vax/vsa/vsbus.c

1.9     ragge /*	$NetBSD: vsbus.c,v 1.9 1998/01/24 14:16:11 ragge Exp $ */
1.1     ragge /*
1.1     ragge  * Copyright (c) 1996 Ludd, University of Lule}, Sweden.
1.1     ragge  * All rights reserved.
1.1     ragge  *
1.1     ragge  * This code is derived from software contributed to Ludd by Bertram Barth.
1.1     ragge  *
1.1     ragge  * Redistribution and use in source and binary forms, with or without
1.1     ragge  * modification, are permitted provided that the following conditions
1.1     ragge  * are met:
1.1     ragge  * 1. Redistributions of source code must retain the above copyright
1.1     ragge  *    notice, this list of conditions and the following disclaimer.
1.1     ragge  * 2. Redistributions in binary form must reproduce the above copyright
1.1     ragge  *    notice, this list of conditions and the following disclaimer in the
1.1     ragge  *    documentation and/or other materials provided with the distribution.
1.1     ragge  * 3. All advertising materials mentioning features or use of this software
1.1     ragge  *    must display the following acknowledgement:
1.1     ragge  *	This product includes software developed at Ludd, University of
1.1     ragge  *	Lule}, Sweden and its contributors.
1.1     ragge  * 4. The name of the author may not be used to endorse or promote products
1.1     ragge  *    derived from this software without specific prior written permission
1.1     ragge  *
1.1     ragge  * THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR
1.1     ragge  * IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES
1.1     ragge  * OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED.
1.1     ragge  * IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT,
1.1     ragge  * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT
1.1     ragge  * NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
1.1     ragge  * DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
1.1     ragge  * THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
1.1     ragge  * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF
1.1     ragge  * THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
1.1     ragge  */
1.1     ragge
1.1     ragge #include <sys/param.h>
1.1     ragge #include <sys/systm.h>
1.1     ragge #include <sys/buf.h>
1.1     ragge #include <sys/conf.h>
1.1     ragge #include <sys/file.h>
1.1     ragge #include <sys/ioctl.h>
1.1     ragge #include <sys/proc.h>
1.1     ragge #include <sys/user.h>
1.1     ragge #include <sys/map.h>
1.1     ragge #include <sys/device.h>
1.1     ragge #include <sys/dkstat.h>
1.1     ragge #include <sys/disklabel.h>
1.1     ragge #include <sys/syslog.h>
1.1     ragge #include <sys/stat.h>
1.1     ragge
1.1     ragge #include <machine/pte.h>
1.1     ragge #include <machine/sid.h>
1.1     ragge #include <machine/scb.h>
1.1     ragge #include <machine/cpu.h>
1.1     ragge #include <machine/trap.h>
1.1     ragge #include <machine/nexus.h>
1.1     ragge
1.1     ragge #include <machine/uvax.h>
1.1     ragge #include <machine/ka410.h>
1.1     ragge #include <machine/ka43.h>
1.1     ragge
1.1     ragge #include <machine/vsbus.h>
1.1     ragge
1.1     ragge #define trace(x)
1.1     ragge #define debug(x)
1.1     ragge
1.9     ragge int	vsbus_match	__P((struct device *, struct cfdata *, void *));
1.1     ragge void	vsbus_attach	__P((struct device *, struct device *, void *));
1.2       cgd int	vsbus_print	__P((void *, const char *));
1.1     ragge
1.1     ragge void	ka410_attach	__P((struct device *, struct device *, void *));
1.1     ragge void	ka43_attach	__P((struct device *, struct device *, void *));
1.1     ragge
1.1     ragge struct	cfattach vsbus_ca = {
1.1     ragge 	sizeof(struct device), vsbus_match, vsbus_attach
1.1     ragge };
1.1     ragge
1.1     ragge /*
1.1     ragge void	vsbus_intr_register __P((struct confargs *ca, int (*)(void*), void*));
1.1     ragge void	vsbus_intr_unregister __P((struct confargs *));
1.1     ragge */
1.1     ragge
1.1     ragge void	vsbus_intr_dispatch __P((int i));
1.1     ragge
1.1     ragge #define VSBUS_MAXDEVS	8
1.1     ragge #define VSBUS_MAXINTR	8
1.1     ragge
1.1     ragge struct confargs *vsbus_devs = NULL;
1.1     ragge
1.6     ragge #ifdef VAX410
1.1     ragge struct confargs ka410_devs[] = {
1.1     ragge 	/* name		intslot intpri intvec	intbit	ioaddr	*/
1.1     ragge 	{ "dc",		7,	7,	0x2C0,	(1<<7), KA410_SER_BASE,
1.1     ragge 			6,	6,	0x2C4,	(1<<6), 0x01,		},
1.1     ragge 	{ "dc (xmit)",	6,	6,	0x2C4,	(1<<6), KA410_SER_BASE, },
1.1     ragge 	{ "le",		5,	5,	0x250,	(1<<5), KA410_LAN_BASE,
1.1     ragge 			KA410_NWA_BASE, 0x00,				},
1.1     ragge 	{ "ncr",	1,	1,	0x3F8,	(1<<1), KA410_SCS_BASE,
1.1     ragge 			KA410_SCS_DADR, KA410_SCS_DCNT, KA410_SCS_DDIR,
1.1     ragge 			KA410_DMA_BASE, KA410_DMA_SIZE, 0x00,	0x07,	},
1.1     ragge 	{ "hdc",	0,	0,	0x3FC,	(1<<0), KA410_DKC_BASE,
1.1     ragge 			0, 0, 0,
1.1     ragge 			KA410_DMA_BASE, KA410_DMA_SIZE, 0x00,		},
1.1     ragge #if 0
1.1     ragge 	{ "dc (recv)",	7,	7,	0x2C0,	(1<<7), KA410_SER_BASE, },
1.1     ragge 	{ "dc (xmit)",	6,	6,	0x2C4,	(1<<6), KA410_SER_BASE, },
1.1     ragge 	{ "hdc9224",	0,	0,	0x3FC,	(1<<0), KA410_DKC_BASE, },
1.1     ragge 	{ "ncr5380",	1,	1,	0x3F8,	(1<<1), KA410_SCS_BASE, },
1.1     ragge 	{ "am7990",	5,	5,	0x250,	(1<<5), KA410_LAN_BASE, },
1.1     ragge 	{ "NETOPT",	4,	4,	0x254,	(1<<4), KA410_LAN_BASE, },
1.1     ragge #endif
1.1     ragge 	{ "" },
1.1     ragge };
1.6     ragge
1.6     ragge /*
1.6     ragge  * It would be better if we could use the (provided) system config
1.6     ragge  * information for each CPU instead of this.
1.6     ragge  */
1.6     ragge struct confargs ka420_devs[] = {
1.6     ragge 	{ "le",		5,	5,	0x250,	(1<<5),	KA410_LAN_BASE,
1.6     ragge 		KA410_NWA_BASE,	0x00,					},
1.6     ragge 	{ "ncr",	1,	1,	0x3F8,	(1<<1),	KA410_SCS_BASE,
1.6     ragge 			KA410_SCS_DADR,	KA410_SCS_DCNT,	KA410_SCS_DDIR,
1.6     ragge 			KA410_DMA_BASE,	KA410_DMA_SIZE,	0x00,	0x07,	},
1.6     ragge 	{ "ncr",	0,	0,	0x3FC,	(1<<0),	0x200C0180,
1.6     ragge 			0x200C01A0,	0x200C01C0,	0x200C01C4,
1.6     ragge 			KA410_DMA_BASE,	KA410_DMA_SIZE,	0x00,	0x07,	},
1.6     ragge 	{ "" },
1.6     ragge };
1.1     ragge #endif
1.1     ragge
1.1     ragge #ifdef VAX43
1.1     ragge struct confargs ka43_devs[] = {
1.1     ragge 	/* name		intslot intpri intvec	intbit	ioaddr	*/
1.1     ragge 	{ "dc",		7,	7,	0x2C0,	(1<<7), KA43_SER_BASE,
1.1     ragge 			6,	6,	0x2C4,	(1<<6), 0x01,		},
1.1     ragge 	{ "dc (xmit)",	6,	6,	0x2C4,	(1<<6), KA43_SER_BASE,	},
1.1     ragge 	{ "le",		5,	5,	0x250,	(1<<5), KA43_LAN_BASE,
1.1     ragge 			KA43_NWA_BASE,	0x00,				},
1.1     ragge 	{ "ncr",	1,	1,	0x3F8,	(1<<1), KA43_SC1_BASE,
1.1     ragge 			KA43_SC1_DADR,	KA43_SC1_DCNT,	KA43_SC1_DDIR,
1.1     ragge 			KA43_DMA_BASE,	KA43_DMA_SIZE,	0x01,	0x06,	},
1.1     ragge 	{ "ncr",	0,	0,	0x3FC,	(1<<0), KA43_SC2_BASE,
1.1     ragge 			KA43_SC2_DADR,	KA43_SC2_DCNT,	KA43_SC2_DDIR,
1.1     ragge 			KA43_DMA_BASE,	KA43_DMA_SIZE,	0x01,	0x06,	},
1.1     ragge #if 0
1.1     ragge 	{ "le (2nd)",	4,	4,	0x254,	(1<<4), 0x???,		},
1.1     ragge 	{ "NETOPT",	4,	4,	0x254,	(1<<4), 0x???,		},
1.1     ragge #endif
1.1     ragge 	{ "" },
1.1     ragge };
1.1     ragge #endif
1.1     ragge
1.1     ragge int
1.1     ragge vsbus_print(aux, name)
1.1     ragge 	void *aux;
1.2       cgd 	const char *name;
1.1     ragge {
1.1     ragge 	struct confargs *ca = aux;
1.1     ragge
1.1     ragge 	trace(("vsbus_print(%x, %s)\n", ca->ca_name, name));
1.1     ragge
1.1     ragge 	if (name) {
1.4  christos 		printf ("device %s at %s", ca->ca_name, name);
1.1     ragge 		return (UNSUPP);
1.1     ragge 	}
1.1     ragge 	return (UNCONF);
1.1     ragge }
1.1     ragge
1.1     ragge int
1.1     ragge vsbus_match(parent, cf, aux)
1.1     ragge 	struct	device	*parent;
1.9     ragge 	struct cfdata	*cf;
1.1     ragge 	void	*aux;
1.1     ragge {
1.1     ragge 	struct bp_conf *bp = aux;
1.1     ragge
1.1     ragge 	trace(("vsbus_match: bp->type = \"%s\"\n", bp->type));
1.1     ragge
1.1     ragge 	if (strcmp(bp->type, "vsbus"))
1.1     ragge 		return 0;
1.1     ragge 	/*
1.1     ragge 	 * on machines which can have it, the vsbus is always there
1.1     ragge 	 */
1.1     ragge 	if ((vax_bustype & VAX_VSBUS) == 0)
1.1     ragge 		return (0);
1.1     ragge
1.1     ragge 	return (1);
1.1     ragge }
1.1     ragge
1.1     ragge #if 1	/*------------------------------------------------------------*/
1.1     ragge #if 1
1.1     ragge #define REG(name)	short name; short X##name##X;
1.1     ragge #else
1.1     ragge #define REG(name)	int name;
1.1     ragge #endif
1.1     ragge static volatile struct {/* base address of DZ-controller: 0x200A0000 */
1.1     ragge   REG(csr);		/* 00 Csr: control/status register */
1.1     ragge   REG(rbuf);		/* 04 Rbuf/Lpr: receive buffer/line param reg. */
1.1     ragge   REG(tcr);		/* 08 Tcr: transmit console register */
1.1     ragge   REG(tdr);		/* 0C Msr/Tdr: modem status reg/transmit data reg */
1.1     ragge   REG(lpr0);		/* 10 Lpr0: */
1.1     ragge   REG(lpr1);		/* 14 Lpr0: */
1.1     ragge   REG(lpr2);		/* 18 Lpr0: */
1.1     ragge   REG(lpr3);		/* 1C Lpr0: */
1.1     ragge } *dz = (void*)0x200A0000;
1.1     ragge extern int dzcnrint();
1.1     ragge extern int dzcntint();
1.1     ragge int hardclock_count = 0;
1.1     ragge int
1.1     ragge ka410_consintr_enable()
1.1     ragge {
1.1     ragge 	vsbus_intr_enable(&ka410_devs[0]);
1.1     ragge 	vsbus_intr_enable(&ka410_devs[1]);
1.1     ragge }
1.1     ragge
1.1     ragge int
1.1     ragge ka410_consRecv_intr(p)
1.1     ragge 	void *p;
1.1     ragge {
1.4  christos   /* printf("ka410_consRecv_intr: hc-count=%d\n", hardclock_count); */
1.1     ragge   dzcnrint();
1.4  christos   /* printf("gencnrint() returned.\n"); */
1.1     ragge   return(0);
1.1     ragge }
1.1     ragge
1.1     ragge int
1.1     ragge ka410_consXmit_intr(p)
1.1     ragge 	void *p;
1.1     ragge {
1.4  christos   /* printf("ka410_consXmit_intr: hc-count=%d\n", hardclock_count); */
1.1     ragge   dzcntint();
1.4  christos   /* printf("gencntint() returned.\n"); */
1.1     ragge   return(0);
1.1     ragge }
1.1     ragge #endif	/*------------------------------------------------------------*/
1.1     ragge
1.1     ragge void
1.1     ragge vsbus_attach(parent, self, aux)
1.1     ragge 	struct	device	*parent, *self;
1.1     ragge 	void	*aux;
1.1     ragge {
1.1     ragge 	struct confargs *ca;
1.1     ragge 	int i;
1.1     ragge
1.4  christos 	printf("\n");
1.1     ragge 	trace (("vsbus_attach()\n"));
1.1     ragge
1.1     ragge 	switch (vax_boardtype) {
1.6     ragge 	case VAX_BTYP_420:
1.6     ragge 		vsbus_devs = ka420_devs;
1.6     ragge 		break;
1.6     ragge
1.1     ragge 	case VAX_BTYP_410:
1.1     ragge 		vsbus_devs = ka410_devs;
1.1     ragge 		break;
1.1     ragge
1.1     ragge 	case VAX_BTYP_43:
1.1     ragge 	case VAX_BTYP_46:
1.1     ragge 	case VAX_BTYP_49:
1.5     ragge #ifdef VAX43
1.1     ragge 		vsbus_devs = ka43_devs;
1.5     ragge #endif
1.1     ragge 		break;
1.1     ragge
1.1     ragge 	default:
1.4  christos 		printf ("unsupported boardtype 0x%x in vsbus_attach()\n",
1.1     ragge 			vax_boardtype);
1.1     ragge 		return;
1.1     ragge 	}
1.1     ragge
1.1     ragge 	/*
1.1     ragge 	 * first setup interrupt-table, so that devices can register
1.1     ragge 	 * their interrupt-routines...
1.1     ragge 	 */
1.1     ragge 	vsbus_intr_setup();
1.1     ragge
1.1     ragge 	/*
1.1     ragge 	 * now check for all possible devices on this "bus"
1.1     ragge 	 */
1.1     ragge 	for (i=0; i<VSBUS_MAXDEVS; i++) {
1.1     ragge 		ca = &vsbus_devs[i];
1.1     ragge 		if (*ca->ca_name == '\0')
1.1     ragge 			break;
1.1     ragge 		config_found(self, (void*)ca, vsbus_print);
1.1     ragge 	}
1.1     ragge
1.1     ragge 	/*
1.1     ragge 	 * as long as there's no working DZ-driver, we use this dummy
1.1     ragge 	 */
1.1     ragge 	vsbus_intr_register(&ka410_devs[0], ka410_consRecv_intr, NULL);
1.1     ragge 	vsbus_intr_register(&ka410_devs[1], ka410_consXmit_intr, NULL);
1.1     ragge }
1.1     ragge
1.1     ragge #define VSBUS_MAX_INTR	8	/* 64? */
1.1     ragge /*
1.1     ragge  * interrupt service routines are given an int as argument, which is
1.1     ragge  * pushed onto stack as LITERAL. Thus the value is between 0-63.
1.1     ragge  * This array of 64 might be oversized for now, but it's all which
1.1     ragge  * ever will be possible.
1.1     ragge  */
1.1     ragge struct vsbus_ivec {
1.1     ragge 	struct ivec_dsp intr_vec;		/* this is referenced in SCB */
1.1     ragge 	int		intr_count;		/* keep track of interrupts */
1.1     ragge 	int		intr_flags;		/* valid, etc. */
1.1     ragge 	void		(*enab)(int);		/* enable interrupt */
1.1     ragge 	void		(*disab)(int);		/* disable interrupt */
1.1     ragge 	void		(*prep)(int);		/* need pre-processing? */
1.1     ragge 	int		(*handler)(void*);	/* isr-routine to call */
1.1     ragge 	void		*hndlarg;		/* args to this routine */
1.1     ragge 	void		(*postp)(int);		/* need post-processing? */
1.1     ragge } vsbus_ivtab[VSBUS_MAX_INTR];
1.1     ragge
1.1     ragge /*
1.1     ragge  *
1.1     ragge  */
1.1     ragge int
1.1     ragge vsbus_intr_setup()
1.1     ragge {
1.1     ragge 	int i;
1.1     ragge 	struct vsbus_ivec *ip;
1.1     ragge 	extern struct ivec_dsp idsptch;		/* subr.s */
1.1     ragge
1.1     ragge 	for (i=0; i<VSBUS_MAX_INTR; i++) {
1.1     ragge 		ip = &vsbus_ivtab[i];
1.1     ragge 		bcopy(&idsptch, &ip->intr_vec, sizeof(struct ivec_dsp));
1.1     ragge 		ip->intr_vec.pushlarg = i;
1.1     ragge 		ip->intr_vec.hoppaddr = vsbus_intr_dispatch;
1.1     ragge 		ip->intr_count = 0;
1.1     ragge 		ip->intr_flags = 0;
1.1     ragge 		ip->enab = NULL;
1.1     ragge 		ip->disab = NULL;
1.1     ragge 		ip->postp = NULL;
1.1     ragge 	}
1.1     ragge 	switch (vax_boardtype) {
1.1     ragge 	case VAX_BTYP_410:
1.1     ragge 	case VAX_BTYP_420:
1.1     ragge 	case VAX_BTYP_43:
1.1     ragge 	case VAX_BTYP_46:
1.1     ragge 	case VAX_BTYP_49:
1.1     ragge 		ka410_intr_setup();
1.1     ragge 		return(0);
1.1     ragge 	default:
1.4  christos 		printf("unsupported board-type 0x%x in vsbus_intr_setup()\n",
1.1     ragge 			vax_boardtype);
1.1     ragge 		return(1);
1.1     ragge 	}
1.1     ragge }
1.1     ragge
1.1     ragge int
1.1     ragge vsbus_intr_register(ca, handler, arg)
1.1     ragge 	struct confargs *ca;
1.1     ragge 	int (*handler)(void*);
1.1     ragge 	void *arg;
1.1     ragge {
1.1     ragge 	/* struct device *dev = arg; */
1.1     ragge 	int i = ca->ca_intslot;
1.1     ragge 	struct vsbus_ivec *ip = &vsbus_ivtab[i];
1.1     ragge
1.1     ragge 	trace (("vsbus_intr_register(%s/%d)\n", ca->ca_name, ca->ca_intslot));
1.1     ragge
1.1     ragge 	ip->handler = handler;
1.1     ragge 	ip->hndlarg = arg;
1.1     ragge }
1.1     ragge
1.1     ragge int
1.1     ragge vsbus_intr_enable(ca)
1.1     ragge 	struct confargs *ca;
1.1     ragge {
1.1     ragge 	int i = ca->ca_intslot;
1.1     ragge 	struct vsbus_ivec *ip = &vsbus_ivtab[i];
1.1     ragge
1.1     ragge 	trace (("vsbus_intr_enable(%s/%d)\n", ca->ca_name, ca->ca_intslot));
1.1     ragge
1.1     ragge 	/* XXX check for valid handler etc. !!! */
1.1     ragge 	if (ip->handler == NULL) {
1.4  christos 		printf("interrupts for \"%s\"(%d) not enabled: null-handler\n",
1.1     ragge 		      ca->ca_name, ca->ca_intslot);
1.1     ragge 		return;
1.1     ragge 	}
1.1     ragge
1.1     ragge 	ip->enab(i);
1.1     ragge }
1.1     ragge
1.1     ragge int
1.1     ragge vsbus_intr_disable(ca)
1.1     ragge 	struct confargs *ca;
1.1     ragge {
1.1     ragge 	int i = ca->ca_intslot;
1.1     ragge 	struct vsbus_ivec *ip = &vsbus_ivtab[i];
1.1     ragge
1.1     ragge 	trace (("vsbus_intr_disable(%s/%d)\n", ca->ca_name, i));
1.1     ragge
1.1     ragge 	ip->disab(i);
1.1     ragge }
1.1     ragge
1.1     ragge int
1.1     ragge vsbus_intr_unregister(ca)
1.1     ragge 	struct confargs *ca;
1.1     ragge {
1.1     ragge 	int i = ca->ca_intslot;
1.1     ragge 	struct vsbus_ivec *ip = &vsbus_ivtab[i];
1.1     ragge
1.1     ragge 	trace (("vsbus_intr_unregister(%s/%d)\n", ca->ca_name, i));
1.1     ragge
1.1     ragge 	ip->handler = NULL;
1.1     ragge 	ip->hndlarg = NULL;
1.1     ragge }
1.1     ragge
1.1     ragge void
1.1     ragge vsbus_intr_dispatch(i)
1.1     ragge 	register int i;
1.1     ragge {
1.1     ragge 	register struct vsbus_ivec *ip = &vsbus_ivtab[i];
1.1     ragge
1.1     ragge 	trace (("vsbus_intr_dispatch(%d)", i));
1.1     ragge
1.1     ragge 	if (i < VSBUS_MAX_INTR && ip->handler != NULL) {
1.1     ragge 		ip->intr_count++;
1.1     ragge 		debug (("intr-count[%d] = %d\n", i, ip->intr_count));
1.1     ragge 		(ip->handler)(ip->hndlarg);
1.1     ragge 		if (ip->postp)
1.1     ragge 			(ip->postp)(i);
1.1     ragge 		return;
1.1     ragge 	}
1.1     ragge
1.1     ragge 	if (i < 0 || i >= VSBUS_MAX_INTR) {
1.4  christos 		printf ("stray interrupt %d on vsbus.\n", i);
1.1     ragge 		return;
1.1     ragge 	}
1.1     ragge
1.1     ragge 	if (!ip->handler) {
1.4  christos 		printf ("unhandled interrupt %d on vsbus.\n", i);
1.1     ragge 		return;
1.1     ragge 	}
1.1     ragge }
1.1     ragge
1.1     ragge /*
1.1     ragge  * These addresses are invalid and will be updated/corrected by
1.1     ragge  * ka410_intr_setup(), but having them this way helps debugging
1.1     ragge  */
1.1     ragge static volatile u_char *ka410_intmsk = (void*)KA410_INTMSK;
1.1     ragge static volatile u_char *ka410_intreq = (void*)KA410_INTREQ;
1.1     ragge static volatile u_char *ka410_intclr = (void*)KA410_INTCLR;
1.1     ragge
1.1     ragge static void
1.1     ragge ka410_intr_enable(i)
1.1     ragge 	int i;
1.1     ragge {
1.1     ragge 	trace (("ka410_intr_enable(%d)\n", i));
1.1     ragge 	*ka410_intmsk |= (1<<i);
1.1     ragge }
1.1     ragge
1.1     ragge static void
1.1     ragge ka410_intr_disable(i)
1.1     ragge 	int i;
1.1     ragge {
1.1     ragge 	trace (("ka410_intr_disable(%d)\n", i));
1.1     ragge 	*ka410_intmsk &= ~(1<<i);
1.1     ragge }
1.1     ragge
1.1     ragge static void
1.1     ragge ka410_intr_clear(i)
1.1     ragge 	int i;
1.1     ragge {
1.1     ragge 	trace (("ka410_intr_clear(%d)\n", i));
1.1     ragge 	*ka410_intclr = (1<<i);
1.1     ragge }
1.1     ragge
1.1     ragge ka410_intr_setup()
1.1     ragge {
1.1     ragge 	int i;
1.1     ragge 	struct vsbus_ivec *ip;
1.1     ragge 	void **scbP = (void*)scb;
1.1     ragge
1.1     ragge 	trace (("ka410_intr_setup()\n"));
1.1     ragge
1.1     ragge 	ka410_intmsk = (void*)uvax_phys2virt(KA410_INTMSK);
1.1     ragge 	ka410_intreq = (void*)uvax_phys2virt(KA410_INTREQ);
1.1     ragge 	ka410_intclr = (void*)uvax_phys2virt(KA410_INTCLR);
1.1     ragge
1.1     ragge 	*ka410_intmsk = 0;		/* disable all interrupts */
1.1     ragge 	*ka410_intclr = 0xFF;		/* clear all old interrupts */
1.1     ragge
1.1     ragge 	/*
1.1     ragge 	 * insert the VS2000-specific routines into ivec-table...
1.1     ragge 	 */
1.1     ragge 	for (i=0; i<8; i++) {
1.1     ragge 		ip = &vsbus_ivtab[i];
1.1     ragge 		ip->enab  = ka410_intr_enable;
1.1     ragge 		ip->disab = ka410_intr_disable;
1.1     ragge 		/* ip->postp = ka410_intr_clear; bertram XXX */
1.1     ragge 	}
1.1     ragge 	/*
1.1     ragge 	 * ...and register the interrupt-vectors in SCB
1.1     ragge 	 */
1.1     ragge 	scbP[IVEC_DC/4] = &vsbus_ivtab[0].intr_vec;
1.1     ragge 	scbP[IVEC_SC/4] = &vsbus_ivtab[1].intr_vec;
1.1     ragge 	scbP[IVEC_VS/4] = &vsbus_ivtab[2].intr_vec;
1.1     ragge 	scbP[IVEC_VF/4] = &vsbus_ivtab[3].intr_vec;
1.1     ragge 	scbP[IVEC_NS/4] = &vsbus_ivtab[4].intr_vec;
1.1     ragge 	scbP[IVEC_NP/4] = &vsbus_ivtab[5].intr_vec;
1.1     ragge 	scbP[IVEC_ST/4] = &vsbus_ivtab[6].intr_vec;
1.1     ragge 	scbP[IVEC_SR/4] = &vsbus_ivtab[7].intr_vec;
1.1     ragge }
1.1     ragge
1.1     ragge /*
1.1     ragge  *
1.1     ragge  *
1.1     ragge  */
1.1     ragge
1.1     ragge static volatile struct dma_lock {
1.1     ragge 	int	dl_locked;
1.1     ragge 	int	dl_wanted;
1.1     ragge 	void	*dl_owner;
1.1     ragge 	int	dl_count;
1.1     ragge } dmalock = { 0, 0, NULL, 0 };
1.1     ragge
1.1     ragge int
1.1     ragge vsbus_lockDMA(ca)
1.1     ragge 	struct confargs *ca;
1.1     ragge {
1.1     ragge 	while (dmalock.dl_locked) {
1.1     ragge 		dmalock.dl_wanted++;
1.1     ragge 		sleep((caddr_t)&dmalock, PRIBIO);	/* PLOCK or PRIBIO ? */
1.1     ragge 		dmalock.dl_wanted--;
1.1     ragge 	}
1.1     ragge 	dmalock.dl_locked++;
1.1     ragge 	dmalock.dl_owner = ca;
1.1     ragge
1.1     ragge 	/*
1.1     ragge 	 * no checks yet, no timeouts, nothing...
1.1     ragge 	 */
1.1     ragge
1.1     ragge #ifdef DEBUG
1.1     ragge 	if ((++dmalock.dl_count % 1000) == 0)
1.4  christos 		printf("%d locks, owner: %s\n", dmalock.dl_count, ca->ca_name);
1.1     ragge #endif
1.1     ragge 	return (0);
1.1     ragge }
1.1     ragge
1.1     ragge int
1.1     ragge vsbus_unlockDMA(ca)
1.1     ragge 	struct confargs *ca;
1.1     ragge {
1.1     ragge 	if (dmalock.dl_locked != 1 || dmalock.dl_owner != ca) {
1.4  christos 		printf("locking-problem: %d, %s\n", dmalock.dl_locked,
1.1     ragge 		       (dmalock.dl_owner ? dmalock.dl_owner : "null"));
1.1     ragge 		dmalock.dl_locked = 0;
1.1     ragge 		return (-1);
1.1     ragge 	}
1.1     ragge 	dmalock.dl_owner = NULL;
1.1     ragge 	dmalock.dl_locked = 0;
1.1     ragge 	if (dmalock.dl_wanted) {
1.1     ragge 		wakeup((caddr_t)&dmalock);
1.1     ragge 	}
1.1     ragge 	return (0);
1.1     ragge }
1.1     ragge
1.1     ragge /*----------------------------------------------------------------------*/
1.1     ragge #if 0
1.1     ragge /*
1.1     ragge  * small set of routines needed for mapping when doing pseudo-DMA,
1.1     ragge  * quasi-DMA or virtual-DMA (choose whatever name you like).
1.1     ragge  *
1.1     ragge  * Once I know how VS3100 is doing real DMA (I hope it does), this
1.1     ragge  * should be rewritten to present a general interface...
1.1     ragge  *
1.1     ragge  */
1.1     ragge
1.1     ragge extern u_long uVAX_physmap;
1.1     ragge
1.1     ragge u_long
1.1     ragge vsdma_mapin(bp, len)
1.1     ragge 	struct buf *bp;
1.1     ragge 	int len;
1.1     ragge {
1.1     ragge 	pt_entry_t *pte;	/* pointer to Page-Table-Entry */
1.1     ragge 	struct pcb *pcb;	/* pointer to Process-Controll-Block */
1.1     ragge 	pt_entry_t *xpte;
1.1     ragge 	caddr_t addr;
1.1     ragge 	int pgoff;		/* offset into 1st page */
1.1     ragge 	int pgcnt;		/* number of pages needed */
1.1     ragge 	int pfnum;
1.1     ragge 	int i;
1.1     ragge
1.1     ragge 	trace(("mapin(bp=%x, bp->data=%x)\n", bp, bp->b_data));
1.1     ragge
1.1     ragge 	addr = bp->b_data;
1.1     ragge 	pgoff = (int)bp->b_data & PGOFSET;	/* get starting offset */
1.1     ragge 	pgcnt = btoc(bp->b_bcount + pgoff) + 1; /* one more than needed */
1.1     ragge
1.1     ragge 	/*
1.1     ragge 	 * Get a pointer to the pte pointing out the first virtual address.
1.1     ragge 	 * Use different ways in kernel and user space.
1.1     ragge 	 */
1.1     ragge 	if ((bp->b_flags & B_PHYS) == 0) {
1.1     ragge 		pte = kvtopte(addr);
1.1     ragge 	} else {
1.7   thorpej 		pcb = &bp->b_proc->p_addr->u_pcb;
1.1     ragge 		pte = uvtopte(addr, pcb);
1.1     ragge 	}
1.1     ragge
1.1     ragge 	/*
1.1     ragge 	 * When we are doing DMA to user space, be sure that all pages
1.1     ragge 	 * we want to transfer to are mapped. WHY DO WE NEED THIS???
1.1     ragge 	 * SHOULDN'T THEY ALWAYS BE MAPPED WHEN DOING THIS???
1.1     ragge 	 */
1.1     ragge 	for (i=0; i<(pgcnt-1); i++) {
1.1     ragge 		if ((pte + i)->pg_pfn == 0) {
1.1     ragge 			int rv;
1.1     ragge 			rv = vm_fault(&bp->b_proc->p_vmspace->vm_map,
1.1     ragge 				      (unsigned)addr + i * NBPG,
1.1     ragge 				      VM_PROT_READ|VM_PROT_WRITE, FALSE);
1.1     ragge 			if (rv)
1.1     ragge 				panic("vs-DMA to nonexistent page, %d", rv);
1.1     ragge 		}
1.1     ragge 	}
1.1     ragge
1.1     ragge 	/*
1.1     ragge 	 * now insert new mappings for this memory area into kernel's
1.1     ragge 	 * mapping-table
1.1     ragge 	 */
1.1     ragge 	xpte = kvtopte(uVAX_physmap);
1.1     ragge 	while (--pgcnt > 0) {
1.1     ragge 		pfnum = pte->pg_pfn;
1.1     ragge 		if (pfnum == 0)
1.1     ragge 			panic("vsbus: zero entry");
1.1     ragge 		*(int *)xpte++ = *(int *)pte++;
1.1     ragge 	}
1.1     ragge 	*(int *)xpte = 0;	/* mark last mapped page as invalid! */
1.1     ragge
1.1     ragge 	debug(("uVAX: 0x%x\n", uVAX_physmap + pgoff));
1.1     ragge
1.1     ragge 	return (uVAX_physmap + pgoff);	/* ??? */
1.1     ragge }
1.1     ragge #endif
1.1     ragge /*----------------------------------------------------------------------*/
1.1     ragge /*
1.1     ragge  * Here follows some currently(?) unused stuff. Someday this should be removed
1.1     ragge  */
1.1     ragge
1.1     ragge #if 0
1.1     ragge /*
1.1     ragge  * Configure devices on VS2000/KA410 directly attached to vsbus
1.1     ragge  */
1.1     ragge void
1.1     ragge ka410_attach(parent, self, aux)
1.1     ragge 	struct device *parent;
1.1     ragge 	struct device *self;
1.1     ragge 	void *aux;
1.1     ragge {
1.1     ragge 	struct confargs *ca;
1.1     ragge 	int i;
1.1     ragge
1.1     ragge 	for (i=0; i<KA410_MAXDEVS; i++) {
1.1     ragge 		ca = &ka410_devs[i];
1.1     ragge 		if (*ca->ca_name == '\0')
1.1     ragge 			break;
1.1     ragge 		config_found(self, (void*)ca, vsbus_print);
1.1     ragge 	}
1.1     ragge 	/*
1.1     ragge 	 * as long as there's no real DZ-driver, we used this dummy
1.1     ragge 	 */
1.1     ragge 	vsbus_intr_register(&ka410_devs[0], ka410_consRecv_intr, NULL);
1.1     ragge 	vsbus_intr_register(&ka410_devs[1], ka410_consXmit_intr, NULL);
1.1     ragge }
1.1     ragge
1.1     ragge #endif