mirror of https://github.com/ecmwf/eccodes.git
Merge grib api and eccodes - part 1
This commit is contained in:
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5f53102b46
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14
Makefile.am
14
Makefile.am
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@ -76,6 +76,7 @@ EXTRA_DIST = README AUTHORS NOTICE LICENSE ChangeLog version.sh html \
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data/scan_y_rotated_ll_8_4_good.dump \
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data/scan_y_rotated_ll_8_7_good.dump \
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data/tigge_pf_ecmwf.grib2 \
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data/tigge_pf_ecmwf.grib2.ref \
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data/regular_gaussian_pressure_level.grib1 \
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data/regular_gaussian_model_level.grib1 \
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data/regular_gaussian_surface.grib1 \
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@ -370,6 +371,19 @@ EXTRA_DIST = README AUTHORS NOTICE LICENSE ChangeLog version.sh html \
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data/download.sh \
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perf/jmeter.awk \
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perf/time.sh \
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CMakeLists.txt \
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project_summary.cmake \
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VERSION.cmake \
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grib_api_config.h.in \
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examples/CMakeLists.txt \
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data/CMakeLists.txt \
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data/tigge/CMakeLists.txt \
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ifs_samples/grib1/CMakeLists.txt \
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ifs_samples/grib1_mlgrib2_ieee64/CMakeLists.txt \
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ifs_samples/grib1_mlgrib2_ieee32/CMakeLists.txt \
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ifs_samples/CMakeLists.txt \
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ifs_samples/grib1_mlgrib2/CMakeLists.txt \
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samples/CMakeLists.txt \
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windows/msvc/grib_api.sln \
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windows/msvc/grib_api_lib/grib_api_lib.vcproj \
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windows/msvc/grib_dump/grib_dump.vcproj \
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@ -22,13 +22,11 @@ set(files_to_download
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gen_ext_spd_2.grib
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gen_ext_spd_3_boust_bitmap.grib
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gen_ext_spd_3.grib
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gep10.t12z.pgrb2af78.grib2
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gfs.c255.grib2
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gts.grib
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index.grib
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jpeg.grib2
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lfpw.grib1
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lfpw.grib2
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missing_field.grib1
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missing.grib2
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mixed.grib
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@ -103,7 +101,6 @@ endforeach()
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LIST(APPEND other_files
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60_model_levels
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bitmap.diff
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filter_rules
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ieee_test.good
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index.ok
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index_f90.ok
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@ -111,15 +108,10 @@ LIST(APPEND other_files
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list_points
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local.good.log
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ls.log
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mf.rules
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multi.ok
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multi_level.txt
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multi_step.txt
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no_bitmap.diff
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perf.ksh
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read_any.ok
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ret.sh
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sample_grib.txt
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scan_x_regular_gg_5_7_good.dump
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scan_x_regular_ll_5_4_good.dump
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scan_x_regular_ll_5_7_good.dump
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@ -144,6 +136,7 @@ LIST(APPEND other_files
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step_grib1.filter
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step_grib1.log
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typeOfProcessedData.ok
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tigge_pf_ecmwf.grib2.ref
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)
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foreach( file ${other_files} )
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@ -1 +1 @@
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EXTRA_DIST = CMakeLists.txt
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@ -1,6 +1,7 @@
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#!/bin/sh
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DATA_DIR=$1
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VERBOSE=0
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# Check if all downloads are already done
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DOWNLOADED=${DATA_DIR}/.downloaded
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@ -10,6 +11,7 @@ fi
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files="
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bad.grib
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in_copy.grib
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budg
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constant_field.grib1
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constant_width_bitmap.grib
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@ -25,13 +27,12 @@ files="
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gen_ext_spd_2.grib
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gen_ext_spd_3_boust_bitmap.grib
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gen_ext_spd_3.grib
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gep10.t12z.pgrb2af78.grib2
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gfs.c255.grib2
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gts.grib
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index.grib
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grid_ieee.grib
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jpeg.grib2
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lfpw.grib1
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lfpw.grib2
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missing_field.grib1
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missing.grib2
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mixed.grib
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@ -336,13 +337,15 @@ files="
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download_URL="http://download.ecmwf.org"
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cd ${DATA_DIR}
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#echo "Downloading data files for testing..."
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echo "Downloading data files for testing..."
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for f in $files; do
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# If we haven't already got the file, download it
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if [ ! -f "$f" ]; then
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wget --no-verbose -q -O $f ${download_URL}/test-data/grib_api/data/$f
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wget -nv -q -O $f ${download_URL}/test-data/grib_api/data/$f
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#chmod 444 $f
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#echo "Downloaded $f ..."
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if [ $VERBOSE -eq 1 ]; then
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echo "Downloaded $f ..."
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fi
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fi
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done
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@ -521,6 +521,7 @@ dist_definitionsgrib2_DATA = \
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grib2/template.4.horizontal.def\
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grib2/template.4.parameter.def\
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grib2/template.4.parameter_aerosol.def\
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grib2/template.4.parameter_aerosol_44.def\
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grib2/template.4.parameter_aerosol_optical.def\
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grib2/template.4.parameter_chemical.def\
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grib2/template.4.parameter_partition.def\
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@ -2519,4 +2520,6 @@ dist_definitionstide_DATA = \
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tide/section.1.def\
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tide/section.4.def
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EXTRA_DIST=CMakeLists.txt
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include $(DEVEL_RULES)
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@ -13,6 +13,11 @@ constant internalVersion=22 : hidden;
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constant UseEcmfConventions = 1: hidden;
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constant defaultTypeOfLevel="unknown" : hidden;
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# GRIBEX special boustrophedonic mode. See GRIB-472
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# If the environment variable is not defined, the key will be 0
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GRIBEX_boustrophedonic = getenv("GRIB_API_GRIBEX_BOUSTROPHEDONIC","0");
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constant zero=0 : hidden;
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constant one=1 : hidden;
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constant two=1 : hidden;
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@ -1,58 +1,60 @@
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# This file was automatically generated by ./param.pl
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51 51 - Surface geopotential m**2 s**-2
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52 52 - Surface pressure Pa
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53 53 - Vertical integral of mass of atmosphere kg m**-2
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54 54 - Vertical integral of temperature K kg m**-2
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55 55 - Vertical integral of water vapour kg m**-2
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56 56 - Vertical integral of cloud liquid water kg m**-2
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57 57 - Vertical integral of cloud frozen water kg m**-2
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58 58 - Vertical integral of ozone kg m**-2
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59 59 - Vertical integral of kinetic energy J m**-2
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60 60 - Vertical integral of thermal energy J m**-2
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61 61 - Vertical integral of potential+internal energy J m**-2
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62 62 - Vertical integral of potential+internal+latent energy J m**-2
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63 63 - Vertical integral of total energy J m**-2
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64 64 - Vertical integral of energy conversion W m**-2
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65 65 - Vertical integral of eastward mass flux kg m**-1 s**-1
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66 66 - Vertical integral of northward mass flux kg m**-1 s**-1
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67 67 - Vertical integral of eastward kinetic energy flux W m**-2
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68 68 - Vertical integral of northward kinetic energy flux W m**-2
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69 69 - Vertical integral of eastward heat flux W m**-2
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70 70 - Vertical integral of northward heat flux W m**-2
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71 71 - Vertical integral of eastward water vapour flux kg m**-1 s**-1
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72 72 - Vertical integral of northward water vapour flux kg m**-1 s**-1
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73 73 - Vertical integral of eastward geopotential flux W m**-2
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74 74 - Vertical integral of northward geopotential flux W m**-2
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75 75 - Vertical integral of eastward total energy flux W m**-2
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76 76 - Vertical integral of northward total energy flux W m**-2
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77 77 - Vertical integral of eastward ozone flux kg m**-1 s**-1
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78 78 - Vertical integral of northward ozone flux kg m**-1 s**-1
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81 81 - Vertical integral of divergence of mass flux kg m**-2 s**-1
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82 82 - Vertical integral of divergence of kinetic energy flux W m**-2
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83 83 - Vertical integral of divergence of thermal energy flux W m**-2
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84 84 - Vertical integral of divergence of moisture flux kg m**-2 s**-1
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85 85 - Vertical integral of divergence of geopotential flux W m**-2
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86 86 - Vertical integral of divergence of total energy flux W m**-2
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87 87 - Vertical integral of divergence of ozone flux kg m**-2 s**-1
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51 51 - Surface geopotential (m**2 s**-2)
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52 52 SP Surface pressure (Pa)
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53 53 - Vertical integral of mass of atmosphere (kg m**-2)
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54 54 - Vertical integral of temperature (K kg m**-2)
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55 55 - Vertical integral of water vapour (kg m**-2)
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56 56 - Vertical integral of cloud liquid water (kg m**-2)
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57 57 - Vertical integral of cloud frozen water (kg m**-2)
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58 58 - Vertical integral of ozone (kg m**-2)
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59 59 - Vertical integral of kinetic energy (J m**-2)
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60 60 - Vertical integral of thermal energy (J m**-2)
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61 61 - Vertical integral of potential+internal energy (J m**-2)
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62 62 - Vertical integral of potential+internal+latent energy (J m**-2)
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63 63 - Vertical integral of total energy (J m**-2)
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64 64 - Vertical integral of energy conversion (J m**-2)
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65 65 - Vertical integral of eastward mass flux (kg m**-1 s**-1)
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66 66 - Vertical integral of northward mass flux (kg m**-1 s**-1)
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67 67 - Vertical integral of eastward kinetic energy flux (J m**-2)
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68 68 - Vertical integral of northward kinetic energy flux (J m**-2)
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69 69 - Vertical integral of eastward heat flux (J m**-2)
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70 70 - Vertical integral of northward heat flux (J m**-2)
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71 71 - Vertical integral of eastward water vapour flux (kg m**-1 s**-1)
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72 72 - Vertical integral of northward water vapour flux (kg m**-1 s**-1)
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73 73 - Vertical integral of eastward geopotential flux (J m**-2)
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74 74 - Vertical integral of northward geopotential flux (J m**-2)
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75 75 - Vertical integral of eastward total energy flux (J m**-2)
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76 76 - Vertical integral of northward total energy flux (J m**-2)
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77 77 - Vertical integral of eastward ozone flux (kg m**-1 s**-1)
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78 78 - Vertical integral of northward ozone flux (kg m**-1 s**-1)
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79 79 - Vertical integral of divergence of cloud liquid water flux (kg m**-2 s**-1)
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80 80 - Vertical integral of divergence of cloud frozen water flux (kg m**-2 s**-1)
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81 81 - Vertical integral of divergence of mass flux (kg m**-2 s**-1)
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82 82 - Vertical integral of divergence of kinetic energy flux (J m**-2)
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83 83 - Vertical integral of divergence of thermal energy flux (J m**-2)
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84 84 - Vertical integral of divergence of moisture flux (kg m**-2 s**-1)
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85 85 - Vertical integral of divergence of geopotential flux (J m**-2)
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86 86 - Vertical integral of divergence of total energy flux (J m**-2)
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87 87 - Vertical integral of divergence of ozone flux (kg m**-2 s**-1)
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88 88 - Vertical integral of eastward cloud liquid water flux (kg m**-1 s**-1)
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89 89 - Vertical integral of northward cloud liquid water flux (kg m**-1 s**-1)
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90 90 - Vertical integral of eastward cloud frozen water flux (kg m**-1 s**-1)
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91 91 - Vertical integral of northward cloud frozen water flux (kg m**-1 s**-1)
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92 92 - Vertical integral of mass tendency (kg m**-2 s**-1)
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100 100 - Tendency of short wave radiation K
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101 101 - Tendency of long wave radiation K
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102 102 - Tendency of clear sky short wave radiation K
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103 103 - Tendency of clear sky long wave radiation K
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104 104 - Updraught mass flux kg m**-2
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105 105 - Downdraught mass flux kg m**-2
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106 106 - Updraught detrainment rate kg m**-3
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107 107 - Downdraught detrainment rate kg m**-3
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108 108 - Total precipitation flux kg m**-2
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109 109 - Turbulent diffusion coefficient for heat m**2
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110 110 - Tendency of temperature due to physics K
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111 111 - Tendency of specific humidity due to physics kg kg**-1
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112 112 - Tendency of u component due to physics m s**-1
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113 113 - Tendency of v component due to physics m s**-1
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100 100 - Tendency of short wave radiation (K)
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101 101 - Tendency of long wave radiation (K)
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102 102 - Tendency of clear sky short wave radiation (K)
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103 103 - Tendency of clear sky long wave radiation (K)
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104 104 - Updraught mass flux (kg m**-2)
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105 105 - Downdraught mass flux (kg m**-2)
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106 106 - Updraught detrainment rate (kg m**-3)
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107 107 - Downdraught detrainment rate (kg m**-3)
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108 108 - Total precipitation flux (kg m**-2)
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109 109 - Turbulent diffusion coefficient for heat (m**2)
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110 110 - Tendency of temperature due to physics (K)
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111 111 - Tendency of specific humidity due to physics (kg kg**-1)
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112 112 - Tendency of u component due to physics (m s**-1)
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113 113 - Tendency of v component due to physics (m s**-1)
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114 114 UTENDD U-tendency from dynamics (m s**-1)
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115 115 VTENDD V-tendency from dynamics (m s**-1)
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116 116 TTENDD T-tendency from dynamics (K)
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@ -81,31 +83,31 @@
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139 139 VTENDCS V-tendency from shallow convection (m s**-1)
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140 140 TTENDSC T-tendency from shallow convection (K)
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141 141 QTENDSC q-tendency from shallow convection (kg kg**-1)
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206 206 - Variance of geopotential m**4 s**-4
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207 207 - Covariance of geopotential/temperature m**2 K s**-2
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208 208 - Variance of temperature K**2
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209 209 - Covariance of geopotential/specific humidity m**2 s**-2
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210 210 - Covariance of temperature/specific humidity K
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206 206 - Variance of geopotential (m**4 s**-4)
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207 207 - Covariance of geopotential/temperature (m**2 K s**-2)
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208 208 - Variance of temperature (K**2)
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209 209 - Covariance of geopotential/specific humidity (m**2 s**-2)
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210 210 - Covariance of temperature/specific humidity (K)
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211 211 - Variance of specific humidity
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212 212 - Covariance of u component/geopotential M**3 s**-3
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213 213 - Covariance of u component/temperature m s**-1 K
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214 214 - Covariance of u component/specific humidity m s**-1
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215 215 - Variance of u component m**2 s**-2
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216 216 - Covariance of v component/geopotential M**3 s**-3
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217 217 - Covariance of v component/temperature m s**-1 K
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218 218 - Covariance of v component/specific humidity m s**-1
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219 219 - Covariance of v component/u component m**2 s**-2
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220 220 - Variance of v component m**2 s**-2
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221 221 - Covariance of omega/geopotential m**2 Pa s**-3
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222 222 - Covariance of omega/temperature Pa s**-1 K
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223 223 - Covariance of omega/specific humidity Pa s**-1
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224 224 - Covariance of omega/u component m Pa s**-2
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225 225 - Covariance of omega/v component m Pa s**-2
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226 226 - Variance of omega Pa**2 s**-2
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227 227 - Variance of surface pressure Pa**2
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229 229 - Variance of relative humidity dimensionless
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230 230 - Covariance of u component/ozone m s**-1
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231 231 - Covariance of v component/ozone m s**-1
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232 232 - Covariance of omega/ozone Pa s**-1
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233 233 - Variance of ozone dimensionless
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212 212 - Covariance of u component/geopotential (m**3 s**-3)
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213 213 - Covariance of u component/temperature (m s**-1 K)
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214 214 - Covariance of u component/specific humidity (m s**-1)
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215 215 - Variance of u component (m**2 s**-2)
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216 216 - Covariance of v component/geopotential (m**3 s**-3)
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217 217 - Covariance of v component/temperature (m s**-1 K)
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218 218 - Covariance of v component/specific humidity (m s**-1)
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219 219 - Covariance of v component/u component (m**2 s**-2)
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220 220 - Variance of v component (m**2 s**-2)
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221 221 - Covariance of omega/geopotential (m**2 Pa s**-3)
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222 222 - Covariance of omega/temperature (Pa s**-1 K)
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223 223 - Covariance of omega/specific humidity (Pa s**-1)
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224 224 - Covariance of omega/u component (m Pa s**-2)
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225 225 - Covariance of omega/v component (m Pa s**-2)
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226 226 - Variance of omega (Pa**2 s**-2)
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227 227 - Variance of surface pressure (Pa**2)
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229 229 - Variance of relative humidity (dimensionless)
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230 230 - Covariance of u component/ozone (m s**-1)
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231 231 - Covariance of v component/ozone (m s**-1)
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232 232 - Covariance of omega/ozone (Pa s**-1)
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233 233 - Variance of ozone (dimensionless)
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255 255 - Indicates a missing value
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@ -1,22 +1,33 @@
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# This file was automatically generated by ./param.pl
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129 129 Z Geopotential (m**2 s**-2)
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130 130 T Temperature (K)
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131 131 U U velocity (m s**-1)
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132 132 V V velocity (m s**-1)
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131 131 U U component of wind (m s**-1)
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132 132 V V component of wind (m s**-1)
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133 133 Q Specific humidity (kg kg**-1)
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135 135 W Vertical velocity (Pa s**-1)
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138 138 VO Vorticity (relative) (s**-1)
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139 139 STL1 Soil temperature level 1 (K)
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140 140 SWL1 Soil wetness level 1 (m)
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141 141 SD Snow depth m of water equivalent
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140 140 SWL1 Soil wetness level 1 (m of water equivalent)
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141 141 SD Snow depth (m of water equivalent)
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142 142 LSP Large-scale precipitation (m)
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143 143 CP Convective precipitation (m)
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146 146 SSHF Surface sensible heat flux (J m**-2)
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147 147 SLHF Surface latent heat flux (J m**-2)
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149 149 TSW Total soil moisture (m)
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151 151 MSL Mean sea level pressure Pa
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155 155 D Divergence s**-1
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171 171 SWL2 Soil wetness level 2 m
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179 179 TTR Top thermal radiation W m-2
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184 184 SWL3 Soil wetness level 3 m
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201 201 MX2T Maximum temperature at 2 metres K
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202 202 MN2T Minimum temperature at 2 metres K
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228 228 TP Total precipitation m
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151 151 MSL Mean sea level pressure (Pa)
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155 155 D Divergence (s**-1)
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157 157 R Relative humidity (%)
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164 164 TCC Total cloud cover ((0 - 1))
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171 171 SWL2 Soil wetness level 2 (m)
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176 176 SSR Surface net solar radiation (J m**-2)
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177 177 STR Surface net thermal radiation (J m**-2)
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179 179 TTR Top net thermal radiation (J m**-2)
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180 180 EWSS Eastward turbulent surface stress (N m**-2 s)
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181 181 NSSS Northward turbulent surface stress (N m**-2 s)
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182 182 E Evaporation (m of water equivalent)
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184 184 SWL3 Soil wetness level 3 (m of water equivalent)
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185 185 CCC Convective cloud cover ((0 - 1))
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201 201 MX2T Maximum temperature at 2 metres since previous post-processing (K)
|
||||
202 202 MN2T Minimum temperature at 2 metres since previous post-processing (K)
|
||||
228 228 TP Total precipitation (m)
|
||||
255 255 - Indicates a missing value
|
||||
|
|
|
@ -2,9 +2,9 @@
|
|||
6 6 - Total soil moisture (m)
|
||||
8 8 SRO Surface runoff (kg m**-2)
|
||||
9 9 SSRO Sub-surface runoff (kg m**-2)
|
||||
10 10 - Clear-sky II down surface sw flux
|
||||
13 13 - Clear-sky II up surface sw flux
|
||||
25 25 - Visibility at 1.5m
|
||||
10 10 SSWCSDOWN Clear-sky (II) down surface sw flux (W m**-2)
|
||||
13 13 SSWCSUP Clear-sky (II) up surface sw flux (W m**-2)
|
||||
25 25 VIS15 Visibility at 1.5m (m)
|
||||
31 31 - Fraction of sea-ice in sea (0 - 1)
|
||||
34 34 - Open-sea surface temperature (K)
|
||||
39 39 - Volumetric soil water layer 1 (m**3 m**-3)
|
||||
|
@ -12,42 +12,43 @@
|
|||
41 41 - Volumetric soil water layer 3 (m**3 m**-3)
|
||||
42 42 - Volumetric soil water layer 4 (m**3 m**-3)
|
||||
49 49 - 10 metre wind gust in the last 24 hours (m s**-1)
|
||||
50 50 - Minimum temperature at 1.5m since previous post-processing (K)
|
||||
51 51 - Maximum temperature at 1.5m since previous post-processing (K)
|
||||
52 52 - Relative humidity at 1.5m
|
||||
50 50 MN15T Minimum temperature at 1.5m since previous post-processing (K)
|
||||
51 51 MX15T Maximum temperature at 1.5m since previous post-processing (K)
|
||||
52 52 RHUM Relative humidity at 1.5m (kg kg**-1)
|
||||
55 55 - 1.5m temperature - mean in the last 24 hours (K)
|
||||
83 83 - Net primary productivity (kg C m**-2 s**-1)
|
||||
85 85 - 10m U wind over land (m s**-1)
|
||||
86 86 - 10m V wind over land (m s**-1)
|
||||
87 87 - 1.5m temperature over land (K)
|
||||
88 88 - 1.5m dewpoint temperature over land (K)
|
||||
89 89 - Top incoming solar radiation (W m**-2 s)
|
||||
90 90 - Top outgoing solar radiation (W m**-2 s)
|
||||
89 89 - Top incoming solar radiation (J m**-2)
|
||||
90 90 - Top outgoing solar radiation (J m**-2)
|
||||
94 94 - Mean sea surface temperature (K)
|
||||
95 95 - 1.5m specific humidity (kg kg**-1)
|
||||
98 98 - Sea-ice thickness (m)
|
||||
99 99 - Liquid water potential temperature (K)
|
||||
110 110 - Ocean ice concentration (0 - 1)
|
||||
111 111 - Ocean mean ice depth (m)
|
||||
116 116 - Short wave radiation flux at surface (J m**-2)
|
||||
117 117 - Short wave radiation flux at top of atmosphere (J m**-2)
|
||||
137 137 - Total column water vapour (kg m**-2)
|
||||
116 116 SWRSURF Short wave radiation flux at surface (J m**-2)
|
||||
117 117 SWRTOP Short wave radiation flux at top of atmosphere (J m**-2)
|
||||
137 137 TCWVAP Total column water vapour (kg m**-2)
|
||||
139 139 - Soil temperature layer 1 (K)
|
||||
142 142 - Large scale rainfall rate
|
||||
143 143 - Convective rainfall rate
|
||||
142 142 LSRRATE Large scale rainfall rate (kg m**-2 s**-1)
|
||||
143 143 CRFRATE Convective rainfall rate (kg m**-2 s**-1)
|
||||
164 164 - Average potential temperature in upper 293.4m (degrees C)
|
||||
167 167 - 1.5m temperature (K)
|
||||
168 168 - 1.5m dewpoint temperature (K)
|
||||
170 170 - Soil temperature layer 2 (K)
|
||||
172 172 - Fractional land mask (0 - 1)
|
||||
175 175 - Average salinity in upper 293.4m psu
|
||||
172 172 LSM Land-sea mask (0 - 1)
|
||||
175 175 - Average salinity in upper 293.4m (psu)
|
||||
183 183 - Soil temperature layer 3 (K)
|
||||
186 186 - Very low cloud amount
|
||||
186 186 VLCA Very low cloud amount (0 - 1)
|
||||
201 201 - 1.5m temperature - maximum in the last 24 hours (K)
|
||||
202 202 - 1.5m temperature - minimum in the last 24 hours (K)
|
||||
236 236 - Soil temperature layer 4 (K)
|
||||
239 239 - Convective snowfall rate
|
||||
240 240 - Large scale snowfall rate
|
||||
248 248 - Total cloud amount - random overlap
|
||||
249 249 - Total cloud amount in lw radiation
|
||||
239 239 CSFRATE Convective snowfall rate (kg m**-2 s**-1)
|
||||
240 240 LSFRATE Large scale snowfall rate (kg m**-2 s**-1)
|
||||
248 248 TCCRO Total cloud amount - random overlap (0 - 1)
|
||||
249 249 TCCLWR Total cloud amount in lw radiation (0 - 1)
|
||||
255 255 - Indicates a missing value
|
||||
|
||||
|
|
|
@ -13,17 +13,17 @@
|
|||
86 86 - 10m V wind over land (m s**-1)
|
||||
87 87 - 1.5m temperature over land (K)
|
||||
88 88 - 1.5m dewpoint temperature over land (K)
|
||||
89 89 - Top incoming solar radiation (W m**-2 s)
|
||||
90 90 - Top outgoing solar radiation (W m**-2 s)
|
||||
89 89 - Top incoming solar radiation (J m**-2)
|
||||
90 90 - Top outgoing solar radiation (J m**-2)
|
||||
110 110 - Ocean ice concentration (0 - 1)
|
||||
111 111 - Ocean mean ice depth (m)
|
||||
139 139 - Soil temperature layer 1 (K)
|
||||
164 164 - Average potential temperature in upper 293.4m degrees C
|
||||
164 164 - Average potential temperature in upper 293.4m (degrees C)
|
||||
167 167 - 1.5m temperature (K)
|
||||
168 168 - 1.5m dewpoint temperature (K)
|
||||
170 170 - Soil temperature layer 2 (K)
|
||||
172 172 - Fractional land mask (0 - 1)
|
||||
175 175 - Average salinity in upper 293.4m psu
|
||||
172 172 lsm Land-sea mask (0 - 1)
|
||||
175 175 - Average salinity in upper 293.4m (psu)
|
||||
183 183 - Soil temperature layer 3 (K)
|
||||
201 201 - 1.5m temperature - maximum in the last 24 hours (K)
|
||||
202 202 - 1.5m temperature - minimum in the last 24 hours (K)
|
||||
|
|
|
@ -1,33 +1,33 @@
|
|||
# This file was automatically generated by ./param.pl
|
||||
129 129 Z Geopotential m**2 s**-2
|
||||
130 130 T Temperature K
|
||||
131 131 U U velocity m s**-1
|
||||
132 132 V V velocity m s**-1
|
||||
133 133 Q Specific humidity kg kg**-1
|
||||
134 134 SP Surface pressure Pa
|
||||
137 137 TCWV Total column water vapour kg m**-2
|
||||
138 138 VO Vorticity (relative) s**-1
|
||||
141 141 SD Snow depth m of water equivalent
|
||||
142 142 LSP Large-scale precipitation m
|
||||
143 143 CP Convective precipitation m
|
||||
144 144 SF Snowfall m of water equivalent
|
||||
146 146 SSHF Surface sensible heat flux W m**-2 s
|
||||
147 147 SLHF Surface latent heat flux W m**-2 s
|
||||
149 149 TSW Total soil wetness m
|
||||
151 151 MSL Mean sea level pressure Pa
|
||||
155 155 D Divergence s**-1
|
||||
129 129 Z Geopotential (m**2 s**-2)
|
||||
130 130 T Temperature (K)
|
||||
131 131 U U component of wind (m s**-1)
|
||||
132 132 V V component of wind (m s**-1)
|
||||
133 133 Q Specific humidity (kg kg**-1)
|
||||
134 134 SP Surface pressure (Pa)
|
||||
137 137 TCWV Total column water vapour (kg m**-2)
|
||||
138 138 VO Vorticity (relative) (s**-1)
|
||||
141 141 SD Snow depth (m of water equivalent)
|
||||
142 142 LSP Large-scale precipitation (m)
|
||||
143 143 CP Convective precipitation (m)
|
||||
144 144 SF Snowfall (m of water equivalent)
|
||||
146 146 SSHF Surface sensible heat flux (J m**-2)
|
||||
147 147 SLHF Surface latent heat flux (J m**-2)
|
||||
149 149 TSW Total soil wetness (m)
|
||||
151 151 MSL Mean sea level pressure (Pa)
|
||||
155 155 D Divergence (s**-1)
|
||||
164 164 TCC Total cloud cover (0 - 1)
|
||||
165 165 10U 10 metre U wind component m s**-1
|
||||
166 166 10V 10 metre V wind component m s**-1
|
||||
167 167 2T 2 metre temperature K
|
||||
168 168 2D 2 metre dewpoint temperature K
|
||||
165 165 10U 10 metre U wind component (m s**-1)
|
||||
166 166 10V 10 metre V wind component (m s**-1)
|
||||
167 167 2T 2 metre temperature (K)
|
||||
168 168 2D 2 metre dewpoint temperature (K)
|
||||
172 172 LSM Land-sea mask (0 - 1)
|
||||
176 176 SSR Surface solar radiation J m**-2 s
|
||||
177 177 STR Surface thermal radiation J m**-2 s
|
||||
178 178 TSR Top solar radiation J m**-2 s
|
||||
179 179 TTR Top thermal radiation J m**-2 s
|
||||
180 180 EWSS East-West surface stress N m**-2 s
|
||||
181 181 NSSS North-South surface stress N m**-2 s
|
||||
182 182 E Evaporation m of water
|
||||
205 205 RO Runoff m
|
||||
176 176 SSR Surface net solar radiation (J m**-2)
|
||||
177 177 STR Surface net thermal radiation (J m**-2)
|
||||
178 178 TSR Top net solar radiation (J m**-2)
|
||||
179 179 TTR Top net thermal radiation (J m**-2)
|
||||
180 180 EWSS Eastward turbulent surface stress (N m**-2 s)
|
||||
181 181 NSSS Northward turbulent surface stress (N m**-2 s)
|
||||
182 182 E Evaporation (m of water equivalent)
|
||||
205 205 RO Runoff (m)
|
||||
255 255 - Indicates a missing value
|
||||
|
|
|
@ -1,33 +1,37 @@
|
|||
# This file was automatically generated by ./param.pl
|
||||
129 129 Z Geopotential m**2 s**-2
|
||||
130 130 T Temperature K
|
||||
131 131 U U velocity m s**-1
|
||||
132 132 V V velocity m s**-1
|
||||
133 133 Q Specific humidity kg kg**-1
|
||||
139 139 STL1 Soil temperature level 1 K
|
||||
141 141 SD Snow depth m of water
|
||||
146 146 SSHF Surface sensible heat flux W m**-2 s
|
||||
147 147 SLHF Surface latent heat flux W m**-2 s
|
||||
151 151 MSL Mean sea level pressure Pa
|
||||
129 129 Z Geopotential (m**2 s**-2)
|
||||
130 130 T Temperature (K)
|
||||
131 131 U U component of wind (m s**-1)
|
||||
132 132 V V component of wind (m s**-1)
|
||||
133 133 Q Specific humidity (kg kg**-1)
|
||||
134 134 SP Surface pressure (Pa)
|
||||
138 138 VO Vorticity (relative) (s**-1)
|
||||
139 139 STL1 Soil temperature level 1 (K)
|
||||
141 141 SDSIEN Snow depth (kg m**-2)
|
||||
146 146 SSHF Surface sensible heat flux (J m**-2)
|
||||
147 147 SLHF Surface latent heat flux (J m**-2)
|
||||
151 151 MSL Mean sea level pressure (Pa)
|
||||
155 155 D Divergence (s**-1)
|
||||
157 157 R Relative humidity (%)
|
||||
164 164 TCC Total cloud cover (0 - 1)
|
||||
165 165 10U 10 metre U wind component m s**-1
|
||||
166 166 10V 10 metre V wind component m s**-1
|
||||
167 167 2T 2 metre temperature K
|
||||
168 168 2D 2 metre dewpoint temperature K
|
||||
169 169 SSRD Downward surface solar radiation W m**-2 s (W m**-2 for monthly means)
|
||||
170 170 CAP Field capacity ?
|
||||
171 171 WILT Wilting points ?
|
||||
165 165 10U 10 metre U wind component (m s**-1)
|
||||
166 166 10V 10 metre V wind component (m s**-1)
|
||||
167 167 2T 2 metre temperature (K)
|
||||
168 168 2D 2 metre dewpoint temperature (K)
|
||||
169 169 SSRD Surface solar radiation downwards (J m**-2)
|
||||
170 170 CAP Field capacity (0 - 1)
|
||||
171 171 WILTSIEN Wilting point (0 - 1)
|
||||
172 172 LSM Land-sea mask (0 - 1)
|
||||
173 173 SR Roughness length (0 - 1)
|
||||
174 174 AL Albedo (0 - 1)
|
||||
175 175 STRD Downward surface long wave radiation W m**-2 s (W m**-2 for monthly means)
|
||||
176 176 SSR Surface net solar radiation W m**-2 s (W m**-2 for monthly means)
|
||||
177 177 STR Surface net long wave radiation W m**-2 s (W m**-2 for monthly means)
|
||||
178 178 TSR Top net solar radiation W m**-2 s (W m**-2 for monthly means)
|
||||
179 179 TTR Top net long wave radiation W m**-2 s (W m**-2 for monthly means)
|
||||
182 182 E Evaporation m (m s**-1 for monthly means)
|
||||
201 201 MX2T Maximum 2 metre temperature K
|
||||
202 202 MN2T Minimum 2 metre temperature K
|
||||
228 228 TP Total precipitation m (m s**-1 for monthly means)
|
||||
229 229 TSM Total soil moisture m**3 m**-3
|
||||
175 175 STRD Surface thermal radiation downwards (J m**-2)
|
||||
176 176 SSR Surface net solar radiation (J m**-2)
|
||||
177 177 STR Surface net thermal radiation (J m**-2)
|
||||
178 178 TSR Top net solar radiation (J m**-2)
|
||||
179 179 TTR Top net thermal radiation (J m**-2)
|
||||
182 182 E Evaporation (m of water equivalent)
|
||||
201 201 MX2T Maximum temperature at 2 metres since previous post-processing (K)
|
||||
202 202 MN2T Minimum temperature at 2 metres since previous post-processing (K)
|
||||
228 228 TP Total precipitation (m)
|
||||
229 229 TSM Total soil moisture (m**3 m**-3)
|
||||
255 255 - Indicates a missing value
|
|
@ -1,237 +1,236 @@
|
|||
# This file was automatically generated by ./param.pl
|
||||
1 1 STRF Stream function m**2 s**-1
|
||||
2 2 VPOT Velocity potential m**2 s**-1
|
||||
3 3 PT Potential temperature K
|
||||
4 4 EQPT Equivalent potential temperature K
|
||||
5 5 SEPT Saturated equivalent potential temperature K
|
||||
11 11 UDVW U component of divergent wind m s**-1
|
||||
12 12 VDVW V component of divergent wind m s**-1
|
||||
13 13 URTW U component of rotational wind m s**-1
|
||||
14 14 VRTW V component of rotational wind m s**-1
|
||||
21 21 UCTP Unbalanced component of temperature K
|
||||
22 22 UCLN Unbalanced component of logarithm of surface pressure
|
||||
23 23 UCDV Unbalanced component of divergence s**-1
|
||||
24 24 - Reserved for future unbalanced components
|
||||
25 25 - Reserved for future unbalanced components
|
||||
26 26 CL Lake cover (0 - 1)
|
||||
27 27 CVL Low vegetation cover (0 - 1)
|
||||
28 28 CVH High vegetation cover (0 - 1)
|
||||
29 29 TVL Type of low vegetation
|
||||
30 30 TVH Type of high vegetation
|
||||
31 31 CI Sea-ice cover (0 - 1)
|
||||
32 32 ASN Snow albedo (0 - 1)
|
||||
33 33 RSN Snow density kg m**-3
|
||||
34 34 SSTK Sea surface temperature K
|
||||
35 35 ISTL1 Ice surface temperature layer 1 K
|
||||
36 36 ISTL2 Ice surface temperature layer 2 K
|
||||
37 37 ISTL3 Ice surface temperature layer 3 K
|
||||
38 38 ISTL4 Ice surface temperature layer 4 K
|
||||
39 39 SWVL1 Volumetric soil water layer 1 m**3 m**-3
|
||||
40 40 SWVL2 Volumetric soil water layer 2 m**3 m**-3
|
||||
41 41 SWVL3 Volumetric soil water layer 3 m**3 m**-3
|
||||
42 42 SWVL4 Volumetric soil water layer 4 m**3 m**-3
|
||||
43 43 SLT Soil type
|
||||
44 44 ES Snow evaporation m of water
|
||||
45 45 SMLT Snowmelt m of water
|
||||
46 46 SDUR Solar duration s
|
||||
47 47 DSRP Direct solar radiation w m**-2
|
||||
48 48 MAGSS Magnitude of surface stress N m**-2 s
|
||||
49 49 10FG 10 metre wind gust m s**-1
|
||||
50 50 LSPF Large-scale precipitation fraction s
|
||||
51 51 MX2T24 Maximum 2 metre temperature K
|
||||
52 52 MN2T24 Minimum 2 metre temperature K
|
||||
53 53 MONT Montgomery potential m**2 s**-2
|
||||
54 54 PRES Pressure Pa
|
||||
55 55 MEAN2T24 Mean 2 metre temperature in past 24 hours K
|
||||
56 56 MN2D24 Mean 2 metre dewpoint temperature in past 24 hours K
|
||||
57 57 UVB Downward UV radiation at the surface w m**-2 s
|
||||
58 58 PAR Photosynthetically active radiation at the surface w m**-2 s
|
||||
59 59 CAPE Convective available potential energy J kg**-1
|
||||
60 60 PV Potential vorticity K m**2 kg**-1 s**-1
|
||||
61 61 TPO Total precipitation from observations Millimetres*100 + number of stations
|
||||
62 62 OBCT Observation count
|
||||
63 63 - Start time for skin temperature difference s
|
||||
64 64 - Finish time for skin temperature difference s
|
||||
65 65 - Skin temperature difference K
|
||||
66 66 - Leaf area index, low vegetation m**2 / m**2
|
||||
67 67 - Leaf area index, high vegetation m**2 / m**2
|
||||
68 68 - Minimum stomatal resistance, low vegetation s m**-1
|
||||
69 69 - Minimum stomatal resistance, high vegetation s m**-1
|
||||
1 1 STRFDIFF Stream function difference (m**2 s**-1)
|
||||
2 2 VPOTDIFF Velocity potential difference (m**2 s**-1)
|
||||
3 3 PTDIFF Potential temperature difference (K)
|
||||
4 4 EQPTDIFF Equivalent potential temperature difference (K)
|
||||
5 5 SEPTDIFF Saturated equivalent potential temperature difference (K)
|
||||
11 11 UDVWDIFF U component of divergent wind difference (m s**-1)
|
||||
12 12 VDVWDIFF V component of divergent wind difference (m s**-1)
|
||||
13 13 URTWDIFF U component of rotational wind difference (m s**-1)
|
||||
14 14 VRTWDIFF V component of rotational wind difference (m s**-1)
|
||||
21 21 UCTPDIFF Unbalanced component of temperature difference (K)
|
||||
22 22 UCLNDIFF Unbalanced component of logarithm of surface pressure difference (~)
|
||||
23 23 UCDVDIFF Unbalanced component of divergence difference (s**-1)
|
||||
24 24 - Reserved for future unbalanced components (~)
|
||||
25 25 - Reserved for future unbalanced components (~)
|
||||
26 26 CLDIFF Lake cover difference (0 - 1)
|
||||
27 27 CVLDIFF Low vegetation cover difference (0 - 1)
|
||||
28 28 CVHDIFF High vegetation cover difference (0 - 1)
|
||||
29 29 TVLDIFF Type of low vegetation difference (~)
|
||||
30 30 TVHDIFF Type of high vegetation difference (~)
|
||||
31 31 SICDIFF Sea-ice cover difference (0 - 1)
|
||||
32 32 ASNDIFF Snow albedo difference (0 - 1)
|
||||
33 33 RSNDIFF Snow density difference (kg m**-3)
|
||||
34 34 SSTDIFF Sea surface temperature difference (K)
|
||||
35 35 ISTL1DIFF Ice surface temperature layer 1 difference (K)
|
||||
36 36 ISTL2DIFF Ice surface temperature layer 2 difference (K)
|
||||
37 37 ISTL3DIFF Ice surface temperature layer 3 difference (K)
|
||||
38 38 ISTL4DIFF Ice surface temperature layer 4 difference (K)
|
||||
39 39 SWVL1DIFF Volumetric soil water layer 1 difference (m**3 m**-3)
|
||||
40 40 SWVL2DIFF Volumetric soil water layer 2 difference (m**3 m**-3)
|
||||
41 41 SWVL3DIFF Volumetric soil water layer 3 difference (m**3 m**-3)
|
||||
42 42 SWVL4DIFF Volumetric soil water layer 4 difference (m**3 m**-3)
|
||||
43 43 SLTDIFF Soil type difference (~)
|
||||
44 44 ESDIFF Snow evaporation difference (kg m**-2)
|
||||
45 45 SMLTDIFF Snowmelt difference (kg m**-2)
|
||||
46 46 SDURDIFF Solar duration difference (s)
|
||||
47 47 DSRPDIFF Direct solar radiation difference (J m**-2)
|
||||
48 48 MAGSSDIFF Magnitude of surface stress difference (N m**-2 s)
|
||||
49 49 10FGDIFF 10 metre wind gust difference (m s**-1)
|
||||
50 50 LSPFDIFF Large-scale precipitation fraction difference (s)
|
||||
51 51 MX2T24DIFF Maximum 2 metre temperature difference (K)
|
||||
52 52 MN2T24DIFF Minimum 2 metre temperature difference (K)
|
||||
53 53 MONTDIFF Montgomery potential difference (m**2 s**-2)
|
||||
54 54 PRESDIFF Pressure difference (Pa)
|
||||
55 55 MEAN2T24DIFF Mean 2 metre temperature in the last 24 hours difference (K)
|
||||
56 56 MN2D24DIFF Mean 2 metre dewpoint temperature in the last 24 hours difference (K)
|
||||
57 57 UVBDIFF Downward UV radiation at the surface difference (J m**-2)
|
||||
58 58 PARDIFF Photosynthetically active radiation at the surface difference (J m**-2)
|
||||
59 59 CAPEDIFF Convective available potential energy difference (J kg**-1)
|
||||
60 60 PVDIFF Potential vorticity difference (K m**2 kg**-1 s**-1)
|
||||
61 61 TPODIFF Total precipitation from observations difference (Millimetres*100 + number of stations)
|
||||
62 62 OBCTDIFF Observation count difference (~)
|
||||
63 63 - Start time for skin temperature difference (s)
|
||||
64 64 - Finish time for skin temperature difference (s)
|
||||
65 65 - Skin temperature difference (K)
|
||||
66 66 - Leaf area index, low vegetation (m**2 m**-2)
|
||||
67 67 - Leaf area index, high vegetation (m**2 m**-2)
|
||||
68 68 - Minimum stomatal resistance, low vegetation (s m**-1)
|
||||
69 69 - Minimum stomatal resistance, high vegetation (s m**-1)
|
||||
70 70 - Biome cover, low vegetation (0 - 1)
|
||||
71 71 - Biome cover, high vegetation (0 - 1)
|
||||
78 78 - Total column liquid water kg m**-2
|
||||
79 79 - Total column ice water kg m**-2
|
||||
80 80 - Experimental product
|
||||
81 81 - Experimental product
|
||||
82 82 - Experimental product
|
||||
83 83 - Experimental product
|
||||
84 84 - Experimental product
|
||||
85 85 - Experimental product
|
||||
86 86 - Experimental product
|
||||
87 87 - Experimental product
|
||||
88 88 - Experimental product
|
||||
89 89 - Experimental product
|
||||
90 90 - Experimental product
|
||||
91 91 - Experimental product
|
||||
92 92 - Experimental product
|
||||
93 93 - Experimental product
|
||||
94 94 - Experimental product
|
||||
95 95 - Experimental product
|
||||
96 96 - Experimental product
|
||||
97 97 - Experimental product
|
||||
98 98 - Experimental product
|
||||
99 99 - Experimental product
|
||||
100 100 - Experimental product
|
||||
101 101 - Experimental product
|
||||
102 102 - Experimental product
|
||||
103 103 - Experimental product
|
||||
104 104 - Experimental product
|
||||
105 105 - Experimental product
|
||||
106 106 - Experimental product
|
||||
107 107 - Experimental product
|
||||
108 108 - Experimental product
|
||||
109 109 - Experimental product
|
||||
110 110 - Experimental product
|
||||
111 111 - Experimental product
|
||||
112 112 - Experimental product
|
||||
113 113 - Experimental product
|
||||
114 114 - Experimental product
|
||||
115 115 - Experimental product
|
||||
116 116 - Experimental product
|
||||
117 117 - Experimental product
|
||||
118 118 - Experimental product
|
||||
119 119 - Experimental product
|
||||
120 120 - Experimental product
|
||||
121 121 MX2T6 Maximum temperature at 2 metres K
|
||||
122 122 MN2T6 Minimum temperature at 2 metres K
|
||||
123 123 10FG6 10 metre wind gust in the past 6 hours m s**-1
|
||||
125 125 - Vertically integrated total energy J m**-2
|
||||
126 126 - Generic parameter for sensitive area prediction Various
|
||||
127 127 AT Atmospheric tide
|
||||
128 128 BV Budget values
|
||||
129 129 Z Geopotential m**2 s**-2
|
||||
130 130 T Temperature K
|
||||
131 131 U U velocity m s**-1
|
||||
132 132 V V velocity m s**-1
|
||||
133 133 Q Specific humidity kg kg**-1
|
||||
134 134 SP Surface pressure Pa
|
||||
135 135 W Vertical velocity Pa s**-1
|
||||
136 136 TCW Total column water kg m**-2
|
||||
137 137 TCWV Total column water vapour kg m**-2
|
||||
138 138 VO Vorticity (relative) s**-1
|
||||
139 139 STL1 Soil temperature level 1 K
|
||||
140 140 SWL1 Soil wetness level 1 m of water
|
||||
141 141 SD Snow depth m of water equivalent
|
||||
142 142 LSP Stratiform precipitation (Large-scale precipitation) m
|
||||
143 143 CP Convective precipitation m
|
||||
144 144 SF Snowfall (convective + stratiform) m of water equivalent
|
||||
145 145 BLD Boundary layer dissipation W m**-2 s
|
||||
146 146 SSHF Surface sensible heat flux W m**-2 s
|
||||
147 147 SLHF Surface latent heat flux W m**-2 s
|
||||
148 148 CHNK Charnock
|
||||
149 149 SNR Surface net radiation W m**-2 s
|
||||
150 150 TNR Top net radiation
|
||||
151 151 MSL Mean sea level pressure Pa
|
||||
152 152 LNSP Logarithm of surface pressure
|
||||
153 153 SWHR Short-wave heating rate K
|
||||
154 154 LWHR Long-wave heating rate K
|
||||
155 155 D Divergence s**-1
|
||||
156 156 GH Height m
|
||||
157 157 R Relative humidity %
|
||||
158 158 TSP Tendency of surface pressure Pa s**-1
|
||||
159 159 BLH Boundary layer height m
|
||||
160 160 SDOR Standard deviation of orography
|
||||
161 161 ISOR Anisotropy of sub-gridscale orography
|
||||
162 162 ANOR Angle of sub-gridscale orography rad
|
||||
163 163 SLOR Slope of sub-gridscale orography
|
||||
164 164 TCC Total cloud cover (0 - 1)
|
||||
165 165 10U 10 metre U wind component m s**-1
|
||||
166 166 10V 10 metre V wind component m s**-1
|
||||
167 167 2T 2 metre temperature K
|
||||
168 168 2D 2 metre dewpoint temperature K
|
||||
169 169 SSRD Surface solar radiation downwards W m**-2 s
|
||||
170 170 STL2 Soil temperature level 2 K
|
||||
171 171 SWL2 Soil wetness level 2 m of water
|
||||
172 172 LSM Land-sea mask (0 - 1)
|
||||
173 173 SR Surface roughness m
|
||||
174 174 AL Albedo (0 - 1)
|
||||
175 175 STRD Surface thermal radiation downwards W m**-2 s
|
||||
176 176 SSR Surface solar radiation W m**-2 s
|
||||
177 177 STR Surface thermal radiation W m**-2 s
|
||||
178 178 TSR Top solar radiation W m**-2 s
|
||||
179 179 TTR Top thermal radiation W m**-2 s
|
||||
180 180 EWSS East-West surface stress N m**-2 s
|
||||
181 181 NSSS North-South surface stress N m**-2 s
|
||||
182 182 E Evaporation m of water
|
||||
183 183 STL3 Soil temperature level 3 K
|
||||
184 184 SWL3 Soil wetness level 3 m of water
|
||||
185 185 CCC Convective cloud cover (0 - 1)
|
||||
186 186 LCC Low cloud cover (0 - 1)
|
||||
187 187 MCC Medium cloud cover (0 - 1)
|
||||
188 188 HCC High cloud cover (0 - 1)
|
||||
189 189 SUND Sunshine duration s
|
||||
190 190 EWOV East-West component of sub-gridscale orographic variance m**2
|
||||
191 191 NSOV North-South component of sub-gridscale orographic variance m**2
|
||||
192 192 NWOV North-West/South-East component of sub-gridscale orographic variance m**2
|
||||
193 193 NEOV North-East/South-West component of sub-gridscale orographic variance m**2
|
||||
194 194 BTMP Brightness temperature K
|
||||
195 195 LGWS Latitudinal component of gravity wave stress N m**-2 s
|
||||
196 196 MGWS Meridional component of gravity wave stress N m**-2 s
|
||||
197 197 GWD Gravity wave dissipation W m**-2 s
|
||||
198 198 SRC Skin reservoir content m of water
|
||||
199 199 VEG Vegetation fraction (0 - 1)
|
||||
200 200 VSO Variance of sub-gridscale orography m**2
|
||||
201 201 MX2T Maximum temperature at 2 metres since previous post-processing K
|
||||
202 202 MN2T Minimum temperature at 2 metres since previous post-processing K
|
||||
203 203 O3 Ozone mass mixing ratio kg kg**-1
|
||||
204 204 PAW Precipitation analysis weights
|
||||
205 205 RO Runoff m
|
||||
206 206 TCO3 Total column ozone kg m**-2
|
||||
207 207 10SI 10 metre wind speed m s**-1
|
||||
208 208 TSRC Top net solar radiation, clear sky W m**-2 s
|
||||
209 209 TTRC Top net thermal radiation, clear sky W m**-2 s
|
||||
210 210 SSRC Surface net solar radiation, clear sky W m**-2 s
|
||||
211 211 STRC Surface net thermal radiation, clear sky W m**-2 s
|
||||
212 212 TISR TOA incident solar radiation W m**-2 s
|
||||
214 214 DHR Diabatic heating by radiation K
|
||||
215 215 DHVD Diabatic heating by vertical diffusion K
|
||||
216 216 DHCC Diabatic heating by cumulus convection K
|
||||
217 217 DHLC Diabatic heating large-scale condensation K
|
||||
218 218 VDZW Vertical diffusion of zonal wind m s**-1
|
||||
219 219 VDMW Vertical diffusion of meridional wind m s**-1
|
||||
220 220 EWGD East-West gravity wave drag tendency m s**-1
|
||||
221 221 NSGD North-South gravity wave drag tendency m s**-1
|
||||
222 222 CTZW Convective tendency of zonal wind m s**-1
|
||||
223 223 CTMW Convective tendency of meridional wind m s**-1
|
||||
224 224 VDH Vertical diffusion of humidity kg kg**-1
|
||||
225 225 HTCC Humidity tendency by cumulus convection kg kg**-1
|
||||
226 226 HTLC Humidity tendency by large-scale condensation kg kg**-1
|
||||
227 227 CRNH Change from removal of negative humidity kg kg**-1
|
||||
228 228 TP Total precipitation m
|
||||
229 229 IEWS Instantaneous X surface stress N m**-2
|
||||
230 230 INSS Instantaneous Y surface stress N m**-2
|
||||
231 231 ISHF Instantaneous surface heat flux W m**-2
|
||||
232 232 IE Instantaneous moisture flux kg m**-2 s
|
||||
233 233 ASQ Apparent surface humidity kg kg**-1
|
||||
234 234 LSRH Logarithm of surface roughness length for heat
|
||||
235 235 SKT Skin temperature K
|
||||
236 236 STL4 Soil temperature level 4 K
|
||||
237 237 SWL4 Soil wetness level 4 m
|
||||
238 238 TSN Temperature of snow layer K
|
||||
239 239 CSF Convective snowfall m of water equivalent
|
||||
240 240 LSF Large-scale snowfall m of water equivalent
|
||||
241 241 ACF Accumulated cloud fraction tendency (-1 to 1)
|
||||
242 242 ALW Accumulated liquid water tendency (-1 to 1)
|
||||
243 243 FAL Forecast albedo (0 - 1)
|
||||
244 244 FSR Forecast surface roughness m
|
||||
245 245 FLSR Forecast logarithm of surface roughness for heat
|
||||
246 246 CLWC Cloud liquid water content kg kg**-1
|
||||
247 247 CIWC Cloud ice water content kg kg**-1
|
||||
248 248 CC Cloud cover (0 - 1)
|
||||
249 249 AIW Accumulated ice water tendency (-1 to 1)
|
||||
250 250 ICE Ice age (0 - 1)
|
||||
251 251 ATTE Adiabatic tendency of temperature K
|
||||
252 252 ATHE Adiabatic tendency of humidity kg kg**-1
|
||||
253 253 ATZE Adiabatic tendency of zonal wind m s**-1
|
||||
254 254 ATMW Adiabatic tendency of meridional wind m s**-1
|
||||
255 255 - Indicates a missing value
|
||||
78 78 - Total column liquid water (kg m**-2)
|
||||
79 79 - Total column ice water (kg m**-2)
|
||||
80 80 - Experimental product (~)
|
||||
81 81 - Experimental product (~)
|
||||
82 82 - Experimental product (~)
|
||||
83 83 - Experimental product (~)
|
||||
84 84 - Experimental product (~)
|
||||
85 85 - Experimental product (~)
|
||||
86 86 - Experimental product (~)
|
||||
87 87 - Experimental product (~)
|
||||
88 88 - Experimental product (~)
|
||||
89 89 - Experimental product (~)
|
||||
90 90 - Experimental product (~)
|
||||
91 91 - Experimental product (~)
|
||||
92 92 - Experimental product (~)
|
||||
93 93 - Experimental product (~)
|
||||
94 94 - Experimental product (~)
|
||||
95 95 - Experimental product (~)
|
||||
96 96 - Experimental product (~)
|
||||
97 97 - Experimental product (~)
|
||||
98 98 - Experimental product (~)
|
||||
99 99 - Experimental product (~)
|
||||
100 100 - Experimental product (~)
|
||||
101 101 - Experimental product (~)
|
||||
102 102 - Experimental product (~)
|
||||
103 103 - Experimental product (~)
|
||||
104 104 - Experimental product (~)
|
||||
105 105 - Experimental product (~)
|
||||
106 106 - Experimental product (~)
|
||||
107 107 - Experimental product (~)
|
||||
108 108 - Experimental product (~)
|
||||
109 109 - Experimental product (~)
|
||||
110 110 - Experimental product (~)
|
||||
111 111 - Experimental product (~)
|
||||
112 112 - Experimental product (~)
|
||||
113 113 - Experimental product (~)
|
||||
114 114 - Experimental product (~)
|
||||
115 115 - Experimental product (~)
|
||||
116 116 - Experimental product (~)
|
||||
117 117 - Experimental product (~)
|
||||
118 118 - Experimental product (~)
|
||||
119 119 - Experimental product (~)
|
||||
120 120 - Experimental product (~)
|
||||
121 121 MX2T6DIFF Maximum temperature at 2 metres difference (K)
|
||||
122 122 MN2T6DIFF Minimum temperature at 2 metres difference (K)
|
||||
123 123 10FG6DIFF 10 metre wind gust in the last 6 hours difference (m s**-1)
|
||||
125 125 - Vertically integrated total energy (J m**-2)
|
||||
126 126 - Generic parameter for sensitive area prediction (Various)
|
||||
127 127 ATDIFF Atmospheric tide difference (~)
|
||||
128 128 BVDIFF Budget values difference (~)
|
||||
129 129 ZDIFF Geopotential difference (m**2 s**-2)
|
||||
130 130 TDIFF Temperature difference (K)
|
||||
131 131 UDIFF U component of wind difference (m s**-1)
|
||||
132 132 VDIFF V component of wind difference (m s**-1)
|
||||
133 133 QDIFF Specific humidity difference (kg kg**-1)
|
||||
134 134 SPDIFF Surface pressure difference (Pa)
|
||||
135 135 WDIFF Vertical velocity (pressure) difference (Pa s**-1)
|
||||
136 136 TCWDIFF Total column water difference (kg m**-2)
|
||||
137 137 TCWVDIFF Total column water vapour difference (kg m**-2)
|
||||
138 138 VODIFF Vorticity (relative) difference (s**-1)
|
||||
139 139 STL1DIFF Soil temperature level 1 difference (K)
|
||||
140 140 SWL1DIFF Soil wetness level 1 difference (kg m**-2)
|
||||
141 141 SDDIFF Snow depth difference (m of water equivalent)
|
||||
142 142 LSPDIFF Stratiform precipitation (Large-scale precipitation) difference (m)
|
||||
143 143 CPDIFF Convective precipitation difference (m)
|
||||
144 144 SFDIFF Snowfall (convective + stratiform) difference (m of water equivalent)
|
||||
145 145 BLDDIFF Boundary layer dissipation difference (J m**-2)
|
||||
146 146 SSHFDIFF Surface sensible heat flux difference (J m**-2)
|
||||
147 147 SLHFDIFF Surface latent heat flux difference (J m**-2)
|
||||
148 148 CHNKDIFF Charnock difference (~)
|
||||
149 149 SNRDIFF Surface net radiation difference (J m**-2)
|
||||
150 150 TNRDIFF Top net radiation difference (~)
|
||||
151 151 MSLDIFF Mean sea level pressure difference (Pa)
|
||||
152 152 LNSPDIFF Logarithm of surface pressure difference (kg m**-2)
|
||||
153 153 SWHRDIFF Short-wave heating rate difference (K)
|
||||
154 154 LWHRDIFF Long-wave heating rate difference (K)
|
||||
155 155 DDIFF Divergence difference (s**-1)
|
||||
156 156 GHDIFF Height difference (m)
|
||||
157 157 RDIFF Relative humidity difference (%)
|
||||
158 158 TSPDIFF Tendency of surface pressure difference (Pa s**-1)
|
||||
159 159 BLHDIFF Boundary layer height difference (m)
|
||||
160 160 SDORDIFF Standard deviation of orography difference (~)
|
||||
161 161 ISORDIFF Anisotropy of sub-gridscale orography difference (~)
|
||||
162 162 ANORDIFF Angle of sub-gridscale orography difference (radians)
|
||||
163 163 SLORDIFF Slope of sub-gridscale orography difference (~)
|
||||
164 164 TCCDIFF Total cloud cover difference (0 - 1)
|
||||
165 165 10UDIFF 10 metre U wind component difference (m s**-1)
|
||||
166 166 10VDIFF 10 metre V wind component difference (m s**-1)
|
||||
167 167 2TDIFF 2 metre temperature difference (K)
|
||||
168 168 2DDIFF 2 metre dewpoint temperature difference (K)
|
||||
169 169 SSRDDIFF Surface solar radiation downwards difference (J m**-2)
|
||||
170 170 STL2DIFF Soil temperature level 2 difference (K)
|
||||
171 171 SWL2DIFF Soil wetness level 2 difference (kg m**-2)
|
||||
172 172 LSMDIFF Land-sea mask difference (0 - 1)
|
||||
173 173 SRDIFF Surface roughness difference (m)
|
||||
174 174 ALDIFF Albedo difference (0 - 1)
|
||||
175 175 STRDDIFF Surface thermal radiation downwards difference (J m**-2)
|
||||
176 176 SSRDIFF Surface net solar radiation difference (J m**-2)
|
||||
177 177 STRDIFF Surface net thermal radiation difference (J m**-2)
|
||||
178 178 TSRDIFF Top net solar radiation difference (J m**-2)
|
||||
179 179 TTRDIFF Top net thermal radiation difference (J m**-2)
|
||||
180 180 EWSSDIFF East-West surface stress difference (N m**-2 s)
|
||||
181 181 NSSSDIFF North-South surface stress difference (N m**-2 s)
|
||||
182 182 EDIFF Evaporation difference (kg m**-2)
|
||||
183 183 STL3DIFF Soil temperature level 3 difference (K)
|
||||
184 184 SWL3DIFF Soil wetness level 3 difference (kg m**-2)
|
||||
185 185 CCCDIFF Convective cloud cover difference (0 - 1)
|
||||
186 186 LCCDIFF Low cloud cover difference (0 - 1)
|
||||
187 187 MCCDIFF Medium cloud cover difference (0 - 1)
|
||||
188 188 HCCDIFF High cloud cover difference (0 - 1)
|
||||
189 189 SUNDDIFF Sunshine duration difference (s)
|
||||
190 190 EWOVDIFF East-West component of sub-gridscale orographic variance difference (m**2)
|
||||
191 191 NSOVDIFF North-South component of sub-gridscale orographic variance difference (m**2)
|
||||
192 192 NWOVDIFF North-West/South-East component of sub-gridscale orographic variance difference (m**2)
|
||||
193 193 NEOVDIFF North-East/South-West component of sub-gridscale orographic variance difference (m**2)
|
||||
194 194 BTMPDIFF Brightness temperature difference (K)
|
||||
195 195 LGWSDIFF Longitudinal component of gravity wave stress difference (N m**-2 s)
|
||||
196 196 MGWSDIFF Meridional component of gravity wave stress difference (N m**-2 s)
|
||||
197 197 GWDDIFF Gravity wave dissipation difference (J m**-2)
|
||||
198 198 SRCDIFF Skin reservoir content difference (kg m**-2)
|
||||
199 199 VEGDIFF Vegetation fraction difference (0 - 1)
|
||||
200 200 VSODIFF Variance of sub-gridscale orography difference (m**2)
|
||||
201 201 MX2TDIFF Maximum temperature at 2 metres since previous post-processing difference (K)
|
||||
202 202 MN2TDIFF Minimum temperature at 2 metres since previous post-processing difference (K)
|
||||
203 203 O3DIFF Ozone mass mixing ratio difference (kg kg**-1)
|
||||
204 204 PAWDIFF Precipitation analysis weights difference (~)
|
||||
205 205 RODIFF Runoff difference (m)
|
||||
206 206 TCO3DIFF Total column ozone difference (kg m**-2)
|
||||
207 207 10SIDIFF 10 metre wind speed difference (m s**-1)
|
||||
208 208 TSRCDIFF Top net solar radiation, clear sky difference (J m**-2)
|
||||
209 209 TTRCDIFF Top net thermal radiation, clear sky difference (J m**-2)
|
||||
210 210 SSRCDIFF Surface net solar radiation, clear sky difference (J m**-2)
|
||||
211 211 STRCDIFF Surface net thermal radiation, clear sky difference (J m**-2)
|
||||
212 212 TISRDIFF TOA incident solar radiation difference (J m**-2)
|
||||
214 214 DHRDIFF Diabatic heating by radiation difference (K)
|
||||
215 215 DHVDDIFF Diabatic heating by vertical diffusion difference (K)
|
||||
216 216 DHCCDIFF Diabatic heating by cumulus convection difference (K)
|
||||
217 217 DHLCDIFF Diabatic heating large-scale condensation difference (K)
|
||||
218 218 VDZWDIFF Vertical diffusion of zonal wind difference (m s**-1)
|
||||
219 219 VDMWDIFF Vertical diffusion of meridional wind difference (m s**-1)
|
||||
220 220 EWGDDIFF East-West gravity wave drag tendency difference (m s**-1)
|
||||
221 221 NSGDDIFF North-South gravity wave drag tendency difference (m s**-1)
|
||||
222 222 CTZWDIFF Convective tendency of zonal wind difference (m s**-1)
|
||||
223 223 CTMWDIFF Convective tendency of meridional wind difference (m s**-1)
|
||||
224 224 VDHDIFF Vertical diffusion of humidity difference (kg kg**-1)
|
||||
225 225 HTCCDIFF Humidity tendency by cumulus convection difference (kg kg**-1)
|
||||
226 226 HTLCDIFF Humidity tendency by large-scale condensation difference (kg kg**-1)
|
||||
227 227 CRNHDIFF Change from removal of negative humidity difference (kg kg**-1)
|
||||
228 228 TPDIFF Total precipitation difference (m)
|
||||
229 229 IEWSDIFF Instantaneous X surface stress difference (N m**-2)
|
||||
230 230 INSSDIFF Instantaneous Y surface stress difference (N m**-2)
|
||||
231 231 ISHFDIFF Instantaneous surface heat flux difference (J m**-2)
|
||||
232 232 IEDIFF Instantaneous moisture flux difference (kg m**-2 s)
|
||||
233 233 ASQDIFF Apparent surface humidity difference (kg kg**-1)
|
||||
234 234 LSRHDIFF Logarithm of surface roughness length for heat difference (~)
|
||||
235 235 SKTDIFF Skin temperature difference (K)
|
||||
236 236 STL4DIFF Soil temperature level 4 difference (K)
|
||||
237 237 SWL4DIFF Soil wetness level 4 difference (m)
|
||||
238 238 TSNDIFF Temperature of snow layer difference (K)
|
||||
239 239 CSFDIFF Convective snowfall difference (m of water equivalent)
|
||||
240 240 LSFDIFF Large scale snowfall difference (m of water equivalent)
|
||||
241 241 ACFDIFF Accumulated cloud fraction tendency difference ((-1 to 1))
|
||||
242 242 ALWDIFF Accumulated liquid water tendency difference ((-1 to 1))
|
||||
243 243 FALDIFF Forecast albedo difference (0 - 1)
|
||||
244 244 FSRDIFF Forecast surface roughness difference (m)
|
||||
245 245 FLSRDIFF Forecast logarithm of surface roughness for heat difference (~)
|
||||
246 246 CLWCDIFF Specific cloud liquid water content difference (kg kg**-1)
|
||||
247 247 CIWCDIFF Specific cloud ice water content difference (kg kg**-1)
|
||||
248 248 CCDIFF Cloud cover difference (0 - 1)
|
||||
249 249 AIWDIFF Accumulated ice water tendency difference ((-1 to 1))
|
||||
250 250 ICEDIFF Ice age difference (0 - 1)
|
||||
251 251 ATTEDIFF Adiabatic tendency of temperature difference (K)
|
||||
252 252 ATHEDIFF Adiabatic tendency of humidity difference (kg kg**-1)
|
||||
253 253 ATZEDIFF Adiabatic tendency of zonal wind difference (m s**-1)
|
||||
254 254 ATMWDIFF Adiabatic tendency of meridional wind difference (m s**-1)
|
||||
|
|
|
@ -1,33 +1,33 @@
|
|||
# This file was automatically generated by ./param.pl
|
||||
1 1 - downward shortwave radiant flux density W m**-2
|
||||
2 2 - upward shortwave radiant flux density W m**-2
|
||||
3 3 - downward longwave radiant flux density W m**-2
|
||||
4 4 - upward longwave radiant flux density W m**-2
|
||||
5 5 APAB_S downwd photosynthetic active radiant flux density W m**-2
|
||||
6 6 - net shortwave flux W m**-2
|
||||
7 7 - net longwave flux W m**-2
|
||||
8 8 - total net radiative flux density W m**-2
|
||||
9 9 - downw shortw radiant flux density, cloudfree part W m**-2
|
||||
10 10 - upw shortw radiant flux density, cloudy part W m**-2
|
||||
11 11 - downw longw radiant flux density, cloudfree part W m**-2
|
||||
12 12 - upw longw radiant flux density, cloudy part W m**-2
|
||||
13 13 SOHR_RAD shortwave radiative heating rate K s**-1
|
||||
14 14 THHR_RAD longwave radiative heating rate K s**-1
|
||||
15 15 - total radiative heating rate W m**-2
|
||||
16 16 - soil heat flux, surface W m**-2
|
||||
17 17 - soil heat flux, bottom of layer W m**-2
|
||||
1 1 - downward shortwave radiant flux density (J m**-2)
|
||||
2 2 - upward shortwave radiant flux density (J m**-2)
|
||||
3 3 - downward longwave radiant flux density (J m**-2)
|
||||
4 4 - upward longwave radiant flux density (J m**-2)
|
||||
5 5 APAB_S downwd photosynthetic active radiant flux density (J m**-2)
|
||||
6 6 - net shortwave flux (J m**-2)
|
||||
7 7 - net longwave flux (J m**-2)
|
||||
8 8 - total net radiative flux density (J m**-2)
|
||||
9 9 - downw shortw radiant flux density, cloudfree part (J m**-2)
|
||||
10 10 - upw shortw radiant flux density, cloudy part (J m**-2)
|
||||
11 11 - downw longw radiant flux density, cloudfree part (J m**-2)
|
||||
12 12 - upw longw radiant flux density, cloudy part (J m**-2)
|
||||
13 13 SOHR_RAD shortwave radiative heating rate (K s**-1)
|
||||
14 14 THHR_RAD longwave radiative heating rate (K s**-1)
|
||||
15 15 - total radiative heating rate (J m**-2)
|
||||
16 16 - soil heat flux, surface (J m**-2)
|
||||
17 17 - soil heat flux, bottom of layer (J m**-2)
|
||||
29 29 CLC fractional cloud cover (0-1)
|
||||
30 30 - cloud cover, grid scale (0-1)
|
||||
31 31 QC specific cloud water content kg kg**-1
|
||||
32 32 - cloud water content, grid scale, vert integrated kg m**-2
|
||||
33 33 QI specific cloud ice content, grid scale kg kg**-1
|
||||
34 34 - cloud ice content, grid scale, vert integrated kg m**-2
|
||||
35 35 - specific rainwater content, grid scale kg kg**-1
|
||||
36 36 - specific snow content, grid scale kg kg**-1
|
||||
37 37 - specific rainwater content, gs, vert. integrated kg m**-2
|
||||
38 38 - specific snow content, gs, vert. integrated kg m**-2
|
||||
41 41 TWATER total column water kg m**-2
|
||||
42 42 - vert. integral of divergence of tot. water content kg m**-2
|
||||
31 31 QC specific cloud water content (kg kg**-1)
|
||||
32 32 - cloud water content, grid scale, vert integrated (kg m**-2)
|
||||
33 33 QI specific cloud ice content, grid scale (kg kg**-1)
|
||||
34 34 - cloud ice content, grid scale, vert integrated (kg m**-2)
|
||||
35 35 - specific rainwater content, grid scale (kg kg**-1)
|
||||
36 36 - specific snow content, grid scale (kg kg**-1)
|
||||
37 37 - specific rainwater content, gs, vert. integrated (kg m**-2)
|
||||
38 38 - specific snow content, gs, vert. integrated (kg m**-2)
|
||||
41 41 TWATER total column water (kg m**-2)
|
||||
42 42 - vert. integral of divergence of tot. water content (kg m**-2)
|
||||
50 50 CH_CM_CL cloud covers CH_CM_CL (000...888) (0-1)
|
||||
51 51 - cloud cover CH (0..8) (0-1)
|
||||
52 52 - cloud cover CM (0..8) (0-1)
|
||||
|
@ -36,43 +36,43 @@
|
|||
55 55 - fog (0..8) (0-1)
|
||||
56 56 - fog (0-1)
|
||||
60 60 - cloud cover, convective cirrus (0-1)
|
||||
61 61 - specific cloud water content, convective clouds kg kg**-1
|
||||
62 62 - cloud water content, conv clouds, vert integrated kg m**-2
|
||||
63 63 - specific cloud ice content, convective clouds kg kg**-1
|
||||
64 64 - cloud ice content, conv clouds, vert integrated kg m**-2
|
||||
65 65 - convective mass flux kg s**-1 m**-2
|
||||
66 66 - updraft velocity, convection m s**-1
|
||||
67 67 - entrainment parameter, convection m**-1
|
||||
68 68 HBAS_CON cloud base, convective clouds (above msl) m
|
||||
69 69 HTOP_CON cloud top, convective clouds (above msl) m
|
||||
61 61 - specific cloud water content, convective clouds (kg kg**-1)
|
||||
62 62 - cloud water content, conv clouds, vert integrated (kg m**-2)
|
||||
63 63 - specific cloud ice content, convective clouds (kg kg**-1)
|
||||
64 64 - cloud ice content, conv clouds, vert integrated (kg m**-2)
|
||||
65 65 - convective mass flux (kg s**-1 m**-2)
|
||||
66 66 - Updraft velocity, convection (m s**-1)
|
||||
67 67 - entrainment parameter, convection (m**-1)
|
||||
68 68 HBAS_CON cloud base, convective clouds (above msl) (m)
|
||||
69 69 HTOP_CON cloud top, convective clouds (above msl) (m)
|
||||
70 70 - convective layers (00...77) (BKE) (0-1)
|
||||
71 71 - KO-index (1)
|
||||
72 72 BAS_CON convection base index (1)
|
||||
73 73 TOP_CON convection top index (1)
|
||||
74 74 DT_CON convective temperature tendency K s**-1
|
||||
75 75 DQV_CON convective tendency of specific humidity s**-1
|
||||
76 76 - convective tendency of total heat J kg**-1 s**-1
|
||||
77 77 - convective tendency of total water s**-1
|
||||
78 78 DU_CON convective momentum tendency (X-component) m s**-2
|
||||
79 79 DV_CON convective momentum tendency (Y-component) m s**-2
|
||||
80 80 - convective vorticity tendency s**-2
|
||||
81 81 - convective divergence tendency s**-2
|
||||
82 82 HTOP_DC top of dry convection (above msl) m
|
||||
83 83 - dry convection top index (1)
|
||||
84 84 HZEROCL height of 0 degree Celsius isotherm above msl m
|
||||
85 85 SNOWLMT height of snow-fall limit m
|
||||
99 99 QRS_GSP spec. content of precip. particles kg kg**-1
|
||||
100 100 PRR_GSP surface precipitation rate, rain, grid scale kg s**-1 m**-2
|
||||
101 101 PRS_GSP surface precipitation rate, snow, grid scale kg s**-1 m**-2
|
||||
102 102 RAIN_GSP surface precipitation amount, rain, grid scale kg m**-2
|
||||
111 111 PRR_CON surface precipitation rate, rain, convective kg s**-1 m**-2
|
||||
112 112 PRS_CON surface precipitation rate, snow, convective kg s**-1 m**-2
|
||||
113 113 RAIN_CON surface precipitation amount, rain, convective kg m**-2
|
||||
139 139 PP deviation of pressure from reference value Pa
|
||||
150 150 - coefficient of horizontal diffusion m**2 s**-1
|
||||
187 187 VMAX_10M maximum wind velocity m s**-1
|
||||
200 200 W_I water content of interception store kg m**-2
|
||||
203 203 T_SNOW snow temperature K
|
||||
215 215 T_ICE ice surface temperature K
|
||||
241 241 CAPE_CON convective available potential energy J kg**-1
|
||||
71 71 - KO-index (dimensionless)
|
||||
72 72 BAS_CON convection base index (dimensionless)
|
||||
73 73 TOP_CON convection top index (dimensionless)
|
||||
74 74 DT_CON convective temperature tendency (K s**-1)
|
||||
75 75 DQV_CON convective tendency of specific humidity (s**-1)
|
||||
76 76 - convective tendency of total heat (J kg**-1 s**-1)
|
||||
77 77 - convective tendency of total water (s**-1)
|
||||
78 78 DU_CON convective momentum tendency (X-component) (m s**-2)
|
||||
79 79 DV_CON convective momentum tendency (Y-component) (m s**-2)
|
||||
80 80 - convective vorticity tendency (s**-2)
|
||||
81 81 - convective divergence tendency (s**-2)
|
||||
82 82 HTOP_DC top of dry convection (above msl) (m)
|
||||
83 83 - dry convection top index (dimensionless)
|
||||
84 84 HZEROCL height of 0 degree Celsius isotherm above msl (m)
|
||||
85 85 SNOWLMT height of snow-fall limit (m)
|
||||
99 99 QRS_GSP spec. content of precip. particles (kg kg**-1)
|
||||
100 100 PRR_GSP surface precipitation rate, rain, grid scale (kg s**-1 m**-2)
|
||||
101 101 PRS_GSP surface precipitation rate, snow, grid scale (kg s**-1 m**-2)
|
||||
102 102 RAIN_GSP surface precipitation amount, rain, grid scale (kg m**-2)
|
||||
111 111 PRR_CON surface precipitation rate, rain, convective (kg s**-1 m**-2)
|
||||
112 112 PRS_CON surface precipitation rate, snow, convective (kg s**-1 m**-2)
|
||||
113 113 RAIN_CON surface precipitation amount, rain, convective (kg m**-2)
|
||||
139 139 PP deviation of pressure from reference value (Pa)
|
||||
150 150 - coefficient of horizontal diffusion (m**2 s**-1)
|
||||
187 187 VMAX_10M Maximum wind velocity (m s**-1)
|
||||
200 200 W_I water content of interception store (kg m**-2)
|
||||
203 203 T_SNOW snow temperature (K)
|
||||
215 215 T_ICE ice surface temperature (K)
|
||||
241 241 CAPE_CON convective available potential energy (J kg**-1)
|
||||
255 255 - Indicates a missing value
|
||||
|
|
|
@ -1,15 +1,172 @@
|
|||
# This file was automatically generated by ./param.pl
|
||||
46 46 AERPR Aerosol precursor mixing ratio kg kg**-1
|
||||
47 47 AERSM Aerosol small mode mixing ratio kg kg**-1
|
||||
48 48 AERLG Aerosol large mode mixing ratio kg kg**-1
|
||||
49 49 AODPR Aerosol precursor optical depth dimensionless
|
||||
50 50 AODSM Aerosol small mode optical depth dimensionless
|
||||
51 51 AODLG Aerosol large mode optical depth dimensionless
|
||||
61 61 CO2 Carbon Dioxide kg kg**-1
|
||||
62 62 CH4 Methane kg kg**-1
|
||||
63 63 N2O Nitrous oxide kg kg**-1
|
||||
121 121 NO2 Nitrogen dioxide kg kg**-1
|
||||
122 122 SO2 Sulphur dioxide kg kg**-1
|
||||
123 123 CO Carbon monoxide kg kg**-1
|
||||
124 124 HCHO Formaldehyde kg kg**-1
|
||||
203 203 GO3 GEMS Ozone kg kg**-1
|
||||
1 1 AERMR01DIFF Sea Salt Aerosol (0.03 - 0.5 um) Mixing Ratio (kg kg**-1)
|
||||
2 2 AERMR02DIFF Sea Salt Aerosol (0.5 - 5 um) Mixing Ratio (kg kg**-1)
|
||||
3 3 AERMR03DIFF Sea Salt Aerosol (5 - 20 um) Mixing Ratio (kg kg**-1)
|
||||
4 4 AERMR04DIFF Dust Aerosol (0.03 - 0.55 um) Mixing Ratio (kg kg**-1)
|
||||
5 5 AERMR05DIFF Dust Aerosol (0.55 - 0.9 um) Mixing Ratio (kg kg**-1)
|
||||
6 6 AERMR06DIFF Dust Aerosol (0.9 - 20 um) Mixing Ratio (kg kg**-1)
|
||||
7 7 AERMR07DIFF Hydrophobic Organic Matter Aerosol Mixing Ratio (kg kg**-1)
|
||||
8 8 AERMR08DIFF Hydrophilic Organic Matter Aerosol Mixing Ratio (kg kg**-1)
|
||||
9 9 AERMR09DIFF Hydrophobic Black Carbon Aerosol Mixing Ratio (kg kg**-1)
|
||||
10 10 AERMR10DIFF Hydrophilic Black Carbon Aerosol Mixing Ratio (kg kg**-1)
|
||||
11 11 AERMR11DIFF Sulphate Aerosol Mixing Ratio (kg kg**-1)
|
||||
12 12 AERMR12DIFF Aerosol type 12 mixing ratio (kg kg**-1)
|
||||
13 13 AERMR13DIFF Aerosol type 13 mass mixing ratio (kg kg**-1)
|
||||
14 14 AERMR14DIFF Aerosol type 14 mass mixing ratio (kg kg**-1)
|
||||
15 15 AERMR15DIFF Aerosol type 15 mass mixing ratio (kg kg**-1)
|
||||
16 16 AERGN01DIFF Aerosol type 1 source/gain accumulated (kg m**-2)
|
||||
17 17 AERGN02DIFF Aerosol type 2 source/gain accumulated (kg m**-2)
|
||||
18 18 AERGN03DIFF Aerosol type 3 source/gain accumulated (kg m**-2)
|
||||
19 19 AERGN04DIFF Aerosol type 4 source/gain accumulated (kg m**-2)
|
||||
20 20 AERGN05DIFF Aerosol type 5 source/gain accumulated (kg m**-2)
|
||||
21 21 AERGN06DIFF Aerosol type 6 source/gain accumulated (kg m**-2)
|
||||
22 22 AERGN07DIFF Aerosol type 7 source/gain accumulated (kg m**-2)
|
||||
23 23 AERGN08DIFF Aerosol type 8 source/gain accumulated (kg m**-2)
|
||||
24 24 AERGN09DIFF Aerosol type 9 source/gain accumulated (kg m**-2)
|
||||
25 25 AERGN10DIFF Aerosol type 10 source/gain accumulated (kg m**-2)
|
||||
26 26 AERGN11DIFF Aerosol type 11 source/gain accumulated (kg m**-2)
|
||||
27 27 AERGN12DIFF Aerosol type 12 source/gain accumulated (kg m**-2)
|
||||
28 28 AERPR03DIFF SO4 aerosol precursor mass mixing ratio (kg kg**-1)
|
||||
29 29 AERWV01DIFF Water vapour mixing ratio for hydrophilic aerosols in mode 1 (kg kg**-1)
|
||||
30 30 AERWV02DIFF Water vapour mixing ratio for hydrophilic aerosols in mode 2 (kg kg**-1)
|
||||
31 31 AERLS01DIFF Aerosol type 1 sink/loss accumulated (kg m**-2)
|
||||
32 32 AERLS02DIFF Aerosol type 2 sink/loss accumulated (kg m**-2)
|
||||
33 33 AERLS03DIFF Aerosol type 3 sink/loss accumulated (kg m**-2)
|
||||
34 34 AERLS04DIFF Aerosol type 4 sink/loss accumulated (kg m**-2)
|
||||
35 35 AERLS05DIFF Aerosol type 5 sink/loss accumulated (kg m**-2)
|
||||
36 36 AERLS06DIFF Aerosol type 6 sink/loss accumulated (kg m**-2)
|
||||
37 37 AERLS07DIFF Aerosol type 7 sink/loss accumulated (kg m**-2)
|
||||
38 38 AERLS08DIFF Aerosol type 8 sink/loss accumulated (kg m**-2)
|
||||
39 39 AERLS09DIFF Aerosol type 9 sink/loss accumulated (kg m**-2)
|
||||
40 40 AERLS10DIFF Aerosol type 10 sink/loss accumulated (kg m**-2)
|
||||
41 41 AERLS11DIFF Aerosol type 11 sink/loss accumulated (kg m**-2)
|
||||
42 42 AERLS12DIFF Aerosol type 12 sink/loss accumulated (kg m**-2)
|
||||
43 43 EMDMSDIFF DMS surface emission (kg m**-2 s**-1)
|
||||
44 44 AERWV03DIFF Water vapour mixing ratio for hydrophilic aerosols in mode 3 (kg kg**-1)
|
||||
45 45 AERWV04DIFF Water vapour mixing ratio for hydrophilic aerosols in mode 4 (kg kg**-1)
|
||||
46 46 AERPRDIFF Aerosol precursor mixing ratio (kg kg**-1)
|
||||
47 47 AERSMDIFF Aerosol small mode mixing ratio (kg kg**-1)
|
||||
48 48 AERLGDIFF Aerosol large mode mixing ratio (kg kg**-1)
|
||||
49 49 AODPRDIFF Aerosol precursor optical depth (dimensionless)
|
||||
50 50 AODSMDIFF Aerosol small mode optical depth (dimensionless)
|
||||
51 51 AODLGDIFF Aerosol large mode optical depth (dimensionless)
|
||||
52 52 AERDEPDIFF Dust emission potential (kg s**2 m**-5)
|
||||
53 53 AERLTSDIFF Lifting threshold speed (m s**-1)
|
||||
54 54 AERSCCDIFF Soil clay content (%)
|
||||
55 55 - Experimental product (~)
|
||||
56 56 - Experimental product (~)
|
||||
61 61 CO2DIFF Carbon Dioxide (kg kg**-1)
|
||||
62 62 CH4DIFF Methane (kg kg**-1)
|
||||
63 63 N2ODIFF Nitrous oxide (kg kg**-1)
|
||||
64 64 TCCO2DIFF Total column Carbon Dioxide (kg m**-2)
|
||||
65 65 TCCH4DIFF Total column Methane (kg m**-2)
|
||||
66 66 TCN2ODIFF Total column Nitrous oxide (kg m**-2)
|
||||
67 67 CO2OFDIFF Ocean flux of Carbon Dioxide (kg m**-2 s**-1)
|
||||
68 68 CO2NBFDIFF Natural biosphere flux of Carbon Dioxide (kg m**-2 s**-1)
|
||||
69 69 CO2APFDIFF Anthropogenic emissions of Carbon Dioxide (kg m**-2 s**-1)
|
||||
70 70 CH4FDIFF Methane Surface Fluxes (kg m**-2 s**-1)
|
||||
71 71 KCH4DIFF Methane loss rate due to radical hydroxyl (OH) (s**-1)
|
||||
80 80 CO2FIREDIFF Wildfire flux of Carbon Dioxide (kg m**-2 s**-1)
|
||||
81 81 COFIREDIFF Wildfire flux of Carbon Monoxide (kg m**-2 s**-1)
|
||||
82 82 CH4FIREDIFF Wildfire flux of Methane (kg m**-2 s**-1)
|
||||
83 83 NMHCFIREDIFF Wildfire flux of Non-Methane Hydro-Carbons (kg m**-2 s**-1)
|
||||
84 84 H2FIREDIFF Wildfire flux of Hydrogen (kg m**-2 s**-1)
|
||||
85 85 NOXFIREDIFF Wildfire flux of Nitrogen Oxides NOx (kg m**-2 s**-1)
|
||||
86 86 N2OFIREDIFF Wildfire flux of Nitrous Oxide (kg m**-2 s**-1)
|
||||
87 87 PM2P5FIREDIFF Wildfire flux of Particulate Matter PM2.5 (kg m**-2 s**-1)
|
||||
88 88 TPMFIREDIFF Wildfire flux of Total Particulate Matter (kg m**-2 s**-1)
|
||||
89 89 TCFIREDIFF Wildfire flux of Total Carbon in Aerosols (kg m**-2 s**-1)
|
||||
90 90 OCFIREDIFF Wildfire flux of Organic Carbon (kg m**-2 s**-1)
|
||||
91 91 BCFIREDIFF Wildfire flux of Black Carbon (kg m**-2 s**-1)
|
||||
92 92 CFIREDIFF Wildfire overall flux of burnt Carbon (kg m**-2 s**-1)
|
||||
93 93 C4FFIREDIFF Wildfire fraction of C4 plants (dimensionless)
|
||||
94 94 VEGFIREDIFF Wildfire vegetation map index (dimensionless)
|
||||
95 95 CCFIREDIFF Wildfire Combustion Completeness (dimensionless)
|
||||
96 96 FLFIREDIFF Wildfire Fuel Load: Carbon per unit area (kg m**-2)
|
||||
97 97 OFFIREDIFF Wildfire fraction of area observed (dimensionless)
|
||||
98 98 OAFIREDIFF Wildfire observed area (m**2)
|
||||
99 99 FRPFIREDIFF Wildfire radiative power (W m**-2)
|
||||
100 100 CRFIREDIFF Wildfire combustion rate (kg m**-2 s**-1)
|
||||
101 101 MAXFRPFIREDIFF Wildfire radiative power maximum (W)
|
||||
102 102 SO2FIREDIFF Wildfire flux of Sulfur Dioxide (kg m**-2 s**-1)
|
||||
103 103 CH3OHFIREDIFF Wildfire Flux of Methanol (CH3OH) (kg m**-2 s**-1)
|
||||
104 104 C2H5OHFIREDIFF Wildfire Flux of Ethanol (C2H5OH) (kg m**-2 s**-1)
|
||||
105 105 C3H8FIREDIFF Wildfire Flux of Propane (C3H8) (kg m**-2 s**-1)
|
||||
106 106 C2H4FIREDIFF Wildfire Flux of Ethene (C2H4) (kg m**-2 s**-1)
|
||||
107 107 C3H6FIREDIFF Wildfire Flux of Propene (C3H6) (kg m**-2 s**-1)
|
||||
108 108 C5H8FIREDIFF Wildfire Flux of Isoprene (C5H8) (kg m**-2 s**-1)
|
||||
109 109 TERPENESFIREDIFF Wildfire Flux of Terpenes (C5H8)n (kg m**-2 s**-1)
|
||||
110 110 TOLUENEFIREDIFF Wildfire Flux of Toluene_lump (C7H8+ C6H6 + C8H10) (kg m**-2 s**-1)
|
||||
111 111 HIALKENESFIREDIFF Wildfire Flux of Higher Alkenes (CnH2n, C>=4) (kg m**-2 s**-1)
|
||||
112 112 HIALKANESFIREDIFF Wildfire Flux of Higher Alkanes (CnH2n+2, C>=4) (kg m**-2 s**-1)
|
||||
113 113 CH2OFIREDIFF Wildfire Flux of Formaldehyde (CH2O) (kg m**-2 s**-1)
|
||||
114 114 C2H4OFIREDIFF Wildfire Flux of Acetaldehyde (C2H4O) (kg m**-2 s**-1)
|
||||
115 115 C3H6OFIREDIFF Wildfire Flux of Acetone (C3H6O) (kg m**-2 s**-1)
|
||||
116 116 NH3FIREDIFF Wildfire Flux of Ammonia (NH3) (kg m**-2 s**-1)
|
||||
117 117 C2H6SFIREDIFF Wildfire Flux of Dimethyl Sulfide (DMS) (C2H6S) (kg m**-2 s**-1)
|
||||
118 118 C2H6FIREDIFF Wildfire Flux of Ethane (C2H6) (kg m**-2 s**-1)
|
||||
119 119 ALEDIFF Altitude of emitter (m above sea level)
|
||||
120 120 APTDIFF Altitude of plume top (m above sea level)
|
||||
121 121 NO2DIFF Nitrogen dioxide (kg kg**-1)
|
||||
122 122 SO2DIFF Sulphur dioxide (kg kg**-1)
|
||||
123 123 CODIFF Carbon monoxide (kg kg**-1)
|
||||
124 124 HCHODIFF Formaldehyde (kg kg**-1)
|
||||
125 125 TCNO2DIFF Total column Nitrogen dioxide (kg m**-2)
|
||||
126 126 TCSO2DIFF Total column Sulphur dioxide (kg m**-2)
|
||||
127 127 TCCODIFF Total column Carbon monoxide (kg m**-2)
|
||||
128 128 TCHCHODIFF Total column Formaldehyde (kg m**-2)
|
||||
129 129 NOXDIFF Nitrogen Oxides (kg kg**-1)
|
||||
130 130 TCNOXDIFF Total Column Nitrogen Oxides (kg m**-2)
|
||||
131 131 GRG1DIFF Reactive tracer 1 mass mixing ratio (kg kg**-1)
|
||||
132 132 TCGRG1DIFF Total column GRG tracer 1 (kg m**-2)
|
||||
133 133 GRG2DIFF Reactive tracer 2 mass mixing ratio (kg kg**-1)
|
||||
134 134 TCGRG2DIFF Total column GRG tracer 2 (kg m**-2)
|
||||
135 135 GRG3DIFF Reactive tracer 3 mass mixing ratio (kg kg**-1)
|
||||
136 136 TCGRG3DIFF Total column GRG tracer 3 (kg m**-2)
|
||||
137 137 GRG4DIFF Reactive tracer 4 mass mixing ratio (kg kg**-1)
|
||||
138 138 TCGRG4DIFF Total column GRG tracer 4 (kg m**-2)
|
||||
139 139 GRG5DIFF Reactive tracer 5 mass mixing ratio (kg kg**-1)
|
||||
140 140 TCGRG5DIFF Total column GRG tracer 5 (kg m**-2)
|
||||
141 141 GRG6DIFF Reactive tracer 6 mass mixing ratio (kg kg**-1)
|
||||
142 142 TCGRG6DIFF Total column GRG tracer 6 (kg m**-2)
|
||||
143 143 GRG7DIFF Reactive tracer 7 mass mixing ratio (kg kg**-1)
|
||||
144 144 TCGRG7DIFF Total column GRG tracer 7 (kg m**-2)
|
||||
145 145 GRG8DIFF Reactive tracer 8 mass mixing ratio (kg kg**-1)
|
||||
146 146 TCGRG8DIFF Total column GRG tracer 8 (kg m**-2)
|
||||
147 147 GRG9DIFF Reactive tracer 9 mass mixing ratio (kg kg**-1)
|
||||
148 148 TCGRG9DIFF Total column GRG tracer 9 (kg m**-2)
|
||||
149 149 GRG10DIFF Reactive tracer 10 mass mixing ratio (kg kg**-1)
|
||||
150 150 TCGRG10DIFF Total column GRG tracer 10 (kg m**-2)
|
||||
151 151 SFNOXDIFF Surface flux Nitrogen oxides (kg m**-2 s**-1)
|
||||
152 152 SFNO2DIFF Surface flux Nitrogen dioxide (kg m**-2 s**-1)
|
||||
153 153 SFSO2DIFF Surface flux Sulphur dioxide (kg m**-2 s**-1)
|
||||
154 154 SFCO2DIFF Surface flux Carbon monoxide (kg m**-2 s**-1)
|
||||
155 155 SFHCHODIFF Surface flux Formaldehyde (kg m**-2 s**-1)
|
||||
156 156 SFGO3DIFF Surface flux GEMS Ozone (kg m**-2 s**-1)
|
||||
157 157 SFGR1DIFF Surface flux reactive tracer 1 (kg m**-2 s**-1)
|
||||
158 158 SFGR2DIFF Surface flux reactive tracer 2 (kg m**-2 s**-1)
|
||||
159 159 SFGR3DIFF Surface flux reactive tracer 3 (kg m**-2 s**-1)
|
||||
160 160 SFGR4DIFF Surface flux reactive tracer 4 (kg m**-2 s**-1)
|
||||
161 161 SFGR5DIFF Surface flux reactive tracer 5 (kg m**-2 s**-1)
|
||||
162 162 SFGR6DIFF Surface flux reactive tracer 6 (kg m**-2 s**-1)
|
||||
163 163 SFGR7DIFF Surface flux reactive tracer 7 (kg m**-2 s**-1)
|
||||
164 164 SFGR8DIFF Surface flux reactive tracer 8 (kg m**-2 s**-1)
|
||||
165 165 SFGR9DIFF Surface flux reactive tracer 9 (kg m**-2 s**-1)
|
||||
166 166 SFGR10DIFF Surface flux reactive tracer 10 (kg m**-2 s**-1)
|
||||
181 181 RADIFF Radon (kg kg**-1)
|
||||
182 182 SF6DIFF Sulphur Hexafluoride (kg kg**-1)
|
||||
183 183 TCRADIFF Total column Radon (kg m**-2)
|
||||
184 184 TCSF6DIFF Total column Sulphur Hexafluoride (kg m**-2)
|
||||
185 185 SF6APFDIFF Anthropogenic Emissions of Sulphur Hexafluoride (kg m**-2 s**-1)
|
||||
203 203 GO3DIFF GEMS Ozone (kg kg**-1)
|
||||
206 206 GTCO3DIFF GEMS Total column ozone (kg m**-2)
|
||||
207 207 AOD550DIFF Total Aerosol Optical Depth at 550nm (~)
|
||||
208 208 SSAOD550DIFF Sea Salt Aerosol Optical Depth at 550nm (~)
|
||||
209 209 DUAOD550DIFF Dust Aerosol Optical Depth at 550nm (~)
|
||||
210 210 OMAOD550DIFF Organic Matter Aerosol Optical Depth at 550nm (~)
|
||||
211 211 BCAOD550DIFF Black Carbon Aerosol Optical Depth at 550nm (~)
|
||||
212 212 SUAOD550DIFF Sulphate Aerosol Optical Depth at 550nm (~)
|
||||
213 213 AOD469DIFF Total Aerosol Optical Depth at 469nm (~)
|
||||
214 214 AOD670DIFF Total Aerosol Optical Depth at 670nm (~)
|
||||
215 215 AOD865DIFF Total Aerosol Optical Depth at 865nm (~)
|
||||
216 216 AOD1240DIFF Total Aerosol Optical Depth at 1240nm (~)
|
||||
|
|
|
@ -1,2 +1,2 @@
|
|||
# This file was automatically generated by ./param.pl
|
||||
228 228 TPOC Total precipitation observation count dimensionless
|
||||
228 228 TPOC Total precipitation observation count (dimensionless)
|
||||
|
|
|
@ -4,7 +4,7 @@
|
|||
3 3 ZUST Friction velocity (m s**-1)
|
||||
4 4 MEAN2T Mean temperature at 2 metres (K)
|
||||
5 5 MEAN10WS Mean of 10 metre wind speed (m s**-1)
|
||||
6 6 MEANTCC Mean total cloud cover ((0 - 1))
|
||||
6 6 MEANTCC Mean total cloud cover (0 - 1)
|
||||
7 7 DL Lake depth (m)
|
||||
8 8 LMLT Lake mix-layer temperature (K)
|
||||
9 9 LMLD Lake mix-layer depth (m)
|
||||
|
@ -26,6 +26,7 @@
|
|||
26 26 MX2T3 Maximum temperature at 2 metres in the last 3 hours (K)
|
||||
27 27 MN2T3 Minimum temperature at 2 metres in the last 3 hours (K)
|
||||
28 28 10FG3 10 metre wind gust in the last 3 hours (m s**-1)
|
||||
29 29 I10FG Instantaneous 10 metre wind gust (m s**-1)
|
||||
39 39 SM Soil Moisture (kg m**-3)
|
||||
40 40 SWI1 Soil wetness index in layer 1 (dimensionless)
|
||||
41 41 SWI2 Soil wetness index in layer 2 (dimensionless)
|
||||
|
@ -37,12 +38,15 @@
|
|||
83 83 FCO2NEE Flux of Carbon Dioxide Net Ecosystem Exchange (kg m**-2 s**-1)
|
||||
84 84 FCO2GPP Flux of Carbon Dioxide Gross Primary Production (kg m**-2 s**-1)
|
||||
85 85 FCO2REC Flux of Carbon Dioxide Ecosystem Respiration (kg m**-2 s**-1)
|
||||
88 88 TCSLW Total column supercooled liquid water (kg m**-2)
|
||||
89 89 TCRW Total column rain water (kg m**-2)
|
||||
90 90 TCSW Total column snow water (kg m**-2)
|
||||
91 91 CCF Canopy cover fraction ((0 - 1))
|
||||
92 92 STF Soil texture fraction ((0 - 1))
|
||||
91 91 CCF Canopy cover fraction (0 - 1)
|
||||
92 92 STF Soil texture fraction (0 - 1)
|
||||
93 93 SWV Volumetric soil moisture (m**3 m**-3)
|
||||
94 94 IST Ice temperature (K)
|
||||
121 121 KX K index (K)
|
||||
123 123 TOTALX Total totals index (K)
|
||||
129 129 SSRDC Surface solar radiation downward clear-sky (J m**-2)
|
||||
130 130 STRDC Surface thermal radiation downward clear-sky (J m**-2)
|
||||
131 131 U10N Neutral wind at 10 m u-component (m s**-1)
|
||||
|
@ -50,18 +54,29 @@
|
|||
134 134 VTNOWD V-tendency from non-orographic wave drag (m s**-2)
|
||||
136 136 UTNOWD U-tendency from non-orographic wave drag (m s**-2)
|
||||
139 139 ST Soil Temperature (K)
|
||||
141 141 SD Snow depth water equivalent (m)
|
||||
141 141 SD Snow depth water equivalent (kg m**-2)
|
||||
144 144 SF Snow Fall water equivalent (kg m**-2)
|
||||
164 164 TCC Total Cloud Cover (%)
|
||||
170 170 CAP Field capacity (kg m**-3)
|
||||
171 171 WILT Wilting point (kg m**-3)
|
||||
217 217 ILSPF Instantaneous large-scale surface precipitation fraction (0 - 1)
|
||||
218 218 CRR Convective rain rate (kg m**-2 s**-1)
|
||||
219 219 LSRR Large scale rain rate (kg m**-2 s**-1)
|
||||
220 220 CSFR Convective snowfall rate water equivalent (kg m**-2 s**-1)
|
||||
221 221 LSSFR Large scale snowfall rate water equivalent (kg m**-2 s**-1)
|
||||
222 222 MXTPR3 Maximum total precipitation rate in the last 3 hours (kg m**-2 s**-1)
|
||||
223 223 MNTPR3 Minimum total precipitation rate in the last 3 hours (kg m**-2 s**-1)
|
||||
224 224 MXTPR6 Maximum total precipitation rate in the last 6 hours (kg m**-2 s**-1)
|
||||
225 225 MNTPR6 Minimum total precipitation rate in the last 6 hours (kg m**-2 s**-1)
|
||||
226 226 MXTPR Maximum total precipitation rate since previous post-processing (kg m**-2 s**-1)
|
||||
227 227 MNTPR Minimum total precipitation rate since previous post-processing (kg m**-2 s**-1)
|
||||
228 228 TP Total Precipitation (kg m**-2)
|
||||
229 229 SMOS_TB_CDFA SMOS first Brightness Temperature Bias Correction parameter (K)
|
||||
230 230 SMOS_TB_CDFB SMOS second Brightness Temperature Bias Correction parameter (dimensionless)
|
||||
242 242 FDIF Surface solar radiation diffuse total sky (J m**-2)
|
||||
243 243 CDIF Surface solar radiation diffuse clear-sky (J m**-2)
|
||||
244 244 ALDR Surface albedo of direct radiation ((0 - 1))
|
||||
245 245 ALDF Surface albedo of diffuse radiation ((0 - 1))
|
||||
244 244 ALDR Surface albedo of direct radiation (0 - 1)
|
||||
245 245 ALDF Surface albedo of diffuse radiation (0 - 1)
|
||||
246 246 100U 100 metre U wind component (m s**-1)
|
||||
247 247 100V 100 metre V wind component (m s**-1)
|
||||
249 249 100SI 100 metre wind speed (m s**-1)
|
||||
|
|
|
@ -3,36 +3,36 @@
|
|||
9 9 SSROVAR Sub-surface runoff (variable resolution) (m)
|
||||
21 21 FDIRVAR Total sky direct solar radiation at surface (variable resolution) (J m**-2)
|
||||
22 22 CDIRVAR Clear-sky direct solar radiation at surface (variable resolution) (J m**-2)
|
||||
44 44 ESVAR Snow evaporation (variable resolution) m of water
|
||||
45 45 SMLTVAR Snowmelt (variable resolution) m of water
|
||||
44 44 ESVAR Snow evaporation (variable resolution) (kg m**-2)
|
||||
45 45 SMLTVAR Snowmelt (variable resolution) (kg m**-2)
|
||||
46 46 SDURVAR Solar duration (variable resolution) (s)
|
||||
57 57 UVBVAR Downward UV radiation at the surface (variable resolution) (w m**-2 s)
|
||||
58 58 PARVAR Photosynthetically active radiation at the surface (variable resolution) (w m**-2 s)
|
||||
57 57 UVBVAR Downward UV radiation at the surface (variable resolution) (J m**-2)
|
||||
58 58 PARVAR Photosynthetically active radiation at the surface (variable resolution) (J m**-2)
|
||||
142 142 LSPVAR Stratiform precipitation (Large-scale precipitation) (variable resolution) (m)
|
||||
143 143 CPVAR Convective precipitation (variable resolution) (m)
|
||||
144 144 SFVAR Snowfall (convective + stratiform) (variable resolution) m of water equivalent
|
||||
145 145 BLDVAR Boundary layer dissipation (variable resolution) (W m**-2 s)
|
||||
146 146 SSHFVAR Surface sensible heat flux (variable resolution) (W m**-2 s)
|
||||
147 147 SLHFVAR Surface latent heat flux (variable resolution) (W m**-2 s)
|
||||
169 169 SSRDVAR Surface solar radiation downwards (variable resolution) (W m**-2 s)
|
||||
174 174 ALVAR Albedo (variable resolution) ((0 - 1))
|
||||
175 175 STRDVAR Surface thermal radiation downwards (variable resolution) (W m**-2 s)
|
||||
176 176 SSRVAR Surface solar radiation (variable resolution) (W m**-2 s)
|
||||
177 177 STRVAR Surface thermal radiation (variable resolution) (W m**-2 s)
|
||||
178 178 TSRVAR Top solar radiation (variable resolution) (W m**-2 s)
|
||||
179 179 TTRVAR Top thermal radiation (variable resolution) (W m**-2 s)
|
||||
144 144 SFVAR Snowfall (convective + stratiform) (variable resolution) (m of water equivalent)
|
||||
145 145 BLDVAR Boundary layer dissipation (variable resolution) (J m**-2)
|
||||
146 146 SSHFVAR Surface sensible heat flux (variable resolution) (J m**-2)
|
||||
147 147 SLHFVAR Surface latent heat flux (variable resolution) (J m**-2)
|
||||
169 169 SSRDVAR Surface solar radiation downwards (variable resolution) (J m**-2)
|
||||
174 174 ALVAR Albedo (variable resolution) (0 - 1)
|
||||
175 175 STRDVAR Surface thermal radiation downwards (variable resolution) (J m**-2)
|
||||
176 176 SSRVAR Surface net solar radiation (variable resolution) (J m**-2)
|
||||
177 177 STRVAR Surface net thermal radiation (variable resolution) (J m**-2)
|
||||
178 178 TSRVAR Top net solar radiation (variable resolution) (J m**-2)
|
||||
179 179 TTRVAR Top net thermal radiation (variable resolution) (J m**-2)
|
||||
180 180 EWSSVAR East-West surface stress (variable resolution) (N m**-2 s)
|
||||
181 181 NSSSVAR North-South surface stress (variable resolution) (N m**-2 s)
|
||||
182 182 EVAR Evaporation (variable resolution) m of water
|
||||
182 182 EVAR Evaporation (variable resolution) (kg m**-2)
|
||||
189 189 SUNDVAR Sunshine duration (variable resolution) (s)
|
||||
195 195 LGWSVAR Longitudinal component of gravity wave stress (variable resolution) (N m**-2 s)
|
||||
196 196 MGWSVAR Meridional component of gravity wave stress (variable resolution) (N m**-2 s)
|
||||
197 197 GWDVAR Gravity wave dissipation (variable resolution) (W m**-2 s)
|
||||
198 198 SRCVAR Skin reservoir content (variable resolution) m of water
|
||||
197 197 GWDVAR Gravity wave dissipation (variable resolution) (J m**-2)
|
||||
198 198 SRCVAR Skin reservoir content (variable resolution) (kg m**-2)
|
||||
205 205 ROVAR Runoff (variable resolution) (m)
|
||||
208 208 TSRCVAR Top net solar radiation, clear sky (variable resolution) (W m**-2 s)
|
||||
209 209 TTRCVAR Top net thermal radiation, clear sky (variable resolution) (W m**-2 s)
|
||||
210 210 SSRCVAR Surface net solar radiation, clear sky (variable resolution) (W m**-2 s)
|
||||
211 211 STRCVAR Surface net thermal radiation, clear sky (variable resolution) (W m**-2 s)
|
||||
212 212 TISRVAR TOA incident solar radiation (variable resolution) (W m**-2 s)
|
||||
208 208 TSRCVAR Top net solar radiation, clear sky (variable resolution) (J m**-2)
|
||||
209 209 TTRCVAR Top net thermal radiation, clear sky (variable resolution) (J m**-2)
|
||||
210 210 SSRCVAR Surface net solar radiation, clear sky (variable resolution) (J m**-2)
|
||||
211 211 STRCVAR Surface net thermal radiation, clear sky (variable resolution) (J m**-2)
|
||||
212 212 TISRVAR TOA incident solar radiation (variable resolution) (J m**-2)
|
||||
228 228 TPVAR Total precipitation (variable resolution) (m)
|
||||
|
|
|
@ -77,10 +77,20 @@ if(bitmapPresent) {
|
|||
): read_only;
|
||||
alias data.packedValues = codedValues;
|
||||
|
||||
if (boustrophedonicOrdering) {
|
||||
if (boustrophedonicOrdering)
|
||||
{
|
||||
if (GRIBEX_boustrophedonic)
|
||||
{
|
||||
meta preBitmapValues data_apply_boustrophedonic_bitmap(codedValues,bitmap,missingValue,binaryScaleFactor,numberOfRows,numberOfColumns,numberOfPoints): read_only;
|
||||
}
|
||||
else
|
||||
{
|
||||
meta preBitmapValues data_apply_bitmap(codedValues,bitmap,missingValue,binaryScaleFactor) : read_only;
|
||||
}
|
||||
meta values data_apply_boustrophedonic(preBitmapValues,numberOfRows,numberOfColumns,numberOfPoints,pl) : dump;
|
||||
} else {
|
||||
}
|
||||
else
|
||||
{
|
||||
meta values data_apply_bitmap(codedValues,bitmap,missingValue,binaryScaleFactor) : dump;
|
||||
}
|
||||
} else {
|
||||
|
|
|
@ -55,10 +55,21 @@ if(bitmapPresent) {
|
|||
|
||||
): read_only;
|
||||
alias data.packedValues = codedValues;
|
||||
if (boustrophedonicOrdering) {
|
||||
|
||||
if (boustrophedonicOrdering)
|
||||
{
|
||||
if (GRIBEX_boustrophedonic)
|
||||
{
|
||||
meta preBitmapValues data_apply_boustrophedonic_bitmap(codedValues,bitmap,missingValue,binaryScaleFactor,numberOfRows,numberOfColumns,numberOfPoints): read_only;
|
||||
}
|
||||
else
|
||||
{
|
||||
meta preBitmapValues data_apply_bitmap(codedValues,bitmap,missingValue,binaryScaleFactor) : read_only;
|
||||
}
|
||||
meta values data_apply_boustrophedonic(preBitmapValues,numberOfRows,numberOfColumns,numberOfPoints,pl) : dump;
|
||||
} else {
|
||||
}
|
||||
else
|
||||
{
|
||||
meta values data_apply_bitmap(codedValues,bitmap,missingValue,binaryScaleFactor) : dump;
|
||||
}
|
||||
|
||||
|
|
|
@ -55,10 +55,21 @@ if(bitmapPresent) {
|
|||
|
||||
): read_only;
|
||||
alias data.packedValues = codedValues;
|
||||
if (boustrophedonicOrdering) {
|
||||
|
||||
if (boustrophedonicOrdering)
|
||||
{
|
||||
if (GRIBEX_boustrophedonic)
|
||||
{
|
||||
meta preBitmapValues data_apply_boustrophedonic_bitmap(codedValues,bitmap,missingValue,binaryScaleFactor,numberOfRows,numberOfColumns,numberOfPoints): read_only;
|
||||
}
|
||||
else
|
||||
{
|
||||
meta preBitmapValues data_apply_bitmap(codedValues,bitmap,missingValue,binaryScaleFactor) : read_only;
|
||||
}
|
||||
meta values data_apply_boustrophedonic(preBitmapValues,numberOfRows,numberOfColumns,numberOfPoints,pl) : dump;
|
||||
} else {
|
||||
}
|
||||
else
|
||||
{
|
||||
meta values data_apply_bitmap(codedValues,bitmap,missingValue,binaryScaleFactor) : dump;
|
||||
}
|
||||
|
||||
|
|
|
@ -1,4 +1,4 @@
|
|||
# Automatically generated by get_definitions.sql from database PRJ_TDCFDOKU.GRIB_PARAMETER@MIRAKEL.DWD.DE, do not edit! 2014-02-10 16:05
|
||||
# Automatically generated by get_definitions.sql from database PRJ_TDCFDOKU.GRIB_PARAMETER@MIRAKEL.DWD.DE, do not edit! 2014-06-11 07:14
|
||||
#paramId: 500000
|
||||
#Pressure (S) (not reduced)
|
||||
'Pressure (S) (not reduced)' = {
|
||||
|
@ -262,14 +262,6 @@
|
|||
indicatorOfParameter = 40 ;
|
||||
}
|
||||
|
||||
#paramId: 500033
|
||||
#Specific Humidity (S)
|
||||
'Specific Humidity (S)' = {
|
||||
table2Version = 2 ;
|
||||
indicatorOfParameter = 51 ;
|
||||
indicatorOfTypeOfLevel = 1 ;
|
||||
}
|
||||
|
||||
#paramId: 500034
|
||||
#Specific Humidity (2m)
|
||||
'Specific Humidity (2m)' = {
|
||||
|
@ -8917,3 +8909,18 @@
|
|||
indicatorOfParameter = 46 ;
|
||||
}
|
||||
|
||||
#paramId: 503076
|
||||
#Gravity wave dissipation
|
||||
'Gravity wave dissipation ' = {
|
||||
table2Version = 202 ;
|
||||
indicatorOfParameter = 233 ;
|
||||
timeRangeIndicator = 3 ;
|
||||
}
|
||||
|
||||
#paramId: 503078
|
||||
#relative humidity over mixed phase
|
||||
'relative humidity over mixed phase' = {
|
||||
table2Version = 250 ;
|
||||
indicatorOfParameter = 20 ;
|
||||
}
|
||||
|
||||
|
|
|
@ -1,4 +1,4 @@
|
|||
# Automatically generated by get_definitions.sql from database PRJ_TDCFDOKU.GRIB_PARAMETER@MIRAKEL.DWD.DE,do not edit! 2014-02-10 16:05
|
||||
# Automatically generated by get_definitions.sql from database PRJ_TDCFDOKU.GRIB_PARAMETER@MIRAKEL.DWD.DE,do not edit! 2014-06-11 07:14
|
||||
#paramId: 500000
|
||||
#Pressure (S) (not reduced)
|
||||
'500000' = {
|
||||
|
@ -262,14 +262,6 @@
|
|||
indicatorOfParameter = 40 ;
|
||||
}
|
||||
|
||||
#paramId: 500033
|
||||
#Specific Humidity (S)
|
||||
'500033' = {
|
||||
table2Version = 2 ;
|
||||
indicatorOfParameter = 51 ;
|
||||
indicatorOfTypeOfLevel = 1 ;
|
||||
}
|
||||
|
||||
#paramId: 500034
|
||||
#Specific Humidity (2m)
|
||||
'500034' = {
|
||||
|
@ -8917,3 +8909,18 @@
|
|||
indicatorOfParameter = 46 ;
|
||||
}
|
||||
|
||||
#paramId: 503076
|
||||
#Gravity wave dissipation
|
||||
'503076' = {
|
||||
table2Version = 202 ;
|
||||
indicatorOfParameter = 233 ;
|
||||
timeRangeIndicator = 3 ;
|
||||
}
|
||||
|
||||
#paramId: 503078
|
||||
#relative humidity over mixed phase
|
||||
'503078' = {
|
||||
table2Version = 250 ;
|
||||
indicatorOfParameter = 20 ;
|
||||
}
|
||||
|
||||
|
|
|
@ -1,4 +1,4 @@
|
|||
# Automatically generated by get_definitions.sql from database PRJ_TDCFDOKU.GRIB_PARAMETER@MIRAKEL.DWD.DE, do not edit! 2014-02-10 16:05
|
||||
# Automatically generated by get_definitions.sql from database PRJ_TDCFDOKU.GRIB_PARAMETER@MIRAKEL.DWD.DE, do not edit! 2014-06-11 07:14
|
||||
#paramId: 500000
|
||||
#Pressure (S) (not reduced)
|
||||
'PS' = {
|
||||
|
@ -262,14 +262,6 @@
|
|||
indicatorOfParameter = 40 ;
|
||||
}
|
||||
|
||||
#paramId: 500033
|
||||
#Specific Humidity (S)
|
||||
'QV_S' = {
|
||||
table2Version = 2 ;
|
||||
indicatorOfParameter = 51 ;
|
||||
indicatorOfTypeOfLevel = 1 ;
|
||||
}
|
||||
|
||||
#paramId: 500034
|
||||
#Specific Humidity (2m)
|
||||
'QV_2M' = {
|
||||
|
@ -8917,3 +8909,18 @@
|
|||
indicatorOfParameter = 46 ;
|
||||
}
|
||||
|
||||
#paramId: 503076
|
||||
#Gravity wave dissipation
|
||||
'AVDIS_SSO' = {
|
||||
table2Version = 202 ;
|
||||
indicatorOfParameter = 233 ;
|
||||
timeRangeIndicator = 3 ;
|
||||
}
|
||||
|
||||
#paramId: 503078
|
||||
#relative humidity over mixed phase
|
||||
'RH_MIX_EC' = {
|
||||
table2Version = 250 ;
|
||||
indicatorOfParameter = 20 ;
|
||||
}
|
||||
|
||||
|
|
|
@ -1,4 +1,4 @@
|
|||
# Automatically generated by get_definitions.sql from database PRJ_TDCFDOKU.GRIB_PARAMETER@MIRAKEL.DWD.DE, do not edit! 2014-02-10 16:05
|
||||
# Automatically generated by get_definitions.sql from database PRJ_TDCFDOKU.GRIB_PARAMETER@MIRAKEL.DWD.DE, do not edit! 2014-06-11 07:14
|
||||
#paramId: 500000
|
||||
#Pressure (S) (not reduced)
|
||||
'Pa' = {
|
||||
|
@ -262,14 +262,6 @@
|
|||
indicatorOfParameter = 40 ;
|
||||
}
|
||||
|
||||
#paramId: 500033
|
||||
#Specific Humidity (S)
|
||||
'kg kg-1' = {
|
||||
table2Version = 2 ;
|
||||
indicatorOfParameter = 51 ;
|
||||
indicatorOfTypeOfLevel = 1 ;
|
||||
}
|
||||
|
||||
#paramId: 500034
|
||||
#Specific Humidity (2m)
|
||||
'kg kg-1' = {
|
||||
|
@ -8917,3 +8909,18 @@
|
|||
indicatorOfParameter = 46 ;
|
||||
}
|
||||
|
||||
#paramId: 503076
|
||||
#Gravity wave dissipation
|
||||
'W m-2' = {
|
||||
table2Version = 202 ;
|
||||
indicatorOfParameter = 233 ;
|
||||
timeRangeIndicator = 3 ;
|
||||
}
|
||||
|
||||
#paramId: 503078
|
||||
#relative humidity over mixed phase
|
||||
'%' = {
|
||||
table2Version = 250 ;
|
||||
indicatorOfParameter = 20 ;
|
||||
}
|
||||
|
||||
|
|
|
@ -68,12 +68,36 @@
|
|||
scaleFactorOfFirstFixedSurface = 0 ;
|
||||
scaledValueOfFirstFixedSurface = 10 ;
|
||||
}
|
||||
#Relative humidity with respect to water
|
||||
'rhw' = {
|
||||
discipline = 0 ;
|
||||
parameterCategory = 1 ;
|
||||
parameterNumber = 93 ;
|
||||
}
|
||||
#Relative humidity with respect to ice
|
||||
'rhi' = {
|
||||
discipline = 0 ;
|
||||
parameterCategory = 1 ;
|
||||
parameterNumber = 94 ;
|
||||
}
|
||||
#Snow albedo
|
||||
'asn' = {
|
||||
discipline = 0 ;
|
||||
parameterCategory = 19 ;
|
||||
parameterNumber = 19 ;
|
||||
}
|
||||
#Fraction of stratiform precipitation cover
|
||||
'fspc' = {
|
||||
discipline = 0 ;
|
||||
parameterCategory = 6 ;
|
||||
parameterNumber = 36 ;
|
||||
}
|
||||
#Fraction of convective precipitation cover
|
||||
'fcpc' = {
|
||||
discipline = 0 ;
|
||||
parameterCategory = 6 ;
|
||||
parameterNumber = 37 ;
|
||||
}
|
||||
#Soil moisture top 20 cm
|
||||
'sm20' = {
|
||||
discipline = 2 ;
|
||||
|
|
|
@ -1,4 +1,4 @@
|
|||
# Automatically generated by get_definitions.sql from database PRJ_TDCFDOKU.GRIB_PARAMETER@MIRAKEL.DWD.DE, do not edit! 2014-02-10 16:05
|
||||
# Automatically generated by get_definitions.sql from database PRJ_TDCFDOKU.GRIB_PARAMETER@MIRAKEL.DWD.DE, do not edit! 2014-06-11 07:14
|
||||
#paramId: 500000
|
||||
#Pressure (S) (not reduced)
|
||||
'Pressure (S) (not reduced)' = {
|
||||
|
@ -312,16 +312,6 @@
|
|||
parameterNumber = 9 ;
|
||||
}
|
||||
|
||||
#paramId: 500033
|
||||
#Specific Humidity (S)
|
||||
'Specific Humidity (S)' = {
|
||||
discipline = 0 ;
|
||||
parameterCategory = 1 ;
|
||||
parameterNumber = 0 ;
|
||||
typeOfFirstFixedSurface = 1 ;
|
||||
scaleFactorOfFirstFixedSurface = 0 ;
|
||||
}
|
||||
|
||||
#paramId: 500034
|
||||
#Specific Humidity (2m)
|
||||
'Specific Humidity (2m)' = {
|
||||
|
@ -1244,6 +1234,70 @@
|
|||
parameterNumber = 6 ;
|
||||
}
|
||||
|
||||
#paramId: 500185
|
||||
#Direction of combined wind waves and swell
|
||||
'Direction of combined wind waves and swell' = {
|
||||
discipline = 10 ;
|
||||
parameterCategory = 0 ;
|
||||
parameterNumber = 14 ;
|
||||
}
|
||||
|
||||
#paramId: 500187
|
||||
#Peak period of total swell
|
||||
'Peak period of total swell' = {
|
||||
discipline = 10 ;
|
||||
parameterCategory = 0 ;
|
||||
parameterNumber = 36 ;
|
||||
}
|
||||
|
||||
#paramId: 500189
|
||||
#Peak period of wind waves
|
||||
'Peak period of wind waves' = {
|
||||
discipline = 10 ;
|
||||
parameterCategory = 0 ;
|
||||
parameterNumber = 35 ;
|
||||
}
|
||||
|
||||
#paramId: 500190
|
||||
#Peak wave period
|
||||
'Peak wave period' = {
|
||||
discipline = 10 ;
|
||||
parameterCategory = 0 ;
|
||||
parameterNumber = 34 ;
|
||||
}
|
||||
|
||||
#paramId: 500191
|
||||
#Mean period of combined wind waves and swell
|
||||
'Mean period of combined wind waves and swell' = {
|
||||
discipline = 10 ;
|
||||
parameterCategory = 0 ;
|
||||
parameterNumber = 15 ;
|
||||
}
|
||||
|
||||
#paramId: 500192
|
||||
#Inverse mean wave frequency
|
||||
'Inverse mean wave frequency' = {
|
||||
discipline = 10 ;
|
||||
parameterCategory = 0 ;
|
||||
parameterNumber = 25 ;
|
||||
}
|
||||
|
||||
#paramId: 500193
|
||||
#Mean zero-crossing wave period
|
||||
'Mean zero-crossing wave period' = {
|
||||
discipline = 10 ;
|
||||
parameterCategory = 0 ;
|
||||
parameterNumber = 28 ;
|
||||
}
|
||||
|
||||
#paramId: 500194
|
||||
#Wave directional width
|
||||
'Wave directional width' = {
|
||||
discipline = 10 ;
|
||||
parameterCategory = 0 ;
|
||||
parameterNumber = 31 ;
|
||||
}
|
||||
|
||||
#paramId: 500200
|
||||
#Standard deviation of sub-grid scale orography
|
||||
'Standard deviation of sub-grid scale orography' = {
|
||||
|
@ -1821,16 +1875,6 @@
|
|||
constituentType = 30175 ;
|
||||
}
|
||||
|
||||
#paramId: 500283
|
||||
#Gravity wave dissipation (initialisation)
|
||||
'Gravity wave dissipation (initialisation)' = {
|
||||
discipline = 0 ;
|
||||
parameterCategory = 3 ;
|
||||
parameterNumber = 23 ;
|
||||
typeOfStatisticalProcessing = 0 ;
|
||||
typeOfGeneratingProcess = 1 ;
|
||||
}
|
||||
|
||||
#paramId: 500284
|
||||
#Gravity wave dissipation (vertical integral)
|
||||
'Gravity wave dissipation (vertical integral)' = {
|
||||
|
@ -3750,6 +3794,14 @@
|
|||
scaledValueOfFirstFixedSurface = 1 ;
|
||||
}
|
||||
|
||||
#paramId: 502397
|
||||
#Virtual Temperature
|
||||
'Virtual Temperature' = {
|
||||
discipline = 0 ;
|
||||
parameterCategory = 0 ;
|
||||
parameterNumber = 1 ;
|
||||
}
|
||||
|
||||
#paramId: 502693
|
||||
#Potential temperature
|
||||
'Potential temperature' = {
|
||||
|
@ -3758,14 +3810,6 @@
|
|||
parameterNumber = 2 ;
|
||||
}
|
||||
|
||||
#paramId: 502698
|
||||
#Virtual temperature
|
||||
'Virtual temperature' = {
|
||||
discipline = 0 ;
|
||||
parameterCategory = 0 ;
|
||||
parameterNumber = 1 ;
|
||||
}
|
||||
|
||||
#paramId: 502700
|
||||
#Boundary layer dissipation
|
||||
'Boundary layer dissipation' = {
|
||||
|
@ -5597,6 +5641,15 @@
|
|||
typeOfFirstFixedSurface = 1 ;
|
||||
}
|
||||
|
||||
#paramId: 503076
|
||||
#Gravity wave dissipation
|
||||
'Gravity wave dissipation ' = {
|
||||
discipline = 0 ;
|
||||
parameterCategory = 3 ;
|
||||
parameterNumber = 23 ;
|
||||
typeOfStatisticalProcessing = 0 ;
|
||||
}
|
||||
|
||||
#paramId: 500092
|
||||
#Solar radiation heating rate
|
||||
'Solar radiation heating rate' = {
|
||||
|
@ -5968,70 +6021,6 @@
|
|||
parameterNumber = 206 ;
|
||||
}
|
||||
|
||||
#paramId: 500185
|
||||
#total wave direction
|
||||
'total wave direction' = {
|
||||
discipline = 10 ;
|
||||
parameterCategory = 0 ;
|
||||
parameterNumber = 192 ;
|
||||
}
|
||||
|
||||
#paramId: 500187
|
||||
#wind sea peak period
|
||||
'wind sea peak period' = {
|
||||
discipline = 10 ;
|
||||
parameterCategory = 0 ;
|
||||
parameterNumber = 193 ;
|
||||
}
|
||||
|
||||
#paramId: 500189
|
||||
#swell peak period
|
||||
'swell peak period' = {
|
||||
discipline = 10 ;
|
||||
parameterCategory = 0 ;
|
||||
parameterNumber = 194 ;
|
||||
}
|
||||
|
||||
#paramId: 500190
|
||||
#total wave peak period
|
||||
'total wave peak period' = {
|
||||
discipline = 10 ;
|
||||
parameterCategory = 0 ;
|
||||
parameterNumber = 195 ;
|
||||
}
|
||||
|
||||
#paramId: 500191
|
||||
#total wave mean period
|
||||
'total wave mean period' = {
|
||||
discipline = 10 ;
|
||||
parameterCategory = 0 ;
|
||||
parameterNumber = 196 ;
|
||||
}
|
||||
|
||||
#paramId: 500192
|
||||
#total Tm1 period
|
||||
'total Tm1 period' = {
|
||||
discipline = 10 ;
|
||||
parameterCategory = 0 ;
|
||||
parameterNumber = 197 ;
|
||||
}
|
||||
|
||||
#paramId: 500193
|
||||
#total Tm2 period
|
||||
'total Tm2 period' = {
|
||||
discipline = 10 ;
|
||||
parameterCategory = 0 ;
|
||||
parameterNumber = 198 ;
|
||||
}
|
||||
|
||||
#paramId: 500194
|
||||
#total directional spread
|
||||
'total directional spread' = {
|
||||
discipline = 10 ;
|
||||
parameterCategory = 0 ;
|
||||
parameterNumber = 199 ;
|
||||
}
|
||||
|
||||
#paramId: 500195
|
||||
#analysis error(standard deviation), geopotential(gpm)
|
||||
'analysis error(standard deviation), geopotential(gpm)' = {
|
||||
|
@ -9644,26 +9633,6 @@
|
|||
typeOfFirstFixedSurface = 1 ;
|
||||
}
|
||||
|
||||
#paramId: 503065
|
||||
#u-momentum flux due to SSO-effects (initialisation)
|
||||
'u-momentum flux due to SSO-effects (initialisation)' = {
|
||||
discipline = 0 ;
|
||||
parameterCategory = 3 ;
|
||||
parameterNumber = 193 ;
|
||||
typeOfStatisticalProcessing = 0 ;
|
||||
typeOfGeneratingProcess = 1 ;
|
||||
}
|
||||
|
||||
#paramId: 503066
|
||||
#v-momentum flux due to SSO-effects (initialisation)
|
||||
'v-momentum flux due to SSO-effects (initialisation)' = {
|
||||
discipline = 0 ;
|
||||
parameterCategory = 3 ;
|
||||
parameterNumber = 194 ;
|
||||
typeOfStatisticalProcessing = 0 ;
|
||||
typeOfGeneratingProcess = 1 ;
|
||||
}
|
||||
|
||||
#paramId: 503068
|
||||
#precipitation, qualified,BRD
|
||||
'precipitation, qualified,BRD' = {
|
||||
|
@ -9726,3 +9695,21 @@
|
|||
parameterNumber = 193 ;
|
||||
}
|
||||
|
||||
#paramId: 503078
|
||||
#relative humidity over mixed phase
|
||||
'relative humidity over mixed phase' = {
|
||||
discipline = 0 ;
|
||||
parameterCategory = 1 ;
|
||||
parameterNumber = 220 ;
|
||||
}
|
||||
|
||||
#paramId: 503079
|
||||
#soil moisture index (multilayers)
|
||||
'soil moisture index (multilayers)' = {
|
||||
discipline = 2 ;
|
||||
parameterCategory = 3 ;
|
||||
parameterNumber = 200 ;
|
||||
typeOfSecondFixedSurface = 106 ;
|
||||
typeOfFirstFixedSurface = 106 ;
|
||||
}
|
||||
|
||||
|
|
|
@ -1,4 +1,4 @@
|
|||
# Automatically generated by get_definitions.sql from database PRJ_TDCFDOKU.GRIB_PARAMETER@MIRAKEL.DWD.DE, do not edit! 2014-02-10 16:05
|
||||
# Automatically generated by get_definitions.sql from database PRJ_TDCFDOKU.GRIB_PARAMETER@MIRAKEL.DWD.DE, do not edit! 2014-06-11 07:14
|
||||
#paramId: 500000
|
||||
#Pressure (S) (not reduced)
|
||||
'500000' = {
|
||||
|
@ -312,16 +312,6 @@
|
|||
parameterNumber = 9 ;
|
||||
}
|
||||
|
||||
#paramId: 500033
|
||||
#Specific Humidity (S)
|
||||
'500033' = {
|
||||
discipline = 0 ;
|
||||
parameterCategory = 1 ;
|
||||
parameterNumber = 0 ;
|
||||
typeOfFirstFixedSurface = 1 ;
|
||||
scaleFactorOfFirstFixedSurface = 0 ;
|
||||
}
|
||||
|
||||
#paramId: 500034
|
||||
#Specific Humidity (2m)
|
||||
'500034' = {
|
||||
|
@ -1616,67 +1606,67 @@
|
|||
}
|
||||
|
||||
#paramId: 500185
|
||||
#total wave direction
|
||||
#Direction of combined wind waves and swell
|
||||
'500185' = {
|
||||
discipline = 10 ;
|
||||
parameterCategory = 0 ;
|
||||
parameterNumber = 192 ;
|
||||
parameterNumber = 14 ;
|
||||
}
|
||||
|
||||
#paramId: 500187
|
||||
#wind sea peak period
|
||||
#Peak period of total swell
|
||||
'500187' = {
|
||||
discipline = 10 ;
|
||||
parameterCategory = 0 ;
|
||||
parameterNumber = 193 ;
|
||||
parameterNumber = 36 ;
|
||||
}
|
||||
|
||||
#paramId: 500189
|
||||
#swell peak period
|
||||
#Peak period of wind waves
|
||||
'500189' = {
|
||||
discipline = 10 ;
|
||||
parameterCategory = 0 ;
|
||||
parameterNumber = 194 ;
|
||||
parameterNumber = 35 ;
|
||||
}
|
||||
|
||||
#paramId: 500190
|
||||
#total wave peak period
|
||||
#Peak wave period
|
||||
'500190' = {
|
||||
discipline = 10 ;
|
||||
parameterCategory = 0 ;
|
||||
parameterNumber = 195 ;
|
||||
parameterNumber = 34 ;
|
||||
}
|
||||
|
||||
#paramId: 500191
|
||||
#total wave mean period
|
||||
#Mean period of combined wind waves and swell
|
||||
'500191' = {
|
||||
discipline = 10 ;
|
||||
parameterCategory = 0 ;
|
||||
parameterNumber = 196 ;
|
||||
parameterNumber = 15 ;
|
||||
}
|
||||
|
||||
#paramId: 500192
|
||||
#total Tm1 period
|
||||
#Inverse mean wave frequency
|
||||
'500192' = {
|
||||
discipline = 10 ;
|
||||
parameterCategory = 0 ;
|
||||
parameterNumber = 197 ;
|
||||
parameterNumber = 25 ;
|
||||
}
|
||||
|
||||
#paramId: 500193
|
||||
#total Tm2 period
|
||||
#Mean zero-crossing wave period
|
||||
'500193' = {
|
||||
discipline = 10 ;
|
||||
parameterCategory = 0 ;
|
||||
parameterNumber = 198 ;
|
||||
parameterNumber = 28 ;
|
||||
}
|
||||
|
||||
#paramId: 500194
|
||||
#total directional spread
|
||||
#Wave directional width
|
||||
'500194' = {
|
||||
discipline = 10 ;
|
||||
parameterCategory = 0 ;
|
||||
parameterNumber = 199 ;
|
||||
parameterNumber = 31 ;
|
||||
}
|
||||
|
||||
#paramId: 500195
|
||||
|
@ -5243,7 +5233,7 @@
|
|||
}
|
||||
|
||||
#paramId: 500583
|
||||
#
|
||||
#Min 2m Temperature (i) Initialisation
|
||||
'500583' = {
|
||||
discipline = 0 ;
|
||||
parameterCategory = 0 ;
|
||||
|
@ -5363,7 +5353,7 @@
|
|||
}
|
||||
|
||||
#paramId: 500600
|
||||
#
|
||||
#Prob Windboeen > 25 kn
|
||||
'500600' = {
|
||||
discipline = 0 ;
|
||||
parameterCategory = 2 ;
|
||||
|
@ -5372,7 +5362,7 @@
|
|||
}
|
||||
|
||||
#paramId: 500601
|
||||
#
|
||||
#Prob Windboeen > 27 kn
|
||||
'500601' = {
|
||||
discipline = 0 ;
|
||||
parameterCategory = 2 ;
|
||||
|
@ -5381,7 +5371,7 @@
|
|||
}
|
||||
|
||||
#paramId: 500602
|
||||
#
|
||||
#Prob Sturmboeen > 33 kn
|
||||
'500602' = {
|
||||
discipline = 0 ;
|
||||
parameterCategory = 2 ;
|
||||
|
@ -5390,7 +5380,7 @@
|
|||
}
|
||||
|
||||
#paramId: 500603
|
||||
#
|
||||
#Prob Sturmboeen > 40 kn
|
||||
'500603' = {
|
||||
discipline = 0 ;
|
||||
parameterCategory = 2 ;
|
||||
|
@ -5399,7 +5389,7 @@
|
|||
}
|
||||
|
||||
#paramId: 500604
|
||||
#
|
||||
#Prob Schwere Sturmboeen > 47 kn
|
||||
'500604' = {
|
||||
discipline = 0 ;
|
||||
parameterCategory = 2 ;
|
||||
|
@ -5408,7 +5398,7 @@
|
|||
}
|
||||
|
||||
#paramId: 500605
|
||||
#
|
||||
#Prob Orkanartige Boeen > 55 kn
|
||||
'500605' = {
|
||||
discipline = 0 ;
|
||||
parameterCategory = 2 ;
|
||||
|
@ -5417,7 +5407,7 @@
|
|||
}
|
||||
|
||||
#paramId: 500606
|
||||
#
|
||||
#Prob Orkanboeen > 63 kn
|
||||
'500606' = {
|
||||
discipline = 0 ;
|
||||
parameterCategory = 2 ;
|
||||
|
@ -5426,7 +5416,7 @@
|
|||
}
|
||||
|
||||
#paramId: 500607
|
||||
#
|
||||
#Prob Oberoertliche Orkanboeen > 75 kn
|
||||
'500607' = {
|
||||
discipline = 0 ;
|
||||
parameterCategory = 2 ;
|
||||
|
@ -5435,7 +5425,7 @@
|
|||
}
|
||||
|
||||
#paramId: 500608
|
||||
#
|
||||
#Prob Starkregen > 10 mm
|
||||
'500608' = {
|
||||
discipline = 0 ;
|
||||
parameterCategory = 1 ;
|
||||
|
@ -5444,7 +5434,7 @@
|
|||
}
|
||||
|
||||
#paramId: 500609
|
||||
#
|
||||
#Prob Heftiger Starkregen > 25 mm
|
||||
'500609' = {
|
||||
discipline = 0 ;
|
||||
parameterCategory = 1 ;
|
||||
|
@ -5453,7 +5443,7 @@
|
|||
}
|
||||
|
||||
#paramId: 500610
|
||||
#
|
||||
#Prob Extrem Heftiger Starkregen > 50 mm
|
||||
'500610' = {
|
||||
discipline = 0 ;
|
||||
parameterCategory = 1 ;
|
||||
|
@ -5462,7 +5452,7 @@
|
|||
}
|
||||
|
||||
#paramId: 500611
|
||||
#
|
||||
#Prob Leichter Schneefall > 0,1 mm
|
||||
'500611' = {
|
||||
discipline = 0 ;
|
||||
parameterCategory = 1 ;
|
||||
|
@ -5471,7 +5461,7 @@
|
|||
}
|
||||
|
||||
#paramId: 500612
|
||||
#
|
||||
#Prob Leichter Schneefall > 0,1 cm
|
||||
'500612' = {
|
||||
discipline = 0 ;
|
||||
parameterCategory = 1 ;
|
||||
|
@ -5480,7 +5470,7 @@
|
|||
}
|
||||
|
||||
#paramId: 500613
|
||||
#
|
||||
#Prob Leichter Schneefall > 0,5 cm
|
||||
'500613' = {
|
||||
discipline = 0 ;
|
||||
parameterCategory = 1 ;
|
||||
|
@ -5489,7 +5479,7 @@
|
|||
}
|
||||
|
||||
#paramId: 500614
|
||||
#
|
||||
#Prob Leichter Schneefall > 1 cm
|
||||
'500614' = {
|
||||
discipline = 0 ;
|
||||
parameterCategory = 1 ;
|
||||
|
@ -5498,7 +5488,7 @@
|
|||
}
|
||||
|
||||
#paramId: 500615
|
||||
#
|
||||
#Prob Schneefall > 5 cm
|
||||
'500615' = {
|
||||
discipline = 0 ;
|
||||
parameterCategory = 1 ;
|
||||
|
@ -5507,7 +5497,7 @@
|
|||
}
|
||||
|
||||
#paramId: 500616
|
||||
#
|
||||
#Prob Starker Schneefall > 10 cm
|
||||
'500616' = {
|
||||
discipline = 0 ;
|
||||
parameterCategory = 1 ;
|
||||
|
@ -5516,7 +5506,7 @@
|
|||
}
|
||||
|
||||
#paramId: 500617
|
||||
#
|
||||
#Prob Extrem starker Schneefall > 25 cm
|
||||
'500617' = {
|
||||
discipline = 0 ;
|
||||
parameterCategory = 1 ;
|
||||
|
@ -5525,7 +5515,7 @@
|
|||
}
|
||||
|
||||
#paramId: 500618
|
||||
#
|
||||
#Prob Frost
|
||||
'500618' = {
|
||||
discipline = 0 ;
|
||||
parameterCategory = 0 ;
|
||||
|
@ -5534,7 +5524,7 @@
|
|||
}
|
||||
|
||||
#paramId: 500619
|
||||
#
|
||||
#Prob Strenger Frost
|
||||
'500619' = {
|
||||
discipline = 0 ;
|
||||
parameterCategory = 0 ;
|
||||
|
@ -8209,6 +8199,14 @@
|
|||
parameterNumber = 226 ;
|
||||
}
|
||||
|
||||
#paramId: 502397
|
||||
#Virtual Temperature
|
||||
'502397' = {
|
||||
discipline = 0 ;
|
||||
parameterCategory = 0 ;
|
||||
parameterNumber = 1 ;
|
||||
}
|
||||
|
||||
#paramId: 502693
|
||||
#Potential temperature
|
||||
'502693' = {
|
||||
|
@ -8217,14 +8215,6 @@
|
|||
parameterNumber = 2 ;
|
||||
}
|
||||
|
||||
#paramId: 502698
|
||||
#Virtual temperature
|
||||
'502698' = {
|
||||
discipline = 0 ;
|
||||
parameterCategory = 0 ;
|
||||
parameterNumber = 1 ;
|
||||
}
|
||||
|
||||
#paramId: 502700
|
||||
#Boundary layer dissipation
|
||||
'502700' = {
|
||||
|
@ -10235,3 +10225,30 @@
|
|||
typeOfFirstFixedSurface = 1 ;
|
||||
}
|
||||
|
||||
#paramId: 503076
|
||||
#Gravity wave dissipation
|
||||
'503076' = {
|
||||
discipline = 0 ;
|
||||
parameterCategory = 3 ;
|
||||
parameterNumber = 23 ;
|
||||
typeOfStatisticalProcessing = 0 ;
|
||||
}
|
||||
|
||||
#paramId: 503078
|
||||
#relative humidity over mixed phase
|
||||
'503078' = {
|
||||
discipline = 0 ;
|
||||
parameterCategory = 1 ;
|
||||
parameterNumber = 220 ;
|
||||
}
|
||||
|
||||
#paramId: 503079
|
||||
#soil moisture index (multilayers)
|
||||
'503079' = {
|
||||
discipline = 2 ;
|
||||
parameterCategory = 3 ;
|
||||
parameterNumber = 200 ;
|
||||
typeOfSecondFixedSurface = 106 ;
|
||||
typeOfFirstFixedSurface = 106 ;
|
||||
}
|
||||
|
||||
|
|
|
@ -1,4 +1,4 @@
|
|||
# Automatically generated by get_definitions.sql from database PRJ_TDCFDOKU.GRIB_PARAMETER@MIRAKEL.DWD.DE, do not edit! 2014-02-10 16:05
|
||||
# Automatically generated by get_definitions.sql from database PRJ_TDCFDOKU.GRIB_PARAMETER@MIRAKEL.DWD.DE, do not edit! 2014-06-11 07:14
|
||||
#paramId: 500000
|
||||
#Pressure (S) (not reduced)
|
||||
'PS' = {
|
||||
|
@ -312,16 +312,6 @@
|
|||
parameterNumber = 9 ;
|
||||
}
|
||||
|
||||
#paramId: 500033
|
||||
#Specific Humidity (S)
|
||||
'QV_S' = {
|
||||
discipline = 0 ;
|
||||
parameterCategory = 1 ;
|
||||
parameterNumber = 0 ;
|
||||
typeOfFirstFixedSurface = 1 ;
|
||||
scaleFactorOfFirstFixedSurface = 0 ;
|
||||
}
|
||||
|
||||
#paramId: 500034
|
||||
#Specific Humidity (2m)
|
||||
'QV_2M' = {
|
||||
|
@ -1244,6 +1234,70 @@
|
|||
parameterNumber = 6 ;
|
||||
}
|
||||
|
||||
#paramId: 500185
|
||||
#Direction of combined wind waves and swell
|
||||
'MWD' = {
|
||||
discipline = 10 ;
|
||||
parameterCategory = 0 ;
|
||||
parameterNumber = 14 ;
|
||||
}
|
||||
|
||||
#paramId: 500187
|
||||
#Peak period of total swell
|
||||
'PPWW' = {
|
||||
discipline = 10 ;
|
||||
parameterCategory = 0 ;
|
||||
parameterNumber = 36 ;
|
||||
}
|
||||
|
||||
#paramId: 500189
|
||||
#Peak period of wind waves
|
||||
'PPPS' = {
|
||||
discipline = 10 ;
|
||||
parameterCategory = 0 ;
|
||||
parameterNumber = 35 ;
|
||||
}
|
||||
|
||||
#paramId: 500190
|
||||
#Peak wave period
|
||||
'PP1D' = {
|
||||
discipline = 10 ;
|
||||
parameterCategory = 0 ;
|
||||
parameterNumber = 34 ;
|
||||
}
|
||||
|
||||
#paramId: 500191
|
||||
#Mean period of combined wind waves and swell
|
||||
'TM10' = {
|
||||
discipline = 10 ;
|
||||
parameterCategory = 0 ;
|
||||
parameterNumber = 15 ;
|
||||
}
|
||||
|
||||
#paramId: 500192
|
||||
#Inverse mean wave frequency
|
||||
'TM01' = {
|
||||
discipline = 10 ;
|
||||
parameterCategory = 0 ;
|
||||
parameterNumber = 25 ;
|
||||
}
|
||||
|
||||
#paramId: 500193
|
||||
#Mean zero-crossing wave period
|
||||
'TM02' = {
|
||||
discipline = 10 ;
|
||||
parameterCategory = 0 ;
|
||||
parameterNumber = 28 ;
|
||||
}
|
||||
|
||||
#paramId: 500194
|
||||
#Wave directional width
|
||||
'SPRD' = {
|
||||
discipline = 10 ;
|
||||
parameterCategory = 0 ;
|
||||
parameterNumber = 31 ;
|
||||
}
|
||||
|
||||
#paramId: 500200
|
||||
#Standard deviation of sub-grid scale orography
|
||||
'SSO_STDH' = {
|
||||
|
@ -1821,16 +1875,6 @@
|
|||
constituentType = 30175 ;
|
||||
}
|
||||
|
||||
#paramId: 500283
|
||||
#Gravity wave dissipation (initialisation)
|
||||
'AVDIS_SSO' = {
|
||||
discipline = 0 ;
|
||||
parameterCategory = 3 ;
|
||||
parameterNumber = 23 ;
|
||||
typeOfStatisticalProcessing = 0 ;
|
||||
typeOfGeneratingProcess = 1 ;
|
||||
}
|
||||
|
||||
#paramId: 500284
|
||||
#Gravity wave dissipation (vertical integral)
|
||||
'VDIS_SSO' = {
|
||||
|
@ -3750,6 +3794,14 @@
|
|||
scaledValueOfFirstFixedSurface = 1 ;
|
||||
}
|
||||
|
||||
#paramId: 502397
|
||||
#Virtual Temperature
|
||||
'' = {
|
||||
discipline = 0 ;
|
||||
parameterCategory = 0 ;
|
||||
parameterNumber = 1 ;
|
||||
}
|
||||
|
||||
#paramId: 502693
|
||||
#Potential temperature
|
||||
'PT' = {
|
||||
|
@ -3758,14 +3810,6 @@
|
|||
parameterNumber = 2 ;
|
||||
}
|
||||
|
||||
#paramId: 502698
|
||||
#Virtual temperature
|
||||
'VTMP' = {
|
||||
discipline = 0 ;
|
||||
parameterCategory = 0 ;
|
||||
parameterNumber = 1 ;
|
||||
}
|
||||
|
||||
#paramId: 502700
|
||||
#Boundary layer dissipation
|
||||
'BLD' = {
|
||||
|
@ -5597,6 +5641,15 @@
|
|||
typeOfFirstFixedSurface = 1 ;
|
||||
}
|
||||
|
||||
#paramId: 503076
|
||||
#Gravity wave dissipation
|
||||
'AVDIS_SSO' = {
|
||||
discipline = 0 ;
|
||||
parameterCategory = 3 ;
|
||||
parameterNumber = 23 ;
|
||||
typeOfStatisticalProcessing = 0 ;
|
||||
}
|
||||
|
||||
#paramId: 500092
|
||||
#Solar radiation heating rate
|
||||
'SOHR_RAD' = {
|
||||
|
@ -5968,70 +6021,6 @@
|
|||
parameterNumber = 206 ;
|
||||
}
|
||||
|
||||
#paramId: 500185
|
||||
#total wave direction
|
||||
'MWD' = {
|
||||
discipline = 10 ;
|
||||
parameterCategory = 0 ;
|
||||
parameterNumber = 192 ;
|
||||
}
|
||||
|
||||
#paramId: 500187
|
||||
#wind sea peak period
|
||||
'PPWW' = {
|
||||
discipline = 10 ;
|
||||
parameterCategory = 0 ;
|
||||
parameterNumber = 193 ;
|
||||
}
|
||||
|
||||
#paramId: 500189
|
||||
#swell peak period
|
||||
'PPPS' = {
|
||||
discipline = 10 ;
|
||||
parameterCategory = 0 ;
|
||||
parameterNumber = 194 ;
|
||||
}
|
||||
|
||||
#paramId: 500190
|
||||
#total wave peak period
|
||||
'PP1D' = {
|
||||
discipline = 10 ;
|
||||
parameterCategory = 0 ;
|
||||
parameterNumber = 195 ;
|
||||
}
|
||||
|
||||
#paramId: 500191
|
||||
#total wave mean period
|
||||
'TM10' = {
|
||||
discipline = 10 ;
|
||||
parameterCategory = 0 ;
|
||||
parameterNumber = 196 ;
|
||||
}
|
||||
|
||||
#paramId: 500192
|
||||
#total Tm1 period
|
||||
'TM01' = {
|
||||
discipline = 10 ;
|
||||
parameterCategory = 0 ;
|
||||
parameterNumber = 197 ;
|
||||
}
|
||||
|
||||
#paramId: 500193
|
||||
#total Tm2 period
|
||||
'TM02' = {
|
||||
discipline = 10 ;
|
||||
parameterCategory = 0 ;
|
||||
parameterNumber = 198 ;
|
||||
}
|
||||
|
||||
#paramId: 500194
|
||||
#total directional spread
|
||||
'SPRD' = {
|
||||
discipline = 10 ;
|
||||
parameterCategory = 0 ;
|
||||
parameterNumber = 199 ;
|
||||
}
|
||||
|
||||
#paramId: 500195
|
||||
#analysis error(standard deviation), geopotential(gpm)
|
||||
'ANA_ERR_FI' = {
|
||||
|
@ -9644,26 +9633,6 @@
|
|||
typeOfFirstFixedSurface = 1 ;
|
||||
}
|
||||
|
||||
#paramId: 503065
|
||||
#u-momentum flux due to SSO-effects (initialisation)
|
||||
'AUSTR_SSO' = {
|
||||
discipline = 0 ;
|
||||
parameterCategory = 3 ;
|
||||
parameterNumber = 193 ;
|
||||
typeOfStatisticalProcessing = 0 ;
|
||||
typeOfGeneratingProcess = 1 ;
|
||||
}
|
||||
|
||||
#paramId: 503066
|
||||
#v-momentum flux due to SSO-effects (initialisation)
|
||||
'AVSTR_SSO' = {
|
||||
discipline = 0 ;
|
||||
parameterCategory = 3 ;
|
||||
parameterNumber = 194 ;
|
||||
typeOfStatisticalProcessing = 0 ;
|
||||
typeOfGeneratingProcess = 1 ;
|
||||
}
|
||||
|
||||
#paramId: 503068
|
||||
#precipitation, qualified,BRD
|
||||
'RADAR_RQ' = {
|
||||
|
@ -9726,3 +9695,21 @@
|
|||
parameterNumber = 193 ;
|
||||
}
|
||||
|
||||
#paramId: 503078
|
||||
#relative humidity over mixed phase
|
||||
'RH_MIX_EC' = {
|
||||
discipline = 0 ;
|
||||
parameterCategory = 1 ;
|
||||
parameterNumber = 220 ;
|
||||
}
|
||||
|
||||
#paramId: 503079
|
||||
#soil moisture index (multilayers)
|
||||
'SMI' = {
|
||||
discipline = 2 ;
|
||||
parameterCategory = 3 ;
|
||||
parameterNumber = 200 ;
|
||||
typeOfSecondFixedSurface = 106 ;
|
||||
typeOfFirstFixedSurface = 106 ;
|
||||
}
|
||||
|
||||
|
|
|
@ -1,4 +1,4 @@
|
|||
# Automatically generated by get_definitions.sql from database PRJ_TDCFDOKU.GRIB_PARAMETER@MIRAKEL.DWD.DE, do not edit! 2014-02-10 16:05
|
||||
# Automatically generated by get_definitions.sql from database PRJ_TDCFDOKU.GRIB_PARAMETER@MIRAKEL.DWD.DE, do not edit! 2014-06-11 07:14
|
||||
#paramId: 500000
|
||||
#Pressure (S) (not reduced)
|
||||
'Pa' = {
|
||||
|
@ -312,16 +312,6 @@
|
|||
parameterNumber = 9 ;
|
||||
}
|
||||
|
||||
#paramId: 500033
|
||||
#Specific Humidity (S)
|
||||
'kg kg-1' = {
|
||||
discipline = 0 ;
|
||||
parameterCategory = 1 ;
|
||||
parameterNumber = 0 ;
|
||||
typeOfFirstFixedSurface = 1 ;
|
||||
scaleFactorOfFirstFixedSurface = 0 ;
|
||||
}
|
||||
|
||||
#paramId: 500034
|
||||
#Specific Humidity (2m)
|
||||
'kg kg-1' = {
|
||||
|
@ -1244,6 +1234,70 @@
|
|||
parameterNumber = 6 ;
|
||||
}
|
||||
|
||||
#paramId: 500185
|
||||
#Direction of combined wind waves and swell
|
||||
'degree true' = {
|
||||
discipline = 10 ;
|
||||
parameterCategory = 0 ;
|
||||
parameterNumber = 14 ;
|
||||
}
|
||||
|
||||
#paramId: 500187
|
||||
#Peak period of total swell
|
||||
's' = {
|
||||
discipline = 10 ;
|
||||
parameterCategory = 0 ;
|
||||
parameterNumber = 36 ;
|
||||
}
|
||||
|
||||
#paramId: 500189
|
||||
#Peak period of wind waves
|
||||
's' = {
|
||||
discipline = 10 ;
|
||||
parameterCategory = 0 ;
|
||||
parameterNumber = 35 ;
|
||||
}
|
||||
|
||||
#paramId: 500190
|
||||
#Peak wave period
|
||||
's' = {
|
||||
discipline = 10 ;
|
||||
parameterCategory = 0 ;
|
||||
parameterNumber = 34 ;
|
||||
}
|
||||
|
||||
#paramId: 500191
|
||||
#Mean period of combined wind waves and swell
|
||||
's' = {
|
||||
discipline = 10 ;
|
||||
parameterCategory = 0 ;
|
||||
parameterNumber = 15 ;
|
||||
}
|
||||
|
||||
#paramId: 500192
|
||||
#Inverse mean wave frequency
|
||||
's' = {
|
||||
discipline = 10 ;
|
||||
parameterCategory = 0 ;
|
||||
parameterNumber = 25 ;
|
||||
}
|
||||
|
||||
#paramId: 500193
|
||||
#Mean zero-crossing wave period
|
||||
's' = {
|
||||
discipline = 10 ;
|
||||
parameterCategory = 0 ;
|
||||
parameterNumber = 28 ;
|
||||
}
|
||||
|
||||
#paramId: 500194
|
||||
#Wave directional width
|
||||
'degree true' = {
|
||||
discipline = 10 ;
|
||||
parameterCategory = 0 ;
|
||||
parameterNumber = 31 ;
|
||||
}
|
||||
|
||||
#paramId: 500200
|
||||
#Standard deviation of sub-grid scale orography
|
||||
'm' = {
|
||||
|
@ -1821,16 +1875,6 @@
|
|||
constituentType = 30175 ;
|
||||
}
|
||||
|
||||
#paramId: 500283
|
||||
#Gravity wave dissipation (initialisation)
|
||||
'W m-2' = {
|
||||
discipline = 0 ;
|
||||
parameterCategory = 3 ;
|
||||
parameterNumber = 23 ;
|
||||
typeOfStatisticalProcessing = 0 ;
|
||||
typeOfGeneratingProcess = 1 ;
|
||||
}
|
||||
|
||||
#paramId: 500284
|
||||
#Gravity wave dissipation (vertical integral)
|
||||
'W m-2' = {
|
||||
|
@ -3750,6 +3794,14 @@
|
|||
scaledValueOfFirstFixedSurface = 1 ;
|
||||
}
|
||||
|
||||
#paramId: 502397
|
||||
#Virtual Temperature
|
||||
'K' = {
|
||||
discipline = 0 ;
|
||||
parameterCategory = 0 ;
|
||||
parameterNumber = 1 ;
|
||||
}
|
||||
|
||||
#paramId: 502693
|
||||
#Potential temperature
|
||||
'K' = {
|
||||
|
@ -3758,14 +3810,6 @@
|
|||
parameterNumber = 2 ;
|
||||
}
|
||||
|
||||
#paramId: 502698
|
||||
#Virtual temperature
|
||||
'K' = {
|
||||
discipline = 0 ;
|
||||
parameterCategory = 0 ;
|
||||
parameterNumber = 1 ;
|
||||
}
|
||||
|
||||
#paramId: 502700
|
||||
#Boundary layer dissipation
|
||||
'' = {
|
||||
|
@ -5597,6 +5641,15 @@
|
|||
typeOfFirstFixedSurface = 1 ;
|
||||
}
|
||||
|
||||
#paramId: 503076
|
||||
#Gravity wave dissipation
|
||||
'W m-2' = {
|
||||
discipline = 0 ;
|
||||
parameterCategory = 3 ;
|
||||
parameterNumber = 23 ;
|
||||
typeOfStatisticalProcessing = 0 ;
|
||||
}
|
||||
|
||||
#paramId: 500092
|
||||
#Solar radiation heating rate
|
||||
'K s-1' = {
|
||||
|
@ -5968,70 +6021,6 @@
|
|||
parameterNumber = 206 ;
|
||||
}
|
||||
|
||||
#paramId: 500185
|
||||
#total wave direction
|
||||
'degree true' = {
|
||||
discipline = 10 ;
|
||||
parameterCategory = 0 ;
|
||||
parameterNumber = 192 ;
|
||||
}
|
||||
|
||||
#paramId: 500187
|
||||
#wind sea peak period
|
||||
's' = {
|
||||
discipline = 10 ;
|
||||
parameterCategory = 0 ;
|
||||
parameterNumber = 193 ;
|
||||
}
|
||||
|
||||
#paramId: 500189
|
||||
#swell peak period
|
||||
's' = {
|
||||
discipline = 10 ;
|
||||
parameterCategory = 0 ;
|
||||
parameterNumber = 194 ;
|
||||
}
|
||||
|
||||
#paramId: 500190
|
||||
#total wave peak period
|
||||
's' = {
|
||||
discipline = 10 ;
|
||||
parameterCategory = 0 ;
|
||||
parameterNumber = 195 ;
|
||||
}
|
||||
|
||||
#paramId: 500191
|
||||
#total wave mean period
|
||||
's' = {
|
||||
discipline = 10 ;
|
||||
parameterCategory = 0 ;
|
||||
parameterNumber = 196 ;
|
||||
}
|
||||
|
||||
#paramId: 500192
|
||||
#total Tm1 period
|
||||
's' = {
|
||||
discipline = 10 ;
|
||||
parameterCategory = 0 ;
|
||||
parameterNumber = 197 ;
|
||||
}
|
||||
|
||||
#paramId: 500193
|
||||
#total Tm2 period
|
||||
's' = {
|
||||
discipline = 10 ;
|
||||
parameterCategory = 0 ;
|
||||
parameterNumber = 198 ;
|
||||
}
|
||||
|
||||
#paramId: 500194
|
||||
#total directional spread
|
||||
'degree true' = {
|
||||
discipline = 10 ;
|
||||
parameterCategory = 0 ;
|
||||
parameterNumber = 199 ;
|
||||
}
|
||||
|
||||
#paramId: 500195
|
||||
#analysis error(standard deviation), geopotential(gpm)
|
||||
'gpm' = {
|
||||
|
@ -9644,26 +9633,6 @@
|
|||
typeOfFirstFixedSurface = 1 ;
|
||||
}
|
||||
|
||||
#paramId: 503065
|
||||
#u-momentum flux due to SSO-effects (initialisation)
|
||||
'N m-2' = {
|
||||
discipline = 0 ;
|
||||
parameterCategory = 3 ;
|
||||
parameterNumber = 193 ;
|
||||
typeOfStatisticalProcessing = 0 ;
|
||||
typeOfGeneratingProcess = 1 ;
|
||||
}
|
||||
|
||||
#paramId: 503066
|
||||
#v-momentum flux due to SSO-effects (initialisation)
|
||||
'N m-2' = {
|
||||
discipline = 0 ;
|
||||
parameterCategory = 3 ;
|
||||
parameterNumber = 194 ;
|
||||
typeOfStatisticalProcessing = 0 ;
|
||||
typeOfGeneratingProcess = 1 ;
|
||||
}
|
||||
|
||||
#paramId: 503068
|
||||
#precipitation, qualified,BRD
|
||||
'kg m-2' = {
|
||||
|
@ -9726,3 +9695,21 @@
|
|||
parameterNumber = 193 ;
|
||||
}
|
||||
|
||||
#paramId: 503078
|
||||
#relative humidity over mixed phase
|
||||
'%' = {
|
||||
discipline = 0 ;
|
||||
parameterCategory = 1 ;
|
||||
parameterNumber = 220 ;
|
||||
}
|
||||
|
||||
#paramId: 503079
|
||||
#soil moisture index (multilayers)
|
||||
'1' = {
|
||||
discipline = 2 ;
|
||||
parameterCategory = 3 ;
|
||||
parameterNumber = 200 ;
|
||||
typeOfSecondFixedSurface = 106 ;
|
||||
typeOfFirstFixedSurface = 106 ;
|
||||
}
|
||||
|
||||
|
|
|
@ -68,12 +68,36 @@
|
|||
scaleFactorOfFirstFixedSurface = 0 ;
|
||||
typeOfStatisticalProcessing = 2 ;
|
||||
}
|
||||
#Relative humidity with respect to water
|
||||
'Relative humidity with respect to water' = {
|
||||
discipline = 0 ;
|
||||
parameterCategory = 1 ;
|
||||
parameterNumber = 93 ;
|
||||
}
|
||||
#Relative humidity with respect to ice
|
||||
'Relative humidity with respect to ice' = {
|
||||
discipline = 0 ;
|
||||
parameterCategory = 1 ;
|
||||
parameterNumber = 94 ;
|
||||
}
|
||||
#Snow albedo
|
||||
'Snow albedo' = {
|
||||
discipline = 0 ;
|
||||
parameterCategory = 19 ;
|
||||
parameterNumber = 19 ;
|
||||
}
|
||||
#Fraction of stratiform precipitation cover
|
||||
'Fraction of stratiform precipitation cover' = {
|
||||
discipline = 0 ;
|
||||
parameterCategory = 6 ;
|
||||
parameterNumber = 36 ;
|
||||
}
|
||||
#Fraction of convective precipitation cover
|
||||
'Fraction of convective precipitation cover' = {
|
||||
discipline = 0 ;
|
||||
parameterCategory = 6 ;
|
||||
parameterNumber = 37 ;
|
||||
}
|
||||
#Soil moisture top 20 cm
|
||||
'Soil moisture top 20 cm' = {
|
||||
discipline = 2 ;
|
||||
|
|
|
@ -68,12 +68,36 @@
|
|||
scaleFactorOfFirstFixedSurface = 0 ;
|
||||
scaledValueOfFirstFixedSurface = 10 ;
|
||||
}
|
||||
#Relative humidity with respect to water
|
||||
'228030' = {
|
||||
discipline = 0 ;
|
||||
parameterCategory = 1 ;
|
||||
parameterNumber = 93 ;
|
||||
}
|
||||
#Relative humidity with respect to ice
|
||||
'228031' = {
|
||||
discipline = 0 ;
|
||||
parameterCategory = 1 ;
|
||||
parameterNumber = 94 ;
|
||||
}
|
||||
#Snow albedo
|
||||
'228032' = {
|
||||
discipline = 0 ;
|
||||
parameterCategory = 19 ;
|
||||
parameterNumber = 19 ;
|
||||
}
|
||||
#Fraction of stratiform precipitation cover
|
||||
'228033' = {
|
||||
discipline = 0 ;
|
||||
parameterCategory = 6 ;
|
||||
parameterNumber = 36 ;
|
||||
}
|
||||
#Fraction of convective precipitation cover
|
||||
'228034' = {
|
||||
discipline = 0 ;
|
||||
parameterCategory = 6 ;
|
||||
parameterNumber = 37 ;
|
||||
}
|
||||
#Soil moisture top 20 cm
|
||||
'228086' = {
|
||||
discipline = 2 ;
|
||||
|
|
|
@ -68,12 +68,36 @@
|
|||
scaledValueOfFirstFixedSurface = 10 ;
|
||||
typeOfStatisticalProcessing = 2 ;
|
||||
}
|
||||
#Relative humidity with respect to water
|
||||
'rhw' = {
|
||||
discipline = 0 ;
|
||||
parameterCategory = 1 ;
|
||||
parameterNumber = 93 ;
|
||||
}
|
||||
#Relative humidity with respect to ice
|
||||
'rhi' = {
|
||||
discipline = 0 ;
|
||||
parameterCategory = 1 ;
|
||||
parameterNumber = 94 ;
|
||||
}
|
||||
#Snow albedo
|
||||
'asn' = {
|
||||
discipline = 0 ;
|
||||
parameterCategory = 19 ;
|
||||
parameterNumber = 19 ;
|
||||
}
|
||||
#Fraction of stratiform precipitation cover
|
||||
'fspc' = {
|
||||
discipline = 0 ;
|
||||
parameterCategory = 6 ;
|
||||
parameterNumber = 36 ;
|
||||
}
|
||||
#Fraction of convective precipitation cover
|
||||
'fcpc' = {
|
||||
discipline = 0 ;
|
||||
parameterCategory = 6 ;
|
||||
parameterNumber = 37 ;
|
||||
}
|
||||
#Soil moisture top 20 cm
|
||||
'sm20' = {
|
||||
discipline = 2 ;
|
||||
|
|
|
@ -5,6 +5,11 @@
|
|||
3 3 Freezing rain
|
||||
4 4 Mixed/ice
|
||||
5 5 Snow
|
||||
# 6-191 Reserved
|
||||
6 6 Wet snow
|
||||
7 7 Mixture of rain and snow
|
||||
8 8 Ice pellets
|
||||
9 9 Graupel
|
||||
10 10 Hail
|
||||
# 11-191 Reserved
|
||||
# 192-254 Reserved for local use
|
||||
255 255 Missing
|
||||
|
|
|
@ -7,7 +7,6 @@
|
|||
# virtue of its status as an intergovernmental organisation nor does it submit to any jurisdiction.
|
||||
#
|
||||
|
||||
|
||||
# TEMPLATE 3.100, Triangular grid based on an icosahedron (see Attachment I.2-GRIB-Att.)
|
||||
|
||||
# n2 - exponent of 2 for the number of intervals on main triangle sides
|
||||
|
@ -25,14 +24,15 @@ alias numberOfDiamonds=nd;
|
|||
|
||||
# Latitude of the pole point of the icosahedron on the sphere
|
||||
signed[4] latitudeOfThePolePoint : dump ;
|
||||
meta geography.latitudeOfThePolePointInDegrees scale(latitudeOfThePolePoint,one,grib2divider,truncateDegrees) : dump;
|
||||
|
||||
# Longitude of the pole point of the icosahedron on the sphere
|
||||
unsigned[4] longitudeOfThePolePoint : dump ;
|
||||
meta longitudeOfThePolePointInDegrees g2lon(longitudeOfThePolePoint);
|
||||
meta geography.longitudeOfThePolePointInDegrees g2lon(longitudeOfThePolePoint);
|
||||
|
||||
# Longitude of the centre line of the first diamond of the icosahedron on the sphere
|
||||
unsigned[4] longitudeOfFirstDiamondCenterLine : dump ;
|
||||
meta longitudeOfFirstDiamondCenterLineInDegrees g2lon(longitudeOfFirstDiamondCenterLine);
|
||||
meta geography.longitudeOfFirstDiamondCenterLineInDegrees g2lon(longitudeOfFirstDiamondCenterLine);
|
||||
|
||||
# Grid point position
|
||||
codetable[1] gridPointPosition ('3.8.table',masterDir,localDir);
|
||||
|
|
|
@ -9,6 +9,8 @@
|
|||
|
||||
# TEMPLATE 4.44, Analysis or forecast at a horizontal level or in a horizontal layer at a point in time
|
||||
|
||||
include "template.4.parameter_aerosol.def";
|
||||
# GRIB-530: Special case for aerosol thanks to WMO error
|
||||
include "template.4.parameter_aerosol_44.def";
|
||||
|
||||
include "template.4.point_in_time.def";
|
||||
include "template.4.horizontal.def";
|
||||
|
|
|
@ -68,12 +68,36 @@
|
|||
scaleFactorOfFirstFixedSurface = 0 ;
|
||||
typeOfStatisticalProcessing = 2 ;
|
||||
}
|
||||
#Relative humidity with respect to water
|
||||
'%' = {
|
||||
discipline = 0 ;
|
||||
parameterCategory = 1 ;
|
||||
parameterNumber = 93 ;
|
||||
}
|
||||
#Relative humidity with respect to ice
|
||||
'%' = {
|
||||
discipline = 0 ;
|
||||
parameterCategory = 1 ;
|
||||
parameterNumber = 94 ;
|
||||
}
|
||||
#Snow albedo
|
||||
'%' = {
|
||||
discipline = 0 ;
|
||||
parameterCategory = 19 ;
|
||||
parameterNumber = 19 ;
|
||||
}
|
||||
#Fraction of stratiform precipitation cover
|
||||
'Proportion' = {
|
||||
discipline = 0 ;
|
||||
parameterCategory = 6 ;
|
||||
parameterNumber = 36 ;
|
||||
}
|
||||
#Fraction of convective precipitation cover
|
||||
'Proportion' = {
|
||||
discipline = 0 ;
|
||||
parameterCategory = 6 ;
|
||||
parameterNumber = 37 ;
|
||||
}
|
||||
#Soil moisture top 20 cm
|
||||
'kg m**-3' = {
|
||||
discipline = 2 ;
|
||||
|
|
|
@ -8,6 +8,7 @@ foreach my $d ( sort @sub )
|
|||
{
|
||||
process($d) unless $d =~ /bufr/;
|
||||
}
|
||||
print "EXTRA_DIST=CMakeLists.txt\n\n";
|
||||
print "include \$(DEVEL_RULES)\n";
|
||||
|
||||
sub navigate {
|
||||
|
|
|
@ -30,6 +30,7 @@ list( APPEND test_bins
|
|||
iterator_bitmap
|
||||
large_grib1
|
||||
clone
|
||||
check_gaussian_grid
|
||||
)
|
||||
foreach( tool ${test_bins} )
|
||||
ecbuild_add_executable( TARGET ${tool}
|
||||
|
|
|
@ -6,7 +6,8 @@ TESTS = iterator.sh get.sh print_data.sh set.sh keys_iterator.sh multi.sh multi_
|
|||
|
||||
noinst_PROGRAMS = nearest set_bitmap iterator get print_data set set_missing keys_iterator \
|
||||
set_data mars_param values_check box multi multi2 multi_write precision \
|
||||
set_pv list sections_copy large_grib1 get_data iterator_bitmap clone
|
||||
set_pv list sections_copy large_grib1 get_data iterator_bitmap clone new_sample \
|
||||
check_gaussian_grid
|
||||
bin_PROGRAMS = points
|
||||
|
||||
box_SOURCES = box.c
|
||||
|
@ -32,11 +33,13 @@ sections_copy_SOURCES = sections_copy.c
|
|||
large_grib1_SOURCES = large_grib1.c
|
||||
get_data_SOURCES = get_data.c
|
||||
clone_SOURCES = clone.c
|
||||
new_sample_SOURCES = new_sample.c
|
||||
check_gaussian_grid_SOURCES = check_gaussian_grid.c
|
||||
|
||||
INCLUDES = -I$(top_builddir)/src
|
||||
|
||||
LDADD = $(top_builddir)/src/libgrib_api.la
|
||||
DEPENDENCIES = $(LDADD)
|
||||
|
||||
EXTRA_DIST =$(TESTS) include.sh
|
||||
EXTRA_DIST =$(TESTS) include.sh CMakeLists.txt include.ctest.sh.in
|
||||
|
||||
|
|
|
@ -10,7 +10,8 @@
|
|||
|
||||
#include "grib_api.h"
|
||||
|
||||
int main(int argc, char* argv[]) {
|
||||
int main(int argc, char* argv[])
|
||||
{
|
||||
FILE* f;
|
||||
int err=0;
|
||||
char infile[]="../../data/reduced_gaussian_model_level.grib1";
|
||||
|
|
|
@ -0,0 +1,184 @@
|
|||
/*
|
||||
* Copyright 2005-2014 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
|
||||
* with a Gaussian Grid (reduced or regular)
|
||||
*
|
||||
*/
|
||||
#include <stdio.h>
|
||||
#include <stdlib.h>
|
||||
#include <assert.h>
|
||||
#include <stdarg.h>
|
||||
#include "grib_api.h"
|
||||
|
||||
#define STR_EQUAL(s1, s2) (strcmp((s1), (s2)) == 0)
|
||||
|
||||
int DBL_EQUAL(double d1, double d2, double tolerance)
|
||||
{
|
||||
return fabs(d1-d2) <= tolerance;
|
||||
}
|
||||
|
||||
void usage(const char* prog)
|
||||
{
|
||||
printf("usage: %s file\n",prog);
|
||||
exit(1);
|
||||
}
|
||||
|
||||
void error(const char* fmt, ...)
|
||||
{
|
||||
char msg[1024];
|
||||
va_list list;
|
||||
va_start(list,fmt);
|
||||
vsprintf(msg, fmt, list);
|
||||
va_end(list);
|
||||
|
||||
fprintf(stderr,msg);
|
||||
exit(1);
|
||||
}
|
||||
|
||||
double get_precision(long edition)
|
||||
{
|
||||
if (edition == 1) return 1.0/1000.0; /* milli degrees */
|
||||
if (edition == 2) return 1.0/1000000.0; /* micro degrees */
|
||||
assert(!"Invalid edition");
|
||||
return 0.0;
|
||||
}
|
||||
|
||||
int main(int argc, char** argv)
|
||||
{
|
||||
int err = 0, msg_num = 0;
|
||||
FILE* in = NULL;
|
||||
char* filename = NULL;
|
||||
grib_handle *h = NULL;
|
||||
|
||||
if (argc != 2) {
|
||||
usage(argv[0]);
|
||||
return 1;
|
||||
}
|
||||
filename = argv[1];
|
||||
in = fopen(filename,"r");
|
||||
if(!in) {
|
||||
error("ERROR: unable to open input file %s\n",filename);
|
||||
}
|
||||
|
||||
while ((h = grib_handle_new_from_file(0,in,&err)) != NULL ) {
|
||||
int is_reduced = 0, is_regular = 0, grid_ok = 0;
|
||||
long edition = 0, N = 0, Nj = 0, numberOfDataPoints;
|
||||
size_t len = 0, numberOfValues = 0;
|
||||
double *lats = NULL;
|
||||
long *pl = NULL;
|
||||
char gridType[32] = {0,};
|
||||
double angular_tolerance, lat1, lon1, lat2, lon2, expected_lon2;
|
||||
double iDirectionIncrementInDegrees;
|
||||
|
||||
if (err != GRIB_SUCCESS) GRIB_CHECK(err,0);
|
||||
++msg_num;
|
||||
printf("Processing GRIB message #%d\n", msg_num);
|
||||
|
||||
len = 32;
|
||||
GRIB_CHECK(grib_get_string(h,"gridType",gridType,&len),0);
|
||||
is_regular = STR_EQUAL(gridType, "regular_gg");
|
||||
is_reduced = STR_EQUAL(gridType, "reduced_gg");
|
||||
grid_ok = is_regular || is_reduced;
|
||||
if( !grid_ok ) {
|
||||
error("ERROR: gridType should be Reduced or Regular Gaussian Grid!\n");
|
||||
}
|
||||
|
||||
GRIB_CHECK(grib_get_long(h,"edition",&edition),0);
|
||||
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_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_double(h,"iDirectionIncrementInDegrees",&iDirectionIncrementInDegrees),0);
|
||||
|
||||
angular_tolerance = get_precision(edition);
|
||||
|
||||
if ( Nj != 2*N ) {
|
||||
error("ERROR: Nj is %ld but should be 2*N (%ld)!\n", Nj, 2*N);
|
||||
}
|
||||
|
||||
if (is_reduced) {
|
||||
int pl_sum = 0;
|
||||
size_t i = 0, pl_len = 0;
|
||||
int is_missing = grib_is_missing(h, "Ni", &err);
|
||||
assert(err == GRIB_SUCCESS);
|
||||
if (!is_missing) {
|
||||
error("ERROR: Ni should be missing!\n");
|
||||
}
|
||||
|
||||
GRIB_CHECK(grib_get_size(h, "pl", &pl_len),0);
|
||||
if (pl_len != 2*N) {
|
||||
error("ERROR: Length of pl array is %ld but should be 2*N (%ld)!\n", pl_len, 2*N);
|
||||
}
|
||||
pl = malloc(pl_len*sizeof(long));
|
||||
assert(pl);
|
||||
GRIB_CHECK(grib_get_long_array(h, "pl", pl, &pl_len),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("ERROR: 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_sum != numberOfDataPoints) {
|
||||
error("ERROR: Sum of pl array %ld does not match numberOfDataPoints %ld!\n", pl_sum, numberOfDataPoints);
|
||||
}
|
||||
free(pl);
|
||||
}
|
||||
|
||||
if (lon1 != 0) {
|
||||
error("ERROR: latitudeOfFirstGridPointInDegrees=%f but should be 0!\n", lon1);
|
||||
}
|
||||
expected_lon2 = 360.0 - 90.0/N;
|
||||
if (fabs(lon2 - expected_lon2) > angular_tolerance) {
|
||||
error("ERROR: longitudeOfLastGridPointInDegrees=%f but should be %f!\n", lon2, expected_lon2);
|
||||
}
|
||||
|
||||
/* Check first and last latitudes */
|
||||
if (lat1 != -lat2) {
|
||||
error("First latitude must be = last latitude but opposite in sign: lat1=%f, lat2=%f\n",
|
||||
lat1, lat2);
|
||||
}
|
||||
lats = (double*)malloc(sizeof(double)*Nj);
|
||||
GRIB_CHECK(grib_get_gaussian_latitudes(N,lats), 0);
|
||||
|
||||
if (!DBL_EQUAL(lats[0], lat1, angular_tolerance)) {
|
||||
error("First latitude %f must be %f\n", lat1, lats[0]);
|
||||
}
|
||||
if (!DBL_EQUAL(lats[Nj-1], lat2, angular_tolerance)) {
|
||||
error("Last latitude %f must be %f\n", lat2, lats[Nj-1]);
|
||||
}
|
||||
|
||||
GRIB_CHECK(grib_get_size(h, "values", &numberOfValues),0);
|
||||
if (numberOfValues != numberOfDataPoints) {
|
||||
error("Number of data points %d different from number of values %d\n",
|
||||
numberOfDataPoints, numberOfValues);
|
||||
}
|
||||
|
||||
free(lats);
|
||||
grib_handle_delete(h);
|
||||
}
|
||||
fclose(in);
|
||||
printf("\nFile %s OK\n", filename);
|
||||
return 0;
|
||||
}
|
|
@ -42,6 +42,8 @@ int main(int argc, char *argv[])
|
|||
|
||||
if (!in || !out) {
|
||||
perror("ERROR: unable to open files");
|
||||
fclose(out);
|
||||
fclose(in);
|
||||
return 1;
|
||||
}
|
||||
|
||||
|
|
|
@ -26,7 +26,8 @@ void usage(char* prog) {
|
|||
exit(1);
|
||||
}
|
||||
|
||||
int main(int argc, char** argv) {
|
||||
int main(int argc, char** argv)
|
||||
{
|
||||
int err = 0;
|
||||
long step,levelType;
|
||||
char** filenames;
|
||||
|
|
|
@ -19,7 +19,8 @@
|
|||
#include <assert.h>
|
||||
#include "grib_api.h"
|
||||
|
||||
int main(int argc, char** argv) {
|
||||
int main(int argc, char** argv)
|
||||
{
|
||||
int err = 0;
|
||||
double *values = NULL;
|
||||
size_t values_len= 0;
|
||||
|
@ -118,7 +119,6 @@ int main(int argc, char** argv) {
|
|||
}
|
||||
|
||||
grib_handle_delete(h);
|
||||
|
||||
fclose(in);
|
||||
return 0;
|
||||
}
|
||||
|
|
|
@ -54,11 +54,14 @@ int main (int argc, char **argv)
|
|||
lons = (double *) malloc (numberOfPoints * sizeof (double));
|
||||
if (!lons) {
|
||||
printf ("unable to allocate %ld bytes\n", (long) (numberOfPoints * sizeof (double)));
|
||||
free (lats);
|
||||
return 1;
|
||||
}
|
||||
values = (double *) malloc (numberOfPoints * sizeof (double));
|
||||
if (!values) {
|
||||
printf ("unable to allocate %ld bytes\n", (long) (numberOfPoints * sizeof (double)));
|
||||
free (lats);
|
||||
free (lons);
|
||||
return 1;
|
||||
}
|
||||
|
||||
|
|
|
@ -25,12 +25,13 @@
|
|||
|
||||
#include "grib_api.h"
|
||||
|
||||
void usage(char* prog) {
|
||||
void usage(const char* prog) {
|
||||
printf("usage: %s filename\n",prog);
|
||||
exit(1);
|
||||
}
|
||||
|
||||
int main(int argc, char** argv) {
|
||||
int main(int argc, char** argv)
|
||||
{
|
||||
int err = 0,i;
|
||||
double *values = NULL;
|
||||
double max,min,average;
|
||||
|
|
|
@ -21,6 +21,7 @@ else
|
|||
then
|
||||
cd ../../
|
||||
cpath=`pwd`
|
||||
proj_dir=$cpath
|
||||
GRIB_DEFINITION_PATH=$cpath/definitions
|
||||
export GRIB_DEFINITION_PATH
|
||||
GRIB_SAMPLES_PATH=$cpath/samples
|
||||
|
|
|
@ -21,12 +21,13 @@
|
|||
|
||||
#include "grib_api.h"
|
||||
|
||||
void usage(char* prog) {
|
||||
void usage(const char* prog) {
|
||||
printf("Usage: %s grib_file\n",prog);
|
||||
exit(1);
|
||||
}
|
||||
|
||||
int main(int argc, char** argv) {
|
||||
int main(int argc, char** argv)
|
||||
{
|
||||
FILE* in = NULL;
|
||||
int err = 0;
|
||||
double lat,lon,value,missingValue=0;
|
||||
|
@ -40,11 +41,11 @@ int main(int argc, char** argv) {
|
|||
|
||||
if (argc != 2) usage(argv[0]);
|
||||
|
||||
filename=strdup(argv[1]);
|
||||
filename=argv[1];
|
||||
|
||||
in = fopen(filename,"r");
|
||||
if(!in) {
|
||||
printf("ERROR: unable to open file %s\n",filename);
|
||||
printf("ERROR: unable to open file %s\n", filename);
|
||||
return 1;
|
||||
}
|
||||
|
||||
|
@ -79,7 +80,6 @@ int main(int argc, char** argv) {
|
|||
grib_handle_delete(h);
|
||||
}
|
||||
|
||||
|
||||
fclose(in);
|
||||
|
||||
return 0;
|
||||
|
|
|
@ -41,7 +41,7 @@ int main(int argc, char** argv)
|
|||
grib_iterator* iter=NULL;
|
||||
|
||||
if (argc != 2) usage(argv[0]);
|
||||
filename=strdup(argv[1]);
|
||||
filename=argv[1];
|
||||
in = fopen(filename,"r");
|
||||
if(!in) {
|
||||
fprintf(stderr, "ERROR: unable to open file %s\n",filename);
|
||||
|
|
|
@ -20,7 +20,8 @@
|
|||
|
||||
#include "grib_api.h"
|
||||
|
||||
int main(int argc, char** argv) {
|
||||
int main(int argc, char** argv)
|
||||
{
|
||||
int err = 0;
|
||||
|
||||
size_t i = 0;
|
||||
|
|
|
@ -19,7 +19,8 @@
|
|||
|
||||
#include "grib_api.h"
|
||||
|
||||
int main(int argc, char** argv) {
|
||||
int main(int argc, char** argv)
|
||||
{
|
||||
grib_string_list* list;
|
||||
grib_string_list* list2;
|
||||
|
||||
|
|
|
@ -23,7 +23,8 @@
|
|||
|
||||
#include "grib_api.h"
|
||||
|
||||
int main(int argc, char** argv) {
|
||||
int main(int argc, char** argv)
|
||||
{
|
||||
int err = 0;
|
||||
long parameterCategory=0,parameterNumber=0,discipline=0;
|
||||
FILE* in = NULL;
|
||||
|
|
|
@ -27,7 +27,8 @@ const int NUM_FIELDS = 4;
|
|||
const int COUNT = 20;
|
||||
const char* file_path = "../../data/multi_created.grib2";
|
||||
|
||||
int main(int argc, char** argv) {
|
||||
int main(int argc, char** argv)
|
||||
{
|
||||
int i;
|
||||
|
||||
/* turn on support for multi fields messages */
|
||||
|
|
|
@ -19,12 +19,13 @@
|
|||
#include <assert.h>
|
||||
#include "grib_api.h"
|
||||
|
||||
void usage(char* prog) {
|
||||
void usage(const char* prog) {
|
||||
printf("usage: %s in.grib out.grib\n",prog);
|
||||
exit(1);
|
||||
}
|
||||
|
||||
int main(int argc, char** argv) {
|
||||
int main(int argc, char** argv)
|
||||
{
|
||||
int err = 0;
|
||||
FILE* in = NULL;
|
||||
FILE* of = NULL;
|
||||
|
|
|
@ -20,12 +20,13 @@
|
|||
|
||||
#include "grib_api.h"
|
||||
|
||||
void usage(char* prog) {
|
||||
void usage(const char* prog) {
|
||||
printf("Usage: %s grib_file grib_file ...\n",prog);
|
||||
exit(1);
|
||||
}
|
||||
|
||||
int main(int argc, char** argv) {
|
||||
int main(int argc, char** argv)
|
||||
{
|
||||
int err = 0;
|
||||
long step=0;
|
||||
size_t nfiles;
|
||||
|
|
|
@ -19,12 +19,13 @@
|
|||
|
||||
#include "grib_api.h"
|
||||
|
||||
void usage(char* prog) {
|
||||
void usage(const char* prog) {
|
||||
printf("Usage: %s latlon_file grib_orography grib_file grib_file ...\n",prog);
|
||||
exit(1);
|
||||
}
|
||||
|
||||
int main(int argc, char** argv) {
|
||||
int main(int argc, char** argv)
|
||||
{
|
||||
FILE* fin=0;
|
||||
int ret=0;
|
||||
char* fname=0;
|
||||
|
|
|
@ -38,7 +38,7 @@ int main(int argc, char** argv)
|
|||
const void* buffer = NULL;
|
||||
double* values1=NULL;
|
||||
double* values2=NULL;
|
||||
double maxa=0,a=0;
|
||||
double maxa=0;
|
||||
double maxv=0,minv=0;
|
||||
double maxr=0,r=0;
|
||||
long decimalPrecision;
|
||||
|
@ -54,6 +54,7 @@ int main(int argc, char** argv)
|
|||
out = fopen(outfile,"w");
|
||||
if(!out) {
|
||||
printf("ERROR: unable to open output file %s\n",outfile);
|
||||
fclose(in);
|
||||
return 1;
|
||||
}
|
||||
|
||||
|
@ -94,7 +95,7 @@ int main(int argc, char** argv)
|
|||
maxv=values2[0];
|
||||
minv=maxv;
|
||||
for (i=0;i<size;i++) {
|
||||
a=fabs(values2[i]-values1[i]);
|
||||
double a=fabs(values2[i]-values1[i]);
|
||||
if ( values2[i] > maxv ) maxv=values2[i];
|
||||
if ( values2[i] < minv ) minv=values2[i];
|
||||
if ( values2[i] !=0 ) r=fabs((values2[i]-values1[i])/values2[i]);
|
||||
|
|
|
@ -19,12 +19,13 @@
|
|||
|
||||
#include "grib_api.h"
|
||||
|
||||
void usage(char* prog) {
|
||||
void usage(const char* prog) {
|
||||
printf("usage: %s filename\n",prog);
|
||||
exit(1);
|
||||
}
|
||||
|
||||
int main(int argc, char** argv) {
|
||||
int main(int argc, char** argv)
|
||||
{
|
||||
int err = 0,i;
|
||||
double *values = NULL;
|
||||
double max,min,average;
|
||||
|
|
|
@ -8,37 +8,30 @@
|
|||
* virtue of its status as an intergovernmental organisation nor does it submit to any jurisdiction.
|
||||
*/
|
||||
#include "grib_api.h"
|
||||
#include <ctype.h>
|
||||
|
||||
void usage(char* prog) {
|
||||
printf("usage: %s in1.grib in2.grib out.grib\n",prog);
|
||||
printf("in1.grib\t The grib in whose sections we are interested, i.e. the source of the sections (read-only)\n");
|
||||
printf("in2.grib\t The input grib (read-only)\n");
|
||||
printf("out.grib\t The output file\n");
|
||||
printf("usage: %s in1.grib in2.grib what out.grib\n",prog);
|
||||
printf("in1.grib The grib in whose sections we are interested, i.e. the source of the sections (read-only)\n");
|
||||
printf("in2.grib The input grib (read-only)\n");
|
||||
printf("what The section(s) to copy: p(Product), g(Grid), l(Local), d(Data), b(Bitmap)\n");
|
||||
printf("out.grib The output file\n");
|
||||
exit(1);
|
||||
}
|
||||
|
||||
int main ( int argc, char* argv[]) {
|
||||
int main ( int argc, char* argv[])
|
||||
{
|
||||
grib_handle *hfrom,*hto,*h;
|
||||
FILE *in;
|
||||
char *in_name,*in_name1,*out_name;
|
||||
int err=0;
|
||||
int what=0;
|
||||
char *in_name1, *in_name2, *what_str, *out_name;
|
||||
int i, err=0, what=0;
|
||||
|
||||
if (argc<4) usage(argv[0]);
|
||||
if (argc<5) usage(argv[0]);
|
||||
|
||||
in_name=argv[1];
|
||||
in_name1=argv[2];
|
||||
out_name=argv[3];
|
||||
|
||||
in=fopen(in_name,"r");
|
||||
if (!in) {
|
||||
perror(in_name);
|
||||
exit(1);
|
||||
}
|
||||
|
||||
hfrom=grib_handle_new_from_file(0,in,&err);
|
||||
GRIB_CHECK(err,0);
|
||||
fclose(in);
|
||||
in_name1=argv[1];
|
||||
in_name2=argv[2];
|
||||
what_str=argv[3];
|
||||
out_name=argv[4];
|
||||
|
||||
in=fopen(in_name1,"r");
|
||||
if (!in) {
|
||||
|
@ -46,16 +39,67 @@ int main ( int argc, char* argv[]) {
|
|||
exit(1);
|
||||
}
|
||||
|
||||
hfrom=grib_handle_new_from_file(0,in,&err);
|
||||
GRIB_CHECK(err,0);
|
||||
fclose(in);
|
||||
|
||||
in=fopen(in_name2,"r");
|
||||
if (!in) {
|
||||
perror(in_name2);
|
||||
exit(1);
|
||||
}
|
||||
|
||||
hto=grib_handle_new_from_file(0,in,&err);
|
||||
GRIB_CHECK(err,0);
|
||||
fclose(in);
|
||||
|
||||
/*what=GRIB_SECTION_PRODUCT | GRIB_SECTION_LOCAL;*/
|
||||
what=GRIB_SECTION_GRID;
|
||||
/* The sections for the "what" argument are:
|
||||
* GRIB_SECTION_PRODUCT
|
||||
* GRIB_SECTION_GRID
|
||||
* GRIB_SECTION_LOCAL
|
||||
* GRIB_SECTION_DATA
|
||||
* GRIB_SECTION_BITMAP
|
||||
* One can bitwise-OR them to have more than one section copied
|
||||
* E.g. what = GRIB_SECTION_PRODUCT | GRIB_SECTION_LOCAL;
|
||||
*/
|
||||
for(i=0; i<strlen(what_str); ++i) {
|
||||
if (what_str[i] == 'p') {
|
||||
printf("Copying the PRODUCT section\n");
|
||||
what |= GRIB_SECTION_PRODUCT;
|
||||
}
|
||||
else if (what_str[i] == 'g') {
|
||||
printf("Copying the GRID section\n");
|
||||
what |= GRIB_SECTION_GRID;
|
||||
}
|
||||
else if (what_str[i] == 'l') {
|
||||
printf("Copying the LOCAL section\n");
|
||||
what |= GRIB_SECTION_LOCAL;
|
||||
}
|
||||
else if (what_str[i] == 'd') {
|
||||
printf("Copying the DATA section\n");
|
||||
what |= GRIB_SECTION_DATA;
|
||||
}
|
||||
else if (what_str[i] == 'b') {
|
||||
printf("Copying the BITMAP section\n");
|
||||
what |= GRIB_SECTION_BITMAP;
|
||||
}
|
||||
else if (isspace(what_str[i]) || what_str[i] == ',') {
|
||||
/* Ignore spaces and comma separator */
|
||||
}
|
||||
else {
|
||||
fprintf(stderr,"Invalid option: '%c'. Ignoring.\n",
|
||||
what_str[i]);
|
||||
}
|
||||
}
|
||||
|
||||
h=grib_util_sections_copy(hfrom,hto,what,&err);
|
||||
GRIB_CHECK(err,0);
|
||||
|
||||
err=grib_write_message(h,out_name,"w");
|
||||
|
||||
grib_handle_delete(hfrom);
|
||||
grib_handle_delete(hto);
|
||||
grib_handle_delete(h);
|
||||
|
||||
return err;
|
||||
}
|
||||
|
|
|
@ -13,17 +13,41 @@ REGUL_GRID_FILE=${proj_dir}/samples/regular_ll_sfc_grib2.tmpl
|
|||
GAUSS_GRID_FILE=${proj_dir}/samples/reduced_gg_pl_640_grib2.tmpl
|
||||
OUTPUT=temp.sections.grib
|
||||
|
||||
${examples_dir}sections_copy $REGUL_GRID_FILE $GAUSS_GRID_FILE $OUTPUT
|
||||
# Now the output should have a regular grid i.e. gridDefinitionTemplateNumber==0
|
||||
##################
|
||||
# Copy the GRID section from REGUL_GRID_FILE
|
||||
${examples_dir}sections_copy $REGUL_GRID_FILE $GAUSS_GRID_FILE g $OUTPUT >/dev/null
|
||||
|
||||
# Now the output should have a regular grid
|
||||
# but its date should be the same as the Gaussian grid sample
|
||||
grid_tmpl=`${tools_dir}grib_get -p gridDefinitionTemplateNumber,date $OUTPUT`
|
||||
[ "$grid_tmpl" = "0 20100912" ]
|
||||
grid_tmpl=`${tools_dir}grib_get -p gridType,date $OUTPUT`
|
||||
[ "$grid_tmpl" = "regular_ll 20100912" ]
|
||||
|
||||
|
||||
${examples_dir}sections_copy $GAUSS_GRID_FILE $REGUL_GRID_FILE $OUTPUT
|
||||
# Now the output should have a reduced gaussian grid i.e. gridDefinitionTemplateNumber==40
|
||||
# but its date should be the same as the Regular grid sample
|
||||
grid_tmpl=`${tools_dir}grib_get -p gridDefinitionTemplateNumber,date $OUTPUT`
|
||||
[ "$grid_tmpl" = "40 20070323" ]
|
||||
##################
|
||||
# Copy the GRID section from GAUSS_GRID_FILE
|
||||
${examples_dir}sections_copy $GAUSS_GRID_FILE $REGUL_GRID_FILE g $OUTPUT >/dev/null
|
||||
|
||||
# Now the output should have a gaussian grid
|
||||
# but its date should be the same as the regular grid
|
||||
grid_tmpl=`${tools_dir}grib_get -p gridType,date $OUTPUT`
|
||||
[ "$grid_tmpl" = "reduced_gg 20070323" ]
|
||||
|
||||
|
||||
##################
|
||||
# Copy both the PRODUCT and GRID sections from REGUL_GRID_FILE
|
||||
${examples_dir}sections_copy $REGUL_GRID_FILE $GAUSS_GRID_FILE gp $OUTPUT >/dev/null
|
||||
|
||||
# Now the output should have a regular grid
|
||||
# and its date should be the same as the regular latlon
|
||||
grid_tmpl=`${tools_dir}grib_get -p gridType,date $OUTPUT`
|
||||
[ "$grid_tmpl" = "regular_ll 20070323" ]
|
||||
|
||||
|
||||
##################
|
||||
# Copy all sections from REGUL_GRID_FILE (use commas)
|
||||
${examples_dir}sections_copy $REGUL_GRID_FILE $GAUSS_GRID_FILE p,l,g,d,b $OUTPUT >/dev/null
|
||||
|
||||
# Now the output should be identical to the regular grib
|
||||
${tools_dir}grib_compare $REGUL_GRID_FILE $OUTPUT
|
||||
|
||||
rm -f $OUTPUT
|
||||
|
|
|
@ -19,7 +19,8 @@
|
|||
|
||||
#include "grib_api.h"
|
||||
|
||||
int main(int argc, char** argv) {
|
||||
int main(int argc, char** argv)
|
||||
{
|
||||
int err = 0;
|
||||
long centre=80;
|
||||
long long_value=0;
|
||||
|
@ -44,6 +45,7 @@ int main(int argc, char** argv) {
|
|||
out = fopen(outfile,"w");
|
||||
if(!out) {
|
||||
printf("ERROR: unable to open file %s\n",outfile);
|
||||
fclose(in);
|
||||
return 1;
|
||||
}
|
||||
|
||||
|
@ -79,9 +81,7 @@ int main(int argc, char** argv) {
|
|||
exit(1);
|
||||
}
|
||||
|
||||
/* delete handle */
|
||||
grib_handle_delete(h);
|
||||
|
||||
fclose(in);
|
||||
fclose(out);
|
||||
|
||||
|
|
|
@ -21,7 +21,8 @@
|
|||
|
||||
#include "grib_api.h"
|
||||
|
||||
int main(int argc, char** argv) {
|
||||
int main(int argc, char** argv)
|
||||
{
|
||||
int err = 0;
|
||||
size_t size=0;
|
||||
|
||||
|
@ -45,6 +46,7 @@ int main(int argc, char** argv) {
|
|||
out = fopen(outfile,"w");
|
||||
if(!out) {
|
||||
printf("ERROR: unable to open output file %s\n",outfile);
|
||||
fclose(in);
|
||||
return 1;
|
||||
}
|
||||
|
||||
|
|
|
@ -19,7 +19,7 @@
|
|||
|
||||
#include "grib_api.h"
|
||||
|
||||
void usage(char* prog)
|
||||
void usage(const char* prog)
|
||||
{
|
||||
printf("usage: %s out.grib\n",prog);
|
||||
exit(1);
|
||||
|
@ -32,6 +32,9 @@ int main(int argc, char** argv)
|
|||
size_t values_len= 0;
|
||||
|
||||
/* Note: the full name of the sample file is "regular_ll_pl_grib1.tmpl" */
|
||||
/* Sample files are stored in the samples directory (use grib_info to */
|
||||
/* see where that is). The default sample path can be changed by */
|
||||
/* setting the environment variable GRIB_SAMPLES_PATH */
|
||||
const char* sample_filename = "regular_ll_pl_grib1";
|
||||
grib_handle *h = NULL;
|
||||
double d,e;
|
||||
|
|
|
@ -19,7 +19,8 @@
|
|||
#include <assert.h>
|
||||
#include "grib_api.h"
|
||||
|
||||
int main(int argc, char** argv) {
|
||||
int main(int argc, char** argv)
|
||||
{
|
||||
int err = 0, is_missing = 0;
|
||||
|
||||
FILE* in = NULL;
|
||||
|
@ -42,6 +43,7 @@ int main(int argc, char** argv) {
|
|||
out = fopen(outfile,"w");
|
||||
if(!out) {
|
||||
printf("ERROR: unable to open output file %s\n",outfile);
|
||||
fclose(in);
|
||||
return 1;
|
||||
}
|
||||
|
||||
|
|
|
@ -19,7 +19,8 @@
|
|||
|
||||
#include "grib_api.h"
|
||||
|
||||
int main(int argc, char** argv) {
|
||||
int main(int argc, char** argv)
|
||||
{
|
||||
int err = 0;
|
||||
long PVPresent=1;
|
||||
size_t size=0;
|
||||
|
@ -42,6 +43,7 @@ int main(int argc, char** argv) {
|
|||
out = fopen(outfile,"w");
|
||||
if(!out) {
|
||||
printf("ERROR: unable to open output file %s\n",outfile);
|
||||
fclose(in);
|
||||
return 1;
|
||||
}
|
||||
|
||||
|
@ -66,9 +68,7 @@ int main(int argc, char** argv) {
|
|||
exit(1);
|
||||
}
|
||||
|
||||
/* delete handle */
|
||||
grib_handle_delete(h);
|
||||
|
||||
fclose(in);
|
||||
fclose(out);
|
||||
|
||||
|
|
|
@ -9,7 +9,8 @@
|
|||
*/
|
||||
#include "grib_api.h"
|
||||
|
||||
int main(int argc, char* argv[]) {
|
||||
int main(int argc, char* argv[])
|
||||
{
|
||||
FILE* f;
|
||||
int err=0;
|
||||
char infile[]="../../data/reduced_gaussian_model_level.grib1";
|
||||
|
|
|
@ -42,5 +42,5 @@ AM_FCFLAGS = $(F90_MODULE_FLAG)$(top_builddir)/fortran
|
|||
LDADD = $(top_builddir)/fortran/libgrib_api_f90.la $(top_builddir)/src/libgrib_api.la
|
||||
DEPENDENCIES = $(LDADD)
|
||||
|
||||
EXTRA_DIST =$(TESTS) include.sh
|
||||
EXTRA_DIST =$(TESTS) include.sh CMakeLists.txt include.ctest.sh.in
|
||||
|
||||
|
|
|
@ -33,5 +33,5 @@ INCLUDES = -I$(top_builddir)/src
|
|||
LDADD = $(top_builddir)/src/libgrib_api.la
|
||||
DEPENDENCIES = $(LDADD)
|
||||
|
||||
EXTRA_DIST =$(TESTS) include.sh
|
||||
EXTRA_DIST =$(TESTS) include.sh CMakeLists.txt
|
||||
|
||||
|
|
|
@ -15,5 +15,6 @@ LDADD = $(top_builddir)/src/libgrib_api.la
|
|||
DEPENDENCIES = $(LDADD)
|
||||
|
||||
EXTRA_DIST = $(TESTS) include.sh clone.py count_messages.py get.py index.py iterator.py keys_iterator.py multi_write.py \
|
||||
nearest.py print_data.py samples.py set.py set_missing.py binary_message.py set_pv.py set_bitmap.py
|
||||
nearest.py print_data.py samples.py set.py set_missing.py binary_message.py set_pv.py set_bitmap.py \
|
||||
CMakeLists.txt include.ctest.sh.in
|
||||
endif
|
||||
|
|
|
@ -36,7 +36,8 @@ EXTRA_DIST= grib_fortran_prototypes.h grib_api_constants.h grib_api_externals.h
|
|||
grib_api_visibility.h grib_types.f90 create_grib_f90.sh \
|
||||
grib_f90_head.f90 grib_f90_tail.f90 grib_f90_int.f90 grib_f90_long_int.f90 \
|
||||
grib_f90_int_size_t.f90 grib_f90_long_size_t.f90 \
|
||||
same_int_long.f90 same_int_size_t.f90 grib_fortran_kinds.c
|
||||
same_int_long.f90 same_int_size_t.f90 grib_fortran_kinds.c \
|
||||
CMakeLists.txt
|
||||
|
||||
grib_f90.f90: grib_f90_head.f90 grib_f90_tail.f90 grib_f90_int.f90 grib_f90_long_int.f90 grib_f90_int_size_t.f90 grib_f90_long_size_t.f90 same_int_long same_int_size_t grib_kinds.h
|
||||
./create_grib_f90.sh
|
||||
|
|
|
@ -23,6 +23,8 @@ nodist_grib1_DATA = \
|
|||
reduced_gg_ml_grib2.tmpl \
|
||||
reduced_gg_pl_1024_grib1.tmpl \
|
||||
reduced_gg_pl_1024_grib2.tmpl \
|
||||
reduced_gg_pl_1280_grib1.tmpl \
|
||||
reduced_gg_pl_1280_grib2.tmpl \
|
||||
reduced_gg_pl_128_grib1.tmpl \
|
||||
reduced_gg_pl_128_grib2.tmpl \
|
||||
reduced_gg_pl_160_grib1.tmpl \
|
||||
|
@ -114,6 +116,12 @@ reduced_gg_pl_1024_grib1.tmpl: ../../samples/reduced_gg_pl_1024_grib1.tmpl
|
|||
reduced_gg_pl_1024_grib2.tmpl: ../../samples/reduced_gg_pl_1024_grib2.tmpl
|
||||
cp -f ../../samples/reduced_gg_pl_1024_grib2.tmpl .
|
||||
|
||||
reduced_gg_pl_1280_grib1.tmpl: ../../samples/reduced_gg_pl_1280_grib1.tmpl
|
||||
cp -f ../../samples/reduced_gg_pl_1280_grib1.tmpl .
|
||||
|
||||
reduced_gg_pl_1280_grib2.tmpl: ../../samples/reduced_gg_pl_1280_grib2.tmpl
|
||||
cp -f ../../samples/reduced_gg_pl_1280_grib2.tmpl .
|
||||
|
||||
reduced_gg_pl_128_grib1.tmpl: ../../samples/reduced_gg_pl_128_grib1.tmpl
|
||||
cp -f ../../samples/reduced_gg_pl_128_grib1.tmpl .
|
||||
|
||||
|
|
|
@ -23,6 +23,8 @@ nodist_grib1_mlgrib2_DATA = \
|
|||
reduced_gg_ml_grib2.tmpl \
|
||||
reduced_gg_pl_1024_grib1.tmpl \
|
||||
reduced_gg_pl_1024_grib2.tmpl \
|
||||
reduced_gg_pl_1280_grib1.tmpl \
|
||||
reduced_gg_pl_1280_grib2.tmpl \
|
||||
reduced_gg_pl_128_grib1.tmpl \
|
||||
reduced_gg_pl_128_grib2.tmpl \
|
||||
reduced_gg_pl_160_grib1.tmpl \
|
||||
|
@ -114,6 +116,12 @@ reduced_gg_pl_1024_grib1.tmpl: ../../samples/reduced_gg_pl_1024_grib1.tmpl
|
|||
reduced_gg_pl_1024_grib2.tmpl: ../../samples/reduced_gg_pl_1024_grib2.tmpl
|
||||
cp -f ../../samples/reduced_gg_pl_1024_grib2.tmpl .
|
||||
|
||||
reduced_gg_pl_1280_grib1.tmpl: ../../samples/reduced_gg_pl_1280_grib1.tmpl
|
||||
cp -f ../../samples/reduced_gg_pl_1280_grib1.tmpl .
|
||||
|
||||
reduced_gg_pl_1280_grib2.tmpl: ../../samples/reduced_gg_pl_1280_grib2.tmpl
|
||||
cp -f ../../samples/reduced_gg_pl_1280_grib2.tmpl .
|
||||
|
||||
reduced_gg_pl_128_grib1.tmpl: ../../samples/reduced_gg_pl_128_grib1.tmpl
|
||||
cp -f ../../samples/reduced_gg_pl_128_grib1.tmpl .
|
||||
|
||||
|
|
|
@ -22,6 +22,8 @@ nodist_grib1_mlgrib2_ieee32_DATA = \
|
|||
reduced_gg_ml_grib2.tmpl \
|
||||
reduced_gg_pl_1024_grib1.tmpl \
|
||||
reduced_gg_pl_1024_grib2.tmpl \
|
||||
reduced_gg_pl_1280_grib1.tmpl \
|
||||
reduced_gg_pl_1280_grib2.tmpl \
|
||||
reduced_gg_pl_128_grib1.tmpl \
|
||||
reduced_gg_pl_128_grib2.tmpl \
|
||||
reduced_gg_pl_160_grib1.tmpl \
|
||||
|
@ -110,6 +112,12 @@ reduced_gg_pl_1024_grib1.tmpl: ../../samples/reduced_gg_pl_1024_grib1.tmpl
|
|||
reduced_gg_pl_1024_grib2.tmpl: ../../samples/reduced_gg_pl_1024_grib2.tmpl
|
||||
cp -f ../../samples/reduced_gg_pl_1024_grib2.tmpl .
|
||||
|
||||
reduced_gg_pl_1280_grib1.tmpl: ../../samples/reduced_gg_pl_1280_grib1.tmpl
|
||||
cp -f ../../samples/reduced_gg_pl_1280_grib1.tmpl .
|
||||
|
||||
reduced_gg_pl_1280_grib2.tmpl: ../../samples/reduced_gg_pl_1280_grib2.tmpl
|
||||
cp -f ../../samples/reduced_gg_pl_1280_grib2.tmpl .
|
||||
|
||||
reduced_gg_pl_128_grib1.tmpl: ../../samples/reduced_gg_pl_128_grib1.tmpl
|
||||
cp -f ../../samples/reduced_gg_pl_128_grib1.tmpl .
|
||||
|
||||
|
|
|
@ -23,6 +23,8 @@ nodist_grib1_mlgrib2_ieee64_DATA = \
|
|||
reduced_gg_ml_grib2.tmpl \
|
||||
reduced_gg_pl_1024_grib1.tmpl \
|
||||
reduced_gg_pl_1024_grib2.tmpl \
|
||||
reduced_gg_pl_1280_grib1.tmpl \
|
||||
reduced_gg_pl_1280_grib2.tmpl \
|
||||
reduced_gg_pl_128_grib1.tmpl \
|
||||
reduced_gg_pl_128_grib2.tmpl \
|
||||
reduced_gg_pl_160_grib1.tmpl \
|
||||
|
@ -114,6 +116,12 @@ reduced_gg_pl_1024_grib1.tmpl: ../../samples/reduced_gg_pl_1024_grib1.tmpl
|
|||
reduced_gg_pl_1024_grib2.tmpl: ../../samples/reduced_gg_pl_1024_grib2.tmpl
|
||||
cp -f ../../samples/reduced_gg_pl_1024_grib2.tmpl .
|
||||
|
||||
reduced_gg_pl_1280_grib1.tmpl: ../../samples/reduced_gg_pl_1280_grib1.tmpl
|
||||
cp -f ../../samples/reduced_gg_pl_1280_grib1.tmpl .
|
||||
|
||||
reduced_gg_pl_1280_grib2.tmpl: ../../samples/reduced_gg_pl_1280_grib2.tmpl
|
||||
cp -f ../../samples/reduced_gg_pl_1280_grib2.tmpl .
|
||||
|
||||
reduced_gg_pl_128_grib1.tmpl: ../../samples/reduced_gg_pl_128_grib1.tmpl
|
||||
cp -f ../../samples/reduced_gg_pl_128_grib1.tmpl .
|
||||
|
||||
|
|
|
@ -30,7 +30,8 @@ EXTRA_DIST = grib_interface.h \
|
|||
swig_wrap_array.c \
|
||||
swig_wrap_numpy.c \
|
||||
swig_wrap_array.py \
|
||||
swig_wrap_numpy.py
|
||||
swig_wrap_numpy.py \
|
||||
CMakeLists.txt
|
||||
|
||||
# What else I want installed
|
||||
pkgpyexec_DATA = \
|
||||
|
@ -69,7 +70,8 @@ EXTRA_DIST = setup.py.in \
|
|||
swig_wrap_array.c \
|
||||
swig_wrap_numpy.c \
|
||||
swig_wrap_array.py \
|
||||
swig_wrap_numpy.py
|
||||
swig_wrap_numpy.py \
|
||||
CMakeLists.txt
|
||||
|
||||
# What I want installed
|
||||
pdir = $(libdir)/python$(PYTHON_VERSION)/site-packages/grib_api
|
||||
|
|
|
@ -53,6 +53,8 @@ dist_samples_DATA = \
|
|||
reduced_gg_pl_640_grib2.tmpl \
|
||||
reduced_gg_pl_1024_grib1.tmpl \
|
||||
reduced_gg_pl_1024_grib2.tmpl \
|
||||
reduced_gg_pl_1280_grib1.tmpl \
|
||||
reduced_gg_pl_1280_grib2.tmpl \
|
||||
reduced_gg_pl_2000_grib1.tmpl \
|
||||
reduced_gg_pl_2000_grib2.tmpl \
|
||||
reduced_gg_pl_80_grib1.tmpl \
|
||||
|
|
|
@ -163,6 +163,7 @@ list( APPEND grib_api_srcs
|
|||
grib_accessor_class_g2grid.c
|
||||
grib_accessor_class_data_apply_bitmap.c
|
||||
grib_accessor_class_data_apply_boustrophedonic.c
|
||||
grib_accessor_class_data_apply_boustrophedonic_bitmap.c
|
||||
grib_accessor_class_data_secondary_bitmap.c
|
||||
grib_accessor_class_data_g1secondary_bitmap.c
|
||||
grib_accessor_class_data_g2secondary_bitmap.c
|
||||
|
@ -280,7 +281,6 @@ list( APPEND grib_api_srcs
|
|||
grib_accessor_class.h
|
||||
grib_accessor_factory.h
|
||||
grib_api.h
|
||||
grib_api_fortran.h
|
||||
grib_api_internal.h
|
||||
grib_api_prototypes.h
|
||||
grib_box_class.h
|
||||
|
@ -295,9 +295,6 @@ list( APPEND grib_api_srcs
|
|||
grib_nearest_factory.h
|
||||
grib_templates.h
|
||||
grib_yacc.h
|
||||
jgribapi_GribFile.h
|
||||
jgribapi_GribHandle.h
|
||||
jgribapi_GribIterator.h
|
||||
md5.h
|
||||
md5.c
|
||||
# Ship our generated lex/yacc C files
|
||||
|
|
|
@ -177,6 +177,7 @@ libgrib_api_la_prototypes= \
|
|||
grib_accessor_class_g2grid.c \
|
||||
grib_accessor_class_data_apply_bitmap.c \
|
||||
grib_accessor_class_data_apply_boustrophedonic.c \
|
||||
grib_accessor_class_data_apply_boustrophedonic_bitmap.c \
|
||||
grib_accessor_class_data_secondary_bitmap.c \
|
||||
grib_accessor_class_data_g1secondary_bitmap.c \
|
||||
grib_accessor_class_data_g2secondary_bitmap.c \
|
||||
|
@ -334,7 +335,8 @@ EXTRA_DIST= dummy.am griby.y gribl.l grib_accessor_classes_hash.c \
|
|||
grib_bits_fast_big_endian_vector.c grib_bits_any_endian_vector.c \
|
||||
grib_bits_fast_big_endian_simple.c grib_bits_any_endian_simple.c \
|
||||
grib_bits_fast_big_endian_omp.c grib_bits_any_endian_omp.c \
|
||||
encode_double_array.c grib_bits_ibmpow.c grib_bits_ibmpow_opt.c minmax_val.c
|
||||
encode_double_array.c grib_bits_ibmpow.c grib_bits_ibmpow_opt.c minmax_val.c \
|
||||
CMakeLists.txt grib_api_version.c.in
|
||||
|
||||
include $(DEVEL_RULES)
|
||||
|
||||
|
|
|
@ -25,6 +25,7 @@ extern grib_accessor_class* grib_accessor_class_data_2order_packing;
|
|||
extern grib_accessor_class* grib_accessor_class_data_2order_packing_count;
|
||||
extern grib_accessor_class* grib_accessor_class_data_apply_bitmap;
|
||||
extern grib_accessor_class* grib_accessor_class_data_apply_boustrophedonic;
|
||||
extern grib_accessor_class* grib_accessor_class_data_apply_boustrophedonic_bitmap;
|
||||
extern grib_accessor_class* grib_accessor_class_data_apply_gdsnotpresent;
|
||||
extern grib_accessor_class* grib_accessor_class_data_complex_packing;
|
||||
extern grib_accessor_class* grib_accessor_class_data_constant_field;
|
||||
|
|
|
@ -155,7 +155,6 @@ static void dump(grib_accessor* a, grib_dumper* dumper)
|
|||
grib_dump_values(dumper,a);
|
||||
}
|
||||
|
||||
|
||||
static int value_count(grib_accessor* a,long* count)
|
||||
{
|
||||
grib_accessor_data_apply_bitmap *self =(grib_accessor_data_apply_bitmap*)a;
|
||||
|
@ -172,7 +171,6 @@ static int value_count(grib_accessor* a,long* count)
|
|||
return ret;
|
||||
}
|
||||
|
||||
|
||||
static int unpack_double(grib_accessor* a, double* val, size_t *len)
|
||||
{
|
||||
grib_accessor_data_apply_bitmap* self = (grib_accessor_data_apply_bitmap*)a;
|
||||
|
@ -183,9 +181,7 @@ static int unpack_double(grib_accessor* a, double* val, size_t *len)
|
|||
long nn=0;
|
||||
int err=0;
|
||||
size_t coded_n_vals = 0;
|
||||
|
||||
double* coded_vals = NULL;
|
||||
|
||||
double missing_value = 0;
|
||||
|
||||
err=grib_value_count(a,&nn);
|
||||
|
@ -201,8 +197,7 @@ static int unpack_double(grib_accessor* a, double* val, size_t *len)
|
|||
if((err = grib_get_double_internal(a->parent->h,self->missing_value,&missing_value))
|
||||
!= GRIB_SUCCESS) return err;
|
||||
|
||||
if(*len < n_vals)
|
||||
{
|
||||
if(*len < n_vals) {
|
||||
*len = n_vals;
|
||||
return GRIB_ARRAY_TOO_SMALL;
|
||||
}
|
||||
|
@ -230,7 +225,7 @@ static int unpack_double(grib_accessor* a, double* val, size_t *len)
|
|||
}
|
||||
|
||||
grib_context_log(a->parent->h->context, GRIB_LOG_DEBUG,
|
||||
"grib_accessor_data_simple_packing_bitmap : unpack_double : creating %s, %d values",
|
||||
"grib_accessor_class_data_apply_bitmap: unpack_double : creating %s, %d values",
|
||||
a->name, n_vals);
|
||||
|
||||
for(i=0;i < n_vals;i++)
|
||||
|
@ -245,7 +240,7 @@ static int unpack_double(grib_accessor* a, double* val, size_t *len)
|
|||
{
|
||||
grib_context_free(a->parent->h->context,coded_vals);
|
||||
grib_context_log(a->parent->h->context, GRIB_LOG_ERROR,
|
||||
"grib_accessor_data_simple_packing_bitmap [%s]:"
|
||||
"grib_accessor_class_data_apply_bitmap [%s]:"
|
||||
" unpack_double : number of coded values does not match bitmap %ld %ld",
|
||||
a->name,coded_n_vals,n_vals);
|
||||
|
||||
|
@ -297,7 +292,6 @@ static int unpack_double_element(grib_accessor* a, size_t idx,double* val)
|
|||
grib_context_free(a->parent->h->context,bvals);
|
||||
|
||||
return grib_get_double_element_internal(a->parent->h,self->coded_values,cidx,val);
|
||||
|
||||
}
|
||||
|
||||
static int pack_double(grib_accessor* a, const double* val, size_t *len)
|
||||
|
|
|
@ -152,7 +152,6 @@ static void dump(grib_accessor* a, grib_dumper* dumper)
|
|||
grib_dump_values(dumper,a);
|
||||
}
|
||||
|
||||
|
||||
static int value_count(grib_accessor* a, long* numberOfPoints)
|
||||
{
|
||||
grib_accessor_data_apply_boustrophedonic *self =(grib_accessor_data_apply_boustrophedonic*)a;
|
||||
|
@ -162,10 +161,8 @@ static int value_count(grib_accessor* a, long* numberOfPoints)
|
|||
ret=grib_get_long_internal(a->parent->h,self->numberOfPoints,numberOfPoints);
|
||||
|
||||
return ret;
|
||||
|
||||
}
|
||||
|
||||
|
||||
static int unpack_double(grib_accessor* a, double* val, size_t *len)
|
||||
{
|
||||
grib_accessor_data_apply_boustrophedonic* self = (grib_accessor_data_apply_boustrophedonic*)a;
|
||||
|
@ -324,7 +321,6 @@ static int pack_double(grib_accessor* a, const double* val, size_t *len)
|
|||
|
||||
grib_context_free(a->parent->h->context,values);
|
||||
|
||||
|
||||
return ret;
|
||||
}
|
||||
|
||||
|
|
|
@ -0,0 +1,432 @@
|
|||
/*
|
||||
* Copyright 2005-2014 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.
|
||||
*/
|
||||
|
||||
#include "grib_api_internal.h"
|
||||
|
||||
/*
|
||||
This is used by make_class.pl
|
||||
|
||||
START_CLASS_DEF
|
||||
CLASS = accessor
|
||||
SUPER = grib_accessor_class_gen
|
||||
IMPLEMENTS = init
|
||||
IMPLEMENTS = unpack_double;unpack_double_element
|
||||
IMPLEMENTS = pack_double
|
||||
IMPLEMENTS = value_count
|
||||
IMPLEMENTS = dump;get_native_type
|
||||
MEMBERS=const char* coded_values
|
||||
MEMBERS=const char* bitmap
|
||||
MEMBERS=const char* missing_value
|
||||
MEMBERS=const char* binary_scale_factor
|
||||
MEMBERS=const char* numberOfRows
|
||||
MEMBERS=const char* numberOfColumns
|
||||
MEMBERS=const char* numberOfPoints
|
||||
|
||||
END_CLASS_DEF
|
||||
*/
|
||||
|
||||
/* START_CLASS_IMP */
|
||||
|
||||
/*
|
||||
|
||||
Don't edit anything between START_CLASS_IMP and END_CLASS_IMP
|
||||
Instead edit values between START_CLASS_DEF and END_CLASS_DEF
|
||||
or edit "accessor.class" and rerun ./make_class.pl
|
||||
|
||||
*/
|
||||
|
||||
static int get_native_type(grib_accessor*);
|
||||
static int pack_double(grib_accessor*, const double* val,size_t *len);
|
||||
static int unpack_double(grib_accessor*, double* val,size_t *len);
|
||||
static int value_count(grib_accessor*,long*);
|
||||
static void dump(grib_accessor*, grib_dumper*);
|
||||
static void init(grib_accessor*,const long, grib_arguments* );
|
||||
static void init_class(grib_accessor_class*);
|
||||
static int unpack_double_element(grib_accessor*,size_t i, double* val);
|
||||
|
||||
typedef struct grib_accessor_data_apply_boustrophedonic_bitmap {
|
||||
grib_accessor att;
|
||||
/* Members defined in gen */
|
||||
/* Members defined in data_apply_boustrophedonic_bitmap */
|
||||
const char* coded_values;
|
||||
const char* bitmap;
|
||||
const char* missing_value;
|
||||
const char* binary_scale_factor;
|
||||
const char* numberOfRows;
|
||||
const char* numberOfColumns;
|
||||
const char* numberOfPoints;
|
||||
} grib_accessor_data_apply_boustrophedonic_bitmap;
|
||||
|
||||
extern grib_accessor_class* grib_accessor_class_gen;
|
||||
|
||||
static grib_accessor_class _grib_accessor_class_data_apply_boustrophedonic_bitmap = {
|
||||
&grib_accessor_class_gen, /* super */
|
||||
"data_apply_boustrophedonic_bitmap", /* name */
|
||||
sizeof(grib_accessor_data_apply_boustrophedonic_bitmap), /* size */
|
||||
0, /* inited */
|
||||
&init_class, /* init_class */
|
||||
&init, /* init */
|
||||
0, /* post_init */
|
||||
0, /* free mem */
|
||||
&dump, /* describes himself */
|
||||
0, /* get length of section */
|
||||
0, /* get length of string */
|
||||
&value_count, /* get number of values */
|
||||
0, /* get number of bytes */
|
||||
0, /* get offset to bytes */
|
||||
&get_native_type, /* get native type */
|
||||
0, /* get sub_section */
|
||||
0, /* grib_pack procedures long */
|
||||
0, /* grib_pack procedures long */
|
||||
0, /* grib_pack procedures long */
|
||||
0, /* grib_unpack procedures long */
|
||||
&pack_double, /* grib_pack procedures double */
|
||||
&unpack_double, /* grib_unpack procedures double */
|
||||
0, /* grib_pack procedures string */
|
||||
0, /* grib_unpack procedures string */
|
||||
0, /* grib_pack procedures bytes */
|
||||
0, /* grib_unpack procedures bytes */
|
||||
0, /* pack_expression */
|
||||
0, /* notify_change */
|
||||
0, /* update_size */
|
||||
0, /* preferred_size */
|
||||
0, /* resize */
|
||||
0, /* nearest_smaller_value */
|
||||
0, /* next accessor */
|
||||
0, /* compare vs. another accessor */
|
||||
&unpack_double_element, /* unpack only ith value */
|
||||
0, /* unpack a subarray */
|
||||
0, /* clear */
|
||||
};
|
||||
|
||||
|
||||
grib_accessor_class* grib_accessor_class_data_apply_boustrophedonic_bitmap = &_grib_accessor_class_data_apply_boustrophedonic_bitmap;
|
||||
|
||||
|
||||
static void init_class(grib_accessor_class* c)
|
||||
{
|
||||
c->next_offset = (*(c->super))->next_offset;
|
||||
c->string_length = (*(c->super))->string_length;
|
||||
c->byte_count = (*(c->super))->byte_count;
|
||||
c->byte_offset = (*(c->super))->byte_offset;
|
||||
c->sub_section = (*(c->super))->sub_section;
|
||||
c->pack_missing = (*(c->super))->pack_missing;
|
||||
c->is_missing = (*(c->super))->is_missing;
|
||||
c->pack_long = (*(c->super))->pack_long;
|
||||
c->unpack_long = (*(c->super))->unpack_long;
|
||||
c->pack_string = (*(c->super))->pack_string;
|
||||
c->unpack_string = (*(c->super))->unpack_string;
|
||||
c->pack_bytes = (*(c->super))->pack_bytes;
|
||||
c->unpack_bytes = (*(c->super))->unpack_bytes;
|
||||
c->pack_expression = (*(c->super))->pack_expression;
|
||||
c->notify_change = (*(c->super))->notify_change;
|
||||
c->update_size = (*(c->super))->update_size;
|
||||
c->preferred_size = (*(c->super))->preferred_size;
|
||||
c->resize = (*(c->super))->resize;
|
||||
c->nearest_smaller_value = (*(c->super))->nearest_smaller_value;
|
||||
c->next = (*(c->super))->next;
|
||||
c->compare = (*(c->super))->compare;
|
||||
c->unpack_double_subarray = (*(c->super))->unpack_double_subarray;
|
||||
c->clear = (*(c->super))->clear;
|
||||
}
|
||||
|
||||
/* END_CLASS_IMP */
|
||||
|
||||
static void init(grib_accessor* a,const long v, grib_arguments* args)
|
||||
{
|
||||
int n=0;
|
||||
grib_accessor_data_apply_boustrophedonic_bitmap *self =(grib_accessor_data_apply_boustrophedonic_bitmap*)a;
|
||||
|
||||
self->coded_values = grib_arguments_get_name(a->parent->h,args,n++);
|
||||
self->bitmap = grib_arguments_get_name(a->parent->h,args,n++);
|
||||
self->missing_value = grib_arguments_get_name(a->parent->h,args,n++);
|
||||
self->binary_scale_factor = grib_arguments_get_name(a->parent->h,args,n++);
|
||||
|
||||
self->numberOfRows = grib_arguments_get_name(a->parent->h,args,n++);
|
||||
self->numberOfColumns = grib_arguments_get_name(a->parent->h,args,n++);
|
||||
self->numberOfPoints = grib_arguments_get_name(a->parent->h,args,n++);
|
||||
|
||||
a->length = 0;
|
||||
}
|
||||
static void dump(grib_accessor* a, grib_dumper* dumper)
|
||||
{
|
||||
grib_dump_values(dumper,a);
|
||||
}
|
||||
|
||||
static int value_count(grib_accessor* a,long* count)
|
||||
{
|
||||
grib_accessor_data_apply_boustrophedonic_bitmap *self =(grib_accessor_data_apply_boustrophedonic_bitmap*)a;
|
||||
size_t len = 0;
|
||||
int ret = 0;
|
||||
|
||||
/* This accessor is for data with a bitmap after all */
|
||||
Assert(grib_find_accessor(a->parent->h, self->bitmap));
|
||||
|
||||
ret = grib_get_size(a->parent->h, self->bitmap, &len);
|
||||
*count=len;
|
||||
return ret;
|
||||
}
|
||||
|
||||
static int unpack_double(grib_accessor* a, double* val, size_t *len)
|
||||
{
|
||||
grib_accessor_data_apply_boustrophedonic_bitmap* self = (grib_accessor_data_apply_boustrophedonic_bitmap*)a;
|
||||
|
||||
size_t i = 0, j = 0, n_vals = 0, irow = 0;
|
||||
long nn=0;
|
||||
int err=0;
|
||||
size_t coded_n_vals = 0;
|
||||
double* coded_vals = NULL;
|
||||
double missing_value = 0;
|
||||
long numberOfPoints, numberOfRows, numberOfColumns;
|
||||
|
||||
err=grib_value_count(a,&nn);
|
||||
n_vals=nn;
|
||||
if (err) return err;
|
||||
|
||||
err=grib_get_long_internal(a->parent->h,self->numberOfRows,&numberOfRows);
|
||||
if (err) return err;
|
||||
err=grib_get_long_internal(a->parent->h,self->numberOfColumns,&numberOfColumns);
|
||||
if (err) return err;
|
||||
err=grib_get_long_internal(a->parent->h,self->numberOfPoints,&numberOfPoints);
|
||||
if (err) return err;
|
||||
Assert(nn == numberOfPoints);
|
||||
|
||||
if(!grib_find_accessor(a->parent->h,self->bitmap))
|
||||
return grib_get_double_array_internal(a->parent->h,self->coded_values,val,len);
|
||||
|
||||
if((err = grib_get_size(a->parent->h,self->coded_values,&coded_n_vals)) != GRIB_SUCCESS)
|
||||
return err;
|
||||
|
||||
if((err = grib_get_double_internal(a->parent->h,self->missing_value,&missing_value))
|
||||
!= GRIB_SUCCESS) return err;
|
||||
|
||||
if(*len < n_vals) {
|
||||
*len = n_vals;
|
||||
return GRIB_ARRAY_TOO_SMALL;
|
||||
}
|
||||
|
||||
if (coded_n_vals==0) {
|
||||
for(i=0;i < n_vals;i++)
|
||||
val[i] = missing_value;
|
||||
|
||||
*len=n_vals;
|
||||
return GRIB_SUCCESS;
|
||||
}
|
||||
|
||||
if((err = grib_get_double_array_internal(a->parent->h,self->bitmap,val,&n_vals))
|
||||
!= GRIB_SUCCESS)
|
||||
return err;
|
||||
|
||||
coded_vals = grib_context_malloc(a->parent->h->context,coded_n_vals*sizeof(double));
|
||||
if(coded_vals == NULL) return GRIB_OUT_OF_MEMORY;
|
||||
|
||||
if((err = grib_get_double_array_internal(a->parent->h,self->coded_values,coded_vals,&coded_n_vals))
|
||||
!= GRIB_SUCCESS)
|
||||
{
|
||||
grib_context_free(a->parent->h->context,coded_vals);
|
||||
return err;
|
||||
}
|
||||
|
||||
grib_context_log(a->parent->h->context, GRIB_LOG_DEBUG,
|
||||
"grib_accessor_class_data_apply_boustrophedonic_bitmap: unpack_double : creating %s, %d values",
|
||||
a->name, n_vals);
|
||||
|
||||
/* Boustrophedonic ordering (See GRIB-472):
|
||||
* Values on even rank lines (the initial line scanned having rank 1) are swapped
|
||||
*/
|
||||
for(irow=0; irow<numberOfRows; ++irow)
|
||||
{
|
||||
if (irow%2)
|
||||
{
|
||||
/* Reverse bitmap entries */
|
||||
size_t k = 0;
|
||||
size_t start = irow*numberOfColumns;
|
||||
size_t end = start + numberOfColumns - 1;
|
||||
size_t mid = (numberOfColumns - 1)/2;
|
||||
for(k=0; k<mid; ++k)
|
||||
{
|
||||
/* Swap value at either end */
|
||||
double temp = val[start+k];
|
||||
val[start+k] = val[end-k];
|
||||
val[end-k] = temp;
|
||||
}
|
||||
}
|
||||
}
|
||||
|
||||
for(i=0;i < n_vals;i++)
|
||||
{
|
||||
if(val[i] == 0 ){
|
||||
val[i] = missing_value;
|
||||
}
|
||||
else
|
||||
{
|
||||
val[i] = coded_vals[j++];
|
||||
if(j>coded_n_vals)
|
||||
{
|
||||
grib_context_free(a->parent->h->context,coded_vals);
|
||||
grib_context_log(a->parent->h->context, GRIB_LOG_ERROR,
|
||||
"grib_accessor_class_data_apply_boustrophedonic_bitmap [%s]:"
|
||||
" unpack_double : number of coded values does not match bitmap %ld %ld",
|
||||
a->name,coded_n_vals,n_vals);
|
||||
|
||||
return GRIB_ARRAY_TOO_SMALL;
|
||||
}
|
||||
}
|
||||
}
|
||||
|
||||
*len = n_vals;
|
||||
|
||||
grib_context_free(a->parent->h->context,coded_vals);
|
||||
return err;
|
||||
}
|
||||
|
||||
static int unpack_double_element(grib_accessor* a, size_t idx,double* val)
|
||||
{
|
||||
grib_accessor_data_apply_boustrophedonic_bitmap* self = (grib_accessor_data_apply_boustrophedonic_bitmap*)a;
|
||||
int err = 0,i=0;
|
||||
size_t cidx=0;
|
||||
double missing_value = 0;
|
||||
double* bvals=NULL;
|
||||
size_t n_vals = 0;
|
||||
long nn=0;
|
||||
|
||||
err=grib_value_count(a,&nn);
|
||||
n_vals=nn;
|
||||
if (err) return err;
|
||||
|
||||
if(!grib_find_accessor(a->parent->h,self->bitmap))
|
||||
return grib_get_double_element_internal(a->parent->h,self->coded_values,idx,val);
|
||||
|
||||
if((err = grib_get_double_internal(a->parent->h,self->missing_value,&missing_value)) != GRIB_SUCCESS)
|
||||
return err;
|
||||
|
||||
if((err = grib_get_double_element_internal(a->parent->h,self->bitmap,idx,val)) != GRIB_SUCCESS)
|
||||
return err;
|
||||
|
||||
if (*val == 0) {*val=missing_value;return GRIB_SUCCESS;}
|
||||
|
||||
bvals = grib_context_malloc(a->parent->h->context,n_vals*sizeof(double));
|
||||
if(bvals == NULL) return GRIB_OUT_OF_MEMORY;
|
||||
|
||||
if((err = grib_get_double_array_internal(a->parent->h,self->bitmap,bvals,&n_vals)) != GRIB_SUCCESS)
|
||||
return err;
|
||||
|
||||
cidx=0;
|
||||
for (i=0;i<idx;i++) {cidx+=bvals[i];}
|
||||
|
||||
grib_context_free(a->parent->h->context,bvals);
|
||||
|
||||
return grib_get_double_element_internal(a->parent->h,self->coded_values,cidx,val);
|
||||
}
|
||||
|
||||
static int pack_double(grib_accessor* a, const double* val, size_t *len)
|
||||
{
|
||||
grib_accessor_data_apply_boustrophedonic_bitmap* self = (grib_accessor_data_apply_boustrophedonic_bitmap*)a;
|
||||
int err = 0;
|
||||
size_t bmaplen = *len;
|
||||
size_t irow = 0;
|
||||
long coded_n_vals = 0;
|
||||
double* coded_vals = NULL;
|
||||
double *values=0;
|
||||
long i = 0;
|
||||
long j = 0;
|
||||
long numberOfPoints, numberOfRows, numberOfColumns;
|
||||
double missing_value = 0;
|
||||
|
||||
if (*len ==0) return GRIB_NO_VALUES;
|
||||
|
||||
if(!grib_find_accessor(a->parent->h,self->bitmap)){
|
||||
err = grib_set_double_array_internal(a->parent->h,self->coded_values,val,*len);
|
||||
/*printf("SETTING TOTAL number_of_data_points %s %ld\n",self->number_of_data_points,*len);*/
|
||||
/*if(self->number_of_data_points)
|
||||
grib_set_long_internal(a->parent->h,self->number_of_data_points,*len);*/
|
||||
return err;
|
||||
}
|
||||
|
||||
if((err = grib_get_double_internal(a->parent->h,self->missing_value,&missing_value)) != GRIB_SUCCESS)
|
||||
return err;
|
||||
|
||||
err=grib_get_long_internal(a->parent->h,self->numberOfRows, &numberOfRows);
|
||||
if (err) return err;
|
||||
err=grib_get_long_internal(a->parent->h,self->numberOfColumns, &numberOfColumns);
|
||||
if (err) return err;
|
||||
err=grib_get_long_internal(a->parent->h,self->numberOfPoints,&numberOfPoints);
|
||||
if (err) return err;
|
||||
Assert(numberOfPoints == bmaplen);
|
||||
|
||||
/* Create a copy of the incoming 'val' array because we're going to change it */
|
||||
values = grib_context_malloc_clear(a->parent->h->context, sizeof(double)*numberOfPoints);
|
||||
if (!values) return GRIB_OUT_OF_MEMORY;
|
||||
for(i=0; i<numberOfPoints; ++i) {
|
||||
values[i] = val[i];
|
||||
}
|
||||
|
||||
/* Boustrophedonic ordering must be applied to the bitmap (See GRIB-472) */
|
||||
for(irow=0; irow<numberOfRows; ++irow)
|
||||
{
|
||||
if (irow%2)
|
||||
{
|
||||
size_t k = 0;
|
||||
size_t start = irow*numberOfColumns;
|
||||
size_t end = start + numberOfColumns - 1;
|
||||
size_t mid = (numberOfColumns - 1)/2;
|
||||
for(k=0; k<mid; ++k)
|
||||
{
|
||||
double temp = values[start+k];
|
||||
values[start+k] = values[end-k];
|
||||
values[end-k] = temp;
|
||||
}
|
||||
}
|
||||
}
|
||||
/* Now set the bitmap based on the array with the boustrophedonic ordering */
|
||||
if((err = grib_set_double_array_internal(a->parent->h,self->bitmap,values,bmaplen)) != GRIB_SUCCESS)
|
||||
return err;
|
||||
|
||||
grib_context_free(a->parent->h->context,values);
|
||||
|
||||
coded_n_vals = *len;
|
||||
|
||||
if(coded_n_vals < 1){
|
||||
err = grib_set_double_array_internal(a->parent->h,self->coded_values,NULL,0);
|
||||
return err;
|
||||
}
|
||||
|
||||
coded_vals = grib_context_malloc_clear(a->parent->h->context,coded_n_vals*sizeof(double));
|
||||
if(!coded_vals) return GRIB_OUT_OF_MEMORY;
|
||||
|
||||
for(i=0; i<*len ; i++)
|
||||
{
|
||||
/* To set the coded values, look at 'val' (the original array) */
|
||||
/* NOT 'values' (bitmap) which we swapped about */
|
||||
if(val[i] != missing_value) {
|
||||
coded_vals[j++] = val[i];
|
||||
}
|
||||
}
|
||||
|
||||
err = grib_set_double_array_internal(a->parent->h,self->coded_values,coded_vals,j);
|
||||
if (j==0) {
|
||||
/*if (self->number_of_values)
|
||||
err=grib_set_long_internal(a->parent->h,self->number_of_values,0);*/
|
||||
if (self->binary_scale_factor)
|
||||
err=grib_set_long_internal(a->parent->h,self->binary_scale_factor,0);
|
||||
}
|
||||
|
||||
grib_context_free(a->parent->h->context,coded_vals);
|
||||
|
||||
return err;
|
||||
}
|
||||
|
||||
static int get_native_type(grib_accessor* a)
|
||||
{
|
||||
/* grib_accessor_data_apply_boustrophedonic_bitmap* self = (grib_accessor_data_apply_boustrophedonic_bitmap*)a;
|
||||
return grib_accessor_get_native_type(grib_find_accessor(a->parent->h,self->coded_values));*/
|
||||
|
||||
return GRIB_TYPE_DOUBLE;
|
||||
}
|
|
@ -19,6 +19,7 @@
|
|||
IMPLEMENTS = init
|
||||
IMPLEMENTS = pack_double
|
||||
IMPLEMENTS = unpack_double
|
||||
IMPLEMENTS = unpack_double_element
|
||||
IMPLEMENTS = value_count
|
||||
IMPLEMENTS = destroy
|
||||
MEMBERS=const char* half_byte
|
||||
|
@ -67,6 +68,7 @@ static int value_count(grib_accessor*,long*);
|
|||
static void destroy(grib_context*,grib_accessor*);
|
||||
static void init(grib_accessor*,const long, grib_arguments* );
|
||||
static void init_class(grib_accessor_class*);
|
||||
static int unpack_double_element(grib_accessor*,size_t i, double* val);
|
||||
|
||||
typedef struct grib_accessor_data_g1second_order_general_extended_packing {
|
||||
grib_accessor att;
|
||||
|
@ -151,7 +153,7 @@ static grib_accessor_class _grib_accessor_class_data_g1second_order_general_exte
|
|||
0, /* nearest_smaller_value */
|
||||
0, /* next accessor */
|
||||
0, /* compare vs. another accessor */
|
||||
0, /* unpack only ith value */
|
||||
&unpack_double_element, /* unpack only ith value */
|
||||
0, /* unpack a subarray */
|
||||
0, /* clear */
|
||||
};
|
||||
|
@ -185,7 +187,6 @@ static void init_class(grib_accessor_class* c)
|
|||
c->nearest_smaller_value = (*(c->super))->nearest_smaller_value;
|
||||
c->next = (*(c->super))->next;
|
||||
c->compare = (*(c->super))->compare;
|
||||
c->unpack_double_element = (*(c->super))->unpack_double_element;
|
||||
c->unpack_double_subarray = (*(c->super))->unpack_double_subarray;
|
||||
c->clear = (*(c->super))->clear;
|
||||
}
|
||||
|
@ -204,10 +205,15 @@ static unsigned long nbits[32]={
|
|||
0x40000000, 0x80000000
|
||||
};
|
||||
|
||||
GRIB_INLINE static long number_of_bits(unsigned long x) {
|
||||
static long number_of_bits(unsigned long x) {
|
||||
unsigned long *n=nbits;
|
||||
const int count = sizeof(nbits)/sizeof(nbits[0]);
|
||||
long i=0;
|
||||
while (x>=*n) {n++;i++;}
|
||||
while (x>=*n) {
|
||||
n++;
|
||||
i++;
|
||||
Assert(i<count);
|
||||
}
|
||||
return i;
|
||||
}
|
||||
|
||||
|
@ -278,6 +284,24 @@ static int value_count(grib_accessor* a,long* count)
|
|||
return err;
|
||||
}
|
||||
|
||||
static int unpack_double_element(grib_accessor* a, size_t idx, double* val)
|
||||
{
|
||||
size_t size;
|
||||
double* values;
|
||||
int err=0;
|
||||
|
||||
err=grib_get_size(a->parent->h,"values",&size);
|
||||
if (err) return err;
|
||||
if (idx > size) return GRIB_INVALID_NEAREST;
|
||||
|
||||
values=grib_context_malloc_clear(a->parent->h->context,size*sizeof(double));
|
||||
err=grib_get_double_array(a->parent->h,"values",values,&size);
|
||||
if (err) return err;
|
||||
*val=values[idx];
|
||||
grib_context_free(a->parent->h->context,values);
|
||||
return err;
|
||||
}
|
||||
|
||||
static int unpack_double(grib_accessor* a, double* values, size_t *len)
|
||||
{
|
||||
grib_accessor_data_g1second_order_general_extended_packing* self = (grib_accessor_data_g1second_order_general_extended_packing*)a;
|
||||
|
|
|
@ -167,7 +167,6 @@ static void init(grib_accessor* a,const long v, grib_arguments* args)
|
|||
self->decimal_scale_factor = grib_arguments_get_name(a->parent->h,args,self->carg++);
|
||||
a->flags |= GRIB_ACCESSOR_FLAG_DATA;
|
||||
self->dirty=1;
|
||||
|
||||
}
|
||||
|
||||
static unsigned long nbits[32]={
|
||||
|
@ -179,14 +178,22 @@ static unsigned long nbits[32]={
|
|||
0x40000000, 0x80000000
|
||||
};
|
||||
|
||||
GRIB_INLINE static long number_of_bits(unsigned long x) {
|
||||
static int number_of_bits(unsigned long x, long* result)
|
||||
{
|
||||
int err = 0;
|
||||
const int count = sizeof(nbits)/sizeof(nbits[0]);
|
||||
unsigned long *n=nbits;
|
||||
long i=0;
|
||||
while (x>=*n) {n++;i++;}
|
||||
return i;
|
||||
*result=0;
|
||||
while (x >= *n) {
|
||||
n++;
|
||||
(*result)++;
|
||||
if (*result >= count) {
|
||||
return GRIB_ENCODING_ERROR;
|
||||
}
|
||||
}
|
||||
return GRIB_SUCCESS;
|
||||
}
|
||||
|
||||
|
||||
static int value_count(grib_accessor* a,long* number_of_values)
|
||||
{
|
||||
grib_accessor_data_simple_packing* self = (grib_accessor_data_simple_packing*)a;
|
||||
|
@ -281,7 +288,6 @@ static int unpack_double_element(grib_accessor* a, size_t idx, double* val)
|
|||
lvalue |= buf[o++] ;
|
||||
}
|
||||
*val = (double) (((lvalue*s)+reference_value)*d);
|
||||
|
||||
}
|
||||
|
||||
return err;
|
||||
|
@ -303,7 +309,6 @@ static int _unpack_double(grib_accessor* a, double* val, size_t *len,unsigned c
|
|||
double units_factor=1.0;
|
||||
double units_bias=0.0;
|
||||
|
||||
|
||||
if(*len < n_vals)
|
||||
{
|
||||
*len = (long) n_vals;
|
||||
|
@ -571,7 +576,14 @@ static int pack_double(grib_accessor* a, const double* val, size_t *len)
|
|||
max*=decimal;
|
||||
|
||||
/* bits_per_value=(long)ceil(log((double)(imax-imin+1))/log(2.0)); */
|
||||
bits_per_value=number_of_bits((unsigned long)fabs(max-min));
|
||||
/* See GRIB-540 for why we use ceil */
|
||||
err = number_of_bits( (unsigned long)ceil(fabs(max-min)), &bits_per_value );
|
||||
if (err) {
|
||||
grib_context_log(a->parent->h->context,GRIB_LOG_ERROR,
|
||||
"Range of values too large. Try a smaller value for decimal precision (less than %d)",
|
||||
decimal_scale_factor);
|
||||
return err;
|
||||
}
|
||||
/*printf("bits_per_value=%ld\n",bits_per_value);*/
|
||||
if((err = grib_set_long_internal(a->parent->h,self->bits_per_value, bits_per_value)) !=
|
||||
GRIB_SUCCESS)
|
||||
|
@ -649,6 +661,5 @@ static int pack_double(grib_accessor* a, const double* val, size_t *len)
|
|||
!= GRIB_SUCCESS)
|
||||
return err;
|
||||
|
||||
|
||||
return GRIB_SUCCESS;
|
||||
}
|
||||
|
|
|
@ -181,8 +181,8 @@ static int unpack_long(grib_accessor* a, long* val, size_t *len)
|
|||
if((ret = grib_get_long_internal(a->parent->h, self->subdivision,&subdivision)) != GRIB_SUCCESS)
|
||||
return ret;
|
||||
|
||||
if ((basic_angle!=0 && basic_angle!=GRIB_MISSING_LONG) ||
|
||||
( subdivision !=0 && subdivision == GRIB_MISSING_LONG)) {
|
||||
if ( (basic_angle !=0 && basic_angle != GRIB_MISSING_LONG) ||
|
||||
( subdivision !=0 && subdivision != GRIB_MISSING_LONG) ) {
|
||||
*val=0;
|
||||
return ret;
|
||||
}
|
||||
|
|
|
@ -143,10 +143,15 @@ static unsigned long nbits[32]={
|
|||
0x40000000, 0x80000000
|
||||
};
|
||||
|
||||
GRIB_INLINE static long number_of_bits(unsigned long x) {
|
||||
static long number_of_bits(unsigned long x) {
|
||||
unsigned long *n=nbits;
|
||||
const int count = sizeof(nbits)/sizeof(nbits[0]);
|
||||
long i=0;
|
||||
while (x>=*n) {n++;i++;}
|
||||
while (x>=*n) {
|
||||
n++;
|
||||
i++;
|
||||
Assert(i<count);
|
||||
}
|
||||
return i;
|
||||
}
|
||||
|
||||
|
@ -217,11 +222,11 @@ static int unpack_long(grib_accessor* a, long* val, size_t *len)
|
|||
b=grib_power(-binaryScaleFactor,2);
|
||||
|
||||
/* self->bitsPerValue=(long)ceil(log((double)((max-min)*d+1))/log(2.0))-binaryScaleFactor; */
|
||||
self->bitsPerValue=number_of_bits((unsigned long)(fabs(max-min)*b*d));
|
||||
/* See GRIB-540 for why we use ceil */
|
||||
self->bitsPerValue=number_of_bits( (unsigned long)ceil((fabs(max-min)*b*d)) );
|
||||
*val=self->bitsPerValue;
|
||||
|
||||
grib_context_free(a->parent->h->context,values);
|
||||
|
||||
return ret;
|
||||
}
|
||||
|
||||
|
|
|
@ -25,6 +25,7 @@
|
|||
{ "data_2order_packing_count", &grib_accessor_class_data_2order_packing_count, },
|
||||
{ "data_apply_bitmap", &grib_accessor_class_data_apply_bitmap, },
|
||||
{ "data_apply_boustrophedonic", &grib_accessor_class_data_apply_boustrophedonic, },
|
||||
{ "data_apply_boustrophedonic_bitmap", &grib_accessor_class_data_apply_boustrophedonic_bitmap, },
|
||||
{ "data_apply_gdsnotpresent", &grib_accessor_class_data_apply_gdsnotpresent, },
|
||||
{ "data_complex_packing", &grib_accessor_class_data_complex_packing, },
|
||||
{ "data_constant_field", &grib_accessor_class_data_constant_field, },
|
||||
|
|
|
@ -1196,6 +1196,8 @@ void grib_multi_support_off(grib_context* c);
|
|||
* @param f : the file pointer
|
||||
*/
|
||||
void grib_multi_support_reset_file(grib_context* c, FILE* f);
|
||||
|
||||
char* grib_samples_path(const grib_context *c);
|
||||
/*! @} */
|
||||
|
||||
/**
|
||||
|
@ -1242,7 +1244,6 @@ grib_keys_iterator* grib_keys_iterator_new(grib_handle* h,unsigned long filter_f
|
|||
int grib_keys_iterator_next(grib_keys_iterator *kiter);
|
||||
|
||||
|
||||
|
||||
/*! get the key name from the iterator
|
||||
* @param kiter : valid grib_keys_iterator
|
||||
* @return key name
|
||||
|
|
|
@ -429,6 +429,7 @@ second_order_packed *grib_get_second_order_groups(grib_context *c, const unsigne
|
|||
/* grib_accessor_class_data_apply_bitmap.c */
|
||||
|
||||
/* grib_accessor_class_data_apply_boustrophedonic.c */
|
||||
/* grib_accessor_class_data_apply_boustrophedonic_bitmap.c */
|
||||
|
||||
/* grib_accessor_class_data_secondary_bitmap.c */
|
||||
|
||||
|
|
|
@ -230,6 +230,9 @@ void grib_print_api_version(FILE* out)
|
|||
GRIB_API_MAJOR_VERSION,
|
||||
GRIB_API_MINOR_VERSION,
|
||||
GRIB_API_REVISION_VERSION);
|
||||
if (GRIB_API_MAJOR_VERSION < 1) {
|
||||
printf(" PRE-RELEASE");
|
||||
}
|
||||
}
|
||||
|
||||
static grib_context default_grib_context = {
|
||||
|
@ -581,6 +584,12 @@ char *grib_context_full_defs_path(grib_context* c,const char* basename)
|
|||
return NULL;
|
||||
}
|
||||
|
||||
char* grib_samples_path(const grib_context *c)
|
||||
{
|
||||
if (!c) c=grib_context_get_default();
|
||||
return c->grib_samples_path;
|
||||
}
|
||||
|
||||
void grib_context_free(const grib_context* c, void* p)
|
||||
{
|
||||
if (!c) c=grib_context_get_default();
|
||||
|
|
9403
src/grib_hash_keys.c
9403
src/grib_hash_keys.c
File diff suppressed because it is too large
Load Diff
|
@ -103,7 +103,6 @@ static int next(grib_iterator* i, double *lat, double *lon, double *val)
|
|||
return 1;
|
||||
}
|
||||
|
||||
|
||||
static int init(grib_iterator* iter,grib_handle* h,grib_arguments* args)
|
||||
{
|
||||
int ret=GRIB_SUCCESS,j;
|
||||
|
@ -139,6 +138,7 @@ static int init(grib_iterator* iter,grib_handle* h,grib_arguments* args)
|
|||
return ret;
|
||||
|
||||
lats=(double*)grib_context_malloc(h->context,sizeof(double)*order*2);
|
||||
if (!lats) return GRIB_OUT_OF_MEMORY;
|
||||
if((ret = grib_get_gaussian_latitudes(order, lats)) != GRIB_SUCCESS)
|
||||
return ret;
|
||||
|
||||
|
@ -146,10 +146,14 @@ static int init(grib_iterator* iter,grib_handle* h,grib_arguments* args)
|
|||
return ret;
|
||||
|
||||
pl=(long*)grib_context_malloc(c,sizeof(long)*plsize);
|
||||
if (!pl) return GRIB_OUT_OF_MEMORY;
|
||||
|
||||
grib_get_long_array_internal(h,spl,pl, &plsize);
|
||||
|
||||
self->las = grib_context_malloc(h->context,iter->nv*sizeof(double));
|
||||
if (!self->las) return GRIB_OUT_OF_MEMORY;
|
||||
self->los = grib_context_malloc(h->context,iter->nv*sizeof(double));
|
||||
if (!self->los) return GRIB_OUT_OF_MEMORY;
|
||||
|
||||
while (lon_last<0) lon_last+=360;
|
||||
while (lon_first<0) lon_first+=360;
|
||||
|
@ -166,11 +170,14 @@ static int init(grib_iterator* iter,grib_handle* h,grib_arguments* args)
|
|||
iter->e=0;
|
||||
for (j=0;j<plsize;j++) {
|
||||
row_count=0;
|
||||
/*printf("lat=%g\n",lats[j+l]);*/
|
||||
grib_get_reduced_row(pl[j],lon_first,lon_last,
|
||||
&row_count,&ilon_first,&ilon_last);
|
||||
if (ilon_first>ilon_last) ilon_first-=pl[j];
|
||||
for (i=ilon_first;i<=ilon_last;i++) {
|
||||
#ifdef DEBUG
|
||||
Assert(0);
|
||||
Assert(iter->e < iter->nv);
|
||||
#endif
|
||||
self->los[iter->e]=((i)*360.0)/pl[j];
|
||||
self->las[iter->e]=lats[j+l];
|
||||
iter->e++;
|
||||
|
@ -182,6 +189,9 @@ static int init(grib_iterator* iter,grib_handle* h,grib_arguments* args)
|
|||
for (j=0;j<plsize;j++) {
|
||||
row_count=pl[j];
|
||||
for (i=0;i<row_count;i++) {
|
||||
#ifdef DEBUG
|
||||
Assert(iter->e < iter->nv);
|
||||
#endif
|
||||
self->los[iter->e]=(i*360.0)/row_count;
|
||||
self->las[iter->e]=lats[j];
|
||||
iter->e++;
|
||||
|
|
|
@ -214,7 +214,8 @@ static int find(grib_nearest* nearest, grib_handle* h,
|
|||
static int find(grib_nearest* nearest, grib_handle* h,
|
||||
double inlat, double inlon,unsigned long flags,
|
||||
double* outlats,double* outlons,
|
||||
double *values,double *distances,int* indexes, size_t *len) {
|
||||
double *values,double *distances,int* indexes, size_t *len)
|
||||
{
|
||||
grib_nearest_regular* self = (grib_nearest_regular*) nearest;
|
||||
int ret=0,kk=0,ii=0,jj=0;
|
||||
size_t nvalues=0;
|
||||
|
@ -358,12 +359,29 @@ static int find(grib_nearest* nearest, grib_handle* h,
|
|||
}
|
||||
|
||||
kk=0;
|
||||
|
||||
/*
|
||||
* Brute force algorithm:
|
||||
* First unpack all the values into an array. Then when we need the 4 points
|
||||
* we just index into this array so no need to call grib_get_double_element_internal
|
||||
*
|
||||
* if (nearest->values) grib_context_free(nearest->context,nearest->values);
|
||||
* nearest->values = grib_context_malloc(h->context,nvalues*sizeof(double));
|
||||
* if (!nearest->values) return GRIB_OUT_OF_MEMORY;
|
||||
* ret = grib_get_double_array(h, self->values_key, nearest->values ,&nvalues);
|
||||
* if (ret) return ret;
|
||||
*/
|
||||
|
||||
for (jj=0;jj<2;jj++) {
|
||||
for (ii=0;ii<2;ii++) {
|
||||
distances[kk]=self->distances[kk];
|
||||
outlats[kk]=self->lats[self->j[jj]];
|
||||
outlons[kk]=self->lons[self->i[ii]];
|
||||
grib_get_double_element_internal(h,self->values_key,self->k[kk],&(values[kk]));
|
||||
/* Using the brute force approach described above */
|
||||
/* Assert(self->k[kk] < nvalues); */
|
||||
/* values[kk]=nearest->values[self->k[kk]]; */
|
||||
|
||||
indexes[kk]=self->k[kk];
|
||||
kk++;
|
||||
}
|
||||
|
|
|
@ -99,6 +99,7 @@ int grib_recompose_name(grib_handle* h, grib_accessor *observer, const char* una
|
|||
break;
|
||||
default:
|
||||
grib_context_log(h->context, GRIB_LOG_WARNING,"grib_recompose_name: Problem to recompose filename with : %s, invalid type %d", loc,type);
|
||||
break;
|
||||
}
|
||||
|
||||
grib_dependency_add(observer,a);
|
||||
|
@ -146,7 +147,7 @@ int grib_recompose_print(grib_handle* h, grib_accessor *observer, const char* un
|
|||
int maxcolsd=8;
|
||||
int maxcols;
|
||||
int mode = -1;
|
||||
char val[1024];
|
||||
char val[1024] = {0,};
|
||||
char* sval=NULL;
|
||||
char* p=NULL;
|
||||
char* pp=NULL;
|
||||
|
@ -303,6 +304,7 @@ int grib_recompose_print(grib_handle* h, grib_accessor *observer, const char* un
|
|||
break;
|
||||
default:
|
||||
loc[mode++]=uname[i];
|
||||
break;
|
||||
}
|
||||
} else if(uname[i]=='[') {
|
||||
mode = 0;
|
||||
|
@ -317,7 +319,6 @@ int grib_recompose_print(grib_handle* h, grib_accessor *observer, const char* un
|
|||
return ret;
|
||||
}
|
||||
|
||||
|
||||
grib_action_file* grib_find_action_file(const char* fname , grib_action_file_list* afl)
|
||||
{
|
||||
grib_action_file* act = afl->first;
|
||||
|
@ -368,7 +369,6 @@ int grib_yywrap()
|
|||
|
||||
grib_yylineno = stack[top].line;
|
||||
|
||||
|
||||
if(top)
|
||||
{
|
||||
parse_file = stack[top-1].name;
|
||||
|
@ -633,4 +633,3 @@ int grib_type_to_int(char id) {
|
|||
}
|
||||
return GRIB_TYPE_UNDEFINED;
|
||||
}
|
||||
|
||||
|
|
|
@ -576,7 +576,7 @@ int grib_set_double_array_internal(grib_handle* h, const char* name, const doubl
|
|||
int ret=0;
|
||||
|
||||
if (h->context->debug==-1)
|
||||
printf("GRIB_API DEBUG grib_set_double_array_internal %ld values\n",(long)length);
|
||||
printf("GRIB_API DEBUG grib_set_double_array_internal key=%s %ld values\n",name, (long)length);
|
||||
|
||||
if (length==0) {
|
||||
grib_accessor* a = grib_find_accessor(h, name);
|
||||
|
@ -588,6 +588,7 @@ int grib_set_double_array_internal(grib_handle* h, const char* name, const doubl
|
|||
if (ret!=GRIB_SUCCESS)
|
||||
grib_context_log(h->context,GRIB_LOG_ERROR,"unable to set double array %s (%s)",
|
||||
name,grib_get_error_message(ret));
|
||||
/*if (h->context->debug==-1) printf("GRIB_API DEBUG grib_set_double_array_internal key=%s --DONE\n",name);*/
|
||||
return ret;
|
||||
}
|
||||
|
||||
|
@ -597,7 +598,7 @@ static int __grib_set_double_array(grib_handle* h, const char* name, const doubl
|
|||
int constant,i;
|
||||
|
||||
if (h->context->debug==-1)
|
||||
printf("GRIB_API DEBUG grib_set_double_array %ld values\n",(long)length);
|
||||
printf("GRIB_API DEBUG grib_set_double_array key=%s %ld values\n",name,(long)length);
|
||||
|
||||
if (length==0) {
|
||||
grib_accessor* a = grib_find_accessor(h, name);
|
||||
|
|
|
@ -9,7 +9,9 @@ cd ../src
|
|||
|
||||
# Editing keys grib_hash_keys.c
|
||||
|
||||
gperf -I -t -G -H hash_keys -N grib_keys_hash_get -m 3 ../tests/keys | sed s/__inline//g | sed s/inline//g > grib_hash_keys.c
|
||||
gperf -I -t -G -H hash_keys -N grib_keys_hash_get -m 3 ../tests/keys |\
|
||||
sed '/__attribute__ ((__gnu_inline__))/d' |\
|
||||
sed s/__inline//g | sed s/inline//g > grib_hash_keys.c
|
||||
|
||||
cat grib_itrie_keys.c >> grib_hash_keys.c
|
||||
|
||||
|
|
|
@ -14,6 +14,7 @@ list( APPEND test_bins
|
|||
unit_tests
|
||||
gauss_sub
|
||||
)
|
||||
|
||||
foreach( tool ${test_bins} )
|
||||
# here we use the fact that each tool has only one C file that matches its name
|
||||
ecbuild_add_executable( TARGET ${tool}
|
||||
|
@ -62,12 +63,14 @@ list( APPEND tests
|
|||
debug
|
||||
unit_tests
|
||||
)
|
||||
foreach (test ${tests})
|
||||
|
||||
foreach( test ${tests} )
|
||||
|
||||
ecbuild_add_test( TARGET t_${test}
|
||||
TYPE SCRIPT
|
||||
COMMAND ${CMAKE_CURRENT_SOURCE_DIR}/${test}.sh
|
||||
RESOURCES include.sh
|
||||
)
|
||||
)
|
||||
endforeach()
|
||||
|
||||
###########################################
|
||||
|
@ -79,18 +82,16 @@ ecbuild_add_test( TARGET t_lamb_az_eq_area
|
|||
)
|
||||
|
||||
# These ones are conditional
|
||||
if ( ENABLE_NETCDF )
|
||||
ecbuild_add_test( TARGET t_grib_to_netcdf
|
||||
ecbuild_add_test( TARGET t_grib_to_netcdf
|
||||
TYPE SCRIPT
|
||||
CONDITION ENABLE_NETCDF
|
||||
COMMAND ${CMAKE_CURRENT_SOURCE_DIR}/grib_to_netcdf.sh
|
||||
RESOURCES include.sh
|
||||
)
|
||||
endif()
|
||||
)
|
||||
|
||||
if( ENABLE_JPG )
|
||||
ecbuild_add_test( TARGET t_jpeg
|
||||
ecbuild_add_test( TARGET t_jpeg
|
||||
TYPE SCRIPT
|
||||
CONDITION ENABLE_JPG
|
||||
COMMAND ${CMAKE_CURRENT_SOURCE_DIR}/jpeg.sh
|
||||
RESOURCES include.sh
|
||||
)
|
||||
endif()
|
||||
)
|
||||
|
|
|
@ -37,5 +37,5 @@ LDADD = $(top_builddir)/src/libgrib_api.la $(EMOS_LIB)
|
|||
INCLUDES = -I$(top_builddir)/src
|
||||
|
||||
EXTRA_DIST = $(TESTS) mf.rules filter_rules include.sh include.ctest.sh.in \
|
||||
lamb_az_eq_area.ref
|
||||
lamb_az_eq_area.ref CMakeLists.txt
|
||||
|
||||
|
|
|
@ -1,4 +1,4 @@
|
|||
#!/bin/sh
|
||||
#! /bin/sh
|
||||
# Copyright 2005-2014 ECMWF.
|
||||
#
|
||||
# This software is licensed under the terms of the Apache Licence Version 2.0
|
||||
|
|
Some files were not shown because too many files have changed in this diff Show More
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Reference in New Issue