#include "../mem.h"
#include "../types.h"
#include "../q.h"
+#include "../MD5.h"
#include "poly.h"
#include "active.h"
#include "xrow.h"
static gfxpoly_t*current_polygon = 0;
void gfxpoly_fail(char*expr, char*file, int line, const char*function)
{
+ if(!current_polygon) {fprintf(stderr, "error outside polygon\n");exit(1);}
+
+ void*md5 = init_md5();
+
+ edge_t* s = current_polygon->edges;
+ while(s) {
+ update_md5(md5, (unsigned char*)&s->a.x, sizeof(s->a.x));
+ update_md5(md5, (unsigned char*)&s->a.y, sizeof(s->a.y));
+ update_md5(md5, (unsigned char*)&s->b.x, sizeof(s->b.x));
+ update_md5(md5, (unsigned char*)&s->b.y, sizeof(s->b.y));
+ s = s->next;
+ }
+ unsigned char h[16];
+ char filename[32+4+1];
+ finish_md5(md5, h);
+ sprintf(filename, "%02x%02x%02x%02x%02x%02x%02x%02x%02x%02x%02x%02x%02x%02x%02x%02x.ps",
+ h[0],h[1],h[2],h[3],h[4],h[5],h[6],h[7],h[8],h[9],h[10],h[11],h[12],h[13],h[14],h[15]);
+
fprintf(stderr, "assert(%s) failed in %s in line %d: %s\n", expr, file, line, function);
- fprintf(stderr, "I'm saving a debug file \"poly.ps\" to the current directory.\n");
- gfxpoly_save(current_polygon, "poly.ps");
+ fprintf(stderr, "I'm saving a debug file \"%s\" to the current directory.\n", filename);
+
+ gfxpoly_save(current_polygon, filename);
exit(1);
}
-char point_equals(const void*o1, const void*o2)
+static char point_equals(const void*o1, const void*o2)
{
const point_t*p1 = o1;
const point_t*p2 = o2;
return p1->x == p2->x && p1->y == p2->y;
}
-unsigned int point_hash(const void*o)
+static unsigned int point_hash(const void*o)
{
const point_t*p = o;
return p->x^p->y;
}
-void* point_dup(const void*o)
+static void* point_dup(const void*o)
{
const point_t*p = o;
point_t*n = malloc(sizeof(point_t));
n->y = p->y;
return n;
}
-void point_free(void*o)
+static void point_free(void*o)
{
point_t*p = o;
p->x = 0;
p->y = 0;
free(p);
}
-type_t point_type = {
+static type_t point_type = {
equals: point_equals,
hash: point_hash,
dup: point_dup,
};
typedef struct _status {
- int y;
- int num_polygons;
+ int32_t y;
actlist_t*actlist;
heap_t*queue;
edge_t*output;
xrow_t*xrow;
windrule_t*windrule;
+ windcontext_t*context;
segment_t*ending_segments;
#ifdef CHECKS
dict_t*seen_crossings; //list of crossing we saw so far
#endif
} status_t;
-int compare_events_simple(const void*_a,const void*_b)
+/* compare_events_simple differs from compare_events in that it schedules
+ events from left to right regardless of type. It's only used in horizontal
+ processing, in order to get an x-wise sorting of the current scanline */
+static int compare_events_simple(const void*_a,const void*_b)
{
event_t* a = (event_t*)_a;
event_t* b = (event_t*)_b;
- if(a->p.y < b->p.y) {
- return 1;
- } else if(a->p.y > b->p.y) {
- return -1;
- } else if(a->p.x < b->p.x) {
- return 1;
- } else if(a->p.x > b->p.x) {
- return -1;
- } else
- return 0;
+ int d = b->p.y - a->p.y;
+ if(d) return d;
+ d = b->p.x - a->p.x;
+ if(d) return d;
+ return 0;
}
-int compare_events(const void*_a,const void*_b)
+static int compare_events(const void*_a,const void*_b)
{
event_t* a = (event_t*)_a;
event_t* b = (event_t*)_b;
int d = b->p.y - a->p.y;
if(d) return d;
- /* we need to schedule end before intersect (so that a segment about
+ /* we need to schedule end after intersect (so that a segment about
to end has a chance to tear up a few other segs first) and start
- events after intersect (so that start segments don't position themselves
- between two segments about to intersect (not a problem as such, but makes
- things slower)). Horizontal lines come last, because the only purpose
+ events after end (in order not to confuse the intersection check, which
+ assumes there's an actual y overlap between active segments)).
+ Horizontal lines come last, because the only purpose
they have is to create snapping coordinates for the segments (still)
- existing in this scanline */
+ existing in this scanline.
+ */
d = b->type - a->type;
if(d) return d;
d = b->p.x - a->p.x;
}
return t;
}
+
char gfxpoly_check(gfxpoly_t*poly)
{
edge_t* s = poly->edges;
gfxpoly_t* gfxpoly_save(gfxpoly_t*poly, const char*filename)
{
FILE*fi = fopen(filename, "wb");
+ fprintf(fi, "%% gridsize %f\n", poly->gridsize);
fprintf(fi, "%% begin\n");
edge_t* s = poly->edges;
while(s) {
return e;
}
-void event_dump(event_t*e)
+static void event_dump(event_t*e)
{
if(e->type == EVENT_HORIZONTAL) {
fprintf(stderr, "Horizontal [%d] (%d,%d) -> (%d,%d)\n", e->s1->nr, e->s1->a.x, e->s1->a.y, e->s1->b.x, e->s1->b.y);
fprintf(stderr, "event: segment [%d] ends at (%d,%d)\n", e->s1->nr, e->p.x, e->p.y);
} else if(e->type == EVENT_CROSS) {
fprintf(stderr, "event: segment [%d] and [%d] intersect at (%d,%d)\n", e->s1->nr, e->s2->nr, e->p.x, e->p.y);
+ } else if(e->type == EVENT_CORNER) {
+ fprintf(stderr, "event: segment [%d] ends, segment [%d] starts, at (%d,%d)\n", e->s1->nr, e->s2->nr, e->p.x, e->p.y);
} else {
assert(0);
}
static inline max32(int32_t v1, int32_t v2) {return v1>v2?v1:v2;}
static inline min32(int32_t v1, int32_t v2) {return v1<v2?v1:v2;}
-void segment_dump(segment_t*s)
+static void segment_dump(segment_t*s)
{
- fprintf(stderr, "(%d,%d)->(%d,%d) ", s->a.x, s->a.y, s->b.x, s->b.y);
- fprintf(stderr, " dx:%d dy:%d k:%f dx/dy=%f\n", s->delta.x, s->delta.y, s->k,
+ fprintf(stderr, "[%d] (%d,%d)->(%d,%d) ", s->nr, s->a.x, s->a.y, s->b.x, s->b.y);
+ fprintf(stderr, " dx:%d dy:%d k:%f dx/dy=%f\n", s->delta.x, s->delta.y, s->k,
(double)s->delta.x / s->delta.y);
}
-void segment_init(segment_t*s, int x1, int y1, int x2, int y2, windstate_t windstate, int polygon_nr)
+static void segment_init(segment_t*s, int32_t x1, int32_t y1, int32_t x2, int32_t y2, int polygon_nr)
{
if(y1<y2) {
s->dir = DIR_DOWN;
} else if(y1>y2) {
- int x = x1;x1=x2;x2=x;
- int y = y1;y1=y2;y2=y;
+ int32_t x = x1;x1=x2;x2=x;
+ int32_t y = y1;y1=y2;y2=y;
s->dir = DIR_UP;
} else {
/* up/down for horizontal segments is handled by "rotating"
s->dir = DIR_UP;
if(x1>x2) {
s->dir = DIR_DOWN;
- int x = x1;x1=x2;x2=x;
- int y = y1;y1=y2;y2=y;
+ int32_t x = x1;x1=x2;x2=x;
+ int32_t y = y1;y1=y2;y2=y;
}
}
s->a.x = x1;
s->nr = segment_count++;
#endif
+#ifdef CHECKS
assert(LINE_EQ(s->a, s) == 0);
assert(LINE_EQ(s->b, s) == 0);
assert(LINE_EQ(p, s) <= 0);
p.x = max32(s->a.x, s->b.x);
assert(LINE_EQ(p, s) >= 0);
+#endif
dict_init2(&s->scheduled_crossings, &ptr_type, 0);
}
-segment_t* segment_new(int32_t x1, int32_t y1, int32_t x2, int32_t y2, windstate_t initial, int polygon_nr)
+static segment_t* segment_new(int32_t x1, int32_t y1, int32_t x2, int32_t y2, int polygon_nr)
{
segment_t*s = (segment_t*)rfx_calloc(sizeof(segment_t));
- segment_init(s, x1, y1, x2, y2, initial, polygon_nr);
+ segment_init(s, x1, y1, x2, y2, polygon_nr);
return s;
}
-void segment_destroy(segment_t*s)
+
+static void segment_destroy(segment_t*s)
{
dict_clear(&s->scheduled_crossings);
free(s);
}
-void gfxpoly_enqueue(edge_t*list, heap_t*queue, windstate_t initial, int polygon_nr)
+static void gfxpoly_enqueue(edge_t*list, heap_t*queue, int polygon_nr)
{
edge_t*l;
for(l=list;l;l=l->next) {
fprintf(stderr, "Warning: intersector input contains zero-length segments\n");
continue;
}
- segment_t*s = segment_new(l->a.x, l->a.y, l->b.x, l->b.y, initial, polygon_nr);
+ segment_t*s = segment_new(l->a.x, l->a.y, l->b.x, l->b.y, polygon_nr);
+#ifdef DEBUG
if(l->tmp)
s->nr = l->tmp;
-#ifdef DEBUG
fprintf(stderr, "[%d] (%d,%d) -> (%d,%d) %s\n",
s->nr, s->a.x, s->a.y, s->b.x, s->b.y,
s->dir==DIR_UP?"up":"down");
}
}
-void schedule_endpoint(status_t*status, segment_t*s)
+static void schedule_endpoint(status_t*status, segment_t*s)
{
// schedule end point of segment
assert(s->b.y > status->y);
heap_put(status->queue, &e);
}
-void schedule_crossing(status_t*status, segment_t*s1, segment_t*s2)
+static void schedule_crossing(status_t*status, segment_t*s1, segment_t*s2)
{
/* the code that's required (and the checks you can perform) before
it can be said with 100% certainty that we indeed have a valid crossing
return; // we already know about this one
}
- double adx = s1->delta.x;
- double ady = s1->delta.y;
- double bdx = s2->delta.x;
- double bdy = s2->delta.y;
- double det = adx*bdy - ady*bdx;
+ double det = (double)s1->delta.x*s2->delta.y - (double)s1->delta.y*s2->delta.x;
if(!det) {
if(s1->k == s2->k) {
// lines are exactly on top of each other (ignored)
return;
}
+ /* TODO: should we precompute these? */
double la = (double)s1->a.x*(double)s1->b.y - (double)s1->a.y*(double)s1->b.x;
double lb = (double)s2->a.x*(double)s2->b.y - (double)s2->a.y*(double)s2->b.x;
point_t p;
- p.x = (int32_t)ceil((-la*bdx +lb*adx) / det);
- p.y = (int32_t)ceil((+lb*ady -la*bdy) / det);
+ p.x = (int32_t)ceil((-la*s2->delta.x + lb*s1->delta.x) / det);
+ p.y = (int32_t)ceil((+lb*s1->delta.y - la*s2->delta.y) / det);
assert(p.y >= status->y);
#ifdef CHECKS
return;
}
-void exchange_two(status_t*status, event_t*e)
+static void exchange_two(status_t*status, event_t*e)
{
//exchange two segments in list
segment_t*s1 = e->s1;
if(!dict_contains(status->intersecting_segs, s2))
dict_put(status->intersecting_segs, s2, 0);
#endif
- segment_t*left = actlist_left(status->actlist, s2);
- segment_t*right = actlist_right(status->actlist, s1);
- assert(left == s1);
- assert(right == s2);
+ assert(s2->left == s1);
+ assert(s1->right == s2);
actlist_swap(status->actlist, s1, s2);
- assert(actlist_right(status->actlist, s2) == s1);
- assert(actlist_left(status->actlist, s1) == s2);
- left = actlist_left(status->actlist, s2);
- right = actlist_right(status->actlist, s1);
+ assert(s2->right == s1);
+ assert(s1->left == s2);
+ segment_t*left = s2->left;
+ segment_t*right = s1->right;
if(left)
schedule_crossing(status, left, s2);
if(right)
typedef struct _box {
point_t left1, left2, right1, right2;
} box_t;
-static inline box_t box_new(int x, int y)
+static inline box_t box_new(int32_t x, int32_t y)
{
box_t box;
box.right1.x = box.right2.x = x;
if(s->fs_out) {
#ifdef DEBUG
- fprintf(stderr, "[%d] receives next point (%d,%d)->(%d,%d) (drawing)\n", s->nr,
+ fprintf(stderr, "[%d] receives next point (%d,%d)->(%d,%d) (drawing)\n", s->nr,
s->pos.x, s->pos.y, p.x, p.y);
#endif
// omit horizontal lines
if(s->pos.y != p.y) {
edge_t*e = rfx_calloc(sizeof(edge_t));
+#ifdef DEBUG
e->tmp = s->nr;
+#endif
e->a = s->pos;
e->b = p;
assert(e->a.y != e->b.y);
s->pos = p;
}
-/* by restricting the recalculation of line segments to a range between the lowest
- and the highest modified segment, we only do about a 33% overprocessing of fill
- styles. (update: that statistic might be outdated now that xmin/xmax are double) */
typedef struct _segrange {
double xmin;
segment_t*segmin;
segment_t*segmax;
} segrange_t;
-static inline char xpos_eq(segment_t*s1, segment_t*s2, int y)
-{
- if(XPOS_EQ(s1, s2, y)) {
- return 1;
- }
- return 0;
-}
-
-void segrange_adjust_endpoints(segrange_t*range, int y)
+static void segrange_adjust_endpoints(segrange_t*range, int32_t y)
{
-#ifdef CHECK
- /* this would mean that the segment left/right of the minimum/maximum
- intersects the current segment exactly at the scanline, but somehow
- wasn't found to be passing through the same snapping box */
- assert(!min || !min->left || !XPOS_EQ(min, min->left, y));
- assert(!max || !max->right || !XPOS_EQ(max, max->right, y));
-#endif
-
+#define XPOS_EQ(s1,s2,ypos) (XPOS((s1),(ypos))==XPOS((s2),(ypos)))
segment_t*min = range->segmin;
segment_t*max = range->segmax;
- if(min) while(min->left && xpos_eq(min, min->left, y)) {
+
+ /* we need this because if two segments intersect exactly on
+ the scanline, segrange_test_segment_{min,max} can't tell which
+ one is smaller/larger */
+ if(min) while(min->left && XPOS_EQ(min, min->left, y)) {
min = min->left;
}
- if(max) while(max->right && xpos_eq(max, max->right, y)) {
+ if(max) while(max->right && XPOS_EQ(max, max->right, y)) {
max = max->right;
}
range->segmin = min;
range->segmax = max;
}
-void segrange_test_segment_min(segrange_t*range, segment_t*seg, int y)
+static void segrange_test_segment_min(segrange_t*range, segment_t*seg, int32_t y)
{
if(!seg) return;
/* we need to calculate the xpos anew (and can't use start coordinate or
intersection coordinate), because we need the xpos exactly at the end of
this scanline.
- TODO: might be faster to use XPOS_COMPARE here (see also _max)
*/
double x = XPOS(seg, y);
if(!range->segmin || x<range->xmin) {
range->xmin = x;
}
}
-void segrange_test_segment_max(segrange_t*range, segment_t*seg, int y)
+static void segrange_test_segment_max(segrange_t*range, segment_t*seg, int32_t y)
{
if(!seg) return;
double x = XPOS(seg, y);
for(t=0;t<status->xrow->num;t++) {
box_t box = box_new(status->xrow->x[t], y);
segment_t*seg = actlist_find(status->actlist, box.left2, box.left2);
-
- seg = actlist_right(status->actlist, seg);
+ seg = actlist_right(status->actlist, seg);
while(seg) {
if(seg->a.y == y) {
// this segment started in this scanline, ignore it
//break;
}
}
- seg = actlist_right(status->actlist, seg);
+ seg = seg->right;
}
}
segrange_test_segment_min(range, first, y);
for(t=status->xrow->num-1;t>=0;t--) {
box_t box = box_new(status->xrow->x[t], y);
segment_t*seg = actlist_find(status->actlist, box.right2, box.right2);
-
+
while(seg) {
if(seg->a.y == y) {
// this segment started in this scanline, ignore it
//break;
}
}
- seg = actlist_left(status->actlist, seg);
+ seg = seg->left;
}
}
segrange_test_segment_min(range, last, y);
(One other option to consider, however, would be to create a new active list only
for ending segments)
*/
-void add_points_to_ending_segments(status_t*status, int32_t y)
+static void add_points_to_ending_segments(status_t*status, int32_t y)
{
segment_t*seg = status->ending_segments;
while(seg) {
segment_t*next = seg->right;seg->right=0;
assert(seg->b.y == status->y);
-
+
if(status->xrow->num == 1) {
// shortcut
+ assert(seg->b.x == status->xrow->x[0]);
point_t p = {status->xrow->x[0], y};
insert_point_into_segment(status, seg, p);
} else {
static void recalculate_windings(status_t*status, segrange_t*range)
{
+#ifdef DEBUG
+ fprintf(stderr, "range: [%d]..[%d]\n", SEGNR(range->segmin), SEGNR(range->segmax));
+#endif
segrange_adjust_endpoints(range, status->y);
segment_t*s = range->segmin;
s = actlist_leftmost(status->actlist);
while(s && s!=range->segmin) {
assert(!s->changed);
- s = actlist_right(status->actlist, s);
+ s = s->right;
}
s = actlist_rightmost(status->actlist);
while(s && s!=range->segmax) {
assert(!s->changed);
- s = actlist_left(status->actlist, s);
+ s = s->left;
}
/* in check mode, go through the whole interval so we can test
that all polygons where the fillstyle changed also have seg->changed=1 */
#endif
if(end)
- end = actlist_right(status->actlist, end);
+ end = end->right;
while(s!=end) {
-#ifndef CHECK
- if(s->changed)
+#ifndef CHECKS
+ if(s->changed)
#endif
{
segment_t* left = actlist_left(status->actlist, s);
- windstate_t wind = left?left->wind:status->windrule->start(status->num_polygons);
- s->wind = status->windrule->add(wind, s->fs, s->dir, s->polygon_nr);
+ windstate_t wind = left?left->wind:status->windrule->start(status->context);
+ s->wind = status->windrule->add(status->context, wind, s->fs, s->dir, s->polygon_nr);
fillstyle_t*fs_old = s->fs_out;
s->fs_out = status->windrule->diff(&wind, &s->wind);
assert(!(!s->changed && fs_old!=s->fs_out));
s->changed = 0;
+#ifdef CHECKS
s->fs_out_ok = 1;
+#endif
#ifdef DEBUG
- fprintf(stderr, "[%d] %s/%d/%s/%s ", s->nr, s->dir==DIR_UP?"up":"down", s->wind.wind_nr, s->wind.is_filled?"fill":"nofill", s->fs_out?"draw":"omit");
+ fprintf(stderr, "[%d] %s/%d/%s/%s %s\n", s->nr, s->dir==DIR_UP?"up":"down", s->wind.wind_nr, s->wind.is_filled?"fill":"nofill", s->fs_out?"draw":"omit",
+ fs_old!=s->fs_out?"CHANGED":"");
#endif
}
- s = actlist_right(status->actlist, s);
+ s = s->right;
}
-#ifdef DEBUG
- fprintf(stderr, "\n");
-#endif
}
/* we need to handle horizontal lines in order to add points to segments
we otherwise would miss during the windrule re-evaluation */
-void intersect_with_horizontal(status_t*status, segment_t*h)
+static void intersect_with_horizontal(status_t*status, segment_t*h)
{
segment_t* left = actlist_find(status->actlist, h->a, h->a);
segment_t* right = actlist_find(status->actlist, h->b, h->b);
xrow_add(status->xrow, h->a.x);
point_t o = h->a;
- left = actlist_right(status->actlist, left);
- right = actlist_right(status->actlist, right);
+ if(!right) {
+ assert(!left);
+ return;
+ }
+
+ left = actlist_right(status->actlist, left); //first seg to the right of h->a
+ right = right->right; //first seg to the right of h->b
segment_t* s = left;
while(s!=right) {
assert(s);
- int x = XPOS_INT(s, status->y);
+ int32_t x = XPOS_INT(s, status->y);
#ifdef DEBUG
fprintf(stderr, "...into [%d] (%d,%d) -> (%d,%d) at (%d,%d)\n", s->nr,
s->a.x, s->a.y,
assert(s->delta.x > 0 && x <= s->b.x || s->delta.x <= 0 && x >= s->b.x);
xrow_add(status->xrow, x);
- s = actlist_right(status->actlist, s);
+ s = s->right;
}
}
-void event_apply(status_t*status, event_t*e)
+static void event_apply(status_t*status, event_t*e)
{
switch(e->type) {
case EVENT_HORIZONTAL: {
assert(!dict_contains(status->intersecting_segs, s));
assert(!dict_contains(status->segs_with_point, s));
#endif
- segment_t*left = actlist_left(status->actlist, s);
- segment_t*right = actlist_right(status->actlist, s);
+ segment_t*left = s->left;
+ segment_t*right = s->right;
actlist_delete(status->actlist, s);
if(left && right)
schedule_crossing(status, left, right);
+ /* schedule segment for xrow handling */
s->left = 0; s->right = status->ending_segments;
status->ending_segments = s;
break;
event_dump(e);
#endif
segment_t*s = e->s1;
- actlist_insert(status->actlist, e->p, s);
- segment_t*left = actlist_left(status->actlist, s);
- segment_t*right = actlist_right(status->actlist, s);
+ assert(e->p.x == s->a.x && e->p.y == s->a.y);
+ actlist_insert(status->actlist, s->a, s->b, s);
+ segment_t*left = s->left;
+ segment_t*right = s->right;
if(left)
schedule_crossing(status, left, s);
if(right)
#ifdef DEBUG
event_dump(e);
#endif
- if(actlist_right(status->actlist, e->s1) == e->s2 &&
- actlist_left(status->actlist, e->s2) == e->s1) {
+ if(e->s1->right == e->s2) {
+ assert(e->s2->left == e->s1);
exchange_two(status, e);
} else {
+ assert(e->s2->left != e->s1);
+#ifdef DEBUG
+ fprintf(stderr, "Ignore this crossing ([%d] not next to [%d])\n", e->s1->nr, e->s2->nr);
+#endif
/* ignore this crossing for now (there are some line segments in between).
it'll get rescheduled as soon as the "obstacles" are gone */
char del1 = dict_del(&e->s1->scheduled_crossings, e->s2);
}
#ifdef CHECKS
-void check_status(status_t*status)
+static void check_status(status_t*status)
{
DICT_ITERATE_KEY(status->intersecting_segs, segment_t*, s) {
if((s->pos.x != s->b.x ||
}
#endif
-static void add_horizontals(gfxpoly_t*poly, windrule_t*windrule)
+static void add_horizontals(gfxpoly_t*poly, windrule_t*windrule, windcontext_t*context)
{
/*
|..| |...........| | |
fprintf(stderr, "========================================================================\n");
#endif
heap_t* queue = heap_new(sizeof(event_t), compare_events_simple);
- gfxpoly_enqueue(poly->edges, queue, windrule->start(1), 0);
+ gfxpoly_enqueue(poly->edges, queue, 0);
actlist_t* actlist = actlist_new();
event_t*e = heap_chopmax(queue);
while(e) {
- int y = e->p.y;
- int x = 0;
+ int32_t y = e->p.y;
+ int32_t x = 0;
char fill = 0;
#ifdef DEBUG
fprintf(stderr, "----------------------------------- %d\n", y);
actlist_dump(actlist, y-1);
#endif
#ifdef CHECKS
- /* FIXME: this actually fails sometimes */
actlist_verify(actlist, y-1);
#endif
do {
#ifdef DEBUG
fprintf(stderr, "%d) draw horizontal line from %d to %d\n", y, x, e->p.x);
#endif
+ assert(x<e->p.x);
edge_t*l= malloc(sizeof(edge_t));
l->a.y = l->b.y = y;
- l->a.x = x;
- l->b.x = e->p.x;
+ /* we draw from low x to high x so that left/right fillstyles add up
+ (because the horizontal line's fill style controls the area *below* the line)
+ */
+ l->a.x = e->p.x;
+ l->b.x = x;
l->next = poly->edges;
poly->edges = l;
+#ifdef CHECKS
+ /* the output should always be intersection free polygons, so check this horizontal
+ line isn't hacking through any segments in the active list */
+ segment_t* start = actlist_find(actlist, l->b, l->b);
+ segment_t* s = actlist_find(actlist, l->a, l->a);
+ while(s!=start) {
+ assert(s->a.y == y || s->b.y == y);
+ s = s->left;
+ }
+#endif
}
segment_t*left = 0;
segment_t*s = e->s1;
- windstate_t before,after;
switch(e->type) {
case EVENT_START: {
- actlist_insert(actlist, e->p, s);
+ assert(e->p.x == s->a.x && e->p.y == s->a.y);
+ actlist_insert(actlist, s->a, s->b, s);
event_t e;
e.type = EVENT_END;
e.p = s->b;
e.s2 = 0;
heap_put(queue, &e);
left = actlist_left(actlist, s);
-
- before = left?left->wind:windrule->start(1);
- after = s->wind = windrule->add(before, s->fs, s->dir, s->polygon_nr);
break;
}
case EVENT_END: {
left = actlist_left(actlist, s);
actlist_delete(actlist, s);
-
- before = s->wind;
- after = left?left->wind:windrule->start(1);
break;
}
default: assert(0);
heap_destroy(queue);
}
-gfxpoly_t* gfxpoly_process(gfxpoly_t*poly, windrule_t*windrule)
+gfxpoly_t* gfxpoly_process(gfxpoly_t*poly, windrule_t*windrule, windcontext_t*context)
{
current_polygon = poly;
heap_t* queue = heap_new(sizeof(event_t), compare_events);
- gfxpoly_enqueue(poly->edges, queue, windrule->start(1), /*polygon nr*/0);
+ gfxpoly_enqueue(poly->edges, queue, /*polygon nr*/0);
status_t status;
memset(&status, 0, sizeof(status_t));
- status.num_polygons = 1;
status.queue = queue;
status.windrule = windrule;
+ status.context = context;
status.actlist = actlist_new();
#ifdef CHECKS
status.seen_crossings = dict_new2(&point_type);
gfxpoly_t*p = gfxpoly_new(poly->gridsize);
p->edges = status.output;
- add_horizontals(p, &windrule_evenodd); // output is always even/odd
+ add_horizontals(p, &windrule_evenodd, context); // output is always even/odd
return p;
}