ref: 0d6a188ddea491e760361c45d9c9fd7ac2f06ffd
dir: /sys/src/9/omap4/mmu.c/
#include "u.h"
#include "../port/lib.h"
#include "mem.h"
#include "dat.h"
#include "fns.h"
#include "io.h"
#include "arm.h"
char iopages[NIOPAGES / 8];
Lock iopagelock;
uchar *periph;
static int
isfree(int i)
{
return (iopages[i / 8] & (1 << (i % 8))) == 0;
}
static void
freeio(int i)
{
iopages[i / 8] &= ~(1 << (i % 8));
}
static int
getiopages(int n)
{
int i, j;
lock(&iopagelock);
for(i = 0; i <= NIOPAGES - n; i++){
for(j = 0; j < n; j++)
if(!isfree(i + j))
goto next;
for(j = 0; j < n; j++)
iopages[(i + j) / 8] |= (1 << ((i + j) % 8));
unlock(&iopagelock);
return i;
next: ;
}
panic("out of i/o pages");
return 0;
}
static void
putiopages(int i, int n)
{
lock(&iopagelock);
while(n--)
freeio(i++);
unlock(&iopagelock);
}
void *
vmap(ulong phys, ulong length)
{
ulong virt, off, *l2;
off = phys % BY2PG;
length = (ROUNDUP(phys + length, BY2PG) - ROUNDDN(phys, BY2PG)) / BY2PG;
if(length == 0)
return nil;
phys = ROUNDDN(phys, BY2PG);
virt = getiopages(length);
l2 = KADDR(IOPT);
l2 += virt;
while(length--){
*l2++ = phys | L2AP(Krw) | Small | PTEIO;
phys += BY2PG;
}
flushtlb();
return (void *) (IZERO + BY2PG * virt + off);
}
void
vunmap(void *virt, ulong length)
{
ulong v, *l2;
if((ulong)virt < IZERO || (ulong)virt >= IZERO + NIOPAGES * BY2PG)
panic("vunmap: virt=%p", virt);
v = (ROUNDDN((ulong) virt, BY2PG) - IZERO) / BY2PG;
length = (ROUNDUP(((ulong) virt) + length, BY2PG) - ROUNDDN((ulong) virt, BY2PG)) / BY2PG;
if(length == 0)
return;
l2 = KADDR(IOPT);
l2 += v;
lock(&iopagelock);
while(length--){
*l2++ = 0;
freeio(v++);
}
unlock(&iopagelock);
flushtlb();
}
void
markidle(int n)
{
setgpio(7 + m->machno, !n);
}
void
mmuinit(void)
{
ulong *l1, l2, *pl2;
int i, n;
extern ulong *uart;
l1 = KADDR(L1PT);
l2 = IOPT;
n = NIOPAGES / 256;
memset(KADDR(l2), 0, n * L2SIZ);
for(i = 0; i < n; i++){
l1[(IZERO / MiB) + i] = l2 | Coarse;
l2 += L2SIZ;
}
uart = vmap((ulong) uart, BY2PG);
periph = vmap(0x48240000, 2 * BY2PG);
memset(l1, 0, sizeof(ulong) * (IZERO / MiB));
l1[4095] = PRIVL2 | Coarse;
pl2 = KADDR(PRIVL2);
for(i = 0; i < 240; i++)
pl2[i] = (0x8FF00000 + i * BY2PG) | L2AP(Krw) | Small | Cached | Buffered;
pl2[240] = PHYSVECTORS | L2AP(Krw) | Small | Cached | Buffered;
pl2[241] = FIRSTMACH | L2AP(Krw) | Small | Cached | Buffered;
flushtlb();
m = (Mach *) MACHADDR;
}
void
mmuswitch(Proc *p)
{
ulong *l1;
l1 = KADDR(L1PT);
memmove(l1, p->l1, sizeof p->l1);
flushtlb();
}
void
putmmu(uintptr va, uintptr pa, Page *)
{
ulong *l1a, *l1b, *l2;
int l1o, l2o;
l1o = va / MiB;
l2o = (va % MiB) / BY2PG;
l1a = KADDR(L1PT);
l1b = up->l1;
if(l1a[l1o] == 0){
if((pa & PTEVALID) == 0)
return;
l2 = xspanalloc(L2SIZ, L2SIZ, 0);
l1a[l1o] = l1b[l1o] = PADDR(l2) | Coarse;
} else
l2 = KADDR(ROUNDDN(l1a[l1o], L2SIZ));
l2 += l2o;
if((pa & PTEVALID) == 0){
*l2 = 0;
flushtlb();
return;
}
*l2 = ROUNDDN(pa, BY2PG) | Small;
if((pa & PTEWRITE) == 0)
*l2 |= L2AP(Uro);
else
*l2 |= L2AP(Urw);
if((pa & PTEUNCACHED) == 0)
*l2 |= Buffered | Cached;
flushtlb();
}
void
flushmmu(void)
{
int s, i;
ulong p;
ulong *l1;
l1 = KADDR(L1PT);
s = splhi();
for(i = 0; i < nelem(up->l1); i++){
p = l1[i];
if(p & Small)
free(KADDR(ROUNDDN(p, BY2PG)));
}
memset(up->l1, 0, sizeof up->l1);
memset(l1, 0, sizeof up->l1);
flushtlb();
splx(s);
}
void
mmurelease(Proc *p)
{
int i;
ulong pg;
if(p == up){
flushmmu();
return;
}
for(i = 0; i < nelem(p->l1); i++){
pg = p->l1[i];
if(pg & Small)
free(KADDR(ROUNDDN(pg, BY2PG)));
}
memset(p->l1, 0, sizeof p->l1);
}
void
countpagerefs()
{
panic("countpagerefs");
}
void*
KADDR(ulong pa)
{
if(pa < (ulong)PHYSDRAM || pa > (ulong)(PHYSDRAM + VECTORS - KZERO))
panic("kaddr: pa=%#.8lux, pc=%p", pa, getcallerpc(&pa));
return (void*)(pa + KZERO - PHYSDRAM);
}
ulong
paddr(void* v)
{
ulong va;
va = (ulong) v;
if(va < KZERO)
panic("paddr: v=%p", v);
return va - KZERO + PHYSDRAM;
}
ulong
cankaddr(ulong arg)
{
if(arg < PHYSDRAM || arg > (ulong)(PHYSDRAM + VECTORS - KZERO))
return 0;
return PHYSDRAM - KZERO - arg;
}