/*** GEOMETRY.C ***/
#include <math.h>
#include "vdefs.h"
double deltax, deltay ;
int nedges, sqrt_nsites, nvertices ;
Freelist efl ;
void
geominit(void)
{
freeinit(&efl, sizeof(Edge)) ;
nvertices = nedges = 0 ;
sqrt_nsites = sqrt(nsites+4) ;
deltay = ymax - ymin ;
deltax = xmax - xmin ;
}
Edge *
bisect(Site * s1, Site * s2)
{
double dx, dy, adx, ady ;
Edge * newedge ;
newedge = (Edge *)getfree(&efl) ;
newedge->reg[0] = s1 ;
newedge->reg[1] = s2 ;
ref(s1) ;
ref(s2) ;
newedge->ep[0] = newedge->ep[1] = (Site *)NULL ;
dx = s2->coord.x - s1->coord.x ;
dy = s2->coord.y - s1->coord.y ;
adx = dx>0 ? dx : -dx ;
ady = dy>0 ? dy : -dy ;
newedge->c = s1->coord.x * dx + s1->coord.y * dy + (dx*dx +
dy*dy) * 0.5 ;
if (adx > ady)
{
newedge->a = 1.0 ;
newedge->b = dy/dx ;
newedge->c /= dx ;
}
else
{
newedge->b = 1.0 ;
newedge->a = dx/dy ;
newedge->c /= dy ;
}
newedge->edgenbr = nedges ;
out_bisector(newedge) ;
nedges++ ;
return (newedge) ;
}
Site *
intersect(Halfedge * el1, Halfedge * el2)
{
Edge * e1, * e2, * e ;
Halfedge * el ;
double d, xint, yint ;
int right_of_site ;
Site * v ;
e1 = el1->ELedge ;
e2 = el2->ELedge ;
if ((e1 == (Edge*)NULL) || (e2 == (Edge*)NULL))
{
return ((Site *)NULL) ;
}
if (e1->reg[1] == e2->reg[1])
{
return ((Site *)NULL) ;
}
d = (e1->a * e2->b) - (e1->b * e2->a) ;
if ((-1.0e-10 < d) && (d < 1.0e-10))
{
return ((Site *)NULL) ;
}
xint = (e1->c * e2->b - e2->c * e1->b) / d ;
yint = (e2->c * e1->a - e1->c * e2->a) / d ;
if ((e1->reg[1]->coord.y < e2->reg[1]->coord.y) ||
(e1->reg[1]->coord.y == e2->reg[1]->coord.y &&
e1->reg[1]->coord.x < e2->reg[1]->coord.x))
{
el = el1 ;
e = e1 ;
}
else
{
el = el2 ;
e = e2 ;
}
right_of_site = (xint >= e->reg[1]->coord.x) ;
if ((right_of_site && (el->ELpm == le)) ||
(!right_of_site && (el->ELpm == re)))
{
return ((Site *)NULL) ;
}
v = (Site *)getfree(&sfl) ;
v->refcnt = 0 ;
v->coord.x = xint ;
v->coord.y = yint ;
return (v) ;
}
/*** returns 1 if p is to right of halfedge e ***/
int
right_of(Halfedge * el, Point * p)
{
Edge * e ;
Site * topsite ;
int right_of_site, above, fast ;
double dxp, dyp, dxs, t1, t2, t3, yl ;
e = el->ELedge ;
topsite = e->reg[1] ;
right_of_site = (p->x > topsite->coord.x) ;
if (right_of_site && (el->ELpm == le))
{
return (1) ;
}
if(!right_of_site && (el->ELpm == re))
{
return (0) ;
}
if (e->a == 1.0)
{
dyp = p->y - topsite->coord.y ;
dxp = p->x - topsite->coord.x ;
fast = 0 ;
if ((!right_of_site & (e->b < 0.0)) ||
(right_of_site & (e->b >= 0.0)))
{
fast = above = (dyp >= e->b*dxp) ;
}
else
{
above = ((p->x + p->y * e->b) > (e->c)) ;
if (e->b < 0.0)
{
above = !above ;
}
if (!above)
{
fast = 1 ;
}
}
if (!fast)
{
dxs = topsite->coord.x - (e->reg[0])->coord.x ;
above = (e->b * (dxp*dxp - dyp*dyp))
<
(dxs * dyp * (1.0 + 2.0 * dxp /
dxs + e->b * e->b)) ;
if (e->b < 0.0)
{
above = !above ;
}
}
}
else /*** e->b == 1.0 ***/
{
yl = e->c - e->a * p->x ;
t1 = p->y - yl ;
t2 = p->x - topsite->coord.x ;
t3 = yl - topsite->coord.y ;
above = ((t1*t1) > ((t2 * t2) + (t3 * t3))) ;
}
return (el->ELpm == le ? above : !above) ;
}
void
endpoint(Edge * e, int lr, Site * s)
{
e->ep[lr] = s ;
ref(s) ;
if (e->ep[re-lr] == (Site *)NULL)
{
return ;
}
out_ep(e) ;
deref(e->reg[le]) ;
deref(e->reg[re]) ;
makefree((Freenode *)e, (Freelist *) &efl) ;
}
double
dist(Site * s, Site * t)
{
double dx,dy ;
dx = s->coord.x - t->coord.x ;
dy = s->coord.y - t->coord.y ;
return (sqrt(dx*dx + dy*dy)) ;
}
void
makevertex(Site * v)
{
v->sitenbr = nvertices++ ;
out_vertex(v) ;
}
void
deref(Site * v)
{
if (--(v->refcnt) == 0 )
{
makefree((Freenode *)v, (Freelist *)&sfl) ;
}
}
void
ref(Site * v)
{
++(v->refcnt) ;
}