/* ScummVM - Graphic Adventure Engine
*
* ScummVM is the legal property of its developers, whose names
* are too numerous to list here. Please refer to the COPYRIGHT
* file distributed with this source distribution.
*
* This program is free software; you can redistribute it and/or
* modify it under the terms of the GNU General Public License
* as published by the Free Software Foundation; either version 2
* of the License, or (at your option) any later version.
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
* You should have received a copy of the GNU General Public License
* along with this program; if not, write to the Free Software
* Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA.
*
* $URL$
* $Id$
*
*/
#include "sci/gfx/gfx_resource.h"
/* Generic pic filling code, to be included by sci_pic_0.c
*
*
* To use, define the following:
* AUXBUF_FILL: Name of the exported floodfill function
* AUXBUF_FILL_HELPER: Name of the helper function
* FILL_FUNCTION: Name of the exported floodfill function
* FILL_FUNCTION_RECURSIVE: Name of the helper function
*
* Define DRAW_SCALED to support scaled drawing, or leave it out for faster
* processing.
*
*/
namespace Sci {
#define CLIPMASK_HARD_BOUND 0x80 /* ensures that we don't re-fill filled stuff */
static void AUXBUF_FILL_HELPER(gfxr_pic_t *pic, int old_xl, int old_xr, int y, int dy,
int clipmask, int control, int sci_titlebar_size) {
int xl, xr;
int oldytotal = y * 320;
#ifdef DRAW_SCALED
unsigned const char fillmask = CLIPMASK_HARD_BOUND | 0x78;
#else
unsigned const char fillmask = CLIPMASK_HARD_BOUND | 0x84;
#endif
do {
int ytotal = oldytotal + (320 * dy);
int xcont;
int state;
y += dy;
if (y < sci_titlebar_size || y > 199)
return;
xl = old_xl;
if (!(pic->aux_map[ytotal + xl] & clipmask)) { // go left
while (xl && !(pic->aux_map[ytotal + xl - 1] & clipmask))
--xl;
} else // go right and look for the first valid spot
while ((xl <= old_xr) && (pic->aux_map[ytotal + xl] & clipmask))
++xl;
if (xl > old_xr) // No fillable strip above the last one
return;
assert((ytotal + xl) >= 0);
xr = xl;
while (xr < 320 && !(pic->aux_map[ytotal + xr] & clipmask)) {
pic->aux_map[ytotal + xr] |= fillmask;
++xr;
}
assert((ytotal + xr) <= 64000);
--xr;
if (xr < xl)
return;
// Check whether we need to recurse on branches in the same direction
if ((y > sci_titlebar_size && dy < 0) || (y < 199 && dy > 0)) {
state = 0;
xcont = xr + 1;
while (xcont <= old_xr) {
if (pic->aux_map[ytotal + xcont] & clipmask)
state = 0;
else if (!state) { // recurse
state = 1;
AUXBUF_FILL_HELPER(pic, xcont, old_xr, y - dy, dy, clipmask, control, sci_titlebar_size);
}
++xcont;
}
}
// Check whether we need to recurse on backward branches:
// left
if (xl < old_xl - 1) {
state = 0;
for (xcont = old_xl - 1; xcont >= xl; xcont--) {
if (pic->aux_map[oldytotal + xcont] & clipmask)
state = xcont;
else if (state) { // recurse
AUXBUF_FILL_HELPER(pic, xcont, state, y, -dy, clipmask, control, sci_titlebar_size);
state = 0;
}
}
}
// right
if (xr > old_xr + 1) {
state = 0;
for (xcont = old_xr + 1; xcont <= xr; xcont++) {
if (pic->aux_map[oldytotal + xcont] & clipmask)
state = xcont;
else if (state) { // recurse
AUXBUF_FILL_HELPER(pic, state, xcont, y, -dy, clipmask, control, sci_titlebar_size);
state = 0;
}
}
}
assert((ytotal + xl) >= 0);
assert((ytotal + xr + 1) <= 64000);
if (control)
memset(pic->control_map->index_data + ytotal + xl, control, xr - xl + 1);
oldytotal = ytotal;
old_xr = xr;
old_xl = xl;
} while (1);
}
static void AUXBUF_FILL(gfxr_pic_t *pic, int x, int y, int clipmask, int control, int sci_titlebar_size) {
// Fills the aux buffer and the control map (if control != 0)
int xl, xr;
int ytotal = y * 320;
#ifdef DRAW_SCALED
unsigned const char fillmask = 0x78;
#else
unsigned const char fillmask = 0x4;
#endif
#ifndef DRAW_SCALED
if (!control || !(clipmask & 4))
return; // Without pic scaling, we only do this to fill the control map
#endif
if (clipmask & 1)
clipmask = 1; // vis
else if (clipmask & 2)
clipmask = 2; // pri
else if (clipmask & 4)
clipmask = 4; // ctl
else return;
#ifdef DRAW_SCALED
clipmask |= fillmask; // Bits 3-5
#endif
if (pic->aux_map[ytotal + x] & clipmask)
return;
pic->aux_map[ytotal + x] |= fillmask;
xl = x;
while (xl && !(pic->aux_map[ytotal + xl - 1] & clipmask)) {
--xl;
pic->aux_map[ytotal + xl] |= fillmask;
}
xr = x;
while ((xr < 319) && !(pic->aux_map[ytotal + xr + 1] & clipmask)) {
++xr;
pic->aux_map[ytotal + xr] |= fillmask;
}
clipmask |= CLIPMASK_HARD_BOUND; // Guarantee clipping
if (control) // Draw the same strip on the control map
memset(pic->control_map->index_data + ytotal + xl, control, xr - xl + 1);
if (y > sci_titlebar_size)
AUXBUF_FILL_HELPER(pic, xl, xr, y, -1, clipmask, control, sci_titlebar_size);
if (y < 199)
AUXBUF_FILL_HELPER(pic, xl, xr, y, + 1, clipmask, control, sci_titlebar_size);
}
#undef CLIPMASK_HARD_BOUND
#ifdef FILL_RECURSIVE_DEBUG
# define PRINT_DEBUG0(s) if (!fillmagc) fprintf(stderr, s)
# define PRINT_DEBUG1(s,p1) if (!fillmagc) fprintf(stderr, s, p1)
# define PRINT_DEBUG4(s,p1,p2,p3,p4) if (!fillmagc) fprintf(stderr, s, p1)
#else
# define PRINT_DEBUG0(s)
# define PRINT_DEBUG1(s,p1)
# define PRINT_DEBUG4(s,p1,p2,p3,p4)
#endif
#ifdef DRAW_SCALED
# define SCALED_CHECK(x) (x)
# define IS_BOUNDARY(x, y, index) (((index) & legalmask) != legalcolor)
#else
# define SCALED_CHECK(x) 1
# define IS_BOUNDARY(x, y, index) ( \
(((x)+(y)) & 1)? /* figure out which part of the mask to use, to simulate dithering */ \
((((index)) & ((legalmask) )) != ((legalcolor) & ((legalmask)))) /* odd coordinate */ \
: ((((index)) & ((legalmask) >> 8)) != ((legalcolor) & ((legalmask) >> 8))) /* even coordinate */ \
)
#endif
static void FILL_FUNCTION_RECURSIVE(gfxr_pic_t *pic, int old_xl, int old_xr, int y, int dy, byte *bounds,
int legalcolor, int legalmask, int color, int priority, int drawenable, int sci_titlebar_size) {
int linewidth = pic->mode->xfact * 320;
int miny = pic->mode->yfact * sci_titlebar_size;
int maxy = pic->mode->yfact * 200;
int xl, xr;
int oldytotal = y * linewidth;
#ifdef DRAW_SCALED
int old_proj_y = -42;
int proj_y;
int proj_ytotal;
int proj_x;
int proj_xl_bound = 0;
int proj_xr_bound = 0;
#endif
do {
int ytotal = oldytotal + (linewidth * dy);
int xcont;
int state;
y += dy;
#ifdef FILL_RECURSIVE_DEBUG
if (!fillc)
return;
else if (!fillmagc) {
--fillc;
}
#endif
if (y < miny || y >= maxy) {
PRINT_DEBUG0("ABRT on failed initial assertion!\n");
return;
}
#ifdef DRAW_SCALED
proj_y = y / pic->mode->yfact;
if (proj_y != old_proj_y) {
// First, find the projected coordinates, unless known already:
proj_ytotal = proj_y * 320;
proj_x = old_xl / pic->mode->xfact;
proj_xl_bound = proj_x;
if (SCALED_CHECK(pic->aux_map[proj_ytotal + proj_xl_bound] & FRESH_PAINT)) {
while (proj_xl_bound && pic->aux_map[proj_ytotal + proj_xl_bound - 1] & FRESH_PAINT)
--proj_xl_bound;
} else {
while (proj_xl_bound < 319 && !(pic->aux_map[proj_ytotal + proj_xl_bound + 1] & FRESH_PAINT))
++proj_xl_bound;
if (proj_xl_bound < 319)
++proj_xl_bound;
}
if (proj_xl_bound == 319
&& !(pic->aux_map[proj_ytotal + proj_xl_bound] & FRESH_PAINT)) {
PRINT_DEBUG0("ABRT because proj_xl_bound couldn't be found\n");
return;
}
proj_xr_bound = (proj_xl_bound > proj_x) ? proj_xl_bound : proj_x;
while ((proj_xr_bound < 319)
&& pic->aux_map[proj_ytotal + proj_xr_bound + 1] & FRESH_PAINT)
++proj_xr_bound;
#ifdef FILL_RECURSIVE_DEBUG
if (!fillmagc) {
fprintf(stderr, "l%d: {%d,%d} | ", proj_y, proj_xl_bound, proj_xr_bound);
pic->aux_map[proj_y*320 + proj_xl_bound] |= 0x2;
pic->aux_map[proj_y*320 + proj_xr_bound] |= 0x2;
}
#endif
proj_xl_bound *= pic->mode->xfact;
if (proj_xl_bound)
proj_xl_bound -= pic->mode->xfact - 1;
if (proj_xr_bound < 319)
++proj_xr_bound;
proj_xr_bound *= pic->mode->xfact;
proj_xr_bound += pic->mode->xfact - 1;
old_proj_y = proj_y;
}
#else
# define proj_xl_bound 0
# define proj_xr_bound 319
#endif
// Now we have the projected limits, get the real ones:
xl = (old_xl > proj_xl_bound) ? old_xl : proj_xl_bound;
if (!IS_BOUNDARY(xl, y + 1, bounds[ytotal + xl])) { // go left as far as possible
while (xl > proj_xl_bound && (!IS_BOUNDARY(xl - 1, y + 1, bounds[ytotal + xl - 1])))
--xl;
} else // go right until the fillable area starts
while (xl < proj_xr_bound && (IS_BOUNDARY(xl, y + 1, bounds[ytotal + xl])))
++xl;
PRINT_DEBUG1("<%d,", xl);
if ((xl > proj_xr_bound)
|| (xl > old_xr)) {
PRINT_DEBUG0("ABRT because xl > xr_bound\n");
return;
}
xr = (xl > old_xl) ? xl : old_xl;
while (xr < proj_xr_bound && (!IS_BOUNDARY(xr + 1, y + 1, bounds[ytotal + xr + 1])))
++xr;
PRINT_DEBUG1("%d> -> ", xr);
if (IS_BOUNDARY(xl, y + 1, bounds[ytotal + xl])) {
PRINT_DEBUG0("ABRT because xl illegal\n");
return;
}
#ifdef DRAW_SCALED
PRINT_DEBUG4("[%d[%d,%d]%d]\n", proj_xl_bound, xl, xr, proj_xr_bound);
if (xl < proj_xl_bound && xr - 3*pic->mode->xfact < proj_xl_bound) {
PRINT_DEBUG0("ABRT interval left of zone\n");
return;
}
if (xr > proj_xr_bound && xl + 3*pic->mode->xfact > proj_xr_bound) {
PRINT_DEBUG0("ABRT because interval right of zone\n");
return;
}
#endif
if (drawenable & GFX_MASK_VISUAL)
memset(pic->visual_map->index_data + ytotal + xl, color, xr - xl + 1);
if (drawenable & GFX_MASK_PRIORITY)
memset(pic->priority_map->index_data + ytotal + xl, priority, xr - xl + 1);
// Check whether we need to recurse on branches in the same direction
state = 0;
xcont = xr + 1;
while (xcont <= old_xr) {
if (IS_BOUNDARY(xcont, y + 1, bounds[ytotal + xcont]))
state = xcont;
else if (state) { // recurse
PRINT_DEBUG4("[%d[%d,%d],%d]: ", old_xl, xl, xr, old_xr);
PRINT_DEBUG4("rec BRANCH %d [%d,%d] l%d\n", dy, state, xcont, y - dy);
FILL_FUNCTION_RECURSIVE(pic, state, xcont, y - dy, dy, bounds, legalcolor,
legalmask, color, priority, drawenable, sci_titlebar_size);
state = 0;
}
++xcont;
}
// Check whether we need to recurse on backward branches:
// left
if (xl < old_xl - 1) {
state = 0;
for (xcont = old_xl - 1; xcont >= xl; xcont--) {
if (IS_BOUNDARY(xcont, y, bounds[oldytotal + xcont]))
state = xcont;
else if (state) { // recurse
PRINT_DEBUG4("[%d[%d,%d],%d]: ", old_xl, xl, xr, old_xr);
PRINT_DEBUG4("rec BACK-LEFT %d [%d,%d] l%d\n", -dy, state, xcont, y);
FILL_FUNCTION_RECURSIVE(pic, xcont, state, y, -dy, bounds,
legalcolor, legalmask, color, priority, drawenable,
sci_titlebar_size);
state = 0;
}
}
}
// right
if (xr > old_xr + 1) {
state = 0;
for (xcont = old_xr + 1; xcont <= xr; xcont++) {
if (IS_BOUNDARY(xcont, y, bounds[oldytotal + xcont]))
state = xcont;
else if (state) { // recurse
PRINT_DEBUG4("[%d[%d,%d],%d]: ", old_xl, xl, xr, old_xr);
PRINT_DEBUG4("rec BACK-RIGHT %d [%d,%d] l%d\n", -dy, state, xcont, y);
FILL_FUNCTION_RECURSIVE(pic, state, xcont, y, -dy, bounds,
legalcolor, legalmask, color, priority, drawenable,
sci_titlebar_size);
state = 0;
}
}
}
oldytotal = ytotal;
old_xl = xl;
old_xr = xr;
} while (1);
}
static void FILL_FUNCTION(gfxr_pic_t *pic, int x_320, int y_200, int color, int priority, int control, int drawenable,
int sci_titlebar_size) {
int linewidth = pic->mode->xfact * 320;
int x, y;
int xl, xr;
int ytotal;
int bitmask;
byte *bounds = NULL;
int legalcolor, legalmask;
#ifdef DRAW_SCALED
int min_x, min_y, max_x, max_y;
#endif
int original_drawenable = drawenable; // Backup, since we need the unmodified value
// for filling the aux and control map
// Restrict drawenable not to restrict itself to zero
if (pic->control_map->index_data[y_200 * 320 + x_320] != 0)
drawenable &= ~GFX_MASK_CONTROL;
if (color == 0xff)
drawenable &= ~GFX_MASK_VISUAL;
if (priority == 0) {
drawenable &= ~GFX_MASK_PRIORITY;
original_drawenable &= ~GFX_MASK_PRIORITY;
}
AUXBUF_FILL(pic, x_320, y_200, original_drawenable, (drawenable & GFX_MASK_CONTROL) ? control : 0,
sci_titlebar_size);
#ifdef DRAW_SCALED
_gfxr_auxbuf_spread(pic, &min_x, &min_y, &max_x, &max_y);
if (_gfxr_find_fill_point(pic, min_x, min_y, max_x, max_y, x_320, y_200, color, drawenable, &x, &y)) {
//GFXWARN("Could not find scaled fill point, but unscaled fill point was available!\n");
drawenable &= GFX_MASK_PRIORITY;
if (!drawenable)
_gfxr_auxbuf_propagate_changes(pic, 0);
}
#else
x = x_320;
y = y_200;
#endif
ytotal = y * linewidth;
if (!drawenable)
return;
if (drawenable & GFX_MASK_VISUAL) {
bounds = pic->visual_map->index_data;
#if 0
// Code disabled, as removing it fixes qg1 pic.095 (unscaled). However,
// it MAY be of relevance to scaled pic drawing...
if ((color & 0xf) == 0xf // When dithering with white, do more
// conservative checks
|| (color & 0xf0) == 0xf0)
legalcolor = 0xff;
else
legalcolor = 0xf0; // Only check the second color
#endif
#ifdef DRAW_SCALED
legalcolor = 0xff;
legalmask = legalcolor;
#else
legalmask = 0x0ff0;
legalcolor = 0xff;
#endif
} else if (drawenable & GFX_MASK_PRIORITY) {
bounds = pic->priority_map->index_data;
legalcolor = 0;
legalmask = 0x0f0f;
} else {
legalcolor = 0;
legalmask = 0x0f0f;
}
if (!bounds || IS_BOUNDARY(x, y, bounds[ytotal + x]))
return;
if (bounds) {
#ifdef DRAW_SCALED
int proj_y = y_200;
int proj_ytotal = proj_y * 320;
int proj_x = x_320;
int proj_xl_bound;
int proj_xr_bound;
int proj_xl, proj_xr;
ytotal = y * linewidth;
proj_xl_bound = proj_x;
if (SCALED_CHECK(pic->aux_map[proj_ytotal + proj_xl_bound] & FRESH_PAINT)) {
while (proj_xl_bound && SCALED_CHECK(pic->aux_map[proj_ytotal + proj_xl_bound - 1] & FRESH_PAINT))
--proj_xl_bound;
} else
while (proj_xl_bound < 319 && SCALED_CHECK(!(pic->aux_map[proj_ytotal + proj_xl_bound + 1] & FRESH_PAINT)))
++proj_xl_bound;
proj_xr_bound = (proj_xl_bound > proj_x) ? proj_xl_bound : proj_x;
while ((proj_xr_bound < 319) && SCALED_CHECK(pic->aux_map[proj_ytotal + proj_xr_bound + 1] & FRESH_PAINT))
++proj_xr_bound;
proj_xl = proj_xl_bound;
proj_xr = proj_xr_bound;
proj_xl_bound *= pic->mode->xfact;
if (proj_xl_bound)
proj_xl_bound -= pic->mode->xfact - 1;
if (proj_xr_bound < 319)
++proj_xr_bound;
proj_xr_bound *= pic->mode->xfact;
proj_xr_bound += pic->mode->xfact - 1;
#endif
xl = x;
while (xl > proj_xl_bound && (!IS_BOUNDARY(xl - 1, y, bounds[ytotal + xl -1])))
--xl;
while (x < proj_xr_bound && (!IS_BOUNDARY(x + 1, y, bounds[ytotal + x + 1])))
++x;
xr = x;
if (drawenable & GFX_MASK_VISUAL)
memset(pic->visual_map->index_data + ytotal + xl, color, xr - xl + 1);
if (drawenable & GFX_MASK_PRIORITY)
memset(pic->priority_map->index_data + ytotal + xl, priority, xr - xl + 1);
FILL_FUNCTION_RECURSIVE(pic, xl, xr, y, -1, bounds, legalcolor, legalmask, color, priority, drawenable,
sci_titlebar_size);
FILL_FUNCTION_RECURSIVE(pic, xl, xr, y, + 1, bounds, legalcolor, legalmask, color, priority, drawenable,
sci_titlebar_size);
}
// Now finish the aux buffer
bitmask = drawenable & (((color != 0xff) ? 1 : 0) | ((priority) ? 2 : 0) | ((control) ? 4 : 0));
#ifdef DRAW_SCALED
# ifdef FILL_RECURSIVE_DEBUG
if (fillmagc)
# endif
_gfxr_auxbuf_propagate_changes(pic, bitmask);
#endif
}
#undef SCALED_CHECK
#undef IS_BOUNDARY
#ifndef DRAW_SCALED
# undef proj_xl_bound
# undef proj_xr_bound
#endif
} // End of namespace Sci