есть код:
mask = (latitude >= latitudeMin) * (latitude <= latitudeMax) * (longitude >= longitudeMin) * (longitude <= longitudeMax)
points = np.zeros(shape=(latitude[mask].shape[0], 2))
points[:, 0] = longitude[mask]
points[:, 1] = latitude[mask]
Выполняется вечно долго. размер latitude и longitude = 6700x12000. Надо чтобы выполнялось быстрее, если это возможно. Спасибо за любую помощь.
def get_mask(x_index, y_index, ncols, nrows):
"""
"""
mask_nodata = np.zeros(shape=(nrows, ncols))
mask_nodata[y_index, x_index] = 1
for i in range(2):
cusum_0 = np.cumsum(mask_nodata, axis=0)
cusum_1 = np.cumsum(mask_nodata, axis=1)
mask_nodata = (cusum_0 < cusum_0[-1, :]) * (0 < cusum_0) + (cusum_1.T < cusum_1[:, -1].T).T * (0 < cusum_1)
return mask_nodata
def getAllDatasets(path_to_hdf):
"""
Method to get all keys from h5 file
path_to_hdf - file path string variable
return all key from a file
"""
sub_data = gdal.Open(path_to_hdf, gdal.GA_ReadOnly).GetSubDatasets()
return {key.split(' ')[1]: str(value.split(':')[-1]) for (value, key) in sub_data}
def getDataFromFile(path_to_hdf, num):
"""
Method to get Data from file by key
path_to_hdf - file path string variable
num - int key
return data array
"""
hdf_data = gdal.Open(path_to_hdf, gdal.GA_ReadOnly)
subdataset_read = hdf_data.GetSubDatasets()[num]
ds_sub = gdal.Open(subdataset_read[0],gdal.GA_ReadOnly)
return ds_sub.ReadAsArray()
def getCoordinateTransformerOutOfTheLambertProjectionToWGS():
"""
Method for creating a tool to convert from Lambert to WGS
return coordinate transformation, and projection
"""
projection = 'PROJCS["Lambert_Conformal_Conic",' \
'GEOGCS["GCS_WGS_1984",' \
'DATUM["WGS_1984",' \
'SPHEROID["WGS_84",6378137.0,298.252223563]],' \
'PRIMEM["Greenwich",0.0],' \
'UNIT["Degree",0.0174532925199433]],' \
'PROJECTION["Lambert_Conformal_Conic_2SP"],' \
'PARAMETER["False_Easting",0.0],' \
'PARAMETER["False_Northing",0.0],' \
'PARAMETER["Central_Meridian",79.950619],' \
'PARAMETER["Standard_Parallel_1",67.41206675],' \
'PARAMETER["Standard_Parallel_2",43.58046825],' \
'PARAMETER["Scale_Factor",1.0],' \
'PARAMETER["Latitude_Of_Origin",55.4962675],' \
'UNIT["Meter",1]]'
projection_wgs = '''GEOGCS["WGS 84",
DATUM["WGS_1984",SPHEROID["WGS 84",6378137,298.257223563,AUTHORITY["EPSG","7030"]],
AUTHORITY["EPSG","6326"]],PRIMEM["Greenwich",0,AUTHORITY["EPSG","8901"]],
UNIT["degree",0.01745329251994328,AUTHORITY["EPSG","9122"]],AUTHORITY["EPSG","4326"]]
'''
lambert = osr.SpatialReference()
lambert.ImportFromWkt(projection)
wgs84 = osr.SpatialReference()
wgs84.ImportFromWkt(projection_wgs)
return osr.CoordinateTransformation(wgs84, lambert), projection
def saveToFile(outputFileName, ncols, nrows, geotransform, projection, nodata):
return "af"
if __name__ == "__main__":
reflectance = getDataFromFile("SVI01_npp_d20190716_t0808475_e0821357_b00001_c20190716104346439000_ipop_dev.h5", 2)
reflectance2 = getDataFromFile("SVI02_npp_d20190716_t0808475_e0821357_b00001_c20190716104346439000_ipop_dev.h5",2)
reflectance3 = getDataFromFile("SVI03_npp_d20190716_t0808475_e0821357_b00001_c20190716104346439000_ipop_dev.h5",2)
brightnessTemperature4 = getDataFromFile("SVI04_npp_d20190716_t0808475_e0821357_b00001_c20190716104346439000_ipop_dev.h5",0)
brightnessTemperature5 = getDataFromFile("SVI05_npp_d20190716_t0808475_e0821357_b00001_c20190716104346439000_ipop_dev.h5",0)
latitude = getDataFromFile("GIMGO_npp_d20190716_t0808475_e0821357_b00001_c20190716104346439000_ipop_dev.h5",1)
longitude = getDataFromFile("GIMGO_npp_d20190716_t0808475_e0821357_b00001_c20190716104346439000_ipop_dev.h5",2)
###Температура
file = hdf.File('SVI04_npp_d20190716_t0808475_e0821357_b00001_c20190716104346439000_ipop_dev.h5')
brightnessTemperature4DataFactor = np.array(file['All_Data/VIIRS-I4-SDR_All/BrightnessTemperatureFactors'])[:2]
file = hdf.File('SVI05_npp_d20190716_t0808475_e0821357_b00001_c20190716104346439000_ipop_dev.h5')
brightnessTemperature5DataFactor = np.array(file['All_Data/VIIRS-I5-SDR_All/BrightnessTemperatureFactors'])[:2]
###3 канала
file = hdf.File('SVI01_npp_d20190716_t0808475_e0821357_b00001_c20190716104346439000_ipop_dev.h5')
reflectanceDataFactor = np.array(file['All_Data/VIIRS-I1-SDR_All/ReflectanceFactors'])[:2]
file = hdf.File('SVI02_npp_d20190716_t0808475_e0821357_b00001_c20190716104346439000_ipop_dev.h5')
reflectance2DataFactor = np.array(file['All_Data/VIIRS-I2-SDR_All/ReflectanceFactors'])[:2]
file = hdf.File('SVI03_npp_d20190716_t0808475_e0821357_b00001_c20190716104346439000_ipop_dev.h5')
reflectance3DataFactor = np.array(file['All_Data/VIIRS-I3-SDR_All/ReflectanceFactors'])[:2]
ct,projection = getCoordinateTransformerOutOfTheLambertProjectionToWGS()
resolution = 375 #Размер пикселя
latitudeMin = latitude[latitude[...,0]>-500].min() #Latitude min > -999 Non data
latitudeMax = latitude[latitude[...,0]>-500].max() #Latitude max > -999 Non data
longitudeMin = longitude[longitude[...,0]>-500].min() # Longitude min >-999 Non data
longitudeMax = longitude[longitude[...,0]>-500].max() #Longitude max > -99 Non data
mask = (latitude >= latitudeMin) * (latitude <= latitudeMax) * (longitude >= longitudeMin) * (longitude <= longitudeMax)
z = np.array(ct.TransformPoints(
np.array([[latitudeMax, latitudeMin],
[longitudeMin, latitudeMax],
[longitudeMax, latitudeMax],
[longitudeMin, latitudeMin],
[longitudeMax, latitudeMin]]
)))[:, :2]
height = (z[1:3, 1].max() - z[0, 1]) / resolution
width = (z[-1, 0] - z[-2, 0]) / resolution
x_min, y_max = z[-2, 0], z[1:3, 1].max()
ncols = int(width)
nrows = int(height)
x_intervals = np.array(x_min + np.arange(ncols) * resolution)
y_intervals = np.array(y_max- np.arange(nrows) * resolution)
geotransform = [x_min, resolution, 0, y_max, 0, -resolution]
del x_min
del y_max
del z
print('Посчитаны геотрансформации')
points = np.zeros(shape=(latitude[mask].shape[0], 2))
points[:, 0] = longitude[mask]
points[:, 1] = latitude[mask]
print('Посчитаны point')
coord = np.array(ct.TransformPoints(points))[:, :2]
x_index = np.searchsorted(x_intervals, coord[:, 0], 'left')
y_index = np.searchsorted(y_intervals[::-1], coord[:, 1], 'left')
y_index = nrows - y_index - 1
print('Посчитаны coordinate')
mask_nodata = get_mask(x_index=x_index, y_index=y_index, ncols=ncols, nrows=nrows)