EVOLUTION-MANAGER

Edit File: proj.cpp

/* <<<< Cartographic projection filter program >>>> */ #include "proj.h" #include "proj_internal.h" #include <stdio.h> #include <stdlib.h> #include <ctype.h> #include <string.h> #include <math.h> #include "emess.h" #include "utils.h" #if defined(MSDOS) || defined(OS2) || defined(WIN32) || defined(__WIN32__) # include <fcntl.h> # include <io.h> # define SET_BINARY_MODE(file) _setmode(_fileno(file), O_BINARY) #else # define SET_BINARY_MODE(file) #endif #define MAX_LINE 1000 #define MAX_PARGS 100 #define PJ_INVERS(P) (P->inv ? 1 : 0) static PJ *Proj; static union { PJ_XY (*fwd)(PJ_LP, PJ *); PJ_LP (*inv)(PJ_XY, PJ *); } proj; static int reversein = 0, /* != 0 reverse input arguments */ reverseout = 0, /* != 0 reverse output arguments */ bin_in = 0, /* != 0 then binary input */ bin_out = 0, /* != 0 then binary output */ echoin = 0, /* echo input data to output line */ tag = '#', /* beginning of line tag character */ inverse = 0, /* != 0 then inverse projection */ prescale = 0, /* != 0 apply cartesian scale factor */ dofactors = 0, /* determine scale factors */ very_verby = 0, /* very verbose mode */ postscale = 0; static const char *oform = nullptr; /* output format for x-y or decimal degrees */ static char oform_buffer[16]; /* Buffer for oform when using -d */ static const char *oterr = "*\t*", /* output line for unprojectable input */ *usage = "%s\nusage: %s [-bdeEfiIlmorsStTvVwW [args]] [+opt[=arg] ...] [file ...]\n"; static PJ_FACTORS facs; static double (*informat)(const char *, char **), /* input data deformatter function */ fscale = 0.; /* cartesian scale factor */ /* file processing function */ static void process(FILE *fid) { char line[MAX_LINE+3], *s = nullptr, pline[40]; PJ_COORD data; for (;;) { int facs_bad = 0; ++emess_dat.File_line; if (bin_in) { /* binary input */ if (fread(&data, sizeof(PJ_UV), 1, fid) != 1) break; } else { /* ascii input */ if (!(s = fgets(line, MAX_LINE, fid))) break; if (!strchr(s, '\n')) { /* overlong line */ int c; (void)strcat(s, "\n"); /* gobble up to newline */ while ((c = fgetc(fid)) != EOF && c != '\n') ; } if (*s == tag) { if (!bin_out) (void)fputs(line, stdout); continue; } if (reversein) { data.uv.v = (*informat)(s, &s); data.uv.u = (*informat)(s, &s); } else { data.uv.u = (*informat)(s, &s); data.uv.v = (*informat)(s, &s); } if (data.uv.v == HUGE_VAL) data.uv.u = HUGE_VAL; if (!*s && (s > line)) --s; /* assumed we gobbled \n */ if (!bin_out && echoin) { char t; t = *s; *s = '\0'; (void)fputs(line, stdout); *s = t; putchar('\t'); } } if (data.uv.u != HUGE_VAL) { PJ_COORD coord; coord.lp = data.lp; if (prescale) { data.uv.u *= fscale; data.uv.v *= fscale; } if (dofactors && !inverse) { facs = proj_factors(Proj, coord); facs_bad = proj_errno(Proj); } data.xy = (*proj.fwd)(data.lp, Proj); if (dofactors && inverse) { facs = proj_factors(Proj, coord); facs_bad = proj_errno(Proj); } if (postscale && data.uv.u != HUGE_VAL) { data.uv.u *= fscale; data.uv.v *= fscale; } } if (bin_out) { /* binary output */ (void)fwrite(&data, sizeof(PJ_UV), 1, stdout); continue; } else if (data.uv.u == HUGE_VAL) /* error output */ (void)fputs(oterr, stdout); else if (inverse && !oform) { /*ascii DMS output */ if (reverseout) { (void)fputs(rtodms(pline, data.uv.v, 'N', 'S'), stdout); putchar('\t'); (void)fputs(rtodms(pline, data.uv.u, 'E', 'W'), stdout); } else { (void)fputs(rtodms(pline, data.uv.u, 'E', 'W'), stdout); putchar('\t'); (void)fputs(rtodms(pline, data.uv.v, 'N', 'S'), stdout); } } else { /* x-y or decimal degree ascii output, scale if warranted by output units */ if (inverse) { if (proj_angular_input(Proj, PJ_FWD)) { data.uv.v *= RAD_TO_DEG; data.uv.u *= RAD_TO_DEG; } } else { if (proj_angular_output(Proj, PJ_FWD)) { data.uv.v *= RAD_TO_DEG; data.uv.u *= RAD_TO_DEG; } } if (reverseout) { (void)printf(oform, data.uv.v); putchar('\t'); (void)printf(oform, data.uv.u); } else { (void)printf(oform, data.uv.u); putchar('\t'); (void)printf(oform, data.uv.v); } } /* print scale factor data */ if (dofactors) { if (!facs_bad) (void)printf("\t<%g %g %g %g %g %g>", facs.meridional_scale, facs.parallel_scale, facs.areal_scale, facs.angular_distortion * RAD_TO_DEG, facs.tissot_semimajor, facs.tissot_semiminor); else (void)fputs("\t<* * * * * *>", stdout); } (void)fputs(bin_in ? "\n" : s, stdout); } } /* file processing function --- verbosely */ static void vprocess(FILE *fid) { char line[MAX_LINE+3], *s, pline[40]; PJ_LP dat_ll; PJ_XY dat_xy; int linvers; PJ_COORD coord; if (!oform) oform = "%.3f"; if (bin_in || bin_out) emess(1,"binary I/O not available in -V option"); for (;;) { proj_errno_reset(Proj); ++emess_dat.File_line; if (!(s = fgets(line, MAX_LINE, fid))) break; if (!strchr(s, '\n')) { /* overlong line */ int c; (void)strcat(s, "\n"); /* gobble up to newline */ while ((c = fgetc(fid)) != EOF && c != '\n') ; } if (*s == tag) { /* pass on data */ (void)fputs(s, stdout); continue; } /* check to override default input mode */ if (*s == 'I' || *s == 'i') { linvers = 1; ++s; } else linvers = inverse; if (linvers) { if (!PJ_INVERS(Proj)) { emess(-1,"inverse for this projection not avail.\n"); continue; } dat_xy.x = strtod(s, &s); dat_xy.y = strtod(s, &s); if (dat_xy.x == HUGE_VAL || dat_xy.y == HUGE_VAL) { emess(-1,"lon-lat input conversion failure\n"); continue; } if (prescale) { dat_xy.x *= fscale; dat_xy.y *= fscale; } if (reversein) { PJ_XY temp = dat_xy; dat_xy.x = temp.y; dat_xy.y = temp.x; } dat_ll = pj_inv(dat_xy, Proj); } else { dat_ll.lam = proj_dmstor(s, &s); dat_ll.phi = proj_dmstor(s, &s); if (dat_ll.lam == HUGE_VAL || dat_ll.phi == HUGE_VAL) { emess(-1,"lon-lat input conversion failure\n"); continue; } if (reversein) { PJ_LP temp = dat_ll; dat_ll.lam = temp.phi; dat_ll.phi = temp.lam; } dat_xy = pj_fwd(dat_ll, Proj); if (postscale) { dat_xy.x *= fscale; dat_xy.y *= fscale; } } /* For some reason pj_errno does not work as expected in some */ /* versions of Visual Studio, so using pj_get_errno_ref instead */ if (*pj_get_errno_ref()) { emess(-1, pj_strerrno(*pj_get_errno_ref())); continue; } if (!*s && (s > line)) --s; /* assumed we gobbled \n */ coord.lp = dat_ll; facs = proj_factors(Proj, coord); if (proj_errno(Proj)) { emess(-1,"failed to compute factors\n\n"); continue; } if (*s != '\n') (void)fputs(s, stdout); (void)fputs("Longitude: ", stdout); (void)fputs(proj_rtodms(pline, dat_ll.lam, 'E', 'W'), stdout); (void)printf(" [ %.11g ]\n", dat_ll.lam * RAD_TO_DEG); (void)fputs("Latitude: ", stdout); (void)fputs(proj_rtodms(pline, dat_ll.phi, 'N', 'S'), stdout); (void)printf(" [ %.11g ]\n", dat_ll.phi * RAD_TO_DEG); (void)fputs("Easting (x): ", stdout); (void)printf(oform, dat_xy.x); putchar('\n'); (void)fputs("Northing (y): ", stdout); (void)printf(oform, dat_xy.y); putchar('\n'); (void)printf("Meridian scale (h) : %.8f ( %.4g %% error )\n", facs.meridional_scale, (facs.meridional_scale-1.)*100.); (void)printf("Parallel scale (k) : %.8f ( %.4g %% error )\n", facs.parallel_scale, (facs.parallel_scale-1.)*100.); (void)printf("Areal scale (s): %.8f ( %.4g %% error )\n", facs.areal_scale, (facs.areal_scale-1.)*100.); (void)printf("Angular distortion (w): %.3f\n", facs.angular_distortion * RAD_TO_DEG); (void)printf("Meridian/Parallel angle: %.5f\n", facs.meridian_parallel_angle * RAD_TO_DEG); (void)printf("Convergence : "); (void)fputs(proj_rtodms(pline, facs.meridian_convergence, 0, 0), stdout); (void)printf(" [ %.8f ]\n", facs.meridian_convergence * RAD_TO_DEG); (void)printf("Max-min (Tissot axis a-b) scale error: %.5f %.5f\n\n", facs.tissot_semimajor, facs.tissot_semiminor); } } int main(int argc, char **argv) { char *arg; char *pargv[MAX_PARGS] = {}; char **eargv = argv; FILE *fid; int pargc = 0, eargc = 0, mon = 0; if ( (emess_dat.Prog_name = strrchr(*argv,DIR_CHAR)) != nullptr) ++emess_dat.Prog_name; else emess_dat.Prog_name = *argv; inverse = ! strncmp(emess_dat.Prog_name, "inv", 3); if (argc <= 1 ) { (void)fprintf(stderr, usage, pj_get_release(), emess_dat.Prog_name); exit (0); } /* process run line arguments */ while (--argc > 0) { /* collect run line arguments */ if(**++argv == '-') for(arg = *argv;;) { switch(*++arg) { case '\0': /* position of "stdin" */ if (arg[-1] == '-') eargv[eargc++] = const_cast<char*>("-"); break; case 'b': /* binary I/O */ bin_in = bin_out = 1; continue; case 'v': /* monitor dump of initialization */ mon = 1; continue; case 'i': /* input binary */ bin_in = 1; continue; case 'o': /* output binary */ bin_out = 1; continue; case 'I': /* alt. method to spec inverse */ inverse = 1; continue; case 'E': /* echo ascii input to ascii output */ echoin = 1; continue; case 'V': /* very verbose processing mode */ very_verby = 1; mon = 1; continue; case 'S': /* compute scale factors */ dofactors = 1; continue; case 't': /* set col. one char */ if (arg[1]) tag = *++arg; else emess(1,"missing -t col. 1 tag"); continue; case 'l': /* list projections, ellipses or units */ if (!arg[1] || arg[1] == 'p' || arg[1] == 'P') { /* list projections */ const struct PJ_LIST *lp; int do_long = arg[1] == 'P', c; const char *str; for (lp = proj_list_operations() ; lp->id ; ++lp) { if( strcmp(lp->id,"latlong") == 0 || strcmp(lp->id,"longlat") == 0 || strcmp(lp->id,"geocent") == 0 ) continue; (void)printf("%s : ", lp->id); if (do_long) /* possibly multiline description */ (void)puts(*lp->descr); else { /* first line, only */ str = *lp->descr; while ((c = *str++) && c != '\n') putchar(c); putchar('\n'); } } } else if (arg[1] == '=') { /* list projection 'descr' */ const struct PJ_LIST *lp; arg += 2; for (lp = proj_list_operations(); lp->id ; ++lp) if (!strcmp(lp->id, arg)) { (void)printf("%9s : %s\n", lp->id, *lp->descr); break; } } else if (arg[1] == 'e') { /* list ellipses */ const struct PJ_ELLPS *le; for (le = proj_list_ellps(); le->id ; ++le) (void)printf("%9s %-16s %-16s %s\n", le->id, le->major, le->ell, le->name); } else if (arg[1] == 'u') { /* list units */ const struct PJ_UNITS *lu; for (lu = proj_list_units(); lu->id ; ++lu) (void)printf("%12s %-20s %s\n", lu->id, lu->to_meter, lu->name); } else if (arg[1] == 'd') { /* list datums */ const struct PJ_DATUMS *ld; printf("__datum_id__ __ellipse___ __definition/comments______________________________\n" ); for (ld = pj_get_datums_ref(); ld->id ; ++ld) { printf("%12s %-12s %-30s\n", ld->id, ld->ellipse_id, ld->defn); if( ld->comments != nullptr && strlen(ld->comments) > 0 ) printf( "%25s %s\n", " ", ld->comments ); } } else emess(1,"invalid list option: l%c",arg[1]); exit(0); /* cppcheck-suppress duplicateBreak */ continue; /* artificial */ case 'e': /* error line alternative */ if (--argc <= 0) noargument: emess(1,"missing argument for -%c",*arg); oterr = *++argv; continue; case 'm': /* cartesian multiplier */ if (--argc <= 0) goto noargument; postscale = 1; if (!strncmp("1/",*++argv,2) || !strncmp("1:",*argv,2)) { if((fscale = atof((*argv)+2)) == 0.) goto badscale; fscale = 1. / fscale; } else if ((fscale = atof(*argv)) == 0.) { badscale: emess(1,"invalid scale argument"); } continue; case 'W': /* specify seconds precision */ case 'w': /* -W for constant field width */ { int c = arg[1]; if (c != 0 && isdigit(c)) { set_rtodms(c - '0', *arg == 'W'); ++arg; } else emess(1,"-W argument missing or non-digit"); continue; } case 'f': /* alternate output format degrees or xy */ if (--argc <= 0) goto noargument; oform = *++argv; continue; case 'd': if (--argc <= 0) goto noargument; sprintf(oform_buffer, "%%.%df", atoi(*++argv)); oform = oform_buffer; break; case 'r': /* reverse input */ reversein = 1; continue; case 's': /* reverse output */ reverseout = 1; continue; default: emess(1, "invalid option: -%c",*arg); break; } break; } else if (**argv == '+') { /* + argument */ if (pargc < MAX_PARGS) pargv[pargc++] = *argv + 1; else emess(1,"overflowed + argument table"); } else /* assumed to be input file name(s) */ eargv[eargc++] = *argv; } if (eargc == 0) /* if no specific files force sysin */ eargv[eargc++] = const_cast<char*>("-"); if( oform ) { if( !validate_form_string_for_numbers(oform) ) { emess(3, "invalid format string"); exit(0); } } /* done with parameter and control input */ if (inverse && postscale) { prescale = 1; postscale = 0; fscale = 1./fscale; } if (!(Proj = pj_init(pargc, pargv))) emess(3,"projection initialization failure\ncause: %s", pj_strerrno(pj_errno)); if (!proj_angular_input(Proj, PJ_FWD)) { emess(3, "can't initialize operations that take non-angular input coordinates"); exit(0); } if (proj_angular_output(Proj, PJ_FWD)) { emess(3, "can't initialize operations that produce angular output coordinates"); exit(0); } // Ugly hack. See https://github.com/OSGeo/PROJ/issues/1782 if( Proj->right == PJ_IO_UNITS_WHATEVER && Proj->descr && strncmp(Proj->descr, "General Oblique Transformation", strlen("General Oblique Transformation")) == 0 ) { Proj->right = PJ_IO_UNITS_PROJECTED; } if (inverse) { if (!Proj->inv) emess(3,"inverse projection not available"); proj.inv = pj_inv; } else proj.fwd = pj_fwd; /* set input formatting control */ if (mon) { pj_pr_list(Proj); if (very_verby) { (void)printf("#Final Earth figure: "); if (Proj->es != 0.0) { (void)printf("ellipsoid\n# Major axis (a): "); (void)printf(oform ? oform : "%.3f", Proj->a); (void)printf("\n# 1/flattening: %.6f\n", 1./(1. - sqrt(1. - Proj->es))); (void)printf("# squared eccentricity: %.12f\n", Proj->es); } else { (void)printf("sphere\n# Radius: "); (void)printf(oform ? oform : "%.3f", Proj->a); (void)putchar('\n'); } } } if (inverse) informat = strtod; else { informat = proj_dmstor; if (!oform) oform = "%.2f"; } if (bin_out) { SET_BINARY_MODE(stdout); } /* process input file list */ for ( ; eargc-- ; ++eargv) { if (**eargv == '-') { fid = stdin; emess_dat.File_name = const_cast<char*>("<stdin>"); if (bin_in) { SET_BINARY_MODE(stdin); } } else { if ((fid = fopen(*eargv, "rb")) == nullptr) { emess(-2, "input file: %s", *eargv); continue; } emess_dat.File_name = *eargv; } emess_dat.File_line = 0; if (very_verby) vprocess(fid); else process(fid); (void)fclose(fid); emess_dat.File_name = nullptr; } if( Proj ) pj_free(Proj); exit(0); /* normal completion */ }