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root/radiance/ray/src/meta/mgraph.c
Revision: 1.1
Committed: Sat Feb 22 02:07:26 2003 UTC (21 years, 9 months ago) by greg
Content type: text/plain
Branch: MAIN
CVS Tags: rad3R5
Log Message:
Changes and check-in for 3.5 release
Includes new source files and modifications not recorded for many years
See ray/doc/notes/ReleaseNotes for notes between 3.1 and 3.5 release

File Contents

# Content
1 #ifndef lint
2 static const char RCSid[] = "$Id$";
3 #endif
4 /*
5 * mgraph.c - routines for plotting graphs from variables.
6 *
7 * 6/23/86
8 *
9 * Greg Ward Larson
10 */
11
12 #include <stdio.h>
13
14 #include "mgvars.h"
15
16 #include "mgraph.h"
17
18 extern char *progname; /* argv[0] */
19
20 extern double goodstep(), floor(), ceil(), sin(), cos();
21
22 static BOUNDS xbounds, ybounds; /* the boundaries for the graph */
23
24 static double period = DEFPERIOD; /* period for polar plot */
25
26 static double axbegin, axsize; /* the mapped x axis boundaries */
27 static double aybegin, aysize; /* the mapped y axis boundaries */
28
29 static int npltbl[MAXCUR]; /* plottable points per curve */
30
31 static double lastx, lasty; /* last curve postion */
32 static int nplottable; /* number of plottable points */
33 static int nplotted; /* number of plotted points */
34
35
36 mgraph() /* plot the current graph */
37 {
38 /* load the symbol file */
39 if (gparam[SYMFILE].flags & DEFINED)
40 minclude(gparam[SYMFILE].v.s);
41 /* check for polar plot */
42 if (gparam[PERIOD].flags & DEFINED)
43 period = varvalue(gparam[PERIOD].name);
44
45 getbounds(); /* get the boundaries */
46 makeaxis(); /* draw the coordinate axis */
47 plotcurves(); /* plot the curves */
48
49 mendpage(); /* advance page */
50 }
51
52
53 getbounds() /* compute the boundaries */
54 {
55 int i, stretchbounds();
56
57 xbounds.min = gparam[XMIN].flags & DEFINED ?
58 varvalue(gparam[XMIN].name) - FTINY :
59 FHUGE ;
60 xbounds.max = gparam[XMAX].flags & DEFINED ?
61 varvalue(gparam[XMAX].name) + FTINY :
62 -FHUGE ;
63 ybounds.min = gparam[YMIN].flags & DEFINED ?
64 varvalue(gparam[YMIN].name) - FTINY :
65 FHUGE ;
66 ybounds.max = gparam[YMAX].flags & DEFINED ?
67 varvalue(gparam[YMAX].name) + FTINY :
68 -FHUGE ;
69
70 nplottable = 0;
71 for (i = 0; i < MAXCUR; i++) {
72 npltbl[i] = 0;
73 mgcurve(i, stretchbounds);
74 nplottable += npltbl[i];
75 }
76 if (nplottable == 0) {
77 fprintf(stderr, "%s: no plottable data\n", progname);
78 quit(1);
79 }
80
81 xbounds.step = gparam[XSTEP].flags & DEFINED ?
82 varvalue(gparam[XSTEP].name) :
83 period > FTINY ?
84 DEFPLSTEP*period :
85 goodstep(xbounds.max - xbounds.min) ;
86 if (!(gparam[XMIN].flags & DEFINED))
87 xbounds.min = floor(xbounds.min/xbounds.step) *
88 xbounds.step;
89 if (!(gparam[XMAX].flags & DEFINED))
90 xbounds.max = ceil(xbounds.max/xbounds.step) *
91 xbounds.step;
92 ybounds.step = gparam[YSTEP].flags & DEFINED ?
93 varvalue(gparam[YSTEP].name) :
94 period > FTINY ?
95 goodstep((ybounds.max - ybounds.min)*1.75) :
96 goodstep(ybounds.max - ybounds.min) ;
97 if (!(gparam[YMIN].flags & DEFINED))
98 ybounds.min = floor(ybounds.min/ybounds.step) *
99 ybounds.step;
100 if (!(gparam[YMAX].flags & DEFINED))
101 ybounds.max = ceil(ybounds.max/ybounds.step) *
102 ybounds.step;
103 if (gparam[XMAP].flags & DEFINED) {
104 axbegin = funvalue(gparam[XMAP].name, 1, &xbounds.min);
105 axsize = funvalue(gparam[XMAP].name, 1, &xbounds.max);
106 axsize -= axbegin;
107 } else {
108 axbegin = xbounds.min;
109 axsize = xbounds.max;
110 axsize -= axbegin;
111 }
112 if (gparam[YMAP].flags & DEFINED) {
113 aybegin = funvalue(gparam[YMAP].name, 1, &ybounds.min);
114 aysize = funvalue(gparam[YMAP].name, 1, &ybounds.max);
115 aysize -= aybegin;
116 } else {
117 aybegin = ybounds.min;
118 aysize = ybounds.max;
119 aysize -= aybegin;
120 }
121 }
122
123
124 makeaxis() /* draw the coordinate axis */
125 {
126 char stmp[64];
127
128 if (period > FTINY)
129 polaraxis();
130 else
131 cartaxis();
132 /* x axis label */
133 if (gparam[XLABEL].flags & DEFINED)
134 boxstring(XL_L,XL_D,XL_R,XL_U,gparam[XLABEL].v.s,'r',0,0);
135 /* x mapping */
136 if (gparam[XMAP].flags & DEFINED) {
137 mgtoa(stmp, &gparam[XMAP]);
138 boxstring(XM_L,XM_D,XM_R,XM_U,stmp,'r',0,0);
139 }
140 /* y axis label */
141 if (gparam[YLABEL].flags & DEFINED)
142 boxstring(YL_L,YL_D,YL_R,YL_U,gparam[YLABEL].v.s,'u',0,0);
143 /* y mapping */
144 if (gparam[YMAP].flags & DEFINED) {
145 mgtoa(stmp, &gparam[YMAP]);
146 boxstring(YM_L,YM_D,YM_R,YM_U,stmp,'u',0,0);
147 }
148 /* title */
149 if (gparam[TITLE].flags & DEFINED)
150 boxstring(TI_L,TI_D,TI_R,TI_U,gparam[TITLE].v.s,'r',2,0);
151 /* subtitle */
152 if (gparam[SUBTITLE].flags & DEFINED)
153 boxstring(ST_L,ST_D,ST_R,ST_U,gparam[SUBTITLE].v.s,'r',1,0);
154 /* legend */
155 if (gparam[LEGEND].flags & DEFINED)
156 mtext(LT_X, LT_Y, gparam[LEGEND].v.s, CPI, 0);
157 }
158
159
160 polaraxis() /* print polar coordinate axis */
161 {
162 int lw, tstyle, t0, t1;
163 double d, d1, ybeg, xstep;
164 char stmp[64], *fmt, *goodformat();
165 /* get tick style */
166 if (gparam[TSTYLE].flags & DEFINED)
167 tstyle = varvalue(gparam[TSTYLE].name) + 0.5;
168 else
169 tstyle = DEFTSTYLE;
170 /* start of numbering */
171 ybeg = ceil(ybounds.min/ybounds.step)*ybounds.step;
172 /* theta (x) numbering */
173 fmt = goodformat(xbounds.step);
174 for (d = 0.0; d < period-FTINY; d += xbounds.step) {
175 sprintf(stmp, fmt, d);
176 d1 = d*(2*PI)/period;
177 t0 = TN_X + TN_R*cos(d1) + .5;
178 if (t0 < TN_X)
179 t0 -= strlen(stmp)*CWID;
180 mtext(t0,(int)(TN_Y+TN_R*sin(d1)+.5),stmp,CPI,0);
181 }
182 /* radius (y) numbering */
183 fmt = goodformat(ybounds.step);
184 lw = PL_R+RN_S;
185 for (d = ybeg; d <= ybounds.max+FTINY; d += ybounds.step) {
186 t0 = rconv(d);
187 if (t0 >= lw+RN_S || t0 <= lw-RN_S) {
188 sprintf(stmp, fmt, d);
189 mtext(RN_X+t0-strlen(stmp)*(CWID/2),RN_Y,stmp,CPI,0);
190 lw = t0;
191 }
192 }
193 /* frame */
194 if (gparam[FTHICK].flags & DEFINED)
195 lw = varvalue(gparam[FTHICK].name) + 0.5;
196 else
197 lw = DEFFTHICK;
198 if (lw-- > 0) {
199 drawcircle(PL_X,PL_Y,PL_R,0,lw,0);
200 switch (tstyle) {
201 case 1: /* outside */
202 t0 = 0; t1 = TLEN; break;
203 case 2: /* inside */
204 t0 = TLEN; t1 = 0; break;
205 case 3: /* accross */
206 t0 = TLEN/2; t1 = TLEN/2; break;
207 default: /* none */
208 t0 = t1 = 0; break;
209 }
210 if (t0 + t1) {
211 for (d = 0.0; d < 2*PI-FTINY;
212 d += xbounds.step*(2*PI)/period) {
213 mline((int)(PL_X+(PL_R-t0)*cos(d)+.5),
214 (int)(PL_Y+(PL_R-t0)*sin(d)+.5),
215 0, lw, 0);
216 mdraw((int)(PL_X+(PL_R+t1)*cos(d)+.5),
217 (int)(PL_Y+(PL_R+t1)*sin(d)+.5));
218 }
219 }
220 }
221 /* origin */
222 if (gparam[OTHICK].flags & DEFINED)
223 lw = varvalue(gparam[OTHICK].name) + 0.5;
224 else
225 lw = DEFOTHICK;
226 if (lw-- > 0) {
227 mline(PL_X-PL_R,PL_Y,0,lw,0);
228 mdraw(PL_X+PL_R,PL_Y);
229 mline(PL_X,PL_Y-PL_R,0,lw,0);
230 mdraw(PL_X,PL_Y+PL_R);
231 if (tstyle > 0)
232 for (d = ybeg; d <= ybounds.max+FTINY;
233 d += ybounds.step) {
234 t0 = rconv(d);
235 mline(PL_X+t0,PL_Y-TLEN/2,0,lw,0);
236 mdraw(PL_X+t0,PL_Y+TLEN/2);
237 mline(PL_X-TLEN/2,PL_Y+t0,0,lw,0);
238 mdraw(PL_X+TLEN/2,PL_Y+t0);
239 mline(PL_X-t0,PL_Y-TLEN/2,0,lw,0);
240 mdraw(PL_X-t0,PL_Y+TLEN/2);
241 mline(PL_X-TLEN/2,PL_Y-t0,0,lw,0);
242 mdraw(PL_X+TLEN/2,PL_Y-t0);
243 }
244 }
245 /* grid */
246 if (gparam[GRID].flags & DEFINED)
247 lw = varvalue(gparam[GRID].name);
248 else
249 lw = DEFGRID;
250 if (lw-- > 0) {
251 for (d = 0.0; d < PI-FTINY; d += xbounds.step*(2*PI)/period) {
252 mline((int)(PL_X+PL_R*cos(d)+.5),
253 (int)(PL_Y+PL_R*sin(d)+.5),2,0,0);
254 mdraw((int)(PL_X-PL_R*cos(d)+.5),
255 (int)(PL_Y-PL_R*sin(d)+.5));
256 }
257 for (d = ybeg; d <= ybounds.max + FTINY; d += ybounds.step)
258 drawcircle(PL_X,PL_Y,rconv(d),2,0,0);
259 }
260 }
261
262
263 cartaxis() /* print Cartesian coordinate axis */
264 {
265 int lw, t0, t1, tstyle;
266 double d, xbeg, ybeg;
267 char stmp[64], *fmt, *goodformat();
268 register int i;
269 /* get tick style */
270 if (gparam[TSTYLE].flags & DEFINED)
271 tstyle = varvalue(gparam[TSTYLE].name) + 0.5;
272 else
273 tstyle = DEFTSTYLE;
274 /* start of numbering */
275 xbeg = ceil(xbounds.min/xbounds.step)*xbounds.step;
276 ybeg = ceil(ybounds.min/ybounds.step)*ybounds.step;
277
278 /* x numbering */
279 fmt = goodformat(xbounds.step);
280 lw = 2*AX_L-AX_R;
281 for (d = xbeg;
282 d <= xbounds.max + FTINY;
283 d += xbounds.step)
284 if ((i = xconv(d)) >= lw+XN_S || i <= lw-XN_S) {
285 sprintf(stmp, fmt, d);
286 mtext(i-strlen(stmp)*(CWID/2)+XN_X,XN_Y,stmp,CPI,0);
287 lw = i;
288 }
289 /* y numbering */
290 fmt = goodformat(ybounds.step);
291 lw = 2*AX_D-AX_U;
292 for (d = ybeg;
293 d <= ybounds.max + FTINY;
294 d += ybounds.step)
295 if ((i = yconv(d)) >= lw+YN_S || i <= lw-YN_S) {
296 sprintf(stmp, fmt, d);
297 mtext(YN_X-strlen(stmp)*CWID,i+YN_Y,stmp,CPI,0);
298 lw = i;
299 }
300 /* frame */
301 if (gparam[FTHICK].flags & DEFINED)
302 lw = varvalue(gparam[FTHICK].name) + 0.5;
303 else
304 lw = DEFFTHICK;
305 if (lw-- > 0) {
306 mline(AX_L,AX_D,0,lw,0);
307 mdraw(AX_R,AX_D);
308 mdraw(AX_R,AX_U);
309 mdraw(AX_L,AX_U);
310 mdraw(AX_L,AX_D);
311 switch (tstyle) {
312 case 1: /* outside */
313 t0 = 0; t1 = TLEN; break;
314 case 2: /* inside */
315 t0 = TLEN; t1 = 0; break;
316 case 3: /* accross */
317 t0 = TLEN/2; t1 = TLEN/2; break;
318 default: /* none */
319 t0 = t1 = 0; break;
320 }
321 if (t0 + t1) {
322 for (d = xbeg;
323 d <= xbounds.max + FTINY;
324 d += xbounds.step) {
325 i = xconv(d);
326 mline(i,AX_D+t0,0,lw,0);
327 mdraw(i,AX_D-t1);
328 mline(i,AX_U-t0,0,lw,0);
329 mdraw(i,AX_U+t1);
330 }
331 for (d = ybeg;
332 d <= ybounds.max + FTINY;
333 d += ybounds.step) {
334 i = yconv(d);
335 mline(AX_L+t0,i,0,lw,0);
336 mdraw(AX_L-t1,i);
337 mline(AX_R-t0,i,0,lw,0);
338 mdraw(AX_R+t1,i);
339 }
340 }
341 }
342 /* origin */
343 if (gparam[OTHICK].flags & DEFINED)
344 lw = varvalue(gparam[OTHICK].name) + 0.5;
345 else
346 lw = DEFOTHICK;
347 if (lw-- > 0) {
348 i = yconv(0.0);
349 if (i >= AX_D && i <= AX_U) {
350 mline(AX_L,i,0,lw,0);
351 mdraw(AX_R,i);
352 if (tstyle > 0)
353 for (d = xbeg; d <= xbounds.max+FTINY;
354 d += xbounds.step) {
355 mline(xconv(d),i+TLEN/2,0,lw,0);
356 mdraw(xconv(d),i-TLEN/2);
357 }
358 }
359 i = xconv(0.0);
360 if (i >= AX_L && i <= AX_R) {
361 mline(i,AX_D,0,lw,0);
362 mdraw(i,AX_U);
363 if (tstyle > 0)
364 for (d = ybeg; d <= ybounds.max+FTINY;
365 d += ybounds.step) {
366 mline(i+TLEN/2,yconv(d),0,lw,0);
367 mdraw(i-TLEN/2,yconv(d));
368 }
369 }
370 }
371 /* grid */
372 if (gparam[GRID].flags & DEFINED)
373 lw = varvalue(gparam[GRID].name);
374 else
375 lw = DEFGRID;
376 if (lw-- > 0) {
377 for (d = xbeg;
378 d <= xbounds.max + FTINY;
379 d += xbounds.step) {
380 i = xconv(d);
381 mline(i,AX_D,2,0,0);
382 mdraw(i,AX_U);
383 }
384 for (d = ybeg;
385 d <= ybounds.max + FTINY;
386 d += ybounds.step) {
387 i = yconv(d);
388 mline(AX_L,i,2,0,0);
389 mdraw(AX_R,i);
390 }
391 }
392 }
393
394
395 plotcurves() /* plot the curves */
396 {
397 int i, j, k, nextpoint();
398
399 for (i = 0; i < MAXCUR; i++) {
400 nplottable = nplotted = 0;
401 lastx = FHUGE;
402 if (mgcurve(i, nextpoint) > 0 &&
403 cparam[i][CLABEL].flags & DEFINED) {
404 j = (LE_U-LE_D)/MAXCUR;
405 k = LE_U - i*j;
406 mtext(LE_L+(LE_R-LE_L)/8,k+j/3,
407 cparam[i][CLABEL].v.s,CPI,0);
408 cmsymbol(i,LE_L,k);
409 if (cmline(i,LE_L,k) == 0)
410 mdraw(LE_R-(LE_R-LE_L)/4,k);
411 }
412 }
413 }
414
415
416 nextpoint(c, x, y) /* plot the next point for c */
417 register int c;
418 double x, y;
419 {
420 if (inbounds(x, y)) {
421
422 if (!(cparam[c][CNPOINTS].flags & DEFINED) ||
423 nplotted * npltbl[c] <= nplottable *
424 (int)varvalue(cparam[c][CNPOINTS].name) ) {
425 csymbol(c, x, y);
426 nplotted++;
427 }
428 nplottable++;
429 if (lastx != FHUGE)
430 climline(c, x, y, lastx, lasty);
431
432 } else if (inbounds(lastx, lasty)) {
433
434 climline(c, lastx, lasty, x, y);
435
436 }
437 lastx = x;
438 lasty = y;
439 }
440
441
442 stretchbounds(c, x, y) /* stretch our boundaries */
443 int c;
444 double x, y;
445 {
446 if (gparam[XMIN].flags & DEFINED &&
447 x < xbounds.min)
448 return;
449 if (gparam[XMAX].flags & DEFINED &&
450 x > xbounds.max)
451 return;
452 if (gparam[YMIN].flags & DEFINED &&
453 y < ybounds.min)
454 return;
455 if (gparam[YMAX].flags & DEFINED &&
456 y > ybounds.max)
457 return;
458
459 if (x < xbounds.min)
460 xbounds.min = x;
461 if (x > xbounds.max)
462 xbounds.max = x;
463 if (y < ybounds.min)
464 ybounds.min = y;
465 if (y > ybounds.max)
466 ybounds.max = y;
467
468 npltbl[c]++;
469 }
470
471
472 #define exp10(x) exp((x)*2.3025850929940456)
473
474 double
475 goodstep(interval) /* determine a good step for the interval */
476 double interval;
477 {
478 static int steps[] = {50, 20, 10, 5, 2, 1};
479 double fact, exp(), log10(), floor();
480 int i;
481
482 if (interval <= FTINY)
483 return(1.0);
484 fact = exp10(floor(log10(interval)))/10;
485 interval /= fact * MINDIVS;
486 for (i = 0; interval < steps[i]; i++)
487 ;
488 return(steps[i] * fact);
489 }
490
491 #undef exp10
492
493
494 int
495 xconv(x) /* convert x to meta coords */
496 double x;
497 {
498 if (gparam[XMAP].flags & DEFINED)
499 x = funvalue(gparam[XMAP].name, 1, &x);
500 x = (x - axbegin)/axsize;
501 return( AX_L + (int)(x*(AX_R-AX_L)) );
502 }
503
504
505 int
506 yconv(y) /* convert y to meta coords */
507 double y;
508 {
509 if (gparam[YMAP].flags & DEFINED)
510 y = funvalue(gparam[YMAP].name, 1, &y);
511 y = (y - aybegin)/aysize;
512 return( AX_D + (int)(y*(AX_U-AX_D)) );
513 }
514
515
516 pconv(xp, yp, t, r) /* convert theta and radius to meta coords */
517 int *xp, *yp;
518 double t, r;
519 {
520 t *= (2.*PI)/period;
521 r = rconv(r);
522 *xp = r*cos(t) + (PL_X+.5);
523 *yp = r*sin(t) + (PL_Y+.5);
524 }
525
526
527 int
528 rconv(r) /* convert radius to meta coords */
529 double r;
530 {
531 if (gparam[YMAP].flags & DEFINED)
532 r = funvalue(gparam[YMAP].name, 1, &r);
533
534 return((r - aybegin)*PL_R/aysize + .5);
535 }
536
537
538 boxstring(xmin, ymin, xmax, ymax, s, d, width, color) /* put string in box */
539 int xmin, ymin, xmax, ymax;
540 char *s;
541 int d, width, color;
542 {
543 register long size;
544
545 if (d == 'u' || d == 'd') { /* up or down */
546 size = strlen(s)*(xmax-xmin)/ASPECT;
547 size -= ymax-ymin;
548 size /= 2;
549 if (size < 0) { /* center */
550 ymin -= size;
551 ymax += size;
552 }
553 } else { /* left or right */
554 size = strlen(s)*(ymax-ymin)/ASPECT;
555 size -= xmax-xmin;
556 size /= 2;
557 if (size < 0) { /* center */
558 xmin -= size;
559 xmax += size;
560 }
561 }
562 mvstr(xmin, ymin, xmax, ymax, s, d, width, color); /* print */
563 }
564
565
566 char *
567 goodformat(d) /* return a suitable format string for d */
568 double d;
569 {
570 static char *f[5] = {"%.0f", "%.1f", "%.2f", "%.3f", "%.4f"};
571 double floor();
572 register int i;
573
574 if (d < 0.0)
575 d = -d;
576 if (d > 1e-4 && d < 1e6)
577 for (i = 0; i < 5; i++) {
578 if (d - floor(d+FTINY) <= FTINY)
579 return(f[i]);
580 d *= 10.0;
581 }
582 return("%.1e");
583 }
584
585
586 drawcircle(x, y, r, typ, wid, col) /* draw a circle */
587 int x, y, r;
588 int typ, wid, col;
589 {
590 double d;
591
592 if (r <= 0)
593 return;
594 mline(x+r, y, typ, wid, col);
595 for (d = 2*PI*PL_F; d <= 2*PI+FTINY; d += 2*PI*PL_F)
596 mdraw((int)(x+r*cos(d)+.5), (int)(y+r*sin(d)+.5));
597 }
598
599
600 climline(c, x, y, xout, yout) /* print line from/to out of bounds */
601 int c;
602 double x, y, xout, yout;
603 {
604 for ( ; ; )
605 if (xout < xbounds.min) {
606 yout = y + (yout - y)*(xbounds.min - x)/(xout - x);
607 xout = xbounds.min;
608 } else if (yout < ybounds.min) {
609 xout = x + (xout - x)*(ybounds.min - y)/(yout - y);
610 yout = ybounds.min;
611 } else if (xout > xbounds.max) {
612 yout = y + (yout - y)*(xbounds.max - x)/(xout - x);
613 xout = xbounds.max;
614 } else if (yout > ybounds.max) {
615 xout = x + (xout - x)*(ybounds.max - y)/(yout - y);
616 yout = ybounds.max;
617 } else {
618 cline(c, x, y, xout, yout);
619 break;
620 }
621 }
622
623
624 cline(c, u1, v1, u2, v2) /* print a curve line */
625 int c;
626 double u1, v1, u2, v2;
627 {
628 int x, y;
629 double ustep, vstep;
630
631 if (period > FTINY) { /* polar */
632 if (u1 > u2) {
633 ustep = u1; u1 = u2; u2 = ustep;
634 vstep = v1; v1 = v2; v2 = vstep;
635 }
636 pconv(&x, &y, u1, v1);
637 if (cmline(c, x, y) < 0)
638 return;
639 ustep = period*PL_F;
640 if (u2-u1 > ustep) {
641 vstep = ustep*(v2-v1)/(u2-u1);
642 while ((u1 += ustep) < u2) {
643 v1 += vstep;
644 pconv(&x, &y, u1, v1);
645 mdraw(x, y);
646 }
647 }
648 pconv(&x, &y, u2, v2);
649 mdraw(x, y);
650 } else if (cmline(c, xconv(u1), yconv(v1)) == 0)
651 mdraw(xconv(u2), yconv(v2));
652 }
653
654
655 int
656 cmline(c, x, y) /* start curve line in meta coords */
657 int c;
658 int x, y;
659 {
660 int lw, lt, col;
661 register VARIABLE *cv;
662
663 cv = cparam[c];
664 if (cv[CLINTYPE].flags & DEFINED)
665 lt = varvalue(cv[CLINTYPE].name);
666 else
667 lt = DEFLINTYPE;
668 if (lt-- <= 0)
669 return(-1);
670 if (cv[CTHICK].flags & DEFINED)
671 lw = varvalue(cv[CTHICK].name);
672 else
673 lw = DEFTHICK;
674 if (lw-- <= 0)
675 return(-1);
676 if (cv[CCOLOR].flags & DEFINED)
677 col = varvalue(cv[CCOLOR].name);
678 else
679 col = DEFCOLOR;
680 if (col-- <= 0)
681 return(-1);
682 mline(x, y, lt, lw, col);
683 return(0);
684 }
685
686
687 csymbol(c, u, v) /* plot curve symbol */
688 int c;
689 double u, v;
690 {
691 int x, y;
692
693 if (period > FTINY) {
694 pconv(&x, &y, u, v);
695 cmsymbol(c, x, y);
696 } else
697 cmsymbol(c, xconv(u), yconv(v));
698 }
699
700
701 cmsymbol(c, x, y) /* print curve symbol in meta coords */
702 int c;
703 int x, y;
704 {
705 int col, ss;
706 register VARIABLE *cv;
707
708 cv = cparam[c];
709 if (!(cv[CSYMTYPE].flags & DEFINED))
710 return;
711 if (cv[CSYMSIZE].flags & DEFINED)
712 ss = varvalue(cv[CSYMSIZE].name);
713 else
714 ss = DEFSYMSIZE;
715 if (ss <= 0)
716 return;
717 if (cv[CCOLOR].flags & DEFINED)
718 col = varvalue(cv[CCOLOR].name);
719 else
720 col = DEFCOLOR;
721 if (col-- <= 0)
722 return;
723 msegment(x-ss,y-ss,x+ss,y+ss,
724 cv[CSYMTYPE].v.s,'r',0,col);
725 }
726
727
728 inbounds(x, y) /* determine if x and y are within gbounds */
729 double x, y;
730 {
731 if (x < xbounds.min || x > xbounds.max)
732 return(0);
733 if (y < ybounds.min || y > ybounds.max)
734 return(0);
735 return(1);
736 }