#include #include #include #include #include #include "common.h" #include "main.hh" int loadClutter(char *filename, double radius, struct site tx) { /* This function reads a MODIS 17-class clutter file in ASCII Grid format. The nominal heights it applies to each value, eg. 5 (Mixed forest) = 15m are taken from ITU-R P.452-11. It doesn't have it's own matrix, instead it boosts the DEM matrix like point clutter AddElevation(lat, lon, height); If tiles are standard 2880 x 3840 then cellsize is constant at 0.004166 */ int x, y, z, result, h, w; double clh, xll, yll, xur, yur, cellsize, cellsize2, xOffset, yOffset, lat, lon, i, j; char line[50000]; char * pch; FILE *fd; fd = fopen(filename, "rb"); if (fd != NULL) { if (fgets(line, 19, fd) != NULL) { pch = strtok (line," "); pch = strtok (NULL, " "); w = atoi(pch); } if (fgets(line, 19, fd) != NULL) { //pch = strtok (line," "); //pch = strtok (NULL, " "); h = atoi(pch); } if(w==2880 && h==3840){ cellsize=0.004167; cellsize2 = cellsize * 2; }else{ return 0; // can't work with this yet } if (debug) { fprintf(stderr, "\nLoading clutter file \"%s\" %d x %d...\n", filename, w,h); fflush(stderr); } if (fgets(line, 25, fd) != NULL) { sscanf(pch, "%lf", &xll); } fgets(line, 25, fd); if (fgets(line, 25, fd) != NULL) { sscanf(pch, "%lf", &yll); } if (debug) { fprintf(stderr, "\nxll %.2f yll %.2f\n", xll, yll); fflush(stderr); } fgets(line, 25, fd); // cellsize //loop over matrix for (y = h; y > 0; y--) { x = 0; if (fgets(line, 100000, fd) != NULL) { pch = strtok(line, " "); while (pch != NULL && x < w) { z = atoi(pch); // Apply ITU-R P.452-11 // Treat classes 0, 9, 10, 11, 15, 16 as water, (Water, savanna, grassland, wetland, snow, barren) clh = 0.0; // evergreen, evergreen, urban if(z == 1 || z == 2 || z == 13) clh = 20.0; // deciduous, deciduous, mixed if(z==3 || z==4 || z==5) clh = 15.0; // woody shrublands & savannas if(z==6 || z==8) clh = 4.0; // shurblands, savannas, croplands... if(z==7 || z==9 || z==10 || z==12 || z==14) clh = 2.0; if(clh>1){ xOffset=x*cellsize; // 12 deg wide yOffset=y*cellsize; // 16 deg high // make all longitudes positive if(xll+xOffset>0){ lon=360-(xll+xOffset); }else{ lon=(xll+xOffset)*-1; } lat = yll+yOffset; // bounding box if(lat > tx.lat - radius && lat < tx.lat + radius && lon > tx.lon - radius && lon < tx.lon + radius){ // not in near field if((lat > tx.lat+cellsize2 || lat < tx.lat-cellsize2) || (lon > tx.lon + cellsize2 || lon < tx.lon - cellsize2)){ AddElevation(lat,lon,clh,3); } } } x++; pch = strtok(NULL, " "); }//while } else { fprintf(stderr, "Clutter error @ x %d y %d\n", x, y); }//if }//for } fclose(fd); return 0; } void readLIDAR(FILE *fd, int h, int w, int indx,double n, double e, double s, double west) { int x = 0, y = 0, reads = 0, a=0, b=0, avg=0, tWidth = 0, tHeight = 0; char line[25000]; char *pch; dem[indx].max_north=n; dem[indx].min_west=e; dem[indx].min_north=s; dem[indx].max_west=west; if (max_north == -90) max_north = dem[indx].max_north; else if (dem[indx].max_north > max_north) max_north = dem[indx].max_north; if (min_north == 90) min_north = dem[indx].min_north; else if (dem[indx].min_north < min_north) min_north = dem[indx].min_north; if (dem[indx].max_west > max_west) max_west = dem[indx].max_west; if (dem[indx].min_west < min_west) min_west = dem[indx].min_west; if (max_west == -1) { max_west = dem[indx].max_west; } else { if (abs(dem[indx].max_west - max_west) < 180) { if (dem[indx].max_west > max_west) max_west = dem[indx].max_west; } else { if (dem[indx].max_west < max_west) max_west = dem[indx].max_west; } } if (min_west == 360) { min_west = dem[indx].min_west; } else { if (fabs(dem[indx].min_west - min_west) < 180.0) { if (dem[indx].min_west < min_west) min_west = dem[indx].min_west; } else { if (dem[indx].min_west > min_west) min_west = dem[indx].min_west; } } for (y = h-1; y > -1; y--) { x = w-1; if (fgets(line, 25000, fd) != NULL) { pch = strtok(line, " "); // split line into values while (pch != NULL && x > -1) { if (atoi(pch) <= -9999) pch = "0"; dem[indx].data[y][x] = atoi(pch); dem[indx].signal[x][y] = 0; dem[indx].mask[x][y] = 0; if (atoi(pch) > dem[indx].max_el) { dem[indx].max_el = atoi(pch); max_elevation = atoi(pch); } if (atoi(pch) < dem[indx].min_el) { dem[indx].min_el = atoi(pch); min_elevation = dem[indx].min_el; } x--; pch = strtok(NULL, " "); }//while } else { fprintf(stderr, "LIDAR error @ x %d y %d indx %d\n", x, y, indx); }//if }//for } int loadLIDAR(char *filenames) { char *filename; char *files[100]; // 10x10 tiles int x, y, indx = 0, fc = 0, hoffset = 0, voffset = 0, pos, dem_alloced = 0; double xll, yll, xur, yur, cellsize, avgCellsize; char found, free_page = 0, jline[20], lid_file[255], path_plus_name[255], *junk = NULL; char line[25000]; char * pch; double TO_DEG = (180 / PI); FILE *fd; // test for multiple files filename = strtok(filenames, " ,"); while (filename != NULL) { files[fc] = filename; filename = strtok(NULL, " ,"); fc++; } while (indx < fc) { fd = fopen(files[indx], "rb"); if (fd != NULL) { if (fgets(line, 255, fd) != NULL) { pch = strtok (line," "); pch = strtok (NULL, " "); width = atoi(pch); // ncols if (debug) { fprintf(stderr, "Loading \"%s\" into page %d with width %d...\n", files[indx], indx, width); fflush(stderr); } if (fgets(line, 255, fd) != NULL) height = atoi(pch); // nrows if (!dem_alloced) { //Reduce MAXPAGES to increase speed MAXPAGES=fc; if(width>height){ IPPD = width; }else{ IPPD = height; } // add fudge as reprojected tiles sometimes vary by a pixel or ten IPPD+=50; ARRAYSIZE = (MAXPAGES * IPPD)+50; do_allocs(); dem_alloced = 1; } } if (fgets(line, 255, fd) != NULL) { sscanf(pch, "%lf", &xll); // xll } if (fgets(line, 255, fd) != NULL) { sscanf(pch, "%lf", &yll); // yll } if (fgets(line, 255, fd) != NULL) sscanf(pch, "%lf", &cellsize); avgCellsize=avgCellsize+cellsize; /*if(cellsize>=0.5){ // 50cm LIDAR? // compute xur and yur with inverse haversine if cellsize in *metres* double roundDistance = (width*cellsize)/6371000; yur = asin(sin(yll*DEG2RAD) * cos(roundDistance) + cos(yll * DEG2RAD) * sin(roundDistance) * cos(0)) * TO_DEG; xur = ((xll*DEG2RAD) + atan2(sin(90*DEG2RAD) * sin(roundDistance) * cos(yll*DEG2RAD), cos(roundDistance) - sin(yll * DEG2RAD) * sin(yur*DEG2RAD))) * TO_DEG; }else{*/ // Degrees with GDAL option: -co "FORCE_CELLSIZE=YES" xur = xll+(cellsize*width); yur = yll+(cellsize*height); //} if (xur > eastoffset) eastoffset = xur; if (xll < westoffset) westoffset = xll; if (debug) fprintf(stderr,"%d, %d, %.7f, %.7f, %.7f, %.7f, %.7f\n",width,height,xll,yll,cellsize,yur,xur); // Greenwich straddling hack if (xll <= 0 && xur > 0) { xll = (xur - xll); // full width xur = 0.0; // budge it along so it's west of greenwich delta = eastoffset; // add to Tx longitude later } else { // Transform WGS84 longitudes into 'west' values as society finishes east of Greenwich ;) if (xll >= 0) xll = 360-xll; if(xur >= 0) xur = 360-xur; if(xll < 0) xll = xll * -1; if(xur < 0) xur = xur * -1; } if (debug) fprintf(stderr, "POST yll %.7f yur %.7f xur %.7f xll %.7f delta %.6f\n", yll, yur, xur, xll, delta); fgets(line, 255, fd); // NODATA pos = ftell(fd); // tile 0 [x| ] if (debug) fprintf(stderr, "readLIDAR(fd,%d,%d,%d,%.4f,%.4f,%.4f,%.4f)\n", height, width, indx, yur, xur, yll, xll); readLIDAR(fd, height, width, indx, yur, xur, yll, xll); fclose(fd); if (debug) fprintf(stderr, "LIDAR LOADED %d x %d\n", width, height); } else { return -1; } indx++; } // filename(s) IPPD=width; ippd=IPPD; height = (unsigned)((max_north-min_north) / cellsize); width = (unsigned)((max_west-min_west) / cellsize); if (debug) fprintf(stderr, "fc %d WIDTH %d HEIGHT %d ippd %d minN %.5f maxN %.5f minW %.5f maxW %.5f avgCellsize %.5f\n", fc, width, height, ippd,min_north,max_north,min_west,max_west,avgCellsize); return 0; } int LoadSDF_SDF(char *name) { /* This function reads uncompressed ss Data Files (.sdf) containing digital elevation model data into memory. Elevation data, maximum and minimum elevations, and quadrangle limits are stored in the first available dem[] structure. */ int x, y, data = 0, indx, minlat, minlon, maxlat, maxlon, j; char found, free_page = 0, line[20], jline[20], sdf_file[255], path_plus_name[255], *junk = NULL; FILE *fd; for (x = 0; name[x] != '.' && name[x] != 0 && x < 250; x++) sdf_file[x] = name[x]; sdf_file[x] = 0; /* Parse filename for minimum latitude and longitude values */ sscanf(sdf_file, "%d:%d:%d:%d", &minlat, &maxlat, &minlon, &maxlon); sdf_file[x] = '.'; sdf_file[x + 1] = 's'; sdf_file[x + 2] = 'd'; sdf_file[x + 3] = 'f'; sdf_file[x + 4] = 0; /* Is it already in memory? */ for (indx = 0, found = 0; indx < MAXPAGES && found == 0; indx++) { if (minlat == dem[indx].min_north && minlon == dem[indx].min_west && maxlat == dem[indx].max_north && maxlon == dem[indx].max_west) found = 1; } /* Is room available to load it? */ if (found == 0) { for (indx = 0, free_page = 0; indx < MAXPAGES && free_page == 0; indx++) if (dem[indx].max_north == -90) free_page = 1; } indx--; if (free_page && found == 0 && indx >= 0 && indx < MAXPAGES) { /* Search for SDF file in current working directory first */ strncpy(path_plus_name, sdf_file, 255); fd = fopen(path_plus_name, "rb"); if (fd == NULL) { /* Next, try loading SDF file from path specified in $HOME/.ss_path file or by -d argument */ strncpy(path_plus_name, sdf_path, 255); strncat(path_plus_name, sdf_file, 255); fd = fopen(path_plus_name, "rb"); } if (fd != NULL) { if (debug == 1) { fprintf(stderr, "Loading \"%s\" into page %d...", path_plus_name, indx + 1); fflush(stderr); } if (fgets(line, 19, fd) != NULL) { sscanf(line, "%f", &dem[indx].max_west); } if (fgets(line, 19, fd) != NULL) { sscanf(line, "%f", &dem[indx].min_north); } if (fgets(line, 19, fd) != NULL) { sscanf(line, "%f", &dem[indx].min_west); } if (fgets(line, 19, fd) != NULL) { sscanf(line, "%f", &dem[indx].max_north); } /* Here X lines of DEM will be read until IPPD is reached. Each .sdf tile contains 1200x1200 = 1.44M 'points' Each point is sampled for 1200 resolution! */ for (x = 0; x < ippd; x++) { for (y = 0; y < ippd; y++) { for (j = 0; j < jgets; j++) { junk = fgets(jline, 19, fd); } if (fgets(line, 19, fd) != NULL) { data = atoi(line); } dem[indx].data[x][y] = data; dem[indx].signal[x][y] = 0; dem[indx].mask[x][y] = 0; if (data > dem[indx].max_el) dem[indx].max_el = data; if (data < dem[indx].min_el) dem[indx].min_el = data; } if (ippd == 600) { for (j = 0; j < IPPD; j++) { junk = fgets(jline, 19, fd); } } if (ippd == 300) { for (j = 0; j < IPPD; j++) { junk = fgets(jline, 19, fd); junk = fgets(jline, 19, fd); junk = fgets(jline, 19, fd); } } } fclose(fd); if (dem[indx].min_el < min_elevation) min_elevation = dem[indx].min_el; if (dem[indx].max_el > max_elevation) max_elevation = dem[indx].max_el; if (max_north == -90) max_north = dem[indx].max_north; else if (dem[indx].max_north > max_north) max_north = dem[indx].max_north; if (min_north == 90) min_north = dem[indx].min_north; else if (dem[indx].min_north < min_north) min_north = dem[indx].min_north; if (max_west == -1) max_west = dem[indx].max_west; else { if (abs(dem[indx].max_west - max_west) < 180) { if (dem[indx].max_west > max_west) max_west = dem[indx].max_west; } else { if (dem[indx].max_west < max_west) max_west = dem[indx].max_west; } } if (min_west == 360) min_west = dem[indx].min_west; else { if (fabs(dem[indx].min_west - min_west) < 180.0) { if (dem[indx].min_west < min_west) min_west = dem[indx].min_west; } else { if (dem[indx].min_west > min_west) min_west = dem[indx].min_west; } } return 1; } else return -1; } else return 0; } char LoadSDF(char *name) { /* This function loads the requested SDF file from the filesystem. It first tries to invoke the LoadSDF_SDF() function to load an uncompressed SDF file (since uncompressed files load slightly faster). If that attempt fails, then it tries to load a compressed SDF file by invoking the LoadSDF_BZ() function. If that fails, then we can assume that no elevation data exists for the region requested, and that the region requested must be entirely over water. */ int x, y, indx, minlat, minlon, maxlat, maxlon; char found, free_page = 0; int return_value = -1; return_value = LoadSDF_SDF(name); /* If neither format can be found, then assume the area is water. */ if (return_value == 0 || return_value == -1) { sscanf(name, "%d:%d:%d:%d", &minlat, &maxlat, &minlon, &maxlon); /* Is it already in memory? */ for (indx = 0, found = 0; indx < MAXPAGES && found == 0; indx++) { if (minlat == dem[indx].min_north && minlon == dem[indx].min_west && maxlat == dem[indx].max_north && maxlon == dem[indx].max_west) found = 1; } /* Is room available to load it? */ if (found == 0) { for (indx = 0, free_page = 0; indx < MAXPAGES && free_page == 0; indx++) if (dem[indx].max_north == -90) free_page = 1; } indx--; if (free_page && found == 0 && indx >= 0 && indx < MAXPAGES) { if (debug == 1) { fprintf(stderr, "Region \"%s\" assumed as sea-level into page %d...\n", name, indx + 1); fflush(stderr); } dem[indx].max_west = maxlon; dem[indx].min_north = minlat; dem[indx].min_west = minlon; dem[indx].max_north = maxlat; /* Fill DEM with sea-level topography */ for (x = 0; x < ippd; x++) for (y = 0; y < ippd; y++) { dem[indx].data[x][y] = 0; dem[indx].signal[x][y] = 0; dem[indx].mask[x][y] = 0; if (dem[indx].min_el > 0) dem[indx].min_el = 0; } if (dem[indx].min_el < min_elevation) min_elevation = dem[indx].min_el; if (dem[indx].max_el > max_elevation) max_elevation = dem[indx].max_el; if (max_north == -90) max_north = dem[indx].max_north; else if (dem[indx].max_north > max_north) max_north = dem[indx].max_north; if (min_north == 90) min_north = dem[indx].min_north; else if (dem[indx].min_north < min_north) min_north = dem[indx].min_north; if (max_west == -1) max_west = dem[indx].max_west; else { if (abs(dem[indx].max_west - max_west) < 180) { if (dem[indx].max_west > max_west) max_west = dem[indx].max_west; } else { if (dem[indx].max_west < max_west) max_west = dem[indx].max_west; } } if (min_west == 360) min_west = dem[indx].min_west; else { if (abs(dem[indx].min_west - min_west) < 180) { if (dem[indx].min_west < min_west) min_west = dem[indx].min_west; } else { if (dem[indx].min_west > min_west) min_west = dem[indx].min_west; } } return_value = 1; } } return return_value; } void LoadPAT(char *filename) { /* This function reads and processes antenna pattern (.az and .el) files that correspond in name to previously loaded ss .lrp files. */ int a, b, w, x, y, z, last_index, next_index, span; char string[255], azfile[255], elfile[255], *pointer = NULL; float az, xx, elevation, amplitude, rotation, valid1, valid2, delta, azimuth[361], azimuth_pattern[361], el_pattern[10001], elevation_pattern[361][1001], slant_angle[361], tilt, mechanical_tilt = 0.0, tilt_azimuth, tilt_increment, sum; FILE *fd = NULL; unsigned char read_count[10001]; for (x = 0; filename[x] != '.' && filename[x] != 0 && x < 250; x++) { azfile[x] = filename[x]; elfile[x] = filename[x]; } azfile[x] = '.'; azfile[x + 1] = 'a'; azfile[x + 2] = 'z'; azfile[x + 3] = 0; elfile[x] = '.'; elfile[x + 1] = 'e'; elfile[x + 2] = 'l'; elfile[x + 3] = 0; rotation = 0.0; got_azimuth_pattern = 0; got_elevation_pattern = 0; /* Load .az antenna pattern file */ fd = fopen(azfile, "r"); if (fd != NULL) { /* Clear azimuth pattern array */ for (x = 0; x <= 360; x++) { azimuth[x] = 0.0; read_count[x] = 0; } /* Read azimuth pattern rotation in degrees measured clockwise from true North. */ if (fgets(string, 254, fd) == NULL) { //fprintf(stderr,"Azimuth read error\n"); //exit(0); } pointer = strchr(string, ';'); if (pointer != NULL) *pointer = 0; sscanf(string, "%f", &rotation); /* Read azimuth (degrees) and corresponding normalized field radiation pattern amplitude (0.0 to 1.0) until EOF is reached. */ if (fgets(string, 254, fd) == NULL) { //fprintf(stderr,"Azimuth read error\n"); //exit(0); } pointer = strchr(string, ';'); if (pointer != NULL) *pointer = 0; sscanf(string, "%f %f", &az, &litude); do { x = (int)rintf(az); if (x >= 0 && x <= 360 && fd != NULL) { azimuth[x] += amplitude; read_count[x]++; } if (fgets(string, 254, fd) == NULL) { //fprintf(stderr,"Azimuth read error\n"); // exit(0); } pointer = strchr(string, ';'); if (pointer != NULL) *pointer = 0; sscanf(string, "%f %f", &az, &litude); } while (feof(fd) == 0); fclose(fd); /* Handle 0=360 degree ambiguity */ if ((read_count[0] == 0) && (read_count[360] != 0)) { read_count[0] = read_count[360]; azimuth[0] = azimuth[360]; } if ((read_count[0] != 0) && (read_count[360] == 0)) { read_count[360] = read_count[0]; azimuth[360] = azimuth[0]; } /* Average pattern values in case more than one was read for each degree of azimuth. */ for (x = 0; x <= 360; x++) { if (read_count[x] > 1) azimuth[x] /= (float)read_count[x]; } /* Interpolate missing azimuths to completely fill the array */ last_index = -1; next_index = -1; for (x = 0; x <= 360; x++) { if (read_count[x] != 0) { if (last_index == -1) last_index = x; else next_index = x; } if (last_index != -1 && next_index != -1) { valid1 = azimuth[last_index]; valid2 = azimuth[next_index]; span = next_index - last_index; delta = (valid2 - valid1) / (float)span; for (y = last_index + 1; y < next_index; y++) azimuth[y] = azimuth[y - 1] + delta; last_index = y; next_index = -1; } } /* Perform azimuth pattern rotation and load azimuth_pattern[361] with azimuth pattern data in its final form. */ for (x = 0; x < 360; x++) { y = x + (int)rintf(rotation); if (y >= 360) y -= 360; azimuth_pattern[y] = azimuth[x]; } azimuth_pattern[360] = azimuth_pattern[0]; got_azimuth_pattern = 255; } /* Read and process .el file */ fd = fopen(elfile, "r"); if (fd != NULL) { for (x = 0; x <= 10000; x++) { el_pattern[x] = 0.0; read_count[x] = 0; } /* Read mechanical tilt (degrees) and tilt azimuth in degrees measured clockwise from true North. */ if (fgets(string, 254, fd) == NULL) { //fprintf(stderr,"Tilt read error\n"); //exit(0); } pointer = strchr(string, ';'); if (pointer != NULL) *pointer = 0; sscanf(string, "%f %f", &mechanical_tilt, &tilt_azimuth); /* Read elevation (degrees) and corresponding normalized field radiation pattern amplitude (0.0 to 1.0) until EOF is reached. */ if (fgets(string, 254, fd) == NULL) { //fprintf(stderr,"Ant elevation read error\n"); //exit(0); } pointer = strchr(string, ';'); if (pointer != NULL) *pointer = 0; sscanf(string, "%f %f", &elevation, &litude); while (feof(fd) == 0) { /* Read in normalized radiated field values for every 0.01 degrees of elevation between -10.0 and +90.0 degrees */ x = (int)rintf(100.0 * (elevation + 10.0)); if (x >= 0 && x <= 10000) { el_pattern[x] += amplitude; read_count[x]++; } if (fgets(string, 254, fd) != NULL) { pointer = strchr(string, ';'); } if (pointer != NULL) *pointer = 0; sscanf(string, "%f %f", &elevation, &litude); } fclose(fd); /* Average the field values in case more than one was read for each 0.01 degrees of elevation. */ for (x = 0; x <= 10000; x++) { if (read_count[x] > 1) el_pattern[x] /= (float)read_count[x]; } /* Interpolate between missing elevations (if any) to completely fill the array and provide radiated field values for every 0.01 degrees of elevation. */ last_index = -1; next_index = -1; for (x = 0; x <= 10000; x++) { if (read_count[x] != 0) { if (last_index == -1) last_index = x; else next_index = x; } if (last_index != -1 && next_index != -1) { valid1 = el_pattern[last_index]; valid2 = el_pattern[next_index]; span = next_index - last_index; delta = (valid2 - valid1) / (float)span; for (y = last_index + 1; y < next_index; y++) el_pattern[y] = el_pattern[y - 1] + delta; last_index = y; next_index = -1; } } /* Fill slant_angle[] array with offset angles based on the antenna's mechanical beam tilt (if any) and tilt direction (azimuth). */ if (mechanical_tilt == 0.0) { for (x = 0; x <= 360; x++) slant_angle[x] = 0.0; } else { tilt_increment = mechanical_tilt / 90.0; for (x = 0; x <= 360; x++) { xx = (float)x; y = (int)rintf(tilt_azimuth + xx); while (y >= 360) y -= 360; while (y < 0) y += 360; if (x <= 180) slant_angle[y] = -(tilt_increment * (90.0 - xx)); if (x > 180) slant_angle[y] = -(tilt_increment * (xx - 270.0)); } } slant_angle[360] = slant_angle[0]; /* 360 degree wrap-around */ for (w = 0; w <= 360; w++) { tilt = slant_angle[w]; /** Convert tilt angle to an array index offset **/ y = (int)rintf(100.0 * tilt); /* Copy shifted el_pattern[10001] field values into elevation_pattern[361][1001] at the corresponding azimuth, downsampling (averaging) along the way in chunks of 10. */ for (x = y, z = 0; z <= 1000; x += 10, z++) { for (sum = 0.0, a = 0; a < 10; a++) { b = a + x; if (b >= 0 && b <= 10000) sum += el_pattern[b]; if (b < 0) sum += el_pattern[0]; if (b > 10000) sum += el_pattern[10000]; } elevation_pattern[w][z] = sum / 10.0; } } got_elevation_pattern = 255; } for (x = 0; x <= 360; x++) { for (y = 0; y <= 1000; y++) { if (got_elevation_pattern) elevation = elevation_pattern[x][y]; else elevation = 1.0; if (got_azimuth_pattern) az = azimuth_pattern[x]; else az = 1.0; LR.antenna_pattern[x][y] = az * elevation; } } } void LoadSignalColors(struct site xmtr) { int x, y, ok, val[4]; char filename[255], string[80], *pointer = NULL, *s = NULL; FILE *fd = NULL; for (x = 0; xmtr.filename[x] != '.' && xmtr.filename[x] != 0 && x < 250; x++) filename[x] = xmtr.filename[x]; filename[x] = '.'; filename[x + 1] = 's'; filename[x + 2] = 'c'; filename[x + 3] = 'f'; filename[x + 4] = 0; /* Default values */ region.level[0] = 128; region.color[0][0] = 255; region.color[0][1] = 0; region.color[0][2] = 0; region.level[1] = 118; region.color[1][0] = 255; region.color[1][1] = 165; region.color[1][2] = 0; region.level[2] = 108; region.color[2][0] = 255; region.color[2][1] = 206; region.color[2][2] = 0; region.level[3] = 98; region.color[3][0] = 255; region.color[3][1] = 255; region.color[3][2] = 0; region.level[4] = 88; region.color[4][0] = 184; region.color[4][1] = 255; region.color[4][2] = 0; region.level[5] = 78; region.color[5][0] = 0; region.color[5][1] = 255; region.color[5][2] = 0; region.level[6] = 68; region.color[6][0] = 0; region.color[6][1] = 208; region.color[6][2] = 0; region.level[7] = 58; region.color[7][0] = 0; region.color[7][1] = 196; region.color[7][2] = 196; region.level[8] = 48; region.color[8][0] = 0; region.color[8][1] = 148; region.color[8][2] = 255; region.level[9] = 38; region.color[9][0] = 80; region.color[9][1] = 80; region.color[9][2] = 255; region.level[10] = 28; region.color[10][0] = 0; region.color[10][1] = 38; region.color[10][2] = 255; region.level[11] = 18; region.color[11][0] = 142; region.color[11][1] = 63; region.color[11][2] = 255; region.level[12] = 8; region.color[12][0] = 140; region.color[12][1] = 0; region.color[12][2] = 128; region.levels = 13; fd = fopen(filename, "r"); if (fd == NULL && xmtr.filename[0] == '\0') /* Don't save if we don't have an output file */ return; if (fd == NULL) { fd = fopen(filename, "w"); for (x = 0; x < region.levels; x++) fprintf(fd, "%3d: %3d, %3d, %3d\n", region.level[x], region.color[x][0], region.color[x][1], region.color[x][2]); fclose(fd); } else { x = 0; s = fgets(string, 80, fd); while (x < 128 && feof(fd) == 0) { pointer = strchr(string, ';'); if (pointer != NULL) *pointer = 0; ok = sscanf(string, "%d: %d, %d, %d", &val[0], &val[1], &val[2], &val[3]); if (ok == 4) { for (y = 0; y < 4; y++) { if (val[y] > 255) val[y] = 255; if (val[y] < 0) val[y] = 0; } region.level[x] = val[0]; region.color[x][0] = val[1]; region.color[x][1] = val[2]; region.color[x][2] = val[3]; x++; } s = fgets(string, 80, fd); } fclose(fd); region.levels = x; } } void LoadLossColors(struct site xmtr) { int x, y, ok, val[4]; char filename[255], string[80], *pointer = NULL, *s = NULL; FILE *fd = NULL; for (x = 0; xmtr.filename[x] != '.' && xmtr.filename[x] != 0 && x < 250; x++) filename[x] = xmtr.filename[x]; filename[x] = '.'; filename[x + 1] = 'l'; filename[x + 2] = 'c'; filename[x + 3] = 'f'; filename[x + 4] = 0; /* Default values */ region.level[0] = 80; region.color[0][0] = 255; region.color[0][1] = 0; region.color[0][2] = 0; region.level[1] = 90; region.color[1][0] = 255; region.color[1][1] = 128; region.color[1][2] = 0; region.level[2] = 100; region.color[2][0] = 255; region.color[2][1] = 165; region.color[2][2] = 0; region.level[3] = 110; region.color[3][0] = 255; region.color[3][1] = 206; region.color[3][2] = 0; region.level[4] = 120; region.color[4][0] = 255; region.color[4][1] = 255; region.color[4][2] = 0; region.level[5] = 130; region.color[5][0] = 184; region.color[5][1] = 255; region.color[5][2] = 0; region.level[6] = 140; region.color[6][0] = 0; region.color[6][1] = 255; region.color[6][2] = 0; region.level[7] = 150; region.color[7][0] = 0; region.color[7][1] = 208; region.color[7][2] = 0; region.level[8] = 160; region.color[8][0] = 0; region.color[8][1] = 196; region.color[8][2] = 196; region.level[9] = 170; region.color[9][0] = 0; region.color[9][1] = 148; region.color[9][2] = 255; region.level[10] = 180; region.color[10][0] = 80; region.color[10][1] = 80; region.color[10][2] = 255; region.level[11] = 190; region.color[11][0] = 0; region.color[11][1] = 38; region.color[11][2] = 255; region.level[12] = 200; region.color[12][0] = 142; region.color[12][1] = 63; region.color[12][2] = 255; region.level[13] = 210; region.color[13][0] = 196; region.color[13][1] = 54; region.color[13][2] = 255; region.level[14] = 220; region.color[14][0] = 255; region.color[14][1] = 0; region.color[14][2] = 255; region.level[15] = 230; region.color[15][0] = 255; region.color[15][1] = 194; region.color[15][2] = 204; region.levels = 16; fd = fopen(filename, "r"); if (fd == NULL && xmtr.filename[0] == '\0') /* Don't save if we don't have an output file */ return; if (fd == NULL) { fd = fopen(filename, "w"); for (x = 0; x < region.levels; x++) fprintf(fd, "%3d: %3d, %3d, %3d\n", region.level[x], region.color[x][0], region.color[x][1], region.color[x][2]); fclose(fd); } else { x = 0; s = fgets(string, 80, fd); while (x < 128 && feof(fd) == 0) { pointer = strchr(string, ';'); if (pointer != NULL) *pointer = 0; ok = sscanf(string, "%d: %d, %d, %d", &val[0], &val[1], &val[2], &val[3]); if (ok == 4) { for (y = 0; y < 4; y++) { if (val[y] > 255) val[y] = 255; if (val[y] < 0) val[y] = 0; } region.level[x] = val[0]; region.color[x][0] = val[1]; region.color[x][1] = val[2]; region.color[x][2] = val[3]; x++; } s = fgets(string, 80, fd); } fclose(fd); region.levels = x; } } void LoadDBMColors(struct site xmtr) { int x, y, ok, val[4]; char filename[255], string[80], *pointer = NULL, *s = NULL; FILE *fd = NULL; for (x = 0; xmtr.filename[x] != '.' && xmtr.filename[x] != 0 && x < 250; x++) filename[x] = xmtr.filename[x]; filename[x] = '.'; filename[x + 1] = 'd'; filename[x + 2] = 'c'; filename[x + 3] = 'f'; filename[x + 4] = 0; /* Default values */ region.level[0] = 0; region.color[0][0] = 255; region.color[0][1] = 0; region.color[0][2] = 0; region.level[1] = -10; region.color[1][0] = 255; region.color[1][1] = 128; region.color[1][2] = 0; region.level[2] = -20; region.color[2][0] = 255; region.color[2][1] = 165; region.color[2][2] = 0; region.level[3] = -30; region.color[3][0] = 255; region.color[3][1] = 206; region.color[3][2] = 0; region.level[4] = -40; region.color[4][0] = 255; region.color[4][1] = 255; region.color[4][2] = 0; region.level[5] = -50; region.color[5][0] = 184; region.color[5][1] = 255; region.color[5][2] = 0; region.level[6] = -60; region.color[6][0] = 0; region.color[6][1] = 255; region.color[6][2] = 0; region.level[7] = -70; region.color[7][0] = 0; region.color[7][1] = 208; region.color[7][2] = 0; region.level[8] = -80; region.color[8][0] = 0; region.color[8][1] = 196; region.color[8][2] = 196; region.level[9] = -90; region.color[9][0] = 0; region.color[9][1] = 148; region.color[9][2] = 255; region.level[10] = -100; region.color[10][0] = 80; region.color[10][1] = 80; region.color[10][2] = 255; region.level[11] = -110; region.color[11][0] = 0; region.color[11][1] = 38; region.color[11][2] = 255; region.level[12] = -120; region.color[12][0] = 142; region.color[12][1] = 63; region.color[12][2] = 255; region.level[13] = -130; region.color[13][0] = 196; region.color[13][1] = 54; region.color[13][2] = 255; region.level[14] = -140; region.color[14][0] = 255; region.color[14][1] = 0; region.color[14][2] = 255; region.level[15] = -150; region.color[15][0] = 255; region.color[15][1] = 194; region.color[15][2] = 204; region.levels = 16; fd = fopen(filename, "r"); if (fd == NULL && xmtr.filename[0] == '\0') /* Don't save if we don't have an output file */ return; if (fd == NULL) { fd = fopen(filename, "w"); for (x = 0; x < region.levels; x++) fprintf(fd, "%+4d: %3d, %3d, %3d\n", region.level[x], region.color[x][0], region.color[x][1], region.color[x][2]); fclose(fd); } else { x = 0; s = fgets(string, 80, fd); while (x < 128 && feof(fd) == 0) { pointer = strchr(string, ';'); if (pointer != NULL) *pointer = 0; ok = sscanf(string, "%d: %d, %d, %d", &val[0], &val[1], &val[2], &val[3]); if (ok == 4) { if (val[0] < -200) val[0] = -200; if (val[0] > +40) val[0] = +40; region.level[x] = val[0]; for (y = 1; y < 4; y++) { if (val[y] > 255) val[y] = 255; if (val[y] < 0) val[y] = 0; } region.color[x][0] = val[1]; region.color[x][1] = val[2]; region.color[x][2] = val[3]; x++; } s = fgets(string, 80, fd); } fclose(fd); region.levels = x; } } void LoadTopoData(int max_lon, int min_lon, int max_lat, int min_lat) { /* This function loads the SDF files required to cover the limits of the region specified. */ int x, y, width, ymin, ymax; width = ReduceAngle(max_lon - min_lon); if ((max_lon - min_lon) <= 180.0) { for (y = 0; y <= width; y++) for (x = min_lat; x <= max_lat; x++) { ymin = (int)(min_lon + (double)y); while (ymin < 0) ymin += 360; while (ymin >= 360) ymin -= 360; ymax = ymin + 1; while (ymax < 0) ymax += 360; while (ymax >= 360) ymax -= 360; if (ippd == 3600) snprintf(string, 19, "%d:%d:%d:%d-hd", x, x + 1, ymin, ymax); else snprintf(string, 16, "%d:%d:%d:%d", x, x + 1, ymin, ymax); LoadSDF(string); } } else { for (y = 0; y <= width; y++) for (x = min_lat; x <= max_lat; x++) { ymin = max_lon + y; while (ymin < 0) ymin += 360; while (ymin >= 360) ymin -= 360; ymax = ymin + 1; while (ymax < 0) ymax += 360; while (ymax >= 360) ymax -= 360; if (ippd == 3600) snprintf(string, 19, "%d:%d:%d:%d-hd", x, x + 1, ymin, ymax); else snprintf(string, 16, "%d:%d:%d:%d", x, x + 1, ymin, ymax); LoadSDF(string); } } } void LoadUDT(char *filename) { /* This function reads a file containing User-Defined Terrain features for their addition to the digital elevation model data used by SPLAT!. Elevations in the UDT file are evaluated and then copied into a temporary file under /tmp. Then the contents of the temp file are scanned, and if found to be unique, are added to the ground elevations described by the digital elevation data already loaded into memory. */ int i, x, y, z, ypix, xpix, tempxpix, tempypix, fd = 0, n = 0; char input[80], str[3][80], tempname[15], *pointer = NULL, *s = NULL; double latitude, longitude, height, tempheight; FILE *fd1 = NULL, *fd2 = NULL; strcpy(tempname, "/tmp/XXXXXX\0"); fd1 = fopen(filename, "r"); if (fd1 != NULL) { fd = mkstemp(tempname); fd2 = fopen(tempname, "w"); s = fgets(input, 78, fd1); pointer = strchr(input, ';'); if (pointer != NULL) *pointer = 0; while (feof(fd1) == 0) { /* Parse line for latitude, longitude, height */ for (x = 0, y = 0, z = 0; x < 78 && input[x] != 0 && z < 3; x++) { if (input[x] != ',' && y < 78) { str[z][y] = input[x]; y++; } else { str[z][y] = 0; z++; y = 0; } } latitude = ReadBearing(str[0]); longitude = ReadBearing(str[1]); if (longitude < 0.0) longitude += 360; /* Remove and/or from antenna height string */ for (i = 0; str[2][i] != 13 && str[2][i] != 10 && str[2][i] != 0; i++) ; str[2][i] = 0; /* The terrain feature may be expressed in either feet or meters. If the letter 'M' or 'm' is discovered in the string, then this is an indication that the value given is expressed in meters. Otherwise the height is interpreted as being expressed in feet. */ for (i = 0; str[2][i] != 'M' && str[2][i] != 'm' && str[2][i] != 0 && i < 48; i++) ; if (str[2][i] == 'M' || str[2][i] == 'm') { str[2][i] = 0; height = rint(atof(str[2])); } else { str[2][i] = 0; height = rint(METERS_PER_FOOT * atof(str[2])); } if (height > 0.0) fprintf(fd2, "%d, %d, %f\n", (int)rint(latitude / dpp), (int)rint(longitude / dpp), height); s = fgets(input, 78, fd1); pointer = strchr(input, ';'); if (pointer != NULL) *pointer = 0; } fclose(fd1); fclose(fd2); close(fd); fd1 = fopen(tempname, "r"); fd2 = fopen(tempname, "r"); y = 0; n = fscanf(fd1, "%d, %d, %lf", &xpix, &ypix, &height); do { x = 0; z = 0; n = fscanf(fd2, "%d, %d, %lf", &tempxpix, &tempypix, &tempheight); do { if (x > y && xpix == tempxpix && ypix == tempypix) { z = 1; /* Dupe! */ if (tempheight > height) height = tempheight; } else { n = fscanf(fd2, "%d, %d, %lf", &tempxpix, &tempypix, &tempheight); x++; } } while (feof(fd2) == 0 && z == 0); if (z == 0) /* No duplicate found */ //fprintf(stderr,"%lf, %lf \n",xpix*dpp, ypix*dpp); fflush(stderr); AddElevation(xpix * dpp, ypix * dpp, height, 1); fflush(stderr); n = fscanf(fd1, "%d, %d, %lf", &xpix, &ypix, &height); y++; rewind(fd2); } while (feof(fd1) == 0); fclose(fd1); fclose(fd2); unlink(tempname); } }