ref: 0a7d581eec1319c643337d302176b3f9ba565ea5
dir: /sys/src/9/bcm64/mem.c/
#include "u.h"
#include "../port/lib.h"
#include "mem.h"
#include "dat.h"
#include "fns.h"
#define INITMAP (ROUND((uintptr)end + BY2PG, PGLSZ(1))-KZERO)
/*
* Create initial identity map in top-level page table
* (L1BOT) for TTBR0. This page table is only used until
* mmu1init() loads m->mmutop.
*/
void
mmuidmap(uintptr *l1bot)
{
uintptr pa, pe, attr;
attr = PTEWRITE | PTEAF | PTEKERNEL | PTEUXN | PTESH(SHARE_INNER);
pe = -KZERO;
for(pa = PHYSDRAM; pa < pe; pa += PGLSZ(PTLEVELS-1))
l1bot[PTLX(pa, PTLEVELS-1)] = pa | PTEVALID | PTEBLOCK | attr;
}
/*
* Create initial shared kernel page table (L1) for TTBR1.
* This page table coveres the KZERO and VIRTIO.
*/
void
mmu0init(uintptr *l1)
{
uintptr va, pa, pe, attr;
/* KZERO */
attr = PTEWRITE | PTEAF | PTEKERNEL | PTEUXN | PTESH(SHARE_INNER);
pe = -KZERO;
for(pa = PHYSDRAM, va = KZERO; pa < pe; pa += PGLSZ(1), va += PGLSZ(1))
l1[PTL1X(va, 1)] = pa | PTEVALID | PTEBLOCK | attr;
/* VIRTIO */
attr = PTEWRITE | PTEAF | PTEKERNEL | PTEUXN | PTEPXN | PTESH(SHARE_OUTER) | PTEDEVICE;
pe = soc.physio + soc.iosize;
for(pa = soc.physio, va = soc.virtio; pa < pe; pa += PGLSZ(1), va += PGLSZ(1)){
if(((pa|va) & PGLSZ(1)-1) != 0){
l1[PTL1X(va, 1)] = (uintptr)l1 | PTEVALID | PTETABLE;
for(; pa < pe && ((va|pa) & PGLSZ(1)-1) != 0; pa += PGLSZ(0), va += PGLSZ(0)){
assert(l1[PTLX(va, 0)] == 0);
l1[PTLX(va, 0)] = pa | PTEVALID | PTEPAGE | attr;
}
break;
}
l1[PTL1X(va, 1)] = pa | PTEVALID | PTEBLOCK | attr;
}
/* ARMLOCAL */
attr = PTEWRITE | PTEAF | PTEKERNEL | PTEUXN | PTEPXN | PTESH(SHARE_OUTER) | PTEDEVICE;
pe = soc.armlocal + MB;
for(pa = soc.armlocal, va = ARMLOCAL; pa < pe; pa += PGLSZ(1), va += PGLSZ(1)){
if(((pa|va) & PGLSZ(1)-1) != 0){
l1[PTL1X(va, 1)] = (uintptr)l1 | PTEVALID | PTETABLE;
for(; pa < pe && ((va|pa) & PGLSZ(1)-1) != 0; pa += PGLSZ(0), va += PGLSZ(0)){
assert(l1[PTLX(va, 0)] == 0);
l1[PTLX(va, 0)] = pa | PTEVALID | PTEPAGE | attr;
}
break;
}
l1[PTL1X(va, 1)] = pa | PTEVALID | PTEBLOCK | attr;
}
if(PTLEVELS > 2)
for(va = KSEG0; va != 0; va += PGLSZ(2))
l1[PTL1X(va, 2)] = (uintptr)&l1[L1TABLEX(va, 1)] | PTEVALID | PTETABLE;
if(PTLEVELS > 3)
for(va = KSEG0; va != 0; va += PGLSZ(3))
l1[PTL1X(va, 3)] = (uintptr)&l1[L1TABLEX(va, 2)] | PTEVALID | PTETABLE;
}
void
meminit(void)
{
uvlong memsize = 0;
uintptr pa, va;
char *p, *e;
int i;
if(p = getconf("*maxmem")){
memsize = strtoull(p, &e, 0) - PHYSDRAM;
for(i = 1; i < nelem(conf.mem); i++){
if(e <= p || *e != ' ')
break;
p = ++e;
conf.mem[i].base = strtoull(p, &e, 0);
if(e <= p || *e != ' ')
break;
p = ++e;
conf.mem[i].limit = strtoull(p, &e, 0);
}
}
if (memsize < INITMAP) /* sanity */
memsize = INITMAP;
getramsize(&conf.mem[0]);
if(conf.mem[0].limit == 0){
conf.mem[0].base = PHYSDRAM;
conf.mem[0].limit = PHYSDRAM + memsize;
}else if(p != nil)
conf.mem[0].limit = conf.mem[0].base + memsize;
/*
* now we know the real memory regions, unmap
* everything above INITMAP and map again with
* the proper sizes.
*/
coherence();
for(va = INITMAP+KZERO; va != 0; va += PGLSZ(1))
((uintptr*)L1)[PTL1X(va, 1)] = 0;
flushtlb();
pa = PGROUND((uintptr)end)-KZERO;
for(i=0; i<nelem(conf.mem); i++){
if(conf.mem[i].limit >= KMAPEND-KMAP)
conf.mem[i].limit = KMAPEND-KMAP;
if(conf.mem[i].limit <= conf.mem[i].base){
conf.mem[i].limit = conf.mem[i].base = 0;
continue;
}
if(conf.mem[i].base < PHYSDRAM + soc.dramsize
&& conf.mem[i].limit > PHYSDRAM + soc.dramsize)
conf.mem[i].limit = PHYSDRAM + soc.dramsize;
/* take kernel out of allocatable space */
if(pa > conf.mem[i].base && pa < conf.mem[i].limit)
conf.mem[i].base = pa;
kmapram(conf.mem[i].base, conf.mem[i].limit);
}
flushtlb();
/* rampage() is now done, count up the pages for each bank */
for(i=0; i<nelem(conf.mem); i++)
conf.mem[i].npage = (conf.mem[i].limit - conf.mem[i].base)/BY2PG;
}