ref: 5c1feb0ef0b795e5de71e956f9ccddcd5c4b7f21
dir: /sys/src/cmd/scat/plot.c/
#include <u.h> #include <libc.h> #include <bio.h> #include <draw.h> #include <event.h> #include <ctype.h> #include "map.h" #undef RAD #undef TWOPI #include "sky.h" /* convert to milliarcsec */ static long c = MILLIARCSEC; /* 1 degree */ static long m5 = 1250*60*60; /* 5 minutes of ra */ DAngle ramin; DAngle ramax; DAngle decmin; DAngle decmax; int folded; Image *grey; Image *alphagrey; Image *green; Image *lightblue; Image *lightgrey; Image *ocstipple; Image *suncolor; Image *mooncolor; Image *shadowcolor; Image *mercurycolor; Image *venuscolor; Image *marscolor; Image *jupitercolor; Image *saturncolor; Image *uranuscolor; Image *neptunecolor; Image *plutocolor; Image *cometcolor; Planetrec *planet; long mapx0, mapy0; long mapra, mapdec; double mylat, mylon, mysid; double mapscale; double maps; int (*projection)(struct place*, double*, double*); char *fontname = "/lib/font/bit/lucida/unicode.6.font"; /* types Coord and Loc correspond to types in map(3) thus: Coord == struct coord; Loc == struct place, except longitudes are measured positive east for Loc and west for struct place */ typedef struct Xyz Xyz; typedef struct coord Coord; typedef struct Loc Loc; struct Xyz{ double x,y,z; }; struct Loc{ Coord nlat, elon; }; Xyz north = { 0, 0, 1 }; int plotopen(void) { if(display != nil) return 1; display = initdisplay(nil, nil, drawerror); if(display == nil){ fprint(2, "initdisplay failed: %r\n"); return -1; } grey = allocimage(display, Rect(0, 0, 1, 1), CMAP8, 1, 0x777777FF); lightgrey = allocimage(display, Rect(0, 0, 1, 1), CMAP8, 1, 0xAAAAAAFF); alphagrey = allocimage(display, Rect(0, 0, 2, 2), RGBA32, 1, 0x77777777); green = allocimage(display, Rect(0, 0, 1, 1), CMAP8, 1, 0x00AA00FF); lightblue = allocimage(display, Rect(0, 0, 1, 1), CMAP8, 1, 0x009EEEFF); ocstipple = allocimage(display, Rect(0, 0, 2, 2), CMAP8, 1, 0xAAAAAAFF); draw(ocstipple, Rect(0, 0, 1, 1), display->black, nil, ZP); draw(ocstipple, Rect(1, 1, 2, 2), display->black, nil, ZP); suncolor = allocimage(display, Rect(0, 0, 1, 1), RGBA32, 1, 0xFFFF77FF); mooncolor = allocimage(display, Rect(0, 0, 1, 1), RGBA32, 1, 0xAAAAAAFF); shadowcolor = allocimage(display, Rect(0, 0, 1, 1), RGBA32, 1, 0x00000055); mercurycolor = allocimage(display, Rect(0, 0, 1, 1), RGBA32, 1, 0xFFAAAAFF); venuscolor = allocimage(display, Rect(0, 0, 1, 1), RGBA32, 1, 0xAAAAFFFF); marscolor = allocimage(display, Rect(0, 0, 1, 1), RGBA32, 1, 0xFF5555FF); jupitercolor = allocimage(display, Rect(0, 0, 1, 1), RGBA32, 1, 0xFFFFAAFF); saturncolor = allocimage(display, Rect(0, 0, 1, 1), RGBA32, 1, 0xAAFFAAFF); uranuscolor = allocimage(display, Rect(0, 0, 1, 1), RGBA32, 1, 0x77DDDDFF); neptunecolor = allocimage(display, Rect(0, 0, 1, 1), RGBA32, 1, 0x77FF77FF); plutocolor = allocimage(display, Rect(0, 0, 1, 1), RGBA32, 1, 0x7777FFFF); cometcolor = allocimage(display, Rect(0, 0, 1, 1), RGBA32, 1, 0xAAAAFFFF); font = openfont(display, fontname); if(font == nil) fprint(2, "warning: no font %s: %r\n", fontname); return 1; } /* * Function heavens() for setting up observer-eye-view * sky charts, plus subsidiary functions. * Written by Doug McIlroy. */ /* heavens(nlato, wlono, nlatc, wlonc) sets up a map(3)-style coordinate change (by calling orient()) and returns a projection function heavens for calculating a star map centered on nlatc,wlonc and rotated so it will appear upright as seen by a ground observer at nlato,wlono. all coordinates (north latitude and west longitude) are in degrees. */ Coord mkcoord(double degrees) { Coord c; c.l = degrees*PI/180; c.s = sin(c.l); c.c = cos(c.l); return c; } Xyz ptov(struct place p) { Xyz v; v.z = p.nlat.s; v.x = p.nlat.c * p.wlon.c; v.y = -p.nlat.c * p.wlon.s; return v; } double dot(Xyz a, Xyz b) { return a.x*b.x + a.y*b.y + a.z*b.z; } Xyz cross(Xyz a, Xyz b) { Xyz v; v.x = a.y*b.z - a.z*b.y; v.y = a.z*b.x - a.x*b.z; v.z = a.x*b.y - a.y*b.x; return v; } double len(Xyz a) { return sqrt(dot(a, a)); } /* An azimuth vector from a to b is a tangent to the sphere at a pointing along the (shorter) great-circle direction to b. It lies in the plane of the vectors a and b, is perpendicular to a, and has a positive compoent along b, provided a and b span a 2-space. Otherwise it is null. (aXb)Xa, where X denotes cross product, is such a vector. */ Xyz azvec(Xyz a, Xyz b) { return cross(cross(a,b), a); } /* Find the azimuth of point b as seen from point a, given that a is distinct from either pole and from b */ double azimuth(Xyz a, Xyz b) { Xyz aton = azvec(a,north); Xyz atob = azvec(a,b); double lenaton = len(aton); double lenatob = len(atob); double az = acos(dot(aton,atob)/(lenaton*lenatob)); if(dot(b,cross(north,a)) < 0) az = -az; return az; } /* Find the rotation (3rd argument of orient() in the map projection package) for the map described below. The return is radians; it must be converted to degrees for orient(). */ double rot(struct place center, struct place zenith) { Xyz cen = ptov(center); Xyz zen = ptov(zenith); if(cen.z > 1-FUZZ) /* center at N pole */ return PI + zenith.wlon.l; if(cen.z < FUZZ-1) /* at S pole */ return -zenith.wlon.l; if(fabs(dot(cen,zen)) > 1-FUZZ) /* at zenith */ return 0; return azimuth(cen, zen); } int (* heavens(double zlatdeg, double zlondeg, double clatdeg, double clondeg))(Loc*, double*, double*) { struct place center; struct place zenith; center.nlat = mkcoord(clatdeg); center.wlon = mkcoord(clondeg); zenith.nlat = mkcoord(zlatdeg); zenith.wlon = mkcoord(zlondeg); projection = stereographic(); orient(clatdeg, clondeg, rot(center, zenith)*180/PI); return projection; } int maptoxy(long ra, long dec, double *x, double *y) { double lat, lon; struct place pl; lat = angle(dec); lon = angle(ra); pl.nlat.l = lat; pl.nlat.s = sin(lat); pl.nlat.c = cos(lat); pl.wlon.l = lon; pl.wlon.s = sin(lon); pl.wlon.c = cos(lon); normalize(&pl); return projection(&pl, x, y); } /* end of 'heavens' section */ int setmap(long ramin, long ramax, long decmin, long decmax, Rectangle r, int zenithup) { int c; double minx, maxx, miny, maxy; c = 1000*60*60; mapra = ramax/2+ramin/2; mapdec = decmax/2+decmin/2; if(zenithup) projection = heavens(mylat, mysid, (double)mapdec/c, (double)mapra/c); else{ orient((double)mapdec/c, (double)mapra/c, 0.); projection = stereographic(); } mapx0 = (r.max.x+r.min.x)/2; mapy0 = (r.max.y+r.min.y)/2; maps = ((double)Dy(r))/(double)(decmax-decmin); if(maptoxy(ramin, decmin, &minx, &miny) < 0) return -1; if(maptoxy(ramax, decmax, &maxx, &maxy) < 0) return -1; /* * It's tricky to get the scale right. This noble attempt scales * to fit the lengths of the sides of the rectangle. */ mapscale = Dx(r)/(minx-maxx); if(mapscale > Dy(r)/(maxy-miny)) mapscale = Dy(r)/(maxy-miny); /* * near the pole It's not a rectangle, though, so this scales * to fit the corners of the trapezoid (a triangle at the pole). */ mapscale *= (cos(angle(mapdec))+1.)/2; if(maxy < miny){ /* upside down, between zenith and pole */ fprint(2, "reverse plot\n"); mapscale = -mapscale; } return 1; } Point map(long ra, long dec) { double x, y; Point p; if(maptoxy(ra, dec, &x, &y) > 0){ p.x = mapscale*x + mapx0; p.y = mapscale*-y + mapy0; }else{ p.x = -100; p.y = -100; } return p; } int dsize(int mag) /* mag is 10*magnitude; return disc size */ { double d; mag += 25; /* make mags all positive; sirius is -1.6m */ d = (130-mag)/10; /* if plate scale is huge, adjust */ if(maps < 100.0/MILLIARCSEC) d *= .71; if(maps < 50.0/MILLIARCSEC) d *= .71; return d; } void drawname(Image *scr, Image *col, char *s, int ra, int dec) { Point p; if(font == nil) return; p = addpt(map(ra, dec), Pt(4, -1)); /* font has huge ascent */ string(scr, p, col, ZP, font, s); } int npixels(DAngle diam) { Point p0, p1; diam = DEG(angle(diam)*MILLIARCSEC); /* diam in milliarcsec */ diam /= 2; /* radius */ /* convert to plate scale */ /* BUG: need +100 because we sometimes crash in library if we plot the exact center */ p0 = map(mapra+100, mapdec); p1 = map(mapra+100+diam, mapdec); return hypot(p0.x-p1.x, p0.y-p1.y); } void drawdisc(Image *scr, DAngle semidiam, int ring, Image *color, Point pt, char *s) { int d; d = npixels(semidiam*2); if(d < 5) d = 5; fillellipse(scr, pt, d, d, color, ZP); if(ring == 1) ellipse(scr, pt, 5*d/2, d/2, 0, color, ZP); if(ring == 2) ellipse(scr, pt, d, d, 0, grey, ZP); if(s){ d = stringwidth(font, s); pt.x -= d/2; pt.y -= font->height/2 + 1; string(scr, pt, display->black, ZP, font, s); } } void drawplanet(Image *scr, Planetrec *p, Point pt) { if(strcmp(p->name, "sun") == 0){ drawdisc(scr, p->semidiam, 0, suncolor, pt, nil); return; } if(strcmp(p->name, "moon") == 0){ drawdisc(scr, p->semidiam, 0, mooncolor, pt, nil); return; } if(strcmp(p->name, "shadow") == 0){ drawdisc(scr, p->semidiam, 2, shadowcolor, pt, nil); return; } if(strcmp(p->name, "mercury") == 0){ drawdisc(scr, p->semidiam, 0, mercurycolor, pt, "m"); return; } if(strcmp(p->name, "venus") == 0){ drawdisc(scr, p->semidiam, 0, venuscolor, pt, "v"); return; } if(strcmp(p->name, "mars") == 0){ drawdisc(scr, p->semidiam, 0, marscolor, pt, "M"); return; } if(strcmp(p->name, "jupiter") == 0){ drawdisc(scr, p->semidiam, 0, jupitercolor, pt, "J"); return; } if(strcmp(p->name, "saturn") == 0){ drawdisc(scr, p->semidiam, 1, saturncolor, pt, "S"); return; } if(strcmp(p->name, "uranus") == 0){ drawdisc(scr, p->semidiam, 0, uranuscolor, pt, "U"); return; } if(strcmp(p->name, "neptune") == 0){ drawdisc(scr, p->semidiam, 0, neptunecolor, pt, "N"); return; } if(strcmp(p->name, "pluto") == 0){ drawdisc(scr, p->semidiam, 0, plutocolor, pt, "P"); return; } if(strcmp(p->name, "comet") == 0){ drawdisc(scr, p->semidiam, 0, cometcolor, pt, "C"); return; } pt.x -= stringwidth(font, p->name)/2; pt.y -= font->height/2; string(scr, pt, grey, ZP, font, p->name); } void tolast(char *name) { int i, nlast; Record *r, rr; /* stop early to simplify inner loop adjustment */ nlast = 0; for(i=0,r=rec; i<nrec-nlast; i++,r++) if(r->type == Planet) if(name==nil || strcmp(r->planet.name, name)==0){ rr = *r; memmove(rec+i, rec+i+1, (nrec-i-1)*sizeof(Record)); rec[nrec-1] = rr; --i; --r; nlast++; } } int bbox(long extrara, long extradec, int quantize) { int i; Record *r; int ra, dec; int rah, ram, d1, d2; double r0; ramin = 0x7FFFFFFF; ramax = -0x7FFFFFFF; decmin = 0x7FFFFFFF; decmax = -0x7FFFFFFF; for(i=0,r=rec; i<nrec; i++,r++){ if(r->type == Patch){ radec(r->index, &rah, &ram, &dec); ra = 15*rah+ram/4; r0 = c/cos(dec*PI/180); ra *= c; dec *= c; if(dec == 0) d1 = c, d2 = c; else if(dec < 0) d1 = c, d2 = 0; else d1 = 0, d2 = c; }else if(r->type==SAO || r->type==NGC || r->type==Planet || r->type==Abell){ ra = r->ngc.ra; dec = r->ngc.dec; d1 = 0, d2 = 0, r0 = 0; }else continue; if(dec+d2+extradec > decmax) decmax = dec+d2+extradec; if(dec-d1-extradec < decmin) decmin = dec-d1-extradec; if(folded){ ra -= 180*c; if(ra < 0) ra += 360*c; } if(ra+r0+extrara > ramax) ramax = ra+r0+extrara; if(ra-extrara < ramin) ramin = ra-extrara; } if(decmax > 90*c) decmax = 90*c; if(decmin < -90*c) decmin = -90*c; if(ramin < 0) ramin += 360*c; if(ramax >= 360*c) ramax -= 360*c; if(quantize){ /* quantize to degree boundaries */ ramin -= ramin%m5; if(ramax%m5 != 0) ramax += m5-(ramax%m5); if(decmin > 0) decmin -= decmin%c; else decmin -= c - (-decmin)%c; if(decmax > 0){ if(decmax%c != 0) decmax += c-(decmax%c); }else if(decmax < 0){ if(decmax%c != 0) decmax += ((-decmax)%c); } } if(folded){ if(ramax-ramin > 270*c){ fprint(2, "ra range too wide %ld°\n", (ramax-ramin)/c); return -1; } }else if(ramax-ramin > 270*c){ folded = 1; return bbox(0, 0, quantize); } return 1; } int inbbox(DAngle ra, DAngle dec) { int min; if(dec < decmin) return 0; if(dec > decmax) return 0; min = ramin; if(ramin > ramax){ /* straddling 0h0m */ min -= 360*c; if(ra > 180*c) ra -= 360*c; } if(ra < min) return 0; if(ra > ramax) return 0; return 1; } int gridra(long mapdec) { mapdec = abs(mapdec)+c/2; mapdec /= c; if(mapdec < 60) return m5; if(mapdec < 80) return 2*m5; if(mapdec < 85) return 4*m5; return 8*m5; } #define GREY (nogrey? display->white : grey) void plot(char *flags) { int i, j, k; char *t; long x, y; int ra, dec; int m; Point p, pts[10]; Record *r; Rectangle rect, r1; int dx, dy, nogrid, textlevel, nogrey, zenithup; Image *scr; char *name, buf[32]; double v; if(plotopen() < 0) return; nogrid = 0; nogrey = 0; textlevel = 1; dx = 512; dy = 512; zenithup = 0; for(;;){ if(t = alpha(flags, "nogrid")){ nogrid = 1; flags = t; continue; } if((t = alpha(flags, "zenith")) || (t = alpha(flags, "zenithup")) ){ zenithup = 1; flags = t; continue; } if((t = alpha(flags, "notext")) || (t = alpha(flags, "nolabel")) ){ textlevel = 0; flags = t; continue; } if((t = alpha(flags, "alltext")) || (t = alpha(flags, "alllabel")) ){ textlevel = 2; flags = t; continue; } if(t = alpha(flags, "dx")){ dx = strtol(t, &t, 0); if(dx < 100){ fprint(2, "dx %d too small (min 100) in plot\n", dx); return; } flags = skipbl(t); continue; } if(t = alpha(flags, "dy")){ dy = strtol(t, &t, 0); if(dy < 100){ fprint(2, "dy %d too small (min 100) in plot\n", dy); return; } flags = skipbl(t); continue; } if((t = alpha(flags, "nogrey")) || (t = alpha(flags, "nogray"))){ nogrey = 1; flags = skipbl(t); continue; } if(*flags){ fprint(2, "syntax error in plot\n"); return; } break; } flatten(); folded = 0; if(bbox(0, 0, 1) < 0) return; if(ramax-ramin<100 || decmax-decmin<100){ fprint(2, "plot too small\n"); return; } scr = allocimage(display, Rect(0, 0, dx, dy), RGB24, 0, DBlack); if(scr == nil){ fprint(2, "can't allocate image: %r\n"); return; } rect = scr->r; rect.min.x += 16; rect = insetrect(rect, 40); if(setmap(ramin, ramax, decmin, decmax, rect, zenithup) < 0){ fprint(2, "can't set up map coordinates\n"); return; } if(!nogrid){ for(x=ramin; ; ){ for(j=0; j<nelem(pts); j++){ /* use double to avoid overflow */ v = (double)j / (double)(nelem(pts)-1); v = decmin + v*(decmax-decmin); pts[j] = map(x, v); } bezspline(scr, pts, nelem(pts), Endsquare, Endsquare, 0, GREY, ZP); ra = x; if(folded){ ra -= 180*c; if(ra < 0) ra += 360*c; } p = pts[0]; p.x -= stringwidth(font, hm5(angle(ra)))/2; string(scr, p, GREY, ZP, font, hm5(angle(ra))); p = pts[nelem(pts)-1]; p.x -= stringwidth(font, hm5(angle(ra)))/2; p.y -= font->height; string(scr, p, GREY, ZP, font, hm5(angle(ra))); if(x == ramax) break; x += gridra(mapdec); if(x > ramax) x = ramax; } for(y=decmin; y<=decmax; y+=c){ for(j=0; j<nelem(pts); j++){ /* use double to avoid overflow */ v = (double)j / (double)(nelem(pts)-1); v = ramin + v*(ramax-ramin); pts[j] = map(v, y); } bezspline(scr, pts, nelem(pts), Endsquare, Endsquare, 0, GREY, ZP); p = pts[0]; p.x += 3; p.y -= font->height/2; string(scr, p, GREY, ZP, font, deg(angle(y))); p = pts[nelem(pts)-1]; p.x -= 3+stringwidth(font, deg(angle(y))); p.y -= font->height/2; string(scr, p, GREY, ZP, font, deg(angle(y))); } } /* reorder to get planets in front of stars */ tolast(nil); tolast("moon"); /* moon is in front of everything... */ tolast("shadow"); /* ... except the shadow */ for(i=0,r=rec; i<nrec; i++,r++){ dec = r->ngc.dec; ra = r->ngc.ra; if(folded){ ra -= 180*c; if(ra < 0) ra += 360*c; } if(textlevel){ name = nameof(r); if(name==nil && textlevel>1 && r->type==SAO){ snprint(buf, sizeof buf, "SAO%ld", r->index); name = buf; } if(name) drawname(scr, nogrey? display->white : alphagrey, name, ra, dec); } if(r->type == Planet){ drawplanet(scr, &r->planet, map(ra, dec)); continue; } if(r->type == SAO){ m = r->sao.mag; if(m == UNKNOWNMAG) m = r->sao.mpg; if(m == UNKNOWNMAG) continue; m = dsize(m); if(m < 3) fillellipse(scr, map(ra, dec), m, m, nogrey? display->white : lightgrey, ZP); else{ ellipse(scr, map(ra, dec), m+1, m+1, 0, display->black, ZP); fillellipse(scr, map(ra, dec), m, m, display->white, ZP); } continue; } if(r->type == Abell){ ellipse(scr, addpt(map(ra, dec), Pt(-3, 2)), 2, 1, 0, lightblue, ZP); ellipse(scr, addpt(map(ra, dec), Pt(3, 2)), 2, 1, 0, lightblue, ZP); ellipse(scr, addpt(map(ra, dec), Pt(0, -2)), 1, 2, 0, lightblue, ZP); continue; } switch(r->ngc.type){ case Galaxy: j = npixels(r->ngc.diam); if(j < 4) j = 4; if(j > 10) k = j/3; else k = j/2; ellipse(scr, map(ra, dec), j, k, 0, lightblue, ZP); break; case PlanetaryN: p = map(ra, dec); j = npixels(r->ngc.diam); if(j < 3) j = 3; ellipse(scr, p, j, j, 0, green, ZP); line(scr, Pt(p.x, p.y+j+1), Pt(p.x, p.y+j+4), Endsquare, Endsquare, 0, green, ZP); line(scr, Pt(p.x, p.y-(j+1)), Pt(p.x, p.y-(j+4)), Endsquare, Endsquare, 0, green, ZP); line(scr, Pt(p.x+j+1, p.y), Pt(p.x+j+4, p.y), Endsquare, Endsquare, 0, green, ZP); line(scr, Pt(p.x-(j+1), p.y), Pt(p.x-(j+4), p.y), Endsquare, Endsquare, 0, green, ZP); break; case DiffuseN: case NebularCl: p = map(ra, dec); j = npixels(r->ngc.diam); if(j < 4) j = 4; r1.min = Pt(p.x-j, p.y-j); r1.max = Pt(p.x+j, p.y+j); if(r->ngc.type != DiffuseN) draw(scr, r1, ocstipple, ocstipple, ZP); line(scr, Pt(p.x-j, p.y-j), Pt(p.x+j, p.y-j), Endsquare, Endsquare, 0, green, ZP); line(scr, Pt(p.x-j, p.y+j), Pt(p.x+j, p.y+j), Endsquare, Endsquare, 0, green, ZP); line(scr, Pt(p.x-j, p.y-j), Pt(p.x-j, p.y+j), Endsquare, Endsquare, 0, green, ZP); line(scr, Pt(p.x+j, p.y-j), Pt(p.x+j, p.y+j), Endsquare, Endsquare, 0, green, ZP); break; case OpenCl: p = map(ra, dec); j = npixels(r->ngc.diam); if(j < 4) j = 4; fillellipse(scr, p, j, j, ocstipple, ZP); break; case GlobularCl: j = npixels(r->ngc.diam); if(j < 4) j = 4; p = map(ra, dec); ellipse(scr, p, j, j, 0, lightgrey, ZP); line(scr, Pt(p.x-(j-1), p.y), Pt(p.x+j, p.y), Endsquare, Endsquare, 0, lightgrey, ZP); line(scr, Pt(p.x, p.y-(j-1)), Pt(p.x, p.y+j), Endsquare, Endsquare, 0, lightgrey, ZP); break; } } flushimage(display, 1); displayimage(scr); } int runcommand(char *command, int p[2]) { switch(rfork(RFPROC|RFFDG|RFNOWAIT)){ case -1: return -1; default: break; case 0: dup(p[1], 1); close(p[0]); close(p[1]); execl("/bin/rc", "rc", "-c", command, nil); fprint(2, "can't exec %s: %r", command); exits(nil); } return 1; } void parseplanet(char *line, Planetrec *p) { char *fld[6]; int i, nfld; char *s; if(line[0] == '\0') return; line[10] = '\0'; /* terminate name */ s = strrchr(line, ' '); if(s == nil) s = line; else s++; strcpy(p->name, s); for(i=0; s[i]!='\0'; i++) p->name[i] = tolower(s[i]); p->name[i] = '\0'; nfld = getfields(line+11, fld, nelem(fld), 1, " "); p->ra = dangle(getra(fld[0])); p->dec = dangle(getra(fld[1])); p->az = atof(fld[2])*MILLIARCSEC; p->alt = atof(fld[3])*MILLIARCSEC; p->semidiam = atof(fld[4])*1000; if(nfld > 5) p->phase = atof(fld[5]); else p->phase = 0; } void astro(char *flags, int initial) { int p[2]; int i, n, np; char cmd[256], buf[4096], *lines[20], *fld[10]; snprint(cmd, sizeof cmd, "/bin/astro -p %s", flags); if(pipe(p) < 0){ fprint(2, "can't pipe: %r\n"); return; } if(runcommand(cmd, p) < 0){ close(p[0]); close(p[1]); fprint(2, "can't run astro: %r"); return; } close(p[1]); n = readn(p[0], buf, sizeof buf-1); if(n <= 0){ fprint(2, "no data from astro\n"); return; } if(!initial) Bwrite(&bout, buf, n); buf[n] = '\0'; np = getfields(buf, lines, nelem(lines), 0, "\n"); if(np <= 1){ fprint(2, "astro: not enough output\n"); return; } Bprint(&bout, "%s\n", lines[0]); Bflush(&bout); /* get latitude and longitude */ if(getfields(lines[0], fld, nelem(fld), 1, " ") < 8) fprint(2, "astro: can't read longitude: too few fields\n"); else{ mysid = getra(fld[5])*180./PI; mylat = getra(fld[6])*180./PI; mylon = getra(fld[7])*180./PI; } /* * Each time we run astro, we generate a new planet list * so multiple appearances of a planet may exist as we plot * its motion over time. */ planet = malloc(NPlanet*sizeof planet[0]); if(planet == nil){ fprint(2, "astro: malloc failed: %r\n"); exits("malloc"); } memset(planet, 0, NPlanet*sizeof planet[0]); for(i=1; i<np; i++) parseplanet(lines[i], &planet[i-1]); }