/*
* 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.
*
* Generic SVGA handling.
*
* This is intended to be used by another SVGA driver,
* and not as a card in it's own right.
*
* Version: @(#)vid_svga.c 1.0.42 2020/01/20
*
* Authors: Sarah Walker,
* Miran Grca,
*
* Copyright 2008-2019 Sarah Walker.
* Copyright 2016-2019 Miran Grca.
*/
#include
#include
#include
#include
#include
#include
#include "../86box.h"
#include "../cpu/cpu.h"
#include "../machine/machine.h"
#include "../timer.h"
#include "../io.h"
#include "../pit.h"
#include "../mem.h"
#include "../rom.h"
#include "video.h"
#include "vid_svga.h"
#include "vid_svga_render.h"
void svga_doblit(int y1, int y2, int wx, int wy, svga_t *svga);
extern int cyc_total;
extern uint8_t edatlookup[4][4];
uint8_t svga_rotate[8][256];
/*Primary SVGA device. As multiple video cards are not yet supported this is the
only SVGA device.*/
static svga_t *svga_pri;
svga_t
*svga_get_pri()
{
return svga_pri;
}
void
svga_set_override(svga_t *svga, int val)
{
if (svga->override && !val)
svga->fullchange = changeframecount;
svga->override = val;
if (!val) {
/* Override turned off, restore overscan X and Y per the CRTC. */
if (enable_overscan) {
overscan_y = (svga->rowcount + 1) << 1;
if (overscan_y < 16)
overscan_y = 16;
}
overscan_x = (svga->seqregs[1] & 1) ? 16 : 18;
if (svga->seqregs[1] & 8)
overscan_x <<= 1;
} else
overscan_x = overscan_y = 16;
/* Override turned off, fix overcan X and Y to 16. */
}
void
svga_out(uint16_t addr, uint8_t val, void *p)
{
svga_t *svga = (svga_t *)p;
int c;
uint8_t o, index;
switch (addr) {
case 0x3c0:
case 0x3c1:
if (!svga->attrff) {
svga->attraddr = val & 31;
if ((val & 0x20) != svga->attr_palette_enable) {
svga->fullchange = 3;
svga->attr_palette_enable = val & 0x20;
svga_recalctimings(svga);
}
} else {
if ((svga->attraddr == 0x13) && (svga->attrregs[0x13] != val))
svga->fullchange = changeframecount;
o = svga->attrregs[svga->attraddr & 31];
svga->attrregs[svga->attraddr & 31] = val;
if (svga->attraddr < 16)
svga->fullchange = changeframecount;
if (svga->attraddr == 0x10 || svga->attraddr == 0x14 || svga->attraddr < 0x10) {
for (c = 0; c < 16; c++) {
if (svga->attrregs[0x10] & 0x80) {
svga->egapal[c] = (svga->attrregs[c] & 0xf) |
((svga->attrregs[0x14] & 0xf) << 4);
} else {
svga->egapal[c] = (svga->attrregs[c] & 0x3f) |
((svga->attrregs[0x14] & 0xc) << 4);
}
}
}
/* Recalculate timings on change of attribute register 0x11
(overscan border color) too. */
if (svga->attraddr == 0x10) {
if (o != val)
svga_recalctimings(svga);
} else if (svga->attraddr == 0x11) {
svga->overscan_color = svga->pallook[svga->attrregs[0x11]];
if (o != val)
svga_recalctimings(svga);
} else if (svga->attraddr == 0x12) {
if ((val & 0xf) != svga->plane_mask)
svga->fullchange = changeframecount;
svga->plane_mask = val & 0xf;
}
}
svga->attrff ^= 1;
break;
case 0x3c2:
svga->miscout = val;
svga->vidclock = val & 4;
io_removehandler(0x03a0, 0x0020, svga->video_in, NULL, NULL, svga->video_out, NULL, NULL, svga->p);
if (!(val & 1))
io_sethandler(0x03a0, 0x0020, svga->video_in, NULL, NULL, svga->video_out, NULL, NULL, svga->p);
svga_recalctimings(svga);
break;
case 0x3c4:
svga->seqaddr = val;
break;
case 0x3c5:
if (svga->seqaddr > 0xf)
return;
o = svga->seqregs[svga->seqaddr & 0xf];
svga->seqregs[svga->seqaddr & 0xf] = val;
if (o != val && (svga->seqaddr & 0xf) == 1)
svga_recalctimings(svga);
switch (svga->seqaddr & 0xf) {
case 1:
if (svga->scrblank && !(val & 0x20))
svga->fullchange = 3;
svga->scrblank = (svga->scrblank & ~0x20) | (val & 0x20);
svga_recalctimings(svga);
break;
case 2:
svga->writemask = val & 0xf;
break;
case 3:
svga->charsetb = (((val >> 2) & 3) * 0x10000) + 2;
svga->charseta = ((val & 3) * 0x10000) + 2;
if (val & 0x10)
svga->charseta += 0x8000;
if (val & 0x20)
svga->charsetb += 0x8000;
break;
case 4:
svga->chain2_write = !(val & 4);
svga->chain4 = val & 8;
svga->fast = (svga->gdcreg[8] == 0xff && !(svga->gdcreg[3] & 0x18) &&
!svga->gdcreg[1]) && svga->chain4 && !(svga->adv_flags & FLAG_ADDR_BY8);
break;
}
break;
case 0x3c6:
svga->dac_mask = val;
break;
case 0x3c7:
case 0x3c8:
svga->dac_pos = 0;
svga->dac_status = addr & 0x03;
svga->dac_addr = (val + (addr & 0x01)) & 255;
break;
case 0x3c9:
svga->fullchange = changeframecount;
switch (svga->dac_pos) {
case 0:
svga->dac_r = val;
svga->dac_pos++;
break;
case 1:
svga->dac_g = val;
svga->dac_pos++;
break;
case 2:
index = svga->dac_addr & 255;
svga->vgapal[index].r = svga->dac_r;
svga->vgapal[index].g = svga->dac_g;
svga->vgapal[index].b = val;
if (svga->ramdac_type == RAMDAC_8BIT)
svga->pallook[index] = makecol32(svga->vgapal[index].r, svga->vgapal[index].g, svga->vgapal[index].b);
else
svga->pallook[index] = makecol32(video_6to8[svga->vgapal[index].r & 0x3f], video_6to8[svga->vgapal[index].g & 0x3f], video_6to8[svga->vgapal[index].b & 0x3f]);
svga->dac_pos = 0;
svga->dac_addr = (svga->dac_addr + 1) & 255;
break;
}
break;
case 0x3ce:
svga->gdcaddr = val;
break;
case 0x3cf:
o = svga->gdcreg[svga->gdcaddr & 15];
switch (svga->gdcaddr & 15) {
case 2:
svga->colourcompare = val;
break;
case 4:
svga->readplane = val & 3;
break;
case 5:
svga->writemode = val & 3;
svga->readmode = val & 8;
svga->chain2_read = val & 0x10;
break;
case 6:
if ((svga->gdcreg[6] & 0xc) != (val & 0xc)) {
switch (val&0xC) {
case 0x0: /*128k at A0000*/
mem_mapping_set_addr(&svga->mapping, 0xa0000, 0x20000);
svga->banked_mask = 0xffff;
break;
case 0x4: /*64k at A0000*/
mem_mapping_set_addr(&svga->mapping, 0xa0000, 0x10000);
svga->banked_mask = 0xffff;
break;
case 0x8: /*32k at B0000*/
mem_mapping_set_addr(&svga->mapping, 0xb0000, 0x08000);
svga->banked_mask = 0x7fff;
break;
case 0xC: /*32k at B8000*/
mem_mapping_set_addr(&svga->mapping, 0xb8000, 0x08000);
svga->banked_mask = 0x7fff;
break;
}
}
break;
case 7:
svga->colournocare = val;
break;
}
svga->gdcreg[svga->gdcaddr & 15] = val;
svga->fast = (svga->gdcreg[8] == 0xff && !(svga->gdcreg[3] & 0x18) &&
!svga->gdcreg[1]) && svga->chain4;
if (((svga->gdcaddr & 15) == 5 && (val ^ o) & 0x70) ||
((svga->gdcaddr & 15) == 6 && (val ^ o) & 1))
svga_recalctimings(svga);
break;
}
}
uint8_t
svga_in(uint16_t addr, void *p)
{
svga_t *svga = (svga_t *)p;
uint8_t index, ret = 0xff;
switch (addr) {
case 0x3c0:
ret = svga->attraddr | svga->attr_palette_enable;
break;
case 0x3c1:
ret = svga->attrregs[svga->attraddr];
break;
case 0x3c2:
if ((svga->vgapal[0].r + svga->vgapal[0].g + svga->vgapal[0].b) >= 0x4e)
ret = 0;
else
ret = 0x10;
break;
case 0x3c4:
ret = svga->seqaddr;
break;
case 0x3c5:
ret = svga->seqregs[svga->seqaddr & 0x0f];
break;
case 0x3c6:
ret = svga->dac_mask;
break;
case 0x3c7:
ret = svga->dac_status;
break;
case 0x3c8:
ret = svga->dac_addr;
break;
case 0x3c9:
index = (svga->dac_addr - 1) & 255;
switch (svga->dac_pos) {
case 0:
svga->dac_pos++;
if (svga->ramdac_type == RAMDAC_8BIT)
ret = svga->vgapal[index].r;
else
ret = svga->vgapal[index].r & 0x3f;
break;
case 1:
svga->dac_pos++;
if (svga->ramdac_type == RAMDAC_8BIT)
ret = svga->vgapal[index].g;
else
ret = svga->vgapal[index].g & 0x3f;
break;
case 2:
svga->dac_pos=0;
svga->dac_addr = (svga->dac_addr + 1) & 255;
if (svga->ramdac_type == RAMDAC_8BIT)
ret = svga->vgapal[index].b;
else
ret = svga->vgapal[index].b & 0x3f;
break;
}
break;
case 0x3cc:
ret = svga->miscout;
break;
case 0x3ce:
ret = svga->gdcaddr;
break;
case 0x3cf:
/* The spec says GDC addresses 0xF8 to 0xFB return the latch. */
switch(svga->gdcaddr) {
case 0xf8:
ret = svga->latch.b[0];
break;
case 0xf9:
ret = svga->latch.b[1];
break;
case 0xfa:
ret = svga->latch.b[2];
break;
case 0xfb:
ret = svga->latch.b[3];
break;
default:
ret = svga->gdcreg[svga->gdcaddr & 0xf];
break;
}
break;
case 0x3da:
svga->attrff = 0;
if (svga->cgastat & 0x01)
svga->cgastat &= ~0x30;
else
svga->cgastat ^= 0x30;
ret = svga->cgastat;
break;
}
return(ret);
}
void
svga_set_ramdac_type(svga_t *svga, int type)
{
int c;
if (svga->ramdac_type != type) {
svga->ramdac_type = type;
for (c = 0; c < 256; c++) {
if (svga->ramdac_type == RAMDAC_8BIT)
svga->pallook[c] = makecol32(svga->vgapal[c].r, svga->vgapal[c].g, svga->vgapal[c].b);
else
svga->pallook[c] = makecol32((svga->vgapal[c].r & 0x3f) * 4,
(svga->vgapal[c].g & 0x3f) * 4,
(svga->vgapal[c].b & 0x3f) * 4);
}
}
}
void
svga_recalctimings(svga_t *svga)
{
double crtcconst, _dispontime, _dispofftime, disptime;
svga->vtotal = svga->crtc[6];
svga->dispend = svga->crtc[0x12];
svga->vsyncstart = svga->crtc[0x10];
svga->split = svga->crtc[0x18];
svga->vblankstart = svga->crtc[0x15];
if (svga->crtc[7] & 1)
svga->vtotal |= 0x100;
if (svga->crtc[7] & 32)
svga->vtotal |= 0x200;
svga->vtotal += 2;
if (svga->crtc[7] & 2)
svga->dispend |= 0x100;
if (svga->crtc[7] & 64)
svga->dispend |= 0x200;
svga->dispend++;
if (svga->crtc[7] & 4)
svga->vsyncstart |= 0x100;
if (svga->crtc[7] & 128)
svga->vsyncstart |= 0x200;
svga->vsyncstart++;
if (svga->crtc[7] & 0x10)
svga->split|=0x100;
if (svga->crtc[9] & 0x40)
svga->split|=0x200;
svga->split++;
if (svga->crtc[7] & 0x08)
svga->vblankstart |= 0x100;
if (svga->crtc[9] & 0x20)
svga->vblankstart |= 0x200;
svga->vblankstart++;
svga->hdisp = svga->crtc[1];
svga->hdisp++;
svga->htotal = svga->crtc[0];
svga->htotal += 6; /*+6 is required for Tyrian*/
svga->rowoffset = svga->crtc[0x13];
svga->clock = (svga->vidclock) ? VGACONST2 : VGACONST1;
svga->lowres = svga->attrregs[0x10] & 0x40;
svga->interlace = 0;
svga->ma_latch = (svga->crtc[0xc] << 8) | svga->crtc[0xd];
svga->hdisp_time = svga->hdisp;
svga->render = svga_render_blank;
if (!svga->scrblank && svga->attr_palette_enable) {
if (!(svga->gdcreg[6] & 1) && !(svga->attrregs[0x10] & 1)) { /*Text mode*/
if (svga->seqregs[1] & 8) /*40 column*/ {
svga->render = svga_render_text_40;
svga->hdisp *= (svga->seqregs[1] & 1) ? 16 : 18;
} else {
svga->render = svga_render_text_80;
svga->hdisp *= (svga->seqregs[1] & 1) ? 8 : 9;
}
svga->hdisp_old = svga->hdisp;
} else {
svga->hdisp *= (svga->seqregs[1] & 8) ? 16 : 8;
svga->hdisp_old = svga->hdisp;
switch (svga->gdcreg[5] & 0x60) {
case 0x00:
if (svga->seqregs[1] & 8) /*Low res (320)*/
svga->render = svga_render_4bpp_lowres;
else
svga->render = svga_render_4bpp_highres;
break;
case 0x20: /*4 colours*/
if (svga->seqregs[1] & 8) /*Low res (320)*/
svga->render = svga_render_2bpp_lowres;
else
svga->render = svga_render_2bpp_highres;
break;
case 0x40: case 0x60: /*256+ colours*/
switch (svga->bpp) {
case 8:
svga->map8 = svga->pallook;
if (svga->lowres)
svga->render = svga_render_8bpp_lowres;
else
svga->render = svga_render_8bpp_highres;
break;
case 15:
if (svga->lowres)
svga->render = svga_render_15bpp_lowres;
else
svga->render = svga_render_15bpp_highres;
break;
case 16:
if (svga->lowres)
svga->render = svga_render_16bpp_lowres;
else
svga->render = svga_render_16bpp_highres;
break;
case 24:
if (svga->lowres)
svga->render = svga_render_24bpp_lowres;
else
svga->render = svga_render_24bpp_highres;
break;
case 32:
if (svga->lowres)
svga->render = svga_render_32bpp_lowres;
else
svga->render = svga_render_32bpp_highres;
break;
}
break;
}
}
}
svga->linedbl = svga->crtc[9] & 0x80;
svga->rowcount = svga->crtc[9] & 31;
svga->char_width = (svga->seqregs[1] & 1) ? 8 : 9;
if (enable_overscan) {
overscan_y = (svga->rowcount + 1) << 1;
if (overscan_y < 16)
overscan_y = 16;
}
if (!(svga->gdcreg[6] & 1) && !(svga->attrregs[0x10] & 1)) {
overscan_x = (svga->seqregs[1] & 1) ? 16 : 18;
if (svga->seqregs[1] & 8)
overscan_x <<= 1;
} else
overscan_x = 16;
if (svga->recalctimings_ex)
svga->recalctimings_ex(svga);
svga->y_add = (overscan_y >> 1) - (svga->crtc[8] & 0x1f);
svga->x_add = (overscan_x >> 1);
if (svga->vblankstart < svga->dispend)
svga->dispend = svga->vblankstart;
crtcconst = svga->clock * svga->char_width;
disptime = svga->htotal;
_dispontime = svga->hdisp_time;
if (svga->seqregs[1] & 8) {
disptime *= 2;
_dispontime *= 2;
}
_dispofftime = disptime - _dispontime;
_dispontime *= crtcconst;
_dispofftime *= crtcconst;
svga->dispontime = (uint64_t)(_dispontime);
svga->dispofftime = (uint64_t)(_dispofftime);
if (svga->dispontime < TIMER_USEC)
svga->dispontime = TIMER_USEC;
if (svga->dispofftime < TIMER_USEC)
svga->dispofftime = TIMER_USEC;
}
static void
svga_do_render(svga_t *svga)
{
if (!svga->override) {
svga->render(svga);
svga->x_add = (overscan_x >> 1);
svga_render_overscan_left(svga);
svga_render_overscan_right(svga);
svga->x_add = (overscan_x >> 1) - svga->scrollcache;
}
if (svga->overlay_on) {
if (!svga->override && svga->overlay_draw)
svga->overlay_draw(svga, svga->displine + svga->y_add);
svga->overlay_on--;
if (svga->overlay_on && svga->interlace)
svga->overlay_on--;
}
if (svga->dac_hwcursor_on) {
if (!svga->override && svga->dac_hwcursor_draw)
svga->dac_hwcursor_draw(svga, svga->displine + svga->y_add);
svga->dac_hwcursor_on--;
if (svga->dac_hwcursor_on && svga->interlace)
svga->dac_hwcursor_on--;
}
if (svga->hwcursor_on) {
if (!svga->override && svga->hwcursor_draw)
svga->hwcursor_draw(svga, svga->displine + svga->y_add);
svga->hwcursor_on--;
if (svga->hwcursor_on && svga->interlace)
svga->hwcursor_on--;
}
}
void
svga_poll(void *p)
{
svga_t *svga = (svga_t *)p;
uint32_t x, blink_delay;
int wx, wy;
int skip = (svga->crtc[8] >> 5) & 0x03;
int ret, old_ma;
if (!svga->linepos) {
if (svga->displine == svga->hwcursor_latch.y && svga->hwcursor_latch.ena) {
svga->hwcursor_on = 64 - svga->hwcursor_latch.yoff;
svga->hwcursor_oddeven = 0;
}
if (svga->displine == (svga->hwcursor_latch.y + 1) && svga->hwcursor_latch.ena &&
svga->interlace) {
svga->hwcursor_on = 64 - (svga->hwcursor_latch.yoff + 1);
svga->hwcursor_oddeven = 1;
}
if (svga->displine == svga->dac_hwcursor_latch.y && svga->dac_hwcursor_latch.ena) {
svga->dac_hwcursor_on = 64 - svga->dac_hwcursor_latch.yoff;
svga->dac_hwcursor_oddeven = 0;
}
if (svga->displine == (svga->dac_hwcursor_latch.y + 1) && svga->dac_hwcursor_latch.ena &&
svga->interlace) {
svga->dac_hwcursor_on = 64 - (svga->dac_hwcursor_latch.yoff + 1);
svga->dac_hwcursor_oddeven = 1;
}
if (svga->displine == svga->overlay_latch.y && svga->overlay_latch.ena) {
svga->overlay_on = svga->overlay_latch.ysize - svga->overlay_latch.yoff;
svga->overlay_oddeven = 0;
}
if (svga->displine == svga->overlay_latch.y+1 && svga->overlay_latch.ena && svga->interlace) {
svga->overlay_on = svga->overlay_latch.ysize - svga->overlay_latch.yoff;
svga->overlay_oddeven = 1;
}
timer_advance_u64(&svga->timer, svga->dispofftime);
svga->cgastat |= 1;
svga->linepos = 1;
if (svga->dispon) {
svga->hdisp_on = 1;
svga->ma &= svga->vram_display_mask;
if (svga->firstline == 2000) {
svga->firstline = svga->displine;
video_wait_for_buffer();
}
if (svga->hwcursor_on || svga->dac_hwcursor_on || svga->overlay_on) {
svga->changedvram[svga->ma >> 12] = svga->changedvram[(svga->ma >> 12) + 1] =
svga->interlace ? 3 : 2;
}
if (svga->vertical_linedbl) {
old_ma = svga->ma;
svga->displine <<= 1;
svga->y_add <<= 1;
svga_do_render(svga);
svga->displine++;
svga->ma = old_ma;
svga_do_render(svga);
svga->y_add >>= 1;
svga->displine >>= 1;
} else
svga_do_render(svga);
if (svga->lastline < svga->displine)
svga->lastline = svga->displine;
}
svga->displine++;
if (svga->interlace)
svga->displine++;
if ((svga->cgastat & 8) && ((svga->displine & 15) == (svga->crtc[0x11] & 15)) && svga->vslines)
svga->cgastat &= ~8;
svga->vslines++;
if (svga->displine > 1500)
svga->displine = 0;
} else {
timer_advance_u64(&svga->timer, svga->dispontime);
if (svga->dispon)
svga->cgastat &= ~1;
svga->hdisp_on = 0;
svga->linepos = 0;
if ((svga->sc == (svga->crtc[11] & 31)) || (svga->sc == svga->rowcount))
svga->con = 0;
if (svga->dispon) {
if (svga->linedbl && !svga->linecountff) {
svga->linecountff = 1;
svga->ma = svga->maback;
} else if (svga->sc == svga->rowcount) {
svga->linecountff = 0;
svga->sc = 0;
svga->maback += (svga->rowoffset << 3);
if (svga->interlace)
svga->maback += (svga->rowoffset << 3);
svga->maback &= svga->vram_display_mask;
svga->ma = svga->maback;
} else {
svga->linecountff = 0;
svga->sc++;
svga->sc &= 31;
svga->ma = svga->maback;
}
}
svga->hsync_divisor = !svga->hsync_divisor;
if (svga->hsync_divisor && (svga->crtc[0x17] & 4))
return;
svga->vc++;
svga->vc &= 2047;
if (svga->vc == svga->split) {
ret = 1;
if (svga->line_compare)
ret = svga->line_compare(svga);
if (ret) {
svga->ma = svga->maback = 0;
svga->sc = 0;
if (svga->attrregs[0x10] & 0x20) {
svga->scrollcache = 0;
svga->x_add = (overscan_x >> 1);
}
}
}
if (svga->vc == svga->dispend) {
if (svga->vblank_start)
svga->vblank_start(svga);
svga->dispon = 0;
blink_delay = (svga->crtc[11] & 0x60) >> 5;
if (svga->crtc[10] & 0x20)
svga->cursoron = 0;
else if (blink_delay == 2)
svga->cursoron = ((svga->blink % 96) >= 48);
else
svga->cursoron = svga->blink & (16 + (16 * blink_delay));
if (!(svga->gdcreg[6] & 1) && !(svga->blink & 15))
svga->fullchange = 2;
svga->blink = (svga->blink + 1) & 0x7f;
for (x = 0; x < ((svga->vram_mask + 1) >> 12); x++) {
if (svga->changedvram[x])
svga->changedvram[x]--;
}
if (svga->fullchange)
svga->fullchange--;
}
if (svga->vc == svga->vsyncstart) {
svga->dispon = 0;
svga->cgastat |= 8;
x = svga->hdisp;
if (svga->interlace && !svga->oddeven)
svga->lastline++;
if (svga->interlace && svga->oddeven)
svga->firstline--;
wx = x;
if (!svga->override) {
if (svga->vertical_linedbl) {
wy = (svga->lastline - svga->firstline) << 1;
svga_doblit(svga->firstline_draw << 1, (svga->lastline_draw + 1) << 1, wx, wy, svga);
} else {
wy = svga->lastline - svga->firstline;
svga_doblit(svga->firstline_draw, svga->lastline_draw + 1, wx, wy, svga);
}
}
svga->firstline = 2000;
svga->lastline = 0;
svga->firstline_draw = 2000;
svga->lastline_draw = 0;
svga->oddeven ^= 1;
changeframecount = svga->interlace ? 3 : 2;
svga->vslines = 0;
if (svga->interlace && svga->oddeven)
svga->ma = svga->maback = svga->ma_latch + (svga->rowoffset << 1);
else
svga->ma = svga->maback = svga->ma_latch;
svga->ca = (svga->crtc[0xe] << 8) | svga->crtc[0xf];
svga->ma = (svga->ma << 2) + (skip << 2);
svga->maback = (svga->maback << 2) + (skip << 2);
svga->ca = (svga->ca << 2) + (skip << 2);
}
if (svga->vc == svga->vtotal) {
svga->vc = 0;
svga->sc = 0;
svga->dispon = 1;
svga->displine = (svga->interlace && svga->oddeven) ? 1 : 0;
svga->scrollcache = (svga->attrregs[0x13] & 0x0f);
if (!(svga->gdcreg[6] & 1) && !(svga->attrregs[0x10] & 1)) { /*Text mode*/
if (svga->seqregs[1] & 1)
svga->scrollcache &= 0x07;
else {
svga->scrollcache++;
if (svga->scrollcache > 8)
svga->scrollcache = 0;
}
} else if ((svga->render == svga_render_2bpp_lowres) || (svga->render == svga_render_2bpp_highres) ||
(svga->render == svga_render_4bpp_lowres) || (svga->render == svga_render_4bpp_highres))
svga->scrollcache &= 0x07;
else
svga->scrollcache = (svga->scrollcache & 0x06) >> 1;
if ((svga->seqregs[1] & 8) || (svga->render == svga_render_8bpp_lowres))
svga->scrollcache <<= 1;
svga->x_add = (overscan_x >> 1) - svga->scrollcache;
svga->linecountff = 0;
svga->hwcursor_on = 0;
svga->hwcursor_latch = svga->hwcursor;
svga->dac_hwcursor_on = 0;
svga->dac_hwcursor_latch = svga->dac_hwcursor;
svga->overlay_on = 0;
svga->overlay_latch = svga->overlay;
}
if (svga->sc == (svga->crtc[10] & 31))
svga->con = 1;
}
}
int
svga_init(svga_t *svga, void *p, int memsize,
void (*recalctimings_ex)(struct svga_t *svga),
uint8_t (*video_in) (uint16_t addr, void *p),
void (*video_out)(uint16_t addr, uint8_t val, void *p),
void (*hwcursor_draw)(struct svga_t *svga, int displine),
void (*overlay_draw)(struct svga_t *svga, int displine))
{
int c, d, e;
svga->p = p;
for (c = 0; c < 256; c++) {
e = c;
for (d = 0; d < 8; d++) {
svga_rotate[d][c] = e;
e = (e >> 1) | ((e & 1) ? 0x80 : 0);
}
}
svga->readmode = 0;
svga->attrregs[0x11] = 0;
svga->overscan_color = 0x000000;
overscan_x = 16;
overscan_y = 32;
svga->x_add = 8;
svga->y_add = 16;
svga->crtc[0] = 63;
svga->crtc[6] = 255;
svga->dispontime = 1000ull << 32;
svga->dispofftime = 1000ull << 32;
svga->bpp = 8;
svga->vram = malloc(memsize);
svga->vram_max = memsize;
svga->vram_display_mask = svga->vram_mask = memsize - 1;
svga->decode_mask = 0x7fffff;
svga->changedvram = malloc(memsize >> 12);
svga->recalctimings_ex = recalctimings_ex;
svga->video_in = video_in;
svga->video_out = video_out;
svga->hwcursor_draw = hwcursor_draw;
svga->overlay_draw = overlay_draw;
svga->hwcursor.xsize = svga->hwcursor.ysize = 32;
svga->hwcursor.yoff = 32;
svga->dac_hwcursor.xsize = svga->dac_hwcursor.ysize = 32;
svga->dac_hwcursor.yoff = 32;
mem_mapping_add(&svga->mapping, 0xa0000, 0x20000,
svga_read, svga_readw, svga_readl,
svga_write, svga_writew, svga_writel,
NULL, MEM_MAPPING_EXTERNAL, svga);
timer_add(&svga->timer, svga_poll, svga, 1);
svga_pri = svga;
svga->ramdac_type = RAMDAC_6BIT;
svga->map8 = svga->pallook;
return 0;
}
void
svga_close(svga_t *svga)
{
free(svga->changedvram);
free(svga->vram);
svga_pri = NULL;
}
static uint32_t
svga_decode_addr(svga_t *svga, uint32_t addr, int write)
{
int memory_map_mode = (svga->gdcreg[6] >> 2) & 3;
addr &= 0x1ffff;
switch (memory_map_mode) {
case 0:
break;
case 1:
if (addr >= 0x10000)
return 0xffffffff;
break;
case 2:
addr -= 0x10000;
if (addr >= 0x8000)
return 0xffffffff;
break;
default:
case 3:
addr -= 0x18000;
if (addr >= 0x8000)
return 0xffffffff;
break;
}
if (memory_map_mode <= 1) {
if (svga->adv_flags & FLAG_EXTRA_BANKS)
addr = (addr & 0x17fff) + svga->extra_banks[(addr >> 15) & 1];
else {
if (write)
addr += svga->write_bank;
else
addr += svga->read_bank;
}
}
return addr;
}
void
svga_write_common(uint32_t addr, uint8_t val, uint8_t linear, void *p)
{
svga_t *svga = (svga_t *)p;
int writemask2 = svga->writemask, reset_wm = 0;
latch_t vall;
uint8_t wm = svga->writemask;
uint8_t count, i;
if (svga->adv_flags & FLAG_ADDR_BY8)
writemask2 = svga->seqregs[2];
egawrites++;
sub_cycles(video_timing_write_b);
if (!linear) {
addr = svga_decode_addr(svga, addr, 1);
if (addr == 0xffffffff)
return;
}
if (!(svga->gdcreg[6] & 1))
svga->fullchange = 2;
if ((svga->adv_flags & FLAG_ADDR_BY8) && (svga->writemode < 4))
addr <<= 3;
else if ((svga->chain4 || svga->fb_only) && (svga->writemode < 4)) {
writemask2 = 1 << (addr & 3);
addr &= ~3;
} else if (svga->chain2_write) {
writemask2 &= ~0xa;
if (addr & 1)
writemask2 <<= 1;
addr &= ~1;
addr <<= 2;
} else
addr <<= 2;
addr &= svga->decode_mask;
if (addr >= svga->vram_max)
return;
addr &= svga->vram_mask;
svga->changedvram[addr >> 12] = changeframecount;
count = 4;
if (svga->adv_flags & FLAG_LATCH8)
count = 8;
switch (svga->writemode) {
case 0:
if (svga->gdcreg[3] & 7)
val = svga_rotate[svga->gdcreg[3] & 7][val];
if ((svga->gdcreg[8] == 0xff) && !(svga->gdcreg[3] & 0x18) && (!svga->gdcreg[1] || svga->set_reset_disabled)) {
for (i = 0; i < count; i++) {
if (writemask2 & (1 << i))
svga->vram[addr | i] = val;
}
return;
} else {
for (i = 0; i < count; i++) {
if (svga->gdcreg[1] & (1 << i))
vall.b[i] = !!(svga->gdcreg[0] & (1 << i)) * 0xff;
else
vall.b[i] = val;
}
}
break;
case 1:
for (i = 0; i < count; i++) {
if (writemask2 & (1 << i))
svga->vram[addr | i] = svga->latch.b[i];
}
return;
case 2:
for (i = 0; i < count; i++)
vall.b[i] = !!(val & (1 << i)) * 0xff;
if (!(svga->gdcreg[3] & 0x18) && (!svga->gdcreg[1] || svga->set_reset_disabled)) {
for (i = 0; i < count; i++) {
if (writemask2 & (1 << i))
svga->vram[addr | i] = (vall.b[i] & svga->gdcreg[8]) | (svga->latch.b[i] & ~svga->gdcreg[8]);
}
return;
}
break;
case 3:
if (svga->gdcreg[3] & 7)
val = svga_rotate[svga->gdcreg[3] & 7][val];
wm = svga->gdcreg[8];
svga->gdcreg[8] &= val;
for (i = 0; i < count; i++)
vall.b[i] = !!(svga->gdcreg[0] & (1 << i)) * 0xff;
reset_wm = 1;
break;
default:
if (svga->ven_write)
svga->ven_write(svga, val, addr);
return;
}
switch (svga->gdcreg[3] & 0x18) {
case 0x00: /* Set */
for (i = 0; i < count; i++) {
if (writemask2 & (1 << i))
svga->vram[addr | i] = (vall.b[i] & svga->gdcreg[8]) | (svga->latch.b[i] & ~svga->gdcreg[8]);
}
break;
case 0x08: /* AND */
for (i = 0; i < count; i++) {
if (writemask2 & (1 << i))
svga->vram[addr | i] = (vall.b[i] | ~svga->gdcreg[8]) & svga->latch.b[i];
}
break;
case 0x10: /* OR */
for (i = 0; i < count; i++) {
if (writemask2 & (1 << i))
svga->vram[addr | i] = (vall.b[i] & svga->gdcreg[8]) | svga->latch.b[i];
}
break;
case 0x18: /* XOR */
for (i = 0; i < count; i++) {
if (writemask2 & (1 << i))
svga->vram[addr | i] = (vall.b[i] & svga->gdcreg[8]) ^ svga->latch.b[i];
}
break;
}
if (reset_wm)
svga->gdcreg[8] = wm;
}
uint8_t
svga_read_common(uint32_t addr, uint8_t linear, void *p)
{
svga_t *svga = (svga_t *)p;
uint32_t latch_addr = 0;
int readplane = svga->readplane;
uint8_t count, i;
uint8_t plane, pixel;
uint8_t temp, ret;
if (svga->adv_flags & FLAG_ADDR_BY8)
readplane = svga->gdcreg[4] & 7;
sub_cycles(video_timing_read_b);
egareads++;
if (!linear) {
addr = svga_decode_addr(svga, addr, 0);
if (addr == 0xffffffff)
return 0xff;
}
count = 2;
if (svga->adv_flags & FLAG_LATCH8)
count = 3;
latch_addr = (addr << count) & svga->decode_mask;
count = (1 << count);
if (svga->adv_flags & FLAG_ADDR_BY8)
addr <<= 3;
else if (svga->chain4 || svga->fb_only) {
addr &= svga->decode_mask;
if (addr >= svga->vram_max)
return 0xff;
return svga->vram[addr & svga->vram_mask];
} else if (svga->chain2_read) {
readplane = (readplane & 2) | (addr & 1);
addr &= ~1;
addr <<= 2;
} else
addr <<= 2;
addr &= svga->decode_mask;
/* standard VGA latched access */
if (latch_addr >= svga->vram_max) {
for (i = 0; i < count; i++)
svga->latch.b[i] = 0xff;
} else {
latch_addr &= svga->vram_mask;
for (i = 0; i < count; i++)
svga->latch.b[i] = svga->vram[latch_addr | i];
}
if (addr >= svga->vram_max)
return 0xff;
addr &= svga->vram_mask;
if (svga->readmode) {
temp = 0xff;
for (pixel = 0; pixel < 8; pixel++) {
for (plane = 0; plane < count; plane++) {
if (svga->colournocare & (1 << plane)) {
/* If we care about a plane, and the pixel has a mismatch on it, clear its bit. */
if (((svga->latch.b[plane] >> pixel) & 1) != ((svga->colourcompare >> plane) & 1))
temp &= ~(1 << pixel);
}
}
}
ret = temp;
} else
ret = svga->vram[addr | readplane];
return ret;
}
void
svga_write(uint32_t addr, uint8_t val, void *p)
{
svga_write_common(addr, val, 0, p);
}
void
svga_write_linear(uint32_t addr, uint8_t val, void *p)
{
svga_write_common(addr, val, 1, p);
}
uint8_t
svga_read(uint32_t addr, void *p)
{
return svga_read_common(addr, 0, p);
}
uint8_t
svga_read_linear(uint32_t addr, void *p)
{
return svga_read_common(addr, 1, p);
}
void
svga_doblit(int y1, int y2, int wx, int wy, svga_t *svga)
{
int y_add, x_add, y_start, x_start, bottom;
uint32_t *p;
int i, j;
int xs_temp, ys_temp;
y_add = (enable_overscan) ? overscan_y : 0;
x_add = (enable_overscan) ? overscan_x : 0;
y_start = (enable_overscan) ? 0 : (overscan_y >> 1);
x_start = (enable_overscan) ? 0 : (overscan_x >> 1);
bottom = (overscan_y >> 1) + (svga->crtc[8] & 0x1f);
if (svga->vertical_linedbl) {
y_add <<= 1;
y_start <<= 1;
bottom <<= 1;
}
if ((wx <= 0) || (wy <= 0)) {
video_blit_memtoscreen(x_start, y_start, 0, 0, 0, 0);
return;
}
if (y1 > y2) {
video_blit_memtoscreen(x_start, y_start, 0, 0, xsize + x_add, ysize + y_add);
return;
}
if (svga->vertical_linedbl)
svga->y_add <<= 1;
xs_temp = wx;
ys_temp = wy + 1;
if (svga->vertical_linedbl)
ys_temp++;
if (xs_temp < 64)
xs_temp = 640;
if (ys_temp < 32)
ys_temp = 200;
if ((xs_temp != xsize) || (ys_temp != ysize) || video_force_resize_get()) {
/* Screen res has changed.. fix up, and let them know. */
xsize = xs_temp;
ysize = ys_temp;
if ((xsize > 1984) || (ysize > 2016)) {
/* 2048x2048 is the biggest safe render texture, to account for overscan,
we suppress overscan starting from x 1984 and y 2016. */
x_add = 0;
y_add = 0;
suppress_overscan = 1;
} else
suppress_overscan = 0;
set_screen_size(xsize + x_add, ysize + y_add);
if (video_force_resize_get())
video_force_resize_set(0);
}
if ((wx >= 160) && ((wy + 1) >= 120)) {
/* Draw (overscan_size - scroll size) lines of overscan on top and bottom. */
for (i = 0; i < svga->y_add; i++) {
p = &buffer32->line[i & 0x7ff][0];
for (j = 0; j < (xsize + x_add); j++)
p[j] = svga->overscan_color;
}
for (i = 0; i < bottom; i++) {
p = &buffer32->line[(ysize + svga->y_add + i) & 0x7ff][0];
for (j = 0; j < (xsize + x_add); j++)
p[j] = svga->overscan_color;
}
}
video_blit_memtoscreen(x_start, y_start, y1, y2 + y_add, xsize + x_add, ysize + y_add);
if (svga->vertical_linedbl)
svga->vertical_linedbl >>= 1;
}
void
svga_writeb_linear(uint32_t addr, uint8_t val, void *p)
{
svga_t *svga = (svga_t *)p;
if (!svga->fast) {
svga_write_linear(addr, val, p);
return;
}
egawrites++;
addr &= svga->decode_mask;
if (addr >= svga->vram_max)
return;
addr &= svga->vram_mask;
svga->changedvram[addr >> 12] = changeframecount;
*(uint8_t *)&svga->vram[addr] = val;
}
void
svga_writew_common(uint32_t addr, uint16_t val, uint8_t linear, void *p)
{
svga_t *svga = (svga_t *)p;
if (!svga->fast) {
svga_write_common(addr, val, linear, p);
svga_write_common(addr + 1, val >> 8, linear, p);
return;
}
egawrites += 2;
sub_cycles(video_timing_write_w);
if (!linear) {
addr = svga_decode_addr(svga, addr, 1);
if (addr == 0xffffffff)
return;
}
addr &= svga->decode_mask;
if (addr >= svga->vram_max)
return;
addr &= svga->vram_mask;
svga->changedvram[addr >> 12] = changeframecount;
*(uint16_t *)&svga->vram[addr] = val;
}
void
svga_writew(uint32_t addr, uint16_t val, void *p)
{
svga_writew_common(addr, val, 0, p);
}
void
svga_writew_linear(uint32_t addr, uint16_t val, void *p)
{
svga_writew_common(addr, val, 1, p);
}
void
svga_writel_common(uint32_t addr, uint32_t val, uint8_t linear, void *p)
{
svga_t *svga = (svga_t *)p;
if (!svga->fast) {
svga_write_common(addr, val, linear, p);
svga_write_common(addr + 1, val >> 8, linear, p);
svga_write_common(addr + 2, val >> 16, linear, p);
svga_write_common(addr + 3, val >> 24, linear, p);
return;
}
egawrites += 4;
sub_cycles(video_timing_write_l);
if (!linear) {
addr = svga_decode_addr(svga, addr, 1);
if (addr == 0xffffffff)
return;
}
addr &= svga->decode_mask;
if (addr >= svga->vram_max)
return;
addr &= svga->vram_mask;
svga->changedvram[addr >> 12] = changeframecount;
*(uint32_t *)&svga->vram[addr] = val;
}
void
svga_writel(uint32_t addr, uint32_t val, void *p)
{
svga_writel_common(addr, val, 0, p);
}
void
svga_writel_linear(uint32_t addr, uint32_t val, void *p)
{
svga_writel_common(addr, val, 1, p);
}
uint8_t
svga_readb_linear(uint32_t addr, void *p)
{
svga_t *svga = (svga_t *)p;
if (!svga->fast)
return svga_read_linear(addr, p);
egareads++;
addr &= svga->decode_mask;
if (addr >= svga->vram_max)
return 0xff;
return *(uint8_t *)&svga->vram[addr & svga->vram_mask];
}
uint16_t
svga_readw_common(uint32_t addr, uint8_t linear, void *p)
{
svga_t *svga = (svga_t *)p;
if (!svga->fast)
return svga_read_common(addr, linear, p) | (svga_read_common(addr + 1, linear, p) << 8);
egareads += 2;
sub_cycles(video_timing_read_w);
if (!linear) {
addr = svga_decode_addr(svga, addr, 0);
if (addr == 0xffffffff)
return 0xffff;
}
addr &= svga->decode_mask;
if (addr >= svga->vram_max)
return 0xffff;
return *(uint16_t *)&svga->vram[addr & svga->vram_mask];
}
uint16_t
svga_readw(uint32_t addr, void *p)
{
return svga_readw_common(addr, 0, p);
}
uint16_t
svga_readw_linear(uint32_t addr, void *p)
{
return svga_readw_common(addr, 1, p);
}
uint32_t
svga_readl_common(uint32_t addr, uint8_t linear, void *p)
{
svga_t *svga = (svga_t *)p;
if (!svga->fast) {
return svga_read_common(addr, linear, p) | (svga_read_common(addr + 1, linear, p) << 8) |
(svga_read_common(addr + 2, linear, p) << 16) | (svga_read_common(addr + 3, linear, p) << 24);
}
egareads += 4;
sub_cycles(video_timing_read_l);
if (!linear) {
addr = svga_decode_addr(svga, addr, 0);
if (addr == 0xffffffff)
return 0xffffffff;
}
addr &= svga->decode_mask;
if (addr >= svga->vram_max)
return 0xffffffff;
return *(uint32_t *)&svga->vram[addr & svga->vram_mask];
}
uint32_t
svga_readl(uint32_t addr, void *p)
{
return svga_readl_common(addr, 0, p);
}
uint32_t
svga_readl_linear(uint32_t addr, void *p)
{
return svga_readl_common(addr, 1, p);
}