freebsd-skq/sys/amd64/isa/isa.c
David Greenman 2838c9682a Implemented a (sorely needed for years) double fault handler to catch stack
overflows.
It sure would be nice if there was an unmapped page between the PCB and
the stack (and that the size of the stack was configurable!). With the
way things are now, the PCB will get clobbered before the double fault
handler gets control, making somewhat of a mess of things. Despite this,
it is still fairly easy to poke around in the overflowed stack to figure
out the cause.
1995-12-19 14:30:50 +00:00

991 lines
27 KiB
C

/*-
* Copyright (c) 1991 The Regents of the University of California.
* All rights reserved.
*
* This code is derived from software contributed to Berkeley by
* William Jolitz.
*
* 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 by the University of
* California, Berkeley and its contributors.
* 4. Neither the name of the University nor the names of its contributors
* may be used to endorse or promote products derived from this software
* without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS ``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 REGENTS OR CONTRIBUTORS 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.
*
* from: @(#)isa.c 7.2 (Berkeley) 5/13/91
* $Id: isa.c,v 1.58 1995/12/07 12:46:01 davidg Exp $
*/
/*
* code to manage AT bus
*
* 92/08/18 Frank P. MacLachlan (fpm@crash.cts.com):
* Fixed uninitialized variable problem and added code to deal
* with DMA page boundaries in isa_dmarangecheck(). Fixed word
* mode DMA count compution and reorganized DMA setup code in
* isa_dmastart()
*/
#include <sys/param.h>
#include <sys/systm.h> /* isn't it a joy */
#include <sys/kernel.h> /* to have three of these */
#include <sys/sysctl.h>
#include <sys/proc.h>
#include <sys/conf.h>
#include <sys/file.h>
#include <sys/buf.h>
#include <sys/uio.h>
#include <sys/syslog.h>
#include <sys/malloc.h>
#include <sys/rlist.h>
#include <machine/segments.h>
#include <vm/vm.h>
#include <vm/vm_param.h>
#include <vm/pmap.h>
#include <machine/spl.h>
#include <machine/cpu.h>
#include <i386/isa/isa_device.h>
#include <i386/isa/isa.h>
#include <i386/isa/icu.h>
#include <i386/isa/ic/i8237.h>
#include <i386/isa/ic/i8042.h>
#include <sys/devconf.h>
#include "vector.h"
/*
** Register definitions for DMA controller 1 (channels 0..3):
*/
#define DMA1_CHN(c) (IO_DMA1 + 1*(2*(c))) /* addr reg for channel c */
#define DMA1_SMSK (IO_DMA1 + 1*10) /* single mask register */
#define DMA1_MODE (IO_DMA1 + 1*11) /* mode register */
#define DMA1_FFC (IO_DMA1 + 1*12) /* clear first/last FF */
/*
** Register definitions for DMA controller 2 (channels 4..7):
*/
#define DMA2_CHN(c) (IO_DMA2 + 2*(2*(c))) /* addr reg for channel c */
#define DMA2_SMSK (IO_DMA2 + 2*10) /* single mask register */
#define DMA2_MODE (IO_DMA2 + 2*11) /* mode register */
#define DMA2_FFC (IO_DMA2 + 2*12) /* clear first/last FF */
/*
* XXX these defines should be in a central place.
*/
#define read_eflags() ({u_long ef; \
__asm("pushfl; popl %0" : "=a" (ef)); \
ef; })
#define write_eflags(ef) __asm("pushl %0; popfl" : : "a" ((u_long)(ef)))
u_long *intr_countp[ICU_LEN];
inthand2_t *intr_handler[ICU_LEN];
u_int intr_mask[ICU_LEN];
u_int* intr_mptr[ICU_LEN];
int intr_unit[ICU_LEN];
extern struct kern_devconf kdc_cpu0;
struct kern_devconf kdc_isa0 = {
0, 0, 0, /* filled in by dev_attach */
"isa", 0, { MDDT_BUS, 0 },
0, 0, 0, BUS_EXTERNALLEN,
&kdc_cpu0, /* parent is the CPU */
0, /* no parentdata */
DC_BUSY, /* busses are always busy */
"ISA or EISA bus",
DC_CLS_BUS /* class */
};
static inthand_t *fastintr[ICU_LEN] = {
&IDTVEC(fastintr0), &IDTVEC(fastintr1),
&IDTVEC(fastintr2), &IDTVEC(fastintr3),
&IDTVEC(fastintr4), &IDTVEC(fastintr5),
&IDTVEC(fastintr6), &IDTVEC(fastintr7),
&IDTVEC(fastintr8), &IDTVEC(fastintr9),
&IDTVEC(fastintr10), &IDTVEC(fastintr11),
&IDTVEC(fastintr12), &IDTVEC(fastintr13),
&IDTVEC(fastintr14), &IDTVEC(fastintr15)
};
static inthand_t *slowintr[ICU_LEN] = {
&IDTVEC(intr0), &IDTVEC(intr1), &IDTVEC(intr2), &IDTVEC(intr3),
&IDTVEC(intr4), &IDTVEC(intr5), &IDTVEC(intr6), &IDTVEC(intr7),
&IDTVEC(intr8), &IDTVEC(intr9), &IDTVEC(intr10), &IDTVEC(intr11),
&IDTVEC(intr12), &IDTVEC(intr13), &IDTVEC(intr14), &IDTVEC(intr15)
};
static void config_isadev __P((struct isa_device *isdp, u_int *mp));
static void config_isadev_c __P((struct isa_device *isdp, u_int *mp,
int reconfig));
static void conflict __P((struct isa_device *dvp, struct isa_device *tmpdvp,
int item, char const *whatnot, char const *reason,
char const *format));
static int haveseen __P((struct isa_device *dvp, struct isa_device *tmpdvp,
u_int checkbits));
static inthand2_t isa_strayintr;
static void register_imask __P((struct isa_device *dvp, u_int mask));
/*
* print a conflict message
*/
static void
conflict(dvp, tmpdvp, item, whatnot, reason, format)
struct isa_device *dvp;
struct isa_device *tmpdvp;
int item;
char const *whatnot;
char const *reason;
char const *format;
{
printf("%s%d not %sed due to %s conflict with %s%d at ",
dvp->id_driver->name, dvp->id_unit, whatnot, reason,
tmpdvp->id_driver->name, tmpdvp->id_unit);
printf(format, item);
printf("\n");
}
/*
* Check to see if things are already in use, like IRQ's, I/O addresses
* and Memory addresses.
*/
static int
haveseen(dvp, tmpdvp, checkbits)
struct isa_device *dvp;
struct isa_device *tmpdvp;
u_int checkbits;
{
/*
* Only check against devices that have already been found and are not
* unilaterally allowed to conflict anyway.
*/
if (tmpdvp->id_alive && !dvp->id_conflicts) {
char const *whatnot;
whatnot = checkbits & CC_ATTACH ? "attach" : "prob";
/*
* Check for I/O address conflict. We can only check the
* starting address of the device against the range of the
* device that has already been probed since we do not
* know how many I/O addresses this device uses.
*/
if (checkbits & CC_IOADDR && tmpdvp->id_alive != -1) {
if ((dvp->id_iobase >= tmpdvp->id_iobase) &&
(dvp->id_iobase <=
(tmpdvp->id_iobase + tmpdvp->id_alive - 1))) {
conflict(dvp, tmpdvp, dvp->id_iobase, whatnot,
"I/O address", "0x%x");
return 1;
}
}
/*
* Check for Memory address conflict. We can check for
* range overlap, but it will not catch all cases since the
* driver may adjust the msize paramater during probe, for
* now we just check that the starting address does not
* fall within any allocated region.
* XXX could add a second check after the probe for overlap,
* since at that time we would know the full range.
* XXX KERNBASE is a hack, we should have vaddr in the table!
*/
if (checkbits & CC_MEMADDR && tmpdvp->id_maddr) {
if ((KERNBASE + dvp->id_maddr >= tmpdvp->id_maddr) &&
(KERNBASE + dvp->id_maddr <=
(tmpdvp->id_maddr + tmpdvp->id_msize - 1))) {
conflict(dvp, tmpdvp, (int)dvp->id_maddr,
whatnot, "maddr", "0x%x");
return 1;
}
}
/*
* Check for IRQ conflicts.
*/
if (checkbits & CC_IRQ && tmpdvp->id_irq) {
if (tmpdvp->id_irq == dvp->id_irq) {
conflict(dvp, tmpdvp, ffs(dvp->id_irq) - 1,
whatnot, "irq", "%d");
return 1;
}
}
/*
* Check for DRQ conflicts.
*/
if (checkbits & CC_DRQ && tmpdvp->id_drq != -1) {
if (tmpdvp->id_drq == dvp->id_drq) {
conflict(dvp, tmpdvp, dvp->id_drq, whatnot,
"drq", "%d");
return 1;
}
}
}
return 0;
}
/*
* Search through all the isa_devtab_* tables looking for anything that
* conflicts with the current device.
*/
int
haveseen_isadev(dvp, checkbits)
struct isa_device *dvp;
u_int checkbits;
{
struct isa_device *tmpdvp;
int status = 0;
for (tmpdvp = isa_devtab_tty; tmpdvp->id_driver; tmpdvp++) {
status |= haveseen(dvp, tmpdvp, checkbits);
if (status)
return status;
}
for (tmpdvp = isa_devtab_bio; tmpdvp->id_driver; tmpdvp++) {
status |= haveseen(dvp, tmpdvp, checkbits);
if (status)
return status;
}
for (tmpdvp = isa_devtab_net; tmpdvp->id_driver; tmpdvp++) {
status |= haveseen(dvp, tmpdvp, checkbits);
if (status)
return status;
}
for (tmpdvp = isa_devtab_null; tmpdvp->id_driver; tmpdvp++) {
status |= haveseen(dvp, tmpdvp, checkbits);
if (status)
return status;
}
return(status);
}
/*
* Configure all ISA devices
*/
void
isa_configure() {
struct isa_device *dvp;
dev_attach(&kdc_isa0);
splhigh();
enable_intr();
INTREN(IRQ_SLAVE);
printf("Probing for devices on the ISA bus:\n");
/* First probe all the sensitive probes */
for (dvp = isa_devtab_tty; dvp->id_driver; dvp++)
if (dvp->id_driver->sensitive_hw)
config_isadev(dvp, &tty_imask);
for (dvp = isa_devtab_bio; dvp->id_driver; dvp++)
if (dvp->id_driver->sensitive_hw)
config_isadev(dvp, &bio_imask);
for (dvp = isa_devtab_net; dvp->id_driver; dvp++)
if (dvp->id_driver->sensitive_hw)
config_isadev(dvp, &net_imask);
for (dvp = isa_devtab_null; dvp->id_driver; dvp++)
if (dvp->id_driver->sensitive_hw)
config_isadev(dvp, (u_int *)NULL);
/* Then all the bad ones */
for (dvp = isa_devtab_tty; dvp->id_driver; dvp++)
if (!dvp->id_driver->sensitive_hw)
config_isadev(dvp, &tty_imask);
for (dvp = isa_devtab_bio; dvp->id_driver; dvp++)
if (!dvp->id_driver->sensitive_hw)
config_isadev(dvp, &bio_imask);
for (dvp = isa_devtab_net; dvp->id_driver; dvp++)
if (!dvp->id_driver->sensitive_hw)
config_isadev(dvp, &net_imask);
for (dvp = isa_devtab_null; dvp->id_driver; dvp++)
if (!dvp->id_driver->sensitive_hw)
config_isadev(dvp, (u_int *)NULL);
bio_imask |= SWI_CLOCK_MASK;
net_imask |= SWI_NET_MASK;
tty_imask |= SWI_TTY_MASK;
/*
* XXX we should really add the tty device to net_imask when the line is
* switched to SLIPDISC, and then remove it when it is switched away from
* SLIPDISC. No need to block out ALL ttys during a splimp when only one
* of them is running slip.
*
* XXX actually, blocking all ttys during a splimp doesn't matter so much
* with sio because the serial interrupt layer doesn't use tty_imask. Only
* non-serial ttys suffer. It's more stupid that ALL 'net's are blocked
* during spltty.
*/
#include "sl.h"
#include "ppp.h"
#if (NSL > 0)
net_imask |= tty_imask;
tty_imask = net_imask;
#endif
/* bio_imask |= tty_imask ; can some tty devices use buffers? */
if (bootverbose)
printf("imasks: bio %x, tty %x, net %x\n",
bio_imask, tty_imask, net_imask);
/*
* Finish initializing intr_mask[]. Note that the partly
* constructed masks aren't actually used since we're at splhigh.
* For fully dynamic initialization, register_intr() and
* unregister_intr() will have to adjust the masks for _all_
* interrupts and for tty_imask, etc.
*/
for (dvp = isa_devtab_tty; dvp->id_driver; dvp++)
register_imask(dvp, tty_imask);
for (dvp = isa_devtab_bio; dvp->id_driver; dvp++)
register_imask(dvp, bio_imask);
for (dvp = isa_devtab_net; dvp->id_driver; dvp++)
register_imask(dvp, net_imask);
for (dvp = isa_devtab_null; dvp->id_driver; dvp++)
register_imask(dvp, SWI_CLOCK_MASK);
spl0();
}
/*
* Configure an ISA device.
*/
static void
config_isadev(isdp, mp)
struct isa_device *isdp;
u_int *mp;
{
config_isadev_c(isdp, mp, 0);
}
void
reconfig_isadev(isdp, mp)
struct isa_device *isdp;
u_int *mp;
{
config_isadev_c(isdp, mp, 1);
}
static void
config_isadev_c(isdp, mp, reconfig)
struct isa_device *isdp;
u_int *mp;
int reconfig;
{
u_int checkbits;
int id_alive;
int last_alive;
struct isa_driver *dp = isdp->id_driver;
checkbits = 0;
checkbits |= CC_DRQ;
checkbits |= CC_IOADDR;
checkbits |= CC_MEMADDR;
if (!isdp->id_enabled) {
printf("%s%d: disabled, not probed.\n",
dp->name, isdp->id_unit);
return;
}
if (!reconfig && haveseen_isadev(isdp, checkbits))
return;
if (!reconfig && isdp->id_maddr) {
isdp->id_maddr -= 0xa0000; /* XXX should be a define */
isdp->id_maddr += atdevbase;
}
if (reconfig) {
last_alive = isdp->id_alive;
isdp->id_reconfig = 1;
}
else {
last_alive = 0;
isdp->id_reconfig = 0;
}
id_alive = (*dp->probe)(isdp);
if (id_alive) {
/*
* Only print the I/O address range if id_alive != -1
* Right now this is a temporary fix just for the new
* NPX code so that if it finds a 486 that can use trap
* 16 it will not report I/O addresses.
* Rod Grimes 04/26/94
*/
if (!isdp->id_reconfig) {
printf("%s%d", dp->name, isdp->id_unit);
if (id_alive != -1) {
printf(" at 0x%x", isdp->id_iobase);
if ((isdp->id_iobase + id_alive - 1) !=
isdp->id_iobase) {
printf("-0x%x",
isdp->id_iobase + id_alive - 1);
}
}
if (isdp->id_irq)
printf(" irq %d", ffs(isdp->id_irq) - 1);
if (isdp->id_drq != -1)
printf(" drq %d", isdp->id_drq);
if (isdp->id_maddr)
printf(" maddr 0x%lx", kvtop(isdp->id_maddr));
if (isdp->id_msize)
printf(" msize %d", isdp->id_msize);
if (isdp->id_flags)
printf(" flags 0x%x", isdp->id_flags);
if (isdp->id_iobase && !(isdp->id_iobase & 0xf300)) {
printf(" on motherboard");
} else if (isdp->id_iobase >= 0x1000 &&
!(isdp->id_iobase & 0x300)) {
printf (" on eisa slot %d",
isdp->id_iobase >> 12);
} else {
printf (" on isa");
}
printf("\n");
/*
* Check for conflicts again. The driver may have
* changed *dvp. We should weaken the early check
* since the driver may have been able to change
* *dvp to avoid conflicts if given a chance. We
* already skip the early check for IRQs and force
* a check for IRQs in the next group of checks.
*/
checkbits |= CC_IRQ;
if (haveseen_isadev(isdp, checkbits))
return;
isdp->id_alive = id_alive;
}
(*dp->attach)(isdp);
if (isdp->id_irq) {
if (mp)
INTRMASK(*mp, isdp->id_irq);
register_intr(ffs(isdp->id_irq) - 1, isdp->id_id,
isdp->id_ri_flags, isdp->id_intr,
mp, isdp->id_unit);
INTREN(isdp->id_irq);
}
} else {
if (isdp->id_reconfig) {
(*dp->attach)(isdp); /* reconfiguration attach */
}
if (!last_alive) {
if (!isdp->id_reconfig) {
printf("%s%d not found", dp->name, isdp->id_unit);
if (isdp->id_iobase) {
printf(" at 0x%x", isdp->id_iobase);
}
printf("\n");
}
}
else {
/* This code has not been tested.... */
if (isdp->id_irq) {
INTRDIS(isdp->id_irq);
unregister_intr(ffs(isdp->id_irq) - 1,
isdp->id_intr);
if (mp)
INTRUNMASK(*mp, isdp->id_irq);
}
}
}
}
/*
* Provide ISA-specific device information to user programs using the
* hw.devconf interface.
*/
int
isa_externalize(struct isa_device *id, struct sysctl_req *req)
{
return (SYSCTL_OUT(req, id, sizeof *id));
}
/*
* This is used to forcibly reconfigure an ISA device. It currently just
* returns an error 'cos you can't do that yet. It is here to demonstrate
* what the `internalize' routine is supposed to do.
*/
int
isa_internalize(struct isa_device *id, struct sysctl_req *req)
{
struct isa_device myid;
int rv;
rv = SYSCTL_IN(req, &myid, sizeof *id);
if(rv)
return rv;
rv = EOPNOTSUPP;
/* code would go here to validate the configuration request */
/* code would go here to actually perform the reconfiguration */
return rv;
}
int
isa_generic_externalize(struct kern_devconf *kdc, struct sysctl_req *req)
{
return isa_externalize(kdc->kdc_isa, req);
}
/*
* Fill in default interrupt table (in case of spuruious interrupt
* during configuration of kernel, setup interrupt control unit
*/
void
isa_defaultirq()
{
int i;
/* icu vectors */
for (i = 0; i < ICU_LEN; i++)
unregister_intr(i, (inthand2_t *)NULL);
/* initialize 8259's */
outb(IO_ICU1, 0x11); /* reset; program device, four bytes */
outb(IO_ICU1+1, NRSVIDT); /* starting at this vector index */
outb(IO_ICU1+1, 1<<2); /* slave on line 2 */
#ifdef AUTO_EOI_1
outb(IO_ICU1+1, 2 | 1); /* auto EOI, 8086 mode */
#else
outb(IO_ICU1+1, 1); /* 8086 mode */
#endif
outb(IO_ICU1+1, 0xff); /* leave interrupts masked */
outb(IO_ICU1, 0x0a); /* default to IRR on read */
outb(IO_ICU1, 0xc0 | (3 - 1)); /* pri order 3-7, 0-2 (com2 first) */
outb(IO_ICU2, 0x11); /* reset; program device, four bytes */
outb(IO_ICU2+1, NRSVIDT+8); /* staring at this vector index */
outb(IO_ICU2+1,2); /* my slave id is 2 */
#ifdef AUTO_EOI_2
outb(IO_ICU2+1, 2 | 1); /* auto EOI, 8086 mode */
#else
outb(IO_ICU2+1,1); /* 8086 mode */
#endif
outb(IO_ICU2+1, 0xff); /* leave interrupts masked */
outb(IO_ICU2, 0x0a); /* default to IRR on read */
}
/* region of physical memory known to be contiguous */
vm_offset_t isaphysmem;
static caddr_t dma_bounce[8]; /* XXX */
static char bounced[8]; /* XXX */
#define MAXDMASZ 512 /* XXX */
/* high byte of address is stored in this port for i-th dma channel */
static short dmapageport[8] =
{ 0x87, 0x83, 0x81, 0x82, 0x8f, 0x8b, 0x89, 0x8a };
/*
* isa_dmacascade(): program 8237 DMA controller channel to accept
* external dma control by a board.
*/
void isa_dmacascade(unsigned chan)
{
if (chan > 7)
panic("isa_dmacascade: impossible request");
/* set dma channel mode, and set dma channel mode */
if ((chan & 4) == 0) {
outb(DMA1_MODE, DMA37MD_CASCADE | chan);
outb(DMA1_SMSK, chan);
} else {
outb(DMA2_MODE, DMA37MD_CASCADE | (chan & 3));
outb(DMA2_SMSK, chan & 3);
}
}
static int
isa_dmarangecheck(caddr_t va, unsigned length, unsigned chan);
/*
* isa_dmastart(): program 8237 DMA controller channel, avoid page alignment
* problems by using a bounce buffer.
*/
void isa_dmastart(int flags, caddr_t addr, unsigned nbytes, unsigned chan)
{ vm_offset_t phys;
int waport;
caddr_t newaddr;
if ( chan > 7
|| (chan < 4 && nbytes > (1<<16))
|| (chan >= 4 && (nbytes > (1<<17) || (u_int)addr & 1)))
panic("isa_dmastart: impossible request");
if (isa_dmarangecheck(addr, nbytes, chan)) {
if (dma_bounce[chan] == 0)
dma_bounce[chan] =
(caddr_t) isaphysmem + NBPG*chan;
bounced[chan] = 1;
newaddr = dma_bounce[chan];
*(int *) newaddr = 0; /* XXX */
/* copy bounce buffer on write */
if (!(flags & B_READ))
bcopy(addr, newaddr, nbytes);
addr = newaddr;
}
/* translate to physical */
phys = pmap_extract(pmap_kernel(), (vm_offset_t)addr);
if ((chan & 4) == 0) {
/*
* Program one of DMA channels 0..3. These are
* byte mode channels.
*/
/* set dma channel mode, and reset address ff */
/* If B_RAW flag is set, then use autoinitialise mode */
if (flags & B_RAW) {
if (flags & B_READ)
outb(DMA1_MODE, DMA37MD_AUTO|DMA37MD_WRITE|chan);
else
outb(DMA1_MODE, DMA37MD_AUTO|DMA37MD_READ|chan);
}
else
if (flags & B_READ)
outb(DMA1_MODE, DMA37MD_SINGLE|DMA37MD_WRITE|chan);
else
outb(DMA1_MODE, DMA37MD_SINGLE|DMA37MD_READ|chan);
outb(DMA1_FFC, 0);
/* send start address */
waport = DMA1_CHN(chan);
outb(waport, phys);
outb(waport, phys>>8);
outb(dmapageport[chan], phys>>16);
/* send count */
outb(waport + 1, --nbytes);
outb(waport + 1, nbytes>>8);
/* unmask channel */
outb(DMA1_SMSK, chan);
} else {
/*
* Program one of DMA channels 4..7. These are
* word mode channels.
*/
/* set dma channel mode, and reset address ff */
/* If B_RAW flag is set, then use autoinitialise mode */
if (flags & B_RAW) {
if (flags & B_READ)
outb(DMA2_MODE, DMA37MD_AUTO|DMA37MD_WRITE|(chan&3));
else
outb(DMA2_MODE, DMA37MD_AUTO|DMA37MD_READ|(chan&3));
}
else
if (flags & B_READ)
outb(DMA2_MODE, DMA37MD_SINGLE|DMA37MD_WRITE|(chan&3));
else
outb(DMA2_MODE, DMA37MD_SINGLE|DMA37MD_READ|(chan&3));
outb(DMA2_FFC, 0);
/* send start address */
waport = DMA2_CHN(chan - 4);
outb(waport, phys>>1);
outb(waport, phys>>9);
outb(dmapageport[chan], phys>>16);
/* send count */
nbytes >>= 1;
outb(waport + 2, --nbytes);
outb(waport + 2, nbytes>>8);
/* unmask channel */
outb(DMA2_SMSK, chan & 3);
}
}
void isa_dmadone(int flags, caddr_t addr, int nbytes, int chan)
{
/* copy bounce buffer on read */
/*if ((flags & (B_PHYS|B_READ)) == (B_PHYS|B_READ))*/
if (bounced[chan]) {
bcopy(dma_bounce[chan], addr, nbytes);
bounced[chan] = 0;
}
}
/*
* Check for problems with the address range of a DMA transfer
* (non-contiguous physical pages, outside of bus address space,
* crossing DMA page boundaries).
* Return true if special handling needed.
*/
static int
isa_dmarangecheck(caddr_t va, unsigned length, unsigned chan) {
vm_offset_t phys, priorpage = 0, endva;
u_int dma_pgmsk = (chan & 4) ? ~(128*1024-1) : ~(64*1024-1);
endva = (vm_offset_t)round_page(va + length);
for (; va < (caddr_t) endva ; va += NBPG) {
phys = trunc_page(pmap_extract(pmap_kernel(), (vm_offset_t)va));
#define ISARAM_END RAM_END
if (phys == 0)
panic("isa_dmacheck: no physical page present");
if (phys >= ISARAM_END)
return (1);
if (priorpage) {
if (priorpage + NBPG != phys)
return (1);
/* check if crossing a DMA page boundary */
if (((u_int)priorpage ^ (u_int)phys) & dma_pgmsk)
return (1);
}
priorpage = phys;
}
return (0);
}
#define NMI_PARITY (1 << 7)
#define NMI_IOCHAN (1 << 6)
#define ENMI_WATCHDOG (1 << 7)
#define ENMI_BUSTIMER (1 << 6)
#define ENMI_IOSTATUS (1 << 5)
/*
* Handle a NMI, possibly a machine check.
* return true to panic system, false to ignore.
*/
int
isa_nmi(cd)
int cd;
{
int isa_port = inb(0x61);
int eisa_port = inb(0x461);
if(isa_port & NMI_PARITY) {
panic("RAM parity error, likely hardware failure.");
} else if(isa_port & NMI_IOCHAN) {
panic("I/O channel check, likely hardware failure.");
} else if(eisa_port & ENMI_WATCHDOG) {
panic("EISA watchdog timer expired, likely hardware failure.");
} else if(eisa_port & ENMI_BUSTIMER) {
panic("EISA bus timeout, likely hardware failure.");
} else if(eisa_port & ENMI_IOSTATUS) {
panic("EISA I/O port status error.");
} else {
printf("\nNMI ISA %x, EISA %x\n", isa_port, eisa_port);
return(0);
}
}
/*
* Caught a stray interrupt, notify
*/
static void
isa_strayintr(d)
int d;
{
/* DON'T BOTHER FOR NOW! */
/* for some reason, we get bursts of intr #7, even if not enabled! */
/*
* Well the reason you got bursts of intr #7 is because someone
* raised an interrupt line and dropped it before the 8259 could
* prioritize it. This is documented in the intel data book. This
* means you have BAD hardware! I have changed this so that only
* the first 5 get logged, then it quits logging them, and puts
* out a special message. rgrimes 3/25/1993
*/
/*
* XXX TODO print a different message for #7 if it is for a
* glitch. Glitches can be distinguished from real #7's by
* testing that the in-service bit is _not_ set. The test
* must be done before sending an EOI so it can't be done if
* we are using AUTO_EOI_1.
*/
if (intrcnt[NR_DEVICES + d] <= 5)
log(LOG_ERR, "stray irq %d\n", d);
if (intrcnt[NR_DEVICES + d] == 5)
log(LOG_CRIT,
"too many stray irq %d's; not logging any more\n", d);
}
/*
* Find the highest priority enabled display device. Since we can't
* distinguish display devices from ttys, depend on display devices
* being sensitive and before sensitive non-display devices (if any)
* in isa_devtab_tty.
*
* XXX we should add capability flags IAMDISPLAY and ISUPPORTCONSOLES.
*/
struct isa_device *
find_display()
{
struct isa_device *dvp;
for (dvp = isa_devtab_tty; dvp->id_driver != NULL; dvp++)
if (dvp->id_driver->sensitive_hw && dvp->id_enabled)
return (dvp);
return (NULL);
}
/*
* find an ISA device in a given isa_devtab_* table, given
* the table to search, the expected id_driver entry, and the unit number.
*
* this function is defined in isa_device.h, and this location is debatable;
* i put it there because it's useless w/o, and directly operates on
* the other stuff in that file.
*
*/
struct isa_device *find_isadev(table, driverp, unit)
struct isa_device *table;
struct isa_driver *driverp;
int unit;
{
if (driverp == NULL) /* sanity check */
return NULL;
while ((table->id_driver != driverp) || (table->id_unit != unit)) {
if (table->id_driver == 0)
return NULL;
table++;
}
return table;
}
/*
* Return nonzero if a (masked) irq is pending for a given device.
*/
int
isa_irq_pending(dvp)
struct isa_device *dvp;
{
unsigned id_irq;
id_irq = dvp->id_irq;
if (id_irq & 0xff)
return (inb(IO_ICU1) & id_irq);
return (inb(IO_ICU2) & (id_irq >> 8));
}
int
update_intr_masks(void)
{
int intr, n=0;
u_int mask,*maskptr;
for (intr=0; intr < ICU_LEN; intr ++) {
if (intr==2) continue;
maskptr = intr_mptr[intr];
if (!maskptr) continue;
*maskptr |= 1 << intr;
mask = *maskptr;
if (mask != intr_mask[intr]) {
#if 0
printf ("intr_mask[%2d] old=%08x new=%08x ptr=%p.\n",
intr, intr_mask[intr], mask, maskptr);
#endif
intr_mask[intr]=mask;
n++;
}
}
return (n);
}
int
register_intr(intr, device_id, flags, handler, maskptr, unit)
int intr;
int device_id;
u_int flags;
inthand2_t *handler;
u_int *maskptr;
int unit;
{
char *cp;
u_long ef;
int id;
u_int mask = (maskptr ? *maskptr : 0);
if ((u_int)intr >= ICU_LEN || intr == 2
|| (u_int)device_id >= NR_DEVICES)
return (EINVAL);
if (intr_handler[intr] != isa_strayintr)
return (EBUSY);
ef = read_eflags();
disable_intr();
intr_countp[intr] = &intrcnt[device_id];
intr_handler[intr] = handler;
intr_mptr[intr] = maskptr;
intr_mask[intr] = mask | (1 << intr);
intr_unit[intr] = unit;
setidt(ICU_OFFSET + intr,
flags & RI_FAST ? fastintr[intr] : slowintr[intr],
SDT_SYS386IGT, SEL_KPL, GSEL(GCODE_SEL, SEL_KPL));
write_eflags(ef);
for (cp = intrnames, id = 0; id <= device_id; id++)
while (*cp++ != '\0')
;
if (cp > eintrnames)
return (0);
if (intr < 10) {
cp[-3] = intr + '0';
cp[-2] = ' ';
} else {
cp[-3] = '1';
cp[-2] = intr - 10 + '0';
}
return (0);
}
static void
register_imask(dvp, mask)
struct isa_device *dvp;
u_int mask;
{
if (dvp->id_alive && dvp->id_irq) {
int intr;
intr = ffs(dvp->id_irq) - 1;
intr_mask[intr] = mask | (1 <<intr);
}
(void) update_intr_masks();
}
int
unregister_intr(intr, handler)
int intr;
inthand2_t *handler;
{
u_long ef;
if ((u_int)intr >= ICU_LEN || handler != intr_handler[intr])
return (EINVAL);
ef = read_eflags();
disable_intr();
intr_countp[intr] = &intrcnt[NR_DEVICES + intr];
intr_handler[intr] = isa_strayintr;
intr_mptr[intr] = NULL;
intr_mask[intr] = HWI_MASK | SWI_MASK;
intr_unit[intr] = intr;
setidt(ICU_OFFSET + intr, slowintr[intr], SDT_SYS386IGT, SEL_KPL,
GSEL(GCODE_SEL, SEL_KPL));
write_eflags(ef);
return (0);
}