NetBSD/sys/arch/mac68k/dev/sbc.c

1124 lines
30 KiB
C

/* $NetBSD: sbc.c,v 1.11 1996/08/28 19:00:12 cgd Exp $ */
/*
* Copyright (c) 1996 Scott Reynolds
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
* 3. The name of the authors may not be used to endorse or promote products
* derived from this software without specific prior written permission.
* 4. All advertising materials mentioning features or use of this software
* must display the following acknowledgements:
* This product includes software developed by Scott Reynolds.
*
* THIS SOFTWARE IS PROVIDED BY THE AUTHORS ``AS IS'' AND ANY EXPRESS OR
* IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES
* OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED.
* IN NO EVENT SHALL THE AUTHORS BE LIABLE FOR ANY DIRECT, INDIRECT,
* INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT
* NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
* DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
* THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF
* THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*/
/*
* This file contains only the machine-dependent parts of the mac68k
* NCR 5380 SCSI driver. (Autoconfig stuff and PDMA functions.)
* The machine-independent parts are in ncr5380sbc.c
*
* Supported hardware includes:
* Macintosh II family 5380-based controller
*
* Credits, history:
*
* Scott Reynolds wrote this module, based on work by Allen Briggs
* (mac68k), Gordon W. Ross and David Jones (sun3), and Leo Weppelman
* (atari). Thanks to Allen for supplying crucial interpretation of the
* NetBSD/mac68k 1.1 'ncrscsi' driver. Also, Allen, Gordon, and Jason
* Thorpe all helped to refine this code, and were considerable sources
* of moral support.
*/
#include <sys/types.h>
#include <sys/param.h>
#include <sys/systm.h>
#include <sys/kernel.h>
#include <sys/errno.h>
#include <sys/device.h>
#include <sys/buf.h>
#include <sys/proc.h>
#include <sys/user.h>
#include <scsi/scsi_all.h>
#include <scsi/scsi_debug.h>
#include <scsi/scsiconf.h>
#include <dev/ic/ncr5380reg.h>
#include <dev/ic/ncr5380var.h>
#include <machine/cpu.h>
#include <machine/viareg.h>
#include "sbcreg.h"
/*
* Transfers smaller than this are done using PIO
* (on assumption they're not worth PDMA overhead)
*/
#define MIN_DMA_LEN 128
/*
* Transfers larger than 8192 bytes need to be split up
* due to the size of the PDMA space.
*/
#define MAX_DMA_LEN 0x2000
/*
* From Guide to the Macintosh Family Hardware, pp. 137-143
* These are offsets from SCSIBase (see pmap_bootstrap.c)
*/
#define SBC_REG_OFS 0x10000
#define SBC_HSK_OFS 0x06000
#define SBC_DMA_OFS 0x12000
#define SBC_DMA_OFS_PB500 0x06000
#define SBC_REG_OFS_IIFX 0x08000 /* Just guessing... */
#define SBC_HSK_OFS_IIFX 0x0e000
#define SBC_DMA_OFS_IIFX 0x0c000
#ifdef SBC_DEBUG
# define SBC_DB_INTR 0x01
# define SBC_DB_DMA 0x02
# define SBC_DB_REG 0x04
# define SBC_DB_BREAK 0x08
int sbc_debug = 0 /* | SBC_DB_INTR | SBC_DB_DMA */;
int sbc_link_flags = 0 /* | SDEV_DB2 */;
# ifndef DDB
# define Debugger() printf("Debug: sbc.c:%d\n", __LINE__)
# endif
# define SBC_BREAK \
do { if (sbc_debug & SBC_DB_BREAK) Debugger(); } while (0)
#else
# define SBC_BREAK
#endif
/*
* This structure is used to keep track of PDMA requests.
*/
struct sbc_pdma_handle {
int dh_flags; /* flags */
#define SBC_DH_BUSY 0x01 /* This handle is in use */
#define SBC_DH_OUT 0x02 /* PDMA data out (write) */
#define SBC_DH_DONE 0x04 /* PDMA transfer is complete */
u_char *dh_addr; /* data buffer */
int dh_len; /* length of data buffer */
};
/*
* The first structure member has to be the ncr5380_softc
* so we can just cast to go back and forth between them.
*/
struct sbc_softc {
struct ncr5380_softc ncr_sc;
volatile struct sbc_regs *sc_regs;
volatile vm_offset_t sc_drq_addr;
volatile vm_offset_t sc_nodrq_addr;
volatile u_int8_t *sc_ienable;
volatile u_int8_t *sc_iflag;
int sc_options; /* options for this instance. */
struct sbc_pdma_handle sc_pdma[SCI_OPENINGS];
};
/*
* Options. By default, SCSI interrupts and reselect are disabled.
* You may enable either of these features with the `flags' directive
* in your kernel's configuration file.
*
* Alternatively, you can patch your kernel with DDB or some other
* mechanism. The sc_options member of the softc is OR'd with
* the value in sbc_options.
*
* The options code is based on the sparc 'si' driver's version of
* the same.
*/
#define SBC_PDMA 0x01 /* Use PDMA for polled transfers */
#define SBC_INTR 0x02 /* Allow SCSI IRQ/DRQ interrupts */
#define SBC_RESELECT 0x04 /* Allow disconnect/reselect */
#define SBC_OPTIONS_MASK (SBC_RESELECT|SBC_INTR|SBC_PDMA)
#define SBC_OPTIONS_BITS "\10\3RESELECT\2INTR\1PDMA"
int sbc_options = SBC_PDMA;
static int sbc_match __P((struct device *, void *, void *));
static void sbc_attach __P((struct device *, struct device *, void *));
static void sbc_minphys __P((struct buf *bp));
static int sbc_wait_busy __P((struct ncr5380_softc *));
static int sbc_ready __P((struct ncr5380_softc *));
static int sbc_wait_dreq __P((struct ncr5380_softc *));
static int sbc_pdma_in __P((struct ncr5380_softc *, int, int, u_char *));
static int sbc_pdma_out __P((struct ncr5380_softc *, int, int, u_char *));
#ifdef SBC_DEBUG
static void decode_5380_intr __P((struct ncr5380_softc *));
#endif
void sbc_intr_enable __P((struct ncr5380_softc *));
void sbc_intr_disable __P((struct ncr5380_softc *));
void sbc_irq_intr __P((void *));
void sbc_drq_intr __P((void *));
void sbc_dma_alloc __P((struct ncr5380_softc *));
void sbc_dma_free __P((struct ncr5380_softc *));
void sbc_dma_poll __P((struct ncr5380_softc *));
void sbc_dma_setup __P((struct ncr5380_softc *));
void sbc_dma_start __P((struct ncr5380_softc *));
void sbc_dma_eop __P((struct ncr5380_softc *));
void sbc_dma_stop __P((struct ncr5380_softc *));
static struct scsi_adapter sbc_ops = {
ncr5380_scsi_cmd, /* scsi_cmd() */
sbc_minphys, /* scsi_minphys() */
NULL, /* open_target_lu() */
NULL, /* close_target_lu() */
};
/* This is copied from julian's bt driver */
/* "so we have a default dev struct for our link struct." */
static struct scsi_device sbc_dev = {
NULL, /* Use default error handler. */
NULL, /* Use default start handler. */
NULL, /* Use default async handler. */
NULL, /* Use default "done" routine. */
};
struct cfattach sbc_ca = {
sizeof(struct sbc_softc), sbc_match, sbc_attach
};
struct cfdriver sbc_cd = {
NULL, "sbc", DV_DULL
};
static int
sbc_match(parent, match, args)
struct device *parent;
void *match, *args;
{
if (!mac68k_machine.scsi80)
return 0;
return 1;
}
static void
sbc_attach(parent, self, args)
struct device *parent, *self;
void *args;
{
struct sbc_softc *sc = (struct sbc_softc *) self;
struct ncr5380_softc *ncr_sc = (struct ncr5380_softc *) sc;
extern vm_offset_t SCSIBase;
/* Pull in the options flags. */
sc->sc_options = ((ncr_sc->sc_dev.dv_cfdata->cf_flags | sbc_options)
& SBC_OPTIONS_MASK);
/*
* Set up offsets to 5380 registers and GLUE I/O space, and turn
* off options we know we can't support on certain models.
*/
switch (current_mac_model->machineid) {
case MACH_MACIIFX: /* Note: the IIfx isn't (yet) supported. */
sc->sc_regs = (struct sbc_regs *)(SCSIBase + SBC_REG_OFS_IIFX);
sc->sc_drq_addr = (vm_offset_t)(SCSIBase + SBC_HSK_OFS_IIFX);
sc->sc_nodrq_addr = (vm_offset_t)(SCSIBase + SBC_DMA_OFS_IIFX);
sc->sc_options &= ~(SBC_INTR | SBC_RESELECT);
break;
case MACH_MACPB500:
sc->sc_regs = (struct sbc_regs *)(SCSIBase + SBC_REG_OFS);
sc->sc_drq_addr = (vm_offset_t)(SCSIBase + SBC_HSK_OFS); /*??*/
sc->sc_nodrq_addr = (vm_offset_t)(SCSIBase + SBC_DMA_OFS_PB500);
sc->sc_options &= ~(SBC_INTR | SBC_RESELECT);
break;
default:
sc->sc_regs = (struct sbc_regs *)(SCSIBase + SBC_REG_OFS);
sc->sc_drq_addr = (vm_offset_t)(SCSIBase + SBC_HSK_OFS);
sc->sc_nodrq_addr = (vm_offset_t)(SCSIBase + SBC_DMA_OFS);
break;
}
/*
* Fill in the prototype scsi_link.
*/
ncr_sc->sc_link.channel = SCSI_CHANNEL_ONLY_ONE;
ncr_sc->sc_link.adapter_softc = sc;
ncr_sc->sc_link.adapter_target = 7;
ncr_sc->sc_link.adapter = &sbc_ops;
ncr_sc->sc_link.device = &sbc_dev;
/*
* Initialize fields used by the MI code
*/
ncr_sc->sci_r0 = &sc->sc_regs->sci_pr0.sci_reg;
ncr_sc->sci_r1 = &sc->sc_regs->sci_pr1.sci_reg;
ncr_sc->sci_r2 = &sc->sc_regs->sci_pr2.sci_reg;
ncr_sc->sci_r3 = &sc->sc_regs->sci_pr3.sci_reg;
ncr_sc->sci_r4 = &sc->sc_regs->sci_pr4.sci_reg;
ncr_sc->sci_r5 = &sc->sc_regs->sci_pr5.sci_reg;
ncr_sc->sci_r6 = &sc->sc_regs->sci_pr6.sci_reg;
ncr_sc->sci_r7 = &sc->sc_regs->sci_pr7.sci_reg;
/*
* MD function pointers used by the MI code.
*/
if (sc->sc_options & SBC_PDMA) {
ncr_sc->sc_pio_out = sbc_pdma_out;
ncr_sc->sc_pio_in = sbc_pdma_in;
} else {
ncr_sc->sc_pio_out = ncr5380_pio_out;
ncr_sc->sc_pio_in = ncr5380_pio_in;
}
ncr_sc->sc_dma_alloc = NULL;
ncr_sc->sc_dma_free = NULL;
ncr_sc->sc_dma_poll = NULL;
ncr_sc->sc_intr_on = NULL;
ncr_sc->sc_intr_off = NULL;
ncr_sc->sc_dma_setup = NULL;
ncr_sc->sc_dma_start = NULL;
ncr_sc->sc_dma_eop = NULL;
ncr_sc->sc_dma_stop = NULL;
ncr_sc->sc_flags = 0;
ncr_sc->sc_min_dma_len = MIN_DMA_LEN;
if (sc->sc_options & SBC_INTR) {
if (sc->sc_options & SBC_RESELECT)
ncr_sc->sc_flags |= NCR5380_PERMIT_RESELECT;
ncr_sc->sc_dma_alloc = sbc_dma_alloc;
ncr_sc->sc_dma_free = sbc_dma_free;
ncr_sc->sc_dma_poll = sbc_dma_poll;
ncr_sc->sc_dma_setup = sbc_dma_setup;
ncr_sc->sc_dma_start = sbc_dma_start;
ncr_sc->sc_dma_eop = sbc_dma_eop;
ncr_sc->sc_dma_stop = sbc_dma_stop;
mac68k_register_scsi_drq(sbc_drq_intr, ncr_sc);
mac68k_register_scsi_irq(sbc_irq_intr, ncr_sc);
} else
ncr_sc->sc_flags |= NCR5380_FORCE_POLLING;
/*
* Initialize fields used only here in the MD code.
*/
if (VIA2 == VIA2OFF) {
sc->sc_ienable = Via1Base + VIA2 * 0x2000 + vIER;
sc->sc_iflag = Via1Base + VIA2 * 0x2000 + vIFR;
} else {
sc->sc_ienable = Via1Base + VIA2 * 0x2000 + rIER;
sc->sc_iflag = Via1Base + VIA2 * 0x2000 + rIFR;
}
if (sc->sc_options)
printf(": options=%b", sc->sc_options, SBC_OPTIONS_BITS);
printf("\n");
/* Now enable SCSI interrupts through VIA2, if appropriate */
if (sc->sc_options & SBC_INTR)
sbc_intr_enable(ncr_sc);
#ifdef SBC_DEBUG
if (sbc_debug)
printf("%s: softc=%p regs=%p\n", ncr_sc->sc_dev.dv_xname,
sc, sc->sc_regs);
ncr_sc->sc_link.flags |= sbc_link_flags;
#endif
/*
* Initialize the SCSI controller itself.
*/
ncr5380_init(ncr_sc);
ncr5380_reset_scsibus(ncr_sc);
config_found(self, &(ncr_sc->sc_link), scsiprint);
}
static void
sbc_minphys(struct buf *bp)
{
if (bp->b_bcount > MAX_DMA_LEN)
bp->b_bcount = MAX_DMA_LEN;
return (minphys(bp));
}
/***
* General support for Mac-specific SCSI logic.
***/
/* These are used in the following inline functions. */
int sbc_wait_busy_timo = 1000 * 5000; /* X2 = 10 S. */
int sbc_ready_timo = 1000 * 5000; /* X2 = 10 S. */
int sbc_wait_dreq_timo = 1000 * 5000; /* X2 = 10 S. */
/* Return zero on success. */
static __inline__ int
sbc_wait_busy(sc)
struct ncr5380_softc *sc;
{
register int timo = sbc_wait_busy_timo;
for (;;) {
if (SCI_BUSY(sc)) {
timo = 0; /* return 0 */
break;
}
if (--timo < 0)
break; /* return -1 */
delay(2);
}
return (timo);
}
static __inline__ int
sbc_ready(sc)
struct ncr5380_softc *sc;
{
register int timo = sbc_ready_timo;
for (;;) {
if ((*sc->sci_csr & (SCI_CSR_DREQ|SCI_CSR_PHASE_MATCH))
== (SCI_CSR_DREQ|SCI_CSR_PHASE_MATCH)) {
timo = 0;
break;
}
if (((*sc->sci_csr & SCI_CSR_PHASE_MATCH) == 0)
|| (SCI_BUSY(sc) == 0)) {
timo = -1;
break;
}
if (--timo < 0)
break; /* return -1 */
delay(2);
}
return (timo);
}
static __inline__ int
sbc_wait_dreq(sc)
struct ncr5380_softc *sc;
{
register int timo = sbc_wait_dreq_timo;
for (;;) {
if ((*sc->sci_csr & (SCI_CSR_DREQ|SCI_CSR_PHASE_MATCH))
== (SCI_CSR_DREQ|SCI_CSR_PHASE_MATCH)) {
timo = 0;
break;
}
if (--timo < 0)
break; /* return -1 */
delay(2);
}
return (timo);
}
/***
* Macintosh SCSI interrupt support routines.
***/
void
sbc_intr_enable(ncr_sc)
struct ncr5380_softc *ncr_sc;
{
register struct sbc_softc *sc = (struct sbc_softc *) ncr_sc;
int s;
s = splhigh();
*sc->sc_ienable = 0x80 | (V2IF_SCSIIRQ | V2IF_SCSIDRQ);
splx(s);
}
void
sbc_intr_disable(ncr_sc)
struct ncr5380_softc *ncr_sc;
{
register struct sbc_softc *sc = (struct sbc_softc *) ncr_sc;
int s;
s = splhigh();
*sc->sc_ienable = (V2IF_SCSIIRQ | V2IF_SCSIDRQ);
splx(s);
}
void
sbc_irq_intr(p)
void *p;
{
register struct ncr5380_softc *ncr_sc = p;
register int claimed = 0;
/* How we ever arrive here without IRQ set is a mystery... */
if (*ncr_sc->sci_csr & SCI_CSR_INT) {
#ifdef SBC_DEBUG
if (sbc_debug & SBC_DB_INTR)
decode_5380_intr(ncr_sc);
#endif
claimed = ncr5380_intr(ncr_sc);
if (!claimed) {
if (((*ncr_sc->sci_csr & ~SCI_CSR_PHASE_MATCH) == SCI_CSR_INT)
&& ((*ncr_sc->sci_bus_csr & ~SCI_BUS_RST) == 0))
SCI_CLR_INTR(ncr_sc); /* RST interrupt */
#ifdef SBC_DEBUG
else {
printf("%s: spurious intr\n",
ncr_sc->sc_dev.dv_xname);
SBC_BREAK;
}
#endif
}
}
}
#ifdef SBC_DEBUG
void
decode_5380_intr(ncr_sc)
struct ncr5380_softc *ncr_sc;
{
register u_char csr = *ncr_sc->sci_csr;
register u_char bus_csr = *ncr_sc->sci_bus_csr;
if (((csr & ~(SCI_CSR_PHASE_MATCH | SCI_CSR_ATN)) == SCI_CSR_INT) &&
((bus_csr & ~(SCI_BUS_MSG | SCI_BUS_CD | SCI_BUS_IO | SCI_BUS_DBP)) == SCI_BUS_SEL)) {
if (csr & SCI_BUS_IO)
printf("%s: reselect\n", ncr_sc->sc_dev.dv_xname);
else
printf("%s: select\n", ncr_sc->sc_dev.dv_xname);
} else if (((csr & ~SCI_CSR_ACK) == (SCI_CSR_DONE | SCI_CSR_INT)) &&
((bus_csr & (SCI_BUS_RST | SCI_BUS_BSY | SCI_BUS_SEL)) == SCI_BUS_BSY))
printf("%s: dma eop\n", ncr_sc->sc_dev.dv_xname);
else if (((csr & ~SCI_CSR_PHASE_MATCH) == SCI_CSR_INT) &&
((bus_csr & ~SCI_BUS_RST) == 0))
printf("%s: bus reset\n", ncr_sc->sc_dev.dv_xname);
else if (((csr & ~(SCI_CSR_DREQ | SCI_CSR_ATN | SCI_CSR_ACK)) == (SCI_CSR_PERR | SCI_CSR_INT | SCI_CSR_PHASE_MATCH)) &&
((bus_csr & (SCI_BUS_RST | SCI_BUS_BSY | SCI_BUS_SEL)) == SCI_BUS_BSY))
printf("%s: parity error\n", ncr_sc->sc_dev.dv_xname);
else if (((csr & ~SCI_CSR_ATN) == SCI_CSR_INT) &&
((bus_csr & (SCI_BUS_RST | SCI_BUS_BSY | SCI_BUS_REQ | SCI_BUS_SEL)) == (SCI_BUS_BSY | SCI_BUS_REQ)))
printf("%s: phase mismatch\n", ncr_sc->sc_dev.dv_xname);
else if (((csr & ~SCI_CSR_PHASE_MATCH) == (SCI_CSR_INT | SCI_CSR_DISC)) &&
(bus_csr == 0))
printf("%s: disconnect\n", ncr_sc->sc_dev.dv_xname);
else
printf("%s: unknown intr: csr=%x, bus_csr=%x\n",
ncr_sc->sc_dev.dv_xname, csr, bus_csr);
}
#endif
/***
* The following code implements polled PDMA.
***/
static int
sbc_pdma_out(ncr_sc, phase, count, data)
struct ncr5380_softc *ncr_sc;
int phase;
int count;
u_char *data;
{
struct sbc_softc *sc = (struct sbc_softc *)ncr_sc;
register volatile long *long_data = (long *) sc->sc_drq_addr;
register volatile u_char *byte_data = (u_char *) sc->sc_nodrq_addr;
register int len = count;
if (count < ncr_sc->sc_min_dma_len || (sc->sc_options & SBC_PDMA) == 0)
return ncr5380_pio_out(ncr_sc, phase, count, data);
if (sbc_wait_busy(ncr_sc) == 0) {
*ncr_sc->sci_mode |= SCI_MODE_DMA;
*ncr_sc->sci_icmd |= SCI_ICMD_DATA;
*ncr_sc->sci_dma_send = 0;
#define W1 *byte_data = *data++
#define W4 *long_data = *((long*)data)++
while (len >= 64) {
if (sbc_ready(ncr_sc))
goto timeout;
W1;
if (sbc_ready(ncr_sc))
goto timeout;
W1;
if (sbc_ready(ncr_sc))
goto timeout;
W1;
if (sbc_ready(ncr_sc))
goto timeout;
W1;
if (sbc_ready(ncr_sc))
goto timeout;
W4; W4; W4; W4;
W4; W4; W4; W4;
W4; W4; W4; W4;
W4; W4; W4;
len -= 64;
}
while (len) {
if (sbc_ready(ncr_sc))
goto timeout;
W1;
len--;
}
#undef W1
#undef W4
if (sbc_wait_dreq(ncr_sc))
printf("%s: timeout waiting for DREQ.\n",
ncr_sc->sc_dev.dv_xname);
*byte_data = 0;
SCI_CLR_INTR(ncr_sc);
*ncr_sc->sci_mode &= ~SCI_MODE_DMA;
*ncr_sc->sci_icmd = 0;
}
return count - len;
timeout:
printf("%s: pdma_out: timeout len=%d count=%d\n",
ncr_sc->sc_dev.dv_xname, len, count);
if ((*ncr_sc->sci_csr & SCI_CSR_PHASE_MATCH) == 0) {
*ncr_sc->sci_icmd &= ~SCI_ICMD_DATA;
--len;
}
SCI_CLR_INTR(ncr_sc);
*ncr_sc->sci_mode &= ~SCI_MODE_DMA;
*ncr_sc->sci_icmd = 0;
return count - len;
}
static int
sbc_pdma_in(ncr_sc, phase, count, data)
struct ncr5380_softc *ncr_sc;
int phase;
int count;
u_char *data;
{
struct sbc_softc *sc = (struct sbc_softc *)ncr_sc;
register volatile long *long_data = (long *) sc->sc_drq_addr;
register volatile u_char *byte_data = (u_char *) sc->sc_nodrq_addr;
register int len = count;
if (count < ncr_sc->sc_min_dma_len || (sc->sc_options & SBC_PDMA) == 0)
return ncr5380_pio_in(ncr_sc, phase, count, data);
if (sbc_wait_busy(ncr_sc) == 0) {
*ncr_sc->sci_mode |= SCI_MODE_DMA;
*ncr_sc->sci_icmd |= SCI_ICMD_DATA;
*ncr_sc->sci_irecv = 0;
#define R4 *((long *)data)++ = *long_data
#define R1 *data++ = *byte_data
while (len >= 1024) {
if (sbc_ready(ncr_sc))
goto timeout;
R4; R4; R4; R4; R4; R4; R4; R4;
R4; R4; R4; R4; R4; R4; R4; R4;
R4; R4; R4; R4; R4; R4; R4; R4;
R4; R4; R4; R4; R4; R4; R4; R4; /* 128 */
if (sbc_ready(ncr_sc))
goto timeout;
R4; R4; R4; R4; R4; R4; R4; R4;
R4; R4; R4; R4; R4; R4; R4; R4;
R4; R4; R4; R4; R4; R4; R4; R4;
R4; R4; R4; R4; R4; R4; R4; R4; /* 256 */
if (sbc_ready(ncr_sc))
goto timeout;
R4; R4; R4; R4; R4; R4; R4; R4;
R4; R4; R4; R4; R4; R4; R4; R4;
R4; R4; R4; R4; R4; R4; R4; R4;
R4; R4; R4; R4; R4; R4; R4; R4; /* 384 */
if (sbc_ready(ncr_sc))
goto timeout;
R4; R4; R4; R4; R4; R4; R4; R4;
R4; R4; R4; R4; R4; R4; R4; R4;
R4; R4; R4; R4; R4; R4; R4; R4;
R4; R4; R4; R4; R4; R4; R4; R4; /* 512 */
if (sbc_ready(ncr_sc))
goto timeout;
R4; R4; R4; R4; R4; R4; R4; R4;
R4; R4; R4; R4; R4; R4; R4; R4;
R4; R4; R4; R4; R4; R4; R4; R4;
R4; R4; R4; R4; R4; R4; R4; R4; /* 640 */
if (sbc_ready(ncr_sc))
goto timeout;
R4; R4; R4; R4; R4; R4; R4; R4;
R4; R4; R4; R4; R4; R4; R4; R4;
R4; R4; R4; R4; R4; R4; R4; R4;
R4; R4; R4; R4; R4; R4; R4; R4; /* 768 */
if (sbc_ready(ncr_sc))
goto timeout;
R4; R4; R4; R4; R4; R4; R4; R4;
R4; R4; R4; R4; R4; R4; R4; R4;
R4; R4; R4; R4; R4; R4; R4; R4;
R4; R4; R4; R4; R4; R4; R4; R4; /* 896 */
if (sbc_ready(ncr_sc))
goto timeout;
R4; R4; R4; R4; R4; R4; R4; R4;
R4; R4; R4; R4; R4; R4; R4; R4;
R4; R4; R4; R4; R4; R4; R4; R4;
R4; R4; R4; R4; R4; R4; R4; R4; /* 1024 */
len -= 1024;
}
while (len >= 128) {
if (sbc_ready(ncr_sc))
goto timeout;
R4; R4; R4; R4; R4; R4; R4; R4;
R4; R4; R4; R4; R4; R4; R4; R4;
R4; R4; R4; R4; R4; R4; R4; R4;
R4; R4; R4; R4; R4; R4; R4; R4; /* 128 */
len -= 128;
}
while (len) {
if (sbc_ready(ncr_sc))
goto timeout;
R1;
len--;
}
#undef R4
#undef R1
SCI_CLR_INTR(ncr_sc);
*ncr_sc->sci_mode &= ~SCI_MODE_DMA;
*ncr_sc->sci_icmd = 0;
}
return count - len;
timeout:
printf("%s: pdma_in: timeout len=%d count=%d\n",
ncr_sc->sc_dev.dv_xname, len, count);
SCI_CLR_INTR(ncr_sc);
*ncr_sc->sci_mode &= ~SCI_MODE_DMA;
*ncr_sc->sci_icmd = 0;
return count - len;
}
/***
* The following code implements interrupt-driven PDMA.
***/
/*
* This is the meat of the PDMA transfer.
* When we get here, we shove data as fast as the mac can take it.
* We depend on several things:
* * All macs after the Mac Plus that have a 5380 chip should have a general
* logic IC that handshakes data for blind transfers.
* * If the SCSI controller finishes sending/receiving data before we do,
* the same general logic IC will generate a /BERR for us in short order.
* * The fault address for said /BERR minus the base address for the
* transfer will be the amount of data that was actually written.
*
* We use the nofault flag and the setjmp/longjmp in locore.s so we can
* detect and handle the bus error for early termination of a command.
* This is usually caused by a disconnecting target.
*/
void
sbc_drq_intr(p)
void *p;
{
extern int *nofault, mac68k_buserr_addr;
register struct sbc_softc *sc = (struct sbc_softc *) p;
register struct ncr5380_softc *ncr_sc = (struct ncr5380_softc *) p;
register struct sci_req *sr = ncr_sc->sc_current;
register struct sbc_pdma_handle *dh = sr->sr_dma_hand;
label_t faultbuf;
volatile u_int32_t *long_drq;
u_int32_t *long_data;
volatile u_int8_t *drq;
u_int8_t *data;
register int count;
int dcount, resid;
u_int8_t tmp;
/*
* If we're not ready to xfer data, or have no more, just return.
*/
if ((*ncr_sc->sci_csr & SCI_CSR_DREQ) == 0 || dh->dh_len == 0)
return;
#ifdef SBC_DEBUG
if (sbc_debug & SBC_DB_INTR)
printf("%s: drq intr, dh_len=0x%x, dh_flags=0x%x\n",
ncr_sc->sc_dev.dv_xname, dh->dh_len, dh->dh_flags);
#endif
/*
* Setup for a possible bus error caused by SCSI controller
* switching out of DATA-IN/OUT before we're done with the
* current transfer.
*/
nofault = (int *) &faultbuf;
if (setjmp((label_t *) nofault)) {
nofault = (int *) 0;
if ((dh->dh_flags & SBC_DH_DONE) == 0) {
count = (( (u_long) mac68k_buserr_addr
- (u_long) sc->sc_drq_addr));
if ((count < 0) || (count > dh->dh_len)) {
printf("%s: complete=0x%x (pending 0x%x)\n",
ncr_sc->sc_dev.dv_xname, count, dh->dh_len);
panic("something is wrong");
}
dh->dh_addr += count;
dh->dh_len -= count;
}
#ifdef SBC_DEBUG
if (sbc_debug & SBC_DB_INTR)
printf("%s: drq /berr, complete=0x%x (pending 0x%x)\n",
ncr_sc->sc_dev.dv_xname, count, dh->dh_len);
#endif
mac68k_buserr_addr = 0;
return;
}
if (dh->dh_flags & SBC_DH_OUT) { /* Data Out */
#if notyet /* XXX */
/*
* Get the source address aligned.
*/
resid =
count = min(dh->dh_len, 4 - (((int) dh->dh_addr) & 0x3));
if (count && count < 4) {
drq = (volatile u_int8_t *) sc->sc_drq_addr;
data = (u_int8_t *) dh->dh_addr;
#define W1 *drq++ = *data++
while (count) {
W1; count--;
}
#undef W1
dh->dh_addr += resid;
dh->dh_len -= resid;
}
/*
* Start the transfer.
*/
while (dh->dh_len) {
dcount = count = min(dh->dh_len, MAX_DMA_LEN);
long_drq = (volatile u_int32_t *) sc->sc_drq_addr;
long_data = (u_int32_t *) dh->dh_addr;
#define W4 *long_drq++ = *long_data++
while (count >= 64) {
W4; W4; W4; W4; W4; W4; W4; W4;
W4; W4; W4; W4; W4; W4; W4; W4; /* 64 */
count -= 64;
}
while (count >= 4) {
W4; count -= 4;
}
#undef W4
data = (u_int8_t *) long_data;
drq = (u_int8_t *) long_drq;
#else /* notyet */
/*
* Start the transfer.
*/
while (dh->dh_len) {
dcount = count = min(dh->dh_len, MAX_DMA_LEN);
drq = (volatile u_int8_t *) sc->sc_drq_addr;
data = (u_int8_t *) dh->dh_addr;
#endif /* notyet */
#define W1 *drq++ = *data++
while (count) {
W1; count--;
}
#undef W1
dh->dh_len -= dcount;
dh->dh_addr += dcount;
}
dh->dh_flags |= SBC_DH_DONE;
/*
* XXX -- Read a byte from the SBC to trigger a /BERR.
* This seems to be necessary for us to notice that
* the target has disconnected. Ick. 06 jun 1996 (sr)
*/
if (dcount >= MAX_DMA_LEN) {
#if 0
while ((*ncr_sc->sci_csr & SCI_CSR_ACK) == 0)
;
#endif
drq = (volatile u_int8_t *) sc->sc_drq_addr;
}
tmp = *drq;
} else { /* Data In */
/*
* Get the dest address aligned.
*/
resid =
count = min(dh->dh_len, 4 - (((int) dh->dh_addr) & 0x3));
if (count && count < 4) {
data = (u_int8_t *) dh->dh_addr;
drq = (volatile u_int8_t *) sc->sc_drq_addr;
#define R1 *data++ = *drq++
while (count) {
R1; count--;
}
#undef R1
dh->dh_addr += resid;
dh->dh_len -= resid;
}
/*
* Start the transfer.
*/
while (dh->dh_len) {
dcount = count = min(dh->dh_len, MAX_DMA_LEN);
long_data = (u_int32_t *) dh->dh_addr;
long_drq = (volatile u_int32_t *) sc->sc_drq_addr;
#define R4 *long_data++ = *long_drq++
while (count >= 64) {
R4; R4; R4; R4; R4; R4; R4; R4;
R4; R4; R4; R4; R4; R4; R4; R4; /* 64 */
count -= 64;
}
while (count >= 4) {
R4; count -= 4;
}
#undef R4
data = (u_int8_t *) long_data;
drq = (volatile u_int8_t *) long_drq;
#define R1 *data++ = *drq++
while (count) {
R1; count--;
}
#undef R1
dh->dh_len -= dcount;
dh->dh_addr += dcount;
}
dh->dh_flags |= SBC_DH_DONE;
}
/*
* OK. No bus error occurred above. Clear the nofault flag
* so we no longer short-circuit bus errors.
*/
nofault = (int *) 0;
#ifdef SBC_DEBUG
if (sbc_debug & (SBC_DB_REG | SBC_DB_INTR))
printf("%s: drq intr complete: csr=0x%x, bus_csr=0x%x\n",
ncr_sc->sc_dev.dv_xname, *ncr_sc->sci_csr,
*ncr_sc->sci_bus_csr);
#endif
}
void
sbc_dma_alloc(ncr_sc)
struct ncr5380_softc *ncr_sc;
{
struct sbc_softc *sc = (struct sbc_softc *) ncr_sc;
struct sci_req *sr = ncr_sc->sc_current;
struct scsi_xfer *xs = sr->sr_xs;
struct sbc_pdma_handle *dh;
int i, xlen;
#ifdef DIAGNOSTIC
if (sr->sr_dma_hand != NULL)
panic("sbc_dma_alloc: already have PDMA handle");
#endif
/* Polled transfers shouldn't allocate a PDMA handle. */
if (sr->sr_flags & SR_IMMED)
return;
xlen = ncr_sc->sc_datalen;
/* Make sure our caller checked sc_min_dma_len. */
if (xlen < MIN_DMA_LEN)
panic("sbc_dma_alloc: len=0x%x\n", xlen);
/*
* Find free PDMA handle. Guaranteed to find one since we
* have as many PDMA handles as the driver has processes.
* (instances?)
*/
for (i = 0; i < SCI_OPENINGS; i++) {
if ((sc->sc_pdma[i].dh_flags & SBC_DH_BUSY) == 0)
goto found;
}
panic("sbc: no free PDMA handles");
found:
dh = &sc->sc_pdma[i];
dh->dh_flags = SBC_DH_BUSY;
dh->dh_addr = ncr_sc->sc_dataptr;
dh->dh_len = xlen;
/* Copy the 'write' flag for convenience. */
if (xs->flags & SCSI_DATA_OUT)
dh->dh_flags |= SBC_DH_OUT;
sr->sr_dma_hand = dh;
}
void
sbc_dma_free(ncr_sc)
struct ncr5380_softc *ncr_sc;
{
struct sci_req *sr = ncr_sc->sc_current;
struct sbc_pdma_handle *dh = sr->sr_dma_hand;
#ifdef DIAGNOSTIC
if (sr->sr_dma_hand == NULL)
panic("sbc_dma_free: no DMA handle");
#endif
if (ncr_sc->sc_state & NCR_DOINGDMA)
panic("sbc_dma_free: free while in progress");
if (dh->dh_flags & SBC_DH_BUSY) {
dh->dh_flags = 0;
dh->dh_addr = NULL;
dh->dh_len = 0;
}
sr->sr_dma_hand = NULL;
}
void
sbc_dma_poll(ncr_sc)
struct ncr5380_softc *ncr_sc;
{
struct sci_req *sr = ncr_sc->sc_current;
/*
* We shouldn't arrive here; if SR_IMMED is set, then
* dma_alloc() should have refused to allocate a handle
* for the transfer. This forces the polled PDMA code
* to handle the request...
*/
#ifdef SBC_DEBUG
if (sbc_debug & SBC_DB_DMA)
printf("%s: lost DRQ interrupt?\n", ncr_sc->sc_dev.dv_xname);
#endif
sr->sr_flags |= SR_OVERDUE;
}
void
sbc_dma_setup(ncr_sc)
struct ncr5380_softc *ncr_sc;
{
/* Not needed; we don't have real DMA */
}
void
sbc_dma_start(ncr_sc)
struct ncr5380_softc *ncr_sc;
{
register struct sbc_softc *sc = (struct sbc_softc *) ncr_sc;
struct sci_req *sr = ncr_sc->sc_current;
struct sbc_pdma_handle *dh = sr->sr_dma_hand;
/*
* Match bus phase, clear pending interrupts, set DMA mode, and
* assert data bus (for writing only), then start the transfer.
*/
if (dh->dh_flags & SBC_DH_OUT) {
*ncr_sc->sci_tcmd = PHASE_DATA_OUT;
SCI_CLR_INTR(ncr_sc);
*sc->sc_iflag = 0x80 | (V2IF_SCSIIRQ | V2IF_SCSIDRQ);
*ncr_sc->sci_mode |= SCI_MODE_DMA;
*ncr_sc->sci_icmd = SCI_ICMD_DATA;
*ncr_sc->sci_dma_send = 0;
} else {
*ncr_sc->sci_tcmd = PHASE_DATA_IN;
SCI_CLR_INTR(ncr_sc);
*sc->sc_iflag = 0x80 | (V2IF_SCSIIRQ | V2IF_SCSIDRQ);
*ncr_sc->sci_mode |= SCI_MODE_DMA;
*ncr_sc->sci_icmd = 0;
*ncr_sc->sci_irecv = 0;
}
ncr_sc->sc_state |= NCR_DOINGDMA;
#ifdef SBC_DEBUG
if (sbc_debug & SBC_DB_DMA)
printf("%s: PDMA started, va=%p, len=0x%x\n",
ncr_sc->sc_dev.dv_xname, dh->dh_addr, dh->dh_len);
#endif
}
void
sbc_dma_eop(ncr_sc)
struct ncr5380_softc *ncr_sc;
{
/* Not used; the EOP pin is wired high (GMFH, pp. 389-390) */
}
void
sbc_dma_stop(ncr_sc)
struct ncr5380_softc *ncr_sc;
{
register struct sbc_softc *sc = (struct sbc_softc *) ncr_sc;
struct sci_req *sr = ncr_sc->sc_current;
struct sbc_pdma_handle *dh = sr->sr_dma_hand;
register int ntrans;
if ((ncr_sc->sc_state & NCR_DOINGDMA) == 0) {
#ifdef SBC_DEBUG
if (sbc_debug & SBC_DB_DMA)
printf("%s: dma_stop: DMA not running\n",
ncr_sc->sc_dev.dv_xname);
#endif
return;
}
ncr_sc->sc_state &= ~NCR_DOINGDMA;
if ((ncr_sc->sc_state & NCR_ABORTING) == 0) {
ntrans = ncr_sc->sc_datalen - dh->dh_len;
#ifdef SBC_DEBUG
if (sbc_debug & SBC_DB_DMA)
printf("%s: dma_stop: ntrans=0x%x\n",
ncr_sc->sc_dev.dv_xname, ntrans);
#endif
if (ntrans > ncr_sc->sc_datalen)
panic("sbc_dma_stop: excess transfer\n");
/* Adjust data pointer */
ncr_sc->sc_dataptr += ntrans;
ncr_sc->sc_datalen -= ntrans;
/* Clear any pending interrupts. */
SCI_CLR_INTR(ncr_sc);
*sc->sc_iflag = 0x80 | V2IF_SCSIIRQ;
}
/* Put SBIC back into PIO mode. */
*ncr_sc->sci_mode &= ~SCI_MODE_DMA;
*ncr_sc->sci_icmd = 0;
#ifdef SBC_DEBUG
if (sbc_debug & SBC_DB_REG)
printf("%s: dma_stop: csr=0x%x, bus_csr=0x%x\n",
ncr_sc->sc_dev.dv_xname, *ncr_sc->sci_csr,
*ncr_sc->sci_bus_csr);
#endif
}