def load(h): h.add(_.Unsigned('forecastProbabilityNumber', 1)) h.add(_.Unsigned('totalNumberOfForecastProbabilities', 1)) h.add( _.Codetable('probabilityType', 1, "4.9.table", _.Get('masterDir'), _.Get('localDir'))) h.add(_.Codetable_title('probabilityTypeName', _.Get('probabilityType'))) h.add(_.Signed('scaleFactorOfLowerLimit', 1)) h.add(_.Signed('scaledValueOfLowerLimit', 4)) h.add( _.From_scale_factor_scaled_value('lowerLimit', _.Get('scaleFactorOfLowerLimit'), _.Get('scaledValueOfLowerLimit'))) h.add(_.Signed('scaleFactorOfUpperLimit', 1)) h.add(_.Signed('scaledValueOfUpperLimit', 4)) h.add( _.From_scale_factor_scaled_value('upperLimit', _.Get('scaleFactorOfUpperLimit'), _.Get('scaledValueOfUpperLimit')))
def load(h): h.add( _.Codetable('shapeOfTheEarth', 1, "3.2.table", _.Get('masterDir'), _.Get('localDir'))) h.add(_.Unsigned('scaleFactorOfRadiusOfSphericalEarth', 1)) h.add(_.Unsigned('scaledValueOfRadiusOfSphericalEarth', 4)) h.add(_.Unsigned('scaleFactorOfEarthMajorAxis', 1)) h.alias('scaleFactorOfMajorAxisOfOblateSpheroidEarth', 'scaleFactorOfEarthMajorAxis') h.add(_.Unsigned('scaledValueOfEarthMajorAxis', 4)) h.alias('scaledValueOfMajorAxisOfOblateSpheroidEarth', 'scaledValueOfEarthMajorAxis') h.add(_.Unsigned('scaleFactorOfEarthMinorAxis', 1)) h.alias('scaleFactorOfMinorAxisOfOblateSpheroidEarth', 'scaleFactorOfEarthMinorAxis') h.add(_.Unsigned('scaledValueOfEarthMinorAxis', 4)) h.alias('scaledValueOfMinorAxisOfOblateSpheroidEarth', 'scaledValueOfEarthMinorAxis') h.alias('earthIsOblate', 'one') if (h.get_l('shapeOfTheEarth') == 0): h.add(_.Transient('radius', 6367470)) h.alias('radiusOfTheEarth', 'radius') h.alias('radiusInMetres', 'radius') h.alias('earthIsOblate', 'zero') if (h.get_l('shapeOfTheEarth') == 1): h.add( _.From_scale_factor_scaled_value( 'radius', _.Get('scaleFactorOfRadiusOfSphericalEarth'), _.Get('scaledValueOfRadiusOfSphericalEarth'))) h.alias('radiusOfTheEarth', 'radius') h.alias('radiusInMetres', 'radius') h.alias('earthIsOblate', 'zero') if (h.get_l('shapeOfTheEarth') == 6): h.add(_.Transient('radius', 6371229)) h.alias('radiusOfTheEarth', 'radius') h.alias('radiusInMetres', 'radius') h.alias('earthIsOblate', 'zero') if (h.get_l('shapeOfTheEarth') == 8): h.add(_.Transient('radius', 6371200)) h.alias('radiusOfTheEarth', 'radius') h.alias('radiusInMetres', 'radius') h.alias('earthIsOblate', 'zero') if (h.get_l('shapeOfTheEarth') == 2): h.add(_.Transient('earthMajorAxis', 6.37816e+06)) h.add(_.Transient('earthMinorAxis', 6.35678e+06)) h.alias('earthMajorAxisInMetres', 'earthMajorAxis') h.alias('earthMinorAxisInMetres', 'earthMinorAxis') if (h.get_l('shapeOfTheEarth') == 3): h.add( _.From_scale_factor_scaled_value( 'earthMajorAxis', _.Get('scaleFactorOfEarthMajorAxis'), _.Get('scaledValueOfEarthMajorAxis'))) h.add( _.From_scale_factor_scaled_value( 'earthMinorAxis', _.Get('scaleFactorOfEarthMinorAxis'), _.Get('scaledValueOfEarthMinorAxis'))) h.add( _.Divdouble('earthMajorAxisInMetres', _.Get('earthMajorAxis'), 0.001)) h.add( _.Divdouble('earthMinorAxisInMetres', _.Get('earthMinorAxis'), 0.001)) if (h.get_l('shapeOfTheEarth') == 7): h.add( _.From_scale_factor_scaled_value( 'earthMajorAxis', _.Get('scaleFactorOfEarthMajorAxis'), _.Get('scaledValueOfEarthMajorAxis'))) h.add( _.From_scale_factor_scaled_value( 'earthMinorAxis', _.Get('scaleFactorOfEarthMinorAxis'), _.Get('scaledValueOfEarthMinorAxis'))) h.alias('earthMajorAxisInMetres', 'earthMajorAxis') h.alias('earthMinorAxisInMetres', 'earthMinorAxis') if ((h.get_l('shapeOfTheEarth') == 4) or (h.get_l('shapeOfTheEarth') == 5)): h.add(_.Transient('earthMajorAxis', 6.37814e+06)) h.add(_.Transient('earthMinorAxis', 6.35675e+06)) h.alias('earthMajorAxisInMetres', 'earthMajorAxis') h.alias('earthMinorAxisInMetres', 'earthMinorAxis') if (h.get_l('shapeOfTheEarth') == 9): h.add(_.Transient('earthMajorAxis', 6.37756e+06)) h.add(_.Transient('earthMinorAxis', 6.35626e+06)) h.alias('earthMajorAxisInMetres', 'earthMajorAxis') h.alias('earthMinorAxisInMetres', 'earthMinorAxis') h.add(_.Unsigned('Ni', 4)) h.alias('numberOfPointsAlongAParallel', 'Ni') h.alias('Nx', 'Ni') h.alias('geography.Ni', 'Ni') h.add(_.Unsigned('Nj', 4)) h.alias('numberOfPointsAlongAMeridian', 'Nj') h.alias('Ny', 'Nj') h.alias('geography.Nj', 'Nj') h.add(_.Signed('latitudeOfReferencePoint', 4)) h.alias('LaR', 'latitudeOfReferencePoint') h.add( _.Scale('latitudeOfReferencePointInDegrees', _.Get('latitudeOfReferencePoint'), _.Get('oneConstant'), _.Get('grib2divider'), _.Get('truncateDegrees'))) h.alias('geography.latitudeOfReferencePointInDegrees', 'latitudeOfReferencePointInDegrees') h.add(_.Signed('longitudeOfReferencePoint', 4)) h.alias('LoR', 'longitudeOfReferencePoint') h.add( _.Scale('longitudeOfReferencePointInDegrees', _.Get('longitudeOfReferencePoint'), _.Get('oneConstant'), _.Get('grib2divider'), _.Get('truncateDegrees'))) h.alias('geography.longitudeOfReferencePointInDegrees', 'longitudeOfReferencePointInDegrees') h.add( _.Codeflag('resolutionAndComponentFlags', 1, "grib2/tables/[tablesVersion]/3.3.table")) h.add( _.Bit('resolutionAndComponentFlags1', _.Get('resolutionAndComponentFlags'), 7)) h.add( _.Bit('resolutionAndComponentFlags2', _.Get('resolutionAndComponentFlags'), 6)) h.add( _.Bit('iDirectionIncrementGiven', _.Get('resolutionAndComponentFlags'), 5)) h.add( _.Bit('jDirectionIncrementGiven', _.Get('resolutionAndComponentFlags'), 4)) h.add(_.Bit('uvRelativeToGrid', _.Get('resolutionAndComponentFlags'), 3)) h.add( _.Bit('resolutionAndComponentFlags6', _.Get('resolutionAndComponentFlags'), 7)) h.add( _.Bit('resolutionAndComponentFlags7', _.Get('resolutionAndComponentFlags'), 6)) h.add( _.Bit('resolutionAndComponentFlags8', _.Get('resolutionAndComponentFlags'), 6)) def ijDirectionIncrementGiven_inline_concept(h): def wrapped(h): iDirectionIncrementGiven = h.get_l('iDirectionIncrementGiven') jDirectionIncrementGiven = h.get_l('jDirectionIncrementGiven') if iDirectionIncrementGiven == 1 and jDirectionIncrementGiven == 1: return 1 if iDirectionIncrementGiven == 1 and jDirectionIncrementGiven == 0: return 0 if iDirectionIncrementGiven == 0 and jDirectionIncrementGiven == 1: return 0 if iDirectionIncrementGiven == 0 and jDirectionIncrementGiven == 0: return 0 return wrapped h.add( _.Concept('ijDirectionIncrementGiven', None, concepts=ijDirectionIncrementGiven_inline_concept(h))) h.alias('DiGiven', 'iDirectionIncrementGiven') h.alias('DjGiven', 'jDirectionIncrementGiven') h.add(_.Ieeefloat('scaleFactorAtReferencePoint', 4)) h.alias('m', 'scaleFactorAtReferencePoint') h.alias('geography.m', 'm') h.add(_.Signed('XR', 4)) h.alias('falseEasting', 'XR') h.add(_.Scale('XRInMetres', _.Get('XR'), _.Get('one'), _.Get('hundred'))) h.alias('geography.XRInMetres', 'XRInMetres') h.add(_.Signed('YR', 4)) h.alias('falseNorthing', 'YR') h.add(_.Scale('YRInMetres', _.Get('YR'), _.Get('one'), _.Get('hundred'))) h.alias('geography.YRInMetres', 'YRInMetres') h.add( _.Codeflag('scanningMode', 1, "grib2/tables/[tablesVersion]/3.4.table")) h.add(_.Bit('iScansNegatively', _.Get('scanningMode'), 7)) h.add(_.Bit('jScansPositively', _.Get('scanningMode'), 6)) h.add(_.Bit('jPointsAreConsecutive', _.Get('scanningMode'), 5)) h.add(_.Bit('alternativeRowScanning', _.Get('scanningMode'), 4)) if h.get_l('jPointsAreConsecutive'): h.alias('numberOfRows', 'Ni') h.alias('numberOfColumns', 'Nj') else: h.alias('numberOfRows', 'Nj') h.alias('numberOfColumns', 'Ni') h.alias('geography.iScansNegatively', 'iScansNegatively') h.alias('geography.jScansPositively', 'jScansPositively') h.alias('geography.jPointsAreConsecutive', 'jPointsAreConsecutive') h.add(_.Transient('iScansPositively', _.Not(_.Get('iScansNegatively')))) h.add(_.Bit('scanningMode5', _.Get('scanningMode'), 3)) h.add(_.Bit('scanningMode6', _.Get('scanningMode'), 2)) h.add(_.Bit('scanningMode7', _.Get('scanningMode'), 1)) h.add(_.Bit('scanningMode8', _.Get('scanningMode'), 0)) h.add( _.Change_scanning_direction('swapScanningX', _.Get('values'), _.Get('Ni'), _.Get('Nj'), _.Get('iScansNegatively'), _.Get('jScansPositively'), _.Get('xFirst'), _.Get('xLast'), _.Get('x'))) h.alias('swapScanningLon', 'swapScanningX') h.add( _.Change_scanning_direction('swapScanningY', _.Get('values'), _.Get('Ni'), _.Get('Nj'), _.Get('iScansNegatively'), _.Get('jScansPositively'), _.Get('yFirst'), _.Get('yLast'), _.Get('y'))) h.alias('swapScanningLat', 'swapScanningY') h.add(_.Unsigned('Di', 4)) h.alias('iDirectionIncrementGridLength', 'Di') h.add( _.Scale('DiInMetres', _.Get('Di'), _.Get('oneConstant'), _.Get('hundred'), _.Get('truncateDegrees'))) h.alias('geography.DiInMetres', 'DiInMetres') h.add(_.Unsigned('Dj', 4)) h.alias('jDirectionIncrementGridLength', 'Dj') h.add( _.Scale('DjInMetres', _.Get('Dj'), _.Get('oneConstant'), _.Get('hundred'), _.Get('truncateDegrees'))) h.alias('geography.DjInMetres', 'DjInMetres') h.add(_.Signed('X1', 4)) h.add( _.Scale('X1InGridLengths', _.Get('X1'), _.Get('one'), _.Get('hundred'))) h.alias('geography.X1InGridLengths', 'X1InGridLengths') h.add(_.Signed('Y1', 4)) h.add( _.Scale('Y1InGridLengths', _.Get('Y1'), _.Get('one'), _.Get('hundred'))) h.alias('geography.Y1InGridLengths', 'Y1InGridLengths') h.add(_.Signed('X2', 4)) h.add( _.Scale('X2InGridLengths', _.Get('X2'), _.Get('one'), _.Get('hundred'))) h.alias('geography.X2InGridLengths', 'X2InGridLengths') h.add(_.Signed('Y2', 4)) h.add( _.Scale('Y2InGridLengths', _.Get('Y2'), _.Get('one'), _.Get('hundred'))) h.alias('geography.Y2InGridLengths', 'Y2InGridLengths')
def load(h): h.add(_.Codetable('shapeOfTheEarth', 1, "3.2.table", _.Get('masterDir'), _.Get('localDir'))) h.add(_.Unsigned('scaleFactorOfRadiusOfSphericalEarth', 1)) h.add(_.Unsigned('scaledValueOfRadiusOfSphericalEarth', 4)) h.add(_.Unsigned('scaleFactorOfEarthMajorAxis', 1)) h.alias('scaleFactorOfMajorAxisOfOblateSpheroidEarth', 'scaleFactorOfEarthMajorAxis') h.add(_.Unsigned('scaledValueOfEarthMajorAxis', 4)) h.alias('scaledValueOfMajorAxisOfOblateSpheroidEarth', 'scaledValueOfEarthMajorAxis') h.add(_.Unsigned('scaleFactorOfEarthMinorAxis', 1)) h.alias('scaleFactorOfMinorAxisOfOblateSpheroidEarth', 'scaleFactorOfEarthMinorAxis') h.add(_.Unsigned('scaledValueOfEarthMinorAxis', 4)) h.alias('scaledValueOfMinorAxisOfOblateSpheroidEarth', 'scaledValueOfEarthMinorAxis') h.alias('earthIsOblate', 'one') if (h.get_l('shapeOfTheEarth') == 0): h.add(_.Transient('radius', 6367470)) h.alias('radiusOfTheEarth', 'radius') h.alias('radiusInMetres', 'radius') h.alias('earthIsOblate', 'zero') if (h.get_l('shapeOfTheEarth') == 1): h.add(_.From_scale_factor_scaled_value('radius', _.Get('scaleFactorOfRadiusOfSphericalEarth'), _.Get('scaledValueOfRadiusOfSphericalEarth'))) h.alias('radiusOfTheEarth', 'radius') h.alias('radiusInMetres', 'radius') h.alias('earthIsOblate', 'zero') if (h.get_l('shapeOfTheEarth') == 6): h.add(_.Transient('radius', 6371229)) h.alias('radiusOfTheEarth', 'radius') h.alias('radiusInMetres', 'radius') h.alias('earthIsOblate', 'zero') if (h.get_l('shapeOfTheEarth') == 8): h.add(_.Transient('radius', 6371200)) h.alias('radiusOfTheEarth', 'radius') h.alias('radiusInMetres', 'radius') h.alias('earthIsOblate', 'zero') if (h.get_l('shapeOfTheEarth') == 2): h.add(_.Transient('earthMajorAxis', 6.37816e+06)) h.add(_.Transient('earthMinorAxis', 6.35678e+06)) h.alias('earthMajorAxisInMetres', 'earthMajorAxis') h.alias('earthMinorAxisInMetres', 'earthMinorAxis') if (h.get_l('shapeOfTheEarth') == 3): h.add(_.From_scale_factor_scaled_value('earthMajorAxis', _.Get('scaleFactorOfEarthMajorAxis'), _.Get('scaledValueOfEarthMajorAxis'))) h.add(_.From_scale_factor_scaled_value('earthMinorAxis', _.Get('scaleFactorOfEarthMinorAxis'), _.Get('scaledValueOfEarthMinorAxis'))) h.add(_.Divdouble('earthMajorAxisInMetres', _.Get('earthMajorAxis'), 0.001)) h.add(_.Divdouble('earthMinorAxisInMetres', _.Get('earthMinorAxis'), 0.001)) if (h.get_l('shapeOfTheEarth') == 7): h.add(_.From_scale_factor_scaled_value('earthMajorAxis', _.Get('scaleFactorOfEarthMajorAxis'), _.Get('scaledValueOfEarthMajorAxis'))) h.add(_.From_scale_factor_scaled_value('earthMinorAxis', _.Get('scaleFactorOfEarthMinorAxis'), _.Get('scaledValueOfEarthMinorAxis'))) h.alias('earthMajorAxisInMetres', 'earthMajorAxis') h.alias('earthMinorAxisInMetres', 'earthMinorAxis') if ((h.get_l('shapeOfTheEarth') == 4) or (h.get_l('shapeOfTheEarth') == 5)): h.add(_.Transient('earthMajorAxis', 6.37814e+06)) h.add(_.Transient('earthMinorAxis', 6.35675e+06)) h.alias('earthMajorAxisInMetres', 'earthMajorAxis') h.alias('earthMinorAxisInMetres', 'earthMinorAxis') if (h.get_l('shapeOfTheEarth') == 9): h.add(_.Transient('earthMajorAxis', 6.37756e+06)) h.add(_.Transient('earthMinorAxis', 6.35626e+06)) h.alias('earthMajorAxisInMetres', 'earthMajorAxis') h.alias('earthMinorAxisInMetres', 'earthMinorAxis') h.add(_.Unsigned('Ni', 4)) h.alias('numberOfPointsAlongAParallel', 'Ni') h.alias('Nx', 'Ni') h.add(_.Unsigned('Nj', 4)) h.alias('numberOfPointsAlongAMeridian', 'Nj') h.alias('Ny', 'Nj') h.alias('geography.Ni', 'Ni') h.alias('geography.Nj', 'Nj') h.add(_.Unsigned('basicAngleOfTheInitialProductionDomain', 4)) h.add(_.Transient('mBasicAngle', (_.Get('basicAngleOfTheInitialProductionDomain') * _.Get('oneMillionConstant')))) h.add(_.Transient('angleMultiplier', 1)) h.add(_.Transient('mAngleMultiplier', 1000000)) pass # when block h.add(_.Unsigned('subdivisionsOfBasicAngle', 4)) h.add(_.Transient('angleDivisor', 1000000)) pass # when block h.add(_.Signed('latitudeOfFirstGridPoint', 4)) h.alias('La1', 'latitudeOfFirstGridPoint') h.add(_.Signed('longitudeOfFirstGridPoint', 4)) h.alias('Lo1', 'longitudeOfFirstGridPoint') h.add(_.Codeflag('resolutionAndComponentFlags', 1, "grib2/tables/[tablesVersion]/3.3.table")) h.add(_.Bit('resolutionAndComponentFlags1', _.Get('resolutionAndComponentFlags'), 7)) h.add(_.Bit('resolutionAndComponentFlags2', _.Get('resolutionAndComponentFlags'), 6)) h.add(_.Bit('iDirectionIncrementGiven', _.Get('resolutionAndComponentFlags'), 5)) h.add(_.Bit('jDirectionIncrementGiven', _.Get('resolutionAndComponentFlags'), 4)) h.add(_.Bit('uvRelativeToGrid', _.Get('resolutionAndComponentFlags'), 3)) h.add(_.Bit('resolutionAndComponentFlags6', _.Get('resolutionAndComponentFlags'), 7)) h.add(_.Bit('resolutionAndComponentFlags7', _.Get('resolutionAndComponentFlags'), 6)) h.add(_.Bit('resolutionAndComponentFlags8', _.Get('resolutionAndComponentFlags'), 6)) def ijDirectionIncrementGiven_inline_concept(h): def wrapped(h): iDirectionIncrementGiven = h.get_l('iDirectionIncrementGiven') jDirectionIncrementGiven = h.get_l('jDirectionIncrementGiven') if iDirectionIncrementGiven == 1 and jDirectionIncrementGiven == 1: return 1 if iDirectionIncrementGiven == 1 and jDirectionIncrementGiven == 0: return 0 if iDirectionIncrementGiven == 0 and jDirectionIncrementGiven == 1: return 0 if iDirectionIncrementGiven == 0 and jDirectionIncrementGiven == 0: return 0 return wrapped h.add(_.Concept('ijDirectionIncrementGiven', None, concepts=ijDirectionIncrementGiven_inline_concept(h))) h.alias('DiGiven', 'iDirectionIncrementGiven') h.alias('DjGiven', 'jDirectionIncrementGiven') h.add(_.Signed('latitudeOfLastGridPoint', 4)) h.alias('La2', 'latitudeOfLastGridPoint') h.add(_.Signed('longitudeOfLastGridPoint', 4)) h.alias('Lo2', 'longitudeOfLastGridPoint') h.add(_.Unsigned('iDirectionIncrement', 4)) h.alias('Di', 'iDirectionIncrement') h.add(_.Unsigned('N', 4)) h.alias('numberOfParallelsBetweenAPoleAndTheEquator', 'N') h.alias('geography.N', 'N') h.add(_.Codeflag('scanningMode', 1, "grib2/tables/[tablesVersion]/3.4.table")) h.add(_.Bit('iScansNegatively', _.Get('scanningMode'), 7)) h.add(_.Bit('jScansPositively', _.Get('scanningMode'), 6)) h.add(_.Bit('jPointsAreConsecutive', _.Get('scanningMode'), 5)) h.add(_.Bit('alternativeRowScanning', _.Get('scanningMode'), 4)) if h.get_l('jPointsAreConsecutive'): h.alias('numberOfRows', 'Ni') h.alias('numberOfColumns', 'Nj') else: h.alias('numberOfRows', 'Nj') h.alias('numberOfColumns', 'Ni') h.alias('geography.iScansNegatively', 'iScansNegatively') h.alias('geography.jScansPositively', 'jScansPositively') h.alias('geography.jPointsAreConsecutive', 'jPointsAreConsecutive') h.add(_.Transient('iScansPositively', _.Not(_.Get('iScansNegatively')))) h.add(_.Bit('scanningMode5', _.Get('scanningMode'), 3)) h.add(_.Bit('scanningMode6', _.Get('scanningMode'), 2)) h.add(_.Bit('scanningMode7', _.Get('scanningMode'), 1)) h.add(_.Bit('scanningMode8', _.Get('scanningMode'), 0)) h.add(_.Change_scanning_direction('swapScanningX', _.Get('values'), _.Get('Ni'), _.Get('Nj'), _.Get('iScansNegatively'), _.Get('jScansPositively'), _.Get('xFirst'), _.Get('xLast'), _.Get('x'))) h.alias('swapScanningLon', 'swapScanningX') h.add(_.Change_scanning_direction('swapScanningY', _.Get('values'), _.Get('Ni'), _.Get('Nj'), _.Get('iScansNegatively'), _.Get('jScansPositively'), _.Get('yFirst'), _.Get('yLast'), _.Get('y'))) h.alias('swapScanningLat', 'swapScanningY') h.add(_.G2grid('g2grid', _.Get('latitudeOfFirstGridPoint'), _.Get('longitudeOfFirstGridPoint'), _.Get('latitudeOfLastGridPoint'), _.Get('longitudeOfLastGridPoint'), _.Get('iDirectionIncrement'), None, _.Get('basicAngleOfTheInitialProductionDomain'), _.Get('subdivisionsOfBasicAngle'))) h.add(_.G2latlon('latitudeOfFirstGridPointInDegrees', _.Get('g2grid'), 0)) h.alias('geography.latitudeOfFirstGridPointInDegrees', 'latitudeOfFirstGridPointInDegrees') h.add(_.G2latlon('longitudeOfFirstGridPointInDegrees', _.Get('g2grid'), 1)) h.alias('geography.longitudeOfFirstGridPointInDegrees', 'longitudeOfFirstGridPointInDegrees') h.add(_.G2latlon('latitudeOfLastGridPointInDegrees', _.Get('g2grid'), 2)) h.alias('geography.latitudeOfLastGridPointInDegrees', 'latitudeOfLastGridPointInDegrees') h.add(_.G2latlon('longitudeOfLastGridPointInDegrees', _.Get('g2grid'), 3)) h.alias('geography.longitudeOfLastGridPointInDegrees', 'longitudeOfLastGridPointInDegrees') h.add(_.G2latlon('iDirectionIncrementInDegrees', _.Get('g2grid'), 4, _.Get('iDirectionIncrementGiven'))) h.alias('geography.iDirectionIncrementInDegrees', 'iDirectionIncrementInDegrees') h.add(_.Global_gaussian('global', _.Get('N'), _.Get('Ni'), _.Get('iDirectionIncrement'), _.Get('latitudeOfFirstGridPoint'), _.Get('longitudeOfFirstGridPoint'), _.Get('latitudeOfLastGridPoint'), _.Get('longitudeOfLastGridPoint'), _.Get('PLPresent'), _.Get('pl'), _.Get('basicAngleOfTheInitialProductionDomain'), _.Get('subdivisionsOfBasicAngle'))) h.alias('xFirst', 'longitudeOfFirstGridPointInDegrees') h.alias('yFirst', 'latitudeOfFirstGridPointInDegrees') h.alias('xLast', 'longitudeOfLastGridPointInDegrees') h.alias('yLast', 'latitudeOfLastGridPointInDegrees') h.alias('latitudeFirstInDegrees', 'latitudeOfFirstGridPointInDegrees') h.alias('longitudeFirstInDegrees', 'longitudeOfFirstGridPointInDegrees') h.alias('latitudeLastInDegrees', 'latitudeOfLastGridPointInDegrees') h.alias('longitudeLastInDegrees', 'longitudeOfLastGridPointInDegrees') h.alias('DiInDegrees', 'iDirectionIncrementInDegrees') if (h._missing('Ni') and (h.get_l('PLPresent') == 1)): h.add(_.Iterator('ITERATOR', _.Get('gaussian_reduced'), _.Get('numberOfPoints'), _.Get('missingValue'), _.Get('values'), _.Get('latitudeOfFirstGridPointInDegrees'), _.Get('longitudeOfFirstGridPointInDegrees'), _.Get('latitudeOfLastGridPointInDegrees'), _.Get('longitudeOfLastGridPointInDegrees'), _.Get('N'), _.Get('pl'), _.Get('Nj'))) h.add(_.Nearest('NEAREST', _.Get('reduced'), _.Get('values'), _.Get('radius'), _.Get('Nj'), _.Get('pl'))) else: h.add(_.Iterator('ITERATOR', _.Get('gaussian'), _.Get('numberOfPoints'), _.Get('missingValue'), _.Get('values'), _.Get('longitudeFirstInDegrees'), _.Get('DiInDegrees'), _.Get('Ni'), _.Get('Nj'), _.Get('iScansNegatively'), _.Get('latitudeFirstInDegrees'), _.Get('latitudeLastInDegrees'), _.Get('N'), _.Get('jScansPositively'))) h.add(_.Nearest('NEAREST', _.Get('regular'), _.Get('values'), _.Get('radius'), _.Get('Ni'), _.Get('Nj'))) h.add(_.Latlonvalues('latLonValues', _.Get('values'))) h.alias('latitudeLongitudeValues', 'latLonValues') h.add(_.Latitudes('latitudes', _.Get('values'), 0)) h.add(_.Longitudes('longitudes', _.Get('values'), 0)) h.add(_.Latitudes('distinctLatitudes', _.Get('values'), 1)) h.add(_.Longitudes('distinctLongitudes', _.Get('values'), 1)) h.add(_.Octahedral_gaussian('isOctahedral', _.Get('N'), _.Get('Ni'), _.Get('PLPresent'), _.Get('pl'))) h.add(_.Gaussian_grid_name('gaussianGridName', _.Get('N'), _.Get('Ni'), _.Get('isOctahedral'))) h.alias('gridName', 'gaussianGridName') h.add(_.Number_of_points_gaussian('numberOfDataPointsExpected', _.Get('Ni'), _.Get('Nj'), _.Get('PLPresent'), _.Get('pl'), _.Get('N'), _.Get('latitudeOfFirstGridPointInDegrees'), _.Get('longitudeOfFirstGridPointInDegrees'), _.Get('latitudeOfLastGridPointInDegrees'), _.Get('longitudeOfLastGridPointInDegrees'), _.Get('zero'))) h.add(_.Evaluate('legacyGaussSubarea', (_.Get('numberOfDataPoints') != _.Get('numberOfDataPointsExpected')))) h.add(_.Signed('latitudeOfSouthernPole', 4)) h.alias('latitudeOfTheSouthernPoleOfProjection', 'latitudeOfSouthernPole') h.add(_.Unsigned('longitudeOfSouthernPole', 4)) h.alias('longitudeOfTheSouthernPoleOfProjection', 'longitudeOfSouthernPole') h.add(_.Scale('latitudeOfSouthernPoleInDegrees', _.Get('latitudeOfSouthernPole'), _.Get('one'), _.Get('grib2divider'), _.Get('truncateDegrees'))) h.alias('geography.latitudeOfSouthernPoleInDegrees', 'latitudeOfSouthernPoleInDegrees') h.add(_.G2lon('longitudeOfSouthernPoleInDegrees', _.Get('longitudeOfSouthernPole'))) h.alias('geography.longitudeOfSouthernPoleInDegrees', 'longitudeOfSouthernPoleInDegrees') h.add(_.Ieeefloat('angleOfRotation', 4)) h.alias('geography.angleOfRotationInDegrees', 'angleOfRotation') h.alias('angleOfRotationOfProjection', 'angleOfRotation') h.alias('isRotatedGrid', 'one')
def load(h): h.add( _.Codetable('shapeOfTheEarth', 1, "3.2.table", _.Get('masterDir'), _.Get('localDir'))) h.add(_.Unsigned('scaleFactorOfRadiusOfSphericalEarth', 1)) h.add(_.Unsigned('scaledValueOfRadiusOfSphericalEarth', 4)) h.add(_.Unsigned('scaleFactorOfEarthMajorAxis', 1)) h.alias('scaleFactorOfMajorAxisOfOblateSpheroidEarth', 'scaleFactorOfEarthMajorAxis') h.add(_.Unsigned('scaledValueOfEarthMajorAxis', 4)) h.alias('scaledValueOfMajorAxisOfOblateSpheroidEarth', 'scaledValueOfEarthMajorAxis') h.add(_.Unsigned('scaleFactorOfEarthMinorAxis', 1)) h.alias('scaleFactorOfMinorAxisOfOblateSpheroidEarth', 'scaleFactorOfEarthMinorAxis') h.add(_.Unsigned('scaledValueOfEarthMinorAxis', 4)) h.alias('scaledValueOfMinorAxisOfOblateSpheroidEarth', 'scaledValueOfEarthMinorAxis') h.alias('earthIsOblate', 'one') if (h.get_l('shapeOfTheEarth') == 0): h.add(_.Transient('radius', 6367470)) h.alias('radiusOfTheEarth', 'radius') h.alias('radiusInMetres', 'radius') h.alias('earthIsOblate', 'zero') if (h.get_l('shapeOfTheEarth') == 1): h.add( _.From_scale_factor_scaled_value( 'radius', _.Get('scaleFactorOfRadiusOfSphericalEarth'), _.Get('scaledValueOfRadiusOfSphericalEarth'))) h.alias('radiusOfTheEarth', 'radius') h.alias('radiusInMetres', 'radius') h.alias('earthIsOblate', 'zero') if (h.get_l('shapeOfTheEarth') == 6): h.add(_.Transient('radius', 6371229)) h.alias('radiusOfTheEarth', 'radius') h.alias('radiusInMetres', 'radius') h.alias('earthIsOblate', 'zero') if (h.get_l('shapeOfTheEarth') == 8): h.add(_.Transient('radius', 6371200)) h.alias('radiusOfTheEarth', 'radius') h.alias('radiusInMetres', 'radius') h.alias('earthIsOblate', 'zero') if (h.get_l('shapeOfTheEarth') == 2): h.add(_.Transient('earthMajorAxis', 6.37816e+06)) h.add(_.Transient('earthMinorAxis', 6.35678e+06)) h.alias('earthMajorAxisInMetres', 'earthMajorAxis') h.alias('earthMinorAxisInMetres', 'earthMinorAxis') if (h.get_l('shapeOfTheEarth') == 3): h.add( _.From_scale_factor_scaled_value( 'earthMajorAxis', _.Get('scaleFactorOfEarthMajorAxis'), _.Get('scaledValueOfEarthMajorAxis'))) h.add( _.From_scale_factor_scaled_value( 'earthMinorAxis', _.Get('scaleFactorOfEarthMinorAxis'), _.Get('scaledValueOfEarthMinorAxis'))) h.add( _.Divdouble('earthMajorAxisInMetres', _.Get('earthMajorAxis'), 0.001)) h.add( _.Divdouble('earthMinorAxisInMetres', _.Get('earthMinorAxis'), 0.001)) if (h.get_l('shapeOfTheEarth') == 7): h.add( _.From_scale_factor_scaled_value( 'earthMajorAxis', _.Get('scaleFactorOfEarthMajorAxis'), _.Get('scaledValueOfEarthMajorAxis'))) h.add( _.From_scale_factor_scaled_value( 'earthMinorAxis', _.Get('scaleFactorOfEarthMinorAxis'), _.Get('scaledValueOfEarthMinorAxis'))) h.alias('earthMajorAxisInMetres', 'earthMajorAxis') h.alias('earthMinorAxisInMetres', 'earthMinorAxis') if ((h.get_l('shapeOfTheEarth') == 4) or (h.get_l('shapeOfTheEarth') == 5)): h.add(_.Transient('earthMajorAxis', 6.37814e+06)) h.add(_.Transient('earthMinorAxis', 6.35675e+06)) h.alias('earthMajorAxisInMetres', 'earthMajorAxis') h.alias('earthMinorAxisInMetres', 'earthMinorAxis') if (h.get_l('shapeOfTheEarth') == 9): h.add(_.Transient('earthMajorAxis', 6.37756e+06)) h.add(_.Transient('earthMinorAxis', 6.35626e+06)) h.alias('earthMajorAxisInMetres', 'earthMajorAxis') h.alias('earthMinorAxisInMetres', 'earthMinorAxis') h.add(_.Unsigned('Nx', 4)) h.alias('numberOfPointsAlongTheXAxis', 'Nx') h.alias('geography.Nx', 'Nx') h.add(_.Unsigned('Ny', 4)) h.alias('numberOfPointsAlongTheYAxis', 'Ny') h.alias('geography.Ny', 'Ny') h.add(_.Signed('latitudeOfFirstGridPoint', 4)) h.alias('La1', 'latitudeOfFirstGridPoint') h.add(_.Unsigned('longitudeOfFirstGridPoint', 4)) h.alias('Lo1', 'longitudeOfFirstGridPoint') h.add( _.Codeflag('resolutionAndComponentFlags', 1, "grib2/tables/[tablesVersion]/3.3.table")) h.add( _.Bit('resolutionAndComponentFlags1', _.Get('resolutionAndComponentFlags'), 7)) h.add( _.Bit('resolutionAndComponentFlags2', _.Get('resolutionAndComponentFlags'), 6)) h.add( _.Bit('iDirectionIncrementGiven', _.Get('resolutionAndComponentFlags'), 5)) h.add( _.Bit('jDirectionIncrementGiven', _.Get('resolutionAndComponentFlags'), 4)) h.add(_.Bit('uvRelativeToGrid', _.Get('resolutionAndComponentFlags'), 3)) h.add( _.Bit('resolutionAndComponentFlags6', _.Get('resolutionAndComponentFlags'), 7)) h.add( _.Bit('resolutionAndComponentFlags7', _.Get('resolutionAndComponentFlags'), 6)) h.add( _.Bit('resolutionAndComponentFlags8', _.Get('resolutionAndComponentFlags'), 6)) def ijDirectionIncrementGiven_inline_concept(h): def wrapped(h): iDirectionIncrementGiven = h.get_l('iDirectionIncrementGiven') jDirectionIncrementGiven = h.get_l('jDirectionIncrementGiven') if iDirectionIncrementGiven == 1 and jDirectionIncrementGiven == 1: return 1 if iDirectionIncrementGiven == 1 and jDirectionIncrementGiven == 0: return 0 if iDirectionIncrementGiven == 0 and jDirectionIncrementGiven == 1: return 0 if iDirectionIncrementGiven == 0 and jDirectionIncrementGiven == 0: return 0 return wrapped h.add( _.Concept('ijDirectionIncrementGiven', None, concepts=ijDirectionIncrementGiven_inline_concept(h))) h.alias('DiGiven', 'iDirectionIncrementGiven') h.alias('DjGiven', 'jDirectionIncrementGiven') h.add(_.Signed('LaD', 4)) h.alias('latitudeWhereDxAndDyAreSpecified', 'LaD') h.add(_.Unsigned('LoV', 4)) h.add(_.Unsigned('xDirectionGridLength', 4)) h.alias('Dx', 'xDirectionGridLength') h.add(_.Unsigned('yDirectionGridLength', 4)) h.alias('Dy', 'yDirectionGridLength') h.add( _.Codeflag('projectionCentreFlag', 1, "grib2/tables/[tablesVersion]/3.5.table")) h.add( _.Codeflag('scanningMode', 1, "grib2/tables/[tablesVersion]/3.4.table")) h.add(_.Bit('iScansNegatively', _.Get('scanningMode'), 7)) h.add(_.Bit('jScansPositively', _.Get('scanningMode'), 6)) h.add(_.Bit('jPointsAreConsecutive', _.Get('scanningMode'), 5)) h.add(_.Bit('alternativeRowScanning', _.Get('scanningMode'), 4)) if h.get_l('jPointsAreConsecutive'): h.alias('numberOfRows', 'Ni') h.alias('numberOfColumns', 'Nj') else: h.alias('numberOfRows', 'Nj') h.alias('numberOfColumns', 'Ni') h.alias('geography.iScansNegatively', 'iScansNegatively') h.alias('geography.jScansPositively', 'jScansPositively') h.alias('geography.jPointsAreConsecutive', 'jPointsAreConsecutive') h.add(_.Transient('iScansPositively', _.Not(_.Get('iScansNegatively')))) h.add(_.Bit('scanningMode5', _.Get('scanningMode'), 3)) h.add(_.Bit('scanningMode6', _.Get('scanningMode'), 2)) h.add(_.Bit('scanningMode7', _.Get('scanningMode'), 1)) h.add(_.Bit('scanningMode8', _.Get('scanningMode'), 0)) h.add( _.Change_scanning_direction('swapScanningX', _.Get('values'), _.Get('Ni'), _.Get('Nj'), _.Get('iScansNegatively'), _.Get('jScansPositively'), _.Get('xFirst'), _.Get('xLast'), _.Get('x'))) h.alias('swapScanningLon', 'swapScanningX') h.add( _.Change_scanning_direction('swapScanningY', _.Get('values'), _.Get('Ni'), _.Get('Nj'), _.Get('iScansNegatively'), _.Get('jScansPositively'), _.Get('yFirst'), _.Get('yLast'), _.Get('y'))) h.alias('swapScanningLat', 'swapScanningY') h.add(_.Signed('Latin1', 4)) h.add( _.Scale('Latin1InDegrees', _.Get('Latin1'), _.Get('one'), _.Get('grib2divider'), _.Get('truncateDegrees'))) h.alias('geography.Latin1InDegrees', 'Latin1InDegrees') h.add(_.Unsigned('Latin2', 4)) h.add( _.Scale('Latin2InDegrees', _.Get('Latin2'), _.Get('one'), _.Get('grib2divider'), _.Get('truncateDegrees'))) h.alias('geography.Latin2InDegrees', 'Latin2InDegrees') h.add(_.Signed('latitudeOfTheSouthernPoleOfProjection', 4)) h.alias('latitudeOfSouthernPole', 'latitudeOfTheSouthernPoleOfProjection') h.add( _.Scale('latitudeOfSouthernPoleInDegrees', _.Get('latitudeOfTheSouthernPoleOfProjection'), _.Get('one'), _.Get('grib2divider'), _.Get('truncateDegrees'))) h.alias('geography.latitudeOfSouthernPoleInDegrees', 'latitudeOfSouthernPoleInDegrees') h.add(_.Unsigned('longitudeOfTheSouthernPoleOfProjection', 4)) h.alias('longitudeOfSouthernPole', 'longitudeOfTheSouthernPoleOfProjection') h.add( _.Scale('longitudeOfSouthernPoleInDegrees', _.Get('longitudeOfTheSouthernPoleOfProjection'), _.Get('oneConstant'), _.Get('grib2divider'), _.Get('truncateDegrees'))) h.alias('geography.longitudeOfSouthernPoleInDegrees', 'longitudeOfSouthernPoleInDegrees')
def load(h): h.add(_.Transient('biFourierMakeTemplate', 0)) h.add(_.Label('BiFourier coefficients')) h.add(_.Constant('biFourierCoefficients', 1)) h.add( _.Codetable('spectralType', 1, "3.6.table", _.Get('masterDir'), _.Get('localDir'))) h.alias('spectralDataRepresentationType', 'spectralType') h.add(_.Unsigned('biFourierResolutionParameterN', 4)) h.add(_.Unsigned('biFourierResolutionParameterM', 4)) h.add( _.Codetable('biFourierTruncationType', 1, "3.25.table", _.Get('masterDir'), _.Get('localDir'))) h.add(_.Unsigned('Lx', 8)) h.alias('geography.LxInMetres', 'Lx') h.add(_.Unsigned('Lux', 8)) h.alias('geography.LuxInMetres', 'Lux') h.add(_.Unsigned('Lcx', 8)) h.alias('geography.LcxInMetres', 'Lcx') h.add(_.Unsigned('Ly', 8)) h.alias('geography.LyInMetres', 'Ly') h.add(_.Unsigned('Luy', 8)) h.alias('geography.LuyInMetres', 'Luy') h.add(_.Unsigned('Lcy', 8)) h.alias('geography.LcyInMetres', 'Lcy') h.add( _.Codetable('shapeOfTheEarth', 1, "3.2.table", _.Get('masterDir'), _.Get('localDir'))) h.add(_.Unsigned('scaleFactorOfRadiusOfSphericalEarth', 1)) h.add(_.Unsigned('scaledValueOfRadiusOfSphericalEarth', 4)) h.add(_.Unsigned('scaleFactorOfEarthMajorAxis', 1)) h.alias('scaleFactorOfMajorAxisOfOblateSpheroidEarth', 'scaleFactorOfEarthMajorAxis') h.add(_.Unsigned('scaledValueOfEarthMajorAxis', 4)) h.alias('scaledValueOfMajorAxisOfOblateSpheroidEarth', 'scaledValueOfEarthMajorAxis') h.add(_.Unsigned('scaleFactorOfEarthMinorAxis', 1)) h.alias('scaleFactorOfMinorAxisOfOblateSpheroidEarth', 'scaleFactorOfEarthMinorAxis') h.add(_.Unsigned('scaledValueOfEarthMinorAxis', 4)) h.alias('scaledValueOfMinorAxisOfOblateSpheroidEarth', 'scaledValueOfEarthMinorAxis') h.alias('earthIsOblate', 'one') if (h.get_l('shapeOfTheEarth') == 0): h.add(_.Transient('radius', 6367470)) h.alias('radiusOfTheEarth', 'radius') h.alias('radiusInMetres', 'radius') h.alias('earthIsOblate', 'zero') if (h.get_l('shapeOfTheEarth') == 1): h.add( _.From_scale_factor_scaled_value( 'radius', _.Get('scaleFactorOfRadiusOfSphericalEarth'), _.Get('scaledValueOfRadiusOfSphericalEarth'))) h.alias('radiusOfTheEarth', 'radius') h.alias('radiusInMetres', 'radius') h.alias('earthIsOblate', 'zero') if (h.get_l('shapeOfTheEarth') == 6): h.add(_.Transient('radius', 6371229)) h.alias('radiusOfTheEarth', 'radius') h.alias('radiusInMetres', 'radius') h.alias('earthIsOblate', 'zero') if (h.get_l('shapeOfTheEarth') == 8): h.add(_.Transient('radius', 6371200)) h.alias('radiusOfTheEarth', 'radius') h.alias('radiusInMetres', 'radius') h.alias('earthIsOblate', 'zero') if (h.get_l('shapeOfTheEarth') == 2): h.add(_.Transient('earthMajorAxis', 6.37816e+06)) h.add(_.Transient('earthMinorAxis', 6.35678e+06)) h.alias('earthMajorAxisInMetres', 'earthMajorAxis') h.alias('earthMinorAxisInMetres', 'earthMinorAxis') if (h.get_l('shapeOfTheEarth') == 3): h.add( _.From_scale_factor_scaled_value( 'earthMajorAxis', _.Get('scaleFactorOfEarthMajorAxis'), _.Get('scaledValueOfEarthMajorAxis'))) h.add( _.From_scale_factor_scaled_value( 'earthMinorAxis', _.Get('scaleFactorOfEarthMinorAxis'), _.Get('scaledValueOfEarthMinorAxis'))) h.add( _.Divdouble('earthMajorAxisInMetres', _.Get('earthMajorAxis'), 0.001)) h.add( _.Divdouble('earthMinorAxisInMetres', _.Get('earthMinorAxis'), 0.001)) if (h.get_l('shapeOfTheEarth') == 7): h.add( _.From_scale_factor_scaled_value( 'earthMajorAxis', _.Get('scaleFactorOfEarthMajorAxis'), _.Get('scaledValueOfEarthMajorAxis'))) h.add( _.From_scale_factor_scaled_value( 'earthMinorAxis', _.Get('scaleFactorOfEarthMinorAxis'), _.Get('scaledValueOfEarthMinorAxis'))) h.alias('earthMajorAxisInMetres', 'earthMajorAxis') h.alias('earthMinorAxisInMetres', 'earthMinorAxis') if ((h.get_l('shapeOfTheEarth') == 4) or (h.get_l('shapeOfTheEarth') == 5)): h.add(_.Transient('earthMajorAxis', 6.37814e+06)) h.add(_.Transient('earthMinorAxis', 6.35675e+06)) h.alias('earthMajorAxisInMetres', 'earthMajorAxis') h.alias('earthMinorAxisInMetres', 'earthMinorAxis') if (h.get_l('shapeOfTheEarth') == 9): h.add(_.Transient('earthMajorAxis', 6.37756e+06)) h.add(_.Transient('earthMinorAxis', 6.35626e+06)) h.alias('earthMajorAxisInMetres', 'earthMajorAxis') h.alias('earthMinorAxisInMetres', 'earthMinorAxis') h.add(_.Signed('latitudeOfFirstGridPoint', 4)) h.alias('La1', 'latitudeOfFirstGridPoint') h.add( _.Scale('latitudeOfFirstGridPointInDegrees', _.Get('latitudeOfFirstGridPoint'), _.Get('one'), _.Get('grib2divider'), _.Get('truncateDegrees'))) h.alias('geography.latitudeOfFirstGridPointInDegrees', 'latitudeOfFirstGridPointInDegrees') h.alias('La1InDegrees', 'latitudeOfFirstGridPointInDegrees') h.add(_.Unsigned('longitudeOfFirstGridPoint', 4)) h.alias('Lo1', 'longitudeOfFirstGridPoint') h.add( _.Scale('longitudeOfFirstGridPointInDegrees', _.Get('longitudeOfFirstGridPoint'), _.Get('one'), _.Get('grib2divider'), _.Get('truncateDegrees'))) h.alias('geography.longitudeOfFirstGridPointInDegrees', 'longitudeOfFirstGridPointInDegrees') h.alias('Lo1InDegrees', 'longitudeOfFirstGridPointInDegrees') h.add(_.Signed('LaD', 4)) h.alias('latitudeWhereDxAndDyAreSpecified', 'LaD') h.add( _.Scale('LaDInDegrees', _.Get('LaD'), _.Get('one'), _.Get('grib2divider'), _.Get('truncateDegrees'))) h.alias('geography.LaDInDegrees', 'LaDInDegrees') h.add(_.Unsigned('LoV', 4)) h.add( _.Scale('LoVInDegrees', _.Get('LoV'), _.Get('one'), _.Get('grib2divider'), _.Get('truncateDegrees'))) h.alias('geography.LoVInDegrees', 'LoVInDegrees') h.add( _.Codeflag('projectionCentreFlag', 1, "grib2/tables/[tablesVersion]/3.5.table")) h.add(_.Signed('Latin1', 4)) h.alias('FirstLatitude', 'Latin1') h.add( _.Scale('Latin1InDegrees', _.Get('Latin1'), _.Get('one'), _.Get('grib2divider'), _.Get('truncateDegrees'))) h.alias('geography.Latin1InDegrees', 'Latin1InDegrees') h.add(_.Signed('Latin2', 4)) h.alias('SecondLatitude', 'Latin2') h.add( _.Scale('Latin2InDegrees', _.Get('Latin2'), _.Get('one'), _.Get('grib2divider'), _.Get('truncateDegrees'))) h.alias('geography.Latin2InDegrees', 'Latin2InDegrees') h.add(_.Signed('latitudeOfSouthernPole', 4)) h.alias('latitudeOfTheSouthernPoleOfProjection', 'latitudeOfSouthernPole') h.add( _.Scale('latitudeOfSouthernPoleInDegrees', _.Get('latitudeOfSouthernPole'), _.Get('one'), _.Get('grib2divider'), _.Get('truncateDegrees'))) h.alias('geography.latitudeOfSouthernPoleInDegrees', 'latitudeOfSouthernPoleInDegrees') h.add(_.Unsigned('longitudeOfSouthernPole', 4)) h.alias('longitudeOfTheSouthernPoleOfProjection', 'longitudeOfSouthernPole') h.add( _.Scale('longitudeOfSouthernPoleInDegrees', _.Get('longitudeOfSouthernPole'), _.Get('oneConstant'), _.Get('grib2divider'), _.Get('truncateDegrees'))) h.alias('geography.longitudeOfSouthernPoleInDegrees', 'longitudeOfSouthernPoleInDegrees')
def load(h): h.add( _.Codetable('shapeOfTheEarth', 1, "3.2.table", _.Get('masterDir'), _.Get('localDir'))) h.add(_.Unsigned('scaleFactorOfRadiusOfSphericalEarth', 1)) h.add(_.Unsigned('scaledValueOfRadiusOfSphericalEarth', 4)) h.add(_.Unsigned('scaleFactorOfEarthMajorAxis', 1)) h.alias('scaleFactorOfMajorAxisOfOblateSpheroidEarth', 'scaleFactorOfEarthMajorAxis') h.add(_.Unsigned('scaledValueOfEarthMajorAxis', 4)) h.alias('scaledValueOfMajorAxisOfOblateSpheroidEarth', 'scaledValueOfEarthMajorAxis') h.add(_.Unsigned('scaleFactorOfEarthMinorAxis', 1)) h.alias('scaleFactorOfMinorAxisOfOblateSpheroidEarth', 'scaleFactorOfEarthMinorAxis') h.add(_.Unsigned('scaledValueOfEarthMinorAxis', 4)) h.alias('scaledValueOfMinorAxisOfOblateSpheroidEarth', 'scaledValueOfEarthMinorAxis') h.alias('earthIsOblate', 'one') if (h.get_l('shapeOfTheEarth') == 0): h.add(_.Transient('radius', 6367470)) h.alias('radiusOfTheEarth', 'radius') h.alias('radiusInMetres', 'radius') h.alias('earthIsOblate', 'zero') if (h.get_l('shapeOfTheEarth') == 1): h.add( _.From_scale_factor_scaled_value( 'radius', _.Get('scaleFactorOfRadiusOfSphericalEarth'), _.Get('scaledValueOfRadiusOfSphericalEarth'))) h.alias('radiusOfTheEarth', 'radius') h.alias('radiusInMetres', 'radius') h.alias('earthIsOblate', 'zero') if (h.get_l('shapeOfTheEarth') == 6): h.add(_.Transient('radius', 6371229)) h.alias('radiusOfTheEarth', 'radius') h.alias('radiusInMetres', 'radius') h.alias('earthIsOblate', 'zero') if (h.get_l('shapeOfTheEarth') == 8): h.add(_.Transient('radius', 6371200)) h.alias('radiusOfTheEarth', 'radius') h.alias('radiusInMetres', 'radius') h.alias('earthIsOblate', 'zero') if (h.get_l('shapeOfTheEarth') == 2): h.add(_.Transient('earthMajorAxis', 6.37816e+06)) h.add(_.Transient('earthMinorAxis', 6.35678e+06)) h.alias('earthMajorAxisInMetres', 'earthMajorAxis') h.alias('earthMinorAxisInMetres', 'earthMinorAxis') if (h.get_l('shapeOfTheEarth') == 3): h.add( _.From_scale_factor_scaled_value( 'earthMajorAxis', _.Get('scaleFactorOfEarthMajorAxis'), _.Get('scaledValueOfEarthMajorAxis'))) h.add( _.From_scale_factor_scaled_value( 'earthMinorAxis', _.Get('scaleFactorOfEarthMinorAxis'), _.Get('scaledValueOfEarthMinorAxis'))) h.add( _.Divdouble('earthMajorAxisInMetres', _.Get('earthMajorAxis'), 0.001)) h.add( _.Divdouble('earthMinorAxisInMetres', _.Get('earthMinorAxis'), 0.001)) if (h.get_l('shapeOfTheEarth') == 7): h.add( _.From_scale_factor_scaled_value( 'earthMajorAxis', _.Get('scaleFactorOfEarthMajorAxis'), _.Get('scaledValueOfEarthMajorAxis'))) h.add( _.From_scale_factor_scaled_value( 'earthMinorAxis', _.Get('scaleFactorOfEarthMinorAxis'), _.Get('scaledValueOfEarthMinorAxis'))) h.alias('earthMajorAxisInMetres', 'earthMajorAxis') h.alias('earthMinorAxisInMetres', 'earthMinorAxis') if ((h.get_l('shapeOfTheEarth') == 4) or (h.get_l('shapeOfTheEarth') == 5)): h.add(_.Transient('earthMajorAxis', 6.37814e+06)) h.add(_.Transient('earthMinorAxis', 6.35675e+06)) h.alias('earthMajorAxisInMetres', 'earthMajorAxis') h.alias('earthMinorAxisInMetres', 'earthMinorAxis') if (h.get_l('shapeOfTheEarth') == 9): h.add(_.Transient('earthMajorAxis', 6.37756e+06)) h.add(_.Transient('earthMinorAxis', 6.35626e+06)) h.alias('earthMajorAxisInMetres', 'earthMajorAxis') h.alias('earthMinorAxisInMetres', 'earthMinorAxis') h.add(_.Unsigned('Ni', 4)) h.alias('numberOfPointsAlongAParallel', 'Ni') h.alias('Nx', 'Ni') h.add(_.Unsigned('Nj', 4)) h.alias('numberOfPointsAlongAMeridian', 'Nj') h.alias('Ny', 'Nj') h.alias('geography.Ni', 'Ni') h.alias('geography.Nj', 'Nj') h.add(_.Unsigned('basicAngleOfTheInitialProductionDomain', 4)) h.add( _.Transient('mBasicAngle', (_.Get('basicAngleOfTheInitialProductionDomain') * _.Get('oneMillionConstant')))) h.add(_.Transient('angleMultiplier', 1)) h.add(_.Transient('mAngleMultiplier', 1000000)) pass # when block h.add(_.Unsigned('subdivisionsOfBasicAngle', 4)) h.add(_.Transient('angleDivisor', 1000000)) pass # when block h.add( _.Codeflag('resolutionAndComponentFlags', 1, "grib2/tables/[tablesVersion]/3.3.table")) h.add( _.Bit('resolutionAndComponentFlags1', _.Get('resolutionAndComponentFlags'), 7)) h.add( _.Bit('resolutionAndComponentFlags2', _.Get('resolutionAndComponentFlags'), 6)) h.add( _.Bit('iDirectionIncrementGiven', _.Get('resolutionAndComponentFlags'), 5)) h.add( _.Bit('jDirectionIncrementGiven', _.Get('resolutionAndComponentFlags'), 4)) h.add(_.Bit('uvRelativeToGrid', _.Get('resolutionAndComponentFlags'), 3)) h.add( _.Bit('resolutionAndComponentFlags6', _.Get('resolutionAndComponentFlags'), 7)) h.add( _.Bit('resolutionAndComponentFlags7', _.Get('resolutionAndComponentFlags'), 6)) h.add( _.Bit('resolutionAndComponentFlags8', _.Get('resolutionAndComponentFlags'), 6)) def ijDirectionIncrementGiven_inline_concept(h): def wrapped(h): iDirectionIncrementGiven = h.get_l('iDirectionIncrementGiven') jDirectionIncrementGiven = h.get_l('jDirectionIncrementGiven') if iDirectionIncrementGiven == 1 and jDirectionIncrementGiven == 1: return 1 if iDirectionIncrementGiven == 1 and jDirectionIncrementGiven == 0: return 0 if iDirectionIncrementGiven == 0 and jDirectionIncrementGiven == 1: return 0 if iDirectionIncrementGiven == 0 and jDirectionIncrementGiven == 0: return 0 return wrapped h.add( _.Concept('ijDirectionIncrementGiven', None, concepts=ijDirectionIncrementGiven_inline_concept(h))) h.alias('DiGiven', 'iDirectionIncrementGiven') h.alias('DjGiven', 'jDirectionIncrementGiven') h.add( _.Codeflag('scanningMode', 1, "grib2/tables/[tablesVersion]/3.4.table")) h.add(_.Bit('iScansNegatively', _.Get('scanningMode'), 7)) h.add(_.Bit('jScansPositively', _.Get('scanningMode'), 6)) h.add(_.Bit('jPointsAreConsecutive', _.Get('scanningMode'), 5)) h.add(_.Bit('alternativeRowScanning', _.Get('scanningMode'), 4)) if h.get_l('jPointsAreConsecutive'): h.alias('numberOfRows', 'Ni') h.alias('numberOfColumns', 'Nj') else: h.alias('numberOfRows', 'Nj') h.alias('numberOfColumns', 'Ni') h.alias('geography.iScansNegatively', 'iScansNegatively') h.alias('geography.jScansPositively', 'jScansPositively') h.alias('geography.jPointsAreConsecutive', 'jPointsAreConsecutive') h.add(_.Transient('iScansPositively', _.Not(_.Get('iScansNegatively')))) h.add(_.Bit('scanningMode5', _.Get('scanningMode'), 3)) h.add(_.Bit('scanningMode6', _.Get('scanningMode'), 2)) h.add(_.Bit('scanningMode7', _.Get('scanningMode'), 1)) h.add(_.Bit('scanningMode8', _.Get('scanningMode'), 0)) h.add( _.Change_scanning_direction('swapScanningX', _.Get('values'), _.Get('Ni'), _.Get('Nj'), _.Get('iScansNegatively'), _.Get('jScansPositively'), _.Get('xFirst'), _.Get('xLast'), _.Get('x'))) h.alias('swapScanningLon', 'swapScanningX') h.add( _.Change_scanning_direction('swapScanningY', _.Get('values'), _.Get('Ni'), _.Get('Nj'), _.Get('iScansNegatively'), _.Get('jScansPositively'), _.Get('yFirst'), _.Get('yLast'), _.Get('y'))) h.alias('swapScanningLat', 'swapScanningY') with h.list('longitudesList'): for i in range(0, h.get_l('Ni')): h.add(_.Unsigned('longitudes', 4)) with h.list('latitudesList'): for i in range(0, h.get_l('Nj')): h.add(_.Signed('latitudes', 4)) h.add(_.Signed('latitudeOfSouthernPole', 4)) h.alias('latitudeOfTheSouthernPoleOfProjection', 'latitudeOfSouthernPole') h.add(_.Unsigned('longitudeOfSouthernPole', 4)) h.alias('longitudeOfTheSouthernPoleOfProjection', 'longitudeOfSouthernPole') h.add( _.Scale('latitudeOfSouthernPoleInDegrees', _.Get('latitudeOfSouthernPole'), _.Get('one'), _.Get('grib2divider'), _.Get('truncateDegrees'))) h.alias('geography.latitudeOfSouthernPoleInDegrees', 'latitudeOfSouthernPoleInDegrees') h.add( _.G2lon('longitudeOfSouthernPoleInDegrees', _.Get('longitudeOfSouthernPole'))) h.alias('geography.longitudeOfSouthernPoleInDegrees', 'longitudeOfSouthernPoleInDegrees') h.add(_.Ieeefloat('angleOfRotation', 4)) h.alias('geography.angleOfRotationInDegrees', 'angleOfRotation') h.alias('angleOfRotationOfProjection', 'angleOfRotation') h.alias('isRotatedGrid', 'one')
def load(h): h.add( _.Codetable('shapeOfTheEarth', 1, "3.2.table", _.Get('masterDir'), _.Get('localDir'))) h.add(_.Unsigned('scaleFactorOfRadiusOfSphericalEarth', 1)) h.add(_.Unsigned('scaledValueOfRadiusOfSphericalEarth', 4)) h.add(_.Unsigned('scaleFactorOfEarthMajorAxis', 1)) h.alias('scaleFactorOfMajorAxisOfOblateSpheroidEarth', 'scaleFactorOfEarthMajorAxis') h.add(_.Unsigned('scaledValueOfEarthMajorAxis', 4)) h.alias('scaledValueOfMajorAxisOfOblateSpheroidEarth', 'scaledValueOfEarthMajorAxis') h.add(_.Unsigned('scaleFactorOfEarthMinorAxis', 1)) h.alias('scaleFactorOfMinorAxisOfOblateSpheroidEarth', 'scaleFactorOfEarthMinorAxis') h.add(_.Unsigned('scaledValueOfEarthMinorAxis', 4)) h.alias('scaledValueOfMinorAxisOfOblateSpheroidEarth', 'scaledValueOfEarthMinorAxis') h.alias('earthIsOblate', 'one') if (h.get_l('shapeOfTheEarth') == 0): h.add(_.Transient('radius', 6367470)) h.alias('radiusOfTheEarth', 'radius') h.alias('radiusInMetres', 'radius') h.alias('earthIsOblate', 'zero') if (h.get_l('shapeOfTheEarth') == 1): h.add( _.From_scale_factor_scaled_value( 'radius', _.Get('scaleFactorOfRadiusOfSphericalEarth'), _.Get('scaledValueOfRadiusOfSphericalEarth'))) h.alias('radiusOfTheEarth', 'radius') h.alias('radiusInMetres', 'radius') h.alias('earthIsOblate', 'zero') if (h.get_l('shapeOfTheEarth') == 6): h.add(_.Transient('radius', 6371229)) h.alias('radiusOfTheEarth', 'radius') h.alias('radiusInMetres', 'radius') h.alias('earthIsOblate', 'zero') if (h.get_l('shapeOfTheEarth') == 8): h.add(_.Transient('radius', 6371200)) h.alias('radiusOfTheEarth', 'radius') h.alias('radiusInMetres', 'radius') h.alias('earthIsOblate', 'zero') if (h.get_l('shapeOfTheEarth') == 2): h.add(_.Transient('earthMajorAxis', 6.37816e+06)) h.add(_.Transient('earthMinorAxis', 6.35678e+06)) h.alias('earthMajorAxisInMetres', 'earthMajorAxis') h.alias('earthMinorAxisInMetres', 'earthMinorAxis') if (h.get_l('shapeOfTheEarth') == 3): h.add( _.From_scale_factor_scaled_value( 'earthMajorAxis', _.Get('scaleFactorOfEarthMajorAxis'), _.Get('scaledValueOfEarthMajorAxis'))) h.add( _.From_scale_factor_scaled_value( 'earthMinorAxis', _.Get('scaleFactorOfEarthMinorAxis'), _.Get('scaledValueOfEarthMinorAxis'))) h.add( _.Divdouble('earthMajorAxisInMetres', _.Get('earthMajorAxis'), 0.001)) h.add( _.Divdouble('earthMinorAxisInMetres', _.Get('earthMinorAxis'), 0.001)) if (h.get_l('shapeOfTheEarth') == 7): h.add( _.From_scale_factor_scaled_value( 'earthMajorAxis', _.Get('scaleFactorOfEarthMajorAxis'), _.Get('scaledValueOfEarthMajorAxis'))) h.add( _.From_scale_factor_scaled_value( 'earthMinorAxis', _.Get('scaleFactorOfEarthMinorAxis'), _.Get('scaledValueOfEarthMinorAxis'))) h.alias('earthMajorAxisInMetres', 'earthMajorAxis') h.alias('earthMinorAxisInMetres', 'earthMinorAxis') if ((h.get_l('shapeOfTheEarth') == 4) or (h.get_l('shapeOfTheEarth') == 5)): h.add(_.Transient('earthMajorAxis', 6.37814e+06)) h.add(_.Transient('earthMinorAxis', 6.35675e+06)) h.alias('earthMajorAxisInMetres', 'earthMajorAxis') h.alias('earthMinorAxisInMetres', 'earthMinorAxis') if (h.get_l('shapeOfTheEarth') == 9): h.add(_.Transient('earthMajorAxis', 6.37756e+06)) h.add(_.Transient('earthMinorAxis', 6.35626e+06)) h.alias('earthMajorAxisInMetres', 'earthMajorAxis') h.alias('earthMinorAxisInMetres', 'earthMinorAxis') h.add(_.Unsigned('Nx', 4)) h.alias('Ni', 'Nx') h.alias('numberOfPointsAlongXAxis', 'Nx') h.alias('geography.Nx', 'Nx') h.add(_.Unsigned('Ny', 4)) h.alias('Nj', 'Ny') h.alias('numberOfPointsAlongYAxis', 'Ny') h.alias('geography.Ny', 'Ny') h.add(_.Signed('latitudeOfSubSatellitePoint', 4)) h.add(_.Signed('longitudeOfSubSatellitePoint', 4)) h.add( _.Scale('latitudeOfSubSatellitePointInDegrees', _.Get('latitudeOfSubSatellitePoint'), _.Get('one'), _.Get('grib2divider'), _.Get('truncateDegrees'))) h.alias('geography.latitudeOfSubSatellitePointInDegrees', 'latitudeOfSubSatellitePointInDegrees') h.add( _.Scale('longitudeOfSubSatellitePointInDegrees', _.Get('longitudeOfSubSatellitePoint'), _.Get('one'), _.Get('grib2divider'), _.Get('truncateDegrees'))) h.alias('geography.longitudeOfSubSatellitePointInDegrees', 'longitudeOfSubSatellitePointInDegrees') h.add( _.Codeflag('resolutionAndComponentFlags', 1, "grib2/tables/[tablesVersion]/3.3.table")) h.add( _.Bit('resolutionAndComponentFlags1', _.Get('resolutionAndComponentFlags'), 7)) h.add( _.Bit('resolutionAndComponentFlags2', _.Get('resolutionAndComponentFlags'), 6)) h.add( _.Bit('iDirectionIncrementGiven', _.Get('resolutionAndComponentFlags'), 5)) h.add( _.Bit('jDirectionIncrementGiven', _.Get('resolutionAndComponentFlags'), 4)) h.add(_.Bit('uvRelativeToGrid', _.Get('resolutionAndComponentFlags'), 3)) h.add( _.Bit('resolutionAndComponentFlags6', _.Get('resolutionAndComponentFlags'), 7)) h.add( _.Bit('resolutionAndComponentFlags7', _.Get('resolutionAndComponentFlags'), 6)) h.add( _.Bit('resolutionAndComponentFlags8', _.Get('resolutionAndComponentFlags'), 6)) def ijDirectionIncrementGiven_inline_concept(h): def wrapped(h): iDirectionIncrementGiven = h.get_l('iDirectionIncrementGiven') jDirectionIncrementGiven = h.get_l('jDirectionIncrementGiven') if iDirectionIncrementGiven == 1 and jDirectionIncrementGiven == 1: return 1 if iDirectionIncrementGiven == 1 and jDirectionIncrementGiven == 0: return 0 if iDirectionIncrementGiven == 0 and jDirectionIncrementGiven == 1: return 0 if iDirectionIncrementGiven == 0 and jDirectionIncrementGiven == 0: return 0 return wrapped h.add( _.Concept('ijDirectionIncrementGiven', None, concepts=ijDirectionIncrementGiven_inline_concept(h))) h.alias('DiGiven', 'iDirectionIncrementGiven') h.alias('DjGiven', 'jDirectionIncrementGiven') h.add(_.Unsigned('dx', 4)) h.alias('geography.dx', 'dx') h.add(_.Unsigned('dy', 4)) h.alias('geography.dy', 'dy') h.add(_.Unsigned('Xp', 4)) h.add( _.Scale('XpInGridLengths', _.Get('Xp'), _.Get('one'), _.Get('thousand'))) h.alias('geography.XpInGridLengths', 'XpInGridLengths') h.alias('xCoordinateOfSubSatellitePoint', 'XpInGridLengths') h.add(_.Unsigned('Yp', 4)) h.add( _.Scale('YpInGridLengths', _.Get('Yp'), _.Get('one'), _.Get('thousand'))) h.alias('geography.YpInGridLengths', 'YpInGridLengths') h.alias('yCoordinateOfSubSatellitePoint', 'YpInGridLengths') h.add( _.Codeflag('scanningMode', 1, "grib2/tables/[tablesVersion]/3.4.table")) h.add(_.Bit('iScansNegatively', _.Get('scanningMode'), 7)) h.add(_.Bit('jScansPositively', _.Get('scanningMode'), 6)) h.add(_.Bit('jPointsAreConsecutive', _.Get('scanningMode'), 5)) h.add(_.Bit('alternativeRowScanning', _.Get('scanningMode'), 4)) if h.get_l('jPointsAreConsecutive'): h.alias('numberOfRows', 'Ni') h.alias('numberOfColumns', 'Nj') else: h.alias('numberOfRows', 'Nj') h.alias('numberOfColumns', 'Ni') h.alias('geography.iScansNegatively', 'iScansNegatively') h.alias('geography.jScansPositively', 'jScansPositively') h.alias('geography.jPointsAreConsecutive', 'jPointsAreConsecutive') h.add(_.Transient('iScansPositively', _.Not(_.Get('iScansNegatively')))) h.add(_.Bit('scanningMode5', _.Get('scanningMode'), 3)) h.add(_.Bit('scanningMode6', _.Get('scanningMode'), 2)) h.add(_.Bit('scanningMode7', _.Get('scanningMode'), 1)) h.add(_.Bit('scanningMode8', _.Get('scanningMode'), 0)) h.add( _.Change_scanning_direction('swapScanningX', _.Get('values'), _.Get('Ni'), _.Get('Nj'), _.Get('iScansNegatively'), _.Get('jScansPositively'), _.Get('xFirst'), _.Get('xLast'), _.Get('x'))) h.alias('swapScanningLon', 'swapScanningX') h.add( _.Change_scanning_direction('swapScanningY', _.Get('values'), _.Get('Ni'), _.Get('Nj'), _.Get('iScansNegatively'), _.Get('jScansPositively'), _.Get('yFirst'), _.Get('yLast'), _.Get('y'))) h.alias('swapScanningLat', 'swapScanningY') h.add(_.Signed('orientationOfTheGrid', 4)) h.add( _.Scale('orientationOfTheGridInDegrees', _.Get('orientationOfTheGrid'), _.Get('oneConstant'), _.Get('grib2divider'), _.Get('truncateDegrees'))) h.alias('geography.orientationOfTheGridInDegrees', 'orientationOfTheGridInDegrees') h.add(_.Unsigned('Nr', 4)) h.alias( 'altitudeOfTheCameraFromTheEarthsCentreMeasuredInUnitsOfTheEarthsRadius', 'Nr') h.add( _.Scale('NrInRadiusOfEarth', _.Get('Nr'), _.Get('oneConstant'), _.Get('oneMillionConstant'), _.Get('truncateDegrees'))) h.alias('geography.NrInRadiusOfEarth', 'NrInRadiusOfEarth') h.add(_.Unsigned('Xo', 4)) h.alias('xCoordinateOfOriginOfSectorImage', 'Xo') h.alias('geography.Xo', 'Xo') h.add(_.Unsigned('Yo', 4)) h.alias('yCoordinateOfOriginOfSectorImage', 'Yo') h.alias('geography.Yo', 'Yo') h.add( _.Iterator('ITERATOR', _.Get('space_view'), _.Get('numberOfPoints'), _.Get('missingValue'), _.Get('values'), _.Get('radius'), _.Get('earthIsOblate'), _.Get('earthMajorAxis'), _.Get('earthMinorAxis'), _.Get('Nx'), _.Get('Ny'), _.Get('latitudeOfSubSatellitePointInDegrees'), _.Get('longitudeOfSubSatellitePointInDegrees'), _.Get('dx'), _.Get('dy'), _.Get('XpInGridLengths'), _.Get('YpInGridLengths'), _.Get('orientationOfTheGridInDegrees'), _.Get('NrInRadiusOfEarth'), _.Get('Xo'), _.Get('Yo'), _.Get('iScansNegatively'), _.Get('jScansPositively'), _.Get('jPointsAreConsecutive'), _.Get('alternativeRowScanning')))
def load(h): h.add( _.Codetable('shapeOfTheEarth', 1, "3.2.table", _.Get('masterDir'), _.Get('localDir'))) h.add(_.Unsigned('scaleFactorOfRadiusOfSphericalEarth', 1)) h.add(_.Unsigned('scaledValueOfRadiusOfSphericalEarth', 4)) h.add(_.Unsigned('scaleFactorOfEarthMajorAxis', 1)) h.alias('scaleFactorOfMajorAxisOfOblateSpheroidEarth', 'scaleFactorOfEarthMajorAxis') h.add(_.Unsigned('scaledValueOfEarthMajorAxis', 4)) h.alias('scaledValueOfMajorAxisOfOblateSpheroidEarth', 'scaledValueOfEarthMajorAxis') h.add(_.Unsigned('scaleFactorOfEarthMinorAxis', 1)) h.alias('scaleFactorOfMinorAxisOfOblateSpheroidEarth', 'scaleFactorOfEarthMinorAxis') h.add(_.Unsigned('scaledValueOfEarthMinorAxis', 4)) h.alias('scaledValueOfMinorAxisOfOblateSpheroidEarth', 'scaledValueOfEarthMinorAxis') h.alias('earthIsOblate', 'one') if (h.get_l('shapeOfTheEarth') == 0): h.add(_.Transient('radius', 6367470)) h.alias('radiusOfTheEarth', 'radius') h.alias('radiusInMetres', 'radius') h.alias('earthIsOblate', 'zero') if (h.get_l('shapeOfTheEarth') == 1): h.add( _.From_scale_factor_scaled_value( 'radius', _.Get('scaleFactorOfRadiusOfSphericalEarth'), _.Get('scaledValueOfRadiusOfSphericalEarth'))) h.alias('radiusOfTheEarth', 'radius') h.alias('radiusInMetres', 'radius') h.alias('earthIsOblate', 'zero') if (h.get_l('shapeOfTheEarth') == 6): h.add(_.Transient('radius', 6371229)) h.alias('radiusOfTheEarth', 'radius') h.alias('radiusInMetres', 'radius') h.alias('earthIsOblate', 'zero') if (h.get_l('shapeOfTheEarth') == 8): h.add(_.Transient('radius', 6371200)) h.alias('radiusOfTheEarth', 'radius') h.alias('radiusInMetres', 'radius') h.alias('earthIsOblate', 'zero') if (h.get_l('shapeOfTheEarth') == 2): h.add(_.Transient('earthMajorAxis', 6.37816e+06)) h.add(_.Transient('earthMinorAxis', 6.35678e+06)) h.alias('earthMajorAxisInMetres', 'earthMajorAxis') h.alias('earthMinorAxisInMetres', 'earthMinorAxis') if (h.get_l('shapeOfTheEarth') == 3): h.add( _.From_scale_factor_scaled_value( 'earthMajorAxis', _.Get('scaleFactorOfEarthMajorAxis'), _.Get('scaledValueOfEarthMajorAxis'))) h.add( _.From_scale_factor_scaled_value( 'earthMinorAxis', _.Get('scaleFactorOfEarthMinorAxis'), _.Get('scaledValueOfEarthMinorAxis'))) h.add( _.Divdouble('earthMajorAxisInMetres', _.Get('earthMajorAxis'), 0.001)) h.add( _.Divdouble('earthMinorAxisInMetres', _.Get('earthMinorAxis'), 0.001)) if (h.get_l('shapeOfTheEarth') == 7): h.add( _.From_scale_factor_scaled_value( 'earthMajorAxis', _.Get('scaleFactorOfEarthMajorAxis'), _.Get('scaledValueOfEarthMajorAxis'))) h.add( _.From_scale_factor_scaled_value( 'earthMinorAxis', _.Get('scaleFactorOfEarthMinorAxis'), _.Get('scaledValueOfEarthMinorAxis'))) h.alias('earthMajorAxisInMetres', 'earthMajorAxis') h.alias('earthMinorAxisInMetres', 'earthMinorAxis') if ((h.get_l('shapeOfTheEarth') == 4) or (h.get_l('shapeOfTheEarth') == 5)): h.add(_.Transient('earthMajorAxis', 6.37814e+06)) h.add(_.Transient('earthMinorAxis', 6.35675e+06)) h.alias('earthMajorAxisInMetres', 'earthMajorAxis') h.alias('earthMinorAxisInMetres', 'earthMinorAxis') if (h.get_l('shapeOfTheEarth') == 9): h.add(_.Transient('earthMajorAxis', 6.37756e+06)) h.add(_.Transient('earthMinorAxis', 6.35626e+06)) h.alias('earthMajorAxisInMetres', 'earthMajorAxis') h.alias('earthMinorAxisInMetres', 'earthMinorAxis') with h.list('points'): for i in range(0, h.get_l('numberOfDataPoints')): h.add(_.Signed('latitude', 4)) h.add(_.Signed('longitude', 4))
def load(h): h.add(_.Codetable('shapeOfTheEarth', 1, "3.2.table", _.Get('masterDir'), _.Get('localDir'))) h.add(_.Unsigned('scaleFactorOfRadiusOfSphericalEarth', 1)) h.add(_.Unsigned('scaledValueOfRadiusOfSphericalEarth', 4)) h.add(_.Unsigned('scaleFactorOfEarthMajorAxis', 1)) h.alias('scaleFactorOfMajorAxisOfOblateSpheroidEarth', 'scaleFactorOfEarthMajorAxis') h.add(_.Unsigned('scaledValueOfEarthMajorAxis', 4)) h.alias('scaledValueOfMajorAxisOfOblateSpheroidEarth', 'scaledValueOfEarthMajorAxis') h.add(_.Unsigned('scaleFactorOfEarthMinorAxis', 1)) h.alias('scaleFactorOfMinorAxisOfOblateSpheroidEarth', 'scaleFactorOfEarthMinorAxis') h.add(_.Unsigned('scaledValueOfEarthMinorAxis', 4)) h.alias('scaledValueOfMinorAxisOfOblateSpheroidEarth', 'scaledValueOfEarthMinorAxis') h.alias('earthIsOblate', 'one') if (h.get_l('shapeOfTheEarth') == 0): h.add(_.Transient('radius', 6367470)) h.alias('radiusOfTheEarth', 'radius') h.alias('radiusInMetres', 'radius') h.alias('earthIsOblate', 'zero') if (h.get_l('shapeOfTheEarth') == 1): h.add(_.From_scale_factor_scaled_value('radius', _.Get('scaleFactorOfRadiusOfSphericalEarth'), _.Get('scaledValueOfRadiusOfSphericalEarth'))) h.alias('radiusOfTheEarth', 'radius') h.alias('radiusInMetres', 'radius') h.alias('earthIsOblate', 'zero') if (h.get_l('shapeOfTheEarth') == 6): h.add(_.Transient('radius', 6371229)) h.alias('radiusOfTheEarth', 'radius') h.alias('radiusInMetres', 'radius') h.alias('earthIsOblate', 'zero') if (h.get_l('shapeOfTheEarth') == 8): h.add(_.Transient('radius', 6371200)) h.alias('radiusOfTheEarth', 'radius') h.alias('radiusInMetres', 'radius') h.alias('earthIsOblate', 'zero') if (h.get_l('shapeOfTheEarth') == 2): h.add(_.Transient('earthMajorAxis', 6.37816e+06)) h.add(_.Transient('earthMinorAxis', 6.35678e+06)) h.alias('earthMajorAxisInMetres', 'earthMajorAxis') h.alias('earthMinorAxisInMetres', 'earthMinorAxis') if (h.get_l('shapeOfTheEarth') == 3): h.add(_.From_scale_factor_scaled_value('earthMajorAxis', _.Get('scaleFactorOfEarthMajorAxis'), _.Get('scaledValueOfEarthMajorAxis'))) h.add(_.From_scale_factor_scaled_value('earthMinorAxis', _.Get('scaleFactorOfEarthMinorAxis'), _.Get('scaledValueOfEarthMinorAxis'))) h.add(_.Divdouble('earthMajorAxisInMetres', _.Get('earthMajorAxis'), 0.001)) h.add(_.Divdouble('earthMinorAxisInMetres', _.Get('earthMinorAxis'), 0.001)) if (h.get_l('shapeOfTheEarth') == 7): h.add(_.From_scale_factor_scaled_value('earthMajorAxis', _.Get('scaleFactorOfEarthMajorAxis'), _.Get('scaledValueOfEarthMajorAxis'))) h.add(_.From_scale_factor_scaled_value('earthMinorAxis', _.Get('scaleFactorOfEarthMinorAxis'), _.Get('scaledValueOfEarthMinorAxis'))) h.alias('earthMajorAxisInMetres', 'earthMajorAxis') h.alias('earthMinorAxisInMetres', 'earthMinorAxis') if ((h.get_l('shapeOfTheEarth') == 4) or (h.get_l('shapeOfTheEarth') == 5)): h.add(_.Transient('earthMajorAxis', 6.37814e+06)) h.add(_.Transient('earthMinorAxis', 6.35675e+06)) h.alias('earthMajorAxisInMetres', 'earthMajorAxis') h.alias('earthMinorAxisInMetres', 'earthMinorAxis') if (h.get_l('shapeOfTheEarth') == 9): h.add(_.Transient('earthMajorAxis', 6.37756e+06)) h.add(_.Transient('earthMinorAxis', 6.35626e+06)) h.alias('earthMajorAxisInMetres', 'earthMajorAxis') h.alias('earthMinorAxisInMetres', 'earthMinorAxis') h.add(_.Unsigned('numberOfPointsAlongXAxis', 4)) h.alias('Nx', 'numberOfPointsAlongXAxis') h.add(_.Unsigned('numberOfPointsAlongYAxis', 4)) h.alias('Ny', 'numberOfPointsAlongYAxis') h.add(_.Signed('latitudeOfTangencyPoint', 4)) h.alias('La1', 'latitudeOfTangencyPoint') h.add(_.Unsigned('longitudeOfTangencyPoint', 4)) h.alias('Lo1', 'longitudeOfTangencyPoint') h.add(_.Codeflag('resolutionAndComponentFlags', 1, "grib2/tables/[tablesVersion]/3.3.table")) h.add(_.Unsigned('Dx', 4)) h.add(_.Unsigned('Dy', 4)) h.add(_.Unsigned('projectionCentreFlag', 1)) h.add(_.Codeflag('scanningMode', 1, "grib2/tables/[tablesVersion]/3.4.table")) h.add(_.Bit('iScansNegatively', _.Get('scanningMode'), 7)) h.add(_.Bit('jScansPositively', _.Get('scanningMode'), 6)) h.add(_.Bit('jPointsAreConsecutive', _.Get('scanningMode'), 5)) h.add(_.Bit('alternativeRowScanning', _.Get('scanningMode'), 4)) if h.get_l('jPointsAreConsecutive'): h.alias('numberOfRows', 'Ni') h.alias('numberOfColumns', 'Nj') else: h.alias('numberOfRows', 'Nj') h.alias('numberOfColumns', 'Ni') h.alias('geography.iScansNegatively', 'iScansNegatively') h.alias('geography.jScansPositively', 'jScansPositively') h.alias('geography.jPointsAreConsecutive', 'jPointsAreConsecutive') h.add(_.Transient('iScansPositively', _.Not(_.Get('iScansNegatively')))) h.add(_.Bit('scanningMode5', _.Get('scanningMode'), 3)) h.add(_.Bit('scanningMode6', _.Get('scanningMode'), 2)) h.add(_.Bit('scanningMode7', _.Get('scanningMode'), 1)) h.add(_.Bit('scanningMode8', _.Get('scanningMode'), 0)) h.add(_.Change_scanning_direction('swapScanningX', _.Get('values'), _.Get('Ni'), _.Get('Nj'), _.Get('iScansNegatively'), _.Get('jScansPositively'), _.Get('xFirst'), _.Get('xLast'), _.Get('x'))) h.alias('swapScanningLon', 'swapScanningX') h.add(_.Change_scanning_direction('swapScanningY', _.Get('values'), _.Get('Ni'), _.Get('Nj'), _.Get('iScansNegatively'), _.Get('jScansPositively'), _.Get('yFirst'), _.Get('yLast'), _.Get('y'))) h.alias('swapScanningLat', 'swapScanningY')
def load(h): h.add( _.Codetable('shapeOfTheEarth', 1, "3.2.table", _.Get('masterDir'), _.Get('localDir'))) h.add(_.Unsigned('scaleFactorOfRadiusOfSphericalEarth', 1)) h.add(_.Unsigned('scaledValueOfRadiusOfSphericalEarth', 4)) h.add(_.Unsigned('scaleFactorOfEarthMajorAxis', 1)) h.alias('scaleFactorOfMajorAxisOfOblateSpheroidEarth', 'scaleFactorOfEarthMajorAxis') h.add(_.Unsigned('scaledValueOfEarthMajorAxis', 4)) h.alias('scaledValueOfMajorAxisOfOblateSpheroidEarth', 'scaledValueOfEarthMajorAxis') h.add(_.Unsigned('scaleFactorOfEarthMinorAxis', 1)) h.alias('scaleFactorOfMinorAxisOfOblateSpheroidEarth', 'scaleFactorOfEarthMinorAxis') h.add(_.Unsigned('scaledValueOfEarthMinorAxis', 4)) h.alias('scaledValueOfMinorAxisOfOblateSpheroidEarth', 'scaledValueOfEarthMinorAxis') h.alias('earthIsOblate', 'one') if (h.get_l('shapeOfTheEarth') == 0): h.add(_.Transient('radius', 6367470)) h.alias('radiusOfTheEarth', 'radius') h.alias('radiusInMetres', 'radius') h.alias('earthIsOblate', 'zero') if (h.get_l('shapeOfTheEarth') == 1): h.add( _.From_scale_factor_scaled_value( 'radius', _.Get('scaleFactorOfRadiusOfSphericalEarth'), _.Get('scaledValueOfRadiusOfSphericalEarth'))) h.alias('radiusOfTheEarth', 'radius') h.alias('radiusInMetres', 'radius') h.alias('earthIsOblate', 'zero') if (h.get_l('shapeOfTheEarth') == 6): h.add(_.Transient('radius', 6371229)) h.alias('radiusOfTheEarth', 'radius') h.alias('radiusInMetres', 'radius') h.alias('earthIsOblate', 'zero') if (h.get_l('shapeOfTheEarth') == 8): h.add(_.Transient('radius', 6371200)) h.alias('radiusOfTheEarth', 'radius') h.alias('radiusInMetres', 'radius') h.alias('earthIsOblate', 'zero') if (h.get_l('shapeOfTheEarth') == 2): h.add(_.Transient('earthMajorAxis', 6.37816e+06)) h.add(_.Transient('earthMinorAxis', 6.35678e+06)) h.alias('earthMajorAxisInMetres', 'earthMajorAxis') h.alias('earthMinorAxisInMetres', 'earthMinorAxis') if (h.get_l('shapeOfTheEarth') == 3): h.add( _.From_scale_factor_scaled_value( 'earthMajorAxis', _.Get('scaleFactorOfEarthMajorAxis'), _.Get('scaledValueOfEarthMajorAxis'))) h.add( _.From_scale_factor_scaled_value( 'earthMinorAxis', _.Get('scaleFactorOfEarthMinorAxis'), _.Get('scaledValueOfEarthMinorAxis'))) h.add( _.Divdouble('earthMajorAxisInMetres', _.Get('earthMajorAxis'), 0.001)) h.add( _.Divdouble('earthMinorAxisInMetres', _.Get('earthMinorAxis'), 0.001)) if (h.get_l('shapeOfTheEarth') == 7): h.add( _.From_scale_factor_scaled_value( 'earthMajorAxis', _.Get('scaleFactorOfEarthMajorAxis'), _.Get('scaledValueOfEarthMajorAxis'))) h.add( _.From_scale_factor_scaled_value( 'earthMinorAxis', _.Get('scaleFactorOfEarthMinorAxis'), _.Get('scaledValueOfEarthMinorAxis'))) h.alias('earthMajorAxisInMetres', 'earthMajorAxis') h.alias('earthMinorAxisInMetres', 'earthMinorAxis') if ((h.get_l('shapeOfTheEarth') == 4) or (h.get_l('shapeOfTheEarth') == 5)): h.add(_.Transient('earthMajorAxis', 6.37814e+06)) h.add(_.Transient('earthMinorAxis', 6.35675e+06)) h.alias('earthMajorAxisInMetres', 'earthMajorAxis') h.alias('earthMinorAxisInMetres', 'earthMinorAxis') if (h.get_l('shapeOfTheEarth') == 9): h.add(_.Transient('earthMajorAxis', 6.37756e+06)) h.add(_.Transient('earthMinorAxis', 6.35626e+06)) h.alias('earthMajorAxisInMetres', 'earthMajorAxis') h.alias('earthMinorAxisInMetres', 'earthMinorAxis') h.add(_.Transient('oneThousand', 1000)) h.add(_.Unsigned('Nx', 4)) h.alias('Ni', 'Nx') h.alias('numberOfPointsAlongXAxis', 'Nx') h.alias('geography.Nx', 'Nx') h.add(_.Unsigned('Ny', 4)) h.alias('Nj', 'Ny') h.alias('numberOfPointsAlongYAxis', 'Ny') h.alias('geography.Ny', 'Ny') h.add(_.Signed('latitudeOfFirstGridPoint', 4)) h.add( _.Scale('latitudeOfFirstGridPointInDegrees', _.Get('latitudeOfFirstGridPoint'), _.Get('oneConstant'), _.Get('grib2divider'), _.Get('truncateDegrees'))) h.alias('geography.latitudeOfFirstGridPointInDegrees', 'latitudeOfFirstGridPointInDegrees') h.alias('La1', 'latitudeOfFirstGridPoint') h.add(_.Unsigned('longitudeOfFirstGridPoint', 4)) h.add( _.Scale('longitudeOfFirstGridPointInDegrees', _.Get('longitudeOfFirstGridPoint'), _.Get('oneConstant'), _.Get('grib2divider'), _.Get('truncateDegrees'))) h.alias('geography.longitudeOfFirstGridPointInDegrees', 'longitudeOfFirstGridPointInDegrees') h.alias('Lo1', 'longitudeOfFirstGridPoint') h.add( _.Codeflag('resolutionAndComponentFlags', 1, "grib2/tables/[tablesVersion]/3.3.table")) h.add(_.Signed('LaD', 4)) h.alias('latitudeWhereDxAndDyAreSpecified', 'LaD') h.add( _.Scale('LaDInDegrees', _.Get('LaD'), _.Get('oneConstant'), _.Get('grib2divider'), _.Get('truncateDegrees'))) h.alias('geography.LaDInDegrees', 'LaDInDegrees') h.alias('latitudeWhereDxAndDyAreSpecifiedInDegrees', 'LaDInDegrees') h.add(_.Signed('orientationOfTheGrid', 4)) h.alias('LoV', 'orientationOfTheGrid') h.add( _.Scale('orientationOfTheGridInDegrees', _.Get('orientationOfTheGrid'), _.Get('oneConstant'), _.Get('grib2divider'), _.Get('truncateDegrees'))) h.alias('geography.orientationOfTheGridInDegrees', 'orientationOfTheGridInDegrees') h.add(_.Unsigned('Dx', 4)) h.add( _.Scale('DxInMetres', _.Get('Dx'), _.Get('one'), _.Get('thousand'), _.Get('truncateDegrees'))) h.alias('geography.DxInMetres', 'DxInMetres') h.alias('xDirectionGridLength', 'Dx') h.add(_.Unsigned('Dy', 4)) h.add( _.Scale('DyInMetres', _.Get('Dy'), _.Get('one'), _.Get('thousand'), _.Get('truncateDegrees'))) h.alias('geography.DyInMetres', 'DyInMetres') h.alias('yDirectionGridLength', 'Dy') h.add( _.Codeflag('projectionCentreFlag', 1, "grib2/tables/[tablesVersion]/3.5.table")) h.add(_.Bit('southPoleOnProjectionPlane', _.Get('projectionCentreFlag'), 7)) h.add( _.Codeflag('scanningMode', 1, "grib2/tables/[tablesVersion]/3.4.table")) h.add(_.Bit('iScansNegatively', _.Get('scanningMode'), 7)) h.add(_.Bit('jScansPositively', _.Get('scanningMode'), 6)) h.add(_.Bit('jPointsAreConsecutive', _.Get('scanningMode'), 5)) h.add(_.Bit('alternativeRowScanning', _.Get('scanningMode'), 4)) if h.get_l('jPointsAreConsecutive'): h.alias('numberOfRows', 'Ni') h.alias('numberOfColumns', 'Nj') else: h.alias('numberOfRows', 'Nj') h.alias('numberOfColumns', 'Ni') h.alias('geography.iScansNegatively', 'iScansNegatively') h.alias('geography.jScansPositively', 'jScansPositively') h.alias('geography.jPointsAreConsecutive', 'jPointsAreConsecutive') h.add(_.Transient('iScansPositively', _.Not(_.Get('iScansNegatively')))) h.add(_.Bit('scanningMode5', _.Get('scanningMode'), 3)) h.add(_.Bit('scanningMode6', _.Get('scanningMode'), 2)) h.add(_.Bit('scanningMode7', _.Get('scanningMode'), 1)) h.add(_.Bit('scanningMode8', _.Get('scanningMode'), 0)) h.add( _.Change_scanning_direction('swapScanningX', _.Get('values'), _.Get('Ni'), _.Get('Nj'), _.Get('iScansNegatively'), _.Get('jScansPositively'), _.Get('xFirst'), _.Get('xLast'), _.Get('x'))) h.alias('swapScanningLon', 'swapScanningX') h.add( _.Change_scanning_direction('swapScanningY', _.Get('values'), _.Get('Ni'), _.Get('Nj'), _.Get('iScansNegatively'), _.Get('jScansPositively'), _.Get('yFirst'), _.Get('yLast'), _.Get('y'))) h.alias('swapScanningLat', 'swapScanningY') h.add( _.Iterator('ITERATOR', _.Get('polar_stereographic'), _.Get('numberOfPoints'), _.Get('missingValue'), _.Get('values'), _.Get('radius'), _.Get('Nx'), _.Get('Ny'), _.Get('latitudeOfFirstGridPointInDegrees'), _.Get('longitudeOfFirstGridPointInDegrees'), _.Get('southPoleOnProjectionPlane'), _.Get('orientationOfTheGridInDegrees'), _.Get('LaDInDegrees'), _.Get('DxInMetres'), _.Get('DyInMetres'), _.Get('iScansNegatively'), _.Get('jScansPositively'), _.Get('jPointsAreConsecutive'), _.Get('alternativeRowScanning'))) h.add( _.Nearest('NEAREST', _.Get('polar_stereographic'), _.Get('values'), _.Get('radius'), _.Get('Nx'), _.Get('Ny'))) h.add(_.Latlonvalues('latLonValues', _.Get('values'))) h.alias('latitudeLongitudeValues', 'latLonValues') h.add(_.Latitudes('latitudes', _.Get('values'), 0)) h.add(_.Longitudes('longitudes', _.Get('values'), 0)) h.add(_.Unsigned('Nux', 4)) h.alias('numberOfUsefulPointsAlongXAxis', 'Nux') h.add(_.Unsigned('Ncx', 4)) h.alias('numberOfPointsAlongXAxisInCouplingArea', 'Ncx') h.add(_.Unsigned('Nuy', 4)) h.alias('numberOfUsefulPointsAlongYAxis', 'Nuy') h.add(_.Unsigned('Ncy', 4)) h.alias('numberOfPointsAlongYAxisInCouplingArea', 'Ncy')
def load(h): h.add(_.Codetable('shapeOfTheEarth', 1, "3.2.table", _.Get('masterDir'), _.Get('localDir'))) h.add(_.Unsigned('scaleFactorOfRadiusOfSphericalEarth', 1)) h.add(_.Unsigned('scaledValueOfRadiusOfSphericalEarth', 4)) h.add(_.Unsigned('scaleFactorOfEarthMajorAxis', 1)) h.alias('scaleFactorOfMajorAxisOfOblateSpheroidEarth', 'scaleFactorOfEarthMajorAxis') h.add(_.Unsigned('scaledValueOfEarthMajorAxis', 4)) h.alias('scaledValueOfMajorAxisOfOblateSpheroidEarth', 'scaledValueOfEarthMajorAxis') h.add(_.Unsigned('scaleFactorOfEarthMinorAxis', 1)) h.alias('scaleFactorOfMinorAxisOfOblateSpheroidEarth', 'scaleFactorOfEarthMinorAxis') h.add(_.Unsigned('scaledValueOfEarthMinorAxis', 4)) h.alias('scaledValueOfMinorAxisOfOblateSpheroidEarth', 'scaledValueOfEarthMinorAxis') h.alias('earthIsOblate', 'one') if (h.get_l('shapeOfTheEarth') == 0): h.add(_.Transient('radius', 6367470)) h.alias('radiusOfTheEarth', 'radius') h.alias('radiusInMetres', 'radius') h.alias('earthIsOblate', 'zero') if (h.get_l('shapeOfTheEarth') == 1): h.add(_.From_scale_factor_scaled_value('radius', _.Get('scaleFactorOfRadiusOfSphericalEarth'), _.Get('scaledValueOfRadiusOfSphericalEarth'))) h.alias('radiusOfTheEarth', 'radius') h.alias('radiusInMetres', 'radius') h.alias('earthIsOblate', 'zero') if (h.get_l('shapeOfTheEarth') == 6): h.add(_.Transient('radius', 6371229)) h.alias('radiusOfTheEarth', 'radius') h.alias('radiusInMetres', 'radius') h.alias('earthIsOblate', 'zero') if (h.get_l('shapeOfTheEarth') == 8): h.add(_.Transient('radius', 6371200)) h.alias('radiusOfTheEarth', 'radius') h.alias('radiusInMetres', 'radius') h.alias('earthIsOblate', 'zero') if (h.get_l('shapeOfTheEarth') == 2): h.add(_.Transient('earthMajorAxis', 6.37816e+06)) h.add(_.Transient('earthMinorAxis', 6.35678e+06)) h.alias('earthMajorAxisInMetres', 'earthMajorAxis') h.alias('earthMinorAxisInMetres', 'earthMinorAxis') if (h.get_l('shapeOfTheEarth') == 3): h.add(_.From_scale_factor_scaled_value('earthMajorAxis', _.Get('scaleFactorOfEarthMajorAxis'), _.Get('scaledValueOfEarthMajorAxis'))) h.add(_.From_scale_factor_scaled_value('earthMinorAxis', _.Get('scaleFactorOfEarthMinorAxis'), _.Get('scaledValueOfEarthMinorAxis'))) h.add(_.Divdouble('earthMajorAxisInMetres', _.Get('earthMajorAxis'), 0.001)) h.add(_.Divdouble('earthMinorAxisInMetres', _.Get('earthMinorAxis'), 0.001)) if (h.get_l('shapeOfTheEarth') == 7): h.add(_.From_scale_factor_scaled_value('earthMajorAxis', _.Get('scaleFactorOfEarthMajorAxis'), _.Get('scaledValueOfEarthMajorAxis'))) h.add(_.From_scale_factor_scaled_value('earthMinorAxis', _.Get('scaleFactorOfEarthMinorAxis'), _.Get('scaledValueOfEarthMinorAxis'))) h.alias('earthMajorAxisInMetres', 'earthMajorAxis') h.alias('earthMinorAxisInMetres', 'earthMinorAxis') if ((h.get_l('shapeOfTheEarth') == 4) or (h.get_l('shapeOfTheEarth') == 5)): h.add(_.Transient('earthMajorAxis', 6.37814e+06)) h.add(_.Transient('earthMinorAxis', 6.35675e+06)) h.alias('earthMajorAxisInMetres', 'earthMajorAxis') h.alias('earthMinorAxisInMetres', 'earthMinorAxis') if (h.get_l('shapeOfTheEarth') == 9): h.add(_.Transient('earthMajorAxis', 6.37756e+06)) h.add(_.Transient('earthMinorAxis', 6.35626e+06)) h.alias('earthMajorAxisInMetres', 'earthMajorAxis') h.alias('earthMinorAxisInMetres', 'earthMinorAxis') h.add(_.Unsigned('numberOfPointsAlongXAxis', 4)) h.alias('Nx', 'numberOfPointsAlongXAxis') h.alias('Ni', 'Nx') h.add(_.Unsigned('numberOfPointsAlongYAxis', 4)) h.alias('Ny', 'numberOfPointsAlongYAxis') h.alias('Nj', 'Ny') h.add(_.Signed('latitudeOfFirstGridPoint', 4)) h.alias('La1', 'latitudeOfFirstGridPoint') h.add(_.Scale('latitudeOfFirstGridPointInDegrees', _.Get('latitudeOfFirstGridPoint'), _.Get('one'), _.Get('grib2divider'), _.Get('truncateDegrees'))) h.alias('geography.latitudeOfFirstGridPointInDegrees', 'latitudeOfFirstGridPointInDegrees') h.add(_.Signed('longitudeOfFirstGridPoint', 4)) h.alias('La1', 'longitudeOfFirstGridPoint') h.add(_.Scale('longitudeOfFirstGridPointInDegrees', _.Get('longitudeOfFirstGridPoint'), _.Get('one'), _.Get('grib2divider'), _.Get('truncateDegrees'))) h.alias('geography.longitudeOfFirstGridPointInDegrees', 'longitudeOfFirstGridPointInDegrees') h.add(_.Signed('standardParallelInMicrodegrees', 4)) h.alias('standardParallel', 'standardParallelInMicrodegrees') h.add(_.Scale('standardParallelInDegrees', _.Get('standardParallelInMicrodegrees'), _.Get('one'), _.Get('grib2divider'), _.Get('truncateDegrees'))) h.alias('geography.standardParallelInDegrees', 'standardParallelInDegrees') h.add(_.Signed('centralLongitudeInMicrodegrees', 4)) h.alias('centralLongitude', 'centralLongitudeInMicrodegrees') h.add(_.Scale('centralLongitudeInDegrees', _.Get('centralLongitudeInMicrodegrees'), _.Get('one'), _.Get('grib2divider'), _.Get('truncateDegrees'))) h.alias('geography.centralLongitudeInDegrees', 'centralLongitudeInDegrees') h.add(_.Codeflag('resolutionAndComponentFlags', 1, "grib2/tables/[tablesVersion]/3.3.table")) h.add(_.Unsigned('xDirectionGridLengthInMillimetres', 4)) h.alias('Dx', 'xDirectionGridLengthInMillimetres') h.add(_.Scale('xDirectionGridLengthInMetres', _.Get('xDirectionGridLengthInMillimetres'), _.Get('one'), _.Get('thousand'), _.Get('truncateDegrees'))) h.alias('geography.xDirectionGridLengthInMetres', 'xDirectionGridLengthInMetres') h.add(_.Unsigned('yDirectionGridLengthInMillimetres', 4)) h.alias('Dy', 'yDirectionGridLengthInMillimetres') h.add(_.Scale('yDirectionGridLengthInMetres', _.Get('yDirectionGridLengthInMillimetres'), _.Get('one'), _.Get('thousand'), _.Get('truncateDegrees'))) h.alias('geography.yDirectionGridLengthInMetres', 'yDirectionGridLengthInMetres') h.add(_.Codeflag('scanningMode', 1, "grib2/tables/[tablesVersion]/3.4.table")) h.add(_.Bit('iScansNegatively', _.Get('scanningMode'), 7)) h.add(_.Bit('jScansPositively', _.Get('scanningMode'), 6)) h.add(_.Bit('jPointsAreConsecutive', _.Get('scanningMode'), 5)) h.add(_.Bit('alternativeRowScanning', _.Get('scanningMode'), 4)) if h.get_l('jPointsAreConsecutive'): h.alias('numberOfRows', 'Ni') h.alias('numberOfColumns', 'Nj') else: h.alias('numberOfRows', 'Nj') h.alias('numberOfColumns', 'Ni') h.alias('geography.iScansNegatively', 'iScansNegatively') h.alias('geography.jScansPositively', 'jScansPositively') h.alias('geography.jPointsAreConsecutive', 'jPointsAreConsecutive') h.add(_.Transient('iScansPositively', _.Not(_.Get('iScansNegatively')))) h.add(_.Bit('scanningMode5', _.Get('scanningMode'), 3)) h.add(_.Bit('scanningMode6', _.Get('scanningMode'), 2)) h.add(_.Bit('scanningMode7', _.Get('scanningMode'), 1)) h.add(_.Bit('scanningMode8', _.Get('scanningMode'), 0)) h.add(_.Change_scanning_direction('swapScanningX', _.Get('values'), _.Get('Ni'), _.Get('Nj'), _.Get('iScansNegatively'), _.Get('jScansPositively'), _.Get('xFirst'), _.Get('xLast'), _.Get('x'))) h.alias('swapScanningLon', 'swapScanningX') h.add(_.Change_scanning_direction('swapScanningY', _.Get('values'), _.Get('Ni'), _.Get('Nj'), _.Get('iScansNegatively'), _.Get('jScansPositively'), _.Get('yFirst'), _.Get('yLast'), _.Get('y'))) h.alias('swapScanningLat', 'swapScanningY') h.add(_.Iterator('ITERATOR', _.Get('lambert_azimuthal_equal_area'), _.Get('numberOfPoints'), _.Get('missingValue'), _.Get('values'), _.Get('radius'), _.Get('Nx'), _.Get('Ny'), _.Get('latitudeOfFirstGridPointInDegrees'), _.Get('longitudeOfFirstGridPointInDegrees'), _.Get('standardParallel'), _.Get('centralLongitude'), _.Get('Dx'), _.Get('Dy'), _.Get('iScansNegatively'), _.Get('jScansPositively'), _.Get('jPointsAreConsecutive'), _.Get('alternativeRowScanning'))) h.add(_.Latlonvalues('latLonValues', _.Get('values'))) h.alias('latitudeLongitudeValues', 'latLonValues') h.add(_.Latitudes('latitudes', _.Get('values'), 0)) h.add(_.Longitudes('longitudes', _.Get('values'), 0)) h.add(_.Latitudes('distinctLatitudes', _.Get('values'), 1)) h.add(_.Longitudes('distinctLongitudes', _.Get('values'), 1))
def load(h): h.add( _.Codetable('shapeOfTheEarth', 1, "3.2.table", _.Get('masterDir'), _.Get('localDir'))) h.add(_.Unsigned('scaleFactorOfRadiusOfSphericalEarth', 1)) h.add(_.Unsigned('scaledValueOfRadiusOfSphericalEarth', 4)) h.add(_.Unsigned('scaleFactorOfEarthMajorAxis', 1)) h.alias('scaleFactorOfMajorAxisOfOblateSpheroidEarth', 'scaleFactorOfEarthMajorAxis') h.add(_.Unsigned('scaledValueOfEarthMajorAxis', 4)) h.alias('scaledValueOfMajorAxisOfOblateSpheroidEarth', 'scaledValueOfEarthMajorAxis') h.add(_.Unsigned('scaleFactorOfEarthMinorAxis', 1)) h.alias('scaleFactorOfMinorAxisOfOblateSpheroidEarth', 'scaleFactorOfEarthMinorAxis') h.add(_.Unsigned('scaledValueOfEarthMinorAxis', 4)) h.alias('scaledValueOfMinorAxisOfOblateSpheroidEarth', 'scaledValueOfEarthMinorAxis') h.alias('earthIsOblate', 'one') if (h.get_l('shapeOfTheEarth') == 0): h.add(_.Transient('radius', 6367470)) h.alias('radiusOfTheEarth', 'radius') h.alias('radiusInMetres', 'radius') h.alias('earthIsOblate', 'zero') if (h.get_l('shapeOfTheEarth') == 1): h.add( _.From_scale_factor_scaled_value( 'radius', _.Get('scaleFactorOfRadiusOfSphericalEarth'), _.Get('scaledValueOfRadiusOfSphericalEarth'))) h.alias('radiusOfTheEarth', 'radius') h.alias('radiusInMetres', 'radius') h.alias('earthIsOblate', 'zero') if (h.get_l('shapeOfTheEarth') == 6): h.add(_.Transient('radius', 6371229)) h.alias('radiusOfTheEarth', 'radius') h.alias('radiusInMetres', 'radius') h.alias('earthIsOblate', 'zero') if (h.get_l('shapeOfTheEarth') == 8): h.add(_.Transient('radius', 6371200)) h.alias('radiusOfTheEarth', 'radius') h.alias('radiusInMetres', 'radius') h.alias('earthIsOblate', 'zero') if (h.get_l('shapeOfTheEarth') == 2): h.add(_.Transient('earthMajorAxis', 6.37816e+06)) h.add(_.Transient('earthMinorAxis', 6.35678e+06)) h.alias('earthMajorAxisInMetres', 'earthMajorAxis') h.alias('earthMinorAxisInMetres', 'earthMinorAxis') if (h.get_l('shapeOfTheEarth') == 3): h.add( _.From_scale_factor_scaled_value( 'earthMajorAxis', _.Get('scaleFactorOfEarthMajorAxis'), _.Get('scaledValueOfEarthMajorAxis'))) h.add( _.From_scale_factor_scaled_value( 'earthMinorAxis', _.Get('scaleFactorOfEarthMinorAxis'), _.Get('scaledValueOfEarthMinorAxis'))) h.add( _.Divdouble('earthMajorAxisInMetres', _.Get('earthMajorAxis'), 0.001)) h.add( _.Divdouble('earthMinorAxisInMetres', _.Get('earthMinorAxis'), 0.001)) if (h.get_l('shapeOfTheEarth') == 7): h.add( _.From_scale_factor_scaled_value( 'earthMajorAxis', _.Get('scaleFactorOfEarthMajorAxis'), _.Get('scaledValueOfEarthMajorAxis'))) h.add( _.From_scale_factor_scaled_value( 'earthMinorAxis', _.Get('scaleFactorOfEarthMinorAxis'), _.Get('scaledValueOfEarthMinorAxis'))) h.alias('earthMajorAxisInMetres', 'earthMajorAxis') h.alias('earthMinorAxisInMetres', 'earthMinorAxis') if ((h.get_l('shapeOfTheEarth') == 4) or (h.get_l('shapeOfTheEarth') == 5)): h.add(_.Transient('earthMajorAxis', 6.37814e+06)) h.add(_.Transient('earthMinorAxis', 6.35675e+06)) h.alias('earthMajorAxisInMetres', 'earthMajorAxis') h.alias('earthMinorAxisInMetres', 'earthMinorAxis') if (h.get_l('shapeOfTheEarth') == 9): h.add(_.Transient('earthMajorAxis', 6.37756e+06)) h.add(_.Transient('earthMinorAxis', 6.35626e+06)) h.alias('earthMajorAxisInMetres', 'earthMajorAxis') h.alias('earthMinorAxisInMetres', 'earthMinorAxis') h.add(_.Unsigned('numberOfHorizontalPoints', 5)) h.add(_.Unsigned('basicAngleOfTheInitialProductionDomain', 4)) h.add(_.Unsigned('subdivisionsOfBasicAngle', 4)) h.add(_.Signed('latitudeOfFirstGridPoint', 4)) h.alias('La1', 'latitudeOfFirstGridPoint') h.add(_.Unsigned('longitudeOfFirstGridPoint', 4)) h.alias('Lo1', 'longitudeOfFirstGridPoint') h.add( _.Codeflag('scanningMode', 1, "grib2/tables/[tablesVersion]/3.4.table")) h.add(_.Bit('iScansNegatively', _.Get('scanningMode'), 7)) h.add(_.Bit('jScansPositively', _.Get('scanningMode'), 6)) h.add(_.Bit('jPointsAreConsecutive', _.Get('scanningMode'), 5)) h.add(_.Bit('alternativeRowScanning', _.Get('scanningMode'), 4)) if h.get_l('jPointsAreConsecutive'): h.alias('numberOfRows', 'Ni') h.alias('numberOfColumns', 'Nj') else: h.alias('numberOfRows', 'Nj') h.alias('numberOfColumns', 'Ni') h.alias('geography.iScansNegatively', 'iScansNegatively') h.alias('geography.jScansPositively', 'jScansPositively') h.alias('geography.jPointsAreConsecutive', 'jPointsAreConsecutive') h.add(_.Transient('iScansPositively', _.Not(_.Get('iScansNegatively')))) h.add(_.Bit('scanningMode5', _.Get('scanningMode'), 3)) h.add(_.Bit('scanningMode6', _.Get('scanningMode'), 2)) h.add(_.Bit('scanningMode7', _.Get('scanningMode'), 1)) h.add(_.Bit('scanningMode8', _.Get('scanningMode'), 0)) h.add( _.Change_scanning_direction('swapScanningX', _.Get('values'), _.Get('Ni'), _.Get('Nj'), _.Get('iScansNegatively'), _.Get('jScansPositively'), _.Get('xFirst'), _.Get('xLast'), _.Get('x'))) h.alias('swapScanningLon', 'swapScanningX') h.add( _.Change_scanning_direction('swapScanningY', _.Get('values'), _.Get('Ni'), _.Get('Nj'), _.Get('iScansNegatively'), _.Get('jScansPositively'), _.Get('yFirst'), _.Get('yLast'), _.Get('y'))) h.alias('swapScanningLat', 'swapScanningY') h.add(_.Signed('latitudeOfLastGridPoint', 4)) h.alias('La2', 'latitudeOfLastGridPoint') h.add(_.Unsigned('longitudeOfLastGridPoint', 4)) h.alias('Lo2', 'longitudeOfLastGridPoint') h.add( _.Codetable('typeOfHorizontalLine', 1, "3.20.table", _.Get('masterDir'), _.Get('localDir'))) h.add(_.Unsigned('numberOfTimeSteps', 4)) h.alias('NT', 'numberOfTimeSteps') h.add( _.Codetable('unitOfOffsetFromReferenceTime', 1, "4.4.table", _.Get('masterDir'), _.Get('localDir'))) h.add(_.Unsigned('offsetFromReferenceOfFirstTime', 4)) h.add( _.Codetable('typeOfTimeIncrement', 1, "4.11.table", _.Get('masterDir'), _.Get('localDir'))) h.add( _.Codetable('unitOfTimeIncrement', 1, "4.4.table", _.Get('masterDir'), _.Get('localDir'))) h.add(_.Unsigned('timeIncrement', 4)) h.add(_.Unsigned('year', 2)) h.add(_.Unsigned('month', 1)) h.add(_.Unsigned('day', 1)) h.add(_.Unsigned('hour', 1)) h.add(_.Unsigned('minute', 1)) h.add(_.Unsigned('second', 1))
def load(h): h.add( _.Codetable('parameterCategory', 1, "4.1.[discipline:l].table", _.Get('masterDir'), _.Get('localDir'))) h.add( _.Codetable('parameterNumber', 1, "4.2.[discipline:l].[parameterCategory:l].table", _.Get('masterDir'), _.Get('localDir'))) h.add(_.Codetable_units('parameterUnits', _.Get('parameterNumber'))) h.add(_.Codetable_title('parameterName', _.Get('parameterNumber'))) h.add( _.Codetable('typeOfGeneratingProcess', 1, "4.3.table", _.Get('masterDir'), _.Get('localDir'))) h.add(_.Unsigned('backgroundProcess', 1)) h.alias('backgroundGeneratingProcessIdentifier', 'backgroundProcess') h.add(_.Unsigned('generatingProcessIdentifier', 1)) h.add(_.Unsigned('hoursAfterDataCutoff', 2)) h.alias('hoursAfterReferenceTimeOfDataCutoff', 'hoursAfterDataCutoff') h.add(_.Unsigned('minutesAfterDataCutoff', 1)) h.alias('minutesAfterReferenceTimeOfDataCutoff', 'minutesAfterDataCutoff') h.add( _.Codetable('indicatorOfUnitOfTimeRange', 1, "4.4.table", _.Get('masterDir'), _.Get('localDir'))) h.alias('defaultStepUnits', 'one') _.Template('grib2/localConcepts/[centre:s]/default_step_units.def', True).load(h) h.add(_.TransientCodetable('stepUnits', 1, "stepUnits.table")) h.add(_.Signed('forecastTime', 4)) h.add( _.Step_in_units('startStep', _.Get('forecastTime'), _.Get('indicatorOfUnitOfTimeRange'), _.Get('stepUnits'))) h.add(_.G2end_step('endStep', _.Get('startStep'), _.Get('stepUnits'))) h.alias('step', 'startStep') h.alias('marsStep', 'startStep') h.alias('mars.step', 'startStep') h.alias('marsStartStep', 'startStep') h.alias('marsEndStep', 'endStep') h.add(_.G2step_range('stepRange', _.Get('startStep'))) h.alias('ls.stepRange', 'stepRange') def stepTypeInternal_inline_concept(h): def wrapped(h): dummy = h.get_l('dummy') if dummy == 1: return 'instant' return wrapped h.add( _.Concept('stepTypeInternal', None, concepts=stepTypeInternal_inline_concept(h))) h.alias('time.stepType', 'stepType') h.alias('time.stepRange', 'stepRange') h.alias('time.stepUnits', 'stepUnits') h.alias('time.dataDate', 'dataDate') h.alias('time.dataTime', 'dataTime') h.alias('time.startStep', 'startStep') h.alias('time.endStep', 'endStep') h.add( _.Validity_date('validityDate', _.Get('dataDate'), _.Get('dataTime'), _.Get('step'), _.Get('stepUnits'))) h.alias('time.validityDate', 'validityDate') h.add( _.Validity_time('validityTime', _.Get('dataDate'), _.Get('dataTime'), _.Get('step'), _.Get('stepUnits'))) h.alias('time.validityTime', 'validityTime') h.add( _.StringCodetable('typeOfFirstFixedSurface', 1, "4.5.table", _.Get('masterDir'), _.Get('localDir'))) h.add( _.Codetable_units('unitsOfFirstFixedSurface', _.Get('typeOfFirstFixedSurface'))) h.add( _.Codetable_title('nameOfFirstFixedSurface', _.Get('typeOfFirstFixedSurface'))) h.add(_.Signed('scaleFactorOfFirstFixedSurface', 1)) h.add(_.Unsigned('scaledValueOfFirstFixedSurface', 4)) h.add( _.Codetable('typeOfSecondFixedSurface', 1, "4.5.table", _.Get('masterDir'), _.Get('localDir'))) h.add( _.Codetable_units('unitsOfSecondFixedSurface', _.Get('typeOfSecondFixedSurface'))) h.add( _.Codetable_title('nameOfSecondFixedSurface', _.Get('typeOfSecondFixedSurface'))) h.add(_.Signed('scaleFactorOfSecondFixedSurface', 1)) h.add(_.Unsigned('scaledValueOfSecondFixedSurface', 4)) h.add(_.Transient('pressureUnits', "hPa")) def typeOfLevel_inline_concept(h): def wrapped(h): typeOfFirstFixedSurface = h.get_l('typeOfFirstFixedSurface') typeOfSecondFixedSurface = h.get_l('typeOfSecondFixedSurface') if typeOfFirstFixedSurface == 1 and typeOfSecondFixedSurface == 255: return 'surface' if typeOfFirstFixedSurface == 2 and typeOfSecondFixedSurface == 255: return 'cloudBase' if typeOfFirstFixedSurface == 3 and typeOfSecondFixedSurface == 255: return 'cloudTop' if typeOfFirstFixedSurface == 4 and typeOfSecondFixedSurface == 255: return 'isothermZero' if typeOfFirstFixedSurface == 5 and typeOfSecondFixedSurface == 255: return 'adiabaticCondensation' if typeOfFirstFixedSurface == 6 and typeOfSecondFixedSurface == 255: return 'maxWind' if typeOfFirstFixedSurface == 7 and typeOfSecondFixedSurface == 255: return 'tropopause' if typeOfFirstFixedSurface == 8 and typeOfSecondFixedSurface == 255: return 'nominalTop' if typeOfFirstFixedSurface == 9 and typeOfSecondFixedSurface == 255: return 'seaBottom' if typeOfFirstFixedSurface == 10 and typeOfSecondFixedSurface == 255: return 'atmosphere' if typeOfFirstFixedSurface == 20 and typeOfSecondFixedSurface == 255: return 'isothermal' pressureUnits = h.get_s('pressureUnits') if typeOfFirstFixedSurface == 100 and typeOfSecondFixedSurface == 255 and pressureUnits == "Pa": return 'isobaricInPa' if typeOfFirstFixedSurface == 100 and pressureUnits == "hPa" and typeOfSecondFixedSurface == 255: return 'isobaricInhPa' if typeOfFirstFixedSurface == 100 and typeOfSecondFixedSurface == 100: return 'isobaricLayer' if typeOfFirstFixedSurface == 101 and typeOfSecondFixedSurface == 255: return 'meanSea' if typeOfFirstFixedSurface == 102 and typeOfSecondFixedSurface == 255: return 'heightAboveSea' if typeOfFirstFixedSurface == 102 and typeOfSecondFixedSurface == 102: return 'heightAboveSeaLayer' if typeOfFirstFixedSurface == 103 and typeOfSecondFixedSurface == 255: return 'heightAboveGround' if typeOfFirstFixedSurface == 103 and typeOfSecondFixedSurface == 103: return 'heightAboveGroundLayer' if typeOfFirstFixedSurface == 104 and typeOfSecondFixedSurface == 255: return 'sigma' if typeOfFirstFixedSurface == 104 and typeOfSecondFixedSurface == 104: return 'sigmaLayer' if typeOfFirstFixedSurface == 105 and typeOfSecondFixedSurface == 255: return 'hybrid' if typeOfFirstFixedSurface == 118 and typeOfSecondFixedSurface == 255: return 'hybridHeight' if typeOfFirstFixedSurface == 105 and typeOfSecondFixedSurface == 105: return 'hybridLayer' if typeOfFirstFixedSurface == 106 and typeOfSecondFixedSurface == 255: return 'depthBelowLand' if typeOfFirstFixedSurface == 106 and typeOfSecondFixedSurface == 106: return 'depthBelowLandLayer' if typeOfFirstFixedSurface == 107 and typeOfSecondFixedSurface == 255: return 'theta' if typeOfFirstFixedSurface == 107 and typeOfSecondFixedSurface == 107: return 'thetaLayer' if typeOfFirstFixedSurface == 108 and typeOfSecondFixedSurface == 255: return 'pressureFromGround' if typeOfFirstFixedSurface == 108 and typeOfSecondFixedSurface == 108: return 'pressureFromGroundLayer' if typeOfFirstFixedSurface == 109 and typeOfSecondFixedSurface == 255: return 'potentialVorticity' if typeOfFirstFixedSurface == 111 and typeOfSecondFixedSurface == 255: return 'eta' if typeOfFirstFixedSurface == 151 and typeOfSecondFixedSurface == 255: return 'soil' if typeOfFirstFixedSurface == 151 and typeOfSecondFixedSurface == 151: return 'soilLayer' genVertHeightCoords = h.get_l('genVertHeightCoords') NV = h.get_l('NV') if genVertHeightCoords == 1 and typeOfFirstFixedSurface == 150 and NV == 6: return 'generalVertical' if genVertHeightCoords == 1 and typeOfFirstFixedSurface == 150 and typeOfSecondFixedSurface == 150 and NV == 6: return 'generalVerticalLayer' if typeOfFirstFixedSurface == 160 and typeOfSecondFixedSurface == 255: return 'depthBelowSea' if typeOfFirstFixedSurface == 1 and typeOfSecondFixedSurface == 8: return 'entireAtmosphere' if typeOfFirstFixedSurface == 1 and typeOfSecondFixedSurface == 9: return 'entireOcean' if typeOfFirstFixedSurface == 114 and typeOfSecondFixedSurface == 255: return 'snow' if typeOfFirstFixedSurface == 114 and typeOfSecondFixedSurface == 114: return 'snowLayer' scaleFactorOfFirstFixedSurface = h.get_l( 'scaleFactorOfFirstFixedSurface') scaledValueOfFirstFixedSurface = h.get_l( 'scaledValueOfFirstFixedSurface') if typeOfFirstFixedSurface == 160 and scaleFactorOfFirstFixedSurface == 0 and scaledValueOfFirstFixedSurface == 0 and typeOfSecondFixedSurface == 255: return 'oceanSurface' if typeOfFirstFixedSurface == 160 and typeOfSecondFixedSurface == 160: return 'oceanLayer' if typeOfFirstFixedSurface == 169 and typeOfSecondFixedSurface == 255: return 'mixedLayerDepth' return wrapped h.add( _.Concept('typeOfLevel', 'unknown', concepts=typeOfLevel_inline_concept(h))) h.alias('vertical.typeOfLevel', 'typeOfLevel') h.alias('levelType', 'typeOfFirstFixedSurface') if (h.get_l('typeOfSecondFixedSurface') == 255): h.add( _.G2level('level', _.Get('typeOfFirstFixedSurface'), _.Get('scaleFactorOfFirstFixedSurface'), _.Get('scaledValueOfFirstFixedSurface'), _.Get('pressureUnits'))) h.add(_.Transient('bottomLevel', _.Get('level'))) h.add(_.Transient('topLevel', _.Get('level'))) else: h.add( _.G2level('topLevel', _.Get('typeOfFirstFixedSurface'), _.Get('scaleFactorOfFirstFixedSurface'), _.Get('scaledValueOfFirstFixedSurface'), _.Get('pressureUnits'))) h.add( _.G2level('bottomLevel', _.Get('typeOfSecondFixedSurface'), _.Get('scaleFactorOfSecondFixedSurface'), _.Get('scaledValueOfSecondFixedSurface'), _.Get('pressureUnits'))) h.alias('level', 'topLevel') h.alias('ls.level', 'level') h.alias('vertical.level', 'level') h.alias('vertical.bottomLevel', 'bottomLevel') h.alias('vertical.topLevel', 'topLevel') h.alias('extraDim', 'zero') if h._defined('extraDimensionPresent'): if h.get_l('extraDimensionPresent'): h.alias('extraDim', 'one') if h.get_l('extraDim'): h.alias('mars.levelist', 'dimension') h.alias('mars.levtype', 'dimensionType') else: h.add(_.Transient('tempPressureUnits', _.Get('pressureUnits'))) if not ((h.get_s('typeOfLevel') == "surface")): if (h.get_s('tempPressureUnits') == "Pa"): h.add( _.Scale('marsLevel', _.Get('level'), _.Get('one'), _.Get('hundred'))) h.alias('mars.levelist', 'marsLevel') else: h.alias('mars.levelist', 'level') h.alias('mars.levtype', 'typeOfFirstFixedSurface') if (h.get_s('levtype') == "sfc"): h.unalias('mars.levelist') if ((h.get_l('typeOfFirstFixedSurface') == 151) and (h.get_l('typeOfSecondFixedSurface') == 151)): h.alias('mars.levelist', 'bottomLevel') h.alias('ls.typeOfLevel', 'typeOfLevel') h.add(_.Unsigned('forecastProbabilityNumber', 1)) h.add(_.Unsigned('totalNumberOfForecastProbabilities', 1)) h.add( _.Codetable('probabilityType', 1, "4.9.table", _.Get('masterDir'), _.Get('localDir'))) h.add(_.Codetable_title('probabilityTypeName', _.Get('probabilityType'))) h.add(_.Signed('scaleFactorOfLowerLimit', 1)) h.add(_.Signed('scaledValueOfLowerLimit', 4)) h.add( _.From_scale_factor_scaled_value('lowerLimit', _.Get('scaleFactorOfLowerLimit'), _.Get('scaledValueOfLowerLimit'))) h.add(_.Signed('scaleFactorOfUpperLimit', 1)) h.add(_.Signed('scaledValueOfUpperLimit', 4)) h.add( _.From_scale_factor_scaled_value('upperLimit', _.Get('scaleFactorOfUpperLimit'), _.Get('scaledValueOfUpperLimit')))