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Plan 9 NeXT
#include "u.h"
#include "../port/lib.h"
#include "mem.h"
#include "dat.h"
#include "fns.h"
#include "../port/error.h"
#include "devtab.h"
/*
* real time clock and non-volatile ram
*/
enum {
Paddr= 0x70, /* address port */
Pdata= 0x71, /* data port */
Seconds= 0x00,
Minutes= 0x02,
Hours= 0x04,
Mday= 0x07,
Month= 0x08,
Year= 0x09,
Status= 0x0A,
Nvoff= 128, /* where usable nvram lives */
Nvsize= 256,
Nbcd= 6,
};
typedef struct Rtc Rtc;
struct Rtc
{
int sec;
int min;
int hour;
int mday;
int mon;
int year;
};
QLock rtclock; /* mutex on clock operations */
enum{
Qrtc = 1,
Qnvram,
};
#define NRTC 2
Dirtab rtcdir[]={
"nvram", {Qnvram, 0}, Nvsize, 0664,
"rtc", {Qrtc, 0}, 0, 0664,
};
ulong rtc2sec(Rtc*);
void sec2rtc(ulong, Rtc*);
int *yrsize(int);
void
rtcreset(void)
{
}
void
rtcinit(void)
{
}
Chan*
rtcattach(char *spec)
{
return devattach('r', spec);
}
Chan*
rtcclone(Chan *c, Chan *nc)
{
return devclone(c, nc);
}
int
rtcwalk(Chan *c, char *name)
{
return devwalk(c, name, rtcdir, NRTC, devgen);
}
void
rtcstat(Chan *c, char *dp)
{
devstat(c, dp, rtcdir, NRTC, devgen);
}
Chan*
rtcopen(Chan *c, int omode)
{
omode = openmode(omode);
switch(c->qid.path){
case Qrtc:
if(strcmp(u->p->user, eve)!=0 && omode!=OREAD)
error(Eperm);
break;
case Qnvram:
if(strcmp(u->p->user, eve)!=0)
error(Eperm);
}
return devopen(c, omode, rtcdir, NRTC, devgen);
}
void
rtccreate(Chan *c, char *name, int omode, ulong perm)
{
USED(c, name, omode, perm);
error(Eperm);
}
void
rtcclose(Chan *c)
{
USED(c);
}
#define GETBCD(o) ((bcdclock[o]&0xf) + 10*(bcdclock[o]>>4))
long
rtctime(void)
{
uchar bcdclock[Nbcd];
Rtc rtc;
int i;
for(i = 0; i < 10000; i++){
outb(Paddr, Status);
if((inb(Pdata) & 1) == 0)
break;
}
outb(Paddr, Seconds); bcdclock[0] = inb(Pdata);
outb(Paddr, Minutes); bcdclock[1] = inb(Pdata);
outb(Paddr, Hours); bcdclock[2] = inb(Pdata);
outb(Paddr, Mday); bcdclock[3] = inb(Pdata);
outb(Paddr, Month); bcdclock[4] = inb(Pdata);
outb(Paddr, Year); bcdclock[5] = inb(Pdata);
/*
* convert from BCD
*/
rtc.sec = GETBCD(0);
rtc.min = GETBCD(1);
rtc.hour = GETBCD(2);
rtc.mday = GETBCD(3);
rtc.mon = GETBCD(4);
rtc.year = GETBCD(5);
/*
* the world starts jan 1 1970
*/
if(rtc.year < 70)
rtc.year += 2000;
else
rtc.year += 1900;
return rtc2sec(&rtc);
}
long
rtcread(Chan *c, void *buf, long n, ulong offset)
{
ulong t, ot;
char *a;
if(c->qid.path & CHDIR)
return devdirread(c, buf, n, rtcdir, NRTC, devgen);
switch(c->qid.path){
case Qrtc:
qlock(&rtclock);
t = rtctime();
do{
ot = t;
t = rtctime(); /* make sure there's no skew */
}while(t != ot);
qunlock(&rtclock);
n = readnum(offset, buf, n, t, 12);
return n;
case Qnvram:
a = buf;
if(waserror()){
qunlock(&rtclock);
nexterror();
}
qlock(&rtclock);
for(t = offset; t < offset + n; t++){
if(t >= Nvsize)
break;
outb(Paddr, Nvoff+t);
delay(1);
*a++ = inb(Pdata);
}
qunlock(&rtclock);
poperror();
return t - offset;
}
error(Ebadarg);
return 0;
}
#define PUTBCD(n,o) bcdclock[o] = (n % 10) | (((n / 10) % 10)<<4)
long
rtcwrite(Chan *c, void *buf, long n, ulong offset)
{
int t;
char *a;
Rtc rtc;
ulong secs;
uchar bcdclock[Nbcd];
char *cp, *ep;
USED(c);
if(offset!=0)
error(Ebadarg);
switch(c->qid.path){
case Qrtc:
/*
* read the time
*/
cp = ep = buf;
ep += n;
while(cp < ep){
if(*cp>='0' && *cp<='9')
break;
cp++;
}
secs = strtoul(cp, 0, 0);
/*
* convert to bcd
*/
sec2rtc(secs, &rtc);
PUTBCD(rtc.sec, 0);
PUTBCD(rtc.min, 1);
PUTBCD(rtc.hour, 2);
PUTBCD(rtc.mday, 3);
PUTBCD(rtc.mon, 4);
PUTBCD(rtc.year, 5);
/*
* write the clock
*/
qlock(&rtclock);
outb(Paddr, Seconds); outb(Pdata, bcdclock[0]);
outb(Paddr, Minutes); outb(Pdata, bcdclock[1]);
outb(Paddr, Hours); outb(Pdata, bcdclock[2]);
outb(Paddr, Mday); outb(Pdata, bcdclock[3]);
outb(Paddr, Month); outb(Pdata, bcdclock[4]);
outb(Paddr, Year); outb(Pdata, bcdclock[5]);
qunlock(&rtclock);
return n;
case Qnvram:
a = buf;
if(waserror()){
qunlock(&rtclock);
nexterror();
}
qlock(&rtclock);
for(t = offset; t < offset + n; t++){
if(t >= Nvsize)
break;
outb(Paddr, Nvoff+t);
outb(Pdata, *a++);
}
qunlock(&rtclock);
poperror();
return t - offset;
}
error(Ebadarg);
return 0;
}
void
rtcremove(Chan *c)
{
USED(c);
error(Eperm);
}
void
rtcwstat(Chan *c, char *dp)
{
USED(c, dp);
error(Eperm);
}
#define SEC2MIN 60L
#define SEC2HOUR (60L*SEC2MIN)
#define SEC2DAY (24L*SEC2HOUR)
/*
* days per month plus days/year
*/
static int dmsize[] =
{
365, 31, 28, 31, 30, 31, 30, 31, 31, 30, 31, 30, 31
};
static int ldmsize[] =
{
366, 31, 29, 31, 30, 31, 30, 31, 31, 30, 31, 30, 31
};
/*
* return the days/month for the given year
*/
int *
yrsize(int yr)
{
if((yr % 4) == 0)
return ldmsize;
else
return dmsize;
}
/*
* compute seconds since Jan 1 1970
*/
ulong
rtc2sec(Rtc *rtc)
{
ulong secs;
int i;
int *d2m;
secs = 0;
/*
* seconds per year
*/
for(i = 1970; i < rtc->year; i++){
d2m = yrsize(i);
secs += d2m[0] * SEC2DAY;
}
/*
* seconds per month
*/
d2m = yrsize(rtc->year);
for(i = 1; i < rtc->mon; i++)
secs += d2m[i] * SEC2DAY;
secs += (rtc->mday-1) * SEC2DAY;
secs += rtc->hour * SEC2HOUR;
secs += rtc->min * SEC2MIN;
secs += rtc->sec;
return secs;
}
/*
* compute rtc from seconds since Jan 1 1970
*/
void
sec2rtc(ulong secs, Rtc *rtc)
{
int d;
long hms, day;
int *d2m;
/*
* break initial number into days
*/
hms = secs % SEC2DAY;
day = secs / SEC2DAY;
if(hms < 0) {
hms += SEC2DAY;
day -= 1;
}
/*
* generate hours:minutes:seconds
*/
rtc->sec = hms % 60;
d = hms / 60;
rtc->min = d % 60;
d /= 60;
rtc->hour = d;
/*
* year number
*/
if(day >= 0)
for(d = 1970; day >= *yrsize(d); d++)
day -= *yrsize(d);
else
for (d = 1970; day < 0; d--)
day += *yrsize(d-1);
rtc->year = d;
/*
* generate month
*/
d2m = yrsize(rtc->year);
for(d = 1; day >= d2m[d]; d++)
day -= d2m[d];
rtc->mday = day + 1;
rtc->mon = d;
return;
}
uchar
nvramread(int offset)
{
outb(Paddr, offset);
delay(1);
return inb(Pdata);
}
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