/*
* 86Box A hypervisor and IBM PC system emulator that specializes in
* running old operating systems and software designed for IBM
* PC systems and compatibles from 1981 through fairly recent
* system designs based on the PCI bus.
*
* This file is part of the 86Box distribution.
*
* SVGA renderers.
*
*
*
* Authors: Sarah Walker,
* Miran Grca,
*
* Copyright 2008-2019 Sarah Walker.
* Copyright 2016-2019 Miran Grca.
*/
#include
#include
#include
#include
#include
#include <86box/86box.h>
#include <86box/device.h>
#include <86box/mem.h>
#include <86box/timer.h>
#include <86box/video.h>
#include <86box/vid_svga.h>
#include <86box/vid_svga_render.h>
#include <86box/vid_svga_render_remap.h>
uint32_t
svga_lookup_lut_ram(svga_t* svga, uint32_t val)
{
if (!svga->lut_map)
return val;
uint8_t r = getcolr(svga->pallook[getcolr(val)]);
uint8_t g = getcolg(svga->pallook[getcolg(val)]);
uint8_t b = getcolb(svga->pallook[getcolb(val)]);
return makecol32(r, g, b) | (val & 0xFF000000);
}
#define lookup_lut(val) svga_lookup_lut_ram(svga, val)
void
svga_render_null(svga_t *svga)
{
if ((svga->displine + svga->y_add) < 0)
return;
if (svga->firstline_draw == 2000)
svga->firstline_draw = svga->displine;
svga->lastline_draw = svga->displine;
}
void
svga_render_blank(svga_t *svga)
{
if ((svga->displine + svga->y_add) < 0)
return;
if (svga->firstline_draw == 2000)
svga->firstline_draw = svga->displine;
svga->lastline_draw = svga->displine;
uint32_t char_width = 0;
switch (svga->seqregs[1] & 9) {
case 0:
char_width = 9;
break;
case 1:
char_width = 8;
break;
case 8:
char_width = 18;
break;
case 9:
char_width = 16;
break;
default:
break;
}
uint32_t *line_ptr = &svga->monitor->target_buffer->line[svga->displine + svga->y_add][svga->x_add];
uint32_t line_width = (uint32_t) (svga->hdisp + svga->scrollcache) * char_width * sizeof(uint32_t);
memset(line_ptr, 0, line_width);
}
void
svga_render_overscan_left(svga_t *svga)
{
if ((svga->displine + svga->y_add) < 0)
return;
if (svga->scrblank || (svga->hdisp == 0))
return;
uint32_t *line_ptr = svga->monitor->target_buffer->line[svga->displine + svga->y_add];
for (int i = 0; i < svga->x_add; i++)
*line_ptr++ = svga->overscan_color;
}
void
svga_render_overscan_right(svga_t *svga)
{
int right;
if ((svga->displine + svga->y_add) < 0)
return;
if (svga->scrblank || (svga->hdisp == 0))
return;
uint32_t *line_ptr = &svga->monitor->target_buffer->line[svga->displine + svga->y_add][svga->x_add + svga->hdisp];
right = (overscan_x >> 1);
for (int i = 0; i < right; i++)
*line_ptr++ = svga->overscan_color;
}
void
svga_render_text_40(svga_t *svga)
{
uint32_t *p;
int xx;
int drawcursor;
int xinc;
uint8_t chr;
uint8_t attr;
uint8_t dat;
uint32_t charaddr;
int fg;
int bg;
uint32_t addr = 0;
if ((svga->displine + svga->y_add) < 0)
return;
if (svga->firstline_draw == 2000)
svga->firstline_draw = svga->displine;
svga->lastline_draw = svga->displine;
if (svga->fullchange) {
p = &svga->monitor->target_buffer->line[svga->displine + svga->y_add][svga->x_add];
xinc = (svga->seqregs[1] & 1) ? 16 : 18;
for (int x = 0; x < (svga->hdisp + svga->scrollcache); x += xinc) {
if (!svga->force_old_addr)
addr = svga->remap_func(svga, svga->ma) & svga->vram_display_mask;
drawcursor = ((svga->ma == svga->ca) && svga->con && svga->cursoron);
if (svga->force_old_addr) {
chr = svga->vram[(svga->ma << 1) & svga->vram_display_mask];
attr = svga->vram[((svga->ma << 1) + 1) & svga->vram_display_mask];
} else {
chr = svga->vram[addr];
attr = svga->vram[addr + 1];
}
if (attr & 8)
charaddr = svga->charsetb + (chr * 128);
else
charaddr = svga->charseta + (chr * 128);
if (drawcursor) {
bg = svga->pallook[svga->egapal[attr & 15]];
fg = svga->pallook[svga->egapal[attr >> 4]];
} else {
fg = svga->pallook[svga->egapal[attr & 15]];
bg = svga->pallook[svga->egapal[attr >> 4]];
if (attr & 0x80 && svga->attrregs[0x10] & 8) {
bg = svga->pallook[svga->egapal[(attr >> 4) & 7]];
if (svga->blink & 16)
fg = bg;
}
}
dat = svga->vram[charaddr + (svga->sc << 2)];
if (svga->seqregs[1] & 1) {
for (xx = 0; xx < 16; xx += 2)
p[xx] = p[xx + 1] = (dat & (0x80 >> (xx >> 1))) ? fg : bg;
} else {
for (xx = 0; xx < 16; xx += 2)
p[xx] = p[xx + 1] = (dat & (0x80 >> (xx >> 1))) ? fg : bg;
if ((chr & ~0x1f) != 0xc0 || !(svga->attrregs[0x10] & 4))
p[16] = p[17] = bg;
else
p[16] = p[17] = (dat & 1) ? fg : bg;
}
svga->ma += 4;
p += xinc;
}
svga->ma &= svga->vram_display_mask;
}
}
void
svga_render_text_80(svga_t *svga)
{
uint32_t *p;
int xx;
int drawcursor;
int xinc;
uint8_t chr;
uint8_t attr;
uint8_t dat;
uint32_t charaddr;
int fg;
int bg;
uint32_t addr = 0;
if ((svga->displine + svga->y_add) < 0)
return;
if (svga->firstline_draw == 2000)
svga->firstline_draw = svga->displine;
svga->lastline_draw = svga->displine;
if (svga->fullchange) {
p = &svga->monitor->target_buffer->line[svga->displine + svga->y_add][svga->x_add];
xinc = (svga->seqregs[1] & 1) ? 8 : 9;
for (int x = 0; x < (svga->hdisp + svga->scrollcache); x += xinc) {
if (!svga->force_old_addr)
addr = svga->remap_func(svga, svga->ma) & svga->vram_display_mask;
drawcursor = ((svga->ma == svga->ca) && svga->con && svga->cursoron);
if (svga->force_old_addr) {
chr = svga->vram[(svga->ma << 1) & svga->vram_display_mask];
attr = svga->vram[((svga->ma << 1) + 1) & svga->vram_display_mask];
} else {
chr = svga->vram[addr];
attr = svga->vram[addr + 1];
}
if (attr & 8)
charaddr = svga->charsetb + (chr * 128);
else
charaddr = svga->charseta + (chr * 128);
if (drawcursor) {
bg = svga->pallook[svga->egapal[attr & 15]];
fg = svga->pallook[svga->egapal[attr >> 4]];
} else {
fg = svga->pallook[svga->egapal[attr & 15]];
bg = svga->pallook[svga->egapal[attr >> 4]];
if (attr & 0x80 && svga->attrregs[0x10] & 8) {
bg = svga->pallook[svga->egapal[(attr >> 4) & 7]];
if (svga->blink & 16)
fg = bg;
}
}
dat = svga->vram[charaddr + (svga->sc << 2)];
if (svga->seqregs[1] & 1) {
for (xx = 0; xx < 8; xx++)
p[xx] = (dat & (0x80 >> xx)) ? fg : bg;
} else {
for (xx = 0; xx < 8; xx++)
p[xx] = (dat & (0x80 >> xx)) ? fg : bg;
if ((chr & ~0x1F) != 0xC0 || !(svga->attrregs[0x10] & 4))
p[8] = bg;
else
p[8] = (dat & 1) ? fg : bg;
}
svga->ma += 4;
p += xinc;
}
svga->ma &= svga->vram_display_mask;
}
}
/*Not available on most generic cards.*/
void
svga_render_text_80_ksc5601(svga_t *svga)
{
uint32_t *p;
int xx;
int drawcursor;
int xinc;
uint8_t chr;
uint8_t attr;
uint8_t dat;
uint8_t nextchr;
uint32_t charaddr;
int fg;
int bg;
if ((svga->displine + svga->y_add) < 0)
return;
if (svga->firstline_draw == 2000)
svga->firstline_draw = svga->displine;
svga->lastline_draw = svga->displine;
if (svga->fullchange) {
p = &svga->monitor->target_buffer->line[svga->displine + svga->y_add][svga->x_add];
xinc = (svga->seqregs[1] & 1) ? 8 : 9;
for (int x = 0; x < (svga->hdisp + svga->scrollcache); x += xinc) {
uint32_t addr = svga->remap_func(svga, svga->ma) & svga->vram_display_mask;
drawcursor = ((svga->ma == svga->ca) && svga->con && svga->cursoron);
chr = svga->vram[addr];
nextchr = svga->vram[addr + 8];
attr = svga->vram[addr + 1];
if (drawcursor) {
bg = svga->pallook[svga->egapal[attr & 15]];
fg = svga->pallook[svga->egapal[attr >> 4]];
} else {
fg = svga->pallook[svga->egapal[attr & 15]];
bg = svga->pallook[svga->egapal[attr >> 4]];
if (attr & 0x80 && svga->attrregs[0x10] & 8) {
bg = svga->pallook[svga->egapal[(attr >> 4) & 7]];
if (svga->blink & 16)
fg = bg;
}
}
if ((x + xinc) < svga->hdisp && (chr & (nextchr | svga->ksc5601_sbyte_mask) & 0x80)) {
if ((chr == svga->ksc5601_udc_area_msb[0] || chr == svga->ksc5601_udc_area_msb[1]) && (nextchr > 0xa0 && nextchr < 0xff))
dat = fontdatksc5601_user[(chr == svga->ksc5601_udc_area_msb[1] ? 96 : 0) + (nextchr & 0x7F) - 0x20].chr[svga->sc];
else if (nextchr & 0x80) {
if (svga->ksc5601_swap_mode == 1 && (nextchr > 0xa0 && nextchr < 0xff)) {
if (chr >= 0x80 && chr < 0x99)
chr += 0x30;
else if (chr >= 0xB0 && chr < 0xC9)
chr -= 0x30;
}
dat = fontdatksc5601[((chr & 0x7F) << 7) | (nextchr & 0x7F)].chr[svga->sc];
} else
dat = 0xff;
} else {
if (attr & 8)
charaddr = svga->charsetb + (chr * 128);
else
charaddr = svga->charseta + (chr * 128);
if ((svga->ksc5601_english_font_type >> 8) == 1)
dat = fontdatksc5601[((svga->ksc5601_english_font_type & 0x7F) << 7) | (chr >> 1)].chr[((chr & 1) << 4) | svga->sc];
else
dat = svga->vram[charaddr + (svga->sc << 2)];
}
if (svga->seqregs[1] & 1) {
for (xx = 0; xx < 8; xx++)
p[xx] = (dat & (0x80 >> xx)) ? fg : bg;
} else {
for (xx = 0; xx < 8; xx++)
p[xx] = (dat & (0x80 >> xx)) ? fg : bg;
if (((chr & ~0x1f) != 0xc0) || !(svga->attrregs[0x10] & 4))
p[8] = bg;
else
p[8] = (dat & 1) ? fg : bg;
}
svga->ma += 4;
p += xinc;
if ((x + xinc) < svga->hdisp && (chr & (nextchr | svga->ksc5601_sbyte_mask) & 0x80)) {
attr = svga->vram[((svga->ma << 1) + 1) & svga->vram_display_mask];
if (drawcursor) {
bg = svga->pallook[svga->egapal[attr & 15]];
fg = svga->pallook[svga->egapal[attr >> 4]];
} else {
fg = svga->pallook[svga->egapal[attr & 15]];
bg = svga->pallook[svga->egapal[attr >> 4]];
if (attr & 0x80 && svga->attrregs[0x10] & 8) {
bg = svga->pallook[svga->egapal[(attr >> 4) & 7]];
if (svga->blink & 16)
fg = bg;
}
}
if ((chr == svga->ksc5601_udc_area_msb[0] || chr == svga->ksc5601_udc_area_msb[1]) && (nextchr > 0xa0 && nextchr < 0xff))
dat = fontdatksc5601_user[(chr == svga->ksc5601_udc_area_msb[1] ? 96 : 0) + (nextchr & 0x7F) - 0x20].chr[svga->sc + 16];
else if (nextchr & 0x80)
dat = fontdatksc5601[((chr & 0x7f) << 7) | (nextchr & 0x7F)].chr[svga->sc + 16];
else
dat = 0xff;
if (svga->seqregs[1] & 1) {
for (xx = 0; xx < 8; xx++)
p[xx] = (dat & (0x80 >> xx)) ? fg : bg;
} else {
for (xx = 0; xx < 8; xx++)
p[xx] = (dat & (0x80 >> xx)) ? fg : bg;
if (((chr & ~0x1f) != 0xc0) || !(svga->attrregs[0x10] & 4))
p[8] = bg;
else
p[8] = (dat & 1) ? fg : bg;
}
svga->ma += 4;
p += xinc;
x += xinc;
}
}
svga->ma &= svga->vram_display_mask;
}
}
void
svga_render_2bpp_headland_highres(svga_t *svga)
{
int oddeven;
uint32_t addr;
uint32_t *p;
uint8_t edat[4];
uint8_t dat;
uint32_t changed_addr;
if ((svga->displine + svga->y_add) < 0)
return;
changed_addr = svga->remap_func(svga, svga->ma);
if (svga->changedvram[changed_addr >> 12] || svga->changedvram[(changed_addr >> 12) + 1] || svga->fullchange) {
p = &svga->monitor->target_buffer->line[svga->displine + svga->y_add][svga->x_add];
if (svga->firstline_draw == 2000)
svga->firstline_draw = svga->displine;
svga->lastline_draw = svga->displine;
for (int x = 0; x <= (svga->hdisp + svga->scrollcache); x += 8) {
addr = svga->remap_func(svga, svga->ma);
oddeven = 0;
if (svga->seqregs[1] & 4) {
oddeven = (addr & 4) ? 1 : 0;
edat[0] = svga->vram[addr | oddeven];
edat[2] = svga->vram[addr | oddeven | 0x2];
edat[1] = edat[3] = 0;
} else {
*(uint32_t *) (&edat[0]) = *(uint32_t *) (&svga->vram[addr]);
}
svga->ma += 4;
svga->ma &= svga->vram_mask;
dat = edatlookup[edat[0] >> 6][edat[1] >> 6] | (edatlookup[edat[2] >> 6][edat[3] >> 6] << 2);
p[0] = svga->pallook[svga->egapal[(dat >> 4) & svga->plane_mask]];
p[1] = svga->pallook[svga->egapal[dat & svga->plane_mask]];
dat = edatlookup[(edat[0] >> 4) & 3][(edat[1] >> 4) & 3] | (edatlookup[(edat[2] >> 4) & 3][(edat[3] >> 4) & 3] << 2);
p[2] = svga->pallook[svga->egapal[(dat >> 4) & svga->plane_mask]];
p[3] = svga->pallook[svga->egapal[dat & svga->plane_mask]];
dat = edatlookup[(edat[0] >> 2) & 3][(edat[1] >> 2) & 3] | (edatlookup[(edat[2] >> 2) & 3][(edat[3] >> 2) & 3] << 2);
p[4] = svga->pallook[svga->egapal[(dat >> 4) & svga->plane_mask]];
p[5] = svga->pallook[svga->egapal[dat & svga->plane_mask]];
dat = edatlookup[edat[0] & 3][edat[1] & 3] | (edatlookup[edat[2] & 3][edat[3] & 3] << 2);
p[6] = svga->pallook[svga->egapal[(dat >> 4) & svga->plane_mask]];
p[7] = svga->pallook[svga->egapal[dat & svga->plane_mask]];
p += 8;
}
}
}
static void
svga_render_indexed_gfx(svga_t *svga, bool highres, bool combine8bits)
{
int x;
uint32_t addr;
uint32_t *p;
uint32_t changed_offset;
const bool blinked = !!(svga->blink & 0x10);
const bool attrblink = (!svga->disable_blink) && ((svga->attrregs[0x10] & 0x08) != 0);
/*
The following is likely how it works on an IBM VGA - that is, it works with its BIOS.
But on some cards, certain modes are broken.
- S3 Trio: mode 13h (320x200x8), incbypow2 given as 2 treated as 0
- ET4000/W32i: mode 2Eh (640x480x8), incevery given as 2 treated as 1
*/
const bool forcepacked = combine8bits && (svga->force_old_addr || svga->packed_chain4);
/*
SVGA cards with a high-resolution 8bpp mode may actually bypass the VGA shifter logic.
- HT-216 (+ other Video7 chipsets?) has 0x3C4.0xC8 bit 4 which, when set to 1, loads
bytes directly, bypassing the shifters.
*/
const bool highres8bpp = combine8bits && highres;
const bool dwordload = ((svga->seqregs[0x01] & 0x10) != 0);
const bool wordload = ((svga->seqregs[0x01] & 0x04) != 0) && !dwordload;
const bool wordincr = ((svga->crtc[0x17] & 0x08) != 0);
const bool dwordincr = ((svga->crtc[0x14] & 0x20) != 0) && !wordincr;
const bool dwordshift = ((svga->crtc[0x14] & 0x40) != 0);
const bool wordshift = ((svga->crtc[0x17] & 0x40) == 0) && !dwordshift;
const uint32_t incbypow2 = forcepacked ? 0 : (dwordshift ? 2 : wordshift ? 1 : 0);
const uint32_t incevery = forcepacked ? 1 : (dwordincr ? 4 : wordincr ? 2 : 1);
const uint32_t loadevery = forcepacked ? 1 : (dwordload ? 4 : wordload ? 2 : 1);
const bool shift4bit = ((svga->gdcreg[0x05] & 0x40) == 0x40) || highres8bpp;
const bool shift2bit = (((svga->gdcreg[0x05] & 0x60) == 0x20) && !shift4bit);
const int dwshift = highres ? 0 : 1;
const int dotwidth = 1 << dwshift;
const int charwidth = dotwidth * ((combine8bits && !svga->packed_4bpp) ? 4 : 8);
const uint32_t planemask = 0x11111111 * (uint32_t) (svga->plane_mask);
const uint32_t blinkmask = (attrblink ? 0x88888888 : 0x0);
const uint32_t blinkval = (attrblink && blinked ? 0x88888888 : 0x0);
/*
This is actually a 8x 3-bit lookup table,
preshifted by 2 bits to allow shifting by multiples of 4 bits.
Anyway, when we perform a planar-to-chunky conversion,
we keep the pixel values in a scrambled order.
This lookup table unscrambles them.
WARNING: Octal values are used here!
*/
const uint32_t shift_values = (shift4bit
? ((067452301) << 2)
: shift2bit
? ((026370415) << 2)
: ((002461357) << 2));
if ((svga->displine + svga->y_add) < 0)
return;
if (svga->force_old_addr)
changed_offset = (svga->ma + (svga->sc & ~svga->crtc[0x17] & 3) * 0x8000) >> 12;
else
changed_offset = svga->remap_func(svga, svga->ma) >> 12;
if (!(svga->changedvram[changed_offset] || svga->changedvram[changed_offset + 1] || svga->fullchange))
return;
p = &svga->monitor->target_buffer->line[svga->displine + svga->y_add][svga->x_add];
if (svga->firstline_draw == 2000)
svga->firstline_draw = svga->displine;
svga->lastline_draw = svga->displine;
uint32_t incr_counter = 0;
uint32_t load_counter = 0;
uint32_t edat = 0;
for (x = 0; x <= (svga->hdisp + svga->scrollcache); x += charwidth) {
if (load_counter == 0) {
/* Find our address */
if (svga->force_old_addr) {
addr = ((svga->ma & ~0x3) << incbypow2);
if (incbypow2 == 2) {
if (svga->ma & (4 << 15))
addr |= 0x8;
if (svga->ma & (4 << 14))
addr |= 0x4;
} else if (incbypow2 == 1) {
if ((svga->crtc[0x17] & 0x20)) {
if (svga->ma & (4 << 15))
addr |= 0x4;
} else {
if (svga->ma & (4 << 13))
addr |= 0x4;
}
} else {
/* Nothing */
}
if (!(svga->crtc[0x17] & 0x01))
addr = (addr & ~0x8000) | ((svga->sc & 1) ? 0x8000 : 0);
if (!(svga->crtc[0x17] & 0x02))
addr = (addr & ~0x10000) | ((svga->sc & 2) ? 0x10000 : 0);
} else if (svga->remap_required)
addr = svga->remap_func(svga, svga->ma);
else
addr = svga->ma;
addr &= svga->vram_display_mask;
/* Load VRAM */
edat = *(uint32_t *) &svga->vram[addr];
/*
EGA and VGA actually use 4bpp planar as its native format.
But 4bpp chunky is generally easier to deal with on a modern CPU.
shift4bit is the native format for this renderer (4bpp chunky).
*/
if (svga->ati_4color || !shift4bit) {
if (shift2bit && !svga->ati_4color) {
/* Group 2x 2bpp values into 4bpp values */
edat = (edat & 0xCCCC3333) | ((edat << 14) & 0x33330000) | ((edat >> 14) & 0x0000CCCC);
} else {
/* Group 4x 1bpp values into 4bpp values */
edat = (edat & 0xAA55AA55) | ((edat << 7) & 0x55005500) | ((edat >> 7) & 0x00AA00AA);
edat = (edat & 0xCCCC3333) | ((edat << 14) & 0x33330000) | ((edat >> 14) & 0x0000CCCC);
}
}
} else {
/*
According to the 82C451 VGA clone chipset datasheet, all 4 planes chain in a ring.
So, rotate them all around.
Planar version: edat = (edat >> 8) | (edat << 24);
Here's the chunky version...
*/
edat = ((edat >> 1) & 0x77777777) | ((edat << 3) & 0x88888888);
}
load_counter += 1;
if (load_counter >= loadevery)
load_counter = 0;
incr_counter += 1;
if (incr_counter >= incevery) {
incr_counter = 0;
svga->ma += 4;
/* DISCREPANCY TODO FIXME 2/4bpp used vram_mask, 8bpp used vram_display_mask --GM */
svga->ma &= svga->vram_display_mask;
}
uint32_t current_shift = shift_values;
uint32_t out_edat = edat;
/*
Apply blink
FIXME: Confirm blink behaviour on real hardware
The VGA 4bpp graphics blink logic was a pain to work out.
If plane 3 is enabled in the attribute controller, then:
- if bit 3 is 0, then we force the output of it to be 1.
- if bit 3 is 1, then the output blinks.
This can be tested with Lotus 1-2-3 release 2.3 with the WYSIWYG addon.
If plane 3 is disabled in the attribute controller, then the output blinks.
This can be tested with QBASIC SCREEN 10 - anything using color #2 should
blink and nothing else.
If you can simplify the following and have it still work, give yourself a medal.
*/
out_edat = ((out_edat & planemask & ~blinkmask) | ((out_edat | ~planemask) & blinkmask & blinkval)) ^ blinkmask;
for (int i = 0; i < (8 + (svga->ati_4color ? 8 : 0)); i += (svga->ati_4color ? 4 : 2)) {
/*
c0 denotes the first 4bpp pixel shifted, while c1 denotes the second.
For 8bpp modes, the first 4bpp pixel is the upper 4 bits.
*/
uint32_t c0 = (out_edat >> (current_shift & 0x1C)) & 0xF;
current_shift >>= 3;
uint32_t c1 = (out_edat >> (current_shift & 0x1C)) & 0xF;
current_shift >>= 3;
if (svga->ati_4color) {
uint32_t q[4];
q[0] = svga->pallook[svga->egapal[(c0 & 0x0c) >> 2]];
q[1] = svga->pallook[svga->egapal[c0 & 0x03]];
q[2] = svga->pallook[svga->egapal[(c1 & 0x0c) >> 2]];
q[3] = svga->pallook[svga->egapal[c1 & 0x03]];
const int outoffs = i << dwshift;
for (int ch = 0; ch < 4; ch++) {
for (int subx = 0; subx < dotwidth; subx++)
p[outoffs + subx + (dotwidth * ch)] = q[ch];
}
} else if (combine8bits) {
if (svga->packed_4bpp) {
uint32_t p0 = svga->map8[c0];
uint32_t p1 = svga->map8[c1];
const int outoffs = i << dwshift;
for (int subx = 0; subx < dotwidth; subx++)
p[outoffs + subx] = p0;
for (int subx = 0; subx < dotwidth; subx++)
p[outoffs + subx + dotwidth] = p1;
} else {
uint32_t ccombined = (c0 << 4) | c1;
uint32_t p0 = svga->map8[ccombined];
const int outoffs = (i >> 1) << dwshift;
for (int subx = 0; subx < dotwidth; subx++)
p[outoffs + subx] = p0;
}
} else {
uint32_t p0 = svga->pallook[svga->egapal[c0]];
uint32_t p1 = svga->pallook[svga->egapal[c1]];
const int outoffs = i << dwshift;
for (int subx = 0; subx < dotwidth; subx++)
p[outoffs + subx] = p0;
for (int subx = 0; subx < dotwidth; subx++)
p[outoffs + subx + dotwidth] = p1;
}
}
if (svga->ati_4color)
p += (charwidth << 1);
// p += charwidth;
else
p += charwidth;
}
}
/*
Remap these to the paletted renderer
(*, highres, combine8bits)
*/
void svga_render_2bpp_lowres(svga_t *svga) { svga_render_indexed_gfx(svga, false, false); }
void svga_render_2bpp_highres(svga_t *svga) { svga_render_indexed_gfx(svga, true, false); }
void svga_render_4bpp_lowres(svga_t *svga) { svga_render_indexed_gfx(svga, false, false); }
void svga_render_4bpp_highres(svga_t *svga) { svga_render_indexed_gfx(svga, true, false); }
void svga_render_8bpp_lowres(svga_t *svga) { svga_render_indexed_gfx(svga, false, true); }
void svga_render_8bpp_highres(svga_t *svga) { svga_render_indexed_gfx(svga, true, true); }
void
svga_render_8bpp_incompatible_highres(svga_t *svga)
{
int x;
uint32_t *p;
uint32_t dat;
uint32_t changed_addr;
uint32_t addr;
if ((svga->displine + svga->y_add) < 0)
return;
if (svga->force_old_addr) {
if (svga->changedvram[svga->ma >> 12] || svga->changedvram[(svga->ma >> 12) + 1] || svga->fullchange) {
p = &svga->monitor->target_buffer->line[svga->displine + svga->y_add][svga->x_add];
if (svga->firstline_draw == 2000)
svga->firstline_draw = svga->displine;
svga->lastline_draw = svga->displine;
for (x = 0; x <= (svga->hdisp /* + svga->scrollcache*/); x += 8) {
dat = *(uint32_t *) (&svga->vram[svga->ma & svga->vram_display_mask]);
p[0] = svga->map8[dat & 0xff];
p[1] = svga->map8[(dat >> 8) & 0xff];
p[2] = svga->map8[(dat >> 16) & 0xff];
p[3] = svga->map8[(dat >> 24) & 0xff];
dat = *(uint32_t *) (&svga->vram[(svga->ma + 4) & svga->vram_display_mask]);
p[4] = svga->map8[dat & 0xff];
p[5] = svga->map8[(dat >> 8) & 0xff];
p[6] = svga->map8[(dat >> 16) & 0xff];
p[7] = svga->map8[(dat >> 24) & 0xff];
svga->ma += 8;
p += 8;
}
svga->ma &= svga->vram_display_mask;
}
} else {
changed_addr = svga->remap_func(svga, svga->ma);
if (svga->changedvram[changed_addr >> 12] || svga->changedvram[(changed_addr >> 12) + 1] || svga->fullchange) {
p = &svga->monitor->target_buffer->line[svga->displine + svga->y_add][svga->x_add];
if (svga->firstline_draw == 2000)
svga->firstline_draw = svga->displine;
svga->lastline_draw = svga->displine;
if (!svga->remap_required) {
for (x = 0; x <= (svga->hdisp /* + svga->scrollcache*/); x += 8) {
dat = *(uint32_t *) (&svga->vram[svga->ma & svga->vram_display_mask]);
p[0] = svga->map8[dat & 0xff];
p[1] = svga->map8[(dat >> 8) & 0xff];
p[2] = svga->map8[(dat >> 16) & 0xff];
p[3] = svga->map8[(dat >> 24) & 0xff];
dat = *(uint32_t *) (&svga->vram[(svga->ma + 4) & svga->vram_display_mask]);
p[4] = svga->map8[dat & 0xff];
p[5] = svga->map8[(dat >> 8) & 0xff];
p[6] = svga->map8[(dat >> 16) & 0xff];
p[7] = svga->map8[(dat >> 24) & 0xff];
svga->ma += 8;
p += 8;
}
} else {
for (x = 0; x <= (svga->hdisp /* + svga->scrollcache*/); x += 4) {
addr = svga->remap_func(svga, svga->ma);
dat = *(uint32_t *) (&svga->vram[addr & svga->vram_display_mask]);
p[0] = svga->map8[dat & 0xff];
p[1] = svga->map8[(dat >> 8) & 0xff];
p[2] = svga->map8[(dat >> 16) & 0xff];
p[3] = svga->map8[(dat >> 24) & 0xff];
svga->ma += 4;
p += 4;
}
}
svga->ma &= svga->vram_display_mask;
}
}
}
// TODO: Integrate more of this into the generic paletted renderer --GM
#if 0
void
svga_render_8bpp_lowres(svga_t *svga)
{
int x;
uint32_t *p;
uint32_t dat;
uint32_t changed_addr;
uint32_t addr;
if ((svga->displine + svga->y_add) < 0)
return;
if (svga->force_old_addr) {
if (svga->changedvram[svga->ma >> 12] || svga->changedvram[(svga->ma >> 12) + 1] || svga->fullchange) {
p = &svga->monitor->target_buffer->line[svga->displine + svga->y_add][svga->x_add];
if (svga->firstline_draw == 2000)
svga->firstline_draw = svga->displine;
svga->lastline_draw = svga->displine;
for (x = 0; x <= (svga->hdisp + svga->scrollcache); x += 8) {
dat = *(uint32_t *) (&svga->vram[svga->ma & svga->vram_display_mask]);
p[0] = p[1] = svga->map8[dat & 0xff];
p[2] = p[3] = svga->map8[(dat >> 8) & 0xff];
p[4] = p[5] = svga->map8[(dat >> 16) & 0xff];
p[6] = p[7] = svga->map8[(dat >> 24) & 0xff];
svga->ma += 4;
p += 8;
}
svga->ma &= svga->vram_display_mask;
}
} else {
changed_addr = svga->remap_func(svga, svga->ma);
if (svga->changedvram[changed_addr >> 12] || svga->changedvram[(changed_addr >> 12) + 1] || svga->fullchange) {
p = &svga->monitor->target_buffer->line[svga->displine + svga->y_add][svga->x_add];
if (svga->firstline_draw == 2000)
svga->firstline_draw = svga->displine;
svga->lastline_draw = svga->displine;
if (!svga->remap_required) {
for (x = 0; x <= (svga->hdisp + svga->scrollcache); x += 8) {
dat = *(uint32_t *) (&svga->vram[svga->ma & svga->vram_display_mask]);
p[0] = p[1] = svga->map8[dat & 0xff];
p[2] = p[3] = svga->map8[(dat >> 8) & 0xff];
p[4] = p[5] = svga->map8[(dat >> 16) & 0xff];
p[6] = p[7] = svga->map8[(dat >> 24) & 0xff];
svga->ma += 4;
p += 8;
}
} else {
for (x = 0; x <= (svga->hdisp + svga->scrollcache); x += 8) {
addr = svga->remap_func(svga, svga->ma);
dat = *(uint32_t *) (&svga->vram[addr & svga->vram_display_mask]);
p[0] = p[1] = svga->map8[dat & 0xff];
p[2] = p[3] = svga->map8[(dat >> 8) & 0xff];
p[4] = p[5] = svga->map8[(dat >> 16) & 0xff];
p[6] = p[7] = svga->map8[(dat >> 24) & 0xff];
svga->ma += 4;
p += 8;
}
}
svga->ma &= svga->vram_display_mask;
}
}
}
void
svga_render_8bpp_highres(svga_t *svga)
{
int x;
uint32_t *p;
uint32_t dat;
uint32_t changed_addr;
uint32_t addr;
if ((svga->displine + svga->y_add) < 0)
return;
if (svga->force_old_addr) {
if (svga->changedvram[svga->ma >> 12] || svga->changedvram[(svga->ma >> 12) + 1] || svga->fullchange) {
p = &svga->monitor->target_buffer->line[svga->displine + svga->y_add][svga->x_add];
if (svga->firstline_draw == 2000)
svga->firstline_draw = svga->displine;
svga->lastline_draw = svga->displine;
for (x = 0; x <= (svga->hdisp /* + svga->scrollcache*/); x += 8) {
dat = *(uint32_t *) (&svga->vram[svga->ma & svga->vram_display_mask]);
p[0] = svga->map8[dat & 0xff];
p[1] = svga->map8[(dat >> 8) & 0xff];
p[2] = svga->map8[(dat >> 16) & 0xff];
p[3] = svga->map8[(dat >> 24) & 0xff];
dat = *(uint32_t *) (&svga->vram[(svga->ma + 4) & svga->vram_display_mask]);
p[4] = svga->map8[dat & 0xff];
p[5] = svga->map8[(dat >> 8) & 0xff];
p[6] = svga->map8[(dat >> 16) & 0xff];
p[7] = svga->map8[(dat >> 24) & 0xff];
svga->ma += 8;
p += 8;
}
svga->ma &= svga->vram_display_mask;
}
} else {
changed_addr = svga->remap_func(svga, svga->ma);
if (svga->changedvram[changed_addr >> 12] || svga->changedvram[(changed_addr >> 12) + 1] || svga->fullchange) {
p = &svga->monitor->target_buffer->line[svga->displine + svga->y_add][svga->x_add];
if (svga->firstline_draw == 2000)
svga->firstline_draw = svga->displine;
svga->lastline_draw = svga->displine;
if (!svga->remap_required) {
for (x = 0; x <= (svga->hdisp /* + svga->scrollcache*/); x += 8) {
dat = *(uint32_t *) (&svga->vram[svga->ma & svga->vram_display_mask]);
p[0] = svga->map8[dat & 0xff];
p[1] = svga->map8[(dat >> 8) & 0xff];
p[2] = svga->map8[(dat >> 16) & 0xff];
p[3] = svga->map8[(dat >> 24) & 0xff];
dat = *(uint32_t *) (&svga->vram[(svga->ma + 4) & svga->vram_display_mask]);
p[4] = svga->map8[dat & 0xff];
p[5] = svga->map8[(dat >> 8) & 0xff];
p[6] = svga->map8[(dat >> 16) & 0xff];
p[7] = svga->map8[(dat >> 24) & 0xff];
svga->ma += 8;
p += 8;
}
} else {
for (x = 0; x <= (svga->hdisp /* + svga->scrollcache*/); x += 4) {
addr = svga->remap_func(svga, svga->ma);
dat = *(uint32_t *) (&svga->vram[addr & svga->vram_display_mask]);
p[0] = svga->map8[dat & 0xff];
p[1] = svga->map8[(dat >> 8) & 0xff];
p[2] = svga->map8[(dat >> 16) & 0xff];
p[3] = svga->map8[(dat >> 24) & 0xff];
svga->ma += 4;
p += 4;
}
}
svga->ma &= svga->vram_display_mask;
}
}
}
#endif
void
svga_render_8bpp_tseng_lowres(svga_t *svga)
{
uint32_t *p;
uint32_t dat;
if ((svga->displine + svga->y_add) < 0)
return;
if (svga->changedvram[svga->ma >> 12] || svga->changedvram[(svga->ma >> 12) + 1] || svga->fullchange) {
p = &svga->monitor->target_buffer->line[svga->displine + svga->y_add][svga->x_add];
if (svga->firstline_draw == 2000)
svga->firstline_draw = svga->displine;
svga->lastline_draw = svga->displine;
for (int x = 0; x <= (svga->hdisp + svga->scrollcache); x += 8) {
dat = *(uint32_t *) (&svga->vram[svga->ma & svga->vram_display_mask]);
if (svga->attrregs[0x10] & 0x80)
dat = (dat & ~0xf0) | ((svga->attrregs[0x14] & 0x0f) << 4);
p[0] = p[1] = svga->map8[dat & 0xff];
dat >>= 8;
if (svga->attrregs[0x10] & 0x80)
dat = (dat & ~0xf0) | ((svga->attrregs[0x14] & 0x0f) << 4);
p[2] = p[3] = svga->map8[dat & 0xff];
dat >>= 8;
if (svga->attrregs[0x10] & 0x80)
dat = (dat & ~0xf0) | ((svga->attrregs[0x14] & 0x0f) << 4);
p[4] = p[5] = svga->map8[dat & 0xff];
dat >>= 8;
if (svga->attrregs[0x10] & 0x80)
dat = (dat & ~0xf0) | ((svga->attrregs[0x14] & 0x0f) << 4);
p[6] = p[7] = svga->map8[dat & 0xff];
svga->ma += 4;
p += 8;
}
svga->ma &= svga->vram_display_mask;
}
}
void
svga_render_8bpp_tseng_highres(svga_t *svga)
{
uint32_t *p;
uint32_t dat;
if ((svga->displine + svga->y_add) < 0)
return;
if (svga->changedvram[svga->ma >> 12] || svga->changedvram[(svga->ma >> 12) + 1] || svga->fullchange) {
p = &svga->monitor->target_buffer->line[svga->displine + svga->y_add][svga->x_add];
if (svga->firstline_draw == 2000)
svga->firstline_draw = svga->displine;
svga->lastline_draw = svga->displine;
for (int x = 0; x <= (svga->hdisp /* + svga->scrollcache*/); x += 8) {
dat = *(uint32_t *) (&svga->vram[svga->ma & svga->vram_display_mask]);
if (svga->attrregs[0x10] & 0x80)
dat = (dat & ~0xf0) | ((svga->attrregs[0x14] & 0x0f) << 4);
p[0] = svga->map8[dat & 0xff];
dat >>= 8;
if (svga->attrregs[0x10] & 0x80)
dat = (dat & ~0xf0) | ((svga->attrregs[0x14] & 0x0f) << 4);
p[1] = svga->map8[dat & 0xff];
dat >>= 8;
if (svga->attrregs[0x10] & 0x80)
dat = (dat & ~0xf0) | ((svga->attrregs[0x14] & 0x0f) << 4);
p[2] = svga->map8[dat & 0xff];
dat >>= 8;
if (svga->attrregs[0x10] & 0x80)
dat = (dat & ~0xf0) | ((svga->attrregs[0x14] & 0x0f) << 4);
p[3] = svga->map8[dat & 0xff];
dat = *(uint32_t *) (&svga->vram[(svga->ma + 4) & svga->vram_display_mask]);
if (svga->attrregs[0x10] & 0x80)
dat = (dat & ~0xf0) | ((svga->attrregs[0x14] & 0x0f) << 4);
p[4] = svga->map8[dat & 0xff];
dat >>= 8;
if (svga->attrregs[0x10] & 0x80)
dat = (dat & ~0xf0) | ((svga->attrregs[0x14] & 0x0f) << 4);
p[5] = svga->map8[dat & 0xff];
dat >>= 8;
if (svga->attrregs[0x10] & 0x80)
dat = (dat & ~0xf0) | ((svga->attrregs[0x14] & 0x0f) << 4);
p[6] = svga->map8[dat & 0xff];
dat >>= 8;
if (svga->attrregs[0x10] & 0x80)
dat = (dat & ~0xf0) | ((svga->attrregs[0x14] & 0x0f) << 4);
p[7] = svga->map8[dat & 0xff];
svga->ma += 8;
p += 8;
}
svga->ma &= svga->vram_display_mask;
}
}
void
svga_render_15bpp_lowres(svga_t *svga)
{
int x;
uint32_t *p;
uint32_t dat;
uint32_t changed_addr;
uint32_t addr;
if ((svga->displine + svga->y_add) < 0)
return;
if (svga->force_old_addr) {
if (svga->changedvram[svga->ma >> 12] || svga->changedvram[(svga->ma >> 12) + 1] || svga->fullchange) {
p = &svga->monitor->target_buffer->line[svga->displine + svga->y_add][svga->x_add];
if (svga->firstline_draw == 2000)
svga->firstline_draw = svga->displine;
svga->lastline_draw = svga->displine;
for (x = 0; x <= (svga->hdisp + svga->scrollcache); x += 4) {
dat = *(uint32_t *) (&svga->vram[(svga->ma + (x << 1)) & svga->vram_display_mask]);
p[x << 1] = p[(x << 1) + 1] = svga->conv_16to32(svga, dat & 0xffff, 15);
p[(x << 1) + 2] = p[(x << 1) + 3] = svga->conv_16to32(svga, dat >> 16, 15);
dat = *(uint32_t *) (&svga->vram[(svga->ma + (x << 1) + 4) & svga->vram_display_mask]);
p[(x << 1) + 4] = p[(x << 1) + 5] = svga->conv_16to32(svga, dat & 0xffff, 15);
p[(x << 1) + 6] = p[(x << 1) + 7] = svga->conv_16to32(svga, dat >> 16, 15);
}
svga->ma += x << 1;
svga->ma &= svga->vram_display_mask;
}
} else {
changed_addr = svga->remap_func(svga, svga->ma);
if (svga->changedvram[changed_addr >> 12] || svga->changedvram[(changed_addr >> 12) + 1] || svga->fullchange) {
p = &svga->monitor->target_buffer->line[svga->displine + svga->y_add][svga->x_add];
if (svga->firstline_draw == 2000)
svga->firstline_draw = svga->displine;
svga->lastline_draw = svga->displine;
if (!svga->remap_required) {
for (x = 0; x <= (svga->hdisp + svga->scrollcache); x += 4) {
dat = *(uint32_t *) (&svga->vram[(svga->ma + (x << 1)) & svga->vram_display_mask]);
*p++ = svga->conv_16to32(svga, dat & 0xffff, 15);
*p++ = svga->conv_16to32(svga, dat >> 16, 15);
dat = *(uint32_t *) (&svga->vram[(svga->ma + (x << 1) + 4) & svga->vram_display_mask]);
*p++ = svga->conv_16to32(svga, dat & 0xffff, 15);
*p++ = svga->conv_16to32(svga, dat >> 16, 15);
}
svga->ma += x << 1;
} else {
for (x = 0; x <= (svga->hdisp + svga->scrollcache); x += 2) {
addr = svga->remap_func(svga, svga->ma);
dat = *(uint32_t *) (&svga->vram[addr & svga->vram_display_mask]);
*p++ = svga->conv_16to32(svga, dat & 0xffff, 15);
*p++ = svga->conv_16to32(svga, dat >> 16, 15);
svga->ma += 4;
}
}
svga->ma &= svga->vram_display_mask;
}
}
}
void
svga_render_15bpp_highres(svga_t *svga)
{
int x;
uint32_t *p;
uint32_t dat;
uint32_t changed_addr;
uint32_t addr;
if ((svga->displine + svga->y_add) < 0)
return;
if (svga->force_old_addr) {
if (svga->changedvram[svga->ma >> 12] || svga->changedvram[(svga->ma >> 12) + 1] || svga->fullchange) {
p = &svga->monitor->target_buffer->line[svga->displine + svga->y_add][svga->x_add];
if (svga->firstline_draw == 2000)
svga->firstline_draw = svga->displine;
svga->lastline_draw = svga->displine;
for (x = 0; x <= (svga->hdisp + svga->scrollcache); x += 8) {
dat = *(uint32_t *) (&svga->vram[(svga->ma + (x << 1)) & svga->vram_display_mask]);
p[x] = svga->conv_16to32(svga, dat & 0xffff, 15);
p[x + 1] = svga->conv_16to32(svga, dat >> 16, 15);
dat = *(uint32_t *) (&svga->vram[(svga->ma + (x << 1) + 4) & svga->vram_display_mask]);
p[x + 2] = svga->conv_16to32(svga, dat & 0xffff, 15);
p[x + 3] = svga->conv_16to32(svga, dat >> 16, 15);
dat = *(uint32_t *) (&svga->vram[(svga->ma + (x << 1) + 8) & svga->vram_display_mask]);
p[x + 4] = svga->conv_16to32(svga, dat & 0xffff, 15);
p[x + 5] = svga->conv_16to32(svga, dat >> 16, 15);
dat = *(uint32_t *) (&svga->vram[(svga->ma + (x << 1) + 12) & svga->vram_display_mask]);
p[x + 6] = svga->conv_16to32(svga, dat & 0xffff, 15);
p[x + 7] = svga->conv_16to32(svga, dat >> 16, 15);
}
svga->ma += x << 1;
svga->ma &= svga->vram_display_mask;
}
} else {
changed_addr = svga->remap_func(svga, svga->ma);
if (svga->changedvram[changed_addr >> 12] || svga->changedvram[(changed_addr >> 12) + 1] || svga->fullchange) {
p = &svga->monitor->target_buffer->line[svga->displine + svga->y_add][svga->x_add];
if (svga->firstline_draw == 2000)
svga->firstline_draw = svga->displine;
svga->lastline_draw = svga->displine;
if (!svga->remap_required) {
for (x = 0; x <= (svga->hdisp + svga->scrollcache); x += 8) {
dat = *(uint32_t *) (&svga->vram[(svga->ma + (x << 1)) & svga->vram_display_mask]);
*p++ = svga->conv_16to32(svga, dat & 0xffff, 15);
*p++ = svga->conv_16to32(svga, dat >> 16, 15);
dat = *(uint32_t *) (&svga->vram[(svga->ma + (x << 1) + 4) & svga->vram_display_mask]);
*p++ = svga->conv_16to32(svga, dat & 0xffff, 15);
*p++ = svga->conv_16to32(svga, dat >> 16, 15);
dat = *(uint32_t *) (&svga->vram[(svga->ma + (x << 1) + 8) & svga->vram_display_mask]);
*p++ = svga->conv_16to32(svga, dat & 0xffff, 15);
*p++ = svga->conv_16to32(svga, dat >> 16, 15);
dat = *(uint32_t *) (&svga->vram[(svga->ma + (x << 1) + 12) & svga->vram_display_mask]);
*p++ = svga->conv_16to32(svga, dat & 0xffff, 15);
*p++ = svga->conv_16to32(svga, dat >> 16, 15);
}
svga->ma += x << 1;
} else {
for (x = 0; x <= (svga->hdisp + svga->scrollcache); x += 2) {
addr = svga->remap_func(svga, svga->ma);
dat = *(uint32_t *) (&svga->vram[addr & svga->vram_display_mask]);
*p++ = svga->conv_16to32(svga, dat & 0xffff, 15);
*p++ = svga->conv_16to32(svga, dat >> 16, 15);
svga->ma += 4;
}
}
svga->ma &= svga->vram_display_mask;
}
}
}
void
svga_render_15bpp_mix_lowres(svga_t *svga)
{
int x;
uint32_t *p;
uint32_t dat;
if ((svga->displine + svga->y_add) < 0)
return;
if (svga->changedvram[svga->ma >> 12] || svga->changedvram[(svga->ma >> 12) + 1] || svga->fullchange) {
p = &svga->monitor->target_buffer->line[svga->displine + svga->y_add][svga->x_add];
if (svga->firstline_draw == 2000)
svga->firstline_draw = svga->displine;
svga->lastline_draw = svga->displine;
for (x = 0; x <= (svga->hdisp + svga->scrollcache); x += 4) {
dat = *(uint32_t *) (&svga->vram[(svga->ma + (x << 1)) & svga->vram_display_mask]);
p[x << 1] = p[(x << 1) + 1] = (dat & 0x00008000) ? svga->pallook[dat & 0xff] : svga->conv_16to32(svga, dat & 0xffff, 15);
dat >>= 16;
p[(x << 1) + 2] = p[(x << 1) + 3] = (dat & 0x00008000) ? svga->pallook[dat & 0xff] : svga->conv_16to32(svga, dat & 0xffff, 15);
dat = *(uint32_t *) (&svga->vram[(svga->ma + (x << 1) + 4) & svga->vram_display_mask]);
p[(x << 1) + 4] = p[(x << 1) + 5] = (dat & 0x00008000) ? svga->pallook[dat & 0xff] : svga->conv_16to32(svga, dat & 0xffff, 15);
dat >>= 16;
p[(x << 1) + 6] = p[(x << 1) + 7] = (dat & 0x00008000) ? svga->pallook[dat & 0xff] : svga->conv_16to32(svga, dat & 0xffff, 15);
}
svga->ma += x << 1;
svga->ma &= svga->vram_display_mask;
}
}
void
svga_render_15bpp_mix_highres(svga_t *svga)
{
int x;
uint32_t *p;
uint32_t dat;
if ((svga->displine + svga->y_add) < 0)
return;
if (svga->changedvram[svga->ma >> 12] || svga->changedvram[(svga->ma >> 12) + 1] || svga->fullchange) {
p = &svga->monitor->target_buffer->line[svga->displine + svga->y_add][svga->x_add];
if (svga->firstline_draw == 2000)
svga->firstline_draw = svga->displine;
svga->lastline_draw = svga->displine;
for (x = 0; x <= (svga->hdisp + svga->scrollcache); x += 8) {
dat = *(uint32_t *) (&svga->vram[(svga->ma + (x << 1)) & svga->vram_display_mask]);
p[x] = (dat & 0x00008000) ? svga->pallook[dat & 0xff] : svga->conv_16to32(svga, dat & 0xffff, 15);
dat >>= 16;
p[x + 1] = (dat & 0x00008000) ? svga->pallook[dat & 0xff] : svga->conv_16to32(svga, dat & 0xffff, 15);
dat = *(uint32_t *) (&svga->vram[(svga->ma + (x << 1) + 4) & svga->vram_display_mask]);
p[x + 2] = (dat & 0x00008000) ? svga->pallook[dat & 0xff] : svga->conv_16to32(svga, dat & 0xffff, 15);
dat >>= 16;
p[x + 3] = (dat & 0x00008000) ? svga->pallook[dat & 0xff] : svga->conv_16to32(svga, dat & 0xffff, 15);
dat = *(uint32_t *) (&svga->vram[(svga->ma + (x << 1) + 8) & svga->vram_display_mask]);
p[x + 4] = (dat & 0x00008000) ? svga->pallook[dat & 0xff] : svga->conv_16to32(svga, dat & 0xffff, 15);
dat >>= 16;
p[x + 5] = (dat & 0x00008000) ? svga->pallook[dat & 0xff] : svga->conv_16to32(svga, dat & 0xffff, 15);
dat = *(uint32_t *) (&svga->vram[(svga->ma + (x << 1) + 12) & svga->vram_display_mask]);
p[x + 6] = (dat & 0x00008000) ? svga->pallook[dat & 0xff] : svga->conv_16to32(svga, dat & 0xffff, 15);
dat >>= 16;
p[x + 7] = (dat & 0x00008000) ? svga->pallook[dat & 0xff] : svga->conv_16to32(svga, dat & 0xffff, 15);
}
svga->ma += x << 1;
svga->ma &= svga->vram_display_mask;
}
}
void
svga_render_16bpp_lowres(svga_t *svga)
{
int x;
uint32_t *p;
uint32_t dat;
uint32_t changed_addr;
uint32_t addr;
if ((svga->displine + svga->y_add) < 0)
return;
if (svga->force_old_addr) {
if (svga->changedvram[svga->ma >> 12] || svga->changedvram[(svga->ma >> 12) + 1] || svga->fullchange) {
p = &svga->monitor->target_buffer->line[svga->displine + svga->y_add][svga->x_add];
if (svga->firstline_draw == 2000)
svga->firstline_draw = svga->displine;
svga->lastline_draw = svga->displine;
for (x = 0; x <= (svga->hdisp + svga->scrollcache); x += 4) {
dat = *(uint32_t *) (&svga->vram[(svga->ma + (x << 1)) & svga->vram_display_mask]);
p[x << 1] = p[(x << 1) + 1] = svga->conv_16to32(svga, dat & 0xffff, 16);
p[(x << 1) + 2] = p[(x << 1) + 3] = svga->conv_16to32(svga, dat >> 16, 16);
dat = *(uint32_t *) (&svga->vram[(svga->ma + (x << 1) + 4) & svga->vram_display_mask]);
p[(x << 1) + 4] = p[(x << 1) + 5] = svga->conv_16to32(svga, dat & 0xffff, 16);
p[(x << 1) + 6] = p[(x << 1) + 7] = svga->conv_16to32(svga, dat >> 16, 16);
}
svga->ma += x << 1;
svga->ma &= svga->vram_display_mask;
}
} else {
changed_addr = svga->remap_func(svga, svga->ma);
if (svga->changedvram[changed_addr >> 12] || svga->changedvram[(changed_addr >> 12) + 1] || svga->fullchange) {
p = &svga->monitor->target_buffer->line[svga->displine + svga->y_add][svga->x_add];
if (svga->firstline_draw == 2000)
svga->firstline_draw = svga->displine;
svga->lastline_draw = svga->displine;
if (!svga->remap_required) {
for (x = 0; x <= (svga->hdisp + svga->scrollcache); x += 4) {
dat = *(uint32_t *) (&svga->vram[(svga->ma + (x << 1)) & svga->vram_display_mask]);
*p++ = svga->conv_16to32(svga, dat & 0xffff, 16);
*p++ = svga->conv_16to32(svga, dat >> 16, 16);
dat = *(uint32_t *) (&svga->vram[(svga->ma + (x << 1) + 4) & svga->vram_display_mask]);
*p++ = svga->conv_16to32(svga, dat & 0xffff, 16);
*p++ = svga->conv_16to32(svga, dat >> 16, 16);
}
svga->ma += x << 1;
} else {
for (x = 0; x <= (svga->hdisp + svga->scrollcache); x += 2) {
addr = svga->remap_func(svga, svga->ma);
dat = *(uint32_t *) (&svga->vram[addr & svga->vram_display_mask]);
*p++ = svga->conv_16to32(svga, dat & 0xffff, 16);
*p++ = svga->conv_16to32(svga, dat >> 16, 16);
}
svga->ma += 4;
}
svga->ma &= svga->vram_display_mask;
}
}
}
void
svga_render_16bpp_highres(svga_t *svga)
{
int x;
uint32_t *p;
uint32_t dat;
uint32_t changed_addr;
uint32_t addr;
if ((svga->displine + svga->y_add) < 0)
return;
if (svga->force_old_addr) {
if (svga->changedvram[svga->ma >> 12] || svga->changedvram[(svga->ma >> 12) + 1] || svga->fullchange) {
p = &svga->monitor->target_buffer->line[svga->displine + svga->y_add][svga->x_add];
if (svga->firstline_draw == 2000)
svga->firstline_draw = svga->displine;
svga->lastline_draw = svga->displine;
for (x = 0; x <= (svga->hdisp + svga->scrollcache); x += 8) {
uint32_t dat = *(uint32_t *) (&svga->vram[(svga->ma + (x << 1)) & svga->vram_display_mask]);
p[x] = svga->conv_16to32(svga, dat & 0xffff, 16);
p[x + 1] = svga->conv_16to32(svga, dat >> 16, 16);
dat = *(uint32_t *) (&svga->vram[(svga->ma + (x << 1) + 4) & svga->vram_display_mask]);
p[x + 2] = svga->conv_16to32(svga, dat & 0xffff, 16);
p[x + 3] = svga->conv_16to32(svga, dat >> 16, 16);
dat = *(uint32_t *) (&svga->vram[(svga->ma + (x << 1) + 8) & svga->vram_display_mask]);
p[x + 4] = svga->conv_16to32(svga, dat & 0xffff, 16);
p[x + 5] = svga->conv_16to32(svga, dat >> 16, 16);
dat = *(uint32_t *) (&svga->vram[(svga->ma + (x << 1) + 12) & svga->vram_display_mask]);
p[x + 6] = svga->conv_16to32(svga, dat & 0xffff, 16);
p[x + 7] = svga->conv_16to32(svga, dat >> 16, 16);
}
svga->ma += x << 1;
svga->ma &= svga->vram_display_mask;
}
} else {
changed_addr = svga->remap_func(svga, svga->ma);
if (svga->changedvram[changed_addr >> 12] || svga->changedvram[(changed_addr >> 12) + 1] || svga->fullchange) {
p = &svga->monitor->target_buffer->line[svga->displine + svga->y_add][svga->x_add];
if (svga->firstline_draw == 2000)
svga->firstline_draw = svga->displine;
svga->lastline_draw = svga->displine;
if (!svga->remap_required) {
for (x = 0; x <= (svga->hdisp + svga->scrollcache); x += 8) {
dat = *(uint32_t *) (&svga->vram[(svga->ma + (x << 1)) & svga->vram_display_mask]);
*p++ = svga->conv_16to32(svga, dat & 0xffff, 16);
*p++ = svga->conv_16to32(svga, dat >> 16, 16);
dat = *(uint32_t *) (&svga->vram[(svga->ma + (x << 1) + 4) & svga->vram_display_mask]);
*p++ = svga->conv_16to32(svga, dat & 0xffff, 16);
*p++ = svga->conv_16to32(svga, dat >> 16, 16);
dat = *(uint32_t *) (&svga->vram[(svga->ma + (x << 1) + 8) & svga->vram_display_mask]);
*p++ = svga->conv_16to32(svga, dat & 0xffff, 16);
*p++ = svga->conv_16to32(svga, dat >> 16, 16);
dat = *(uint32_t *) (&svga->vram[(svga->ma + (x << 1) + 12) & svga->vram_display_mask]);
*p++ = svga->conv_16to32(svga, dat & 0xffff, 16);
*p++ = svga->conv_16to32(svga, dat >> 16, 16);
}
svga->ma += x << 1;
} else {
for (x = 0; x <= (svga->hdisp + svga->scrollcache); x += 2) {
addr = svga->remap_func(svga, svga->ma);
dat = *(uint32_t *) (&svga->vram[addr & svga->vram_display_mask]);
*p++ = svga->conv_16to32(svga, dat & 0xffff, 16);
*p++ = svga->conv_16to32(svga, dat >> 16, 16);
svga->ma += 4;
}
}
svga->ma &= svga->vram_display_mask;
}
}
}
void
svga_render_24bpp_lowres(svga_t *svga)
{
int x;
uint32_t *p;
uint32_t changed_addr;
uint32_t addr;
uint32_t dat0;
uint32_t dat1;
uint32_t dat2;
uint32_t fg;
if ((svga->displine + svga->y_add) < 0)
return;
if (svga->force_old_addr) {
if ((svga->displine + svga->y_add) < 0)
return;
if (svga->changedvram[svga->ma >> 12] || svga->changedvram[(svga->ma >> 12) + 1] || svga->fullchange) {
if (svga->firstline_draw == 2000)
svga->firstline_draw = svga->displine;
svga->lastline_draw = svga->displine;
for (x = 0; x <= (svga->hdisp + svga->scrollcache); x++) {
fg = svga->vram[svga->ma] | (svga->vram[svga->ma + 1] << 8) | (svga->vram[svga->ma + 2] << 16);
svga->ma += 3;
svga->ma &= svga->vram_display_mask;
svga->monitor->target_buffer->line[svga->displine + svga->y_add][(x << 1) + svga->x_add] = svga->monitor->target_buffer->line[svga->displine + svga->y_add][(x << 1) + 1 + svga->x_add] = lookup_lut(fg);
}
}
} else {
changed_addr = svga->remap_func(svga, svga->ma);
if (svga->changedvram[changed_addr >> 12] || svga->changedvram[(changed_addr >> 12) + 1] || svga->fullchange) {
p = &svga->monitor->target_buffer->line[svga->displine + svga->y_add][svga->x_add];
if (svga->firstline_draw == 2000)
svga->firstline_draw = svga->displine;
svga->lastline_draw = svga->displine;
if (!svga->remap_required) {
for (x = 0; x <= (svga->hdisp + svga->scrollcache); x++) {
dat0 = *(uint32_t *) (&svga->vram[svga->ma & svga->vram_display_mask]);
dat1 = *(uint32_t *) (&svga->vram[(svga->ma + 4) & svga->vram_display_mask]);
dat2 = *(uint32_t *) (&svga->vram[(svga->ma + 8) & svga->vram_display_mask]);
p[0] = p[1] = lookup_lut(dat0 & 0xffffff);
p[2] = p[3] = lookup_lut((dat0 >> 24) | ((dat1 & 0xffff) << 8));
p[4] = p[5] = lookup_lut((dat1 >> 16) | ((dat2 & 0xff) << 16));
p[6] = p[7] = lookup_lut(dat2 >> 8);
svga->ma += 12;
}
} else {
for (x = 0; x <= (svga->hdisp + svga->scrollcache); x += 4) {
addr = svga->remap_func(svga, svga->ma);
dat0 = *(uint32_t *) (&svga->vram[addr & svga->vram_display_mask]);
addr = svga->remap_func(svga, svga->ma + 4);
dat1 = *(uint32_t *) (&svga->vram[addr & svga->vram_display_mask]);
addr = svga->remap_func(svga, svga->ma + 8);
dat2 = *(uint32_t *) (&svga->vram[addr & svga->vram_display_mask]);
p[0] = p[1] = lookup_lut(dat0 & 0xffffff);
p[2] = p[3] = lookup_lut((dat0 >> 24) | ((dat1 & 0xffff) << 8));
p[4] = p[5] = lookup_lut((dat1 >> 16) | ((dat2 & 0xff) << 16));
p[6] = p[7] = lookup_lut(dat2 >> 8);
svga->ma += 12;
}
}
svga->ma &= svga->vram_display_mask;
}
}
}
void
svga_render_24bpp_highres(svga_t *svga)
{
int x;
uint32_t *p;
uint32_t changed_addr;
uint8_t addr;
uint32_t dat0;
uint32_t dat1;
uint32_t dat2;
uint32_t dat;
if ((svga->displine + svga->y_add) < 0)
return;
if (svga->force_old_addr) {
if (svga->changedvram[svga->ma >> 12] || svga->changedvram[(svga->ma >> 12) + 1] || svga->fullchange) {
p = &svga->monitor->target_buffer->line[svga->displine + svga->y_add][svga->x_add];
if (svga->firstline_draw == 2000)
svga->firstline_draw = svga->displine;
svga->lastline_draw = svga->displine;
for (x = 0; x <= (svga->hdisp + svga->scrollcache); x += 4) {
dat = *(uint32_t *) (&svga->vram[svga->ma & svga->vram_display_mask]);
p[x] = lookup_lut(dat & 0xffffff);
dat = *(uint32_t *) (&svga->vram[(svga->ma + 3) & svga->vram_display_mask]);
p[x + 1] = lookup_lut(dat & 0xffffff);
dat = *(uint32_t *) (&svga->vram[(svga->ma + 6) & svga->vram_display_mask]);
p[x + 2] = lookup_lut(dat & 0xffffff);
dat = *(uint32_t *) (&svga->vram[(svga->ma + 9) & svga->vram_display_mask]);
p[x + 3] = lookup_lut(dat & 0xffffff);
svga->ma += 12;
}
svga->ma &= svga->vram_display_mask;
}
} else {
changed_addr = svga->remap_func(svga, svga->ma);
if (svga->changedvram[changed_addr >> 12] || svga->changedvram[(changed_addr >> 12) + 1] || svga->fullchange) {
p = &svga->monitor->target_buffer->line[svga->displine + svga->y_add][svga->x_add];
if (svga->firstline_draw == 2000)
svga->firstline_draw = svga->displine;
svga->lastline_draw = svga->displine;
if (!svga->remap_required) {
for (x = 0; x <= (svga->hdisp + svga->scrollcache); x += 4) {
dat0 = *(uint32_t *) (&svga->vram[svga->ma & svga->vram_display_mask]);
dat1 = *(uint32_t *) (&svga->vram[(svga->ma + 4) & svga->vram_display_mask]);
dat2 = *(uint32_t *) (&svga->vram[(svga->ma + 8) & svga->vram_display_mask]);
*p++ = lookup_lut(dat0 & 0xffffff);
*p++ = lookup_lut((dat0 >> 24) | ((dat1 & 0xffff) << 8));
*p++ = lookup_lut((dat1 >> 16) | ((dat2 & 0xff) << 16));
*p++ = lookup_lut(dat2 >> 8);
svga->ma += 12;
}
} else {
for (x = 0; x <= (svga->hdisp + svga->scrollcache); x += 4) {
addr = svga->remap_func(svga, svga->ma);
dat0 = *(uint32_t *) (&svga->vram[addr & svga->vram_display_mask]);
addr = svga->remap_func(svga, svga->ma + 4);
dat1 = *(uint32_t *) (&svga->vram[addr & svga->vram_display_mask]);
addr = svga->remap_func(svga, svga->ma + 8);
dat2 = *(uint32_t *) (&svga->vram[addr & svga->vram_display_mask]);
*p++ = lookup_lut(dat0 & 0xffffff);
*p++ = lookup_lut((dat0 >> 24) | ((dat1 & 0xffff) << 8));
*p++ = lookup_lut((dat1 >> 16) | ((dat2 & 0xff) << 16));
*p++ = lookup_lut(dat2 >> 8);
svga->ma += 12;
}
}
svga->ma &= svga->vram_display_mask;
}
}
}
void
svga_render_32bpp_lowres(svga_t *svga)
{
int x;
uint32_t *p;
uint32_t dat;
uint32_t changed_addr;
uint32_t addr;
if ((svga->displine + svga->y_add) < 0)
return;
if (svga->force_old_addr) {
if (svga->changedvram[svga->ma >> 12] || svga->changedvram[(svga->ma >> 12) + 1] || svga->fullchange) {
if (svga->firstline_draw == 2000)
svga->firstline_draw = svga->displine;
svga->lastline_draw = svga->displine;
for (x = 0; x <= (svga->hdisp + svga->scrollcache); x++) {
dat = svga->vram[svga->ma] | (svga->vram[svga->ma + 1] << 8) | (svga->vram[svga->ma + 2] << 16);
svga->ma += 4;
svga->ma &= svga->vram_display_mask;
svga->monitor->target_buffer->line[svga->displine + svga->y_add][(x << 1) + svga->x_add] = svga->monitor->target_buffer->line[svga->displine + svga->y_add][(x << 1) + 1 + svga->x_add] = lookup_lut(dat);
}
}
} else {
changed_addr = svga->remap_func(svga, svga->ma);
if (svga->changedvram[changed_addr >> 12] || svga->changedvram[(changed_addr >> 12) + 1] || svga->fullchange) {
p = &svga->monitor->target_buffer->line[svga->displine + svga->y_add][svga->x_add];
if (svga->firstline_draw == 2000)
svga->firstline_draw = svga->displine;
svga->lastline_draw = svga->displine;
if (!svga->remap_required) {
for (x = 0; x <= (svga->hdisp + svga->scrollcache); x++) {
dat = *(uint32_t *) (&svga->vram[(svga->ma + (x << 2)) & svga->vram_display_mask]);
*p++ = lookup_lut(dat & 0xffffff);
*p++ = lookup_lut(dat & 0xffffff);
}
svga->ma += (x * 4);
} else {
for (x = 0; x <= (svga->hdisp + svga->scrollcache); x++) {
addr = svga->remap_func(svga, svga->ma);
dat = *(uint32_t *) (&svga->vram[addr & svga->vram_display_mask]);
*p++ = lookup_lut(dat & 0xffffff);
*p++ = lookup_lut(dat & 0xffffff);
svga->ma += 4;
}
svga->ma &= svga->vram_display_mask;
}
}
}
}
void
svga_render_32bpp_highres(svga_t *svga)
{
int x;
uint32_t *p;
uint32_t dat;
uint32_t changed_addr;
uint32_t addr;
if ((svga->displine + svga->y_add) < 0)
return;
if (svga->force_old_addr) {
if (svga->changedvram[svga->ma >> 12] || svga->changedvram[(svga->ma >> 12) + 1] || svga->changedvram[(svga->ma >> 12) + 2] || svga->fullchange) {
p = &svga->monitor->target_buffer->line[svga->displine + svga->y_add][svga->x_add];
if (svga->firstline_draw == 2000)
svga->firstline_draw = svga->displine;
svga->lastline_draw = svga->displine;
for (x = 0; x <= (svga->hdisp + svga->scrollcache); x++) {
dat = *(uint32_t *) (&svga->vram[(svga->ma + (x << 2)) & svga->vram_display_mask]);
p[x] = lookup_lut(dat & 0xffffff);
}
svga->ma += 4;
svga->ma &= svga->vram_display_mask;
}
} else {
changed_addr = svga->remap_func(svga, svga->ma);
if (svga->changedvram[changed_addr >> 12] || svga->changedvram[(changed_addr >> 12) + 1] || svga->fullchange) {
p = &svga->monitor->target_buffer->line[svga->displine + svga->y_add][svga->x_add];
if (svga->firstline_draw == 2000)
svga->firstline_draw = svga->displine;
svga->lastline_draw = svga->displine;
if (!svga->remap_required) {
for (x = 0; x <= (svga->hdisp + svga->scrollcache); x++) {
dat = *(uint32_t *) (&svga->vram[(svga->ma + (x << 2)) & svga->vram_display_mask]);
*p++ = lookup_lut(dat & 0xffffff);
}
svga->ma += (x * 4);
} else {
for (x = 0; x <= (svga->hdisp + svga->scrollcache); x++) {
addr = svga->remap_func(svga, svga->ma);
dat = *(uint32_t *) (&svga->vram[addr & svga->vram_display_mask]);
*p++ = lookup_lut(dat & 0xffffff);
svga->ma += 4;
}
}
svga->ma &= svga->vram_display_mask;
}
}
}
void
svga_render_ABGR8888_highres(svga_t *svga)
{
int x;
uint32_t *p;
uint32_t dat;
uint32_t changed_addr;
uint32_t addr;
if ((svga->displine + svga->y_add) < 0)
return;
changed_addr = svga->remap_func(svga, svga->ma);
if (svga->changedvram[changed_addr >> 12] || svga->changedvram[(changed_addr >> 12) + 1] || svga->fullchange) {
p = &svga->monitor->target_buffer->line[svga->displine + svga->y_add][svga->x_add];
if (svga->firstline_draw == 2000)
svga->firstline_draw = svga->displine;
svga->lastline_draw = svga->displine;
if (!svga->remap_required) {
for (x = 0; x <= (svga->hdisp + svga->scrollcache); x++) {
dat = *(uint32_t *) (&svga->vram[(svga->ma + (x << 2)) & svga->vram_display_mask]);
*p++ = lookup_lut(((dat & 0xff0000) >> 16) | (dat & 0x00ff00) | ((dat & 0x0000ff) << 16));
}
svga->ma += x * 4;
} else {
for (x = 0; x <= (svga->hdisp + svga->scrollcache); x++) {
addr = svga->remap_func(svga, svga->ma);
dat = *(uint32_t *) (&svga->vram[addr & svga->vram_display_mask]);
*p++ = lookup_lut(((dat & 0xff0000) >> 16) | (dat & 0x00ff00) | ((dat & 0x0000ff) << 16));
svga->ma += 4;
}
}
svga->ma &= svga->vram_display_mask;
}
}
void
svga_render_RGBA8888_highres(svga_t *svga)
{
int x;
uint32_t *p;
uint32_t dat;
uint32_t changed_addr;
uint32_t addr;
if ((svga->displine + svga->y_add) < 0)
return;
changed_addr = svga->remap_func(svga, svga->ma);
if (svga->changedvram[changed_addr >> 12] || svga->changedvram[(changed_addr >> 12) + 1] || svga->fullchange) {
p = &svga->monitor->target_buffer->line[svga->displine + svga->y_add][svga->x_add];
if (svga->firstline_draw == 2000)
svga->firstline_draw = svga->displine;
svga->lastline_draw = svga->displine;
if (!svga->remap_required) {
for (x = 0; x <= (svga->hdisp + svga->scrollcache); x++) {
dat = *(uint32_t *) (&svga->vram[(svga->ma + (x << 2)) & svga->vram_display_mask]);
*p++ = lookup_lut(dat >> 8);
}
svga->ma += (x * 4);
} else {
for (x = 0; x <= (svga->hdisp + svga->scrollcache); x++) {
addr = svga->remap_func(svga, svga->ma);
dat = *(uint32_t *) (&svga->vram[addr & svga->vram_display_mask]);
*p++ = lookup_lut(dat >> 8);
svga->ma += 4;
}
}
svga->ma &= svga->vram_display_mask;
}
}