/* * (C) Copyright 2005- ECMWF. * * This software is licensed under the terms of the Apache Licence Version 2.0 * which can be obtained at http://www.apache.org/licenses/LICENSE-2.0. * * In applying this licence, ECMWF does not waive the privileges and immunities granted to it by * virtue of its status as an intergovernmental organisation nor does it submit to any jurisdiction. */ /* * * Description: Check the geometry of a global GRIB field * which has a Gaussian Grid (reduced or regular) * */ #include #include #include #include #include "grib_api_internal.h" int exit_on_error = 1; /* By default exit if any check fails */ int verbose = 0; /* By default quiet unless errors */ int error_count = 0; static int DBL_EQUAL(double d1, double d2, double tolerance) { return fabs(d1 - d2) <= tolerance; } static void usage(const char* prog) { printf("Usage: %s [-f] [-v] [-V] grib_file grib_file ...\n\n", prog); printf("Check geometry of GRIB fields with a Gaussian Grid.\n"); printf("(The grid is assumed to be GLOBAL)\n\n"); printf("Options:\n"); printf(" -f Do not exit on first error\n"); printf(" -v Verbose\n"); printf(" -V Print the ecCodes version\n"); printf("\n"); exit(1); } /* Print an error message and optionally die */ static void error(const char* filename, int msg_num, const char* fmt, ...) { char buf[1024] = {0,}; va_list list; va_start(list, fmt); if (verbose) snprintf(buf, sizeof(buf), " Error: %s", fmt); /* indent a bit */ else snprintf(buf, sizeof(buf), "Error: %s #%d: %s", filename, msg_num, fmt); vfprintf(stderr, buf, list); va_end(list); ++error_count; if (exit_on_error) { exit(1); } } static int process_file(const char* filename) { int err = 0, msg_num = 0; grib_handle* h = NULL; FILE* in = NULL; if (!path_is_regular_file(filename)) { if (verbose) printf(" WARNING: '%s' not a regular file! Ignoring\n", filename); return GRIB_IO_PROBLEM; } in = fopen(filename, "r"); if (!in) { fprintf(stderr, "ERROR: unable to open input file '%s'\n", filename); exit(1); } if (verbose) printf("Checking file %s\n", filename); while ((h = grib_handle_new_from_file(0, in, &err)) != NULL) { int is_reduced_gaussian = 0, is_regular_gaussian = 0, grid_ok = 0; long edition = 0, N = 0, Nj = 0, numberOfDataPoints, numberOfValues, angleSubdivisions; size_t len = 0, sizeOfValuesArray = 0; double* lats = NULL; long* pl = NULL; char gridType[128] = {0,}; double angular_tolerance, lat1, lon1, lat2, lon2, expected_lon2; if (err != GRIB_SUCCESS) GRIB_CHECK(err, 0); ++msg_num; GRIB_CHECK(grib_get_long(h, "edition", &edition), 0); len = 32; GRIB_CHECK(grib_get_string(h, "gridType", gridType, &len), 0); is_regular_gaussian = STR_EQUAL(gridType, "regular_gg"); is_reduced_gaussian = STR_EQUAL(gridType, "reduced_gg"); grid_ok = is_regular_gaussian || is_reduced_gaussian; if (!grid_ok) { /*error("ERROR: gridType should be Reduced or Regular Gaussian Grid!\n");*/ if (verbose) printf(" Note: gridType=%s. Not Gaussian so ignoring\n", gridType); grib_handle_delete(h); continue; } if (verbose) printf(" Processing GRIB message #%d (edition=%ld)\n", msg_num, edition); GRIB_CHECK(grib_get_long(h, "N", &N), 0); GRIB_CHECK(grib_get_long(h, "Nj", &Nj), 0); GRIB_CHECK(grib_get_long(h, "numberOfDataPoints", &numberOfDataPoints), 0); GRIB_CHECK(grib_get_long(h, "numberOfValues", &numberOfValues), 0); GRIB_CHECK(grib_get_double(h, "latitudeOfFirstGridPointInDegrees", &lat1), 0); GRIB_CHECK(grib_get_double(h, "longitudeOfFirstGridPointInDegrees", &lon1), 0); GRIB_CHECK(grib_get_double(h, "latitudeOfLastGridPointInDegrees", &lat2), 0); GRIB_CHECK(grib_get_double(h, "longitudeOfLastGridPointInDegrees", &lon2), 0); GRIB_CHECK(grib_get_long(h, "angleSubdivisions", &angleSubdivisions), 0); Assert(angleSubdivisions > 0); angular_tolerance = 1.0/angleSubdivisions; if (N <= 0) { error(filename, msg_num, "N should be > 0\n", N); } if (Nj != 2 * N) { error(filename, msg_num, "Nj is %ld but should be 2*N (%ld)\n", Nj, 2 * N); } if (lon1 != 0) { error(filename, msg_num, "longitudeOfFirstGridPointInDegrees=%f but should be 0\n", lon1); } expected_lon2 = 360.0 - 360.0 / (4 * N); /* Check first and last latitudes */ if (lat1 != -lat2) { error(filename, msg_num, "First latitude must be = last latitude but opposite in sign: lat1=%f, lat2=%f\n", lat1, lat2); } /* Note: grib_get_gaussian_latitudes() assumes the 'lats' array has 2N elements! */ /* So do not allocate Nj */ lats = (double*)malloc(sizeof(double) * 2 * N); GRIB_CHECK(grib_get_gaussian_latitudes(N, lats), 0); if (!DBL_EQUAL(lats[0], lat1, angular_tolerance)) { error(filename, msg_num, "latitudeOfFirstGridPointInDegrees=%f but should be %f\n", lat1, lats[0]); } if (!DBL_EQUAL(lats[Nj - 1], lat2, angular_tolerance)) { error(filename, msg_num, "latitudeOfLastGridPointInDegrees=%f but should be %f\n", lat2, lats[Nj - 1]); } if (is_reduced_gaussian) { int is_missing_Ni = 0, is_missing_Di = 0; long pl_sum = 0, max_pl = 0; size_t i = 0, pl_len = 0; long is_octahedral = 0; long interpretationOfNumberOfPoints = 0; long iDirectionIncrementGiven = 0; is_missing_Ni = grib_is_missing(h, "Ni", &err); Assert(err == GRIB_SUCCESS); is_missing_Di = grib_is_missing(h, "iDirectionIncrement", &err); Assert(err == GRIB_SUCCESS); GRIB_CHECK(grib_get_long(h, "iDirectionIncrementGiven", &iDirectionIncrementGiven), 0); if (iDirectionIncrementGiven) { error(filename, msg_num, "For a reduced grid, iDirectionIncrementGiven should be 0\n"); } if (!is_missing_Ni) { error(filename, msg_num, "For a reduced grid, Ni should be missing\n"); } if (!is_missing_Di) { error(filename, msg_num, "For a reduced grid, iDirectionIncrement should be missing\n"); } GRIB_CHECK(grib_get_size(h, "pl", &pl_len), 0); Assert(pl_len > 0); if (pl_len != (size_t)(2 * N)) { error(filename, msg_num, "Length of pl array is %ld but should be 2*N (%ld)\n", pl_len, 2 * N); } pl = (long*)malloc(pl_len * sizeof(long)); Assert(pl); GRIB_CHECK(grib_get_long_array(h, "pl", pl, &pl_len), 0); max_pl = pl[0]; /* Check pl is symmetric */ for (i = 0; i < pl_len / 2; ++i) { const long pl_start = pl[i]; const long pl_end = pl[pl_len - 1 - i]; if (pl_start != pl_end) { error(filename, msg_num, "pl array is not symmetric: pl[%ld]=%ld, pl[%ld]=%ld\n", i, pl_start, pl_len - 1 - i, pl_end); } } /* Check sum of pl array and total number of points */ for (i = 0; i < pl_len; ++i) { pl_sum += pl[i]; if (pl[i] > max_pl) max_pl = pl[i]; } if (pl_sum != numberOfDataPoints) { error(filename, msg_num, "Sum of pl array %ld does not match numberOfDataPoints %ld\n", pl_sum, numberOfDataPoints); } if (pl_sum != numberOfValues) { error(filename, msg_num, "Sum of pl array %ld does not match numberOfValues %ld\n", pl_sum, numberOfValues); } GRIB_CHECK(grib_get_long(h, "isOctahedral", &is_octahedral), 0); if (is_octahedral) { if (verbose) printf(" This is an Octahedral Gaussian grid\n"); expected_lon2 = 360.0 - 360.0 / max_pl; } free(pl); GRIB_CHECK(grib_get_long(h, "interpretationOfNumberOfPoints", &interpretationOfNumberOfPoints), 0); if (interpretationOfNumberOfPoints != 1) { error(filename, msg_num, "For a reduced grid, interpretationOfNumberOfPoints should be 1 " "(See Code Table 3.11)\n"); } } if (fabs(lon2 - expected_lon2) > angular_tolerance) { error(filename, msg_num, "longitudeOfLastGridPointInDegrees=%f but should be %f\n", lon2, expected_lon2); } GRIB_CHECK(grib_get_size(h, "values", &sizeOfValuesArray), 0); if (sizeOfValuesArray != (size_t)numberOfDataPoints) { error(filename, msg_num, "Number of data points %d different from size of values array %d\n", numberOfDataPoints, sizeOfValuesArray); } free(lats); grib_handle_delete(h); } fclose(in); if (verbose) printf("\n"); return GRIB_SUCCESS; } int main(int argc, char** argv) { int i = 0; if (argc < 2) { usage(argv[0]); return 1; } for (i = 1; i < argc; ++i) { const char* arg = argv[i]; if (STR_EQUAL(arg, "-f")) { if (argc < 3) { usage(argv[0]); return 1; } exit_on_error = 0; } else if (STR_EQUAL(arg, "-V")) { printf("\necCodes Version "); grib_print_api_version(stdout); printf("\n\n"); return 0; } else if (STR_EQUAL(arg, "-v")) { if (argc < 3) { usage(argv[0]); return 1; } verbose = 1; } else { /* We have a file (not an option) */ process_file(arg); } } if (verbose) printf("###############\n"); if (error_count == 0) { if (verbose) printf("ALL OK\n"); } else { printf("Error count: %d\n", error_count); return 1; } return 0; }