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a93ca07acd
freebsd-dev/lib/libvgl/simple.c
Bruce Evans a93ca07acd Fix mouse cursor coloring in depths > 8 (previously, a hack that only 
worked right for white interiors and black borders was used).  Advertise
this by changing the default colors to a red interior and a white
border (the same as the kernel default).  Add undocumented env variables
for changing these colors.  Also change to the larger and better-shaped
16x10 cursor sometimes used in the kernel.  The kernel choice is
fancier, but libvgl is closer to supporting the larger cursors needed
in newer modes.

The (n)and-or logic for the cursor doesn't work right for more than 2
colors.  The (n)and part only masks out all color bits for the pixel
under the cursor when all bits are set in the And mask.  With more
complicated logic, the non-masked bits could be used to implement
translucent cursors, but they actually just gave strange colors
(especially in packed and planar modes where the bits are indirect
through 1 or 2 palettes so it is hard to predict the final color).
They also gave a bug for writing pixels under the cursor.  The
non-masked bits under the cursor were not combined in this case.

Drop support for combining with bits under the cursor by making any nonzero
value in the And mask mean all bits set.

Convert the Or mask (which is represented as a half-initialized 256-color
bitmap) to a fully initialized bitmap with the correct number of colors.
The 256-color representation must be as in 3:3:2 direct mode iff the final
bitmap has more than 256 colors.  The conversion of colors is not very
efficient, so convert at initialization time.
2019-04-22 19:31:16 +00:00

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/*-
* SPDX-License-Identifier: BSD-3-Clause
*
* Copyright (c) 1991-1997 Søren Schmidt
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer
* in this position and unchanged.
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
* 3. The name of the author may not be used to endorse or promote products
* derived from this software without specific prior written permission
*
* THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR
* IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES
* OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED.
* IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT,
* INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT
* NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
* DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
* THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF
* THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*/
#include <sys/cdefs.h>
__FBSDID("$FreeBSD$");
#include <signal.h>
#include <sys/fbio.h>
#include <sys/kbio.h>
#include <sys/endian.h>
#include "vgl.h"
static int VGLBlank;
static byte VGLBorderColor;
static byte VGLSavePaletteRed[256];
static byte VGLSavePaletteGreen[256];
static byte VGLSavePaletteBlue[256];
#define ABS(a) (((a)<0) ? -(a) : (a))
#define SGN(a) (((a)<0) ? -1 : 1)
#define min(x, y) (((x) < (y)) ? (x) : (y))
#define max(x, y) (((x) > (y)) ? (x) : (y))
void
VGLSetXY(VGLBitmap *object, int x, int y, u_long color)
{
int offset;
VGLCheckSwitch();
if (x>=0 && x<object->VXsize && y>=0 && y<object->VYsize) {
if (object == VGLDisplay)
VGLSetXY(&VGLVDisplay, x, y, color);
if (object->Type == MEMBUF ||
!VGLMouseFreeze(x, y, 1, 1, 0x80000000 | color)) {
offset = (y * object->VXsize + x) * object->PixelBytes;
switch (object->Type) {
case VIDBUF8S:
case VIDBUF16S:
case VIDBUF24S:
case VIDBUF32S:
offset = VGLSetSegment(offset);
/* FALLTHROUGH */
case MEMBUF:
case VIDBUF8:
case VIDBUF16:
case VIDBUF24:
case VIDBUF32:
color = htole32(color);
switch (object->PixelBytes) {
case 1:
memcpy(&object->Bitmap[offset], &color, 1);
break;
case 2:
memcpy(&object->Bitmap[offset], &color, 2);
break;
case 3:
memcpy(&object->Bitmap[offset], &color, 3);
break;
case 4:
memcpy(&object->Bitmap[offset], &color, 4);
break;
}
break;
case VIDBUF8X:
outb(0x3c4, 0x02);
outb(0x3c5, 0x01 << (x&0x3));
object->Bitmap[(unsigned)(VGLAdpInfo.va_line_width*y)+(x/4)] = ((byte)color);
break;
case VIDBUF4S:
offset = VGLSetSegment(y*VGLAdpInfo.va_line_width + x/8);
goto set_planar;
case VIDBUF4:
offset = y*VGLAdpInfo.va_line_width + x/8;
set_planar:
outb(0x3c4, 0x02); outb(0x3c5, 0x0f);
outb(0x3ce, 0x00); outb(0x3cf, (byte)color & 0x0f); /* set/reset */
outb(0x3ce, 0x01); outb(0x3cf, 0x0f); /* set/reset enable */
outb(0x3ce, 0x08); outb(0x3cf, 0x80 >> (x%8)); /* bit mask */
object->Bitmap[offset] |= (byte)color;
}
}
if (object->Type != MEMBUF)
VGLMouseUnFreeze();
}
}
static u_long
__VGLGetXY(VGLBitmap *object, int x, int y)
{
int offset;
u_long color;
offset = (y * object->VXsize + x) * object->PixelBytes;
switch (object->PixelBytes) {
case 1:
memcpy(&color, &object->Bitmap[offset], 1);
return le32toh(color) & 0xff;
case 2:
memcpy(&color, &object->Bitmap[offset], 2);
return le32toh(color) & 0xffff;
case 3:
memcpy(&color, &object->Bitmap[offset], 3);
return le32toh(color) & 0xffffff;
case 4:
memcpy(&color, &object->Bitmap[offset], 4);
return le32toh(color);
}
return 0; /* invalid */
}
u_long
VGLGetXY(VGLBitmap *object, int x, int y)
{
VGLCheckSwitch();
if (x<0 || x>=object->VXsize || y<0 || y>=object->VYsize)
return 0;
if (object == VGLDisplay)
object = &VGLVDisplay;
if (object->Type != MEMBUF)
return 0; /* invalid */
return __VGLGetXY(object, x, y);
}
/*
* Symmetric Double Step Line Algorithm by Brian Wyvill from
* "Graphics Gems", Academic Press, 1990.
*/
#define SL_SWAP(a,b) {a^=b; b^=a; a^=b;}
#define SL_ABSOLUTE(i,j,k) ( (i-j)*(k = ( (i-j)<0 ? -1 : 1)))
void
plot(VGLBitmap * object, int x, int y, int flag, u_long color)
{
/* non-zero flag indicates the pixels need swapping back. */
if (flag)
VGLSetXY(object, y, x, color);
else
VGLSetXY(object, x, y, color);
}
void
VGLLine(VGLBitmap *object, int x1, int y1, int x2, int y2, u_long color)
{
int dx, dy, incr1, incr2, D, x, y, xend, c, pixels_left;
int sign_x, sign_y, step, reverse, i;
dx = SL_ABSOLUTE(x2, x1, sign_x);
dy = SL_ABSOLUTE(y2, y1, sign_y);
/* decide increment sign by the slope sign */
if (sign_x == sign_y)
step = 1;
else
step = -1;
if (dy > dx) { /* chooses axis of greatest movement (make dx) */
SL_SWAP(x1, y1);
SL_SWAP(x2, y2);
SL_SWAP(dx, dy);
reverse = 1;
} else
reverse = 0;
/* note error check for dx==0 should be included here */
if (x1 > x2) { /* start from the smaller coordinate */
x = x2;
y = y2;
/* x1 = x1;
y1 = y1; */
} else {
x = x1;
y = y1;
x1 = x2;
y1 = y2;
}
/* Note dx=n implies 0 - n or (dx+1) pixels to be set */
/* Go round loop dx/4 times then plot last 0,1,2 or 3 pixels */
/* In fact (dx-1)/4 as 2 pixels are already plotted */
xend = (dx - 1) / 4;
pixels_left = (dx - 1) % 4; /* number of pixels left over at the
* end */
plot(object, x, y, reverse, color);
if (pixels_left < 0)
return; /* plot only one pixel for zero length
* vectors */
plot(object, x1, y1, reverse, color); /* plot first two points */
incr2 = 4 * dy - 2 * dx;
if (incr2 < 0) { /* slope less than 1/2 */
c = 2 * dy;
incr1 = 2 * c;
D = incr1 - dx;
for (i = 0; i < xend; i++) { /* plotting loop */
++x;
--x1;
if (D < 0) {
/* pattern 1 forwards */
plot(object, x, y, reverse, color);
plot(object, ++x, y, reverse, color);
/* pattern 1 backwards */
plot(object, x1, y1, reverse, color);
plot(object, --x1, y1, reverse, color);
D += incr1;
} else {
if (D < c) {
/* pattern 2 forwards */
plot(object, x, y, reverse, color);
plot(object, ++x, y += step, reverse,
color);
/* pattern 2 backwards */
plot(object, x1, y1, reverse, color);
plot(object, --x1, y1 -= step, reverse,
color);
} else {
/* pattern 3 forwards */
plot(object, x, y += step, reverse, color);
plot(object, ++x, y, reverse, color);
/* pattern 3 backwards */
plot(object, x1, y1 -= step, reverse,
color);
plot(object, --x1, y1, reverse, color);
}
D += incr2;
}
} /* end for */
/* plot last pattern */
if (pixels_left) {
if (D < 0) {
plot(object, ++x, y, reverse, color); /* pattern 1 */
if (pixels_left > 1)
plot(object, ++x, y, reverse, color);
if (pixels_left > 2)
plot(object, --x1, y1, reverse, color);
} else {
if (D < c) {
plot(object, ++x, y, reverse, color); /* pattern 2 */
if (pixels_left > 1)
plot(object, ++x, y += step, reverse, color);
if (pixels_left > 2)
plot(object, --x1, y1, reverse, color);
} else {
/* pattern 3 */
plot(object, ++x, y += step, reverse, color);
if (pixels_left > 1)
plot(object, ++x, y, reverse, color);
if (pixels_left > 2)
plot(object, --x1, y1 -= step, reverse, color);
}
}
} /* end if pixels_left */
}
/* end slope < 1/2 */
else { /* slope greater than 1/2 */
c = 2 * (dy - dx);
incr1 = 2 * c;
D = incr1 + dx;
for (i = 0; i < xend; i++) {
++x;
--x1;
if (D > 0) {
/* pattern 4 forwards */
plot(object, x, y += step, reverse, color);
plot(object, ++x, y += step, reverse, color);
/* pattern 4 backwards */
plot(object, x1, y1 -= step, reverse, color);
plot(object, --x1, y1 -= step, reverse, color);
D += incr1;
} else {
if (D < c) {
/* pattern 2 forwards */
plot(object, x, y, reverse, color);
plot(object, ++x, y += step, reverse,
color);
/* pattern 2 backwards */
plot(object, x1, y1, reverse, color);
plot(object, --x1, y1 -= step, reverse,
color);
} else {
/* pattern 3 forwards */
plot(object, x, y += step, reverse, color);
plot(object, ++x, y, reverse, color);
/* pattern 3 backwards */
plot(object, x1, y1 -= step, reverse, color);
plot(object, --x1, y1, reverse, color);
}
D += incr2;
}
} /* end for */
/* plot last pattern */
if (pixels_left) {
if (D > 0) {
plot(object, ++x, y += step, reverse, color); /* pattern 4 */
if (pixels_left > 1)
plot(object, ++x, y += step, reverse,
color);
if (pixels_left > 2)
plot(object, --x1, y1 -= step, reverse,
color);
} else {
if (D < c) {
plot(object, ++x, y, reverse, color); /* pattern 2 */
if (pixels_left > 1)
plot(object, ++x, y += step, reverse, color);
if (pixels_left > 2)
plot(object, --x1, y1, reverse, color);
} else {
/* pattern 3 */
plot(object, ++x, y += step, reverse, color);
if (pixels_left > 1)
plot(object, ++x, y, reverse, color);
if (pixels_left > 2) {
if (D > c) /* step 3 */
plot(object, --x1, y1 -= step, reverse, color);
else /* step 2 */
plot(object, --x1, y1, reverse, color);
}
}
}
}
}
}
void
VGLBox(VGLBitmap *object, int x1, int y1, int x2, int y2, u_long color)
{
VGLLine(object, x1, y1, x2, y1, color);
VGLLine(object, x2, y1, x2, y2, color);
VGLLine(object, x2, y2, x1, y2, color);
VGLLine(object, x1, y2, x1, y1, color);
}
void
VGLFilledBox(VGLBitmap *object, int x1, int y1, int x2, int y2, u_long color)
{
int y;
for (y=y1; y<=y2; y++) VGLLine(object, x1, y, x2, y, color);
}
static inline void
set4pixels(VGLBitmap *object, int x, int y, int xc, int yc, u_long color)
{
if (x!=0) {
VGLSetXY(object, xc+x, yc+y, color);
VGLSetXY(object, xc-x, yc+y, color);
if (y!=0) {
VGLSetXY(object, xc+x, yc-y, color);
VGLSetXY(object, xc-x, yc-y, color);
}
}
else {
VGLSetXY(object, xc, yc+y, color);
if (y!=0)
VGLSetXY(object, xc, yc-y, color);
}
}
void
VGLEllipse(VGLBitmap *object, int xc, int yc, int a, int b, u_long color)
{
int x = 0, y = b, asq = a*a, asq2 = a*a*2, bsq = b*b;
int bsq2 = b*b*2, d = bsq-asq*b+asq/4, dx = 0, dy = asq2*b;
while (dx<dy) {
set4pixels(object, x, y, xc, yc, color);
if (d>0) {
y--; dy-=asq2; d-=dy;
}
x++; dx+=bsq2; d+=bsq+dx;
}
d+=(3*(asq-bsq)/2-(dx+dy))/2;
while (y>=0) {
set4pixels(object, x, y, xc, yc, color);
if (d<0) {
x++; dx+=bsq2; d+=dx;
}
y--; dy-=asq2; d+=asq-dy;
}
}
static inline void
set2lines(VGLBitmap *object, int x, int y, int xc, int yc, u_long color)
{
if (x!=0) {
VGLLine(object, xc+x, yc+y, xc-x, yc+y, color);
if (y!=0)
VGLLine(object, xc+x, yc-y, xc-x, yc-y, color);
}
else {
VGLLine(object, xc, yc+y, xc, yc-y, color);
}
}
void
VGLFilledEllipse(VGLBitmap *object, int xc, int yc, int a, int b, u_long color)
{
int x = 0, y = b, asq = a*a, asq2 = a*a*2, bsq = b*b;
int bsq2 = b*b*2, d = bsq-asq*b+asq/4, dx = 0, dy = asq2*b;
while (dx<dy) {
set2lines(object, x, y, xc, yc, color);
if (d>0) {
y--; dy-=asq2; d-=dy;
}
x++; dx+=bsq2; d+=bsq+dx;
}
d+=(3*(asq-bsq)/2-(dx+dy))/2;
while (y>=0) {
set2lines(object, x, y, xc, yc, color);
if (d<0) {
x++; dx+=bsq2; d+=dx;
}
y--; dy-=asq2; d+=asq-dy;
}
}
void
VGLClear(VGLBitmap *object, u_long color)
{
VGLBitmap src;
int offset;
int len;
int i;
VGLCheckSwitch();
if (object == VGLDisplay) {
VGLMouseFreeze(0, 0, object->Xsize, object->Ysize, color);
VGLClear(&VGLVDisplay, color);
} else if (object->Type != MEMBUF)
return; /* invalid */
switch (object->Type) {
case MEMBUF:
case VIDBUF8:
case VIDBUF8S:
case VIDBUF16:
case VIDBUF16S:
case VIDBUF24:
case VIDBUF24S:
case VIDBUF32:
case VIDBUF32S:
src.Type = MEMBUF;
src.Xsize = object->Xsize;
src.VXsize = object->VXsize;
src.Ysize = 1;
src.VYsize = 1;
src.Xorigin = 0;
src.Yorigin = 0;
src.Bitmap = alloca(object->VXsize * object->PixelBytes);
src.PixelBytes = object->PixelBytes;
color = htole32(color);
for (i = 0; i < object->VXsize; i++)
bcopy(&color, src.Bitmap + i * object->PixelBytes, object->PixelBytes);
for (i = 0; i < object->VYsize; i++)
__VGLBitmapCopy(&src, 0, 0, object, 0, i, object->VXsize, 1);
break;
case VIDBUF8X:
/* XXX works only for Xsize % 4 = 0 */
outb(0x3c6, 0xff);
outb(0x3c4, 0x02); outb(0x3c5, 0x0f);
memset(object->Bitmap, (byte)color, VGLAdpInfo.va_line_width*object->VYsize);
break;
case VIDBUF4:
case VIDBUF4S:
/* XXX works only for Xsize % 8 = 0 */
outb(0x3c4, 0x02); outb(0x3c5, 0x0f);
outb(0x3ce, 0x05); outb(0x3cf, 0x02); /* mode 2 */
outb(0x3ce, 0x01); outb(0x3cf, 0x00); /* set/reset enable */
outb(0x3ce, 0x08); outb(0x3cf, 0xff); /* bit mask */
for (offset = 0; offset < VGLAdpInfo.va_line_width*object->VYsize; ) {
VGLSetSegment(offset);
len = min(object->VXsize*object->VYsize - offset,
VGLAdpInfo.va_window_size);
memset(object->Bitmap, (byte)color, len);
offset += len;
}
outb(0x3ce, 0x05); outb(0x3cf, 0x00);
break;
}
if (object == VGLDisplay)
VGLMouseUnFreeze();
}
static inline u_long
VGLrgbToNative(uint16_t r, uint16_t g, uint16_t b)
{
int nr, ng, nb;
nr = VGLModeInfo.vi_pixel_fsizes[2];
ng = VGLModeInfo.vi_pixel_fsizes[1];
nb = VGLModeInfo.vi_pixel_fsizes[0];
return (r >> (16 - nr) << (ng + nb)) | (g >> (16 - ng) << nb) |
(b >> (16 - nb) << 0);
}
u_long
VGLrgb332ToNative(byte c)
{
uint16_t r, g, b;
/* 3:3:2 to 16:16:16 */
r = ((c & 0xe0) >> 5) * 0xffff / 7;
g = ((c & 0x1c) >> 2) * 0xffff / 7;
b = ((c & 0x03) >> 0) * 0xffff / 3;
return VGLrgbToNative(r, g, b);
}
void
VGLRestorePalette()
{
int i;
if (VGLModeInfo.vi_mem_model == V_INFO_MM_DIRECT)
return;
outb(0x3C6, 0xFF);
inb(0x3DA);
outb(0x3C8, 0x00);
for (i=0; i<256; i++) {
outb(0x3C9, VGLSavePaletteRed[i]);
inb(0x84);
outb(0x3C9, VGLSavePaletteGreen[i]);
inb(0x84);
outb(0x3C9, VGLSavePaletteBlue[i]);
inb(0x84);
}
inb(0x3DA);
outb(0x3C0, 0x20);
}
void
VGLSavePalette()
{
int i;
if (VGLModeInfo.vi_mem_model == V_INFO_MM_DIRECT)
return;
outb(0x3C6, 0xFF);
inb(0x3DA);
outb(0x3C7, 0x00);
for (i=0; i<256; i++) {
VGLSavePaletteRed[i] = inb(0x3C9);
inb(0x84);
VGLSavePaletteGreen[i] = inb(0x3C9);
inb(0x84);
VGLSavePaletteBlue[i] = inb(0x3C9);
inb(0x84);
}
inb(0x3DA);
outb(0x3C0, 0x20);
}
void
VGLSetPalette(byte *red, byte *green, byte *blue)
{
int i;
if (VGLModeInfo.vi_mem_model == V_INFO_MM_DIRECT)
return;
for (i=0; i<256; i++) {
VGLSavePaletteRed[i] = red[i];
VGLSavePaletteGreen[i] = green[i];
VGLSavePaletteBlue[i] = blue[i];
}
VGLCheckSwitch();
outb(0x3C6, 0xFF);
inb(0x3DA);
outb(0x3C8, 0x00);
for (i=0; i<256; i++) {
outb(0x3C9, VGLSavePaletteRed[i]);
inb(0x84);
outb(0x3C9, VGLSavePaletteGreen[i]);
inb(0x84);
outb(0x3C9, VGLSavePaletteBlue[i]);
inb(0x84);
}
inb(0x3DA);
outb(0x3C0, 0x20);
}
void
VGLSetPaletteIndex(byte color, byte red, byte green, byte blue)
{
if (VGLModeInfo.vi_mem_model == V_INFO_MM_DIRECT)
return;
VGLSavePaletteRed[color] = red;
VGLSavePaletteGreen[color] = green;
VGLSavePaletteBlue[color] = blue;
VGLCheckSwitch();
outb(0x3C6, 0xFF);
inb(0x3DA);
outb(0x3C8, color);
outb(0x3C9, red); outb(0x3C9, green); outb(0x3C9, blue);
inb(0x3DA);
outb(0x3C0, 0x20);
}
void
VGLRestoreBorder(void)
{
VGLSetBorder(VGLBorderColor);
}
void
VGLSetBorder(byte color)
{
if (VGLModeInfo.vi_mem_model == V_INFO_MM_DIRECT && ioctl(0, KDENABIO, 0))
return;
VGLCheckSwitch();
inb(0x3DA);
outb(0x3C0,0x11); outb(0x3C0, color);
inb(0x3DA);
outb(0x3C0, 0x20);
VGLBorderColor = color;
if (VGLModeInfo.vi_mem_model == V_INFO_MM_DIRECT)
ioctl(0, KDDISABIO, 0);
}
void
VGLRestoreBlank(void)
{
VGLBlankDisplay(VGLBlank);
}
void
VGLBlankDisplay(int blank)
{
byte val;
if (VGLModeInfo.vi_mem_model == V_INFO_MM_DIRECT && ioctl(0, KDENABIO, 0))
return;
VGLCheckSwitch();
outb(0x3C4, 0x01); val = inb(0x3C5); outb(0x3C4, 0x01);
outb(0x3C5, ((blank) ? (val |= 0x20) : (val &= 0xDF)));
VGLBlank = blank;
if (VGLModeInfo.vi_mem_model == V_INFO_MM_DIRECT)
ioctl(0, KDDISABIO, 0);
}
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