#include <u.h>
#include <libc.h>
#include <bio.h>
#include "pci.h"
#include "vga.h"
/*
* IBM RGB524.
* 170/220MHz High Performance Palette DAC.
*
* Assumes hooked up to an S3 Vision96[48].
*/
enum {
IndexLo = 0x00,
IndexHi = 0x01,
Data = 0x02,
IndexCtl = 0x03,
};
enum { /* index registers */
MiscClock = 0x02,
PixelFormat = 0x0A,
PLLControl1 = 0x10,
PLLControl2 = 0x11,
PLLReference = 0x14,
Frequency0 = 0x20,
MiscControl1 = 0x70,
MiscControl2 = 0x71,
};
static uchar
setrs2(void)
{
uchar rs2;
rs2 = vgaxi(Crtx, 0x55);
vgaxo(Crtx, 0x55, (rs2 & 0xFC)|0x01);
return rs2;
}
static uchar
rgb524xi(int index)
{
outportb(dacxreg[IndexLo], index & 0xFF);
outportb(dacxreg[IndexHi], (index>>8) & 0xFF);
return inportb(dacxreg[Data]);
}
static void
rgb524xo(int index, uchar data)
{
outportb(dacxreg[IndexLo], index & 0xFF);
outportb(dacxreg[IndexHi], (index>>8) & 0xFF);
outportb(dacxreg[Data], data);
}
static void
restorers2(uchar rs2)
{
vgaxo(Crtx, 0x55, rs2);
}
static void
clock(Vga* vga, Ctlr* ctlr)
{
if(vga->f[0] >= 16250000 && vga->f[0] <= 32000000){
vga->f[0] = (vga->f[0]/250000)*250000;
vga->d[0] = (4*vga->f[0])/1000000 - 65;
}
else if(vga->f[0] >= 32500000 && vga->f[0] <= 64000000){
vga->f[0] = (vga->f[0]/500000)*500000;
vga->d[0] = 0x40|((2*vga->f[0])/1000000 - 65);
}
else if(vga->f[0] >= 65000000 && vga->f[0] <= 128000000){
vga->f[0] = (vga->f[0]/1000000)*1000000;
vga->d[0] = 0x80|(vga->f[0]/1000000 - 65);
}
else if(vga->f[0] >= 130000000 && vga->f[0] <= 220000000){
vga->f[0] = (vga->f[0]/2000000)*2000000;
vga->d[0] = 0xC0|((vga->f[0]/2)/1000000 - 65);
}
else
error("%s: pclk %lud out of range\n",
ctlr->name, vga->f[0]);
}
static void
init(Vga* vga, Ctlr* ctlr)
{
ulong pclk;
char *p;
/*
* Part comes in -170 and -220MHz speed-grades.
*/
pclk = 170000000;
if(p = strrchr(ctlr->name, '-'))
pclk = strtoul(p+1, 0, 0) * 1000000;
/*
* If we don't already have a desired pclk,
* take it from the mode.
* Check it's within range.
*/
if(vga->f[0] == 0)
vga->f[0] = vga->mode->frequency;
if(vga->f[0] > pclk)
error("%s: invalid pclk - %ld\n", ctlr->name, vga->f[0]);
/*
* Determine whether to use clock-doubler or not.
*/
if((ctlr->flag & Uclk2) == 0 && vga->mode->z == 8)
resyncinit(vga, ctlr, Uclk2, 0);
/*
* Clock bits. If the desired video clock is
* one of the two standard VGA clocks it can just be
* set using bits <3:2> of vga->misc, otherwise we
* need to programme the PLL.
*/
vga->misc &= ~0x0C;
if(vga->mode->z == 8 || (vga->f[0] != VgaFreq0 && vga->f[0] != VgaFreq1)){
/*
* Initialise the PLL parameters.
* Use internal FS3 fixed-reference divider.
*/
clock(vga, ctlr);
vga->i[0] = 0x03;
}
else if(vga->f[0] == VgaFreq0)
vga->i[0] = 0;
else if(vga->f[0] == VgaFreq1){
vga->misc |= 0x04;
vga->i[0] = 1;
}
ctlr->flag |= Finit;
}
static void
load(Vga* vga, Ctlr* ctlr)
{
uchar mc2, rs2, x;
char *val;
int f;
rs2 = setrs2();
/*
* Set VgaFreq[01].
*/
rgb524xo(PLLControl1, 0x00);
rgb524xo(Frequency0, 0x24);
rgb524xo(Frequency0+1, 0x30);
if(val = dbattr(vga->attr, "rgb524refclk")){
f = strtol(val, 0, 0);
if(f > 1000000)
f /= 1000000;
rgb524xo(PLLReference, f/2);
}
/*
* Enable pixel programming and clock divide
* factor.
*/
x = rgb524xi(MiscClock) & ~0x0E;
x |= 0x01;
if(ctlr->flag & Uclk2)
x |= 0x02;
rgb524xo(MiscClock, x);
if(vga->mode->z == 1)
rgb524xo(PixelFormat, 0x02);
else if(vga->mode->z == 8)
rgb524xo(PixelFormat, 0x03);
x = rgb524xi(MiscControl1) & ~0x41;
x |= 0x01;
rgb524xo(MiscControl1, x);
mc2 = rgb524xi(MiscControl2) & ~0x41;
vga->crt[0x22] &= ~0x08;
if(vga->i[0] == 3){
rgb524xo(Frequency0+3, vga->d[0]);
rgb524xo(PLLControl1, 0x02);
rgb524xo(PLLControl2, vga->i[0]);
mc2 |= 0x41;
vga->crt[0x22] |= 0x08;
}
rgb524xo(MiscControl2, mc2);
vgaxo(Crtx, 0x22, vga->crt[0x22]);
restorers2(rs2);
ctlr->flag |= Fload;
}
static void
dump(Vga*, Ctlr* ctlr)
{
uchar rs2, r, x[256];
char buf[32];
int df, i, maxf, vcodc, vf;
rs2 = setrs2();
printitem(ctlr->name, "index00");
for(i = 0x00; i < 0x0F; i++){
x[i] = rgb524xi(i);
printreg(x[i]);
}
printitem(ctlr->name, "index10");
for(i = 0x10; i < 0x17; i++){
x[i] = rgb524xi(i);
printreg(x[i]);
}
printitem(ctlr->name, "index20");
for(i = 0x20; i < 0x30; i++){
x[i] = rgb524xi(i);
printreg(x[i]);
}
printitem(ctlr->name, "index30");
for(i = 0x30; i < 0x37; i++){
x[i] = rgb524xi(i);
printreg(x[i]);
}
printitem(ctlr->name, "index40");
for(i = 0x40; i < 0x49; i++){
x[i] = rgb524xi(i);
printreg(x[i]);
}
printitem(ctlr->name, "index60");
for(i = 0x60; i < 0x63; i++){
x[i] = rgb524xi(i);
printreg(x[i]);
}
printitem(ctlr->name, "index70");
for(i = 0x70; i < 0x73; i++){
x[i] = rgb524xi(i);
printreg(x[i]);
}
printitem(ctlr->name, "index8E");
for(i = 0x8E; i < 0x92; i++){
x[i] = rgb524xi(i);
printreg(x[i]);
}
restorers2(rs2);
/*
* x[0x10] pixel clock frequency selection
* 0, 2 for direct programming
* x[0x20-0x2F] pixel frequency 0-15
*/
printitem(ctlr->name, "refclk");
Bprint(&stdout, "%12ud\n", x[PLLReference]*2*1000000);
if((i = (x[0x10] & 0x07)) == 0x00 || i == 0x02){
/*
* Direct programming, external frequency select.
* F[0-4] are probably tied directly to the 2 clock-select
* bits in the VGA Misc register.
*/
if(i == 0)
maxf = 4;
else
maxf = 16;
for(i = 0; i < maxf; i++){
if((r = x[0x20+i]) == 0)
continue;
sprint(buf, "direct F%X", i);
printitem(ctlr->name, buf);
df = (r>>6) & 0x03;
vcodc = r & 0x3F;
vf = 0;
switch(df){
case 0:
vf = (vcodc+65)/4;
break;
case 1:
vf = (vcodc+65)/2;
break;
case 2:
vf = (vcodc+65);
break;
case 3:
vf = (vcodc+65)*2;
break;
}
Bprint(&stdout, "%12ud\n", vf);
}
}
}
Ctlr rgb524 = {
"rgb524", /* name */
0, /* snarf */
0, /* options */
init, /* init */
load, /* load */
dump, /* dump */
};
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