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')
def load(h):
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')
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('aerosolType', 2, "4.233.table", _.Get('masterDir'),
_.Get('localDir')))
h.add(
_.Codetable('sourceSinkChemicalPhysicalProcess', 1, "4.238.table",
_.Get('masterDir'), _.Get('localDir')))
h.add(
_.Codetable('typeOfSizeInterval', 1, "4.91.table", _.Get('masterDir'),
_.Get('localDir')))
h.alias('typeOfIntervalForFirstAndSecondSize', 'typeOfSizeInterval')
h.add(_.Signed('scaleFactorOfFirstSize', 1))
h.add(_.Signed('scaledValueOfFirstSize', 4))
h.add(_.Signed('scaleFactorOfSecondSize', 1))
h.add(_.Signed('scaledValueOfSecondSize', 4))
h.add(
_.Codetable('typeOfWavelengthInterval', 1, "4.91.table",
_.Get('masterDir'), _.Get('localDir')))
h.alias('typeOfIntervalForFirstAndSecondWavelength',
'typeOfWavelengthInterval')
h.add(_.Signed('scaleFactorOfFirstWavelength', 1))
h.add(_.Signed('scaledValueOfFirstWavelength', 4))
h.add(_.Signed('scaleFactorOfSecondWavelength', 1))
h.add(_.Signed('scaledValueOfSecondWavelength', 4))
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(
_.Codetable('typeOfEnsembleForecast', 1, "4.6.table",
_.Get('masterDir'), _.Get('localDir')))
h.add(_.Unsigned('perturbationNumber', 1))
h.alias('number', 'perturbationNumber')
h.add(_.Unsigned('numberOfForecastsInEnsemble', 1))
h.alias('totalNumber', 'numberOfForecastsInEnsemble')
if ((((((((h.get_l('productionStatusOfProcessedData') == 4) or
(h.get_l('productionStatusOfProcessedData') == 5)) or
(h.get_l('productionStatusOfProcessedData') == 6)) or
(h.get_l('productionStatusOfProcessedData') == 7)) or
(h.get_l('productionStatusOfProcessedData') == 8)) or
(h.get_l('productionStatusOfProcessedData') == 9)) or
(h.get_l('productionStatusOfProcessedData') == 10))
or (h.get_l('productionStatusOfProcessedData') == 11)):
h.alias('mars.number', 'perturbationNumber')
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(
_.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(
_.Codetable('derivedForecast', 1, "4.7.table", _.Get('masterDir'),
_.Get('localDir')))
h.add(_.Unsigned('numberOfForecastsInEnsemble', 1))
h.alias('totalNumber', 'numberOfForecastsInEnsemble')
h.add(_.Unsigned('clusterIdentifier', 1))
h.alias('number', 'clusterIdentifier')
h.add(_.Unsigned('numberOfClusterHighResolution', 1))
h.add(_.Unsigned('numberOfClusterLowResolution', 1))
h.add(_.Unsigned('totalNumberOfClusters', 1))
h.alias('totalNumber', 'totalNumberOfClusters')
h.add(
_.Codetable('clusteringMethod', 1, "4.8.table", _.Get('masterDir'),
_.Get('localDir')))
h.add(_.Unsigned('latitudeOfCentralPointInClusterDomain', 4))
h.add(_.Unsigned('longitudeOfCentralPointInClusterDomain', 4))
h.add(_.Unsigned('radiusOfClusterDomain', 4))
h.add(_.Unsigned('numberOfForecastsInTheCluster', 1))
h.alias('NC', 'numberOfForecastsInTheCluster')
h.add(_.Unsigned('scaleFactorOfStandardDeviation', 1))
h.alias('scaleFactorOfStandardDeviationInTheCluster',
'scaleFactorOfStandardDeviation')
h.add(_.Unsigned('scaledValueOfStandardDeviation', 4))
h.alias('scaledValueOfStandardDeviationInTheCluster',
'scaledValueOfStandardDeviation')
h.add(_.Unsigned('scaleFactorOfDistanceFromEnsembleMean', 1))
h.add(_.Unsigned('scaleFactorOfDistanceFromEnsembleMean', 4))
h.add(_.Unsigned('yearOfEndOfOverallTimeInterval', 2))
h.add(_.Unsigned('monthOfEndOfOverallTimeInterval', 1))
h.add(_.Unsigned('dayOfEndOfOverallTimeInterval', 1))
h.add(_.Unsigned('hourOfEndOfOverallTimeInterval', 1))
h.add(_.Unsigned('minuteOfEndOfOverallTimeInterval', 1))
h.add(_.Unsigned('secondOfEndOfOverallTimeInterval', 1))
h.add(_.Unsigned('numberOfTimeRange', 1))
h.alias('n', 'numberOfTimeRange')
h.add(_.Unsigned('numberOfMissingInStatisticalProcess', 4))
h.alias('totalNumberOfDataValuesMissingInStatisticalProcess',
'numberOfMissingInStatisticalProcess')
with h.list('statisticalProcessesList'):
for i in range(0, h.get_l('numberOfTimeRange')):
h.add(
_.Codetable('typeOfStatisticalProcessing', 1, "4.10.table",
_.Get('masterDir'), _.Get('localDir')))
h.add(
_.Codetable('typeOfTimeIncrement', 1, "4.11.table",
_.Get('masterDir'), _.Get('localDir')))
h.alias(
'typeOfTimeIncrementBetweenSuccessiveFieldsUsedInTheStatisticalProcessing',
'typeOfTimeIncrement')
h.add(
_.Codetable('indicatorOfUnitForTimeRange', 1, "4.4.table",
_.Get('masterDir'), _.Get('localDir')))
h.add(_.Unsigned('lengthOfTimeRange', 4))
h.add(
_.Codetable('indicatorOfUnitForTimeIncrement', 1, "4.4.table",
_.Get('masterDir'), _.Get('localDir')))
h.add(_.Unsigned('timeIncrement', 4))
h.alias('timeIncrementBetweenSuccessiveFields', 'timeIncrement')
if ((h.get_l('numberOfTimeRange') == 1)
or (h.get_l('numberOfTimeRange') == 2)):
def stepTypeInternal_inline_concept(h):
def wrapped(h):
typeOfStatisticalProcessing = h.get_l(
'typeOfStatisticalProcessing')
if typeOfStatisticalProcessing == 255:
return 'instant'
typeOfTimeIncrement = h.get_l('typeOfTimeIncrement')
if typeOfStatisticalProcessing == 0 and typeOfTimeIncrement == 2:
return 'avg'
if typeOfStatisticalProcessing == 0 and typeOfTimeIncrement == 3:
return 'avg'
if typeOfStatisticalProcessing == 0 and typeOfTimeIncrement == 1:
return 'avgd'
if typeOfStatisticalProcessing == 1 and typeOfTimeIncrement == 2:
return 'accum'
if typeOfStatisticalProcessing == 2:
return 'max'
if typeOfStatisticalProcessing == 3:
return 'min'
if typeOfStatisticalProcessing == 4:
return 'diff'
if typeOfStatisticalProcessing == 5:
return 'rms'
if typeOfStatisticalProcessing == 6:
return 'sd'
if typeOfStatisticalProcessing == 7:
return 'cov'
if typeOfStatisticalProcessing == 8:
return 'sdiff'
if typeOfStatisticalProcessing == 9:
return 'ratio'
if typeOfStatisticalProcessing == 10:
return 'stdanom'
if typeOfStatisticalProcessing == 11:
return 'sum'
return wrapped
h.add(
_.Concept('stepTypeInternal',
None,
concepts=stepTypeInternal_inline_concept(h)))
h.add(
_.Step_in_units('startStep', _.Get('forecastTime'),
_.Get('indicatorOfUnitOfTimeRange'),
_.Get('stepUnits'),
_.Get('indicatorOfUnitForTimeRange'),
_.Get('lengthOfTimeRange')))
h.add(
_.G2end_step('endStep', _.Get('startStep'), _.Get('stepUnits'),
_.Get('year'), _.Get('month'), _.Get('day'),
_.Get('hour'), _.Get('minute'), _.Get('second'),
_.Get('yearOfEndOfOverallTimeInterval'),
_.Get('monthOfEndOfOverallTimeInterval'),
_.Get('dayOfEndOfOverallTimeInterval'),
_.Get('hourOfEndOfOverallTimeInterval'),
_.Get('minuteOfEndOfOverallTimeInterval'),
_.Get('secondOfEndOfOverallTimeInterval'),
_.Get('indicatorOfUnitForTimeRange'),
_.Get('lengthOfTimeRange'),
_.Get('typeOfTimeIncrement'),
_.Get('numberOfTimeRange')))
h.add(_.G2step_range('stepRange', _.Get('startStep'),
_.Get('endStep')))
else:
h.add(_.Constant('stepType', "multiple steps"))
h.add(_.Constant('stepTypeInternal', "multiple steps"))
h.add(_.Constant('endStep', "unavailable"))
h.add(_.Constant('startStep', "unavailable"))
h.add(_.Constant('stepRange', "unavailable"))
h.alias('ls.stepRange', 'stepRange')
h.alias('mars.step', 'endStep')
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('date'), _.Get('dataTime'),
_.Get('step'), _.Get('stepUnits'),
_.Get('yearOfEndOfOverallTimeInterval'),
_.Get('monthOfEndOfOverallTimeInterval'),
_.Get('dayOfEndOfOverallTimeInterval')))
h.alias('time.validityDate', 'validityDate')
h.add(
_.Validity_time('validityTime', _.Get('date'), _.Get('dataTime'),
_.Get('step'), _.Get('stepUnits'),
_.Get('hourOfEndOfOverallTimeInterval'),
_.Get('minuteOfEndOfOverallTimeInterval')))
h.alias('time.validityTime', 'validityTime')
with h.list('ensembleForecastNumbersList'):
for i in range(0, h.get_l('numberOfForecastsInTheCluster')):
h.add(_.Unsigned('ensembleForecastNumbers', 1))
def load(h):
h.add(_.Unsigned('yearOfEndOfOverallTimeInterval', 2))
h.add(_.Unsigned('monthOfEndOfOverallTimeInterval', 1))
h.add(_.Unsigned('dayOfEndOfOverallTimeInterval', 1))
h.add(_.Unsigned('hourOfEndOfOverallTimeInterval', 1))
h.add(_.Unsigned('minuteOfEndOfOverallTimeInterval', 1))
h.add(_.Unsigned('secondOfEndOfOverallTimeInterval', 1))
h.add(_.Unsigned('numberOfTimeRange', 1))
h.alias('n', 'numberOfTimeRange')
h.add(_.Unsigned('numberOfMissingInStatisticalProcess', 4))
h.alias('totalNumberOfDataValuesMissingInStatisticalProcess',
'numberOfMissingInStatisticalProcess')
with h.list('statisticalProcessesList'):
for i in range(0, h.get_l('numberOfTimeRange')):
h.add(
_.Codetable('typeOfStatisticalProcessing', 1, "4.10.table",
_.Get('masterDir'), _.Get('localDir')))
h.add(
_.Codetable('typeOfTimeIncrement', 1, "4.11.table",
_.Get('masterDir'), _.Get('localDir')))
h.alias(
'typeOfTimeIncrementBetweenSuccessiveFieldsUsedInTheStatisticalProcessing',
'typeOfTimeIncrement')
h.add(
_.Codetable('indicatorOfUnitForTimeRange', 1, "4.4.table",
_.Get('masterDir'), _.Get('localDir')))
h.add(_.Unsigned('lengthOfTimeRange', 4))
h.add(
_.Codetable('indicatorOfUnitForTimeIncrement', 1, "4.4.table",
_.Get('masterDir'), _.Get('localDir')))
h.add(_.Unsigned('timeIncrement', 4))
h.alias('timeIncrementBetweenSuccessiveFields', 'timeIncrement')
if ((h.get_l('numberOfTimeRange') == 1)
or (h.get_l('numberOfTimeRange') == 2)):
def stepTypeInternal_inline_concept(h):
def wrapped(h):
typeOfStatisticalProcessing = h.get_l(
'typeOfStatisticalProcessing')
if typeOfStatisticalProcessing == 255:
return 'instant'
typeOfTimeIncrement = h.get_l('typeOfTimeIncrement')
if typeOfStatisticalProcessing == 0 and typeOfTimeIncrement == 2:
return 'avg'
if typeOfStatisticalProcessing == 0 and typeOfTimeIncrement == 3:
return 'avg'
if typeOfStatisticalProcessing == 0 and typeOfTimeIncrement == 1:
return 'avgd'
if typeOfStatisticalProcessing == 1 and typeOfTimeIncrement == 2:
return 'accum'
if typeOfStatisticalProcessing == 2:
return 'max'
if typeOfStatisticalProcessing == 3:
return 'min'
if typeOfStatisticalProcessing == 4:
return 'diff'
if typeOfStatisticalProcessing == 5:
return 'rms'
if typeOfStatisticalProcessing == 6:
return 'sd'
if typeOfStatisticalProcessing == 7:
return 'cov'
if typeOfStatisticalProcessing == 8:
return 'sdiff'
if typeOfStatisticalProcessing == 9:
return 'ratio'
if typeOfStatisticalProcessing == 10:
return 'stdanom'
if typeOfStatisticalProcessing == 11:
return 'sum'
return wrapped
h.add(
_.Concept('stepTypeInternal',
None,
concepts=stepTypeInternal_inline_concept(h)))
h.add(
_.Step_in_units('startStep', _.Get('forecastTime'),
_.Get('indicatorOfUnitOfTimeRange'),
_.Get('stepUnits'),
_.Get('indicatorOfUnitForTimeRange'),
_.Get('lengthOfTimeRange')))
h.add(
_.G2end_step('endStep', _.Get('startStep'), _.Get('stepUnits'),
_.Get('year'), _.Get('month'), _.Get('day'),
_.Get('hour'), _.Get('minute'), _.Get('second'),
_.Get('yearOfEndOfOverallTimeInterval'),
_.Get('monthOfEndOfOverallTimeInterval'),
_.Get('dayOfEndOfOverallTimeInterval'),
_.Get('hourOfEndOfOverallTimeInterval'),
_.Get('minuteOfEndOfOverallTimeInterval'),
_.Get('secondOfEndOfOverallTimeInterval'),
_.Get('indicatorOfUnitForTimeRange'),
_.Get('lengthOfTimeRange'),
_.Get('typeOfTimeIncrement'),
_.Get('numberOfTimeRange')))
h.add(_.G2step_range('stepRange', _.Get('startStep'),
_.Get('endStep')))
else:
h.add(_.Constant('stepType', "multiple steps"))
h.add(_.Constant('stepTypeInternal', "multiple steps"))
h.add(_.Constant('endStep', "unavailable"))
h.add(_.Constant('startStep', "unavailable"))
h.add(_.Constant('stepRange', "unavailable"))
h.alias('ls.stepRange', 'stepRange')
h.alias('mars.step', 'endStep')
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('date'), _.Get('dataTime'),
_.Get('step'), _.Get('stepUnits'),
_.Get('yearOfEndOfOverallTimeInterval'),
_.Get('monthOfEndOfOverallTimeInterval'),
_.Get('dayOfEndOfOverallTimeInterval')))
h.alias('time.validityDate', 'validityDate')
h.add(
_.Validity_time('validityTime', _.Get('date'), _.Get('dataTime'),
_.Get('step'), _.Get('stepUnits'),
_.Get('hourOfEndOfOverallTimeInterval'),
_.Get('minuteOfEndOfOverallTimeInterval')))
h.alias('time.validityTime', 'validityTime')
def load(h):
h.add(_.Constant('dataRepresentationType', 90))
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(_.Constant('typeOfLevel', "surface"))
h.add(_.Constant('levelType', "surface"))
h.add(_.Constant('level', 0))
h.add(_.Unsigned('NB', 1))
h.alias('numberOfContributingSpectralBands', 'NB')
with h.list('listOfContributingSpectralBands'):
for i in range(0, h.get_l('numberOfContributingSpectralBands')):
h.add(_.Unsigned('satelliteSeries', 2))
h.add(_.Unsigned('satelliteNumber', 2))
h.add(_.Unsigned('instrumentType', 2))
h.add(_.Unsigned('scaleFactorOfCentralWaveNumber', 1))
h.add(_.Unsigned('scaledValueOfCentralWaveNumber', 4))
h.add(
_.Codetable('typeOfEnsembleForecast', 1, "4.6.table",
_.Get('masterDir'), _.Get('localDir')))
h.add(_.Unsigned('perturbationNumber', 1))
h.alias('number', 'perturbationNumber')
h.add(_.Unsigned('numberOfForecastsInEnsemble', 1))
h.alias('totalNumber', 'numberOfForecastsInEnsemble')
if ((((((((h.get_l('productionStatusOfProcessedData') == 4) or
(h.get_l('productionStatusOfProcessedData') == 5)) or
(h.get_l('productionStatusOfProcessedData') == 6)) or
(h.get_l('productionStatusOfProcessedData') == 7)) or
(h.get_l('productionStatusOfProcessedData') == 8)) or
(h.get_l('productionStatusOfProcessedData') == 9)) or
(h.get_l('productionStatusOfProcessedData') == 10))
or (h.get_l('productionStatusOfProcessedData') == 11)):
h.alias('mars.number', 'perturbationNumber')
h.alias('instrument', 'instrumentType')
h.alias('ident', 'satelliteNumber')
def load(h):
h.add(_.Constant('dataRepresentationType', 90))
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(_.Constant('typeOfLevel', "surface"))
h.add(_.Constant('levelType', "surface"))
h.add(_.Constant('level', 0))
h.add(_.Unsigned('NB', 1))
h.alias('numberOfContributingSpectralBands', 'NB')
with h.list('listOfContributingSpectralBands'):
for i in range(0, h.get_l('numberOfContributingSpectralBands')):
h.add(_.Unsigned('satelliteSeries', 2))
h.add(_.Unsigned('satelliteNumber', 2))
h.add(_.Unsigned('instrumentType', 2))
h.add(_.Unsigned('scaleFactorOfCentralWaveNumber', 1))
h.add(_.Unsigned('scaledValueOfCentralWaveNumber', 4))
h.add(
_.Codetable('typeOfEnsembleForecast', 1, "4.6.table",
_.Get('masterDir'), _.Get('localDir')))
h.add(_.Unsigned('perturbationNumber', 1))
h.alias('number', 'perturbationNumber')
h.add(_.Unsigned('numberOfForecastsInEnsemble', 1))
h.alias('totalNumber', 'numberOfForecastsInEnsemble')
if ((((((((h.get_l('productionStatusOfProcessedData') == 4) or
(h.get_l('productionStatusOfProcessedData') == 5)) or
(h.get_l('productionStatusOfProcessedData') == 6)) or
(h.get_l('productionStatusOfProcessedData') == 7)) or
(h.get_l('productionStatusOfProcessedData') == 8)) or
(h.get_l('productionStatusOfProcessedData') == 9)) or
(h.get_l('productionStatusOfProcessedData') == 10))
or (h.get_l('productionStatusOfProcessedData') == 11)):
h.alias('mars.number', 'perturbationNumber')
h.add(_.Unsigned('yearOfEndOfOverallTimeInterval', 2))
h.add(_.Unsigned('monthOfEndOfOverallTimeInterval', 1))
h.add(_.Unsigned('dayOfEndOfOverallTimeInterval', 1))
h.add(_.Unsigned('hourOfEndOfOverallTimeInterval', 1))
h.add(_.Unsigned('minuteOfEndOfOverallTimeInterval', 1))
h.add(_.Unsigned('secondOfEndOfOverallTimeInterval', 1))
h.add(_.Unsigned('numberOfTimeRange', 1))
h.alias('n', 'numberOfTimeRange')
h.add(_.Unsigned('numberOfMissingInStatisticalProcess', 4))
h.alias('totalNumberOfDataValuesMissingInStatisticalProcess',
'numberOfMissingInStatisticalProcess')
with h.list('statisticalProcessesList'):
for i in range(0, h.get_l('numberOfTimeRange')):
h.add(
_.Codetable('typeOfStatisticalProcessing', 1, "4.10.table",
_.Get('masterDir'), _.Get('localDir')))
h.add(
_.Codetable('typeOfTimeIncrement', 1, "4.11.table",
_.Get('masterDir'), _.Get('localDir')))
h.alias(
'typeOfTimeIncrementBetweenSuccessiveFieldsUsedInTheStatisticalProcessing',
'typeOfTimeIncrement')
h.add(
_.Codetable('indicatorOfUnitForTimeRange', 1, "4.4.table",
_.Get('masterDir'), _.Get('localDir')))
h.add(_.Unsigned('lengthOfTimeRange', 4))
h.add(
_.Codetable('indicatorOfUnitForTimeIncrement', 1, "4.4.table",
_.Get('masterDir'), _.Get('localDir')))
h.add(_.Unsigned('timeIncrement', 4))
h.alias('timeIncrementBetweenSuccessiveFields', 'timeIncrement')
if ((h.get_l('numberOfTimeRange') == 1)
or (h.get_l('numberOfTimeRange') == 2)):
def stepTypeInternal_inline_concept(h):
def wrapped(h):
typeOfStatisticalProcessing = h.get_l(
'typeOfStatisticalProcessing')
if typeOfStatisticalProcessing == 255:
return 'instant'
typeOfTimeIncrement = h.get_l('typeOfTimeIncrement')
if typeOfStatisticalProcessing == 0 and typeOfTimeIncrement == 2:
return 'avg'
if typeOfStatisticalProcessing == 0 and typeOfTimeIncrement == 3:
return 'avg'
if typeOfStatisticalProcessing == 0 and typeOfTimeIncrement == 1:
return 'avgd'
if typeOfStatisticalProcessing == 1 and typeOfTimeIncrement == 2:
return 'accum'
if typeOfStatisticalProcessing == 2:
return 'max'
if typeOfStatisticalProcessing == 3:
return 'min'
if typeOfStatisticalProcessing == 4:
return 'diff'
if typeOfStatisticalProcessing == 5:
return 'rms'
if typeOfStatisticalProcessing == 6:
return 'sd'
if typeOfStatisticalProcessing == 7:
return 'cov'
if typeOfStatisticalProcessing == 8:
return 'sdiff'
if typeOfStatisticalProcessing == 9:
return 'ratio'
if typeOfStatisticalProcessing == 10:
return 'stdanom'
if typeOfStatisticalProcessing == 11:
return 'sum'
return wrapped
h.add(
_.Concept('stepTypeInternal',
None,
concepts=stepTypeInternal_inline_concept(h)))
h.add(
_.Step_in_units('startStep', _.Get('forecastTime'),
_.Get('indicatorOfUnitOfTimeRange'),
_.Get('stepUnits'),
_.Get('indicatorOfUnitForTimeRange'),
_.Get('lengthOfTimeRange')))
h.add(
_.G2end_step('endStep', _.Get('startStep'), _.Get('stepUnits'),
_.Get('year'), _.Get('month'), _.Get('day'),
_.Get('hour'), _.Get('minute'), _.Get('second'),
_.Get('yearOfEndOfOverallTimeInterval'),
_.Get('monthOfEndOfOverallTimeInterval'),
_.Get('dayOfEndOfOverallTimeInterval'),
_.Get('hourOfEndOfOverallTimeInterval'),
_.Get('minuteOfEndOfOverallTimeInterval'),
_.Get('secondOfEndOfOverallTimeInterval'),
_.Get('indicatorOfUnitForTimeRange'),
_.Get('lengthOfTimeRange'),
_.Get('typeOfTimeIncrement'),
_.Get('numberOfTimeRange')))
h.add(_.G2step_range('stepRange', _.Get('startStep'),
_.Get('endStep')))
else:
h.add(_.Constant('stepType', "multiple steps"))
h.add(_.Constant('stepTypeInternal', "multiple steps"))
h.add(_.Constant('endStep', "unavailable"))
h.add(_.Constant('startStep', "unavailable"))
h.add(_.Constant('stepRange', "unavailable"))
h.alias('ls.stepRange', 'stepRange')
h.alias('mars.step', 'endStep')
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('date'), _.Get('dataTime'),
_.Get('step'), _.Get('stepUnits'),
_.Get('yearOfEndOfOverallTimeInterval'),
_.Get('monthOfEndOfOverallTimeInterval'),
_.Get('dayOfEndOfOverallTimeInterval')))
h.alias('time.validityDate', 'validityDate')
h.add(
_.Validity_time('validityTime', _.Get('date'), _.Get('dataTime'),
_.Get('step'), _.Get('stepUnits'),
_.Get('hourOfEndOfOverallTimeInterval'),
_.Get('minuteOfEndOfOverallTimeInterval')))
h.alias('time.validityTime', 'validityTime')
h.alias('instrument', 'instrumentType')
h.alias('ident', 'satelliteNumber')
