freebsd-skq/sys/i386/isa/wd7000.c
bde 117209856b Don't include <sys/ioctl.h> in the kernel. Stage 1: don't include
it when it is not used.  In most cases, the reasons for including it
went away when the special ioctl headers became self-sufficient.
1997-03-24 11:25:10 +00:00

735 lines
15 KiB
C

/*
* Copyright (c) 1994 Ludd, University of Lule}, Sweden.
* All rights reserved.
*
* Written by Olof Johansson (offe@ludd.luth.se) 1995.
* Based on code written by Theo de Raadt (deraadt@fsa.ca).
*
* 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. All advertising materials mentioning features or use of this software
* must display the following acknowledgement:
* This product includes software developed at Ludd, University of Lule}.
* 4. The name of the author may not be used to endorse or promote products
* derived from this software without specific prior written permission
*
* THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``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 AUTHOR 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.
*/
/* All bugs are subject to removal without further notice */
/*
* offe 01/07/95
*
* This version of the driver _still_ doesn't implement scatter/gather for the
* WD7000-FASST2. This is due to the fact that my controller doesn't seem to
* support it. That, and the lack of documentation makes it impossible for
* me to implement it.
* What I've done instead is allocated a local buffer, contiguous buffer big
* enough to handle the requests. I haven't seen any read/write bigger than 64k,
* so I allocate a buffer of 64+16k. The data that needs to be DMA'd to/from
* the controller is copied to/from that buffer before/after the command is
* sent to the card.
*/
#include "wds.h"
#if NWDS > 0
#include <sys/types.h>
#include <sys/param.h>
#include <sys/systm.h>
#include <sys/errno.h>
#include <sys/buf.h>
#include <sys/proc.h>
#include <sys/dkbad.h>
#include <sys/disklabel.h>
#include <scsi/scsi_all.h>
#include <scsi/scsiconf.h>
#include <machine/clock.h>
#include <vm/vm.h>
#include <vm/vm_param.h>
#include <vm/pmap.h>
#include <i386/isa/isa_device.h>
#include "ioconf.h"
static struct scsi_device wds_dev =
{
NULL,
NULL,
NULL,
NULL,
"wds",
0,
{ 0, 0 }
};
/*
XXX THIS SHOULD BE FIXED!
I haven't got the KERNBASE-version to work, but on my system the kernel
is at virtual address 0xFxxxxxxx, responding to physical address
0x0xxxxxxx.
#define PHYSTOKV(x) ((x) + KERNBASE)
*/
#define PHYSTOKV(x) ((x) | 0xf0000000)
#define KVTOPHYS(x) vtophys(x)
/* 0x10000 (64k) should be enough. But just to be sure... */
#define BUFSIZ 0x12000
/* WD7000 registers */
#define WDS_STAT 0 /* read */
#define WDS_IRQSTAT 1 /* read */
#define WDS_CMD 0 /* write */
#define WDS_IRQACK 1 /* write */
#define WDS_HCR 2 /* write */
/* WDS_STAT (read) defs */
#define WDS_IRQ 0x80
#define WDS_RDY 0x40
#define WDS_REJ 0x20
#define WDS_INIT 0x10
/* WDS_IRQSTAT (read) defs */
#define WDSI_MASK 0xc0
#define WDSI_ERR 0x00
#define WDSI_MFREE 0x80
#define WDSI_MSVC 0xc0
/* WDS_CMD (write) defs */
#define WDSC_NOOP 0x00
#define WDSC_INIT 0x01
#define WDSC_DISUNSOL 0x02
#define WDSC_ENAUNSOL 0x03
#define WDSC_IRQMFREE 0x04
#define WDSC_SCSIRESETSOFT 0x05
#define WDSC_SCSIRESETHARD 0x06
#define WDSC_MSTART(m) (0x80 + (m))
#define WDSC_MMSTART(m) (0xc0 + (m))
/* WDS_HCR (write) defs */
#define WDSH_IRQEN 0x08
#define WDSH_DRQEN 0x04
#define WDSH_SCSIRESET 0x02
#define WDSH_ASCRESET 0x01
struct wds_cmd {
u_char cmd;
u_char targ;
u_char scb[12]; /*u_char scb[12];*/
u_char stat;
u_char venderr;
u_char len[3];
u_char data[3];
u_char next[3];
u_char write;
u_char xx[6];
};
struct wds_req {
struct wds_cmd cmd;
struct wds_cmd sense;
struct scsi_xfer *sxp;
int busy, polled;
int done, ret, ombn;
};
#define WDSX_SCSICMD 0x00
#define WDSX_OPEN_RCVBUF 0x80
#define WDSX_RCV_CMD 0x81
#define WDSX_RCV_DATA 0x82
#define WDSX_RCV_DATASTAT 0x83
#define WDSX_SND_DATA 0x84
#define WDSX_SND_DATASTAT 0x85
#define WDSX_SND_CMDSTAT 0x86
#define WDSX_READINIT 0x88
#define WDSX_READSCSIID 0x89
#define WDSX_SETUNSOLIRQMASK 0x8a
#define WDSX_GETUNSOLIRQMASK 0x8b
#define WDSX_GETFIRMREV 0x8c
#define WDSX_EXECDIAG 0x8d
#define WDSX_SETEXECPARM 0x8e
#define WDSX_GETEXECPARM 0x8f
struct wds_mb {
u_char stat;
u_char addr[3];
};
/* ICMB status value */
#define ICMB_OK 0x01
#define ICMB_OKERR 0x02
#define ICMB_ETIME 0x04
#define ICMB_ERESET 0x05
#define ICMB_ETARCMD 0x06
#define ICMB_ERESEL 0x80
#define ICMB_ESEL 0x81
#define ICMB_EABORT 0x82
#define ICMB_ESRESET 0x83
#define ICMB_EHRESET 0x84
struct wds_setup {
u_char cmd;
u_char scsi_id;
u_char buson_t;
u_char busoff_t;
u_char xx;
u_char mbaddr[3];
u_char nomb;
u_char nimb;
};
#define WDS_NOMB 8
#define WDS_NIMB 8
#define MAXSIMUL 8
static int wdsunit=0;
static u_char wds_data[NWDS][BUFSIZ];
static u_char wds_data_in_use[NWDS];
static struct wds {
int addr;
struct wds_req wdsr[MAXSIMUL];
struct wds_mb ombs[WDS_NOMB], imbs[WDS_NIMB];
struct scsi_link sc_link;
} wds[NWDS];
static int wdsprobe(struct isa_device *);
static void wds_minphys(struct buf *);
static struct wds_req *wdsr_alloc(int);
static int32_t wds_scsi_cmd(struct scsi_xfer *);
static u_int32_t wds_adapter_info(int);
static int wds_done(int, struct wds_cmd *, u_char);
static int wdsattach(struct isa_device *);
static int wds_init(struct isa_device *);
static int wds_cmd(int, u_char *, int);
static void wds_wait(int, int, int);
struct isa_driver wdsdriver =
{
wdsprobe,
wdsattach,
"wds"
};
static struct scsi_adapter wds_switch =
{
wds_scsi_cmd,
wds_minphys,
0,
0,
wds_adapter_info,
"wds",
{0,0}
};
int
wdsprobe(struct isa_device *dev)
{
if(wdsunit > NWDS)
return 0;
dev->id_unit = wdsunit; /* XXX WRONG! */
wds[wdsunit].addr = dev->id_iobase;
if(wds_init(dev) != 0)
return 0;
wdsunit++;
return 8;
}
void
wds_minphys(struct buf *bp)
{
if(bp->b_bcount > BUFSIZ)
bp->b_bcount = BUFSIZ;
}
struct wds_req *
wdsr_alloc(int unit)
{
struct wds_req *r;
int x;
int i;
r = NULL;
x = splbio();
for(i=0; i<MAXSIMUL; i++)
if(!wds[unit].wdsr[i].busy)
{
r = &wds[unit].wdsr[i];
r->busy = 1;
break;
}
if(!r)
{
splx(x);
return NULL;
}
r->ombn = -1;
for(i=0; i<WDS_NOMB; i++)
if(!wds[unit].ombs[i].stat)
{
wds[unit].ombs[i].stat = 1;
r->ombn = i;
break;
}
if(r->ombn == -1 )
{
r->busy = 0;
splx(x);
return NULL;
}
splx(x);
return r;
}
int32_t
wds_scsi_cmd(struct scsi_xfer *sxp)
{
struct wds_req *r;
int unit = sxp->sc_link->adapter_unit;
int base;
u_char c;
int i;
base = wds[unit].addr;
if( sxp->flags & SCSI_RESET)
{
printf("reset!\n");
return COMPLETE;
}
r = wdsr_alloc(unit);
if(r==NULL)
{
printf("no request slot available!\n");
sxp->error = XS_DRIVER_STUFFUP;
return TRY_AGAIN_LATER;
}
r->done = 0;
r->sxp = sxp;
if(sxp->flags & SCSI_DATA_UIO)
{
printf("UIO!\n");
sxp->error = XS_DRIVER_STUFFUP;
return TRY_AGAIN_LATER;
}
scsi_uto3b(KVTOPHYS(&r->cmd),wds[unit].ombs[r->ombn].addr);
bzero(&r->cmd, sizeof r->cmd);
r->cmd.cmd = WDSX_SCSICMD;
r->cmd.targ = (sxp->sc_link->target << 5) | sxp->sc_link->lun;
bcopy(sxp->cmd, &r->cmd.scb, sxp->cmdlen<12 ? sxp->cmdlen : 12);
scsi_uto3b(sxp->datalen, r->cmd.len);
if(wds_data_in_use[unit])
{
sxp->error = XS_DRIVER_STUFFUP;
return TRY_AGAIN_LATER;
}
else
wds_data_in_use[unit] = 1;
if(sxp->datalen && !(sxp->flags&SCSI_DATA_IN))
bcopy(sxp->data, wds_data[unit], sxp->datalen);
scsi_uto3b(sxp->datalen ? KVTOPHYS(wds_data[unit]) : 0, r->cmd.data);
r->cmd.write = (sxp->flags&SCSI_DATA_IN)? 0x80 : 0x00;
scsi_uto3b(KVTOPHYS(&r->sense),r->cmd.next);
bzero(&r->sense, sizeof r->sense);
r->sense.cmd = r->cmd.cmd;
r->sense.targ = r->cmd.targ;
r->sense.scb[0] = REQUEST_SENSE;
scsi_uto3b(KVTOPHYS(&sxp->sense),r->sense.data);
scsi_uto3b(sizeof(sxp->sense), r->sense.len);
r->sense.write = 0x80;
if(sxp->flags & SCSI_NOMASK)
{
outb(base+WDS_HCR, WDSH_DRQEN);
r->polled = 1;
} else
{
outb(base+WDS_HCR, WDSH_IRQEN|WDSH_DRQEN);
r->polled = 0;
}
c = WDSC_MSTART(r->ombn);
if( wds_cmd(base, &c, sizeof c) != 0)
{
printf("wds%d: unable to start outgoing mbox\n", unit);
r->busy = 0;
wds[unit].ombs[r->ombn].stat = 0;
return TRY_AGAIN_LATER;
}
if(sxp->flags & SCSI_NOMASK)
{
repoll:
i = 0;
while(!(inb(base+WDS_STAT) & WDS_IRQ))
{
DELAY(20000);
if(++i == 20)
{
outb(base + WDS_IRQACK, 0);
/*r->busy = 0;*/
sxp->error = XS_TIMEOUT;
return HAD_ERROR;
}
}
wdsintr(unit);
if(r->done)
{
r->sxp->flags |= ITSDONE;
r->busy = 0;
return r->ret;
}
goto repoll;
}
return SUCCESSFULLY_QUEUED;
}
u_int32_t
wds_adapter_info(int unit)
{
return 1;
}
void
wdsintr(int unit)
{
struct wds_cmd *pc, *vc;
struct wds_mb *in;
u_char stat;
u_char c;
if(!inb(wds[unit].addr+WDS_STAT) & WDS_IRQ)
{
outb(wds[unit].addr + WDS_IRQACK, 0);
return;
}
c = inb(wds[unit].addr + WDS_IRQSTAT);
if( (c&WDSI_MASK) == WDSI_MSVC)
{
c = c & ~WDSI_MASK;
in = &wds[unit].imbs[c];
pc = (struct wds_cmd *)scsi_3btou(in->addr);
vc = (struct wds_cmd *)PHYSTOKV((long)pc);
stat = in->stat;
wds_done(unit, vc, stat);
in->stat = 0;
outb(wds[unit].addr + WDS_IRQACK, 0);
}
}
int
wds_done(int unit, struct wds_cmd *c, u_char stat)
{
struct wds_req *r;
int i;
r = (struct wds_req *)NULL;
for(i=0; i<MAXSIMUL; i++)
if( c == &wds[unit].wdsr[i].cmd && !wds[unit].wdsr[i].done)
{
r = &wds[unit].wdsr[i];
break;
}
if(r == (struct wds_req *)NULL)
{
/* failed to find request! */
return 1;
}
r->done = 1;
wds[unit].ombs[r->ombn].stat = 0;
r->ret = HAD_ERROR;
switch(stat)
{
case ICMB_OK:
r->ret = COMPLETE;
if(r->sxp)
r->sxp->resid = 0;
break;
case ICMB_OKERR:
if(!(r->sxp->flags & SCSI_ERR_OK) && c->stat)
{
r->sxp->sense.error_code = c->venderr;
r->sxp->error=XS_SENSE;
}
else
r->sxp->error=XS_NOERROR;
r->ret = COMPLETE;
break;
case ICMB_ETIME:
r->sxp->error = XS_TIMEOUT;
r->ret = HAD_ERROR;
break;
case ICMB_ERESET:
case ICMB_ETARCMD:
case ICMB_ERESEL:
case ICMB_ESEL:
case ICMB_EABORT:
case ICMB_ESRESET:
case ICMB_EHRESET:
r->sxp->error = XS_DRIVER_STUFFUP;
r->ret = HAD_ERROR;
break;
}
if(r->sxp)
if(r->sxp->datalen && (r->sxp->flags&SCSI_DATA_IN))
bcopy(wds_data[unit],r->sxp->data,r->sxp->datalen);
wds_data_in_use[unit] = 0;
if(!r->polled)
{
r->sxp->flags |= ITSDONE;
scsi_done(r->sxp);
}
r->busy = 0;
return 0;
}
static int
wds_getvers(int unit)
{
struct wds_req *r;
int base;
u_char c;
int i;
base = wds[unit].addr;
r = wdsr_alloc(unit);
if(!r)
{
printf("wds%d: no request slot available!\n", unit);
return -1;
}
r->done = 0;
r->sxp = NULL;
scsi_uto3b(KVTOPHYS(&r->cmd), wds[unit].ombs[r->ombn].addr);
bzero(&r->cmd, sizeof r->cmd);
r->cmd.cmd = WDSX_GETFIRMREV;
outb(base+WDS_HCR, WDSH_DRQEN);
r->polled = 1;
c = WDSC_MSTART(r->ombn);
if(wds_cmd(base, (u_char *)&c, sizeof c))
{
printf("wds%d: version request failed\n", unit);
r->busy = 0;
wds[unit].ombs[r->ombn].stat = 0;
return -1;
}
while(1)
{
i = 0;
while( (inb(base+WDS_STAT) & WDS_IRQ) == 0)
{
DELAY(9000);
if(++i == 20)
return -1;
}
wdsintr(unit);
if(r->done)
{
printf("wds%d: firmware version %d.%02d\n", unit,
r->cmd.targ, r->cmd.scb[0]);
r->busy = 0;
return 0;
}
}
}
int
wdsattach(struct isa_device *dev)
{
int masunit;
static u_long versprobe=0; /* max 32 controllers */
int unit = dev->id_unit;
struct scsibus_data *scbus;
masunit = dev->id_unit;
if( !(versprobe & (1<<masunit)))
{
versprobe |= (1<<masunit);
if(wds_getvers(masunit)==-1)
printf("wds%d: getvers failed\n", masunit);
}
printf("wds%d: using %d bytes for dma buffer\n",unit,BUFSIZ);
wds[unit].sc_link.adapter_unit = unit;
wds[unit].sc_link.adapter_targ = 7;
wds[unit].sc_link.adapter = &wds_switch;
wds[unit].sc_link.device = &wds_dev;
wds[unit].sc_link.flags = SDEV_BOUNCE;
/*
* Prepare the scsibus_data area for the upperlevel
* scsi code.
*/
scbus = scsi_alloc_bus();
if(!scbus)
return 0;
scbus->adapter_link = &wds[unit].sc_link;
scsi_attachdevs(scbus);
return 1;
}
int
wds_init(struct isa_device *dev)
{
struct wds_setup init;
int base;
int unit, i;
struct wds_cmd wc;
unit = dev->id_unit;
base = wds[unit].addr;
/*
* Sending a command causes the CMDRDY bit to clear.
*/
outb(base+WDS_CMD, WDSC_NOOP);
if( inb(base+WDS_STAT) & WDS_RDY)
return 1;
/*
* the controller exists. reset and init.
*/
outb(base+WDS_HCR, WDSH_ASCRESET|WDSH_SCSIRESET);
DELAY(30);
outb(base+WDS_HCR, 0);
outb(base+WDS_HCR, WDSH_DRQEN);
isa_dmacascade(dev->id_drq);
if( (inb(base+WDS_STAT) & (WDS_RDY)) != WDS_RDY)
{
for(i=0; i<10; i++)
{
if( (inb(base+WDS_STAT) & (WDS_RDY)) == WDS_RDY)
break;
DELAY(40000);
}
if( (inb(base+WDS_STAT) & (WDS_RDY)) != WDS_RDY) /* probe timeout */
return 1;
}
bzero(&init, sizeof init);
init.cmd = WDSC_INIT;
init.scsi_id = 7;
init.buson_t = 24;
init.busoff_t = 48;
scsi_uto3b(KVTOPHYS(wds[unit].ombs), init.mbaddr);
init.xx = 0;
init.nomb = WDS_NOMB;
init.nimb = WDS_NIMB;
wds_wait(base+WDS_STAT, WDS_RDY, WDS_RDY);
if( wds_cmd(base, (u_char *)&init, sizeof init) != 0)
{
printf("wds%d: wds_cmd failed\n", unit);
return 1;
}
wds_wait(base+WDS_STAT, WDS_INIT, WDS_INIT);
wds_wait(base+WDS_STAT, WDS_RDY, WDS_RDY);
bzero(&wc,sizeof wc);
wc.cmd = WDSC_DISUNSOL;
if( wds_cmd(base, (char *)&wc, sizeof wc) != 0)
{
printf("wds%d: wds_cmd failed\n", unit);
return 1;
}
return 0;
}
int
wds_cmd(int base, u_char *p, int l)
{
int s=splbio();
while(l--)
{
do
{
outb(base+WDS_CMD,*p);
wds_wait(base+WDS_STAT,WDS_RDY,WDS_RDY);
} while (inb(base+WDS_STAT) & WDS_REJ);
p++;
}
wds_wait(base+WDS_STAT,WDS_RDY,WDS_RDY);
splx(s);
return 0;
}
void
wds_wait(int reg, int mask, int val)
{
while((inb(reg) & mask) != val);
}
#endif