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|
/* $NetBSD: pmap_bootstrap.c,v 1.26 1996/05/18 18:54:52 briggs Exp $ */
/*
* Copyright (c) 1991, 1993
* The Regents of the University of California. All rights reserved.
*
* This code is derived from software contributed to Berkeley by
* the Systems Programming Group of the University of Utah Computer
* Science Department.
*
* 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.
*
* @(#)pmap_bootstrap.c 8.1 (Berkeley) 6/10/93
*/
#include <sys/param.h>
#include <sys/systm.h>
#include <sys/msgbuf.h>
#include <sys/reboot.h>
#include <vm/vm.h>
#include <machine/pte.h>
#include <mac68k/mac68k/clockreg.h>
#include <machine/vmparam.h>
#include <machine/cpu.h>
#include <machine/pmap.h>
#include <machine/autoconf.h>
#include <ufs/mfs/mfs_extern.h>
#include "macrom.h"
#define PA2VA(v, t) (t)((u_int)(v) - firstpa)
extern char *etext;
extern int Sysptsize;
extern char *extiobase, *proc0paddr;
extern st_entry_t *Sysseg;
extern pt_entry_t *Sysptmap, *Sysmap;
extern int maxmem, physmem;
extern int avail_remaining, avail_range, avail_end;
extern vm_offset_t avail_start, avail_next;
extern vm_offset_t virtual_avail, virtual_end;
extern vm_size_t mem_size;
extern int protection_codes[];
extern vm_offset_t reserve_dumppages __P((vm_offset_t));
/*
* These are used to map the RAM:
*/
int numranges; /* = 0 == don't use the ranges */
u_long low[8];
u_long high[8];
extern int nbnumranges;
extern u_long nbphys[];
extern u_long nblog[];
extern signed long nblen[];
#define VIDMAPSIZE btoc(mac68k_round_page(vidlen))
extern u_int32_t mac68k_vidlog;
extern u_int32_t mac68k_vidphys;
extern u_int32_t videoaddr;
extern u_int32_t videorowbytes;
extern u_int32_t videosize;
static int vidlen;
static u_int32_t newvideoaddr;
extern caddr_t ROMBase;
/*
* Special purpose kernel virtual addresses, used for mapping
* physical pages for a variety of temporary or permanent purposes:
*
* CADDR1, CADDR2: pmap zero/copy operations
* vmmap: /dev/mem, crash dumps, parity error checking
* msgbufp: kernel message buffer
*/
caddr_t CADDR1, CADDR2, vmmap;
struct msgbuf *msgbufp;
/*
* Bootstrap the VM system.
*
* This is called with the MMU either on or off. If it's on, we assume
* that it's mapped with the same PA <=> LA mapping that we eventually
* want. The page sizes and the protections will be wrong, anyway.
*
* nextpa is the first address following the loaded kernel. On a IIsi
* on 12 May 1996, that was 0xf9000 beyond firstpa.
*/
void
pmap_bootstrap(nextpa, firstpa)
vm_offset_t nextpa;
register vm_offset_t firstpa;
{
vm_offset_t kstpa, kptpa, vidpa, iiopa, rompa;
vm_offset_t kptmpa, lkptpa, p0upa;
u_int nptpages, kstsize;
int i;
register st_entry_t protoste, *ste;
register pt_entry_t protopte, *pte, *epte;
vidlen = ((videosize >> 16) & 0xffff) * videorowbytes + PGOFSET;
/*
* Calculate important physical addresses:
*
* kstpa kernel segment table 1 page (!040)
* N pages (040)
*
* kptpa statically allocated
* kernel PT pages Sysptsize+ pages
*
* vidpa internal video space for some machines
* PT pages VIDMAPSIZE pages
*
* rompa ROM space
* PT pages ROMMAPSIZE pages
*
* iiopa internal IO space
* PT pages IIOMAPSIZE pages
*
* [ Sysptsize is the number of pages of PT, IIOMAPSIZE and
* NBMAPSIZE are the number of PTEs, hence we need to round
* the total to a page boundary with IO maps at the end. ]
*
* kptmpa kernel PT map 1 page
*
* lkptpa last kernel PT page 1 page
*
* p0upa proc 0 u-area UPAGES pages
*
*/
if (mmutype == MMU_68040)
kstsize = MAXKL2SIZE / (NPTEPG/SG4_LEV2SIZE);
else
kstsize = 1;
kstpa = nextpa;
nextpa += kstsize * NBPG;
kptpa = nextpa;
nptpages = Sysptsize +
(IIOMAPSIZE + ROMMAPSIZE + VIDMAPSIZE + NPTEPG - 1) / NPTEPG;
nextpa += nptpages * NBPG;
vidpa = nextpa - VIDMAPSIZE * sizeof(pt_entry_t);
rompa = vidpa - ROMMAPSIZE * sizeof(pt_entry_t);
iiopa = rompa - IIOMAPSIZE * sizeof(pt_entry_t);
kptmpa = nextpa;
nextpa += NBPG;
lkptpa = nextpa;
nextpa += NBPG;
p0upa = nextpa;
nextpa += USPACE;
if (nextpa > high[0]) {
printf("Failure in BSD boot. nextpa=0x%lx, high[0]=0x%lx.\n",
nextpa, high[0]);
printf("You're hosed! Try booting with 32-bit addressing ");
printf("enabled in the memory control panel.\n");
printf("Older machines may need Mode32 to get that option.\n");
panic("Cannot work with the current memory mappings.\n");
}
/*
* Initialize segment table and kernel page table map.
*
* On 68030s and earlier MMUs the two are identical except for
* the valid bits so both are initialized with essentially the
* same values. On the 68040, which has a mandatory 3-level
* structure, the segment table holds the level 1 table and part
* (or all) of the level 2 table and hence is considerably
* different. Here the first level consists of 128 descriptors
* (512 bytes) each mapping 32mb of address space. Each of these
* points to blocks of 128 second level descriptors (512 bytes)
* each mapping 256kb. Note that there may be additional "segment
* table" pages depending on how large MAXKL2SIZE is.
*
* XXX cramming two levels of mapping into the single "segment"
* table on the 68040 is intended as a temporary hack to get things
* working. The 224mb of address space that this allows will most
* likely be insufficient in the future (at least for the kernel).
*/
if (mmutype == MMU_68040) {
register int num;
/*
* First invalidate the entire "segment table" pages
* (levels 1 and 2 have the same "invalid" value).
*/
pte = PA2VA(kstpa, u_int *);
epte = &pte[kstsize * NPTEPG];
while (pte < epte)
*pte++ = SG_NV;
/*
* Initialize level 2 descriptors (which immediately
* follow the level 1 table). We need:
* NPTEPG / SG4_LEV3SIZE
* level 2 descriptors to map each of the nptpages+1
* pages of PTEs. Note that we set the "used" bit
* now to save the HW the expense of doing it.
*/
num = (nptpages + 1) * (NPTEPG / SG4_LEV3SIZE);
pte = &(PA2VA(kstpa, u_int *))[SG4_LEV1SIZE];
epte = &pte[num];
protoste = kptpa | SG_U | SG_RW | SG_V;
while (pte < epte) {
*pte++ = protoste;
protoste += (SG4_LEV3SIZE * sizeof(st_entry_t));
}
/*
* Initialize level 1 descriptors. We need:
* roundup(num, SG4_LEV2SIZE) / SG4_LEV2SIZE
* level 1 descriptors to map the `num' level 2's.
*/
pte = PA2VA(kstpa, u_int *);
epte = &pte[roundup(num, SG4_LEV2SIZE) / SG4_LEV2SIZE];
protoste = (u_int)&pte[SG4_LEV1SIZE] | SG_U | SG_RW | SG_V;
while (pte < epte) {
*pte++ = protoste;
protoste += (SG4_LEV2SIZE * sizeof(st_entry_t));
}
/*
* Initialize the final level 1 descriptor to map the last
* block of level 2 descriptors.
*/
ste = &(PA2VA(kstpa, u_int*))[SG4_LEV1SIZE-1];
pte = &(PA2VA(kstpa, u_int*))[kstsize*NPTEPG - SG4_LEV2SIZE];
*ste = (u_int)pte | SG_U | SG_RW | SG_V;
/*
* Now initialize the final portion of that block of
* descriptors to map the "last PT page".
*/
pte = &(PA2VA(kstpa, u_int*))
[kstsize*NPTEPG - NPTEPG/SG4_LEV3SIZE];
epte = &pte[NPTEPG/SG4_LEV3SIZE];
protoste = lkptpa | SG_U | SG_RW | SG_V;
while (pte < epte) {
*pte++ = protoste;
protoste += (SG4_LEV3SIZE * sizeof(st_entry_t));
}
/*
* Initialize Sysptmap
*/
pte = PA2VA(kptmpa, u_int *);
epte = &pte[nptpages+1];
protopte = kptpa | PG_RW | PG_CI | PG_V;
while (pte < epte) {
*pte++ = protopte;
protopte += NBPG;
}
/*
* Invalidate all but the last remaining entries in both.
*/
epte = &(PA2VA(kptmpa, u_int *))[NPTEPG-1];
while (pte < epte) {
*pte++ = PG_NV;
}
pte = &(PA2VA(kptmpa, u_int *))[NPTEPG-1];
*pte = lkptpa | PG_RW | PG_CI | PG_V;
} else {
/*
* Map the page table pages in both the HW segment table
* and the software Sysptmap. Note that Sysptmap is also
* considered a PT page hence the +1.
*/
ste = PA2VA(kstpa, u_int*);
pte = PA2VA(kptmpa, u_int*);
epte = &pte[nptpages+1];
protoste = kptpa | SG_RW | SG_V;
protopte = kptpa | PG_RW | PG_CI | PG_V;
while (pte < epte) {
*ste++ = protoste;
*pte++ = protopte;
protoste += NBPG;
protopte += NBPG;
}
/*
* Invalidate all but the last remaining entries in both.
*/
epte = &(PA2VA(kptmpa, u_int *))[NPTEPG-1];
while (pte < epte) {
*ste++ = SG_NV;
*pte++ = PG_NV;
}
/*
* Initialize the last to point to point to the page
* table page allocated earlier.
*/
*ste = lkptpa | SG_RW | SG_V;
*pte = lkptpa | PG_RW | PG_CI | PG_V;
}
/*
* Invalidate all but the final entry in the last kernel PT page
* (u-area PTEs will be validated later). The final entry maps
* the last page of physical memory.
*/
pte = PA2VA(lkptpa, u_int *);
epte = &pte[NPTEPG-1];
while (pte < epte)
*pte++ = PG_NV;
*pte = (0xFFFFF000) | PG_RW | PG_CI | PG_V; /* XXX */
/*
* Initialize kernel page table.
* Start by invalidating the `nptpages' that we have allocated.
*/
pte = PA2VA(kptpa, u_int *);
epte = &pte[nptpages * NPTEPG];
while (pte < epte)
*pte++ = PG_NV;
/*
* Validate PTEs for kernel text (RO)
*/
pte = &(PA2VA(kptpa, u_int *))[mac68k_btop(KERNBASE)];
epte = &pte[mac68k_btop(mac68k_trunc_page(&etext))];
#if defined(KGDB) || defined(DDB)
protopte = firstpa | PG_RW | PG_V; /* XXX RW for now */
#else
protopte = firstpa | PG_RO | PG_V;
#endif
while (pte < epte) {
*pte++ = protopte;
protopte += NBPG;
}
/*
* Validate PTEs for kernel data/bss, dynamic data allocated
* by us so far (nextpa - firstpa bytes), and pages for proc0
* u-area and page table allocated below (RW).
*/
epte = &(PA2VA(kptpa, u_int *))[mac68k_btop(nextpa - firstpa)];
protopte = (protopte & ~PG_PROT) | PG_RW;
/*
* Enable copy-back caching of data pages
*/
if (mmutype == MMU_68040)
protopte |= PG_CCB;
while (pte < epte) {
*pte++ = protopte;
protopte += NBPG;
}
/*
* Finally, validate the internal IO space PTEs (RW+CI).
* We do this here since the 320/350 MMU registers (also
* used, but to a lesser extent, on other models) are mapped
* in this range and it would be nice to be able to access
* them after the MMU is turned on.
*/
pte = PA2VA(iiopa, u_int *);
epte = PA2VA(rompa, u_int *);
protopte = IOBase | PG_RW | PG_CI | PG_V;
while (pte < epte) {
*pte++ = protopte;
protopte += NBPG;
}
pte = PA2VA(rompa, u_int *);
epte = PA2VA(vidpa, u_int *);
protopte = ((u_int) ROMBase) | PG_RO | PG_V;
while (pte < epte) {
*pte++ = protopte;
protopte += NBPG;
}
if (vidlen) {
pte = PA2VA(vidpa, u_int *);
epte = pte + VIDMAPSIZE;
protopte = mac68k_vidphys | PG_RW | PG_V | PG_CI;
while (pte < epte) {
*pte++ = protopte;
protopte += NBPG;
}
}
/*
* Calculate important exported kernel virtual addresses
*/
/*
* Sysseg: base of kernel segment table
*/
Sysseg = PA2VA(kstpa, st_entry_t *);
/*
* Sysptmap: base of kernel page table map
*/
Sysptmap = PA2VA(kptmpa, pt_entry_t *);
/*
* Sysmap: kernel page table (as mapped through Sysptmap)
* Immediately follows `nptpages' of static kernel page table.
*/
Sysmap = (pt_entry_t *)mac68k_ptob(nptpages * NPTEPG);
IOBase = (u_long)mac68k_ptob(nptpages*NPTEPG -
(IIOMAPSIZE + ROMMAPSIZE + VIDMAPSIZE));
ROMBase = (char *)mac68k_ptob(nptpages*NPTEPG -
(ROMMAPSIZE + VIDMAPSIZE));
if (vidlen) {
newvideoaddr = (u_int32_t)
mac68k_ptob(nptpages*NPTEPG - VIDMAPSIZE)
+ (mac68k_vidphys & PGOFSET);
if (mac68k_vidlog)
mac68k_vidlog = newvideoaddr;
}
/*
* Setup u-area for process 0.
*/
/*
* Zero the u-area.
* NOTE: `pte' and `epte' aren't PTEs here.
*/
pte = PA2VA(p0upa, u_int *);
epte = (u_int *) (PA2VA(p0upa, u_int) + USPACE);
while (pte < epte)
*pte++ = 0;
/*
* Remember the u-area address so it can be loaded in the
* proc struct p_addr field later.
*/
proc0paddr = PA2VA(p0upa, char *);
/*
* VM data structures are now initialized, set up data for
* the pmap module.
*/
avail_next = avail_start = mac68k_round_page(nextpa);
avail_remaining = 0;
avail_range = -1;
for (i = 0; i < numranges; i++) {
if (avail_next >= low[i] && avail_next < high[i]) {
avail_range = i;
avail_remaining = high[i] - avail_next;
} else if (avail_range != -1) {
avail_remaining += (high[i] - low[i]);
}
}
physmem = mac68k_btop(avail_remaining + nextpa - firstpa);
avail_remaining -= mac68k_round_page(sizeof(struct msgbuf));
high[numranges - 1] -= mac68k_round_page(sizeof(struct msgbuf));
/* XXX -- this doesn't look correct to me. */
while (high[numranges - 1] < low[numranges - 1]) {
numranges--;
high[numranges - 1] -= low[numranges] - high[numranges];
}
avail_remaining = mac68k_trunc_page(avail_remaining);
avail_end = avail_start + avail_remaining;
avail_remaining = mac68k_btop(avail_remaining);
mem_size = mac68k_ptob(physmem);
virtual_avail = VM_MIN_KERNEL_ADDRESS + (nextpa - firstpa);
virtual_end = VM_MAX_KERNEL_ADDRESS;
/*
* Initialize protection array.
* XXX don't use a switch statement, it might produce an
* absolute "jmp" table.
*/
{
register int *kp;
kp = (int *) &protection_codes;
kp[VM_PROT_NONE|VM_PROT_NONE|VM_PROT_NONE] = 0;
kp[VM_PROT_READ|VM_PROT_NONE|VM_PROT_NONE] = PG_RO;
kp[VM_PROT_READ|VM_PROT_NONE|VM_PROT_EXECUTE] = PG_RO;
kp[VM_PROT_NONE|VM_PROT_NONE|VM_PROT_EXECUTE] = PG_RO;
kp[VM_PROT_NONE|VM_PROT_WRITE|VM_PROT_NONE] = PG_RW;
kp[VM_PROT_NONE|VM_PROT_WRITE|VM_PROT_EXECUTE] = PG_RW;
kp[VM_PROT_READ|VM_PROT_WRITE|VM_PROT_NONE] = PG_RW;
kp[VM_PROT_READ|VM_PROT_WRITE|VM_PROT_EXECUTE] = PG_RW;
}
/*
* Kernel page/segment table allocated in locore,
* just initialize pointers.
*/
{
struct pmap *kpm = (struct pmap *)&kernel_pmap_store;
kpm->pm_stab = Sysseg;
kpm->pm_ptab = Sysmap;
simple_lock_init(&kpm->pm_lock);
kpm->pm_count = 1;
kpm->pm_stpa = (st_entry_t *)kstpa;
/*
* For the 040 we also initialize the free level 2
* descriptor mask noting that we have used:
* 0: level 1 table
* 1 to `num': map page tables
* MAXKL2SIZE-1: maps last-page page table
*/
if (mmutype == MMU_68040) {
register int num;
kpm->pm_stfree = ~l2tobm(0);
num = roundup((nptpages + 1) * (NPTEPG / SG4_LEV3SIZE),
SG4_LEV2SIZE) / SG4_LEV2SIZE;
while (num)
kpm->pm_stfree &= ~l2tobm(num--);
kpm->pm_stfree &= ~l2tobm(MAXKL2SIZE-1);
for (num = MAXKL2SIZE;
num < sizeof(kpm->pm_stfree)*NBBY;
num++)
kpm->pm_stfree &= ~l2tobm(num);
}
}
/*
* Allocate some fixed, special purpose kernel virtual addresses
*/
{
extern vm_offset_t tmp_vpages[];
vm_offset_t va = virtual_avail;
CADDR1 = (caddr_t)va;
va += NBPG;
CADDR2 = (caddr_t)va;
va += NBPG;
vmmap = (caddr_t)va;
va += NBPG;
tmp_vpages[0] = va;
va += NBPG;
msgbufp = (struct msgbuf *)va;
va += NBPG;
virtual_avail = reserve_dumppages(va);
}
}
void
bootstrap_mac68k(tc)
int tc;
{
extern void zs_init __P((void));
extern caddr_t esym;
vm_offset_t nextpa;
caddr_t oldROMBase;
if (mac68k_machine.do_graybars)
printf("Bootstrapping NetBSD/mac68k.\n");
oldROMBase = ROMBase;
mac68k_vidphys = videoaddr;
if ((tc & 0x80000000) && (mmutype == MMU_68030)) {
if (mac68k_machine.do_graybars)
printf("Getting mapping from MMU.\n");
(void) get_mapping();
if (mac68k_machine.do_graybars)
printf("Done.\n");
} else {
/* MMU not enabled. Fake up ranges. */
nbnumranges = 0;
numranges = 1;
low[0] = 0;
high[0] = mac68k_machine.mach_memsize * (1024 * 1024);
if (mac68k_machine.do_graybars)
printf("Faked range to byte 0x%lx.\n", high[0]);
}
nextpa = load_addr + (((int)esym + NBPG - 1) & PG_FRAME);
#if MFS
if (boothowto & RB_MINIROOT) {
int v;
boothowto |= RB_DFLTROOT;
nextpa = mac68k_round_page(nextpa);
if ((v = mfs_initminiroot((caddr_t) nextpa-load_addr)) == 0) {
printf("Error loading miniroot.\n");
}
printf("Loaded %d byte miniroot.\n", v);
nextpa += v;
}
#endif
if (mac68k_machine.do_graybars)
printf("Bootstrapping the pmap system.\n");
pmap_bootstrap(nextpa, load_addr);
if (mac68k_machine.do_graybars)
printf("Pmap bootstrapped.\n");
if (!vidlen)
panic("Don't know how to relocate video!\n");
if (mac68k_machine.do_graybars)
printf("Moving ROMBase from %p to %p.\n",
oldROMBase, ROMBase);
mrg_fixupROMBase(oldROMBase, ROMBase);
if (mac68k_machine.do_graybars)
printf("Video address 0x%lx -> 0x%lx.\n",
(unsigned long) videoaddr,
(unsigned long) newvideoaddr);
mac68k_set_io_offsets(IOBase);
/*
* If the serial ports are going (for console or 'echo'), then
* we need to make sure the IO change gets propagated properly.
* This resets the base addresses for the 8530 (serial) driver.
*
* WARNING!!! No printfs() (etc) BETWEEN zs_init() and the end
* of this function (where we start using the MMU, so the new
* address is correct.
*/
if ( (mac68k_machine.serial_boot_echo)
|| (mac68k_machine.serial_console))
zs_init();
videoaddr = newvideoaddr;
}
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