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freebsd-dev/sys/dev/eisa/eisaconf.c
Justin T. Gibbs b18d8f49f2 Another pass through eisaconf. Ioaddrs and Maddrs are link lists now. 
The Bt driver is the only one that actually registers multiple addresses.

Probe output is formatted to 80 columns.
1996-01-29 03:13:23 +00:00

683 lines
16 KiB
C
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/*
* EISA bus probe and attach routines
*
* Copyright (c) 1995, 1996 Justin T. Gibbs.
* 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 immediately at the beginning of the file, without modification,
* 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. Absolutely no warranty of function or purpose is made by the author
* Justin T. Gibbs.
* 4. Modifications may be freely made to this file if the above conditions
* are met.
*
* $Id: eisaconf.c,v 1.12 1996/01/03 06:28:01 gibbs Exp $
*/
#include <sys/param.h>
#include <sys/systm.h>
#include <sys/devconf.h>
#include <sys/kernel.h>
#include <sys/sysctl.h>
#include <sys/conf.h> /* For kdc_isa */
#include <sys/malloc.h>
#include <i386/eisa/eisaconf.h>
#include <i386/isa/icu.h> /* Hmmm. Interrupt stuff? */
struct eisa_device_node{
struct eisa_device dev;
struct eisa_device_node *next;
};
extern struct kern_devconf kdc_cpu0;
extern int bootverbose;
struct kern_devconf kdc_eisa0 = {
0, 0, 0, /* filled in by dev_attach */
"eisa", 0, { MDDT_BUS, 0 },
0, 0, 0, BUS_EXTERNALLEN,
&kdc_cpu0, /* parent is the CPU */
0, /* no parentdata */
DC_BUSY, /* busses are always busy */
NULL,
DC_CLS_BUS /* class */
};
/*
* This should probably be a list of "struct device" once it exists.
* A struct device will incorperate ioconf and driver entry point data
* regardless of how its attached to the system (via unions) as well
* as more generic information that all device types should support (unit
* number, if its installed, etc).
*/
static struct eisa_device_node *eisa_dev_list;
static struct eisa_device_node **eisa_dev_list_tail = &eisa_dev_list;
static u_long eisa_unit;
static struct eisa_driver mainboard_drv = {
"eisa",
NULL,
NULL,
NULL,
&eisa_unit
};
/*
* Add the mainboard_drv to the eisa driver linkerset so that it is
* defined even if no EISA drivers are linked into the kernel.
*/
DATA_SET (eisadriver_set, mainboard_drv);
/*
* Local function declarations and static variables
*/
void eisa_reg_print __P((struct eisa_device *e_dev, char *string,
char *separator));
static int eisa_add_resvaddr __P((struct resvlist *head, u_long base,
u_long size, int flags));
static int eisa_reg_resvaddr __P((struct eisa_device *e_dev,
struct resvlist *head, resvaddr_t *resvaddr,
int *reg_count));
/*
* Keep some state about what we've printed so far
* to make probe output pretty.
*/
static struct {
int in_registration;/* reg_start has been called */
int num_interrupts;
int num_ioaddrs;
int num_maddrs;
int column; /* How much we have output so far. */
#define MAX_COL 80
} reg_state;
/*
** probe for EISA devices
*/
void
eisa_configure()
{
int i,slot;
char *id_string;
struct eisa_device_node *dev_node;
struct eisa_driver **e_drvp;
struct eisa_driver *e_drv;
struct eisa_device *e_dev;
int eisaBase = 0xc80;
eisa_id_t eisa_id;
e_drvp = (struct eisa_driver**)eisadriver_set.ls_items;
for (slot = 0; slot < EISA_SLOTS; eisaBase+=0x1000, slot++) {
int id_size = sizeof(eisa_id);
eisa_id = 0;
for( i = 0; i < id_size; i++ ) {
outb(eisaBase,0x80 + i); /*Some cards require priming*/
eisa_id |= inb(eisaBase+i) << ((id_size-i-1)*CHAR_BIT);
}
if (eisa_id & 0x80000000)
continue; /* no EISA card in slot */
/* Prepare an eisa_device_node for this slot */
dev_node = (struct eisa_device_node *)malloc(sizeof(*dev_node),
M_DEVBUF, M_NOWAIT);
if (!dev_node) {
printf("eisa0: cannot malloc eisa_device_node");
break; /* Try to attach what we have already */
}
bzero(dev_node, sizeof(*dev_node));
e_dev = &(dev_node->dev);
e_dev->id = eisa_id;
/*
* Add an EISA ID based descriptive name incase we don't
* have a driver for it. We do this now instead of after all
* probes because in the future, the eisa module will only
* be responsible for creating the list of devices in the system
* for the configuration manager to use.
*/
e_dev->full_name = (char *)malloc(10*sizeof(char),
M_DEVBUF, M_NOWAIT);
if (!e_dev->full_name) {
panic("Eisa probe unable to malloc");
}
sprintf(e_dev->full_name, "%c%c%c%x%x",
EISA_MFCTR_CHAR0(e_dev->id),
EISA_MFCTR_CHAR1(e_dev->id),
EISA_MFCTR_CHAR2(e_dev->id),
EISA_PRODUCT_ID(e_dev->id),
EISA_REVISION_ID(e_dev->id));
e_dev->ioconf.slot = slot;
/* Initialize our lists of reserved addresses */
LIST_INIT(&(e_dev->ioconf.ioaddrs));
LIST_INIT(&(e_dev->ioconf.maddrs));
*eisa_dev_list_tail = dev_node;
eisa_dev_list_tail = &dev_node->next;
}
dev_node = eisa_dev_list;
/*
* "Attach" the system board
*/
/* The first will be the motherboard in a true EISA system */
if (dev_node && (dev_node->dev.ioconf.slot == 0)) {
e_dev = &dev_node->dev;
e_dev->driver = &mainboard_drv;
e_dev->unit = (*e_dev->driver->unit)++;
id_string = e_dev->full_name;
e_dev->full_name = (char *)malloc(strlen(e_dev->full_name)
+ sizeof(" (System Board)")
+ 1, M_DEVBUF, M_NOWAIT);
if (!e_dev->full_name) {
panic("Eisa probe unable to malloc");
}
sprintf(e_dev->full_name, "%s (System Board)", id_string);
free(id_string, M_DEVBUF);
printf("%s%ld: <%s>\n",
e_dev->driver->name,
e_dev->unit,
e_dev->full_name);
/* Should set the iosize, but I don't have a spec handy */
kdc_eisa0.kdc_description =
(char *)malloc(strlen(e_dev->full_name)
+ sizeof("EISA bus <>")
+ 1, M_DEVBUF, M_NOWAIT);
if (!kdc_eisa0.kdc_description) {
panic("Eisa probe unable to malloc");
}
sprintf((char *)kdc_eisa0.kdc_description, "EISA bus <%s>",
e_dev->full_name);
dev_attach(&kdc_eisa0);
printf("Probing for devices on the EISA bus\n");
dev_node = dev_node->next;
}
if (!eisa_dev_list) {
/*
* No devices.
*/
return;
}
/*
* See what devices we recognize.
*/
while((e_drv = *e_drvp++)) {
if (e_drv->probe)
(*e_drv->probe)();
}
/*
* Attach the devices we found in slot order
*/
for (; dev_node; dev_node=dev_node->next) {
e_dev = &dev_node->dev;
e_drv = e_dev->driver;
if (e_drv) {
/*
* Determine the proper unit number for this device.
* Here we should look in the device table generated
* by config to see if this type of device is enabled
* either generically or for this particular address
* as well as determine if a reserved unit number
* should be used. We should also ensure that the
* "next availible unit number" skips over "wired" unit
* numbers. This will be done after config is fixed or
* some other configuration method is chosen.
*/
e_dev->unit = (*e_drv->unit)++;
if ((*e_drv->attach)(e_dev) < 0) {
/* Ensure registration has ended */
reg_state.in_registration = 0;
printf("\n%s0:%d <%s> attach failed\n",
mainboard_drv.name,
e_dev->ioconf.slot,
e_dev->full_name);
continue;
}
/* Ensure registration has ended */
reg_state.in_registration = 0;
e_dev->kdc->kdc_unit = e_dev->unit;
}
else {
/* Announce unattached device */
printf("%s0:%d <%s=0x%x> unknown device\n",
mainboard_drv.name,
e_dev->ioconf.slot,
e_dev->full_name,
e_dev->id);
}
}
}
struct eisa_device *
eisa_match_dev(e_dev, match_func)
struct eisa_device *e_dev;
char* (*match_func)(eisa_id_t);
{
struct eisa_device_node *e_node = eisa_dev_list;
if (e_dev) {
/* Start our search from the last successful match */
e_node = ((struct eisa_device_node *)e_dev)->next;
}
for(; e_node; e_node = e_node->next) {
char *result;
if (e_node->dev.driver) {
/* Already claimed */
continue;
}
result = (*match_func)(e_node->dev.id);
if (result) {
free(e_node->dev.full_name, M_DEVBUF);
e_node->dev.full_name = result;
return (&(e_node->dev));
}
}
return NULL;
}
/* Interrupt and I/O space registration facitlities */
void
eisa_reg_start(e_dev)
struct eisa_device *e_dev;
{
/*
* Announce the device.
*/
char *string;
reg_state.in_registration = 1;
reg_state.num_interrupts = 0;
reg_state.num_ioaddrs = 0;
reg_state.num_maddrs = 0;
reg_state.column = 0;
string = malloc(strlen(e_dev->full_name) + sizeof(" <>") + /*NULL*/1,
M_TEMP, M_NOWAIT);
if(!string) {
printf("eisa0: cannot malloc device description string\n");
return;
}
sprintf(string, " <%s>", e_dev->full_name);
eisa_reg_print(e_dev, string, /*separator=*/NULL);
free(string, M_TEMP);
}
/*
* Output registration information mindfull of screen wrap.
* Output an optional character separator before the string
* if the line does not wrap.
*/
void
eisa_reg_print(e_dev, string, separator)
struct eisa_device *e_dev;
char *string;
char *separator;
{
int len = strlen(string);
if( separator )
len++;
if(reg_state.column + len > MAX_COL) {
printf("\n");
reg_state.column = 0;
}
else if( separator ) {
printf("%c", *separator);
reg_state.column++;
}
if(reg_state.column == 0)
reg_state.column += printf("%s%ld:%s",
e_dev->driver->name,
e_dev->unit,
string);
else
reg_state.column += printf("%s", string);
}
/* Interrupt and I/O space registration facitlities */
void
eisa_reg_end(e_dev)
struct eisa_device *e_dev;
{
if( reg_state.in_registration )
{
/*
* The device should have called eisa_registerdev()
* during its probe. So hopefully we can use the kdc
* to weed out ISA/VL devices that use EISA id registers.
*/
char string[25];
if (e_dev->kdc && (e_dev->kdc->kdc_parent == &kdc_isa0)) {
sprintf(string, " on isa");
}
else {
sprintf(string, " on %s0 slot %d",
mainboard_drv.name,
e_dev->ioconf.slot);
}
eisa_reg_print(e_dev, string, NULL);
printf("\n");
reg_state.in_registration = 0;
}
else
printf("eisa_reg_end called outside of a "
"registration session\n");
}
int
eisa_add_intr(e_dev, irq)
struct eisa_device *e_dev;
int irq;
{
e_dev->ioconf.irq |= 1ul << irq;
return 0;
}
int
eisa_reg_intr(e_dev, irq, func, arg, maskptr, shared)
struct eisa_device *e_dev;
int irq;
void (*func)(void *);
void *arg;
u_int *maskptr;
int shared;
{
int result;
int s;
char string[25];
char separator = ',';
#if NOT_YET
/*
* Punt on conflict detection for the moment.
* I want to develop a generic routine to do
* this for all device types.
*/
int checkthese = CC_IRQ;
if (haveseen_dev(dev, checkthese))
return 1;
#endif
if (reg_state.in_registration) {
s = splhigh();
/*
* This should really go to a routine that can optionally
* handle shared interrupts.
*/
result = register_intr(irq, /* isa irq */
0, /* deviced?? */
0, /* flags? */
(inthand2_t*) func, /* handler */
maskptr, /* mask pointer */
(int)arg); /* handler arg */
if (result) {
printf ("\neisa_reg_int: result=%d\n", result);
splx(s);
return (result);
};
update_intr_masks();
splx(s);
}
else
return EPERM;
e_dev->ioconf.irq |= 1ul << irq;
sprintf(string, " irq %d", irq);
eisa_reg_print(e_dev, string, reg_state.num_interrupts ?
&separator : NULL);
reg_state.num_interrupts++;
return (0);
}
int
eisa_release_intr(e_dev, irq, func)
struct eisa_device *e_dev;
int irq;
void (*func)(void *);
{
int result;
int s;
if (!(e_dev->ioconf.irq & (1ul << irq))) {
printf("%s%ld: Attempted to release an interrupt (%d) "
"it doesn't own\n", e_dev->driver->name,
e_dev->unit, irq);
return (-1);
}
s = splhigh();
INTRDIS ((1ul<<irq));
result = unregister_intr (irq, (inthand2_t*)func);
if (result)
printf ("eisa_release_intr: result=%d\n", result);
update_intr_masks();
splx(s);
return (result);
}
int
eisa_enable_intr(e_dev, irq)
struct eisa_device *e_dev;
int irq;
{
int s;
if (!(e_dev->ioconf.irq & (1ul << irq))) {
printf("%s%ld: Attempted to enable an interrupt (%d) "
"it doesn't own\n", e_dev->driver->name,
e_dev->unit, irq);
return (-1);
}
s = splhigh();
INTREN((1ul << irq));
splx(s);
return 0;
}
static int
eisa_add_resvaddr(head, base, size, flags)
struct resvlist *head;
u_long base;
u_long size;
int flags;
{
resvaddr_t *reservation;
reservation = (resvaddr_t *)malloc(sizeof(resvaddr_t),
M_DEVBUF, M_NOWAIT);
if(!reservation)
return (ENOMEM);
reservation->addr = base;
reservation->size = size;
reservation->flags = flags;
if (!head->lh_first) {
LIST_INSERT_HEAD(head, reservation, links);
}
else {
resvaddr_t *node;
for(node = head->lh_first; node; node = node->links.le_next) {
if (node->addr > reservation->addr) {
/*
* List is sorted in increasing
* address order.
*/
LIST_INSERT_BEFORE(node, reservation, links);
break;
}
if (node->addr == reservation->addr) {
/*
* If the entry we want to add
* matches any already in here,
* fail.
*/
free(reservation, M_DEVBUF);
return (EEXIST);
}
if (!node->links.le_next) {
LIST_INSERT_AFTER(node, reservation, links);
break;
}
}
}
return (0);
}
int
eisa_add_mspace(e_dev, mbase, msize, flags)
struct eisa_device *e_dev;
u_long mbase;
u_long msize;
int flags;
{
return eisa_add_resvaddr(&(e_dev->ioconf.maddrs), mbase, msize, flags);
}
int
eisa_add_iospace(e_dev, iobase, iosize, flags)
struct eisa_device *e_dev;
u_long iobase;
u_long iosize;
int flags;
{
return eisa_add_resvaddr(&(e_dev->ioconf.ioaddrs), iobase, iosize,
flags);
}
static int
eisa_reg_resvaddr(e_dev, head, resvaddr, reg_count)
struct eisa_device *e_dev;
struct resvlist *head;
resvaddr_t *resvaddr;
int *reg_count;
{
if (reg_state.in_registration) {
resvaddr_t *node;
/*
* Ensure that this resvaddr is actually in the devices'
* reservation list.
*/
for(node = head->lh_first; node;
node = node->links.le_next) {
if (node == resvaddr) {
char buf[35];
char separator = ',';
char *string = buf;
if (*reg_count == 0) {
/* First time */
string += sprintf(string, " at");
}
if (node->size == 1
|| (node->flags & RESVADDR_BITMASK))
sprintf(string, " 0x%lx", node->addr);
else
sprintf(string, " 0x%lx-0x%lx",
node->addr,
node->addr + node->size - 1);
eisa_reg_print(e_dev, buf,
*reg_count ? &separator : NULL);
(*reg_count)++;
return (0);
}
}
return (ENOENT);
}
return EPERM;
}
int
eisa_reg_mspace(e_dev, resvaddr)
struct eisa_device *e_dev;
resvaddr_t *resvaddr;
{
#ifdef NOT_YET
/*
* Punt on conflict detection for the moment.
* I want to develop a generic routine to do
* this for all device types.
*/
int checkthese = CC_MADDR;
if (haveseen_dev(dev, checkthese))
return -1;
#endif
return (eisa_reg_resvaddr(e_dev, &(e_dev->ioconf.maddrs), resvaddr,
&(reg_state.num_maddrs)));
}
int
eisa_reg_iospace(e_dev, resvaddr)
struct eisa_device *e_dev;
resvaddr_t *resvaddr;
{
#ifdef NOT_YET
/*
* Punt on conflict detection for the moment.
* I want to develop a generic routine to do
* this for all device types.
*/
int checkthese = CC_IOADDR;
if (haveseen_dev(dev, checkthese))
return -1;
#endif
return (eisa_reg_resvaddr(e_dev, &(e_dev->ioconf.ioaddrs), resvaddr,
&(reg_state.num_ioaddrs)));
}
int
eisa_registerdev(e_dev, driver, kdc_template)
struct eisa_device *e_dev;
struct eisa_driver *driver;
struct kern_devconf *kdc_template;
{
e_dev->driver = driver; /* Driver now owns this device */
e_dev->kdc = (struct kern_devconf *)malloc(sizeof(struct kern_devconf),
M_DEVBUF, M_NOWAIT);
if (!e_dev->kdc) {
printf("WARNING: eisa_registerdev unable to malloc! "
"Device kdc will not be registerd\n");
return 1;
}
bcopy(kdc_template, e_dev->kdc, sizeof(*kdc_template));
e_dev->kdc->kdc_description = e_dev->full_name;
e_dev->kdc->kdc_parentdata = e_dev;
dev_attach(e_dev->kdc);
return (0);
}
int
eisa_generic_externalize(struct kern_devconf *kdc, struct sysctl_req *req)
{
return (SYSCTL_OUT(req, kdc->kdc_eisa, sizeof(struct eisa_device)));
}
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