NASA Ocean Color

ocssw V2022

  
 #include "l1b_viirs_nc.h"
 #include "l1.h"
  
 #include "nc4utils.h"
 #include <libnav.h>
 #include <float.h>
 #include "calibrate_viirs.h"
 #include <math.h>
  
 typedef unsigned short ushort;
  
 /***********************************************************************
                              Calibration
  ***********************************************************************/
 static double ***f_cal_corr = NULL; /* f table correction [band][det][ms] */
  
 /***********************************************************************
                             Initialization
  ***********************************************************************/
 static float *Fobar; // reflectance to radiance conversion factors
 static int extract_pixel_start = 0;
 static int extract_pixel_stop = 0;
  
 /* Variables to load for each input file and group */
 typedef struct {
     size_t index;
     char *name;
 } varlist;
  
 /*----- GEO file -----*/
  
 /* Scan Line attributes, to be read on initialization.
    All values are dimensioned as [number_of_scans]. */
 static const char* SCN_GRP = "scan_line_attributes";
  
 enum scn_var {
     SCN_STIME, /*< double scan_start_time */
     //SCN_ETIME, /*< double scan_end_time   */
     //SCN_MTIME, /*< double ev_mid_time     */
     SCN_MSIDE, /*< ubyte  HAM_side        */
     SCN_MODE, /*< ubyte  sensor_mode     */
     SCN_QUAL, /*< short  scan_quality    */
     NVARS_SCN
 };
 static const varlist VARLIST_SCN[] = {
     { SCN_STIME, "scan_start_time"},
     //{ SCN_ETIME, "scan_end_time"   },
     //{ SCN_MTIME, "ev_mid_time"     },
     { SCN_MSIDE, "HAM_side"},
     { SCN_MODE, "sensor_mode"},
     { SCN_QUAL, "scan_quality"}
 };
 static var_str_nc *scn[NVARS_SCN];
  
 /* Navigation data, to be read on initialization.
    All values are float; dimensioned [number_of_scans,3] except as noted. */
 static const char* NAV_GRP = "navigation_data";
  
 enum nav_var {
     //NAV_QUAT,  /*< att_quat_ev [number_of_scans, quaternion_elements] */
     NAV_ANG, /*< att_ang     */
     NAV_POS, /*< orb_pos_ev  */
     NAV_VEL, /*< orb_vel_ev  */
     //NAV_SOLJ, /*< solar_j2000 */
     //NAV_SOLV, /*< solar_inst  */
     //NAV_SOLD, /*< earth_sun_distance [number_of_scans] */
     //NAV_LUNJ,  /*< lunar_j2000 */
     //NAV_LUNV,  /*< lunar_inst  */
     //NAV_LUND,  /*< earth_moon_distance [number_of_scans] */
     NVARS_NAV
 };
 static const varlist VARLIST_NAV[] = {
     //{ NAV_QUAT, "att_quat_ev"         },
     { NAV_ANG, "att_ang"}, // (roll, pitch, yaw: degrees)
     { NAV_POS, "orb_pos_ev"}, // (ECR: meters)
     { NAV_VEL, "orb_vel_ev"}, // (ECR: meters/second)
     //{ NAV_SOLJ, "solar_j2000"},
     //{ NAV_SOLV, "solar_inst"},
     //{ NAV_SOLD, "earth_sun_distance"}, // AU
     //{ NAV_LUNJ, "lunar_j2000"         },
     //{ NAV_LUNV, "lunar_inst"          },
     //{ NAV_LUND, "earth_moon_distance" }
 };
 static var_str_nc *nav[NVARS_NAV]; /* read on initialization */
  
 /* Geolocation data, to be read line-by-line.
    All values are dimensioned as [number_of_lines, number_of_pixels]. */
 static const char* GEO_GRP = "geolocation_data";
  
 enum geo_var {
     GEO_LAT, /*< float latitude        */
     GEO_LON, /*< float longitude       */
     GEO_HGT, /*< short height         (-> float) */
     //GEO_RNG,     /*< short range          (-> float) */
     GEO_SENA, /*< short sensor_azimuth (-> float) */
     GEO_SENZ, /*< short sensor_zenith  (-> float) */
     GEO_SOLA, /*< short solar_azimuth  (-> float) */
     GEO_SOLZ, /*< short solar_zenith   (-> float) */
     //GEO_MASK,    /*< ubyte land_water_mask */
     GEO_QUAL, /*< ubyte quality_flag    */
     NVARS_GEO
 };
 static const varlist VARLIST_GEO[] = {
     { GEO_LAT, "latitude"},
     { GEO_LON, "longitude"},
     { GEO_HGT, "height"},
     //{ GEO_RNG,  "range"           },
     { GEO_SENA, "sensor_azimuth"},
     { GEO_SENZ, "sensor_zenith"},
     { GEO_SOLA, "solar_azimuth"},
     { GEO_SOLZ, "solar_zenith"},
     //{ GEO_MASK, "land_water_mask" },
     { GEO_QUAL, "quality_flag"}
 };
 static var_str_nc *geo[NVARS_GEO];
  
 /*----- L1B file -----*/
  
 /* Scan Line attributes, to be read on initialization.
    All values are dimensioned as [number_of_scans]. */
 enum l1bscn_var {
     L1BSCN_STIME, /*< double scan_start_time */
     //L1BSCN_ETIME, /*< double scan_end_time   */
     //L1BSCN_MTIME, /*< double ev_mid_time     */
     L1BSCN_MODE, /*< ubyte  scan_state_flags    */
     L1BSCN_QUAL, /*< ubyte  scan_quality_flags  */
     NVARS_L1BSCN
 };
 static const varlist VARLIST_L1BSCN[] = {
     { L1BSCN_STIME, "scan_start_time"},
     //{ L1BSCN_ETIME, "scan_end_time"   },
     //{ L1BSCN_MTIME, "ev_mid_time"     },
     { L1BSCN_MODE, "scan_state_flags"},
     { L1BSCN_QUAL, "scan_quality_flags"}
 };
 static var_str_nc *l1bscn[NVARS_L1BSCN];
  
 /* Radiometric data, to be read line-by-line.
    All values are dimensioned as [number_of_lines, number_of_pixels]. */
 static const char* L1B_GRP = "observation_data";
  
 enum bandtypes {
     RSB, TEB, CIR
 };
  
 static const varlist VARLIST_L1B[] = {
     /*** Reflective Solar Bands (aka VIS/SWIR) ***/
     { RSB, "M01"}, //   410 nm
     { RSB, "M02"}, //   443 nm
     { RSB, "M03"}, //   486 nm (blue)
     { RSB, "M04"}, //   551 nm (green)
     { RSB, "M05"}, //   671 nm (red)
     { RSB, "M06"}, //   745 nm
     { RSB, "M07"}, //   862 nm
     { RSB, "M08"}, //  1238 nm
     { CIR, "M09"}, //  1378 nm (cirrus)
     { RSB, "M10"}, //  1601 nm
     { RSB, "M11"}, //  2257 nm
     /*** Thermal Emissive Bands ***/
     { TEB, "M12"}, //  3700 nm
     { TEB, "M13"}, //  4050 nm
     { TEB, "M14"}, //  8550 nm
     { TEB, "M15"}, // 10763 nm
     { TEB, "M16"} // 12013 nm
 };
 #define MAXBANDS 16
 static var_str_nc *l1b[MAXBANDS]; /* ushort -> float */
 static var_str_nc *l1bq[MAXBANDS]; /* ubyte; name = band+"_quality_flags" */
  
 static float latGeoFillValue = -999.9;
 static float lonGeoFillValue = -999.9;
 static short senzGeoFillValue = -32768;
 static short senaGeoFillValue = -32768;
 static short solzGeoFillValue = -32768;
 static short solaGeoFillValue = -32768;
  
 static float latL2FillValue = -999.0;
 static float lonL2FillValue = -999.0;
 static float senzL2FillValue = -32767;
 static float senaL2FillValue = -32767;
 static float solzL2FillValue = -32767;
 static float solaL2FillValue = -32767;
  
 /*---------------------------------------------------------------------*/
  
 /* Info for any VIIRS input file */
  
 typedef struct {
     int32_t id; /*< NetCDF4 file ID */
     char file[FILENAME_MAX]; /*< file path */
     char title[FILENAME_MAX];
     size_t nscans;
     size_t nlines;
     size_t npixls;
     int orbit_number;
     char start_time[25];
     char end_time[25];
     double *scan_start_time;
 } viirs_file;
  
 void print_viirs_file(const viirs_file info) {
     printf("file:\t%s\n", info.file);
     printf("title:\t%s\n", info.title);
     printf("time range:\t%s %s\n", info.start_time, info.end_time);
     printf("orbit: \t%d\n", info.orbit_number);
     printf("nscans =\t%d\n", (int) info.nscans);
     printf("nlines =\t%d\n", (int) info.nlines);
     printf("npixls =\t%d\n", (int) info.npixls);
 }
  
 int init_viirs_file(const char filename[FILENAME_MAX],
                     viirs_file *info) {
     int32_t grpid, varid, dimid;
     size_t attlen; // text attribute length
     int status;
  
     /* open file */
     bzero(info, sizeof(*info));
     strcpy(info->file, filename);
     status = nc_open(info->file, NC_NOWRITE, &info->id);
     if(status != NC_NOERR) {
         printf("-E- init_viirs_file - Could not open netCDF file \"%s\"\n", info->file);
         exit(EXIT_FAILURE);
     }
     
     
     /* load dimensions */
     nc_inq_dimid(info->id, "number_of_scans", &dimid);
     nc_inq_dimlen(info->id, dimid, &info->nscans);
     nc_inq_dimid(info->id, "number_of_lines", &dimid);
     nc_inq_dimlen(info->id, dimid, &info->nlines);
     nc_inq_dimid(info->id, "number_of_pixels", &dimid);
     nc_inq_dimlen(info->id, dimid, &info->npixls);
  
     /* load global attributes */
     nc_get_att_text(info->id, NC_GLOBAL,
             "title", (char*) &info->title);
     nc_inq_attlen(info->id, NC_GLOBAL, "title", &attlen);
     info->title[attlen] = '\0'; // null terminate
  
     nc_get_att_text(info->id, NC_GLOBAL,
             "time_coverage_start", (char*) &info->start_time);
     nc_inq_attlen(info->id, NC_GLOBAL, "time_coverage_start", &attlen);
     info->start_time[attlen] = '\0';
  
     nc_get_att_text(info->id, NC_GLOBAL,
             "time_coverage_end", (char*) &info->end_time);
     nc_inq_attlen(info->id, NC_GLOBAL, "time_coverage_end", &attlen);
     info->end_time[attlen] = '\0';
  
     // yeah, borrowed this from the example code on UCAR's website...
     nc_type vr_type; /* attribute type */
     size_t vr_len; /* attribute length */
     if ((nc_inq_att(info->id, NC_GLOBAL, "orbit_number", &vr_type, &vr_len) == NC_NOERR)) {
         nc_get_att_int(info->id, NC_GLOBAL,
                 "orbit_number", &info->orbit_number);
     } else {
         nc_get_att_int(info->id, NC_GLOBAL,
                 "OrbitNumber", &info->orbit_number);
     }
  
     if ((nc_inq_att(info->id, NC_GLOBAL, "extract_pixel_start", &vr_type, &vr_len) == NC_NOERR)) {
         nc_get_att_int(info->id, NC_GLOBAL,
                 "extract_pixel_start", &extract_pixel_start);
         extract_pixel_start--; // Attribute is one-based
         nc_get_att_int(info->id, NC_GLOBAL,
                 "extract_pixel_stop", &extract_pixel_stop);
         extract_pixel_stop--; // Attribute is one-based
     }
  
     /* load start time for each scan */
     nc_inq_grp_ncid(info->id, "scan_line_attributes", &grpid);
     nc_inq_varid(grpid, "scan_start_time", &varid);
     TRYMEM(__FILE__, __LINE__,
             (info->scan_start_time = malloc(info->nscans *
                     sizeof(*info->scan_start_time))));
     nc_get_var_double(grpid, varid, info->scan_start_time);
  
     return SUCCESS;
 }
  
 /*---------------------------------------------------------------------*/
  
 /* Info for VIIRS L1B and GEO files */
  
 int init_viirs_l1bfile(viirs_file l1binfo) {
     size_t i;
     const char* title =
             "VIIRS M-band Reflected Solar Band and Thermal Emissive Band Data";
     grp_str_nc file = { 0 };
     char qaname[FILENAME_MAX + 1];
  
     /* Verify file type from global attributes */
     if (strcmp(l1binfo.title, title) != 0) {
         fprintf(stderr,
                 "Input file %s has unexpected product title!\n"
                 "Expected:\t\"%s\"\n"
                 "Actual:  \t\"%s\"\n",
                 l1binfo.file, title, l1binfo.title);
         return -1;
     }
  
     /* Determine file contents */
     file.id = l1binfo.id;
     load_grp_nc(&file);
  
     /* Populate array holding info and data for L1BSCN variables */
     for (i = 0; i < NVARS_L1BSCN; i++) {
         l1bscn[i] = find_var_byname_nc(file, VARLIST_L1BSCN[i].name, SCN_GRP);
         readall_var(l1bscn[i]);
     }
  
     /* For each L1B variable, */
     for (i = 0; i < MAXBANDS; i++) {
  
         /* Populate array holding info for L1B variables */
         l1b[i] = find_var_byname_nc(file, VARLIST_L1B[i].name, L1B_GRP);
         // returns NULL if var not found.
  
         /* also load QA flag info (unscaled) */
         sprintf(qaname, "%s%s", VARLIST_L1B[i].name, "_quality_flags");
         l1bq[i] = find_var_byname_nc(file, qaname, L1B_GRP);
  
     }
  
     /* TO DO: free unused memory allocated to grp_str_nc file. */
     return SUCCESS;
 }
  
 int init_viirs_geofile(viirs_file geoinfo) {
     size_t i;
     const char* title = "VIIRS M-band Geolocation Data";
     grp_str_nc file = { 0 };
  
     /* Verify file type from global attributes */
     if (strcmp(geoinfo.title, title) != 0) {
         fprintf(stderr,
                 "Input file %s has unexpected product title!\n"
                 "Expected:\t\"%s\"\n"
                 "Actual:  \t\"%s\"\n",
                 geoinfo.file, title, geoinfo.title);
         return -1;
     }
  
     /* Determine file contents */
     file.id = geoinfo.id;
     load_grp_nc(&file);
  
     /* Populate array holding info for GEO variables */
     for (i = 0; i < NVARS_GEO; i++) {
         geo[i] = find_var_byname_nc(file, VARLIST_GEO[i].name, GEO_GRP);
     }
  
     TRY_NC(__FILE__, __LINE__,
             nc_get_att_float(geo[GEO_LAT]->grpid, geo[GEO_LAT]->id, "_FillValue", &latGeoFillValue));
     TRY_NC(__FILE__, __LINE__,
             nc_get_att_float(geo[GEO_LON]->grpid, geo[GEO_LON]->id, "_FillValue", &lonGeoFillValue));
     TRY_NC(__FILE__, __LINE__,
             nc_get_att_short(geo[GEO_SENZ]->grpid, geo[GEO_SENZ]->id, "_FillValue", &senzGeoFillValue));
     TRY_NC(__FILE__, __LINE__,
             nc_get_att_short(geo[GEO_SENA]->grpid, geo[GEO_SENA]->id, "_FillValue", &senaGeoFillValue));
     TRY_NC(__FILE__, __LINE__,
             nc_get_att_short(geo[GEO_SOLZ]->grpid, geo[GEO_SOLZ]->id, "_FillValue", &solzGeoFillValue));
     TRY_NC(__FILE__, __LINE__,
             nc_get_att_short(geo[GEO_SOLA]->grpid, geo[GEO_SOLA]->id, "_FillValue", &solaGeoFillValue));
  
     // grab the fill values for L2 products
     int status;
     productInfo_t* info = allocateProductInfo();
     status = findProductInfo("lat", VIIRSN, info);
     if (status)
         latL2FillValue = info->fillValue;
     status = findProductInfo("lon", VIIRSN, info);
     if (status)
         lonL2FillValue = info->fillValue;
     status = findProductInfo("sena", VIIRSN, info);
     if (status)
         senaL2FillValue = info->fillValue;
     status = findProductInfo("senz", VIIRSN, info);
     if (status)
         senzL2FillValue = info->fillValue;
     status = findProductInfo("sola", VIIRSN, info);
     if (status)
         solaL2FillValue = info->fillValue;
     status = findProductInfo("solz", VIIRSN, info);
     if (status)
         solzL2FillValue = info->fillValue;
     freeProductInfo(info);
  
     /* Populate array holding info and data for SCN variables */
     for (i = 0; i < NVARS_SCN; i++) {
         scn[i] = find_var_byname_nc(file, VARLIST_SCN[i].name, SCN_GRP);
         readall_var(scn[i]);
     }
  
     /* Populate array holding info and data for NAV variables */
     for (i = 0; i < NVARS_NAV; i++) {
         nav[i] = find_var_byname_nc(file, VARLIST_NAV[i].name, NAV_GRP);
         if (!nav[i]) {
             char *tmpStr = malloc(strlen(VARLIST_NAV[i].name) + 5);
             sprintf(tmpStr, "%s_mid", VARLIST_NAV[i].name);
             nav[i] = find_var_byname_nc(file, tmpStr, NAV_GRP);
             if (!nav[i]) {
                 printf("-E- init_viirs_geofile - could not find variable %s in the geo file\n", VARLIST_NAV[i].name);
                 exit(EXIT_FAILURE);
             }
             free(tmpStr);
         }
         readall_var(nav[i]);
     }
  
     /* TO DO: free unused memory allocated to grp_str_nc file. */
     return SUCCESS;
 }
  
 /*---------------------------------------------------------------------*/
  
 /* Open and validate L1B and GEO files */
  
 int openl1b_viirs_nc(filehandle *l1file) {
     viirs_file l1binfo, geoinfo;
     int iscan;
  
     // make sure a GEO file was passed in
     if(!l1file->geofile || !l1file->geofile[0]) {
         printf("-E- openl1b_viirs_nc - VIIRS L1B files require a GEO file.\n");
         exit(EXIT_FAILURE);
     }
     
     /*----- Initialize L1B and GEO info -----*/
     init_viirs_file(l1file->name, &l1binfo);
     init_viirs_file(l1file->geofile, &geoinfo);
  
     /*----- Populate filehandle structure -----*/
     l1file->ndets = l1binfo.nlines / l1binfo.nscans;
     l1file->nscan = l1binfo.nlines;
     l1file->npix = l1binfo.npixls;
     l1file->terrain_corrected = 1; // presumed.
     l1file->orbit_number = l1binfo.orbit_number;
     strcpy(l1file->spatialResolution, "750 m");
  
     /*----- Check that input files are compatible -----*/
  
     /* dimensions */
     if (
             (l1binfo.nscans != geoinfo.nscans) ||
             (l1binfo.nlines != geoinfo.nlines) ||
             (l1binfo.npixls != geoinfo.npixls)) {
         fprintf(stderr, "Geometry mismatch!\n");
         fprintf(stderr, "L1B: nscans = %3d, nlines = %4d, npixls = %4d\n",
                 (int) l1binfo.nscans, (int) l1binfo.nlines, (int) l1binfo.npixls);
         fprintf(stderr, "GEO: nscans = %3d, nlines = %4d, npixls = %4d\n",
                 (int) geoinfo.nscans, (int) geoinfo.nlines, (int) geoinfo.npixls);
         return -1;
     }
  
     /* time and orbit */
     if (
             (l1binfo.orbit_number != geoinfo.orbit_number) ||
             (strcmp(l1binfo.start_time, geoinfo.start_time) != 0) ||
             (strcmp(l1binfo.end_time, geoinfo.end_time) != 0)) {
         fprintf(stderr, "Time coverage mismatch!\n");
         fprintf(stderr, "L1B: Orbit %6d, %s - %s\n",
                 l1binfo.orbit_number, l1binfo.start_time, l1binfo.end_time);
         fprintf(stderr, "GEO: Orbit %6d, %s - %s\n",
                 geoinfo.orbit_number, geoinfo.start_time, geoinfo.end_time);
         return -1;
     }
  
     /* scan start times */
     for (iscan = 0; iscan < l1binfo.nscans; iscan++)
         if (fabs(l1binfo.scan_start_time[iscan] -
                 geoinfo.scan_start_time[iscan]) > DBL_EPSILON) {
             fprintf(stderr, "Scan time mismatch!\n");
             fprintf(stderr, "Scan %d\tL1B=%f\tGEO=%f\tdiff=%f\n",
                     iscan,
                     l1binfo.scan_start_time[iscan],
                     geoinfo.scan_start_time[iscan],
                     l1binfo.scan_start_time[iscan] -
                     geoinfo.scan_start_time[iscan]);
             return -1;
         }
  
     /*----- Load L1B and GEO info into global variables -----*/
     init_viirs_l1bfile(l1binfo); // l1b, l1bq
     init_viirs_geofile(geoinfo); // scn, nav, geo
  
     /*----- Ancillary Data -----*/
     // TODO: remove this?
     rdsensorinfo(l1file->sensorID, l1_input->evalmask,
             "Fobar", (void **) &Fobar);
  
     /*----- Calibration LUT -----*/
     if (l1_input->calfile[0]) {
         double grantime = l1binfo.scan_start_time[0]; // granule start time
         grantime -= leapseconds_since_1993(grantime); // convert TAI93 to "UTC93"
         grantime += 1104537600.0; // convert "UTC93" to UTC (1958) (verify)
         grantime *= 1000000.0; // convert to IET
         load_fcal_lut(l1_input->calfile, (int64_t) grantime, &f_cal_corr);
     }
  
     free(l1binfo.scan_start_time); // free memory allocated
     free(geoinfo.scan_start_time); //  by init_viirs_file()
     return SUCCESS;
 }
  
 /***********************************************************************
                               Read Lines
  ***********************************************************************/
  
 int read_var_1line(var_str_nc *var, size_t iline) {
     size_t typesize;
     size_t npixl = 0;
     size_t start[2] = {0, 0}; // assume dims [nline,npixl]
     size_t count[2] = {1, 1};
  
     if (var->ndims == 2) {
  
         /* determine # bytes to read */
         npixl = var->dim[1].len;
         TRY_NC(__FILE__, __LINE__,
                 nc_inq_type(var->id, var->type, NULL, &typesize));
  
         /* allocate one line as needed (first call) */
         if (var->data == NULL) {
             TRYMEM(__FILE__, __LINE__,
                     (var->data = calloc(npixl, typesize)));
             var->dim[0].len = 1; // to represent data stored
         }
         /* read data */
         start[0] = iline; // read one line
         count[1] = npixl; // read all pixels
         TRY_NC(__FILE__, __LINE__,
                 nc_get_vara(var->grpid, var->id, start, count, var->data));
     }
     return npixl;
 }
  
 int scale_short(var_str_nc *var, float* dest) {
     /* cheating here: assume scaling is always short to float. */
  
     size_t ipix;
     size_t npix = var->dim[1].len;
     short tmpval, fillval;
     short minval, maxval;
     float scale, offset;
  
     /* load scaling factors */
     TRY_NC(__FILE__, __LINE__,
             nc_get_att_short(var->grpid, var->id, "_FillValue", &fillval));
     TRY_NC(__FILE__, __LINE__,
             nc_get_att_short(var->grpid, var->id, "valid_min", &minval));
     TRY_NC(__FILE__, __LINE__,
             nc_get_att_short(var->grpid, var->id, "valid_max", &maxval));
     TRY_NC(__FILE__, __LINE__,
             nc_get_att_float(var->grpid, var->id, "scale_factor", &scale));
     TRY_NC(__FILE__, __LINE__,
             nc_get_att_float(var->grpid, var->id, "add_offset", &offset));
  
     for (ipix = 0; ipix < npix; ipix++) {
         tmpval = ((short *) var->data)[ipix];
         if ((tmpval == fillval) ||
                 (tmpval < minval) ||
                 (tmpval > maxval))
             dest[ipix] = (float) tmpval;
         else
             dest[ipix] = scale * (float) tmpval + offset;
     }
  
     return SUCCESS;
 }
  
 int scale_l1bvals(l1str *l1rec) {
  
     uint32_t tmpval, fillval;
     uint32_t minval, maxval;
     float scale, offset;
     double f_corr;
  
     size_t ipb, ipix, npix;
     size_t iband;
     size_t irsb = 0;
     size_t iteb = 0;
     enum bandtypes bandtype;
     //char flag; // ubyte
  
     /* Initializations */
     npix = l1rec->npix;
  
     /* Step through all bands */
     for (iband = 0; iband < MAXBANDS; iband++) {
         bandtype = VARLIST_L1B[iband].index;
  
         if (l1b[iband] == NULL) {
             if (bandtype == TEB) iteb++;
             if (bandtype == RSB) irsb++;
             continue; // skip rest of processing for missing band
         }
  
         TRY_NC(__FILE__, __LINE__,
                 nc_get_att_uint(l1b[iband]->grpid, l1b[iband]->id,
                 "_FillValue", &fillval));
         TRY_NC(__FILE__, __LINE__,
                 nc_get_att_uint(l1b[iband]->grpid, l1b[iband]->id,
                 "valid_min", &minval));
         TRY_NC(__FILE__, __LINE__,
                 nc_get_att_uint(l1b[iband]->grpid, l1b[iband]->id,
                 "valid_max", &maxval));
         TRY_NC(__FILE__, __LINE__,
                 nc_get_att_float(l1b[iband]->grpid, l1b[iband]->id,
                 "scale_factor", &scale));
         TRY_NC(__FILE__, __LINE__,
                 nc_get_att_float(l1b[iband]->grpid, l1b[iband]->id,
                 "add_offset", &offset));
  
         /* get specific f table cal correction  */
         f_corr = (f_cal_corr == NULL) ? 1.0
                 : f_cal_corr[iband][l1rec->detnum][l1rec->mside];
  
         /*** Thermal Emissive Bands ***/
         if (bandtype == TEB) {
             for (ipix = 0; ipix < npix; ipix++) {
                 //ipb = ipix * l1rec->l1file->nbandsir + iteb; // band varies fastest
                 ipb = ipix * NBANDSIR + iteb; // band varies fastest
                 l1rec->Ltir[ipb] = 0; // init to fill value
  
                 /* skip out-of-bounds values */
                 if (strcmp(VARLIST_L1B[iband].name, "M13") == 0) {
                     tmpval = ((uint32_t *) l1b[iband]->data)[ipix];
                 } else {
                     tmpval = ((ushort *) l1b[iband]->data)[ipix];
                 }
                 if ((tmpval == fillval) ||
                         (tmpval < minval) ||
                         (tmpval > maxval))
                     continue;
  
                 /* apply radiance scaling */
                 l1rec->Ltir[ipb] = scale * (float) tmpval + offset;
  
                 /* Convert radiance from W/m^2/um/sr to mW/cm^2/um/sr */
                 l1rec->Ltir[ipb] /= 10.0;
  
                 /* Apply F-factor */
                 l1rec->Ltir[ipb] *= f_corr;
  
             } // ipix
             iteb++;
         } // TEB
  
         /*** Cirrus Band ***/
         else if (bandtype == CIR) {
             for (ipix = 0; ipix < npix; ipix++) {
                 l1rec->rho_cirrus[ipix] = BAD_FLT; // init to fill value
  
                 /* skip out-of-bounds values */
                 tmpval = ((ushort *) l1b[iband]->data)[ipix];
                 if ((tmpval == fillval) ||
                         (tmpval < minval) ||
                         (tmpval > maxval))
                     continue;
  
                 /* apply reflectance scaling */
                 l1rec->rho_cirrus[ipix] = scale * (float) tmpval + offset;
  
                 /* Normalize reflectance by solar zenith angle */
                 l1rec->rho_cirrus[ipix] /= cos(l1rec->solz[ipix] / RADEG);
  
                 /* Apply F-factor */
                 l1rec->rho_cirrus[ipix] *= f_corr;
  
             } // ipix
         } // CIR
  
         /*** Reflective Solar Bands ***/
         else { // if (bandtype == RSB)
  
             l1rec->Fo[irsb] = Fobar[irsb] * l1rec->fsol;
  
             for (ipix = 0; ipix < npix; ipix++) {
                 ipb = ipix * l1rec->l1file->nbands + irsb; // band varies fastest
                 l1rec->Lt[ipb] = BAD_FLT; // init to fill value
  
                 /* skip night data for visible bands */
                 if (l1rec->solz[ipix] > SOLZNIGHT)
                     continue;
  
                 /* skip out-of-bounds values */
                 tmpval = ((ushort *) l1b[iband]->data)[ipix];
                 if ((tmpval == fillval) ||
                         (tmpval < minval) ||
                         (tmpval > maxval))
                     continue;
  
                 /* apply reflectance scaling */
                 l1rec->Lt[ipb] = scale * (float) tmpval + offset;
  
                 /* convert from reflectance to radiance */
                 l1rec->Lt[ipb] *= l1rec->Fo[irsb] / PI;
  
                 /* Apply F-factor */
                 l1rec->Lt[ipb] *= f_corr;
  
                 /* TO DO: flag any suspect values */
                 /* TO DO: flag hilt */
                 //flag = ((char*)l1bq[iband]->data)[ipix];
                 /* if ((flag & 4) && (irsb < 13)) ; */
  
             } // ipix
             irsb++;
         } // RSB
  
     } // iband
  
     return SUCCESS;
 }
  
 int readl1b_viirs_nc(filehandle *l1file,
                      const int32_t iline,
                      l1str *l1rec) {
     float nbytes = l1file->npix * sizeof(float);
     size_t ivar;
     size_t ipix;
     size_t iscan;
     size_t i;
  
     float ang[3]; // degrees
     float pos[3]; // km
     float vel[3]; // km/sec
     float sen_mat[3][3], coeff[10]; // for ocorient & mnorm
     double mnorm[3];
  
     /*----- Basic info -----*/
     //    l1rec->sensorID = l1file->sensorID;
     l1rec->npix = l1file->npix;
     l1rec->detnum = iline % l1file->ndets;
  
     /*----- Scan-line values -----*/
     iscan = iline / l1file->ndets;
  
     /* Scan Start Time */
     double TAI93sec = ((double*) scn[SCN_STIME]->data)[iscan];
     if (TAI93sec < 0.0) {
         l1rec->scantime = BAD_FLT;
     } else {
         l1rec->scantime = tai93_to_unix(TAI93sec);
     }
  
     /* Mirror Side */
     l1rec->mside = (int32_t) ((char*) scn[SCN_MSIDE]->data)[iscan];
  
     /* Earth-sun distance correction for this scan */
     int16_t year, day;
     double dsec;
     unix2yds(l1rec->scantime, &year, &day, &dsec);
     int32_t yr = (int32_t) year;
     int32_t dy = (int32_t) day;
     int32_t msec = (int32_t) (dsec * 1000.0);
     double esdist = esdist_(&yr, &dy, &msec);
     l1rec->fsol = pow(1.0 / esdist, 2);
  
     /* TO DO: check SCN_MODE, SCN_QUAL for both GEO and L1B */
     int8_t scanqual = ((int8_t*) l1bscn[L1BSCN_QUAL]->data)[iscan];
  
     if (scanqual & 1) {
         l1file->sv_with_moon = 1;
     }
  
     /*----- Geolocation swath values -----*/
     for (ivar = 0; ivar < NVARS_GEO; ivar++)
         read_var_1line(geo[ivar], iline);
  
     memcpy(l1rec->lat, geo[GEO_LAT]->data, nbytes);
     memcpy(l1rec->lon, geo[GEO_LON]->data, nbytes);
     scale_short(geo[GEO_HGT], l1rec->height);
     scale_short(geo[GEO_SOLZ], l1rec->solz);
     scale_short(geo[GEO_SOLA], l1rec->sola);
     scale_short(geo[GEO_SENZ], l1rec->senz);
     scale_short(geo[GEO_SENA], l1rec->sena);
  
     /* Load Angles */
     for (i = 0; i < 3; i++) {
         ang[i] = ((float*) nav[NAV_ANG]->data)[iscan * 3 + i]; // degrees
         pos[i] = ((float*) nav[NAV_POS]->data)[iscan * 3 + i] / 1000.; // m   -> km
         vel[i] = ((float*) nav[NAV_VEL]->data)[iscan * 3 + i] / 1000.; // m/s -> km/s
     }
  
     /* Check for non-nominal roll, pitch, or yaw */
     /* badatt = */
     /*     (fabs(ang[0]) > MAX_ATTERR) || */
     /*     (fabs(ang[1]) > MAX_ATTERR) || */
     /*     (fabs(ang[2]) > MAX_ATTERR); */
  
     /* Compute polarization rotation angles */
     ocorient_(pos, vel, ang, sen_mat, coeff);
     for (i = 0; i < 3; i++)
         mnorm[i] = sen_mat[i][0];
     compute_alpha(l1rec->lon, l1rec->lat,
             l1rec->senz, l1rec->sena,
             mnorm, l1rec->npix, l1rec->alpha);
  
     //check for moon in spaceview port
     //l1file->sv_with_moon = 1;  // as in l1_viirs_h5.c
  
     /*----- Radiometric swath values -----*/
     for (ivar = 0; ivar < MAXBANDS; ivar++) {
         if (l1b[ivar] == NULL) continue; // skip missing band
         read_var_1line(l1b[ivar], iline);
         read_var_1line(l1bq[ivar], iline);
     }
     scale_l1bvals(l1rec); // get reflectance & radiance
     radiance2bt(l1rec, -1); // calculate brightness temperature
  
     /*----- Check pixel values -----*/
     for (ipix = 0; ipix < l1rec->npix; ipix++) {
         l1rec->pixnum[ipix] = ipix + extract_pixel_start;
         if (l1rec->scantime < 0)
             l1rec->flags[ipix] |= NAVFAIL;
         if (scanqual & 4)
             l1rec->flags[ipix] |= NAVFAIL;
  
         // 1 Input_invalid
         // 2 Pointing_bad
         // 4 Terrain_bad
         // check for Input_invalid or Pointing_bad (==3)
         if (((unsigned char*) (geo[GEO_QUAL]->data))[ipix] & 3)
             l1rec->flags[ipix] |= NAVFAIL;
  
         // check for Terrain_bad (==4)
         if (((unsigned char*) (geo[GEO_QUAL]->data))[ipix] & 4)
             l1rec->flags[ipix] |= NAVWARN;
  
         flag_bowtie_deleted(l1rec, ipix, extract_pixel_start);
         //l1rec->navwarn[ipix] |= (l1file->sv_with_moon == 1);
  
         // convert the fill values to the proper value
         if (l1rec->lat[ipix] == latGeoFillValue)
             l1rec->lat[ipix] = latL2FillValue;
         if (l1rec->lon[ipix] == lonGeoFillValue)
             l1rec->lon[ipix] = lonL2FillValue;
         if (l1rec->sena[ipix] == senaGeoFillValue)
             l1rec->sena[ipix] = senaL2FillValue;
         if (l1rec->senz[ipix] == senzGeoFillValue)
             l1rec->senz[ipix] = senzL2FillValue;
         if (l1rec->sola[ipix] == solaGeoFillValue)
             l1rec->sola[ipix] = solaL2FillValue;
         if (l1rec->solz[ipix] == solzGeoFillValue)
             l1rec->solz[ipix] = solzL2FillValue;
     }
  
     return SUCCESS;
 }
  
 int readl1b_lonlat_viirs_nc(filehandle *l1file,
                             const int32_t iline,
                             l1str *l1rec) {
     float nbytes = l1file->npix * sizeof(float);
     read_var_1line(geo[GEO_LAT], iline);
     read_var_1line(geo[GEO_LON], iline);
     memcpy(l1rec->lat, geo[GEO_LAT]->data, nbytes);
     memcpy(l1rec->lon, geo[GEO_LON]->data, nbytes);
  
     int ip;
     for (ip = 0; ip < l1rec->npix; ip++) {
         // convert the fill values to the proper value
         if (l1rec->lat[ip] == latGeoFillValue)
             l1rec->lat[ip] = latL2FillValue;
         if (l1rec->lon[ip] == lonGeoFillValue)
             l1rec->lon[ip] = lonL2FillValue;
     }
  
     return SUCCESS;
 }
  
 void flag_bowtie_deleted(l1str *l1rec, size_t ipix, int extract_offset) {
     int pix = ipix + extract_offset;
     if (pix < AGZONE1 || pix >= AGZONE5) {
         if (l1rec->detnum < 2 || l1rec->detnum > 13) {
             l1rec->flags[ipix] |= BOWTIEDEL;
         }
     } else if ((pix >= AGZONE1 && pix < AGZONE2)
             || (pix >= AGZONE4 && pix < AGZONE5)) {
         if (l1rec->detnum == 0 || l1rec->detnum == 15) {
             l1rec->flags[ipix] |= BOWTIEDEL;
         }
     }
 }
  
 /***********************************************************************
                               Cleanup
  ***********************************************************************/
  
 int closel1b_viirs_nc() {
     /* int32_t i; */
  
     /* Free memory allocated for global variables */
     /* for (i = 0; i < NVARS_SCN; i++) */
     /*     free_vars_nc(scn[i],1) ; */
     /* for (i = 0; i < NVARS_NAV; i++) */
     /*     free_vars_nc(nav[i],1) ; */
     /* for (i = 0; i < NVARS_GEO; i++) */
     /*     free_vars_nc(geo[i],1) ; */
     /* for (i = 0; i < NVARS_L1BSCN; i++) */
     /*     free_vars_nc(l1bscn[i],1) ; */
     /* for (i = 0; i < MAXBANDS; i++) { */
     /*     free_vars_nc(l1b[i], 1) ; */
     /*     free_vars_nc(l1bq[i],1) ; */
     /* } */
  
     /* Free any memory allocated for input files */
     /* End NetCDF access */
  
     /* TO DO: make grp_str_nc l1bfile & geofile global?
      Then use free_grp_nc & nc_close.  Won't need free_vars_nc calls above,
      since they point to same var_str_nc memory. */
  
     return SUCCESS;
 }

l1file

int32 l1file(int32 sdfid, int32 *nsamp, int32 *nscans, int16 *dtynum)

Definition: l1stat_chk.c:586

GEO_LON

@ GEO_LON

Definition: l1b_viirs_nc.c:98

l1mapgen.stderr

stderr

Definition: l1mapgen.py:204

dim_str_nc::len

size_t len

Definition: nc4utils.h:44

MDN.parameters.float

float

Definition: parameters.py:23

SUCCESS

#define SUCCESS

Definition: ObpgReadGrid.h:15

varlist::name

char * name

Definition: l1b_viirs_nc.c:33

TRY_NC

#define TRY_NC(file, line, ncstat)

Definition: nc4utils.h:31

freeProductInfo

void freeProductInfo(productInfo_t *info)

Definition: productInfo.cpp:130

day

int32_t day

Definition: atrem_corl1v2.h:308

status

int status

Definition: l1_czcs_hdf.c:32

mnorm

double mnorm[3]

Definition: l1_hmodis_hdf.c:754

readl1b_viirs_nc

int readl1b_viirs_nc(filehandle *l1file, const int32_t iline, l1str *l1rec)

Definition: l1b_viirs_nc.c:724

NBANDSIR

#define NBANDSIR

Definition: filehandle.h:23

viirs_file::title

char title[FILENAME_MAX]

Definition: l1b_viirs_nc.c:197

l1bscn_var

Definition: l1b_viirs_nc.c:127

closel1b_viirs_nc

int closel1b_viirs_nc()

Definition: l1b_viirs_nc.c:899

varlist

Definition: l1b_viirs_nc.c:31

L1BSCN_MODE

@ L1BSCN_MODE

Definition: l1b_viirs_nc.c:131

varlist::index

size_t index

Definition: l1b_viirs_nc.c:32

var_str_nc::grpid

int grpid

Definition: nc4utils.h:55

MDN.setup.name

name

Definition: setup.py:14

NULL

#define NULL

Definition: decode_rs.h:63

calibrate_viirs.h

GEO_SOLA

@ GEO_SOLA

Definition: l1b_viirs_nc.c:103

ocorient_

void ocorient_(float *pos, float *vel, float *att, float(*)[3], float *coef)

viirs_file::file

char file[FILENAME_MAX]

Definition: l1b_viirs_nc.c:196

l1rec

read l1rec

Definition: HOWTO_Add_a_sensor.txt:72

VIIRSN

#define VIIRSN

Definition: sensorDefs.h:23

NAV_ANG

@ NAV_ANG

Definition: l1b_viirs_nc.c:67

GEO_LAT

@ GEO_LAT

Definition: l1b_viirs_nc.c:97

NAV_GRP

#define NAV_GRP

Definition: goci_slot.c:12

nc4utils.h

NVARS_L1BSCN

@ NVARS_L1BSCN

Definition: l1b_viirs_nc.c:133

scale_short

int scale_short(var_str_nc *var, float *dest)

Definition: l1b_viirs_nc.c:545

pos

float32 * pos

Definition: l1_czcs_hdf.c:35

msec

int32 * msec

Definition: l1_czcs_hdf.c:31

scale_l1bvals

int scale_l1bvals(l1str *l1rec)

Definition: l1b_viirs_nc.c:579

esdist_

double esdist_(int32_t *year, int32_t *day, int32_t *msec)

GEO_SOLZ

@ GEO_SOLZ

Definition: l1b_viirs_nc.c:104

viirs_file::end_time

char end_time[25]

Definition: l1b_viirs_nc.c:203

GEO_SENA

@ GEO_SENA

Definition: l1b_viirs_nc.c:101

NAV_POS

@ NAV_POS

Definition: l1b_viirs_nc.c:68

AGZONE5

#define AGZONE5

Definition: l1.h:68

bzero

void bzero()

viirs_file::orbit_number

int orbit_number

Definition: l1b_viirs_nc.c:201

spacetrack_tles.year

year

Definition: spacetrack_tles.py:170

file

no change in intended resolving MODur00064 Corrected handling of bad ephemeris attitude resolving resolving GSFcd00179 Corrected handling of fill values for[Sensor|Solar][Zenith|Azimuth] resolving MODxl01751 Changed to validate LUT version against a value retrieved from the resolving MODxl02056 Changed to calculate Solar Diffuser angles without adjustment for estimated post launch changes in the MODIS orientation relative to incidentally resolving defects MODxl01766 Also resolves MODxl01947 Changed to ignore fill values in SCI_ABNORM and SCI_STATE rather than treating them as resolving MODxl01780 Changed to use spacecraft ancillary data to recognise when the mirror encoder data is being set by side A or side B and to change calculations accordingly This removes the need for seperate LUTs for Side A and Side B data it makes the new LUTs incompatible with older versions of the and vice versa Also resolves MODxl01685 A more robust GRing algorithm is being which will create a non default GRing anytime there s even a single geolocated pixel in a granule Removed obsolete messages from seed file

Definition: HISTORY.txt:413

names::if

character(len=1000) if

Definition: names.f90:13

read_var_1line

int read_var_1line(var_str_nc *var, size_t iline)

Definition: l1b_viirs_nc.c:517

#define PI

Definition: l3_get_org.c:6

var_str_nc::type

nc_type type

Definition: nc4utils.h:58

NVARS_GEO

@ NVARS_GEO

Definition: l1b_viirs_nc.c:107

readl1b_lonlat_viirs_nc

int readl1b_lonlat_viirs_nc(filehandle *l1file, const int32_t iline, l1str *l1rec)

Definition: l1b_viirs_nc.c:860

NVARS_SCN

@ NVARS_SCN

Definition: l1b_viirs_nc.c:49

scn_var

Definition: l1b_viirs_nc.c:42

compute_alpha

void compute_alpha(float lon[], float lat[], float senz[], float sena[], double mnorm[3], int npix, float alpha[])

Definition: compute_alpha.c:8

load_grp_nc

int load_grp_nc(grp_str_nc *grp)

Definition: nc4utils.c:423

var_str_nc::ndims

int ndims

Definition: nc4utils.h:59

CIR

@ CIR

Definition: l1b_viirs_nc.c:149

viirs_file::npixls

size_t npixls

Definition: l1b_viirs_nc.c:200

leapseconds_since_1993

int leapseconds_since_1993(double tai93time)

Definition: leapsecond.c:58

convert2ocrvc.title

title

Definition: convert2ocrvc.py:28

allocateProductInfo

productInfo_t * allocateProductInfo()

Definition: productInfo.cpp:118

tai93_to_unix

double tai93_to_unix(double tai93)

Definition: yds2tai.c:16

GEO_QUAL

@ GEO_QUAL

Definition: l1b_viirs_nc.c:106

var_str_nc::id

int id

Definition: nc4utils.h:56

find_var_byname_nc

var_str_nc * find_var_byname_nc(grp_str_nc nc, const char *varname, const char *grpname)

Definition: nc4utils.c:314

bandtypes

Definition: l1b_viirs_nc.c:148

l1b_viirs_nc.h

color_dtdb.scale

int scale

Definition: color_dtdb.py:459

l1.h

var_str_nc::data

void * data

Definition: nc4utils.h:64

AGZONE4

#define AGZONE4

Definition: l1.h:67

var_str_nc

Definition: nc4utils.h:54

init_viirs_file

int init_viirs_file(const char filename[FILENAME_MAX], viirs_file *info)

Definition: l1b_viirs_nc.c:217

l1_input

l1_input_t * l1_input

Definition: l1_options.c:9

MDN.parameters.dest

dest

Definition: parameters.py:94

RSB

@ RSB

Definition: l1b_viirs_nc.c:149

unix2yds

void unix2yds(double usec, short *year, short *day, double *secs)

viirs_file::nlines

size_t nlines

Definition: l1b_viirs_nc.c:199

filename

char filename[FILENAME_MAX]

Definition: atrem_corl1.h:122

NAV_VEL

@ NAV_VEL

Definition: l1b_viirs_nc.c:69

viirs_file::id

int32_t id

Definition: l1b_viirs_nc.c:195

init_viirs_l1bfile

int init_viirs_l1bfile(viirs_file l1binfo)

Definition: l1b_viirs_nc.c:292

L1BSCN_QUAL

@ L1BSCN_QUAL

Definition: l1b_viirs_nc.c:132

RADEG

#define RADEG

Definition: czcs_ctl_pt.c:5

seadasutils.aquarius_utils.start

start

Definition: aquarius_utils.py:27

data

no change in intended resolving MODur00064 Corrected handling of bad ephemeris attitude data

Definition: HISTORY.txt:356

NVARS_NAV

@ NVARS_NAV

Definition: l1b_viirs_nc.c:76

SCN_STIME

@ SCN_STIME

Definition: l1b_viirs_nc.c:43

SOLZNIGHT

#define SOLZNIGHT

Definition: l1.h:57

findProductInfo

int findProductInfo(const char *productName, int sensorId, productInfo_t *info)

Definition: productInfo.cpp:905

grp_str_nc

Definition: nc4utils.h:67

var_str_nc::dim

dim_str_nc * dim

Definition: nc4utils.h:60

viirs_file

Definition: l1b_viirs_nc.c:194

GEO_SENZ

@ GEO_SENZ

Definition: l1b_viirs_nc.c:102

openl1b_viirs_nc

int openl1b_viirs_nc(filehandle *l1file)

Definition: l1b_viirs_nc.c:426

flag_bowtie_deleted

void flag_bowtie_deleted(l1str *l1rec, size_t ipix, int extract_offset)

Definition: l1b_viirs_nc.c:881

BAD_FLT

#define BAD_FLT

Definition: jplaeriallib.h:19

load_fcal_lut

int load_fcal_lut(char *calfile, int64_t UTC58usec, double ****ftable)

Definition: calibrate_viirs.c:12

TEB

@ TEB

Definition: l1b_viirs_nc.c:149

AGZONE2

#define AGZONE2

Definition: l1.h:65

radiance2bt

void radiance2bt(l1str *l1rec, int resolution)

Definition: brightness.c:170

BOWTIEDEL

#define BOWTIEDEL

Definition: l2_flags.h:39

fabs

#define fabs(a)

Definition: misc.h:93

iscan

int32_t iscan

Definition: l1_hmodis_hdf.c:745

SCN_MODE

@ SCN_MODE

Definition: l1b_viirs_nc.c:47

viirs_file::nscans

size_t nscans

Definition: l1b_viirs_nc.c:198

readall_var

int readall_var(var_str_nc *var)

Definition: nc4utils.c:334

libnav.h

init_viirs_geofile

int init_viirs_geofile(viirs_file geoinfo)

Definition: l1b_viirs_nc.c:336

SCN_MSIDE

@ SCN_MSIDE

Definition: l1b_viirs_nc.c:46

esdist

real *8 function esdist(iyr, iday, msec)

Definition: esdist.f:3

AGZONE1

#define AGZONE1

Definition: l1.h:64

rdsensorinfo

int32_t rdsensorinfo(int32_t, int32_t, const char *, void **)

Definition: rdsensorinfo.c:69

MAXBANDS

#define MAXBANDS

Definition: l1b_viirs_nc.c:172

offset

l2prod offset

Definition: HOWTO_Add_a_product.txt:70

TRYMEM

#define TRYMEM(file, line, memstat)

Definition: l1_hmodis_hdf.c:23

viirs_file::start_time

char start_time[25]

Definition: l1b_viirs_nc.c:202

GEO_HGT

@ GEO_HGT

Definition: l1b_viirs_nc.c:99

nav_var

Definition: l1b_viirs_nc.c:65

NAVWARN

#define NAVWARN

Definition: l2_flags.h:27

int i

Definition: decode_rs.h:71

print_viirs_file

void print_viirs_file(const viirs_file info)

Definition: l1b_viirs_nc.c:207

strcpy

How many dimensions is the output array Default is Not sure if anything above will work correctly strcpy(l2prod->title, "no title yet")

ushort

unsigned short ushort

Definition: l1b_viirs_nc.c:16

npix

int npix

Definition: get_cmp.c:27

geo_var

Definition: l1b_viirs_nc.c:96

L1BSCN_STIME

@ L1BSCN_STIME

Definition: l1b_viirs_nc.c:128

viirs_file::scan_start_time

double * scan_start_time

Definition: l1b_viirs_nc.c:204

SCN_QUAL

@ SCN_QUAL

Definition: l1b_viirs_nc.c:48

NAVFAIL

#define NAVFAIL

Definition: l2_flags.h:36

count

int count

Definition: decode_rs.h:79