stand/libsa/sun2.c

1.3.10.1        tv /*	$NetBSD: sun2.c,v 1.3.10.1 2002/05/28 23:11:22 tv Exp $	*/
     1.1  fredette
     1.1  fredette /*-
     1.1  fredette  * Copyright (c) 1998 The NetBSD Foundation, Inc.
     1.1  fredette  * All rights reserved.
     1.1  fredette  *
     1.1  fredette  * This code is derived from software contributed to The NetBSD Foundation
     1.1  fredette  * by Gordon W. Ross and Matthew Fredette.
     1.1  fredette  *
     1.1  fredette  * Redistribution and use in source and binary forms, with or without
     1.1  fredette  * modification, are permitted provided that the following conditions
     1.1  fredette  * are met:
     1.1  fredette  * 1. Redistributions of source code must retain the above copyright
     1.1  fredette  *    notice, this list of conditions and the following disclaimer.
     1.1  fredette  * 2. Redistributions in binary form must reproduce the above copyright
     1.1  fredette  *    notice, this list of conditions and the following disclaimer in the
     1.1  fredette  *    documentation and/or other materials provided with the distribution.
     1.1  fredette  * 3. All advertising materials mentioning features or use of this software
     1.1  fredette  *    must display the following acknowledgement:
     1.1  fredette  *        This product includes software developed by the NetBSD
     1.1  fredette  *        Foundation, Inc. and its contributors.
     1.1  fredette  * 4. Neither the name of The NetBSD Foundation nor the names of its
     1.1  fredette  *    contributors may be used to endorse or promote products derived
     1.1  fredette  *    from this software without specific prior written permission.
     1.1  fredette  *
     1.1  fredette  * THIS SOFTWARE IS PROVIDED BY THE NETBSD FOUNDATION, INC. AND CONTRIBUTORS
     1.1  fredette  * ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED
     1.1  fredette  * TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
     1.1  fredette  * PURPOSE ARE DISCLAIMED.  IN NO EVENT SHALL THE FOUNDATION OR CONTRIBUTORS
     1.1  fredette  * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
     1.1  fredette  * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
     1.1  fredette  * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
     1.1  fredette  * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
     1.1  fredette  * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
     1.1  fredette  * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
     1.1  fredette  * POSSIBILITY OF SUCH DAMAGE.
     1.1  fredette  */
     1.1  fredette
     1.1  fredette /*
     1.1  fredette  * Standalone functions specific to the Sun2.
     1.1  fredette  */
     1.1  fredette
     1.1  fredette /* Need to avoid conflicts on these: */
     1.1  fredette #define get_pte sun2_get_pte
     1.1  fredette #define set_pte sun2_set_pte
     1.1  fredette #define get_segmap sun2_get_segmap
     1.1  fredette #define set_segmap sun2_set_segmap
1.3.10.1        tv
1.3.10.1        tv /*
1.3.10.1        tv  * We need to get the sun2 NBSG definition, even if we're
1.3.10.1        tv  * building this with a different sun68k target.
1.3.10.1        tv  */
1.3.10.1        tv #include <arch/sun2/include/param.h>
     1.1  fredette
     1.1  fredette #include <sys/param.h>
     1.1  fredette #include <machine/idprom.h>
     1.1  fredette #include <machine/mon.h>
     1.1  fredette
     1.1  fredette #include <arch/sun2/include/pte.h>
     1.1  fredette #include <arch/sun2/sun2/control.h>
     1.1  fredette #ifdef notyet
     1.1  fredette #include <arch/sun3/sun3/vme.h>
     1.1  fredette #else
     1.1  fredette #define VME16_BASE MBIO_BASE
     1.1  fredette #define VME16_MASK MBIO_MASK
     1.1  fredette #endif
     1.1  fredette #include <arch/sun2/sun2/mbmem.h>
     1.1  fredette #include <arch/sun2/sun2/mbio.h>
     1.1  fredette
     1.1  fredette #include <stand.h>
     1.1  fredette
     1.1  fredette #include "libsa.h"
     1.1  fredette #include "dvma.h"
     1.1  fredette #include "saio.h"	/* enum MAPTYPES */
     1.1  fredette
     1.1  fredette #define OBIO_MASK 0xFFFFFF
     1.1  fredette
     1.2  fredette u_int	get_pte __P((vaddr_t va));
     1.2  fredette void	set_pte __P((vaddr_t va, u_int pte));
     1.1  fredette char *	dvma2_alloc  __P((int len));
     1.1  fredette void	dvma2_free  __P((char *dvma, int len));
     1.1  fredette char *	dvma2_mapin  __P((char *pkt, int len));
     1.1  fredette void	dvma2_mapout  __P((char *dmabuf, int len));
     1.1  fredette char *	dev2_mapin  __P((int type, u_long addr, int len));
     1.1  fredette
     1.1  fredette struct mapinfo {
     1.1  fredette 	int maptype;
     1.1  fredette 	int pgtype;
     1.1  fredette 	u_int base;
     1.1  fredette 	u_int mask;
     1.1  fredette };
     1.1  fredette
     1.1  fredette #ifdef	notyet
     1.1  fredette struct mapinfo
     1.1  fredette sun2_mapinfo[MAP__NTYPES] = {
     1.1  fredette 	/* On-board memory, I/O */
     1.1  fredette 	{ MAP_MAINMEM,   PGT_OBMEM,   0,          ~0 },
     1.1  fredette 	{ MAP_OBIO,      PGT_OBIO,    0,          OBIO_MASK },
     1.1  fredette 	/* Multibus memory, I/O */
     1.1  fredette 	{ MAP_MBMEM,     PGT_MBMEM, MBMEM_BASE, MBMEM_MASK },
     1.1  fredette 	{ MAP_MBIO,      PGT_MBIO,  MBIO_BASE, MBIO_MASK },
     1.1  fredette 	/* VME A16 */
     1.1  fredette 	{ MAP_VME16A16D, PGT_VME_D16, VME16_BASE, VME16_MASK },
     1.1  fredette 	{ MAP_VME16A32D, 0, 0, 0 },
     1.1  fredette 	/* VME A24 */
     1.1  fredette 	{ MAP_VME24A16D, 0, 0, 0 },
     1.1  fredette 	{ MAP_VME24A32D, 0, 0, 0 },
     1.1  fredette 	/* VME A32 */
     1.1  fredette 	{ MAP_VME32A16D, 0, 0, 0 },
     1.1  fredette 	{ MAP_VME32A32D, 0, 0, 0 },
     1.1  fredette };
     1.1  fredette #endif
     1.1  fredette
     1.1  fredette /* The virtual address we will use for PROM device mappings. */
     1.1  fredette int sun2_devmap = SUN3_MONSHORTSEG;
     1.1  fredette
     1.1  fredette char *
     1.1  fredette dev2_mapin(maptype, physaddr, length)
     1.1  fredette 	int maptype;
     1.1  fredette 	u_long physaddr;
     1.1  fredette 	int length;
     1.1  fredette {
     1.1  fredette #ifdef	notyet
     1.1  fredette 	u_int i, pa, pte, pgva, va;
     1.1  fredette
     1.1  fredette 	if ((sun2_devmap + length) > SUN3_MONSHORTPAGE)
     1.1  fredette 		panic("dev2_mapin: length=%d\n", length);
     1.1  fredette
     1.1  fredette 	for (i = 0; i < MAP__NTYPES; i++)
     1.1  fredette 		if (sun2_mapinfo[i].maptype == maptype)
     1.1  fredette 			goto found;
     1.1  fredette 	panic("dev2_mapin: bad maptype");
     1.1  fredette found:
     1.1  fredette
     1.1  fredette 	if (physaddr & ~(sun2_mapinfo[i].mask))
     1.1  fredette 		panic("dev2_mapin: bad address");
     1.1  fredette 	pa = sun2_mapinfo[i].base += physaddr;
     1.1  fredette
     1.1  fredette 	pte = PA_PGNUM(pa) | PG_PERM |
     1.1  fredette 		sun2_mapinfo[i].pgtype;
     1.1  fredette
     1.1  fredette 	va = pgva = sun2_devmap;
     1.1  fredette 	do {
     1.1  fredette 		set_pte(pgva, pte);
     1.1  fredette 		pgva += NBPG;
     1.1  fredette 		pte += 1;
     1.1  fredette 		length -= NBPG;
     1.1  fredette 	} while (length > 0);
     1.1  fredette 	sun2_devmap = pgva;
     1.1  fredette 	va += (physaddr & PGOFSET);
     1.1  fredette
     1.1  fredette #ifdef	DEBUG_PROM
     1.1  fredette 	if (debug)
     1.1  fredette 		printf("dev2_mapin: va=0x%x pte=0x%x\n",
     1.1  fredette 			   va, get_pte(va));
     1.1  fredette #endif
     1.1  fredette 	return ((char*)va);
     1.1  fredette #else
     1.1  fredette 	panic("dev2_mapin");
     1.1  fredette 	return(NULL);
     1.1  fredette #endif
     1.1  fredette }
     1.1  fredette
     1.1  fredette /*****************************************************************
     1.1  fredette  * DVMA support
     1.1  fredette  */
     1.1  fredette
     1.1  fredette /*
     1.1  fredette  * The easiest way to deal with the need for DVMA mappings is to
     1.1  fredette  * create a DVMA alias mapping of the entire address range used by
     1.1  fredette  * the boot program.  That way, dvma_mapin can just compute the
     1.1  fredette  * DVMA alias address, and dvma_mapout does nothing.
     1.1  fredette  *
     1.1  fredette  * Note that this assumes that standalone programs will do I/O
     1.1  fredette  * operations only within range (SA_MIN_VA .. SA_MAX_VA) checked.
     1.1  fredette  */
     1.1  fredette
     1.1  fredette #define DVMA_BASE 0x00f00000
     1.1  fredette #define DVMA_MAPLEN  0x38000	/* 256K - 32K (save MONSHORTSEG) */
     1.1  fredette
     1.1  fredette #define SA_MIN_VA	0x220000
     1.1  fredette #define SA_MAX_VA	(SA_MIN_VA + DVMA_MAPLEN)
     1.1  fredette
     1.1  fredette /* This points to the end of the free DVMA space. */
     1.1  fredette u_int dvma2_end = DVMA_BASE + DVMA_MAPLEN;
     1.1  fredette
     1.1  fredette void
     1.1  fredette dvma2_init()
     1.1  fredette {
     1.1  fredette 	int segva, dmava, sme;
     1.1  fredette
     1.1  fredette 	segva = SA_MIN_VA;
     1.1  fredette 	dmava = DVMA_BASE;
     1.1  fredette
     1.1  fredette 	while (segva < SA_MAX_VA) {
     1.1  fredette 		sme = get_segmap(segva);
     1.1  fredette 		set_segmap(dmava, sme);
     1.1  fredette 		segva += NBSG;
     1.1  fredette 		dmava += NBSG;
     1.1  fredette 	}
     1.1  fredette }
     1.1  fredette
     1.1  fredette /* Convert a local address to a DVMA address. */
     1.1  fredette char *
     1.1  fredette dvma2_mapin(char *addr, int len)
     1.1  fredette {
     1.1  fredette 	int va = (int)addr;
     1.1  fredette
     1.1  fredette 	/* Make sure the address is in the DVMA map. */
     1.1  fredette 	if ((va < SA_MIN_VA) || (va >= SA_MAX_VA))
     1.1  fredette 		panic("dvma2_mapin: 0x%x outside 0x%x..0x%x\n",
     1.1  fredette 		    va, SA_MIN_VA, SA_MAX_VA);
     1.1  fredette
     1.1  fredette 	va -= SA_MIN_VA;
     1.1  fredette 	va += DVMA_BASE;
     1.1  fredette
     1.1  fredette 	return ((char *) va);
     1.1  fredette }
     1.1  fredette
     1.1  fredette /* Destroy a DVMA address alias. */
     1.1  fredette void
     1.1  fredette dvma2_mapout(char *addr, int len)
     1.1  fredette {
     1.1  fredette 	int va = (int)addr;
     1.1  fredette
     1.1  fredette 	/* Make sure the address is in the DVMA map. */
     1.1  fredette 	if ((va < DVMA_BASE) || (va >= (DVMA_BASE + DVMA_MAPLEN)))
     1.1  fredette 		panic("dvma2_mapout");
     1.1  fredette }
     1.1  fredette
     1.1  fredette char *
     1.1  fredette dvma2_alloc(int len)
     1.1  fredette {
     1.1  fredette 	len = m68k_round_page(len);
     1.1  fredette 	dvma2_end -= len;
     1.1  fredette 	return((char*)dvma2_end);
     1.1  fredette }
     1.1  fredette
     1.1  fredette void
     1.1  fredette dvma2_free(char *dvma, int len)
     1.1  fredette {
     1.1  fredette 	/* not worth the trouble */
     1.1  fredette }
     1.1  fredette
     1.1  fredette /*****************************************************************
     1.1  fredette  * Control space stuff...
     1.1  fredette  */
     1.1  fredette
     1.1  fredette u_int
     1.1  fredette get_pte(va)
     1.2  fredette 	vaddr_t va;
     1.1  fredette {
     1.1  fredette 	u_int pte;
     1.1  fredette
     1.1  fredette 	pte = get_control_word(CONTROL_ADDR_BUILD(PGMAP_BASE, va));
     1.1  fredette 	if (pte & PG_VALID) {
     1.1  fredette 		/*
     1.1  fredette 		 * This clears bit 30 (the kernel readable bit, which
     1.1  fredette 		 * should always be set), bit 28 (which should always
     1.1  fredette 		 * be set) and bit 26 (the user writable bit, which we
     1.1  fredette 		 * always have tracking the kernel writable bit).  In
     1.1  fredette 		 * the protection, this leaves bit 29 (the kernel
     1.1  fredette 		 * writable bit) and bit 27 (the user readable bit).
     1.1  fredette 		 * See pte2.h for more about this hack.
     1.1  fredette 		 */
     1.1  fredette 		pte &= ~(0x54000000);
     1.1  fredette 		/*
     1.1  fredette 		 * Flip bit 27 (the user readable bit) to become bit
     1.1  fredette 		 * 27 (the PG_SYSTEM bit).
     1.1  fredette 		 */
     1.1  fredette 		pte ^= (PG_SYSTEM);
     1.1  fredette 	}
     1.1  fredette 	return (pte);
     1.1  fredette }
     1.1  fredette
     1.1  fredette void
     1.1  fredette set_pte(va, pte)
     1.2  fredette 	vaddr_t va;
     1.1  fredette 	u_int pte;
     1.1  fredette {
     1.1  fredette 	if (pte & PG_VALID) {
     1.1  fredette 		/* Clear bit 26 (the user writable bit).  */
     1.1  fredette 		pte &= (~0x04000000);
     1.1  fredette 		/*
     1.1  fredette 		 * Flip bit 27 (the PG_SYSTEM bit) to become bit 27
     1.1  fredette 		 * (the user readable bit).
     1.1  fredette 		 */
     1.1  fredette 		pte ^= (PG_SYSTEM);
     1.1  fredette 		/*
     1.1  fredette 		 * Always set bits 30 (the kernel readable bit) and
     1.1  fredette 		 * bit 28, and set bit 26 (the user writable bit) iff
     1.1  fredette 		 * bit 29 (the kernel writable bit) is set *and* bit
     1.1  fredette 		 * 27 (the user readable bit) is set.  This latter bit
     1.1  fredette 		 * of logic is expressed in the bizarre second term
     1.1  fredette 		 * below, chosen because it needs no branches.
     1.1  fredette 		 */
     1.1  fredette #if (PG_WRITE >> 2) != PG_SYSTEM
     1.1  fredette #error	"PG_WRITE and PG_SYSTEM definitions don't match!"
     1.1  fredette #endif
     1.1  fredette 		pte |= 0x50000000
     1.1  fredette 		    | ((((pte & PG_WRITE) >> 2) & pte) >> 1);
     1.1  fredette 	}
     1.1  fredette 	set_control_word(CONTROL_ADDR_BUILD(PGMAP_BASE, va), pte);
     1.1  fredette }
     1.1  fredette
     1.1  fredette int
     1.1  fredette get_segmap(va)
     1.2  fredette 	vaddr_t va;
     1.1  fredette {
     1.1  fredette 	va = CONTROL_ADDR_BUILD(SEGMAP_BASE, va);
     1.1  fredette 	return (get_control_byte(va));
     1.1  fredette }
     1.1  fredette
     1.1  fredette void
     1.1  fredette set_segmap(va, sme)
     1.2  fredette 	vaddr_t va;
     1.1  fredette 	int sme;
     1.1  fredette {
     1.1  fredette 	va = CONTROL_ADDR_BUILD(SEGMAP_BASE, va);
     1.1  fredette 	set_control_byte(va, sme);
     1.1  fredette }
     1.1  fredette
     1.1  fredette /*
     1.1  fredette  * Copy the IDPROM contents into the passed buffer.
     1.1  fredette  * The caller (idprom.c) will do the checksum.
     1.1  fredette  */
     1.1  fredette void
     1.1  fredette sun2_getidprom(u_char *dst)
     1.1  fredette {
     1.2  fredette 	vaddr_t src;	/* control space address */
     1.1  fredette 	int len, x;
     1.1  fredette
     1.1  fredette 	src = IDPROM_BASE;
     1.1  fredette 	len = sizeof(struct idprom);
     1.1  fredette 	do {
     1.1  fredette 		x = get_control_byte(src);
     1.1  fredette 		src += NBPG;
     1.1  fredette 		*dst++ = x;
     1.1  fredette 	} while (--len > 0);
     1.1  fredette }
     1.1  fredette
     1.1  fredette /*****************************************************************
     1.1  fredette  * Init our function pointers, etc.
     1.1  fredette  */
     1.1  fredette
     1.3  fredette /*
     1.3  fredette  * For booting, the PROM in fredette's Sun 2/120 doesn't map
     1.3  fredette  * much main memory, and what is mapped is mapped strangely.
     1.3  fredette  * Low virtual memory is mapped like:
     1.3  fredette  *
     1.3  fredette  * 0x000000 - 0x0bffff virtual -> 0x000000 - 0x0bffff physical
     1.3  fredette  * 0x0c0000 - 0x0fffff virtual -> invalid
     1.3  fredette  * 0x100000 - 0x13ffff virtual -> 0x0c0000 - 0x0fffff physical
     1.3  fredette  * 0x200800 - 0x3fffff virtual -> 0x200800 - 0x3fffff physical
     1.3  fredette  *
     1.3  fredette  * I think the SunOS authors wanted to load kernels starting at
     1.3  fredette  * physical zero, and assumed that kernels would be less
     1.3  fredette  * than 768K (0x0c0000) long.  Also, the PROM maps physical
     1.3  fredette  * 0x0c0000 - 0x0fffff into DVMA space, so we can't take the
     1.3  fredette  * easy road and just add more mappings to use that physical
     1.3  fredette  * memory while loading (the PROM might do DMA there).
     1.3  fredette  *
     1.3  fredette  * What we do, then, is assume a 4MB machine (you'll really
     1.3  fredette  * need that to run NetBSD at all anyways), and we map two
     1.3  fredette  * chunks of physical and virtual space:
     1.3  fredette  *
     1.3  fredette  * 0x400000 - 0x4bffff virtual -> 0x000000 - 0x0bffff physical
     1.3  fredette  * 0x4c0000 - 0x600000 virtual -> 0x2c0000 - 0x3fffff physical
     1.3  fredette  *
     1.3  fredette  * And then we load starting at virtual 0x400000.  We will do
     1.3  fredette  * all of this mapping just by copying PMEGs.
     1.3  fredette  *
     1.3  fredette  * After the load is done, but before we enter the kernel, we're
     1.3  fredette  * done with the PROM, so we copy the part of the kernel that
     1.3  fredette  * got loaded at physical 0x2c0000 down to physical 0x0c0000.
     1.3  fredette  * This can't just be a PMEG copy; we've actually got to move
     1.3  fredette  * bytes in physical memory.
     1.3  fredette  *
     1.3  fredette  * These two chunks of physical and virtual space are defined
     1.3  fredette  * in macros below.  Some of the macros are only for completeness:
     1.3  fredette  */
     1.3  fredette #define MEM_CHUNK0_SIZE			(0x0c0000)
     1.3  fredette #define MEM_CHUNK0_LOAD_PHYS		(0x000000)
     1.3  fredette #define MEM_CHUNK0_LOAD_VIRT		(0x400000)
     1.3  fredette #define MEM_CHUNK0_LOAD_VIRT_PROM	MEM_CHUNK0_LOAD_PHYS
     1.3  fredette #define MEM_CHUNK0_COPY_PHYS		MEM_CHUNK0_LOAD_PHYS
     1.3  fredette #define MEM_CHUNK0_COPY_VIRT		MEM_CHUNK0_COPY_PHYS
     1.3  fredette
     1.3  fredette #define MEM_CHUNK1_SIZE			(0x140000)
     1.3  fredette #define MEM_CHUNK1_LOAD_PHYS		(0x2c0000)
     1.3  fredette #define MEM_CHUNK1_LOAD_VIRT		(MEM_CHUNK0_LOAD_VIRT + MEM_CHUNK0_SIZE)
     1.3  fredette #define MEM_CHUNK1_LOAD_VIRT_PROM	MEM_CHUNK1_LOAD_PHYS
     1.3  fredette #define MEM_CHUNK1_COPY_PHYS		(MEM_CHUNK0_LOAD_PHYS + MEM_CHUNK0_SIZE)
     1.3  fredette #define MEM_CHUNK1_COPY_VIRT		MEM_CHUNK1_COPY_PHYS
     1.3  fredette
     1.3  fredette /* Maps memory for loading. */
     1.3  fredette u_long
     1.3  fredette sun2_map_mem_load()
     1.3  fredette {
     1.3  fredette 	vaddr_t off;
     1.3  fredette
     1.3  fredette 	/* Map chunk zero for loading. */
     1.3  fredette 	for(off = 0; off < MEM_CHUNK0_SIZE; off += NBSG)
     1.3  fredette 		set_segmap(MEM_CHUNK0_LOAD_VIRT + off,
     1.3  fredette 			   get_segmap(MEM_CHUNK0_LOAD_VIRT_PROM + off));
     1.3  fredette
     1.3  fredette 	/* Map chunk one for loading. */
     1.3  fredette 	for(off = 0; off < MEM_CHUNK1_SIZE; off += NBSG)
     1.3  fredette 		set_segmap(MEM_CHUNK1_LOAD_VIRT + off,
     1.3  fredette 			   get_segmap(MEM_CHUNK1_LOAD_VIRT_PROM + off));
     1.3  fredette
     1.3  fredette 	/* Tell our caller where in virtual space to load. */
     1.3  fredette 	return MEM_CHUNK0_LOAD_VIRT;
     1.3  fredette }
     1.3  fredette
     1.3  fredette /* Remaps memory for running. */
     1.3  fredette void *
     1.3  fredette sun2_map_mem_run(entry)
     1.3  fredette 	void *entry;
     1.3  fredette {
     1.3  fredette 	vaddr_t off, off_end;
     1.3  fredette 	int sme;
     1.3  fredette 	u_int pte;
     1.3  fredette
     1.3  fredette 	/* Chunk zero is already mapped and copied. */
     1.3  fredette
     1.3  fredette 	/* Chunk one needs to be mapped and copied. */
     1.3  fredette 	pte = (get_pte(0) & ~PG_FRAME);
     1.3  fredette 	for(off = 0; off < MEM_CHUNK1_SIZE; ) {
     1.3  fredette
     1.3  fredette 		/*
     1.3  fredette 		 * We use the PMEG immediately before the
     1.3  fredette 		 * segment we're copying in the PROM virtual
     1.3  fredette 		 * mapping of the chunk.  If this is the first
     1.3  fredette 		 * segment, this is the PMEG the PROM used to
     1.3  fredette 		 * map 0x2b8000 virtual to 0x2b8000 physical,
     1.3  fredette 		 * which I'll assume is unused.  For the second
     1.3  fredette 		 * and subsequent segments, this will be the
     1.3  fredette 		 * PMEG used to map the previous segment, which
     1.3  fredette 		 * is now (since we already copied it) unused.
     1.3  fredette 		 */
     1.3  fredette 		sme = get_segmap((MEM_CHUNK1_LOAD_VIRT_PROM + off) - NBSG);
     1.3  fredette 		set_segmap(MEM_CHUNK1_COPY_VIRT + off, sme);
     1.3  fredette
     1.3  fredette 		/* Set the PTEs in this new PMEG. */
     1.3  fredette 		for(off_end = off + NBSG; off < off_end; off += NBPG)
     1.3  fredette 			set_pte(MEM_CHUNK1_COPY_VIRT + off,
     1.3  fredette 				pte | PA_PGNUM(MEM_CHUNK1_COPY_PHYS + off));
     1.3  fredette
     1.3  fredette 		/* Copy this segment. */
     1.3  fredette 		bcopy((caddr_t)(MEM_CHUNK1_LOAD_VIRT + (off - NBSG)),
     1.3  fredette 		      (caddr_t)(MEM_CHUNK1_COPY_VIRT + (off - NBSG)),
     1.3  fredette 		      NBSG);
     1.3  fredette 	}
     1.3  fredette
     1.3  fredette 	/* Tell our caller where in virtual space to enter. */
     1.3  fredette 	return ((caddr_t)entry) - MEM_CHUNK0_LOAD_VIRT;
     1.3  fredette }
     1.3  fredette
     1.1  fredette void
     1.1  fredette sun2_init()
     1.1  fredette {
     1.1  fredette 	/* Set the function pointers. */
     1.1  fredette 	dev_mapin_p   = dev2_mapin;
     1.1  fredette 	dvma_alloc_p  = dvma2_alloc;
     1.1  fredette 	dvma_free_p   = dvma2_free;
     1.1  fredette 	dvma_mapin_p  = dvma2_mapin;
     1.1  fredette 	dvma_mapout_p = dvma2_mapout;
     1.1  fredette
     1.1  fredette 	/* Prepare DVMA segment. */
     1.1  fredette 	dvma2_init();
     1.1  fredette }