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NetCDF reader/writer module.
This module is used to read and create NetCDF files. NetCDF files are
accessed through the `netcdf_file` object. Data written to and from NetCDF
files are contained in `netcdf_variable` objects. Attributes are given
as member variables of the `netcdf_file` and `netcdf_variable` objects.
This module implements the Scientific.IO.NetCDF API to read and create
NetCDF files. The same API is also used in the PyNIO and pynetcdf
modules, allowing these modules to be used interchangeably when working
with NetCDF files.
Only NetCDF3 is supported here; for NetCDF4 see
`netCDF4-python <>`__,
which has a similar API.
from __future__ import division, print_function, absolute_import
# * properly implement ``_FillValue``.
# * fix character variables.
# * implement PAGESIZE for Python 2.6?
# The Scientific.IO.NetCDF API allows attributes to be added directly to
# instances of ``netcdf_file`` and ``netcdf_variable``. To differentiate
# between user-set attributes and instance attributes, user-set attributes
# are automatically stored in the ``_attributes`` attribute by overloading
#``__setattr__``. This is the reason why the code sometimes uses
#``obj.__dict__['key'] = value``, instead of simply ``obj.key = value``;
# otherwise the key would be inserted into userspace attributes.
__all__ = ['netcdf_file']
import warnings
import weakref
from operator import mul
from collections import OrderedDict
import mmap as mm
import numpy as np
from numpy.compat import asbytes, asstr
from numpy import fromstring, dtype, empty, array, asarray
from numpy import little_endian as LITTLE_ENDIAN
from functools import reduce
from scipy._lib.six import integer_types, text_type, binary_type
ABSENT = b'\x00\x00\x00\x00\x00\x00\x00\x00'
ZERO = b'\x00\x00\x00\x00'
NC_BYTE = b'\x00\x00\x00\x01'
NC_CHAR = b'\x00\x00\x00\x02'
NC_SHORT = b'\x00\x00\x00\x03'
NC_INT = b'\x00\x00\x00\x04'
NC_FLOAT = b'\x00\x00\x00\x05'
NC_DOUBLE = b'\x00\x00\x00\x06'
NC_DIMENSION = b'\x00\x00\x00\n'
NC_VARIABLE = b'\x00\x00\x00\x0b'
NC_ATTRIBUTE = b'\x00\x00\x00\x0c'
TYPEMAP = {NC_BYTE: ('b', 1),
NC_CHAR: ('c', 1),
NC_SHORT: ('h', 2),
NC_INT: ('i', 4),
NC_FLOAT: ('f', 4),
NC_DOUBLE: ('d', 8)}
REVERSE = {('b', 1): NC_BYTE,
('B', 1): NC_CHAR,
('c', 1): NC_CHAR,
('h', 2): NC_SHORT,
('i', 4): NC_INT,
('f', 4): NC_FLOAT,
('d', 8): NC_DOUBLE,
# these come from asarray(1).dtype.char and asarray('foo').dtype.char,
# used when getting the types from generic attributes.
('l', 4): NC_INT,
('S', 1): NC_CHAR}
class netcdf_file(object):
A file object for NetCDF data.
A `netcdf_file` object has two standard attributes: `dimensions` and
`variables`. The values of both are dictionaries, mapping dimension
names to their associated lengths and variable names to variables,
respectively. Application programs should never modify these
All other attributes correspond to global attributes defined in the
NetCDF file. Global file attributes are created by assigning to an
attribute of the `netcdf_file` object.
filename : string or file-like
string -> filename
mode : {'r', 'w', 'a'}, optional
read-write-append mode, default is 'r'
mmap : None or bool, optional
Whether to mmap `filename` when reading. Default is True
when `filename` is a file name, False when `filename` is a
file-like object. Note that when mmap is in use, data arrays
returned refer directly to the mmapped data on disk, and the
file cannot be closed as long as references to it exist.
version : {1, 2}, optional
version of netcdf to read / write, where 1 means *Classic
format* and 2 means *64-bit offset format*. Default is 1. See
`here <>`__
for more info.
maskandscale : bool, optional
Whether to automatically scale and/or mask data based on attributes.
Default is False.
The major advantage of this module over other modules is that it doesn't
require the code to be linked to the NetCDF libraries. This module is
derived from `pupynere <>`_.
NetCDF files are a self-describing binary data format. The file contains
metadata that describes the dimensions and variables in the file. More
details about NetCDF files can be found `here
<>`__. There
are three main sections to a NetCDF data structure:
1. Dimensions
2. Variables
3. Attributes
The dimensions section records the name and length of each dimension used
by the variables. The variables would then indicate which dimensions it
uses and any attributes such as data units, along with containing the data
values for the variable. It is good practice to include a
variable that is the same name as a dimension to provide the values for
that axes. Lastly, the attributes section would contain additional
information such as the name of the file creator or the instrument used to
collect the data.
When writing data to a NetCDF file, there is often the need to indicate the
'record dimension'. A record dimension is the unbounded dimension for a
variable. For example, a temperature variable may have dimensions of
latitude, longitude and time. If one wants to add more temperature data to
the NetCDF file as time progresses, then the temperature variable should
have the time dimension flagged as the record dimension.
In addition, the NetCDF file header contains the position of the data in
the file, so access can be done in an efficient manner without loading
unnecessary data into memory. It uses the ``mmap`` module to create
Numpy arrays mapped to the data on disk, for the same purpose.
Note that when `netcdf_file` is used to open a file with mmap=True
(default for read-only), arrays returned by it refer to data
directly on the disk. The file should not be closed, and cannot be cleanly
closed when asked, if such arrays are alive. You may want to copy data arrays
obtained from mmapped Netcdf file if they are to be processed after the file
is closed, see the example below.
To create a NetCDF file:
>>> from import netcdf
>>> f = netcdf.netcdf_file('', 'w')
>>> f.history = 'Created for a test'
>>> f.createDimension('time', 10)
>>> time = f.createVariable('time', 'i', ('time',))
>>> time[:] = np.arange(10)
>>> time.units = 'days since 2008-01-01'
>>> f.close()
Note the assignment of ``range(10)`` to ``time[:]``. Exposing the slice
of the time variable allows for the data to be set in the object, rather
than letting ``range(10)`` overwrite the ``time`` variable.
To read the NetCDF file we just created:
>>> from import netcdf
>>> f = netcdf.netcdf_file('', 'r')
>>> print(f.history)
Created for a test
>>> time = f.variables['time']
>>> print(time.units)
days since 2008-01-01
>>> print(time.shape)
>>> print(time[-1])
NetCDF files, when opened read-only, return arrays that refer
directly to memory-mapped data on disk:
>>> data = time[:]
>>> data.base.base
<mmap.mmap object at 0x7fe753763180>
If the data is to be processed after the file is closed, it needs
to be copied to main memory:
>>> data = time[:].copy()
>>> f.close()
>>> data.mean()
A NetCDF file can also be used as context manager:
>>> from import netcdf
>>> with netcdf.netcdf_file('', 'r') as f:
... print(f.history)
Created for a test
def __init__(self, filename, mode='r', mmap=None, version=1,
"""Initialize netcdf_file from fileobj (str or file-like)."""
if mode not in 'rwa':
raise ValueError("Mode must be either 'r', 'w' or 'a'.")
if hasattr(filename, 'seek'): # file-like
self.fp = filename
self.filename = 'None'
if mmap is None:
mmap = False
elif mmap and not hasattr(filename, 'fileno'):
raise ValueError('Cannot use file object for mmap')
else: # maybe it's a string
self.filename = filename
omode = 'r+' if mode == 'a' else mode
self.fp = open(self.filename, '%sb' % omode)
if mmap is None:
mmap = True
if mode != 'r':
# Cannot read write-only files
mmap = False
self.use_mmap = mmap
self.mode = mode
self.version_byte = version
self.maskandscale = maskandscale
self.dimensions = OrderedDict()
self.variables = OrderedDict()
self._dims = []
self._recs = 0
self._recsize = 0
self._mm = None
self._mm_buf = None
if self.use_mmap:
self._mm = mm.mmap(self.fp.fileno(), 0, access=mm.ACCESS_READ)
self._mm_buf = np.frombuffer(self._mm, dtype=np.int8)
self._attributes = OrderedDict()
if mode in 'ra':
def __setattr__(self, attr, value):
# Store user defined attributes in a separate dict,
# so we can save them to file later.
self._attributes[attr] = value
except AttributeError:
self.__dict__[attr] = value
def close(self):
"""Closes the NetCDF file."""
if not self.fp.closed:
self.variables = OrderedDict()
if self._mm_buf is not None:
ref = weakref.ref(self._mm_buf)
self._mm_buf = None
if ref() is None:
# self._mm_buf is gc'd, and we can close the mmap
# we cannot close self._mm, since self._mm_buf is
# alive and there may still be arrays referring to it
"Cannot close a netcdf_file opened with mmap=True, when "
"netcdf_variables or arrays referring to its data still exist. "
"All data arrays obtained from such files refer directly to "
"data on disk, and must be copied before the file can be cleanly "
"closed. (See netcdf_file docstring for more information on mmap.)"
), category=RuntimeWarning)
self._mm = None
__del__ = close
def __enter__(self):
return self
def __exit__(self, type, value, traceback):
def createDimension(self, name, length):
Adds a dimension to the Dimension section of the NetCDF data structure.
Note that this function merely adds a new dimension that the variables can
reference. The values for the dimension, if desired, should be added as
a variable using `createVariable`, referring to this dimension.
name : str
Name of the dimension (Eg, 'lat' or 'time').
length : int
Length of the dimension.
See Also
if length is None and self._dims:
raise ValueError("Only first dimension may be unlimited!")
self.dimensions[name] = length
def createVariable(self, name, type, dimensions):
Create an empty variable for the `netcdf_file` object, specifying its data
type and the dimensions it uses.
name : str
Name of the new variable.
type : dtype or str
Data type of the variable.
dimensions : sequence of str
List of the dimension names used by the variable, in the desired order.
variable : netcdf_variable
The newly created ``netcdf_variable`` object.
This object has also been added to the `netcdf_file` object as well.
See Also
Any dimensions to be used by the variable should already exist in the
NetCDF data structure or should be created by `createDimension` prior to
creating the NetCDF variable.
shape = tuple([self.dimensions[dim] for dim in dimensions])
shape_ = tuple([dim or 0 for dim in shape]) # replace None with 0 for numpy
type = dtype(type)
typecode, size = type.char, type.itemsize
if (typecode, size) not in REVERSE:
raise ValueError("NetCDF 3 does not support type %s" % type)
data = empty(shape_, dtype=type.newbyteorder("B")) # convert to big endian always for NetCDF 3
self.variables[name] = netcdf_variable(
data, typecode, size, shape, dimensions,
return self.variables[name]
def flush(self):
Perform a sync-to-disk flush if the `netcdf_file` object is in write mode.
See Also
sync : Identical function
if hasattr(self, 'mode') and self.mode in 'wa':
sync = flush
def _write(self):
self.fp.write(array(self.version_byte, '>b').tostring())
# Write headers and data.
def _write_numrecs(self):
# Get highest record count from all record variables.
for var in self.variables.values():
if var.isrec and len( > self._recs:
self.__dict__['_recs'] = len(
def _write_dim_array(self):
if self.dimensions:
for name in self._dims:
length = self.dimensions[name]
self._pack_int(length or 0) # replace None with 0 for record dimension
def _write_gatt_array(self):
def _write_att_array(self, attributes):
if attributes:
for name, values in attributes.items():
def _write_var_array(self):
if self.variables:
# Sort variable names non-recs first, then recs.
def sortkey(n):
v = self.variables[n]
if v.isrec:
return (-1,)
return v._shape
variables = sorted(self.variables, key=sortkey, reverse=True)
# Set the metadata for all variables.
for name in variables:
# Now that we have the metadata, we know the vsize of
# each record variable, so we can calculate recsize.
self.__dict__['_recsize'] = sum([
var._vsize for var in self.variables.values()
if var.isrec])
# Set the data for all variables.
for name in variables:
def _write_var_metadata(self, name):
var = self.variables[name]
for dimname in var.dimensions:
dimid = self._dims.index(dimname)
nc_type = REVERSE[var.typecode(), var.itemsize()]
if not var.isrec:
vsize = *
vsize += -vsize % 4
else: # record variable
vsize =[0].size *
except IndexError:
vsize = 0
rec_vars = len([v for v in self.variables.values()
if v.isrec])
if rec_vars > 1:
vsize += -vsize % 4
self.variables[name].__dict__['_vsize'] = vsize
# Pack a bogus begin, and set the real value later.
self.variables[name].__dict__['_begin'] = self.fp.tell()
def _write_var_data(self, name):
var = self.variables[name]
# Set begin in file header.
the_beguine = self.fp.tell()
# Write data.
if not var.isrec:
count = *
self.fp.write(b'0' * (var._vsize - count))
else: # record variable
# Handle rec vars with shape[0] < nrecs.
if self._recs > len(
shape = (self._recs,) +[1:]
# Resize in-place does not always work since
# the array might not be single-segment
except ValueError:
var.__dict__['data'] = np.resize(, shape).astype(
pos0 = pos = self.fp.tell()
for rec in
# Apparently scalars cannot be converted to big endian. If we
# try to convert a ``=i4`` scalar to, say, '>i4' the dtype
# will remain as ``=i4``.
if not rec.shape and (rec.dtype.byteorder == '<' or
(rec.dtype.byteorder == '=' and LITTLE_ENDIAN)):
rec = rec.byteswap()
# Padding
count = rec.size * rec.itemsize
self.fp.write(b'0' * (var._vsize - count))
pos += self._recsize + var._vsize)
def _write_values(self, values):
if hasattr(values, 'dtype'):
nc_type = REVERSE[values.dtype.char, values.dtype.itemsize]
types = [(t, NC_INT) for t in integer_types]
types += [
(float, NC_FLOAT),
(str, NC_CHAR)
# bytes index into scalars in py3k. Check for "string" types
if isinstance(values, text_type) or isinstance(values, binary_type):
sample = values
sample = values[0] # subscriptable?
except TypeError:
sample = values # scalar
for class_, nc_type in types:
if isinstance(sample, class_):
typecode, size = TYPEMAP[nc_type]
dtype_ = '>%s' % typecode
# asarray() dies with bytes and '>c' in py3k. Change to 'S'
dtype_ = 'S' if dtype_ == '>c' else dtype_
values = asarray(values, dtype=dtype_)
if values.dtype.char == 'S':
nelems = values.itemsize
nelems = values.size
if not values.shape and (values.dtype.byteorder == '<' or
(values.dtype.byteorder == '=' and LITTLE_ENDIAN)):
values = values.byteswap()
count = values.size * values.itemsize
self.fp.write(b'0' * (-count % 4)) # pad
def _read(self):
# Check magic bytes and version
magic =
if not magic == b'CDF':
raise TypeError("Error: %s is not a valid NetCDF 3 file" %
self.__dict__['version_byte'] = fromstring(, '>b')[0]
# Read file headers and set data.
def _read_numrecs(self):
self.__dict__['_recs'] = self._unpack_int()
def _read_dim_array(self):
header =
if header not in [ZERO, NC_DIMENSION]:
raise ValueError("Unexpected header.")
count = self._unpack_int()
for dim in range(count):
name = asstr(self._unpack_string())
length = self._unpack_int() or None # None for record dimension
self.dimensions[name] = length
self._dims.append(name) # preserve order
def _read_gatt_array(self):
for k, v in self._read_att_array().items():
self.__setattr__(k, v)
def _read_att_array(self):
header =
if header not in [ZERO, NC_ATTRIBUTE]:
raise ValueError("Unexpected header.")
count = self._unpack_int()
attributes = OrderedDict()
for attr in range(count):
name = asstr(self._unpack_string())
attributes[name] = self._read_values()
return attributes
def _read_var_array(self):
header =
if header not in [ZERO, NC_VARIABLE]:
raise ValueError("Unexpected header.")
begin = 0
dtypes = {'names': [], 'formats': []}
rec_vars = []
count = self._unpack_int()
for var in range(count):
(name, dimensions, shape, attributes,
typecode, size, dtype_, begin_, vsize) = self._read_var()
# Note that vsize is the product of the dimension lengths
# (omitting the record dimension) and the number of bytes
# per value (determined from the type), increased to the
# next multiple of 4, for each variable. If a record
# variable, this is the amount of space per record. The
# netCDF "record size" is calculated as the sum of the
# vsize's of all the record variables.
# The vsize field is actually redundant, because its value
# may be computed from other information in the header. The
# 32-bit vsize field is not large enough to contain the size
# of variables that require more than 2^32 - 4 bytes, so
# 2^32 - 1 is used in the vsize field for such variables.
if shape and shape[0] is None: # record variable
# The netCDF "record size" is calculated as the sum of
# the vsize's of all the record variables.
self.__dict__['_recsize'] += vsize
if begin == 0:
begin = begin_
dtypes['formats'].append(str(shape[1:]) + dtype_)
# Handle padding with a virtual variable.
if typecode in 'bch':
actual_size = reduce(mul, (1,) + shape[1:]) * size
padding = -actual_size % 4
if padding:
dtypes['names'].append('_padding_%d' % var)
dtypes['formats'].append('(%d,)>b' % padding)
# Data will be set later.
data = None
else: # not a record variable
# Calculate size to avoid problems with vsize (above)
a_size = reduce(mul, shape, 1) * size
if self.use_mmap:
data = self._mm_buf[begin_:begin_+a_size].view(dtype=dtype_)
data.shape = shape
pos = self.fp.tell()
data = fromstring(, dtype=dtype_)
data.shape = shape
# Add variable.
self.variables[name] = netcdf_variable(
data, typecode, size, shape, dimensions, attributes,
if rec_vars:
# Remove padding when only one record variable.
if len(rec_vars) == 1:
dtypes['names'] = dtypes['names'][:1]
dtypes['formats'] = dtypes['formats'][:1]
# Build rec array.
if self.use_mmap:
rec_array = self._mm_buf[begin:begin+self._recs*self._recsize].view(dtype=dtypes)
rec_array.shape = (self._recs,)
pos = self.fp.tell()
rec_array = fromstring(*self._recsize), dtype=dtypes)
rec_array.shape = (self._recs,)
for var in rec_vars:
self.variables[var].__dict__['data'] = rec_array[var]
def _read_var(self):
name = asstr(self._unpack_string())
dimensions = []
shape = []
dims = self._unpack_int()
for i in range(dims):
dimid = self._unpack_int()
dimname = self._dims[dimid]
dim = self.dimensions[dimname]
dimensions = tuple(dimensions)
shape = tuple(shape)
attributes = self._read_att_array()
nc_type =
vsize = self._unpack_int()
begin = [self._unpack_int, self._unpack_int64][self.version_byte-1]()
typecode, size = TYPEMAP[nc_type]
dtype_ = '>%s' % typecode
return name, dimensions, shape, attributes, typecode, size, dtype_, begin, vsize
def _read_values(self):
nc_type =
n = self._unpack_int()
typecode, size = TYPEMAP[nc_type]
count = n*size
values = % 4) # read padding
if typecode is not 'c':
values = fromstring(values, dtype='>%s' % typecode)
if values.shape == (1,):
values = values[0]
values = values.rstrip(b'\x00')
return values
def _pack_begin(self, begin):
if self.version_byte == 1:
elif self.version_byte == 2:
def _pack_int(self, value):
self.fp.write(array(value, '>i').tostring())
_pack_int32 = _pack_int
def _unpack_int(self):
return int(fromstring(, '>i')[0])
_unpack_int32 = _unpack_int
def _pack_int64(self, value):
self.fp.write(array(value, '>q').tostring())
def _unpack_int64(self):
return fromstring(, '>q')[0]
def _pack_string(self, s):
count = len(s)
self.fp.write(b'0' * (-count % 4)) # pad
def _unpack_string(self):
count = self._unpack_int()
s ='\x00') % 4) # read padding
return s
class netcdf_variable(object):
A data object for the `netcdf` module.
`netcdf_variable` objects are constructed by calling the method
`netcdf_file.createVariable` on the `netcdf_file` object. `netcdf_variable`
objects behave much like array objects defined in numpy, except that their
data resides in a file. Data is read by indexing and written by assigning
to an indexed subset; the entire array can be accessed by the index ``[:]``
or (for scalars) by using the methods `getValue` and `assignValue`.
`netcdf_variable` objects also have attribute `shape` with the same meaning
as for arrays, but the shape cannot be modified. There is another read-only
attribute `dimensions`, whose value is the tuple of dimension names.
All other attributes correspond to variable attributes defined in
the NetCDF file. Variable attributes are created by assigning to an
attribute of the `netcdf_variable` object.
data : array_like
The data array that holds the values for the variable.
Typically, this is initialized as empty, but with the proper shape.
typecode : dtype character code
Desired data-type for the data array.
size : int
Desired element size for the data array.
shape : sequence of ints
The shape of the array. This should match the lengths of the
variable's dimensions.
dimensions : sequence of strings
The names of the dimensions used by the variable. Must be in the
same order of the dimension lengths given by `shape`.
attributes : dict, optional
Attribute values (any type) keyed by string names. These attributes
become attributes for the netcdf_variable object.
maskandscale : bool, optional
Whether to automatically scale and/or mask data based on attributes.
Default is False.
dimensions : list of str
List of names of dimensions used by the variable object.
isrec, shape
See also
isrec, shape
def __init__(self, data, typecode, size, shape, dimensions,
maskandscale=False): = data
self._typecode = typecode
self._size = size
self._shape = shape
self.dimensions = dimensions
self.maskandscale = maskandscale
self._attributes = attributes or OrderedDict()
for k, v in self._attributes.items():
self.__dict__[k] = v
def __setattr__(self, attr, value):
# Store user defined attributes in a separate dict,
# so we can save them to file later.
self._attributes[attr] = value
except AttributeError:
self.__dict__[attr] = value
def isrec(self):
"""Returns whether the variable has a record dimension or not.
A record dimension is a dimension along which additional data could be
easily appended in the netcdf data structure without much rewriting of
the data file. This attribute is a read-only property of the
return bool( and not self._shape[0]
isrec = property(isrec)
def shape(self):
"""Returns the shape tuple of the data variable.
This is a read-only attribute and can not be modified in the
same manner of other numpy arrays.
shape = property(shape)
def getValue(self):
Retrieve a scalar value from a `netcdf_variable` of length one.
If the netcdf variable is an array of length greater than one,
this exception will be raised.
def assignValue(self, value):
Assign a scalar value to a `netcdf_variable` of length one.
value : scalar
Scalar value (of compatible type) to assign to a length-one netcdf
variable. This value will be written to file.
If the input is not a scalar, or if the destination is not a length-one
netcdf variable.
if not
# Work-around for a bug in NumPy. Calling itemset() on a read-only
# memory-mapped array causes a seg. fault.
# See NumPy ticket #1622, and SciPy ticket #1202.
# This check for `writeable` can be removed when the oldest version
# of numpy still supported by scipy contains the fix for #1622.
raise RuntimeError("variable is not writeable")
def typecode(self):
Return the typecode of the variable.
typecode : char
The character typecode of the variable (eg, 'i' for int).
return self._typecode
def itemsize(self):
Return the itemsize of the variable.
itemsize : int
The element size of the variable (eg, 8 for float64).
return self._size
def __getitem__(self, index):
if not self.maskandscale:
data =[index].copy()
missing_value = self._get_missing_value()
data = self._apply_missing_value(data, missing_value)
scale_factor = self._attributes.get('scale_factor')
add_offset = self._attributes.get('add_offset')
if add_offset is not None or scale_factor is not None:
data = data.astype(np.float64)
if scale_factor is not None:
data = data * scale_factor
if add_offset is not None:
data += add_offset
return data
def __setitem__(self, index, data):
if self.maskandscale:
missing_value = (
self._get_missing_value() or
getattr(data, 'fill_value', 999999))
self._attributes.setdefault('missing_value', missing_value)
self._attributes.setdefault('_FillValue', missing_value)
data = ((data - self._attributes.get('add_offset', 0.0)) /
self._attributes.get('scale_factor', 1.0))
data =
if self._typecode not in 'fd' and data.dtype.kind == 'f':
data = np.round(data)
# Expand data for record vars?
if self.isrec:
if isinstance(index, tuple):
rec_index = index[0]
rec_index = index
if isinstance(rec_index, slice):
recs = (rec_index.start or 0) + len(data)
recs = rec_index + 1
if recs > len(
shape = (recs,) + self._shape[1:]
# Resize in-place does not always work since
# the array might not be single-segment
except ValueError:
self.__dict__['data'] = np.resize(, shape).astype([index] = data
def _get_missing_value(self):
Returns the value denoting "no data" for this variable.
If this variable does not have a missing/fill value, returns None.
If both _FillValue and missing_value are given, give precedence to
_FillValue. The netCDF standard gives special meaning to _FillValue;
missing_value is just used for compatibility with old datasets.
if '_FillValue' in self._attributes:
missing_value = self._attributes['_FillValue']
elif 'missing_value' in self._attributes:
missing_value = self._attributes['missing_value']
missing_value = None
return missing_value
def _apply_missing_value(data, missing_value):
Applies the given missing value to the data array.
Returns a array, with any value equal to missing_value masked
out (unless missing_value is None, in which case the original array is
if missing_value is None:
newdata = data
missing_value_isnan = np.isnan(missing_value)
except (TypeError, NotImplementedError):
# some data types (e.g., characters) cannot be tested for NaN
missing_value_isnan = False
if missing_value_isnan:
mymask = np.isnan(data)
mymask = (data == missing_value)
newdata =, data)
return newdata
NetCDFFile = netcdf_file
NetCDFVariable = netcdf_variable