpal_reselect(struct sunscpal_softc *sc)
      1.1  fredette {
1.21.48.2       mjf
     1.17     perry 	/*
      1.1  fredette 	 * This controller does not implement disconnect/reselect, so
      1.1  fredette 	 * we really don't have anything to do here.  We keep this
      1.1  fredette 	 * function as a placeholder, though.
      1.1  fredette 	 */
      1.1  fredette }
      1.1  fredette
      1.1  fredette /*
      1.1  fredette  *  Select target: xs is the transfer that we are selecting for.
      1.1  fredette  *  sc->sc_current should be NULL.
      1.1  fredette  *
      1.1  fredette  *  Returns:
      1.1  fredette  *	sc->sc_current != NULL  ==> we were reselected (race!)
      1.1  fredette  *	XS_NOERROR		==> selection worked
      1.1  fredette  *	XS_BUSY 		==> lost arbitration
      1.1  fredette  *	XS_SELTIMEOUT   	==> no response to selection
      1.1  fredette  */
      1.1  fredette static int
1.21.48.2       mjf sunscpal_select(struct sunscpal_softc *sc, struct sunscpal_req *sr)
      1.1  fredette {
      1.1  fredette 	int timo, target_mask;
      1.1  fredette 	u_short	mode;
      1.1  fredette
      1.1  fredette 	/* Check for reselect */
      1.1  fredette 	sunscpal_reselect(sc);
      1.1  fredette 	if (sc->sc_current) {
      1.1  fredette 		SUNSCPAL_TRACE("select: reselect, cur=0x%x\n",
1.21.48.2       mjf 		    (long)sc->sc_current);
      1.1  fredette 		return XS_BUSY;	/* reselected */
      1.1  fredette 	}
      1.1  fredette
      1.1  fredette 	/*
      1.1  fredette 	 * Select the target.
      1.1  fredette 	 */
      1.1  fredette 	target_mask = (1 << sr->sr_target);
      1.1  fredette 	SUNSCPAL_WRITE_1(sc, sunscpal_data, target_mask);
      1.1  fredette 	SUNSCPAL_WRITE_2(sc, sunscpal_icr, SUNSCPAL_ICR_SELECT);
      1.1  fredette
      1.1  fredette 	/*
      1.1  fredette 	 * Wait for the target to assert BSY.
      1.1  fredette 	 * SCSI spec. says wait for 250 mS.
      1.1  fredette 	 */
      1.1  fredette 	for (timo = 25000;;) {
      1.1  fredette 		if (SUNSCPAL_READ_2(sc, sunscpal_icr) & SUNSCPAL_ICR_BUSY)
      1.1  fredette 			goto success;
      1.1  fredette 		if (--timo <= 0)
      1.1  fredette 			break;
      1.1  fredette 		delay(10);
      1.1  fredette 	}
      1.1  fredette
      1.1  fredette 	SUNSCPAL_WRITE_1(sc, sunscpal_data, 0);
      1.1  fredette 	SUNSCPAL_WRITE_2(sc, sunscpal_icr, 0);
      1.1  fredette
      1.1  fredette 	SUNSCPAL_TRACE("select: device down, rc=%d\n", XS_SELTIMEOUT);
      1.1  fredette 	return XS_SELTIMEOUT;
      1.1  fredette
1.21.48.2       mjf  success:
      1.1  fredette
      1.1  fredette 	/*
      1.1  fredette 	 * The target is now driving BSY, so we can stop
      1.1  fredette 	 * driving SEL and the data bus.  We do set up
      1.1  fredette 	 * whether or not this target needs parity.
      1.1  fredette 	 */
      1.1  fredette 	mode = 0;
      1.1  fredette 	if ((sc->sc_parity_disable & target_mask) == 0)
      1.1  fredette 		mode |= SUNSCPAL_ICR_PARITY_ENABLE;
      1.1  fredette 	SUNSCPAL_WRITE_2(sc, sunscpal_icr, mode);
      1.1  fredette
      1.1  fredette 	return XS_NOERROR;
      1.1  fredette }
      1.1  fredette
      1.1  fredette /*****************************************************************
      1.1  fredette  * Functions to handle each info. transfer phase:
      1.1  fredette  *****************************************************************/
      1.1  fredette
      1.1  fredette /*
      1.1  fredette  * The message system:
      1.1  fredette  *
     1.21  christos  * This is a revamped message system that now should easier accommodate
      1.1  fredette  * new messages, if necessary.
      1.1  fredette  *
      1.1  fredette  * Currently we accept these messages:
      1.1  fredette  * IDENTIFY (when reselecting)
      1.1  fredette  * COMMAND COMPLETE # (expect bus free after messages marked #)
      1.1  fredette  * NOOP
      1.1  fredette  * MESSAGE REJECT
      1.1  fredette  * SYNCHRONOUS DATA TRANSFER REQUEST
      1.1  fredette  * SAVE DATA POINTER
      1.1  fredette  * RESTORE POINTERS
      1.1  fredette  * DISCONNECT #
      1.1  fredette  *
      1.1  fredette  * We may send these messages in prioritized order:
      1.1  fredette  * BUS DEVICE RESET #		if XS_CTL_RESET & xs->xs_control (or in
      1.1  fredette  *				weird sits.)
      1.1  fredette  * MESSAGE PARITY ERROR		par. err. during MSGI
      1.1  fredette  * MESSAGE REJECT		If we get a message we don't know how to handle
      1.1  fredette  * ABORT #			send on errors
      1.1  fredette  * INITIATOR DETECTED ERROR	also on errors (SCSI2) (during info xfer)
      1.1  fredette  * IDENTIFY			At the start of each transfer
      1.1  fredette  * SYNCHRONOUS DATA TRANSFER REQUEST	if appropriate
      1.1  fredette  * NOOP				if nothing else fits the bill ...
      1.1  fredette  */
      1.1  fredette
      1.1  fredette /*
      1.1  fredette  * Precondition:
      1.1  fredette  * The SCSI bus is already in the MSGI phase and there is a message byte
      1.1  fredette  * on the bus, along with an asserted REQ signal.
      1.1  fredette  *
      1.1  fredette  * Our return value determines whether our caller, sunscpal_machine()
      1.1  fredette  * will expect to see another REQ (and possibly phase change).
      1.1  fredette  */
      1.1  fredette static int
1.21.48.2       mjf sunscpal_msg_in(struct sunscpal_softc *sc)
      1.1  fredette {
      1.1  fredette 	struct sunscpal_req *sr = sc->sc_current;
      1.1  fredette 	struct scsipi_xfer *xs = sr->sr_xs;
      1.1  fredette 	int n, phase;
      1.1  fredette 	int act_flags;
      1.1  fredette
      1.1  fredette 	act_flags = ACT_CONTINUE;
      1.1  fredette
      1.1  fredette 	if (sc->sc_prevphase == SUNSCPAL_PHASE_MSG_IN) {
      1.1  fredette 		/* This is a continuation of the previous message. */
      1.1  fredette 		n = sc->sc_imp - sc->sc_imess;
      1.1  fredette 		SUNSCPAL_TRACE("msg_in: continuation, n=%d\n", n);
      1.1  fredette 		goto nextbyte;
      1.1  fredette 	}
      1.1  fredette
      1.1  fredette 	/* This is a new MESSAGE IN phase.  Clean up our state. */
      1.1  fredette 	sc->sc_state &= ~SUNSCPAL_DROP_MSGIN;
      1.1  fredette
1.21.48.2       mjf  nextmsg:
      1.1  fredette 	n = 0;
      1.1  fredette 	sc->sc_imp = &sc->sc_imess[n];
      1.1  fredette
1.21.48.2       mjf  nextbyte:
      1.1  fredette 	/*
      1.1  fredette 	 * Read a whole message, but don't ack the last byte.  If we reject the
      1.1  fredette 	 * message, we have to assert ATN during the message transfer phase
      1.1  fredette 	 * itself.
      1.1  fredette 	 */
      1.1  fredette 	for (;;) {
      1.1  fredette 		/*
      1.1  fredette 		 * Read a message byte.
      1.1  fredette 		 * First, check BSY, REQ, phase...
      1.1  fredette 		 */
      1.1  fredette 		if (!SUNSCPAL_BUSY(sc)) {
      1.1  fredette 			SUNSCPAL_TRACE("msg_in: lost BSY, n=%d\n", n);
      1.1  fredette 			/* XXX - Assume the command completed? */
      1.1  fredette 			act_flags |= (ACT_DISCONNECT | ACT_CMD_DONE);
1.21.48.2       mjf 			return act_flags;
      1.1  fredette 		}
      1.1  fredette 		if (sunscpal_wait_req(sc)) {
      1.1  fredette 			SUNSCPAL_TRACE("msg_in: BSY but no REQ, n=%d\n", n);
      1.1  fredette 			/* Just let sunscpal_machine() handle it... */
1.21.48.2       mjf 			return act_flags;
      1.1  fredette 		}
      1.1  fredette 		phase = SUNSCPAL_BUS_PHASE(SUNSCPAL_READ_2(sc, sunscpal_icr));
      1.1  fredette 		if (phase != SUNSCPAL_PHASE_MSG_IN) {
      1.1  fredette 			/*
      1.1  fredette 			 * Target left MESSAGE IN, probably because it
      1.1  fredette 			 * a) noticed our ATN signal, or
      1.1  fredette 			 * b) ran out of messages.
      1.1  fredette 			 */
1.21.48.2       mjf 			return act_flags;
      1.1  fredette 		}
      1.1  fredette 		/* Still in MESSAGE IN phase, and REQ is asserted. */
1.21.48.2       mjf 		if ((SUNSCPAL_READ_2(sc, sunscpal_icr) &
1.21.48.2       mjf 		    SUNSCPAL_ICR_PARITY_ERROR) != 0) {
      1.1  fredette 			sunscpal_sched_msgout(sc, SEND_PARITY_ERROR);
      1.1  fredette 			sc->sc_state |= SUNSCPAL_DROP_MSGIN;
      1.1  fredette 		}
      1.1  fredette
      1.1  fredette 		/* Gather incoming message bytes if needed. */
      1.1  fredette 		if ((sc->sc_state & SUNSCPAL_DROP_MSGIN) == 0) {
      1.1  fredette 			if (n >= SUNSCPAL_MAX_MSG_LEN) {
      1.1  fredette 				sunscpal_sched_msgout(sc, SEND_REJECT);
      1.1  fredette 				sc->sc_state |= SUNSCPAL_DROP_MSGIN;
      1.1  fredette 			} else {
1.21.48.2       mjf 				*sc->sc_imp++ =
1.21.48.2       mjf 				    SUNSCPAL_READ_1(sc, sunscpal_cmd_stat);
      1.1  fredette 				n++;
      1.1  fredette 				/*
      1.1  fredette 				 * This testing is suboptimal, but most
      1.1  fredette 				 * messages will be of the one byte variety, so
      1.1  fredette 				 * it should not affect performance
      1.1  fredette 				 * significantly.
      1.1  fredette 				 */
      1.8   tsutsui 				if (n == 1 && MSG_IS1BYTE(sc->sc_imess[0]))
      1.1  fredette 					goto have_msg;
      1.8   tsutsui 				if (n == 2 && MSG_IS2BYTE(sc->sc_imess[0]))
      1.1  fredette 					goto have_msg;
      1.8   tsutsui 				if (n >= 3 && MSG_ISEXTENDED(sc->sc_imess[0]) &&
      1.1  fredette 					n == sc->sc_imess[1] + 2)
      1.1  fredette 					goto have_msg;
      1.1  fredette 			}
      1.1  fredette 		}
      1.1  fredette
      1.1  fredette 		/*
      1.1  fredette 		 * If we reach this spot we're either:
      1.1  fredette 		 * a) in the middle of a multi-byte message, or
      1.1  fredette 		 * b) dropping bytes.
      1.1  fredette 		 */
      1.1  fredette
      1.1  fredette 		if (act_flags != ACT_CONTINUE)
1.21.48.2       mjf 			return act_flags;
      1.1  fredette
      1.1  fredette 		/* back to nextbyte */
      1.1  fredette 	}
      1.1  fredette
1.21.48.2       mjf  have_msg:
      1.1  fredette 	/* We now have a complete message.  Parse it. */
      1.1  fredette
      1.1  fredette 	switch (sc->sc_imess[0]) {
      1.1  fredette 	case MSG_CMDCOMPLETE:
      1.1  fredette 		SUNSCPAL_TRACE("msg_in: CMDCOMPLETE\n", 0);
      1.1  fredette 		/* Target is about to disconnect. */
      1.1  fredette 		act_flags |= (ACT_DISCONNECT | ACT_CMD_DONE);
      1.1  fredette 		break;
      1.1  fredette
      1.1  fredette 	case MSG_PARITY_ERROR:
      1.1  fredette 		SUNSCPAL_TRACE("msg_in: PARITY_ERROR\n", 0);
      1.1  fredette 		/* Resend the last message. */
      1.1  fredette 		sunscpal_sched_msgout(sc, sc->sc_msgout);
      1.1  fredette 		break;
      1.1  fredette
      1.1  fredette 	case MSG_MESSAGE_REJECT:
      1.1  fredette 		/* The target rejects the last message we sent. */
      1.1  fredette 		SUNSCPAL_TRACE("msg_in: got reject for 0x%x\n", sc->sc_msgout);
      1.1  fredette 		switch (sc->sc_msgout) {
      1.1  fredette 		case SEND_IDENTIFY:
      1.1  fredette 			/* Really old target controller? */
      1.1  fredette 			/* XXX ... */
      1.1  fredette 			break;
      1.1  fredette 		case SEND_INIT_DET_ERR:
      1.1  fredette 			goto abort;
      1.1  fredette 		}
      1.1  fredette 		break;
      1.1  fredette
      1.1  fredette 	case MSG_NOOP:
      1.1  fredette 		SUNSCPAL_TRACE("msg_in: NOOP\n", 0);
      1.1  fredette 		break;
      1.1  fredette
      1.1  fredette 	case MSG_DISCONNECT:
      1.1  fredette 		SUNSCPAL_TRACE("msg_in: DISCONNECT\n", 0);
      1.1  fredette 		/* Target is about to disconnect. */
      1.1  fredette 		act_flags |= ACT_DISCONNECT;
      1.2    bouyer 		if ((xs->xs_periph->periph_quirks & PQUIRK_AUTOSAVE) == 0)
      1.1  fredette 			break;
      1.1  fredette 		/*FALLTHROUGH*/
      1.1  fredette
      1.1  fredette 	case MSG_SAVEDATAPOINTER:
      1.1  fredette 		SUNSCPAL_TRACE("msg_in: SAVE_PTRS\n", 0);
      1.1  fredette 		sr->sr_dataptr = sc->sc_dataptr;
      1.1  fredette 		sr->sr_datalen = sc->sc_datalen;
      1.1  fredette 		break;
      1.1  fredette
      1.1  fredette 	case MSG_RESTOREPOINTERS:
      1.1  fredette 		SUNSCPAL_TRACE("msg_in: RESTORE_PTRS\n", 0);
      1.1  fredette 		sc->sc_dataptr = sr->sr_dataptr;
      1.1  fredette 		sc->sc_datalen = sr->sr_datalen;
      1.1  fredette 		break;
      1.1  fredette
      1.1  fredette 	case MSG_EXTENDED:
      1.1  fredette 		switch (sc->sc_imess[2]) {
      1.1  fredette 		case MSG_EXT_SDTR:
      1.1  fredette 		case MSG_EXT_WDTR:
1.21.48.2       mjf 			/* This controller can not do synchronous mode. */
      1.1  fredette 			goto reject;
      1.1  fredette 		default:
1.21.48.2       mjf 			printf("%s: unrecognized MESSAGE EXTENDED; "
1.21.48.2       mjf 			    "sending REJECT\n",
1.21.48.2       mjf 			    device_xname(sc->sc_dev));
      1.1  fredette 			SUNSCPAL_BREAK();
      1.1  fredette 			goto reject;
      1.1  fredette 		}
      1.1  fredette 		break;
      1.1  fredette
      1.1  fredette 	default:
      1.1  fredette 		SUNSCPAL_TRACE("msg_in: eh? imsg=0x%x\n", sc->sc_imess[0]);
      1.1  fredette 		printf("%s: unrecognized MESSAGE; sending REJECT\n",
1.21.48.2       mjf 		    device_xname(sc->sc_dev));
      1.1  fredette 		SUNSCPAL_BREAK();
1.21.48.2       mjf 		/* FALLTHROUGH */
      1.1  fredette 	reject:
      1.1  fredette 		sunscpal_sched_msgout(sc, SEND_REJECT);
      1.1  fredette 		break;
      1.1  fredette
      1.1  fredette 	abort:
      1.1  fredette 		sc->sc_state |= SUNSCPAL_ABORTING;
      1.1  fredette 		sunscpal_sched_msgout(sc, SEND_ABORT);
      1.1  fredette 		break;
      1.1  fredette 	}
      1.1  fredette
      1.1  fredette 	/* Go get the next message, if any. */
      1.1  fredette 	if (act_flags == ACT_CONTINUE)
      1.1  fredette 		goto nextmsg;
      1.1  fredette
1.21.48.2       mjf 	return act_flags;
      1.1  fredette }
      1.1  fredette
      1.1  fredette
      1.1  fredette /*
      1.1  fredette  * The message out (and in) stuff is a bit complicated:
      1.1  fredette  * If the target requests another message (sequence) without
      1.1  fredette  * having changed phase in between it really asks for a
      1.1  fredette  * retransmit, probably due to parity error(s).
      1.1  fredette  * The following messages can be sent:
      1.1  fredette  * IDENTIFY	   @ These 4 stem from SCSI command activity
      1.1  fredette  * SDTR		   @
      1.1  fredette  * WDTR		   @
      1.1  fredette  * DEV_RESET	   @
      1.1  fredette  * REJECT if MSGI doesn't make sense
      1.1  fredette  * PARITY_ERROR if parity error while in MSGI
      1.1  fredette  * INIT_DET_ERR if parity error while not in MSGI
      1.1  fredette  * ABORT if INIT_DET_ERR rejected
      1.1  fredette  * NOOP if asked for a message and there's nothing to send
      1.1  fredette  *
      1.1  fredette  * Note that we call this one with (sc_current == NULL)
      1.1  fredette  * when sending ABORT for unwanted reselections.
      1.1  fredette  */
      1.1  fredette static int
1.21.48.2       mjf sunscpal_msg_out(struct sunscpal_softc *sc)
      1.1  fredette {
     1.17     perry 	/*
      1.1  fredette 	 * This controller does not allow you to assert ATN, which
      1.1  fredette 	 * means we will never get the opportunity to send messages to
      1.1  fredette 	 * the target (the bus will never enter this MSG_OUT phase).
      1.1  fredette 	 * This will eventually leave us with no option other than to
      1.1  fredette 	 * reset the bus.  We keep this function as a placeholder,
      1.1  fredette 	 * though, and this printf will eventually go away or get
      1.1  fredette 	 * #ifdef'ed:
      1.1  fredette 	 */
1.21.48.2       mjf 	printf("%s: bus is in MSG_OUT phase?\n", __func__);
1.21.48.2       mjf 	return ACT_CONTINUE | ACT_RESET_BUS;
      1.1  fredette }
      1.1  fredette
      1.1  fredette /*
      1.1  fredette  * Handle command phase.
      1.1  fredette  */
      1.1  fredette static int
1.21.48.2       mjf sunscpal_command(struct sunscpal_softc *sc)
      1.1  fredette {
      1.1  fredette 	struct sunscpal_req *sr = sc->sc_current;
      1.1  fredette 	struct scsipi_xfer *xs = sr->sr_xs;
      1.1  fredette 	int len;
      1.1  fredette
      1.2    bouyer 	/* Assume command can be sent in one go. */
      1.2    bouyer 	/* XXX: Do this using DMA, and get a phase change intr? */
      1.2    bouyer 	len = sunscpal_pio_out(sc, SUNSCPAL_PHASE_COMMAND, xs->cmdlen,
1.21.48.2       mjf 	    (uint8_t *)xs->cmd);
      1.1  fredette
      1.1  fredette 	if (len != xs->cmdlen) {
      1.1  fredette #ifdef	SUNSCPAL_DEBUG
1.21.48.2       mjf 		printf("%s: short transfer: wanted %d got %d.\n",
1.21.48.2       mjf 		    __func__, xs->cmdlen, len);
      1.1  fredette 		sunscpal_show_scsi_cmd(xs);
      1.1  fredette 		SUNSCPAL_BREAK();
      1.1  fredette #endif
      1.1  fredette 		if (len < 6) {
      1.1  fredette 			xs->error = XS_DRIVER_STUFFUP;
      1.1  fredette 			sc->sc_state |= SUNSCPAL_ABORTING;
      1.1  fredette 			sunscpal_sched_msgout(sc, SEND_ABORT);
      1.1  fredette 		}
      1.1  fredette
      1.1  fredette 	}
      1.1  fredette
      1.1  fredette 	return ACT_CONTINUE;
      1.1  fredette }
      1.1  fredette
      1.1  fredette
      1.1  fredette /*
      1.1  fredette  * Handle either data_in or data_out
      1.1  fredette  */
      1.1  fredette static int
1.21.48.2       mjf sunscpal_data_xfer(struct sunscpal_softc *sc, int phase)
      1.1  fredette {
      1.1  fredette 	struct sunscpal_req *sr = sc->sc_current;
      1.1  fredette 	struct scsipi_xfer *xs = sr->sr_xs;
      1.1  fredette 	int expected_phase;
      1.1  fredette 	int len;
      1.1  fredette
      1.1  fredette 	/*
      1.1  fredette 	 * When aborting a command, disallow any data phase.
      1.1  fredette 	 */
      1.1  fredette 	if (sc->sc_state & SUNSCPAL_ABORTING) {
1.21.48.2       mjf 		printf("%s: aborting, bus phase=%s (reset)\n",
1.21.48.2       mjf 		    device_xname(sc->sc_dev), phase_names[(phase >> 8) & 7]);
      1.1  fredette 		return ACT_RESET_BUS;	/* XXX */
      1.1  fredette 	}
      1.1  fredette
      1.1  fredette 	/* Validate expected phase (data_in or data_out) */
      1.1  fredette 	expected_phase = (xs->xs_control & XS_CTL_DATA_OUT) ?
1.21.48.2       mjf 	    SUNSCPAL_PHASE_DATA_OUT : SUNSCPAL_PHASE_DATA_IN;
      1.1  fredette 	if (phase != expected_phase) {
1.21.48.2       mjf 		printf("%s: data phase error\n", device_xname(sc->sc_dev));
      1.1  fredette 		goto abort;
      1.1  fredette 	}
      1.1  fredette
      1.1  fredette 	/* Make sure we have some data to move. */
      1.1  fredette 	if (sc->sc_datalen <= 0) {
      1.1  fredette 		/* Device needs padding. */
      1.1  fredette 		if (phase == SUNSCPAL_PHASE_DATA_IN)
      1.1  fredette 			sunscpal_pio_in(sc, phase, 4096, NULL);
      1.1  fredette 		else
      1.1  fredette 			sunscpal_pio_out(sc, phase, 4096, NULL);
      1.1  fredette 		/* Make sure that caused a phase change. */
1.21.48.2       mjf 		if (SUNSCPAL_BUS_PHASE(SUNSCPAL_READ_2(sc, sunscpal_icr)) ==
1.21.48.2       mjf 		    phase) {
      1.1  fredette 			/* More than 4k is just too much! */
1.21.48.2       mjf 			printf("%s: too much data padding\n",
1.21.48.2       mjf 			    device_xname(sc->sc_dev));
      1.1  fredette 			goto abort;
      1.1  fredette 		}
      1.1  fredette 		return ACT_CONTINUE;
      1.1  fredette 	}
      1.1  fredette
      1.1  fredette 	/*
      1.1  fredette 	 * Attempt DMA only if dma_alloc gave us a DMA handle AND
      1.1  fredette 	 * there is enough left to transfer so DMA is worth while.
      1.1  fredette 	 */
1.21.48.2       mjf 	if (sr->sr_dma_hand && (sc->sc_datalen >= sc->sc_min_dma_len)) {
      1.1  fredette 		/*
      1.1  fredette 		 * OK, really start DMA.  Note, the MD start function
      1.1  fredette 		 * is responsible for setting the TCMD register, etc.
      1.1  fredette 		 * (Acknowledge the phase change there, not here.)
      1.1  fredette 		 */
      1.1  fredette 		SUNSCPAL_TRACE("data_xfer: dma_start, dh=0x%x\n",
1.21.48.2       mjf 		    (long)sr->sr_dma_hand);
      1.1  fredette 		sunscpal_dma_start(sc);
      1.1  fredette 		return ACT_WAIT_DMA;
      1.1  fredette 	}
      1.1  fredette
      1.1  fredette 	/*
      1.1  fredette 	 * Doing PIO for data transfer.  (Possibly "Pseudo DMA")
      1.1  fredette 	 * XXX:  Do PDMA functions need to set tcmd later?
      1.1  fredette 	 */
      1.1  fredette 	SUNSCPAL_TRACE("data_xfer: doing PIO, len=%d\n", sc->sc_datalen);
      1.1  fredette 	if (phase == SUNSCPAL_PHASE_DATA_OUT) {
1.21.48.2       mjf 		len = sunscpal_pio_out(sc, phase,
1.21.48.2       mjf 		    sc->sc_datalen, sc->sc_dataptr);
      1.1  fredette 	} else {
1.21.48.2       mjf 		len = sunscpal_pio_in(sc, phase,
1.21.48.2       mjf 		    sc->sc_datalen, sc->sc_dataptr);
      1.1  fredette 	}
      1.1  fredette 	sc->sc_dataptr += len;
      1.1  fredette 	sc->sc_datalen -= len;
      1.1  fredette
      1.1  fredette 	SUNSCPAL_TRACE("data_xfer: did PIO, resid=%d\n", sc->sc_datalen);
1.21.48.2       mjf 	return ACT_CONTINUE;
      1.1  fredette
1.21.48.2       mjf  abort:
      1.1  fredette 	sc->sc_state |= SUNSCPAL_ABORTING;
      1.1  fredette 	sunscpal_sched_msgout(sc, SEND_ABORT);
1.21.48.2       mjf 	return ACT_CONTINUE;
      1.1  fredette }
      1.1  fredette
      1.1  fredette
      1.1  fredette static int
1.21.48.2       mjf sunscpal_status(struct sunscpal_softc *sc)
      1.1  fredette {
      1.1  fredette 	int len;
1.21.48.2       mjf 	uint8_t status;
      1.1  fredette 	struct sunscpal_req *sr = sc->sc_current;
      1.1  fredette
      1.1  fredette 	len = sunscpal_pio_in(sc, SUNSCPAL_PHASE_STATUS, 1, &status);
      1.1  fredette 	if (len) {
      1.1  fredette 		sr->sr_status = status;
      1.1  fredette 	} else {
1.21.48.2       mjf 		printf("%s: none?\n", __func__);
      1.1  fredette 	}
      1.1  fredette
      1.1  fredette 	return ACT_CONTINUE;
      1.1  fredette }
      1.1  fredette
      1.1  fredette
      1.1  fredette /*
      1.1  fredette  * This is the big state machine that follows SCSI phase changes.
      1.1  fredette  * This is somewhat like a co-routine.  It will do a SCSI command,
      1.1  fredette  * and exit if the command is complete, or if it must wait, i.e.
      1.1  fredette  * for DMA to complete or for reselect to resume the job.
      1.1  fredette  *
      1.1  fredette  * The bus must be selected, and we need to know which command is
      1.1  fredette  * being undertaken.
      1.1  fredette  */
      1.1  fredette static void
1.21.48.2       mjf sunscpal_machine(struct sunscpal_softc *sc)
      1.1  fredette {
      1.1  fredette 	struct sunscpal_req *sr;
      1.1  fredette 	struct scsipi_xfer *xs;
      1.1  fredette 	int act_flags, phase, timo;
      1.1  fredette
      1.1  fredette #ifdef	DIAGNOSTIC
      1.1  fredette 	if (sc->sc_state == SUNSCPAL_IDLE)
1.21.48.2       mjf 		panic("%s: state=idle", __func__);
      1.1  fredette 	if (sc->sc_current == NULL)
1.21.48.2       mjf 		panic("%s: no current cmd", __func__);
      1.1  fredette #endif
      1.1  fredette
      1.1  fredette 	sr = sc->sc_current;
      1.1  fredette 	xs = sr->sr_xs;
      1.1  fredette 	act_flags = ACT_CONTINUE;
      1.1  fredette
      1.1  fredette 	/*
      1.1  fredette 	 * This will be called by sunscpal_intr() when DMA is
      1.1  fredette 	 * complete.  Must stop DMA before touching the PAL or
      1.1  fredette 	 * there will be "register conflict" errors.
      1.1  fredette 	 */
1.21.48.2       mjf 	if ((sc->sc_state & SUNSCPAL_DOINGDMA) != 0) {
      1.1  fredette 		/* Pick-up where where we left off... */
      1.1  fredette 		goto dma_done;
      1.1  fredette 	}
      1.1  fredette
1.21.48.2       mjf  next_phase:
      1.1  fredette
      1.1  fredette 	if (!SUNSCPAL_BUSY(sc)) {
      1.1  fredette 		/* Unexpected disconnect */
1.21.48.2       mjf 		printf("%s: unexpected disconnect.\n", __func__);
      1.1  fredette 		xs->error = XS_DRIVER_STUFFUP;
      1.1  fredette 		act_flags |= (ACT_DISCONNECT | ACT_CMD_DONE);
      1.1  fredette 		goto do_actions;
      1.1  fredette 	}
      1.1  fredette
      1.1  fredette 	/*
      1.1  fredette 	 * Wait for REQ before reading the phase.
      1.1  fredette 	 * Need to wait longer than usual here, because
      1.1  fredette 	 * some devices are just plain slow...
      1.1  fredette 	 */
      1.1  fredette 	timo = sunscpal_wait_phase_timo;
      1.1  fredette 	for (;;) {
      1.1  fredette 		if (SUNSCPAL_READ_2(sc, sunscpal_icr) & SUNSCPAL_ICR_REQUEST)
      1.1  fredette 			break;
      1.1  fredette 		if (--timo <= 0) {
      1.1  fredette 			if (sc->sc_state & SUNSCPAL_ABORTING) {
1.21.48.2       mjf 				printf("%s: no REQ while aborting, reset\n",
1.21.48.2       mjf 				    device_xname(sc->sc_dev));
      1.1  fredette 				act_flags |= ACT_RESET_BUS;
      1.1  fredette 				goto do_actions;
      1.1  fredette 			}
1.21.48.2       mjf 			printf("%s: no REQ for next phase, abort\n",
1.21.48.2       mjf 			    device_xname(sc->sc_dev));
      1.1  fredette 			sc->sc_state |= SUNSCPAL_ABORTING;
      1.1  fredette 			sunscpal_sched_msgout(sc, SEND_ABORT);
      1.1  fredette 			goto next_phase;
      1.1  fredette 		}
      1.1  fredette 		delay(100);
      1.1  fredette 	}
      1.1  fredette
      1.1  fredette 	phase = SUNSCPAL_BUS_PHASE(SUNSCPAL_READ_2(sc, sunscpal_icr));
      1.1  fredette 	SUNSCPAL_TRACE("machine: phase=%s\n",
1.21.48.2       mjf 	    (long)phase_names[(phase >> 8) & 7]);
      1.1  fredette
      1.1  fredette 	/*
      1.1  fredette 	 * We assume that the device knows what it's doing,
      1.1  fredette 	 * so any phase is good.
      1.1  fredette 	 */
      1.1  fredette
      1.1  fredette 	switch (phase) {
      1.1  fredette
      1.1  fredette 	case SUNSCPAL_PHASE_DATA_OUT:
      1.1  fredette 	case SUNSCPAL_PHASE_DATA_IN:
      1.1  fredette 		act_flags = sunscpal_data_xfer(sc, phase);
      1.1  fredette 		break;
      1.1  fredette
      1.1  fredette 	case SUNSCPAL_PHASE_COMMAND:
      1.1  fredette 		act_flags = sunscpal_command(sc);
      1.1  fredette 		break;
      1.1  fredette
      1.1  fredette 	case SUNSCPAL_PHASE_STATUS:
      1.1  fredette 		act_flags = sunscpal_status(sc);
      1.1  fredette 		break;
      1.1  fredette
      1.1  fredette 	case SUNSCPAL_PHASE_MSG_OUT:
      1.1  fredette 		act_flags = sunscpal_msg_out(sc);
      1.1  fredette 		break;
      1.1  fredette
      1.1  fredette 	case SUNSCPAL_PHASE_MSG_IN:
      1.1  fredette 		act_flags = sunscpal_msg_in(sc);
      1.1  fredette 		break;
      1.1  fredette
      1.1  fredette 	default:
1.21.48.2       mjf 		printf("%s: Unexpected phase 0x%x\n", __func__, phase);
      1.1  fredette 		sc->sc_state |= SUNSCPAL_ABORTING;
      1.1  fredette 		sunscpal_sched_msgout(sc, SEND_ABORT);
      1.1  fredette 		goto next_phase;
      1.1  fredette
      1.1  fredette 	} /* switch */
      1.1  fredette 	sc->sc_prevphase = phase;
      1.1  fredette
1.21.48.2       mjf  do_actions:
      1.1  fredette
      1.1  fredette 	if (act_flags & ACT_WAIT_DMA) {
      1.1  fredette 		act_flags &= ~ACT_WAIT_DMA;
      1.1  fredette 		/* Wait for DMA to complete (polling, or interrupt). */
      1.1  fredette 		if ((sr->sr_flags & SR_IMMED) == 0) {
      1.1  fredette 			SUNSCPAL_TRACE("machine: wait for DMA intr.\n", 0);
      1.1  fredette 			return; 	/* will resume at dma_done */
      1.1  fredette 		}
      1.1  fredette 		/* Busy-wait for it to finish. */
      1.1  fredette 		SUNSCPAL_TRACE("machine: dma_poll, dh=0x%x\n",
1.21.48.2       mjf 		    (long)sr->sr_dma_hand);
      1.1  fredette 		sunscpal_dma_poll(sc);
1.21.48.2       mjf  dma_done:
      1.1  fredette 		/* Return here after interrupt. */
      1.1  fredette 		if (sr->sr_flags & SR_OVERDUE)
      1.1  fredette 			sc->sc_state |= SUNSCPAL_ABORTING;
      1.1  fredette 		SUNSCPAL_TRACE("machine: dma_stop, dh=0x%x\n",
1.21.48.2       mjf 		    (long)sr->sr_dma_hand);
      1.1  fredette 		sunscpal_dma_stop(sc);
      1.1  fredette 		SUNSCPAL_CLR_INTR(sc);	/* XXX */
      1.1  fredette 		/*
      1.1  fredette 		 * While DMA is running we can not touch the SBC,
      1.1  fredette 		 * so various places just set SUNSCPAL_ABORTING and
      1.1  fredette 		 * expect us the "kick it" when DMA is done.
      1.1  fredette 		 */
      1.1  fredette 		if (sc->sc_state & SUNSCPAL_ABORTING) {
      1.1  fredette 			sunscpal_sched_msgout(sc, SEND_ABORT);
      1.1  fredette 		}
      1.1  fredette 	}
      1.1  fredette
      1.1  fredette 	/*
      1.1  fredette 	 * Check for parity error.
      1.1  fredette 	 * XXX - better place to check?
      1.1  fredette 	 */
      1.1  fredette 	if (SUNSCPAL_READ_2(sc, sunscpal_icr) & SUNSCPAL_ICR_PARITY_ERROR) {
1.21.48.2       mjf 		printf("%s: parity error!\n", device_xname(sc->sc_dev));
      1.1  fredette 		/* XXX: sc->sc_state |= SUNSCPAL_ABORTING; */
      1.1  fredette 		sunscpal_sched_msgout(sc, SEND_PARITY_ERROR);
      1.1  fredette 	}
      1.1  fredette
      1.1  fredette 	if (act_flags == ACT_CONTINUE)
      1.1  fredette 		goto next_phase;
      1.1  fredette 	/* All other actions "break" from the loop. */
      1.1  fredette
      1.1  fredette 	SUNSCPAL_TRACE("machine: act_flags=0x%x\n", act_flags);
      1.1  fredette
      1.1  fredette 	if (act_flags & ACT_RESET_BUS) {
      1.1  fredette 		act_flags |= ACT_CMD_DONE;
      1.1  fredette 		/*
      1.1  fredette 		 * Reset the SCSI bus, usually due to a timeout.
      1.1  fredette 		 * The error code XS_TIMEOUT allows retries.
      1.1  fredette 		 */
      1.1  fredette 		sc->sc_state |= SUNSCPAL_ABORTING;
      1.1  fredette 		printf("%s: reset SCSI bus for TID=%d LUN=%d\n",
1.21.48.2       mjf 		    device_xname(sc->sc_dev), sr->sr_target, sr->sr_lun);
      1.1  fredette 		sunscpal_reset_scsibus(sc);
      1.1  fredette 	}
      1.1  fredette
      1.1  fredette 	if (act_flags & ACT_CMD_DONE) {
      1.1  fredette 		act_flags |= ACT_DISCONNECT;
      1.1  fredette 		/* Need to call scsipi_done() */
      1.1  fredette 		/* XXX: from the aic6360 driver, but why? */
      1.1  fredette 		if (sc->sc_datalen < 0) {
      1.1  fredette 			printf("%s: %d extra bytes from %d:%d\n",
1.21.48.2       mjf 			    device_xname(sc->sc_dev), -sc->sc_datalen,
      1.1  fredette 			    sr->sr_target, sr->sr_lun);
      1.1  fredette 			sc->sc_datalen = 0;
      1.1  fredette 		}
      1.1  fredette 		xs->resid = sc->sc_datalen;
      1.1  fredette 		/* Note: this will clear sc_current */
      1.1  fredette 		SUNSCPAL_TRACE("machine: call done, cur=0x%x\n", (long)sr);
      1.1  fredette 		sunscpal_done(sc);
      1.1  fredette 	}
      1.1  fredette
      1.1  fredette 	if (act_flags & ACT_DISCONNECT) {
      1.1  fredette 		/*
      1.1  fredette 		 * The device has dropped BSY (or will soon).
      1.1  fredette 		 * We have to wait here for BSY to drop, otherwise
      1.1  fredette 		 * the next command may decide we need a bus reset.
      1.1  fredette 		 */
      1.1  fredette 		timo = sunscpal_wait_req_timo;	/* XXX */
      1.1  fredette 		for (;;) {
      1.1  fredette 			if (!SUNSCPAL_BUSY(sc))
      1.1  fredette 				goto busfree;
      1.1  fredette 			if (--timo <= 0)
      1.1  fredette 				break;
      1.1  fredette 			delay(2);
      1.1  fredette 		}
      1.1  fredette 		/* Device is sitting on the bus! */
      1.1  fredette 		printf("%s: Target %d LUN %d stuck busy, resetting...\n",
1.21.48.2       mjf 		    device_xname(sc->sc_dev), sr->sr_target, sr->sr_lun);
      1.1  fredette 		sunscpal_reset_scsibus(sc);
1.21.48.2       mjf  busfree:
      1.1  fredette 		SUNSCPAL_TRACE("machine: discon, waited %d\n",
      1.1  fredette 			sunscpal_wait_req_timo - timo);
      1.1  fredette
      1.1  fredette 		SUNSCPAL_WRITE_2(sc, sunscpal_icr, 0);
      1.1  fredette
      1.1  fredette 		if ((act_flags & ACT_CMD_DONE) == 0) {
      1.1  fredette 			SUNSCPAL_TRACE("machine: discon, cur=0x%x\n", (long)sr);
      1.1  fredette 		}
      1.1  fredette
      1.1  fredette 		/*
      1.1  fredette 		 * We may be here due to a disconnect message,
      1.1  fredette 		 * in which case we did NOT call sunscpal_done,
      1.1  fredette 		 * and we need to clear sc_current.
      1.1  fredette 		 */
      1.1  fredette 		sc->sc_state = SUNSCPAL_IDLE;
      1.1  fredette 		sc->sc_current = NULL;
      1.1  fredette
      1.1  fredette 		/* Paranoia: clear everything. */
      1.1  fredette 		sc->sc_dataptr = NULL;
      1.1  fredette 		sc->sc_datalen = 0;
      1.1  fredette 		sc->sc_prevphase = SUNSCPAL_PHASE_INVALID;
      1.1  fredette 		sc->sc_msgpriq = 0;
      1.1  fredette 		sc->sc_msgoutq = 0;
      1.1  fredette 		sc->sc_msgout  = 0;
      1.1  fredette
      1.1  fredette 		/* Our caller will re-enable interrupts. */
      1.1  fredette 	}
      1.1  fredette }
      1.1  fredette
      1.1  fredette
      1.1  fredette #ifdef	SUNSCPAL_DEBUG
      1.1  fredette
      1.1  fredette static void
1.21.48.2       mjf sunscpal_show_scsi_cmd(struct scsipi_xfer *xs)
      1.1  fredette {
1.21.48.2       mjf 	uint8_t *b = (uint8_t *)xs->cmd;
1.21.48.2       mjf 	int i = 0;
      1.1  fredette
      1.2    bouyer 	scsipi_printaddr(xs->xs_periph);
1.21.48.2       mjf 	if ((xs->xs_control & XS_CTL_RESET) == 0) {
      1.2    bouyer 		printf("-");
      1.1  fredette 		while (i < xs->cmdlen) {
1.21.48.2       mjf 			if (i != 0)
1.21.48.2       mjf 				printf(",");
1.21.48.2       mjf 			printf("%x", b[i++]);
      1.1  fredette 		}
      1.1  fredette 		printf("-\n");
      1.1  fredette 	} else {
      1.2    bouyer 		printf("-RESET-\n");
      1.1  fredette 	}
      1.1  fredette }
      1.1  fredette
      1.1  fredette
      1.1  fredette int sunscpal_traceidx = 0;
      1.1  fredette
      1.1  fredette #define	TRACE_MAX	1024
      1.1  fredette struct trace_ent {
      1.1  fredette 	char *msg;
      1.1  fredette 	long  val;
      1.1  fredette } sunscpal_tracebuf[TRACE_MAX];
      1.1  fredette
      1.1  fredette void
1.21.48.2       mjf sunscpal_trace(char *msg, long val)
      1.1  fredette {
      1.1  fredette 	struct trace_ent *tr;
      1.1  fredette 	int s;
      1.1  fredette
      1.1  fredette 	s = splbio();
      1.1  fredette
      1.1  fredette 	tr = &sunscpal_tracebuf[sunscpal_traceidx];
      1.1  fredette
      1.1  fredette 	sunscpal_traceidx++;
      1.1  fredette 	if (sunscpal_traceidx >= TRACE_MAX)
      1.1  fredette 		sunscpal_traceidx = 0;
      1.1  fredette
      1.1  fredette 	tr->msg = msg;
      1.1  fredette 	tr->val = val;
      1.1  fredette
      1.1  fredette 	splx(s);
      1.1  fredette }
      1.1  fredette
      1.1  fredette #ifdef	DDB
      1.1  fredette void
1.21.48.2       mjf sunscpal_clear_trace(void)
      1.1  fredette {
1.21.48.2       mjf
      1.1  fredette 	sunscpal_traceidx = 0;
1.21.48.2       mjf 	memset((void *)sunscpal_tracebuf, 0, sizeof(sunscpal_tracebuf));
      1.1  fredette }
      1.1  fredette
      1.1  fredette void
1.21.48.2       mjf sunscpal_show_trace(void)
      1.1  fredette {
      1.1  fredette 	struct trace_ent *tr;
      1.1  fredette 	int idx;
      1.1  fredette
      1.1  fredette 	idx = sunscpal_traceidx;
      1.1  fredette 	do {
      1.1  fredette 		tr = &sunscpal_tracebuf[idx];
      1.1  fredette 		idx++;
      1.1  fredette 		if (idx >= TRACE_MAX)
      1.1  fredette 			idx = 0;
      1.1  fredette 		if (tr->msg)
      1.1  fredette 			db_printf(tr->msg, tr->val);
      1.1  fredette 	} while (idx != sunscpal_traceidx);
      1.1  fredette }
      1.1  fredette
      1.1  fredette void
1.21.48.2       mjf sunscpal_show_req(struct sunscpal_req *sr)
      1.1  fredette {
      1.1  fredette 	struct scsipi_xfer *xs = sr->sr_xs;
      1.1  fredette
      1.1  fredette 	db_printf("TID=%d ",	sr->sr_target);
      1.1  fredette 	db_printf("LUN=%d ",	sr->sr_lun);
      1.1  fredette 	db_printf("dh=%p ",	sr->sr_dma_hand);
      1.1  fredette 	db_printf("dptr=%p ",	sr->sr_dataptr);
      1.1  fredette 	db_printf("dlen=0x%x ",	sr->sr_datalen);
      1.1  fredette 	db_printf("flags=%d ",	sr->sr_flags);
      1.1  fredette 	db_printf("stat=%d ",	sr->sr_status);
      1.1  fredette
      1.1  fredette 	if (xs == NULL) {
      1.1  fredette 		db_printf("(xs=NULL)\n");
      1.1  fredette 		return;
      1.1  fredette 	}
      1.1  fredette 	db_printf("\n");
      1.1  fredette #ifdef	SCSIDEBUG
      1.1  fredette 	show_scsipi_xs(xs);
      1.1  fredette #else
      1.1  fredette 	db_printf("xs=%p\n", xs);
      1.1  fredette #endif
      1.1  fredette }
      1.1  fredette
      1.1  fredette void
1.21.48.2       mjf sunscpal_show_state(void)
      1.1  fredette {
      1.1  fredette 	struct sunscpal_softc *sc;
      1.1  fredette 	struct sunscpal_req *sr;
      1.1  fredette 	int i, j, k;
      1.1  fredette
      1.1  fredette 	sc = sunscpal_debug_sc;
      1.1  fredette
      1.1  fredette 	if (sc == NULL) {
      1.1  fredette 		db_printf("sunscpal_debug_sc == NULL\n");
      1.1  fredette 		return;
      1.1  fredette 	}
      1.1  fredette
      1.1  fredette 	db_printf("sc_ncmds=%d\n",  	sc->sc_ncmds);
      1.1  fredette 	k = -1;	/* which is current? */
      1.1  fredette 	for (i = 0; i < SUNSCPAL_OPENINGS; i++) {
      1.1  fredette 		sr = &sc->sc_ring[i];
      1.1  fredette 		if (sr->sr_xs) {
      1.1  fredette 			if (sr == sc->sc_current)
      1.1  fredette 				k = i;
      1.1  fredette 			db_printf("req %d: (sr=%p)", i, sr);
      1.1  fredette 			sunscpal_show_req(sr);
      1.1  fredette 		}
      1.1  fredette 	}
      1.1  fredette 	db_printf("sc_rr=%d, current=%d\n", sc->sc_rr, k);
      1.1  fredette
      1.1  fredette 	db_printf("Active request matrix:\n");
      1.1  fredette 	for(i = 0; i < 8; i++) {		/* targets */
      1.1  fredette 		for (j = 0; j < 8; j++) {	/* LUN */
      1.1  fredette 			sr = sc->sc_matrix[i][j];
      1.1  fredette 			if (sr) {
      1.1  fredette 				db_printf("TID=%d LUN=%d sr=%p\n", i, j, sr);
      1.1  fredette 			}
      1.1  fredette 		}
      1.1  fredette 	}
      1.1  fredette
      1.1  fredette 	db_printf("sc_state=0x%x\n",	sc->sc_state);
      1.1  fredette 	db_printf("sc_current=%p\n",	sc->sc_current);
      1.1  fredette 	db_printf("sc_dataptr=%p\n",	sc->sc_dataptr);
      1.1  fredette 	db_printf("sc_datalen=0x%x\n",	sc->sc_datalen);
      1.1  fredette
      1.1  fredette 	db_printf("sc_prevphase=%d\n",	sc->sc_prevphase);
      1.1  fredette 	db_printf("sc_msgpriq=0x%x\n",	sc->sc_msgpriq);
      1.1  fredette }
      1.1  fredette #endif	/* DDB */
      1.1  fredette #endif	/* SUNSCPAL_DEBUG */
      1.1  fredette
      1.1  fredette void
1.21.48.2       mjf sunscpal_attach(struct sunscpal_softc *sc, int options)
      1.1  fredette {
      1.1  fredette
      1.1  fredette 	/*
      1.1  fredette 	 * Handle our options.
      1.1  fredette 	 */
1.21.48.2       mjf 	aprint_normal(": options=0x%x\n", options);
      1.1  fredette 	sc->sc_parity_disable = (options & SUNSCPAL_OPT_NO_PARITY_CHK);
      1.1  fredette 	if (options & SUNSCPAL_OPT_DISABLE_DMA)
      1.1  fredette 		sc->sc_flags |= SUNSCPAL_DISABLE_DMA;
      1.1  fredette
      1.1  fredette 	/*
      1.1  fredette 	 * Fill in the adapter.
      1.1  fredette 	 */
      1.2    bouyer 	memset(&sc->sc_adapter, 0, sizeof(sc->sc_adapter));
1.21.48.2       mjf 	sc->sc_adapter.adapt_dev = sc->sc_dev;
      1.2    bouyer 	sc->sc_adapter.adapt_nchannels = 1;
      1.2    bouyer 	sc->sc_adapter.adapt_openings = SUNSCPAL_OPENINGS;
      1.2    bouyer 	sc->sc_adapter.adapt_max_periph = 1;
      1.2    bouyer 	sc->sc_adapter.adapt_request = sunscpal_scsipi_request;
      1.2    bouyer 	sc->sc_adapter.adapt_minphys = sunscpal_minphys;
     1.15   mycroft 	if (options & SUNSCPAL_OPT_FORCE_POLLING)
     1.15   mycroft 		sc->sc_adapter.adapt_flags |= SCSIPI_ADAPT_POLL_ONLY;
      1.2    bouyer
      1.2    bouyer 	sc->sc_channel.chan_adapter = &sc->sc_adapter;
      1.2    bouyer 	sc->sc_channel.chan_bustype = &scsi_bustype;
      1.2    bouyer 	sc->sc_channel.chan_channel = 0;
      1.2    bouyer 	sc->sc_channel.chan_ntargets = 8;
      1.2    bouyer 	sc->sc_channel.chan_nluns = 8;
      1.2    bouyer 	sc->sc_channel.chan_id = 7;
      1.1  fredette
      1.1  fredette 	/*
      1.1  fredette 	 * Add reference to adapter so that we drop the reference after
      1.1  fredette 	 * config_found() to make sure the adatper is disabled.
      1.1  fredette 	 */
      1.2    bouyer 	if (scsipi_adapter_addref(&sc->sc_adapter) != 0) {
1.21.48.2       mjf 		aprint_error_dev(sc->sc_dev, "unable to enable controller\n");
      1.1  fredette 		return;
      1.1  fredette 	}
      1.1  fredette
      1.1  fredette 	sunscpal_init(sc);	/* Init chip and driver */
      1.1  fredette 	sunscpal_reset_scsibus(sc);
      1.1  fredette
      1.1  fredette 	/*
      1.1  fredette 	 * Ask the adapter what subunits are present
      1.1  fredette 	 */
1.21.48.2       mjf 	(void)config_found(sc->sc_dev, &sc->sc_channel, scsiprint);
      1.2    bouyer 	scsipi_adapter_delref(&sc->sc_adapter);
      1.1  fredette }
      1.1  fredette
      1.1  fredette int
1.21.48.2       mjf sunscpal_detach(struct sunscpal_softc *sc, int flags)
      1.1  fredette {
      1.1  fredette
1.21.48.2       mjf 	return EOPNOTSUPP;
      1.1  fredette }
      1.1  fredette
      1.1  fredette static void
      1.1  fredette sunscpal_minphys(struct buf *bp)
      1.1  fredette {
1.21.48.2       mjf
      1.1  fredette 	if (bp->b_bcount > SUNSCPAL_MAX_DMA_LEN) {
      1.1  fredette #ifdef	SUNSCPAL_DEBUG
      1.1  fredette 		if (sunscpal_debug & SUNSCPAL_DBG_DMA) {
1.21.48.2       mjf 			printf("%s: len = 0x%lx.\n", __func__, bp->b_bcount);
      1.1  fredette 			Debugger();
      1.1  fredette 		}
      1.1  fredette #endif
      1.1  fredette 		bp->b_bcount = SUNSCPAL_MAX_DMA_LEN;
      1.1  fredette 	}
1.21.48.2       mjf 	return minphys(bp);
      1.1  fredette }
      1.1  fredette
      1.1  fredette #ifdef SUNSCPAL_USE_BUS_DMA
      1.1  fredette
      1.1  fredette /*
      1.1  fredette  * Allocate a DMA handle and put it in sr->sr_dma_hand.  Prepare
     1.17     perry  * for DMA transfer.
      1.1  fredette  */
      1.1  fredette static void
1.21.48.2       mjf sunscpal_dma_alloc(struct sunscpal_softc *sc)
      1.1  fredette {
      1.1  fredette 	struct sunscpal_req *sr = sc->sc_current;
      1.1  fredette 	sunscpal_dma_handle_t dh;
      1.1  fredette 	int i, xlen;
      1.1  fredette 	u_long addr;
      1.1  fredette
      1.1  fredette #ifdef	DIAGNOSTIC
      1.1  fredette 	if (sr->sr_dma_hand != NULL)
1.21.48.2       mjf 		panic("%s: already have DMA handle", __func__);
      1.1  fredette #endif
      1.1  fredette
1.21.48.2       mjf 	addr = (u_long)sc->sc_dataptr;
      1.1  fredette 	xlen = sc->sc_datalen;
      1.1  fredette
      1.1  fredette 	/* If the DMA start addr is misaligned then do PIO */
      1.1  fredette 	if ((addr & 1) || (xlen & 1)) {
1.21.48.2       mjf 		printf("%s: misaligned.\n", __func__);
      1.1  fredette 		return;
      1.1  fredette 	}
      1.1  fredette
      1.1  fredette 	/* Make sure our caller checked sc_min_dma_len. */
      1.1  fredette 	if (xlen < sc->sc_min_dma_len)
1.21.48.2       mjf 		panic("%s: xlen=0x%x", __func__, xlen);
      1.1  fredette
      1.1  fredette 	/*
      1.1  fredette 	 * Never attempt single transfers of more than 63k, because
      1.1  fredette 	 * our count register is only 16 bits.
      1.1  fredette 	 * This should never happen since already bounded by minphys().
      1.1  fredette 	 * XXX - Should just segment these...
      1.1  fredette 	 */
      1.1  fredette 	if (xlen > SUNSCPAL_MAX_DMA_LEN) {
1.21.48.2       mjf 		printf("%s: excessive xlen=0x%x\n", __func__, xlen);
      1.1  fredette 		Debugger();
      1.1  fredette 		sc->sc_datalen = xlen = SUNSCPAL_MAX_DMA_LEN;
      1.1  fredette 	}
      1.1  fredette
      1.1  fredette 	/* Find free DMA handle.  Guaranteed to find one since we have
      1.1  fredette 	   as many DMA handles as the driver has processes. */
      1.1  fredette 	for (i = 0; i < SUNSCPAL_OPENINGS; i++) {
      1.1  fredette 		if ((sc->sc_dma_handles[i].dh_flags & SUNSCDH_BUSY) == 0)
      1.1  fredette 			goto found;
      1.1  fredette 	}
1.21.48.2       mjf 	panic("%s: no free DMA handles.", device_xname(sc->sc_dev));
1.21.48.2       mjf  found:
      1.1  fredette
      1.1  fredette 	dh = &sc->sc_dma_handles[i];
      1.1  fredette 	dh->dh_flags = SUNSCDH_BUSY;
1.21.48.2       mjf 	dh->dh_mapaddr = (uint8_t *)addr;
      1.1  fredette 	dh->dh_maplen  = xlen;
      1.1  fredette 	dh->dh_dvma = 0;
      1.1  fredette
      1.1  fredette 	/* Load the DMA map. */
1.21.48.2       mjf 	if (bus_dmamap_load(sc->sunscpal_dmat, dh->dh_dmamap,
1.21.48.2       mjf 	    dh->dh_mapaddr, dh->dh_maplen, NULL, BUS_DMA_NOWAIT) != 0) {
      1.1  fredette 		/* Can't load map */
1.21.48.2       mjf 		printf("%s: can't DMA %p/0x%x\n", __func__,
1.21.48.2       mjf 		    dh->dh_mapaddr, dh->dh_maplen);
      1.1  fredette 		dh->dh_flags = 0;
      1.1  fredette 		return;
      1.1  fredette 	}
      1.1  fredette
      1.1  fredette 	/* success */
      1.1  fredette 	sr->sr_dma_hand = dh;
      1.1  fredette }
      1.1  fredette
      1.1  fredette static void
1.21.48.2       mjf sunscpal_dma_free(struct sunscpal_softc *sc)
      1.1  fredette {
      1.1  fredette 	struct sunscpal_req *sr = sc->sc_current;
      1.1  fredette 	sunscpal_dma_handle_t dh = sr->sr_dma_hand;
      1.1  fredette
      1.1  fredette #ifdef	DIAGNOSTIC
      1.1  fredette 	if (dh == NULL)
1.21.48.2       mjf 		panic("%s: no DMA handle", __func__);
      1.1  fredette #endif
      1.1  fredette
      1.1  fredette 	if (sc->sc_state & SUNSCPAL_DOINGDMA)
1.21.48.2       mjf 		panic("%s: free while in progress", __func__);
      1.1  fredette
      1.1  fredette 	if (dh->dh_flags & SUNSCDH_BUSY) {
      1.1  fredette 		/* XXX - Should separate allocation and mapping. */
      1.1  fredette 		/* Give back the DVMA space. */
      1.1  fredette 		bus_dmamap_unload(sc->sunscpal_dmat, dh->dh_dmamap);
      1.1  fredette 		dh->dh_flags = 0;
      1.1  fredette 	}
      1.1  fredette 	sr->sr_dma_hand = NULL;
      1.1  fredette }
      1.1  fredette
      1.1  fredette /*
     1.17     perry  * This function is called during the SELECT phase that
     1.17     perry  * precedes a COMMAND phase, in case we need to setup the
      1.1  fredette  * DMA engine before the bus enters a DATA phase.
      1.1  fredette  *
      1.1  fredette  * On the sc version, setup the start address and the count.
      1.1  fredette  */
      1.1  fredette static void
1.21.48.2       mjf sunscpal_dma_setup(struct sunscpal_softc *sc)
      1.1  fredette {
      1.1  fredette 	struct sunscpal_req *sr = sc->sc_current;
      1.1  fredette 	struct scsipi_xfer *xs = sr->sr_xs;
      1.1  fredette 	sunscpal_dma_handle_t dh = sr->sr_dma_hand;
      1.1  fredette 	long data_pa;
      1.1  fredette 	int xlen;
      1.1  fredette
      1.1  fredette 	/*
      1.1  fredette 	 * Get the DVMA mapping for this segment.
      1.1  fredette 	 * XXX - Should separate allocation and mapin.
      1.1  fredette 	 */
      1.1  fredette 	data_pa = dh->dh_dvma;
      1.1  fredette 	data_pa += (sc->sc_dataptr - dh->dh_mapaddr);
      1.1  fredette 	if (data_pa & 1)
1.21.48.2       mjf 		panic("%s: bad pa=0x%lx", __func__, data_pa);
      1.1  fredette 	xlen = sc->sc_datalen;
      1.1  fredette 	if (xlen & 1)
1.21.48.2       mjf 		panic("%s: bad xlen=0x%x", __func__, xlen);
      1.1  fredette 	sc->sc_reqlen = xlen; 	/* XXX: or less? */
      1.1  fredette
      1.1  fredette #ifdef	SUNSCPAL_DEBUG
      1.1  fredette 	if (sunscpal_debug & SUNSCPAL_DBG_DMA) {
1.21.48.2       mjf 		printf("%s: dh=%p, pa=0x%lx, xlen=0x%x\n",
1.21.48.2       mjf 		    __func__, dh, data_pa, xlen);
      1.1  fredette 	}
      1.1  fredette #endif
      1.1  fredette
      1.1  fredette 	/* sync the DMA map: */
     1.17     perry 	bus_dmamap_sync(sc->sunscpal_dmat, dh->dh_dmamap, 0, dh->dh_maplen,
1.21.48.2       mjf 	    ((xs->xs_control & XS_CTL_DATA_OUT) == 0 ?
1.21.48.2       mjf 	    BUS_DMASYNC_PREREAD : BUS_DMASYNC_PREWRITE));
      1.1  fredette
      1.1  fredette 	/* Load the start address and the count. */
      1.1  fredette 	SUNSCPAL_WRITE_2(sc, sunscpal_dma_addr_h, (data_pa >> 16) & 0xFFFF);
      1.1  fredette 	SUNSCPAL_WRITE_2(sc, sunscpal_dma_addr_l, (data_pa >> 0) & 0xFFFF);
      1.1  fredette 	SUNSCPAL_WRITE_2(sc, sunscpal_dma_count, SUNSCPAL_DMA_COUNT_FLIP(xlen));
      1.1  fredette }
      1.1  fredette
      1.1  fredette #endif /* SUNSCPAL_USE_BUS_DMA */