104 |
|
|
105 |
|
|
106 |
|
hdbcoord(gc, hp, i) /* compute beam coordinates from index */ |
107 |
< |
BCOORD gc; /* returned */ |
107 |
> |
GCOORD gc[2]; /* returned */ |
108 |
|
register HOLO *hp; |
109 |
|
register int i; |
110 |
|
{ |
111 |
|
register int j, n; |
112 |
|
int n2, reverse; |
113 |
< |
BCOORD g2; |
113 |
> |
GCOORD g2[2]; |
114 |
|
/* check range */ |
115 |
|
if (i < 1 | i > nbeams(hp)) |
116 |
|
return(0); |
150 |
|
int |
151 |
|
hdbindex(hp, gc) /* compute index from beam coordinates */ |
152 |
|
register HOLO *hp; |
153 |
< |
register BCOORD gc; |
153 |
> |
register GCOORD gc[2]; |
154 |
|
{ |
155 |
< |
BCOORD g2; |
155 |
> |
GCOORD g2[2]; |
156 |
|
int reverse; |
157 |
|
register int i, j; |
158 |
|
/* check ordering and limits */ |
178 |
|
} |
179 |
|
|
180 |
|
|
181 |
+ |
hdcell(cp, hp, gc) /* compute cell coordinates */ |
182 |
+ |
register FVECT cp[4]; /* returned (may be passed as FVECT cp[2][2]) */ |
183 |
+ |
register HOLO *hp; |
184 |
+ |
register GCOORD *gc; |
185 |
+ |
{ |
186 |
+ |
register FLOAT *v; |
187 |
+ |
double d; |
188 |
+ |
/* compute common component */ |
189 |
+ |
VCOPY(cp[0], hp->orig); |
190 |
+ |
if (gc->w & 1) { |
191 |
+ |
v = hp->xv[gc->w>>1]; |
192 |
+ |
cp[0][0] += v[0]; cp[0][1] += v[1]; cp[0][2] += v[2]; |
193 |
+ |
} |
194 |
+ |
v = hp->xv[wg0[gc->w]]; |
195 |
+ |
d = (double)gc->i[0] / hp->grid[wg0[gc->w]]; |
196 |
+ |
VSUM(cp[0], cp[0], v, d); |
197 |
+ |
v = hp->xv[wg1[gc->w]]; |
198 |
+ |
d = (double)gc->i[1] / hp->grid[wg1[gc->w]]; |
199 |
+ |
VSUM(cp[0], cp[0], v, d); |
200 |
+ |
/* compute x1 sums */ |
201 |
+ |
v = hp->xv[wg0[gc->w]]; |
202 |
+ |
d = 1.0 / hp->grid[wg0[gc->w]]; |
203 |
+ |
VSUM(cp[1], cp[0], v, d); |
204 |
+ |
VSUM(cp[3], cp[0], v, d); |
205 |
+ |
/* compute y1 sums */ |
206 |
+ |
v = hp->xv[wg1[gc->w]]; |
207 |
+ |
d = 1.0 / hp->grid[wg1[gc->w]]; |
208 |
+ |
VSUM(cp[2], cp[0], v, d); |
209 |
+ |
VSUM(cp[3], cp[3], v, d); |
210 |
+ |
} |
211 |
+ |
|
212 |
+ |
|
213 |
|
hdlseg(lseg, hp, i) /* compute line segment for beam */ |
214 |
|
register int lseg[2][3]; |
215 |
|
register HOLO *hp; |
216 |
|
int i; |
217 |
|
{ |
218 |
< |
BCOORD gc; |
218 |
> |
GCOORD gc[2]; |
219 |
|
register int k; |
220 |
|
|
221 |
|
if (!hdbcoord(gc, hp, i)) /* compute grid coordinates */ |
251 |
|
double |
252 |
|
hdray(ro, rd, hp, gc, r) /* compute ray within a beam */ |
253 |
|
FVECT ro, rd; /* returned */ |
254 |
< |
register HOLO *hp; |
255 |
< |
register BCOORD gc; |
254 |
> |
HOLO *hp; |
255 |
> |
GCOORD gc[2]; |
256 |
|
BYTE r[2][2]; |
257 |
|
{ |
258 |
< |
FVECT p[2]; |
259 |
< |
register int i; |
260 |
< |
register FLOAT *v; |
229 |
< |
double d; |
258 |
> |
FVECT cp[4], p[2]; |
259 |
> |
register int i, j; |
260 |
> |
double d0, d1; |
261 |
|
/* compute entry and exit points */ |
262 |
|
for (i = 0; i < 2; i++) { |
263 |
< |
VCOPY(p[i], hp->orig); |
264 |
< |
if (gc[i].w & 1) { |
265 |
< |
v = hp->xv[gc[i].w>>1]; |
266 |
< |
p[i][0] += *v++; p[i][1] += *v++; p[i][2] += *v; |
267 |
< |
} |
268 |
< |
d = ( gc[i].i[0] + (1./256.)*(r[i][0]+.5) ) / |
238 |
< |
hp->grid[wg0[gc[i].w]]; |
239 |
< |
v = hp->xv[wg0[gc[i].w]]; |
240 |
< |
p[i][0] += d * *v++; p[i][1] += d * *v++; p[i][2] += d * *v; |
241 |
< |
d = (gc[i].i[1] + (1./256.)*(r[i][1]+.5)) / |
242 |
< |
hp->grid[wg1[gc[i].w]]; |
243 |
< |
v = hp->xv[wg1[gc[i].w]]; |
244 |
< |
p[i][0] += d * *v++; p[i][1] += d * *v++; p[i][2] += d * *v; |
263 |
> |
hdcell(cp, hp, gc+i); |
264 |
> |
d0 = (1./256.)*(r[i][0]+.5); |
265 |
> |
d1 = (1./256.)*(r[i][1]+.5); |
266 |
> |
for (j = 0; j < 3; j++) |
267 |
> |
p[i][j] = (1.-d0-d1)*cp[0][j] + |
268 |
> |
d0*cp[1][j] + d1*cp[2][j]; |
269 |
|
} |
270 |
|
VCOPY(ro, p[0]); /* assign ray origin and direction */ |
271 |
|
rd[0] = p[1][0] - p[0][0]; |
277 |
|
|
278 |
|
double |
279 |
|
hdinter(gc, r, hp, ro, rd) /* compute ray intersection with section */ |
280 |
< |
register BCOORD gc; /* returned */ |
280 |
> |
register GCOORD gc[2]; /* returned */ |
281 |
|
BYTE r[2][2]; /* returned */ |
282 |
|
register HOLO *hp; |
283 |
|
FVECT ro, rd; /* rd should be normalized */ |