Yes, the API isn't consistent. The raster (the data source) has a GetProjection()
method instead (which returns WKT).
Here is a function that does what you want (drawn from here):
def extract_point_from_raster(point, data_source, band_number=1):
"""Return floating-point value that corresponds to given point."""
# Convert point co-ordinates so that they are in same projection as raster
point_sr = point.GetSpatialReference()
raster_sr = osr.SpatialReference()
raster_sr.ImportFromWkt(data_source.GetProjection())
transform = osr.CoordinateTransformation(point_sr, raster_sr)
point.Transform(transform)
# Convert geographic co-ordinates to pixel co-ordinates
x, y = point.GetX(), point.GetY()
forward_transform = Affine.from_gdal(*data_source.GetGeoTransform())
reverse_transform = ~forward_transform
px, py = reverse_transform * (x, y)
px, py = int(px + 0.5), int(py + 0.5)
# Extract pixel value
band = data_source.GetRasterBand(band_number)
structval = band.ReadRaster(px, py, 1, 1, buf_type=gdal.GDT_Float32)
result = struct.unpack('f', structval)[0]
if result == band.GetNoDataValue():
result = float('nan')
return result
Its documentation is as follows (drawn from here):
spatial.extract_point_from_raster(point, data_source, band_number=1)
data_source is a GDAL raster, and point is an OGR point object. The
function returns the value of the pixel of the specified band of
data_source that is nearest to point.
point and data_source need not be in the same reference system, but
they must both have an appropriate spatial reference defined.
If the point does not fall in the raster, RuntimeError is raised.