int plotstuff_output(plot_args_t* pargs) { switch (pargs->outformat) { case PLOTSTUFF_FORMAT_PDF: cairo_surface_flush(pargs->target); cairo_surface_finish(pargs->target); cairoutils_surface_status_errors(pargs->target); cairoutils_cairo_status_errors(pargs->cairo); if (pargs->outfn) { if (fclose(pargs->fout)) { SYSERROR("Failed to close output file \"%s\"", pargs->outfn); return -1; } } break; case PLOTSTUFF_FORMAT_JPG: case PLOTSTUFF_FORMAT_PPM: case PLOTSTUFF_FORMAT_PNG: case PLOTSTUFF_FORMAT_MEMIMG: { int res; unsigned char* img = cairo_image_surface_get_data(pargs->target); // Convert image for output... cairoutils_argb32_to_rgba(img, pargs->W, pargs->H); if (pargs->outformat == PLOTSTUFF_FORMAT_MEMIMG) { pargs->outimage = img; res = 0; img = NULL; } else if (pargs->outformat == PLOTSTUFF_FORMAT_JPG) { res = cairoutils_write_jpeg(pargs->outfn, img, pargs->W, pargs->H); } else if (pargs->outformat == PLOTSTUFF_FORMAT_PPM) { res = cairoutils_write_ppm(pargs->outfn, img, pargs->W, pargs->H); } else if (pargs->outformat == PLOTSTUFF_FORMAT_PNG) { res = cairoutils_write_png(pargs->outfn, img, pargs->W, pargs->H); } else { res=-1; // for gcc assert(0); } if (res) ERROR("Failed to write output image"); if (img) // Convert image back... cairoutils_rgba_to_argb32(img, pargs->W, pargs->H); return res; } break; default: ERROR("Unknown output format."); return -1; } return 0; }
int main(int argc, char** args) { int c; char* wcsfn = NULL; char* outfn = NULL; char* infn = NULL; sip_t sip; double scale = 1.0; anbool pngformat = TRUE; char* hdpath = NULL; anbool HD = FALSE; cairos_t thecairos; cairos_t* cairos = &thecairos; cairo_surface_t* target = NULL; cairo_t* cairot = NULL; cairo_surface_t* surfbg = NULL; cairo_t* cairobg = NULL; cairo_surface_t* surfshapes = NULL; cairo_t* cairoshapes = NULL; cairo_surface_t* surfshapesmask = NULL; cairo_t* cairoshapesmask = NULL; cairo_surface_t* surffg = NULL; cairo_t* cairo = NULL; double lw = 2.0; // circle linewidth. double cw = 2.0; double ngc_fraction = 0.02; // NGC linewidth double nw = 2.0; // leave a gap short of connecting the points. double endgap = 5.0; // circle radius. double crad = endgap; double fontsize = 14.0; double label_offset = 15.0; int W = 0, H = 0; unsigned char* img = NULL; anbool NGC = FALSE, constell = FALSE; anbool bright = FALSE; anbool common_only = FALSE; anbool print_common_only = FALSE; int Nbright = 0; double ra, dec, px, py; int i, N; anbool justlist = FALSE; anbool only_messier = FALSE; anbool grid = FALSE; double gridspacing = 0.0; double gridcolor[3] = { 0.2, 0.2, 0.2 }; int loglvl = LOG_MSG; char halign = 'L'; char valign = 'C'; sl* json = NULL; anbool whitetext = FALSE; while ((c = getopt(argc, args, OPTIONS)) != -1) { switch (c) { case 'V': valign = optarg[0]; break; case 'O': halign = optarg[0]; break; case 'F': ngc_fraction = atof(optarg); break; case 'h': print_help(args[0]); exit(0); case 'J': json = sl_new(4); break; case 'G': gridspacing = atof(optarg); break; case 'g': { char *tail = NULL; gridcolor[0] = strtod(optarg,&tail); if (*tail) { tail++; gridcolor[1] = strtod(tail,&tail); } if (*tail) { tail++; gridcolor[2] = strtod(tail,&tail); } } break; case 'D': HD = TRUE; break; case 'd': hdpath = optarg; break; case 'M': only_messier = TRUE; break; case 'n': nw = atof(optarg); break; case 'f': fontsize = atof(optarg); break; case 'L': justlist = TRUE; outfn = NULL; break; case 'x': whitetext = TRUE; break; case 'v': loglvl++; break; break; case 'j': print_common_only = TRUE; break; case 'c': common_only = TRUE; break; case 'b': Nbright = atoi(optarg); break; case 'B': bright = TRUE; break; case 'N': NGC = TRUE; break; case 'C': constell = TRUE; break; case 'p': pngformat = FALSE; break; case 's': scale = atof(optarg); break; case 'o': outfn = optarg; break; case 'i': infn = optarg; break; case 'w': wcsfn = optarg; break; case 'W': W = atoi(optarg); break; case 'H': H = atoi(optarg); break; } } log_init(loglvl); log_to(stderr); fits_use_error_system(); if (optind != argc) { print_help(args[0]); exit(-1); } if (!(outfn || justlist) || !wcsfn) { logerr("Need (-o or -L) and -w args.\n"); print_help(args[0]); exit(-1); } // read WCS. logverb("Trying to parse SIP/TAN header from %s...\n", wcsfn); if (!file_exists(wcsfn)) { ERROR("No such file: \"%s\"", wcsfn); exit(-1); } if (sip_read_header_file(wcsfn, &sip)) { logverb("Got SIP header.\n"); } else { ERROR("Failed to parse SIP/TAN header from %s", wcsfn); exit(-1); } if (!(NGC || constell || bright || HD || grid)) { logerr("Neither constellations, bright stars, HD nor NGC/IC overlays selected!\n"); print_help(args[0]); exit(-1); } if (gridspacing > 0.0) grid = TRUE; // adjust for scaling... lw /= scale; cw /= scale; nw /= scale; crad /= scale; endgap /= scale; fontsize /= scale; label_offset /= scale; if (!W || !H) { W = sip.wcstan.imagew; H = sip.wcstan.imageh; } if (!(infn || (W && H))) { logerr("Image width/height unspecified, and no input image given.\n"); exit(-1); } if (infn) { cairoutils_fake_ppm_init(); img = cairoutils_read_ppm(infn, &W, &H); if (!img) { ERROR("Failed to read input image %s", infn); exit(-1); } cairoutils_rgba_to_argb32(img, W, H); } else if (!justlist) { // Allocate a black image. img = calloc(4 * W * H, 1); if (!img) { SYSERROR("Failed to allocate a blank image on which to plot!"); exit(-1); } } if (HD && !hdpath) { logerr("If you specify -D (plot Henry Draper objs), you also have to give -d (path to Henry Draper catalog)\n"); exit(-1); } if (!justlist) { /* Cairo layers: -background: surfbg / cairobg --> gets drawn first, in black, masked by surfshapesmask -shapes: surfshapes / cairoshapes --> gets drawn second, masked by surfshapesmask -foreground/text: surffg / cairo --> gets drawn last. */ surffg = cairo_image_surface_create(CAIRO_FORMAT_ARGB32, W, H); cairo = cairo_create(surffg); cairo_set_line_join(cairo, CAIRO_LINE_JOIN_BEVEL); cairo_set_antialias(cairo, CAIRO_ANTIALIAS_GRAY); cairo_set_source_rgba(cairo, 1.0, 1.0, 1.0, 1.0); cairo_scale(cairo, scale, scale); //cairo_select_font_face(cairo, "helvetica", CAIRO_FONT_SLANT_NORMAL, CAIRO_FONT_WEIGHT_BOLD); cairo_select_font_face(cairo, "DejaVu Sans Mono Book", CAIRO_FONT_SLANT_NORMAL, CAIRO_FONT_WEIGHT_BOLD); cairo_set_font_size(cairo, fontsize); surfshapes = cairo_image_surface_create(CAIRO_FORMAT_ARGB32, W, H); cairoshapes = cairo_create(surfshapes); cairo_set_line_join(cairoshapes, CAIRO_LINE_JOIN_BEVEL); cairo_set_antialias(cairoshapes, CAIRO_ANTIALIAS_GRAY); cairo_set_source_rgba(cairoshapes, 1.0, 1.0, 1.0, 1.0); cairo_scale(cairoshapes, scale, scale); cairo_select_font_face(cairoshapes, "DejaVu Sans Mono Book", CAIRO_FONT_SLANT_NORMAL, CAIRO_FONT_WEIGHT_BOLD); cairo_set_font_size(cairoshapes, fontsize); surfshapesmask = cairo_image_surface_create(CAIRO_FORMAT_A8, W, H); cairoshapesmask = cairo_create(surfshapesmask); cairo_set_line_join(cairoshapesmask, CAIRO_LINE_JOIN_BEVEL); cairo_set_antialias(cairoshapesmask, CAIRO_ANTIALIAS_GRAY); cairo_set_source_rgba(cairoshapesmask, 1.0, 1.0, 1.0, 1.0); cairo_scale(cairoshapesmask, scale, scale); cairo_select_font_face(cairoshapesmask, "DejaVu Sans Mono Book", CAIRO_FONT_SLANT_NORMAL, CAIRO_FONT_WEIGHT_BOLD); cairo_set_font_size(cairoshapesmask, fontsize); cairo_paint(cairoshapesmask); cairo_stroke(cairoshapesmask); surfbg = cairo_image_surface_create(CAIRO_FORMAT_A8, W, H); cairobg = cairo_create(surfbg); cairo_set_line_join(cairobg, CAIRO_LINE_JOIN_BEVEL); cairo_set_antialias(cairobg, CAIRO_ANTIALIAS_GRAY); cairo_set_source_rgba(cairobg, 0, 0, 0, 1); cairo_scale(cairobg, scale, scale); cairo_select_font_face(cairobg, "DejaVu Sans Mono Book", CAIRO_FONT_SLANT_NORMAL, CAIRO_FONT_WEIGHT_BOLD); cairo_set_font_size(cairobg, fontsize); cairos->bg = cairobg; cairos->fg = cairo; cairos->shapes = cairoshapes; cairos->shapesmask = cairoshapesmask; cairos->imgW = (float)W/scale; cairos->imgH = (float)H/scale; // } if (grid) { double ramin, ramax, decmin, decmax; double ra, dec; double rastep = gridspacing / 60.0; double decstep = gridspacing / 60.0; // how many line segments int N = 10; double px, py; int i; cairo_set_source_rgba(cairo, gridcolor[0], gridcolor[1], gridcolor[2], 1.0); sip_get_radec_bounds(&sip, 100, &ramin, &ramax, &decmin, &decmax); logverb("Plotting grid lines from RA=%g to %g in steps of %g; Dec=%g to %g in steps of %g\n", ramin, ramax, rastep, decmin, decmax, decstep); for (dec = decstep * floor(decmin / decstep); dec<=decmax; dec+=decstep) { logverb(" dec=%g\n", dec); for (i=0; i<=N; i++) { ra = ramin + ((double)i / (double)N) * (ramax - ramin); if (!sip_radec2pixelxy(&sip, ra, dec, &px, &py)) continue; // first time, move_to; else line_to ((ra == ramin) ? cairo_move_to : cairo_line_to)(cairo, px, py); } cairo_stroke(cairo); } for (ra = rastep * floor(ramin / rastep); ra <= ramax; ra += rastep) { //for (dec=decmin; dec<=decmax; dec += (decmax - decmin)/(double)N) { logverb(" ra=%g\n", ra); for (i=0; i<=N; i++) { dec = decmin + ((double)i / (double)N) * (decmax - decmin); if (!sip_radec2pixelxy(&sip, ra, dec, &px, &py)) continue; // first time, move_to; else line_to ((dec == decmin) ? cairo_move_to : cairo_line_to)(cairo, px, py); } cairo_stroke(cairo); } cairo_set_source_rgba(cairo, 1.0, 1.0, 1.0, 1.0); } } if (constell) { N = constellations_n(); logverb("Checking %i constellations.\n", N); for (c=0; c<N; c++) { const char* shortname = NULL; const char* longname; il* lines; il* uniqstars; il* inboundstars; float r,g,b; int Ninbounds; int Nunique; cairo_text_extents_t textents; double cmass[3]; uniqstars = constellations_get_unique_stars(c); inboundstars = il_new(16); Nunique = il_size(uniqstars); debug("%s: %zu unique stars.\n", shortname, il_size(uniqstars)); // Count the number of unique stars belonging to this contellation // that are within the image bounds Ninbounds = 0; for (i=0; i<il_size(uniqstars); i++) { int star; star = il_get(uniqstars, i); constellations_get_star_radec(star, &ra, &dec); debug("star %i: ra,dec (%g,%g)\n", il_get(uniqstars, i), ra, dec); if (!sip_radec2pixelxy(&sip, ra, dec, &px, &py)) continue; if (px < 0 || py < 0 || px*scale > W || py*scale > H) continue; Ninbounds++; il_append(inboundstars, star); } il_free(uniqstars); debug("%i are in-bounds.\n", Ninbounds); // Only draw this constellation if at least 2 of its stars // are within the image bounds. if (Ninbounds < 2) { il_free(inboundstars); continue; } // Set the color based on the location of the first in-bounds star. // This is a hack -- we have two different constellation // definitions with different numbering schemes! if (!justlist && (il_size(inboundstars) > 0)) { // This is helpful for videos: ensuring that the same // color is chosen for a constellation in each frame. int star = il_get(inboundstars, 0); constellations_get_star_radec(star, &ra, &dec); if (whitetext) { r = g = b = 1; } else { color_for_radec(ra, dec, &r, &g, &b); } cairo_set_source_rgba(cairoshapes, r,g,b,0.8); cairo_set_line_width(cairoshapes, cw); cairo_set_source_rgba(cairo, r,g,b,0.8); cairo_set_line_width(cairo, cw); } // Draw circles around each star. // Find center of mass (of the in-bounds stars) cmass[0] = cmass[1] = cmass[2] = 0.0; for (i=0; i<il_size(inboundstars); i++) { double xyz[3]; int star = il_get(inboundstars, i); constellations_get_star_radec(star, &ra, &dec); if (!sip_radec2pixelxy(&sip, ra, dec, &px, &py)) continue; if (px < 0 || py < 0 || px*scale > W || py*scale > H) continue; if (!justlist) { cairo_arc(cairobg, px, py, crad+1.0, 0.0, 2.0*M_PI); cairo_stroke(cairobg); cairo_arc(cairoshapes, px, py, crad, 0.0, 2.0*M_PI); cairo_stroke(cairoshapes); } radecdeg2xyzarr(ra, dec, xyz); cmass[0] += xyz[0]; cmass[1] += xyz[1]; cmass[2] += xyz[2]; } cmass[0] /= il_size(inboundstars); cmass[1] /= il_size(inboundstars); cmass[2] /= il_size(inboundstars); xyzarr2radecdeg(cmass, &ra, &dec); il_free(inboundstars); if (!sip_radec2pixelxy(&sip, ra, dec, &px, &py)) continue; shortname = constellations_get_shortname(c); longname = constellations_get_longname(c); assert(shortname && longname); logverb("%s at (%g, %g)\n", longname, px, py); if (Ninbounds == Nunique) { printf("The constellation %s (%s)\n", longname, shortname); } else { printf("Part of the constellation %s (%s)\n", longname, shortname); } if (justlist) continue; // If the label will be off-screen, move it back on. cairo_text_extents(cairo, shortname, &textents); if (px < 0) px = 0; if (py < textents.height) py = textents.height; if ((px + textents.width)*scale > W) px = W/scale - textents.width; if ((py+textents.height)*scale > H) py = H/scale - textents.height; logverb("%s at (%g, %g)\n", shortname, px, py); add_text(cairos, longname, px, py, halign, valign); // Draw the lines. cairo_set_line_width(cairo, lw); lines = constellations_get_lines(c); for (i=0; i<il_size(lines)/2; i++) { int star1, star2; double ra1, dec1, ra2, dec2; double px1, px2, py1, py2; double dx, dy; double dist; double gapfrac; star1 = il_get(lines, i*2+0); star2 = il_get(lines, i*2+1); constellations_get_star_radec(star1, &ra1, &dec1); constellations_get_star_radec(star2, &ra2, &dec2); if (!sip_radec2pixelxy(&sip, ra1, dec1, &px1, &py1) || !sip_radec2pixelxy(&sip, ra2, dec2, &px2, &py2)) continue; dx = px2 - px1; dy = py2 - py1; dist = hypot(dx, dy); gapfrac = endgap / dist; cairo_move_to(cairoshapes, px1 + dx*gapfrac, py1 + dy*gapfrac); cairo_line_to(cairoshapes, px1 + dx*(1.0-gapfrac), py1 + dy*(1.0-gapfrac)); cairo_stroke(cairoshapes); } il_free(lines); } logverb("done constellations.\n"); } if (bright) { double dy = 0; cairo_font_extents_t extents; pl* brightstars = pl_new(16); if (!justlist) { cairo_set_source_rgba(cairoshapes, 0.75, 0.75, 0.75, 0.8); cairo_font_extents(cairo, &extents); dy = extents.ascent * 0.5; cairo_set_line_width(cairoshapes, cw); } N = bright_stars_n(); logverb("Checking %i bright stars.\n", N); for (i=0; i<N; i++) { const brightstar_t* bs = bright_stars_get(i); if (!sip_radec2pixelxy(&sip, bs->ra, bs->dec, &px, &py)) continue; if (px < 0 || py < 0 || px*scale > W || py*scale > H) continue; if (!(bs->name && strlen(bs->name))) continue; if (common_only && !(bs->common_name && strlen(bs->common_name))) continue; if (strcmp(bs->common_name, "Maia") == 0) continue; pl_append(brightstars, bs); } // keep only the Nbright brightest? if (Nbright && (pl_size(brightstars) > Nbright)) { pl_sort(brightstars, sort_by_mag); pl_remove_index_range(brightstars, Nbright, pl_size(brightstars)-Nbright); } for (i=0; i<pl_size(brightstars); i++) { char* text; const brightstar_t* bs = pl_get(brightstars, i); if (!sip_radec2pixelxy(&sip, bs->ra, bs->dec, &px, &py)) continue; if (bs->common_name && strlen(bs->common_name)) if (print_common_only || common_only) text = strdup(bs->common_name); else asprintf_safe(&text, "%s (%s)", bs->common_name, bs->name); else text = strdup(bs->name); logverb("%s at (%g, %g)\n", text, px, py); if (json) { sl* names = sl_new(4); char* namearr; if (bs->common_name && strlen(bs->common_name)) sl_append(names, bs->common_name); if (bs->name) sl_append(names, bs->name); namearr = sl_join(names, "\", \""); sl_appendf(json, "{ \"type\" : \"star\", " " \"pixelx\": %g, " " \"pixely\": %g, " " \"name\" : \"%s\", " " \"names\" : [ \"%s\" ] } " , px, py, (bs->common_name && strlen(bs->common_name)) ? bs->common_name : bs->name, namearr); free(namearr); sl_free2(names); } if (bs->common_name && strlen(bs->common_name)) printf("The star %s (%s)\n", bs->common_name, bs->name); else printf("The star %s\n", bs->name); if (!justlist) { float r,g,b; // set color based on RA,Dec to match constellations above. if (whitetext) { r = g = b = 1; } else { color_for_radec(bs->ra, bs->dec, &r, &g, &b); } cairo_set_source_rgba(cairoshapes, r,g,b,0.8); cairo_set_source_rgba(cairo, r,g,b, 0.8); } if (!justlist) add_text(cairos, text, px + label_offset, py + dy, halign, valign); free(text); if (!justlist) { // plot a black circle behind the light circle... cairo_arc(cairobg, px, py, crad+1.0, 0.0, 2.0*M_PI); cairo_stroke(cairobg); cairo_arc(cairoshapes, px, py, crad, 0.0, 2.0*M_PI); cairo_stroke(cairoshapes); } } pl_free(brightstars); } if (NGC) { double imscale; double imsize; double dy = 0; cairo_font_extents_t extents; if (!justlist) { cairo_set_source_rgb(cairoshapes, 1.0, 1.0, 1.0); cairo_set_source_rgb(cairo, 1.0, 1.0, 1.0); cairo_set_line_width(cairo, nw); cairo_font_extents(cairo, &extents); dy = extents.ascent * 0.5; } // arcsec/pixel imscale = sip_pixel_scale(&sip); // arcmin imsize = imscale * (imin(W, H) / scale) / 60.0; N = ngc_num_entries(); logverb("Checking %i NGC/IC objects.\n", N); for (i=0; i<N; i++) { ngc_entry* ngc = ngc_get_entry(i); sl* str; sl* names; double pixsize; float ara, adec; char* text; if (!ngc) break; if (ngc->size < imsize * ngc_fraction) continue; if (ngcic_accurate_get_radec(ngc->is_ngc, ngc->id, &ara, &adec) == 0) { ngc->ra = ara; ngc->dec = adec; } if (!sip_radec2pixelxy(&sip, ngc->ra, ngc->dec, &px, &py)) continue; if (px < 0 || py < 0 || px*scale > W || py*scale > H) continue; str = sl_new(4); //sl_appendf(str, "%s %i", (ngc->is_ngc ? "NGC" : "IC"), ngc->id); names = ngc_get_names(ngc, NULL); if (names) { int n; for (n=0; n<sl_size(names); n++) { if (only_messier && strncmp(sl_get(names, n), "M ", 2)) continue; sl_append(str, sl_get(names, n)); } } sl_free2(names); text = sl_implode(str, " / "); printf("%s\n", text); pixsize = ngc->size * 60.0 / imscale; if (!justlist) { // black circle behind the white one... cairo_arc(cairobg, px, py, pixsize/2.0+1.0, 0.0, 2.0*M_PI); cairo_stroke(cairobg); cairo_move_to(cairoshapes, px + pixsize/2.0, py); cairo_arc(cairoshapes, px, py, pixsize/2.0, 0.0, 2.0*M_PI); debug("size: %f arcsec, pixsize: %f pixels\n", ngc->size, pixsize); cairo_stroke(cairoshapes); add_text(cairos, text, px + label_offset, py + dy, halign, valign); } if (json) { char* namelist = sl_implode(str, "\", \""); sl_appendf(json, "{ \"type\" : \"ngc\", " " \"names\" : [ \"%s\" ], " " \"pixelx\" : %g, " " \"pixely\" : %g, " " \"radius\" : %g }" , namelist, px, py, pixsize/2.0); free(namelist); } free(text); sl_free2(str); } } if (HD) { double rac, decc, ra2, dec2; double arcsec; hd_catalog_t* hdcat; bl* hdlist; int i; if (!justlist) cairo_set_source_rgb(cairo, 1.0, 1.0, 1.0); logverb("Reading HD catalog: %s\n", hdpath); hdcat = henry_draper_open(hdpath); if (!hdcat) { ERROR("Failed to open HD catalog"); exit(-1); } logverb("Got %i HD stars\n", henry_draper_n(hdcat)); sip_pixelxy2radec(&sip, W/(2.0*scale), H/(2.0*scale), &rac, &decc); sip_pixelxy2radec(&sip, 0.0, 0.0, &ra2, &dec2); arcsec = arcsec_between_radecdeg(rac, decc, ra2, dec2); // Fudge arcsec *= 1.1; hdlist = henry_draper_get(hdcat, rac, decc, arcsec); logverb("Found %zu HD stars within range (%g arcsec of RA,Dec %g,%g)\n", bl_size(hdlist), arcsec, rac, decc); for (i=0; i<bl_size(hdlist); i++) { double px, py; char* txt; hd_entry_t* hd = bl_access(hdlist, i); if (!sip_radec2pixelxy(&sip, hd->ra, hd->dec, &px, &py)) { continue; } if (px < 0 || py < 0 || px*scale > W || py*scale > H) { logverb(" HD %i at RA,Dec (%g, %g) -> pixel (%.1f, %.1f) is out of bounds\n", hd->hd, hd->ra, hd->dec, px, py); continue; } asprintf_safe(&txt, "HD %i", hd->hd); if (!justlist) { cairo_text_extents_t textents; cairo_text_extents(cairo, txt, &textents); cairo_arc(cairobg, px, py, crad+1.0, 0.0, 2.0*M_PI); cairo_stroke(cairobg); cairo_arc(cairoshapes, px, py, crad, 0.0, 2.0*M_PI); cairo_stroke(cairoshapes); px -= (textents.width * 0.5); py -= (crad + 4.0); add_text(cairos, txt, px, py, halign, valign); } if (json) sl_appendf(json, "{ \"type\" : \"hd\"," " \"pixelx\": %g, " " \"pixely\": %g, " " \"name\" : \"HD %i\" }" , px, py, hd->hd); printf("%s\n", txt); free(txt); } bl_free(hdlist); henry_draper_close(hdcat); } if (json) { FILE* fout = stderr; char* annstr = sl_implode(json, ",\n"); fprintf(fout, "{ \n"); fprintf(fout, " \"status\": \"solved\",\n"); fprintf(fout, " \"git-revision\": %s,\n", AN_GIT_REVISION); fprintf(fout, " \"git-date\": \"%s\",\n", AN_GIT_DATE); fprintf(fout, " \"annotations\": [\n%s\n]\n", annstr); fprintf(fout, "}\n"); free(annstr); } sl_free2(json); json = NULL; if (justlist) return 0; target = cairo_image_surface_create_for_data(img, CAIRO_FORMAT_ARGB32, W, H, W*4); cairot = cairo_create(target); cairo_set_source_rgba(cairot, 0, 0, 0, 1); // Here's where you set the background surface's properties... cairo_set_source_surface(cairot, surfbg, 0, 0); cairo_mask_surface(cairot, surfshapesmask, 0, 0); cairo_stroke(cairot); // Add on the shapes. cairo_set_source_surface(cairot, surfshapes, 0, 0); //cairo_mask_surface(cairot, surfshapes, 0, 0); cairo_mask_surface(cairot, surfshapesmask, 0, 0); cairo_stroke(cairot); // Add on the foreground. cairo_set_source_surface(cairot, surffg, 0, 0); cairo_mask_surface(cairot, surffg, 0, 0); cairo_stroke(cairot); // Convert image for output... cairoutils_argb32_to_rgba(img, W, H); if (pngformat) { if (cairoutils_write_png(outfn, img, W, H)) { ERROR("Failed to write PNG"); exit(-1); } } else { if (cairoutils_write_ppm(outfn, img, W, H)) { ERROR("Failed to write PPM"); exit(-1); } } cairo_surface_destroy(target); cairo_surface_destroy(surfshapesmask); cairo_surface_destroy(surffg); cairo_surface_destroy(surfbg); cairo_surface_destroy(surfshapes); cairo_destroy(cairo); cairo_destroy(cairot); cairo_destroy(cairobg); cairo_destroy(cairoshapes); cairo_destroy(cairoshapesmask); free(img); return 0; }