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MRCFILE(1) mrcfile MRCFILE(1)

mrcfile - mrcfile Documentation

Get started by reading the Overview of mrcfile.py and the Usage Guide.

You can also look at the Source documentation.

mrcfile is a Python implementation of the MRC2014 file format, which is used in structural biology to store image and volume data.

It allows MRC files to be created and opened easily using a very simple API, which exposes the file's header and data as numpy arrays. The code runs in Python 2 and 3 and is fully unit-tested.

This library aims to allow users and developers to read and write standard-compliant MRC files in Python as easily as possible, and with no dependencies on any compiled libraries except numpy. You can use it interactively to inspect files, correct headers and so on, or in scripts and larger software packages to provide basic MRC file I/O functions.

  • Clean, simple API for access to MRC files
  • Easy to install and use
  • Validation of files according to the MRC2014 format
  • Seamless support for gzip and bzip2 files
  • Memory-mapped file option for fast random access to very large files
  • Asynchronous opening option for background loading of multiple files
  • Runs in Python 2 & 3, on Linux, Mac OS X and Windows

The mrcfile library is available from the Python package index:

pip install mrcfile


Or from conda-forge:

conda install --channel conda-forge mrcfile


It is also included in the ccpem-python environment in the CCP-EM software suite.

The source code (including the full test suite) can be found on GitHub.

Basic usage

The easiest way to open a file is with the mrcfile.open and mrcfile.new functions. These return an MrcFile object which represents an MRC file on disk.

To open an MRC file and read a slice of data:

>>> import mrcfile
>>> with mrcfile.open('tests/test_data/EMD-3197.map') as mrc:
...     mrc.data[10,10]
...
array([ 2.58179283,  3.1406002 ,  3.64495397,  3.63812137,  3.61837363,

4.0115056 , 3.66981959, 2.07317996, 0.1251585 , -0.87975615,
0.12517013, 2.07319379, 3.66982722, 4.0115037 , 3.61837196,
3.6381247 , 3.64495087, 3.14059472, 2.58178973, 1.92690361], dtype=float32)


To create a new file with a 2D data array, and change some values:

>>> array = np.zeros((5, 5), dtype=np.int8)
>>> with mrcfile.new('tmp.mrc') as mrc:
...     mrc.set_data(array)
...     mrc.data[1:4,1:4] = 10
...     mrc.data
...
array([[ 0,  0,  0,  0,  0],

[ 0, 10, 10, 10, 0],
[ 0, 10, 10, 10, 0],
[ 0, 10, 10, 10, 0],
[ 0, 0, 0, 0, 0]], dtype=int8)


The data will be saved to disk when the file is closed, either automatically at the end of the with block (like a normal Python file object) or manually by calling close(). You can also call flush() to write any changes to disk and keep the file open.

To validate an MRC file:

>>> mrcfile.validate('tests/test_data/EMD-3197.map')
File does not declare MRC format version 20140 or 20141: nversion = 0
False
>>> mrcfile.validate('tmp.mrc')
True


Full documentation is available on Read the Docs.

If you find mrcfile useful in your work, please cite:

Burnley T, Palmer C & Winn M (2017) Recent developments in the CCP-EM software suite. Acta Cryst. D73:469--477. doi: 10.1107/S2059798317007859

Please use the GitHub issue tracker for bug reports and feature requests, or email CCP-EM.

Code contributions are also welcome, please submit pull requests to the GitHub repository.

To run the test suite, go to the top-level project directory (which contains the mrcfile and tests packages) and run python -m unittest tests. (Or, if you have tox installed, run tox.)

The project is released under the BSD licence.

This is a detailed guide to using the mrcfile Python library. For a brief introduction, see the overview.

MRC files can be opened using the mrcfile.new() or mrcfile.open() functions. These return an instance of the MrcFile class, which represents an MRC file on disk and makes the file's header, extended header and data available for read and write access as numpy arrays. :

>>> # First, create a simple dataset
>>> import numpy as np
>>> example_data = np.arange(12, dtype=np.int8).reshape(3, 4)
>>> # Make a new MRC file and write the data to it:
>>> import mrcfile
>>> with mrcfile.new('tmp.mrc') as mrc:
...     mrc.set_data(example_data)
...
>>> # The file is now saved on disk. Open it again and check the data:
>>> with mrcfile.open('tmp.mrc') as mrc:
...     mrc.data
...
array([[ 0,  1,  2,  3],

[ 4, 5, 6, 7],
[ 8, 9, 10, 11]], dtype=int8)


Alternatively, for even quicker access to MRC data but with minimal control of the file header, you can use the read() and write() functions. These do not return MrcFile objects but instead work directly with numpy arrays:

>>> # First, create a simple dataset
>>> import numpy as np
>>> example_data_2 = np.arange(6, dtype=np.int8).reshape(3, 2)
>>> # Write the data to a new MRC file:
>>> mrcfile.write('tmp2.mrc', example_data_2)
>>> # Read it back:
>>> mrcfile.read('tmp2.mrc')
array([[0, 1],

[2, 3],
[4, 5]], dtype=int8)


All of the functions shown above can also handle gzip- or bzip2-compressed files very easily:

>>> # Make a new gzipped MRC file:
>>> with mrcfile.new('tmp.mrc.gz', compression='gzip') as mrc:
...     mrc.set_data(example_data * 2)
...
>>> # Open it again with the normal open function:
>>> with mrcfile.open('tmp.mrc.gz') as mrc:
...     mrc.data
...
array([[ 0,  2,  4,  6],

[ 8, 10, 12, 14],
[16, 18, 20, 22]], dtype=int8) >>> # Same again for bzip2: >>> with mrcfile.new('tmp.mrc.bz2', compression='bzip2') as mrc: ... mrc.set_data(example_data * 3) ... >>> # Open it again with the normal read function: >>> mrcfile.read('tmp.mrc.bz2') array([[ 0, 3, 6, 9],
[12, 15, 18, 21],
[24, 27, 30, 33]], dtype=int8) >>> # The write function applies compression automatically based on the file name >>> mrcfile.write('tmp2.mrc.gz', example_data * 4) >>> # The new file is opened as a GzipMrcFile object: >>> with mrcfile.open('tmp2.mrc.gz') as mrc: ... print(mrc) ... GzipMrcFile('tmp2.mrc.gz', mode='r')


MrcFile objects should be closed when they are finished with, to ensure any changes are flushed to disk and the underlying file object is closed:

>>> mrc = mrcfile.open('tmp.mrc', mode='r+')
>>> # do things...
>>> mrc.close()


As we saw in the examples above, MrcFile objects support Python's with statement, which will ensure the file is closed properly after use (like a normal Python file object). It's generally a good idea to use with if possible, but sometimes when running Python interactively (as in some of these examples), it's more convenient to open a file and keep using it without having to work in an indented block. If you do this, remember to close the file at the end!

There's also a flush() method that writes the MRC data to disk but leaves the file open:

>>> mrc = mrcfile.open('tmp.mrc', mode='r+')
>>> # do things...
>>> mrc.flush()  # make sure changes are written to disk
>>> # continue using the file...
>>> mrc.close()  # close the file when finished


For most purposes, the top-level functions in mrcfile should be all you need to open MRC files, but it is also possible to directly instantiate MrcFile and its subclasses, GzipMrcFile, Bzip2MrcFile and MrcMemmap:

>>> with mrcfile.mrcfile.MrcFile('tmp.mrc') as mrc:
...     mrc
...
MrcFile('tmp.mrc', mode='r')
>>> with mrcfile.gzipmrcfile.GzipMrcFile('tmp.mrc.gz') as mrc:
...     mrc
...
GzipMrcFile('tmp.mrc.gz', mode='r')
>>> with mrcfile.bzip2mrcfile.Bzip2MrcFile('tmp.mrc.bz2') as mrc:
...     mrc
...
Bzip2MrcFile('tmp.mrc.bz2', mode='r')
>>> with mrcfile.mrcmemmap.MrcMemmap('tmp.mrc') as mrc:
...     mrc
...
MrcMemmap('tmp.mrc', mode='r')


MrcFile objects can be opened in three modes: r, r+ and w+. These correspond to the standard Python file modes, so r opens a file in read-only mode:

>>> # The default mode is 'r', for read-only access:
>>> mrc = mrcfile.open('tmp.mrc')
>>> mrc
MrcFile('tmp.mrc', mode='r')
>>> mrc.set_data(example_data)
Traceback (most recent call last):

... ValueError: MRC object is read-only >>> mrc.close()


r+ opens it for reading and writing:

>>> # Using mode 'r+' allows read and write access:
>>> mrc = mrcfile.open('tmp.mrc', mode='r+')
>>> mrc
MrcFile('tmp.mrc', mode='r+')
>>> mrc.set_data(example_data)
>>> mrc.data
array([[ 0,  1,  2,  3],

[ 4, 5, 6, 7],
[ 8, 9, 10, 11]], dtype=int8) >>> mrc.close()


and w+ opens a new, empty file (also for both reading and writing):

>>> # Mode 'w+' creates a new empty file:
>>> mrc = mrcfile.open('empty.mrc', mode='w+')
>>> mrc
MrcFile('empty.mrc', mode='w+')
>>> mrc.data
array([], dtype=int8)
>>> mrc.close()


The new() function is effectively shorthand for open(name, mode='w+'):

>>> # Make a new file
>>> mrc = mrcfile.new('empty.mrc')
Traceback (most recent call last):

... ValueError: File 'empty.mrc' already exists; set overwrite=True to overwrite it >>> # Ooops, we've already got a file with that name! >>> # If we're sure we want to overwrite it, we can try again: >>> mrc = mrcfile.new('empty.mrc', overwrite=True) >>> mrc MrcFile('empty.mrc', mode='w+') >>> mrc.close()


Normally, if an MRC file is badly invalid, an exception is raised when the file is opened. This can be a problem if we want to, say, open a file and fix a header problem. To deal with this situation, open() and mmap() provide an optional permissive argument. If this is set to True, problems with the file will cause warnings to be issued (using Python's warnings module) instead of raising exceptions, and the file will continue to be interpreted as far as possible.

Let's see an example. First we'll deliberately make an invalid file:

>>> # Make a new file and deliberately make a mistake in the header
>>> with mrcfile.new('invalid.mrc') as mrc:
...     mrc.header.map = b'map '  # standard requires b'MAP '
...


Now when we try to open the file, an exception is raised:

>>> # Opening an invalid file raises an exception:
>>> mrc = mrcfile.open('invalid.mrc')
Traceback (most recent call last):

... ValueError: Map ID string not found - not an MRC file, or file is corrupt


If we use permissive mode, we can open the file, and we'll see a warning about the problem (except that here, we have to catch the warning and print the message manually, because warnings don't play nicely with doctests!):

>>> # Opening in permissive mode succeeds, with a warning:
>>> with warnings.catch_warnings(record=True) as w:
...     mrc = mrcfile.open('invalid.mrc', permissive=True)
...     print(w[0].message)
...
Map ID string not found - not an MRC file, or file is corrupt


Now let's fix the file:

>>> # Fix the invalid file by correcting the header
>>> with mrcfile.open('invalid.mrc', mode='r+', permissive=True) as mrc:
...     mrc.header.map = mrcfile.constants.MAP_ID
...


And now we should be able to open the file again normally:

>>> # Now we don't need permissive mode to open the file any more:
>>> mrc = mrcfile.open('invalid.mrc')
>>> mrc.close()


The problems that can cause an exception when opening an MRC file are:

1.
The header's map field is not set correctly to confirm the file type. If the file is otherwise correct, permissive mode should be able to read the file normally.
2.
The machine stamp is invalid and so the file's byte order cannot be determined. In this case, permissive mode assumes that the byte order is little-endian and continues trying to read the file. If the file is actually big-endian, the mode and data size checks will also fail because these values depend on the endianness and will be nonsensical.
3.
The mode number is not recognised. Currently accepted modes are 0, 1, 2, 4 and 6.
4.
The data block is not large enough for the specified data type and dimensions.

In the last two cases, the data block will not be read and the data attribute will be set to None.

Fixing invalid files can be quite complicated! This usage guide might be expanded in future to explain how to analyse and fix problems, or the library itself might be improved to fix certain problems automatically. For now, if you have trouble with an invalid file, inspecting the code in this library might help you to work out how to approach the problem (start with MrcInterpreter._read_header()), or you could try asking on the CCP-EM mailing list for advice.

mrcfile follows the Python / C-style convention for axis ordering. This means that the first index is the slowest axis (typically Z for volume data or Y for images) and the last index is the fastest axis (typically X), and the numpy arrays are C-contiguous:

>>> data = mrcfile.read('tmp.mrc')
>>> data
array([[ 0,  1,  2,  3],

[ 4, 5, 6, 7],
[ 8, 9, 10, 11]], dtype=int8) >>> data[1, 0] # x = 0, y = 1 4 >>> data[2, 3] # x = 3, y = 2 11 >>> data.flags.c_contiguous True >>> data.flags.f_contiguous False


Note that this axis order is the opposite of the FORTRAN-style convention that is used by some other software in structural biology. This can cause confusing errors!

The header and data arrays can be accessed using the header, extended_header and data attributes:

>>> mrc = mrcfile.open('tmp.mrc')
>>> mrc.header
rec.array((4, 3, 1, ...),

dtype=[('nx', ...)]) >>> mrc.extended_header array([],
dtype='|V1') >>> mrc.data array([[ 0, 1, 2, 3],
[ 4, 5, 6, 7],
[ 8, 9, 10, 11]], dtype=int8) >>> mrc.close()


These attributes are read-only and cannot be assigned to directly, but (unless the file mode is r) the arrays can be modified in-place:

>>> mrc = mrcfile.open('tmp.mrc', mode='r+')
>>> # A new data array cannot be assigned directly to the data attribute
>>> mrc.data = np.ones_like(example_data)
Traceback (most recent call last):

... AttributeError: can't set attribute >>> # But the data can be modified by assigning to a slice or index >>> mrc.data[0, 0] = 10 >>> mrc.data array([[10, 1, 2, 3],
[ 4, 5, 6, 7],
[ 8, 9, 10, 11]], dtype=int8) >>> # All of the data values can be replaced this way, as long as the data >>> # size, shape and type are not changed >>> mrc.data[:] = np.ones_like(example_data) >>> mrc.data array([[1, 1, 1, 1],
[1, 1, 1, 1],
[1, 1, 1, 1]], dtype=int8) >>> mrc.close()


To replace the data or extended header completely, call the set_data() and set_extended_header() methods:

>>> mrc = mrcfile.open('tmp.mrc', mode='r+')
>>> data_3d = np.linspace(-1000, 1000, 20, dtype=np.int16).reshape(2, 2, 5)
>>> mrc.set_data(data_3d)
>>> mrc.data
array([[[-1000,  -894,  -789,  -684,  -578],

[ -473, -368, -263, -157, -52]],
[[ 52, 157, 263, 368, 473],
[ 578, 684, 789, 894, 1000]]], dtype=int16) >>> # Setting a new data array updates the header dimensions to match >>> mrc.header.nx array(5, dtype=int32) >>> mrc.header.ny array(2, dtype=int32) >>> mrc.header.nz array(2, dtype=int32) >>> # We can also set the extended header in the same way >>> string_array = np.fromstring(b'The extended header can hold any kind of numpy array', dtype='S52') >>> mrc.set_extended_header(string_array) >>> mrc.extended_header array([b'The extended header can hold any kind of numpy array'],
dtype='|S52') >>> # Setting the extended header updates the header's nsymbt field to match >>> mrc.header.nsymbt array(52, dtype=int32) >>> mrc.close()


Note that setting an extended header does not automatically set or change the header's exttyp field. You should set this yourself to identify the type of extended header you are using.

For a quick overview of the contents of a file's header, call print_header():

>>> with mrcfile.open('tmp.mrc') as mrc:
...     mrc.print_header()
...
nx              : 5
ny              : 2
nz              : 2
mode            : 1
nxstart ...


The voxel (or pixel) size in the file can be accessed using the voxel_size attribute, which returns a numpy record array with three fields, x, y and z, for the voxel size in each dimension:

>>> with mrcfile.open('tmp.mrc') as mrc:
...     mrc.voxel_size
...
rec.array((0.,  0.,  0.),

dtype=[('x', '<f4'), ('y', '<f4'), ('z', '<f4')])


In a new file, the voxel size is zero by default. To set the voxel size, you can assign to the voxel_size attribute, using a single number (for an isotropic voxel size), a 3-tuple or a single-item record array with x, y and z fields (which must be in that order):

>>> mrc = mrcfile.open('tmp.mrc', mode='r+')
>>> # Set a new isotropic voxel size:
>>> mrc.voxel_size = 1.0
>>> mrc.voxel_size
rec.array((1.,  1.,  1.),

dtype=[('x', '<f4'), ('y', '<f4'), ('z', '<f4')]) >>> # Set an anisotropic voxel size using a tuple: >>> mrc.voxel_size = (1.0, 2.0, 3.0) >>> mrc.voxel_size rec.array((1., 2., 3.),
dtype=[('x', '<f4'), ('y', '<f4'), ('z', '<f4')]) >>> # And set a different anisotropic voxel size using a record array: >>> mrc.voxel_size = np.rec.array(( 4., 5., 6.), dtype=[('x', '<f4'), ('y', '<f4'), ('z', '<f4')]) >>> mrc.voxel_size rec.array((4., 5., 6.),
dtype=[('x', '<f4'), ('y', '<f4'), ('z', '<f4')]) >>> mrc.close()


The sizes are not stored directly in the MRC header, but are calculated when required from the header's cell and grid size fields. The voxel size can therefore be changed by altering the cell size:

>>> mrc = mrcfile.open('tmp.mrc', mode='r+')
>>> # Check the current voxel size in X:
>>> mrc.voxel_size.x
array(4., dtype=float32)
>>> # And check the current cell dimensions:
>>> mrc.header.cella
rec.array((20.,  10.,  6.),

dtype=[('x', '<f4'), ('y', '<f4'), ('z', '<f4')]) >>> # Now change the cell's X length: >>> mrc.header.cella.x = 10 >>> # And we see the voxel size has also changed: >>> mrc.voxel_size.x array(2., dtype=float32) >>> mrc.close()


Equivalently, the cell size will be changed if a new voxel size is given:

>>> mrc = mrcfile.open('tmp.mrc', mode='r+')
>>> # Check the current cell dimensions:
>>> mrc.header.cella
rec.array((10.,  10.,  6.),

dtype=[('x', '<f4'), ('y', '<f4'), ('z', '<f4')]) >>> # Set a new voxel size: >>> mrc.voxel_size = 1.0 >>> # And our cell size has been updated: >>> mrc.header.cella rec.array((5., 2., 1.),
dtype=[('x', '<f4'), ('y', '<f4'), ('z', '<f4')]) >>> mrc.close()


Because the voxel size array is calculated on demand, assigning back to it wouldn't work so it's flagged as read-only:

>>> mrc = mrcfile.open('tmp.mrc', mode='r+')
>>> # This doesn't work
>>> mrc.voxel_size.x = 2.0
Traceback (most recent call last):

... ValueError: assignment destination is read-only >>> # But you can do this >>> vsize = mrc.voxel_size.copy() >>> vsize.x = 2.0 >>> mrc.voxel_size = vsize >>> mrc.voxel_size rec.array((2., 1., 1.),
dtype=[('x', '<f4'), ('y', '<f4'), ('z', '<f4')]) >>> mrc.close()


Note that the calculated voxel size will change if the grid size is changed by replacing the data array:

>>> mrc = mrcfile.open('tmp.mrc', mode='r+')
>>> # Check the current voxel size:
>>> mrc.voxel_size
rec.array((2.,  1.,  1.),

dtype=[('x', '<f4'), ('y', '<f4'), ('z', '<f4')]) >>> # And the current data dimensions: >>> mrc.data.shape (2, 2, 5) >>> # Replace the data with an array with a different shape: >>> mrc.set_data(example_data) >>> mrc.data.shape (3, 4) >>> # ...and the voxel size has changed: >>> mrc.voxel_size rec.array((2.5, 0.6666667, 1.),
dtype=[('x', '<f4'), ('y', '<f4'), ('z', '<f4')]) >>> mrc.close()


When a new data array is given (using set_data() or the data argument to mrcfile.new()), the header is automatically updated to ensure the file is is valid:

>>> mrc = mrcfile.open('tmp.mrc', mode='r+')
>>> # Check the current data shape and header dimensions match
>>> mrc.data.shape
(3, 4)
>>> mrc.header.nx
array(4, dtype=int32)
>>> mrc.header.nx == mrc.data.shape[-1]  # X axis is always the last in shape
True
>>> # Let's also check the maximum value recorded in the header
>>> mrc.header.dmax
array(11., dtype=float32)
>>> mrc.header.dmax == mrc.data.max()
True
>>> # Now set a data array with a different shape, and check the header again
>>> mrc.set_data(data_3d)
>>> mrc.data.shape
(2, 2, 5)
>>> mrc.header.nx
array(5, dtype=int32)
>>> mrc.header.nx == mrc.data.shape[-1]
True
>>> # The data statistics are updated as well
>>> mrc.header.dmax
array(1000., dtype=float32)
>>> mrc.header.dmax == mrc.data.max()
True
>>> mrc.close()


If the data array is modified in place, for example by editing values or changing the shape or dtype attributes, the header will no longer be correct:

>>> mrc = mrcfile.open('tmp.mrc', mode='r+')
>>> mrc.data.shape
(2, 2, 5)
>>> # Change the data shape in-place and check the header
>>> mrc.data.shape = (5, 4)
>>> mrc.header.nx == mrc.data.shape[-1]
False
>>> # We'll also change some values and check the data statistics
>>> mrc.data[2:] = 0
>>> mrc.data.max()
0
>>> mrc.header.dmax == mrc.data.max()
False
>>> mrc.close()


Note that the header is deliberately not updated automatically except when set_data() is called, so if you need to override any of the automatic header values you can do.

To keep the header in sync with the data, three methods can be used to update the header:

  • update_header_from_data(): This updates the header's dimension fields, mode, space group and machine stamp to be consistent with the data array. Because it only inspects the data array's attributes, this method is fast even for very large arrays.
  • update_header_stats(): This updates the data statistics fields in the header (dmin, dmax, dmean and rms). This method can be slow with large data arrays because it has to access the full contents of the array.
  • reset_header_stats(): If the data values have changed and the statistics fields are invalid, but the data array is very large and you do not want to wait for update_header_stats() to run, you can call this method to reset the header's statistics fields to indicate that the values are undetermined.

The file we just saved had an invalid header, but of course, that's what's used by mrcfile to work out how to read the file from disk! When we open the file again, our change to the shape has disappeared:

>>> mrc = mrcfile.open('tmp.mrc', mode='r+')
>>> mrc.data.shape
(2, 2, 5)
>>> # Let's change the shape again, as we did before
>>> mrc.data.shape = (5, 4)
>>> mrc.header.nx == mrc.data.shape[-1]
False
>>> # Now let's update the dimensions:
>>> mrc.update_header_from_data()
>>> mrc.header.nx
array(4, dtype=int32)
>>> mrc.header.nx == mrc.data.shape[-1]
True
>>> # The data statistics are still incorrect:
>>> mrc.header.dmax
array(1000., dtype=float32)
>>> mrc.header.dmax == mrc.data.max()
False
>>> # So let's update those as well:
>>> mrc.update_header_stats()
>>> mrc.header.dmax
array(0., dtype=float32)
>>> mrc.header.dmax == mrc.data.max()
True
>>> mrc.close()


In general, if you're changing the shape, type or endianness of the data, it's easiest to use set_data() and the header will be kept up to date for you. If you start changing values in the data, remember that the statistics in the header will be out of date until you call update_header_stats() or reset_header_stats().

MRC files can be used to store several types of data: single images, image stacks, volumes and volume stacks. These are distinguished by the dimensionality of the data array and the space group number (the header's ispg field):

Data type Dimensions Space group
Single image 2 0
Image stack 3 0
Volume 3 1--230 (1 for normal EM data)
Volume stack 4 401--630 (401 for normal EM data)

MrcFile objects have methods to allow easy identification of the data type: is_single_image(), is_image_stack(), is_volume() and is_volume_stack().

>>> mrc = mrcfile.open('tmp.mrc')
>>> # The file currently contains two-dimensional data
>>> mrc.data.shape
(5, 4)
>>> len(mrc.data.shape)
2
>>> # This is intepreted as a single image
>>> mrc.is_single_image()
True
>>> mrc.is_image_stack()
False
>>> mrc.is_volume()
False
>>> mrc.is_volume_stack()
False
>>> mrc.close()


If a file already contains image or image stack data, new three-dimensional data is treated as an image stack; otherwise, 3D data is treated as a volume by default:

>>> mrc = mrcfile.open('tmp.mrc', mode='r+')
>>> # New 3D data in an existing image file is treated as an image stack:
>>> mrc.set_data(data_3d)
>>> len(mrc.data.shape)
3
>>> mrc.is_volume()
False
>>> mrc.is_image_stack()
True
>>> int(mrc.header.ispg)
0
>>> mrc.close()
>>> # But normally, 3D data is treated as a volume:
>>> mrc = mrcfile.new('tmp.mrc', overwrite=True)
>>> mrc.set_data(data_3d)
>>> mrc.is_volume()
True
>>> mrc.is_image_stack()
False
>>> int(mrc.header.ispg)
1
>>> mrc.close()


Call set_image_stack() and set_volume() to change the interpretation of 3D data. (Note: as well as changing ispg, these methods also change mz to be 1 for image stacks and equal to nz for volumes.)

>>> mrc = mrcfile.open('tmp.mrc', mode='r+')
>>> # Change the file to represent an image stack:
>>> mrc.set_image_stack()
>>> mrc.is_volume()
False
>>> mrc.is_image_stack()
True
>>> int(mrc.header.ispg)
0
>>> # And now change it back to representing a volume:
>>> mrc.set_volume()
>>> mrc.is_volume()
True
>>> mrc.is_image_stack()
False
>>> int(mrc.header.ispg)
1
>>> mrc.close()


Note that the MRC format allows the data axes to be swapped using the header's mapc, mapr and maps fields. This library does not attempt to swap the axes and simply assigns the columns to X, rows to Y and sections to Z. (The data array is indexed in C style, so data values can be accessed using mrc.data[z][y][x].) In general, EM data is written using the default axes, but crystallographic data files might use swapped axes in certain space groups -- if this might matter to you, you should check the mapc, mapr and maps fields after opening the file and consider transposing the data array if necessary.

Various numpy data types can be used for MRC data arrays. The conversions to MRC mode numbers are:

Data type MRC mode
float16 12 (see note below)
float32 2
int8 0
int16 1
uint8 6 (note that data will be widened to 16 bits in the file)
uint16 6
complex64 4

(Mode 3 and the proposed 4-bit mode 101 are not supported since there are no corresponding numpy dtypes.)

Note that mode 12 is a proposed extension to the MRC2014 format and is not yet widely supported by other software. If you need to write float16 data to MRC files in a compatible way, you should cast to float32 first and use mode 2.

No other data types are accepted, including integer types of more than 16 bits, or float types of more than 32 bits. Many numpy array creation routines use int64 or float64 dtypes by default, which means you will need to give a dtype argument to ensure the array can be used in an MRC file:

>>> mrc = mrcfile.open('tmp.mrc', mode='r+')
>>> # This does not work
>>> mrc.set_data(np.zeros((4, 5)))
Traceback (most recent call last):

... ValueError: dtype 'float64' cannot be converted to an MRC file mode >>> # But this does >>> mrc.set_data(np.zeros((4, 5), dtype=np.int16)) >>> mrc.data array([[0, 0, 0, 0, 0],
[0, 0, 0, 0, 0],
[0, 0, 0, 0, 0],
[0, 0, 0, 0, 0]], dtype=int16) >>> mrc.close()


Warning: be careful if you have an existing numpy array in float64, int64 or int32 data types. If they try to convert them into one of the narrower types supported by mrcfile and they contain values outside the range of the target type, the values will silently overflow. For floating point formats this can lead to inf values, and with integers it can lead to entirely meaningless values. A full discussion of this issue is outside the scope of this guide; see the numpy documentation for more information.

mrcfile provides two ways of improving performance when handling large files: memory mapping and asynchronous (background) opening. Memory mapping treats the file's data on disk as if it is already in memory, and only actually loads the data in small chunks when it is needed. Asynchronous opening uses a separate thread to open the file, allowing the main thread to carry on with other work while the file is loaded from disk in parallel.

Which technique is better depends on what you intend to do with the file and the characteristics of your computer, and it's usually worth testing both approaches and seeing what works best for your particular task. In general, memory mapping gives better performance when dealing with a single file, particularly if the file is very large. If you need to process several files, asynchronous opening can be faster because you can work on one file while loading the next one.

With very large files, it might be helpful to use the mrcfile.mmap() function to open the file, which will open the data as a memory-mapped numpy array. The contents of the array are only read from disk as needed, so this allows large files to be opened very quickly. Parts of the data can then be read and written by slicing the array:

>>> # Let's make a new file to work with (only small for this example!)
>>> mrcfile.write('maybe_large.mrc', example_data)
>>> # Open the file in memory-mapped mode
>>> mrc = mrcfile.mmap('maybe_large.mrc', mode='r+')
>>> # Now read part of the data by slicing
>>> mrc.data[1:3]
memmap([[ 4,  5,  6,  7],

[ 8, 9, 10, 11]], dtype=int8) >>> # Set some values by assigning to a slice >>> mrc.data[1:3,1:3] = 0 >>> # Read the entire array - with large files this might take a while! >>> mrc.data[:] memmap([[ 0, 1, 2, 3],
[ 4, 0, 0, 7],
[ 8, 0, 0, 11]], dtype=int8) >>> mrc.close()


To create new large, empty files quickly, use the mrcfile.new_mmap() function. This creates an empty file with a given shape and data mode. An optional fill value can be provided but filling a very large mmap array can take a long time, so it's best to use this only when needed. If you plan to fill the array with other data anyway, it's better to leave the fill value as None. A typical use case would be to create a new file and then fill it slice by slice:

>>> # Make a new, empty memory-mapped MRC file
>>> mrc = mrcfile.new_mmap('mmap.mrc', shape=(3, 3, 4), mrc_mode=0)
>>> # Fill each slice with a different value
>>> for val in range(len(mrc.data)):
...     mrc.data[val] = val
...
>>> mrc.data[:]
memmap([[[0, 0, 0, 0],

[0, 0, 0, 0],
[0, 0, 0, 0]],
[[1, 1, 1, 1],
[1, 1, 1, 1],
[1, 1, 1, 1]],
[[2, 2, 2, 2],
[2, 2, 2, 2],
[2, 2, 2, 2]]], dtype=int8)


When processing several files in a row, asynchronous (background) opening can improve performance by allowing you to open multiple files in parallel. The mrcfile.open_async() function starts a background thread to open a file, and returns a FutureMrcFile object which you can call later to get the file after it's been opened:

>>> # Open the first example file
>>> mrc1 = mrcfile.open('maybe_large.mrc')
>>> # Start opening the second example file before we process the first
>>> future_mrc2 = mrcfile.open_async('tmp.mrc.gz')
>>> # Now we'll do some calculations with the first file
>>> mrc1.data.sum()
36
>>> # Get the second file from its "Future" container ('result()' will wait
>>> # until the file is ready)
>>> mrc2 = future_mrc2.result()
>>> # Before we process the second file, we'll start the third one opening
>>> future_mrc3 = mrcfile.open_async('tmp.mrc.bz2')
>>> mrc2.data.max()
22
>>> # Finally, we'll get the third file and process it
>>> mrc3 = future_mrc3.result()
>>> mrc3.data
array([[ 0,  3,  6,  9],

[12, 15, 18, 21],
[24, 27, 30, 33]], dtype=int8)


As we saw in that example, calling result() will give us the MrcFile from the file opening operation. If the file hasn't been fully opened yet, result() will simply wait until it's ready. To avoid waiting, call done() to check if it's finished.

MRC files can be validated with mrcfile.validate(), which prints an explanation of what is happening and also returns True if the file is valid or False otherwise:

>>> mrcfile.validate('tmp.mrc')
Checking if tmp.mrc is a valid MRC2014 file...
File appears to be valid.
True


This works equally well for gzip- or bzip2-compressed files:

>>> mrcfile.validate('tmp.mrc.gz')
Checking if tmp.mrc.gz is a valid MRC2014 file...
File appears to be valid.
True
>>> mrcfile.validate('tmp.mrc.bz2')
Checking if tmp.mrc.bz2 is a valid MRC2014 file...
File appears to be valid.
True


Errors will cause messages to be printed to the console, and validate() will return False:

>>> # Let's make a file which is valid except for the header's mz value
>>> with mrcfile.new('tmp.mrc', overwrite=True) as mrc:
...     mrc.set_data(example_data)
...     mrc.header.mz = -1
...
>>> # Now it should fail validation and print a helpful message
>>> mrcfile.validate('tmp.mrc')
Checking if tmp.mrc is a valid MRC2014 file...
Header field 'mz' is negative
False


(More serious errors might also cause warnings to be printed to sys.stderr.)

Normally, messages are printed to sys.stdout (as normal for Python print() calls). validate() has an optional print_file argument which allows any text stream to be used for the output instead:

>>> # Create a text stream to capture the output
>>> import io
>>> output = io.StringIO()
>>> # Now validate the file...
>>> mrcfile.validate('tmp.mrc', print_file=output)
False
>>> # ...and check the output separately
>>> print(output.getvalue().strip())
Checking if tmp.mrc is a valid MRC2014 file...
Header field 'mz' is negative


Behind the scenes, mrcfile.validate() opens the file in permissive mode using mrcfile.open() and then calls MrcFile.validate(). If you already have an MrcFile open, you can call its validate() method directly to check the file -- but note that the file size test might be inaccurate unless you call flush() first. To ensure the file is completely valid, it's best to flush or close the file and then validate it from scratch using mrcfile.validate().

If you find that a file created with this library is invalid, and you haven't altered anything in the header in a way that might cause problems, please file a bug report on the issue tracker!

Some mrcfile functionality is available directly from the command line, via scripts that are installed along with the package, or in some cases by running modules with python -m.

(If you've downloaded the source code instead of installing via pip, run pip install <path-to-mrcfile> or python setup.py install to make the command line scripts available.)

MRC files can be validated with the mrcfile-validate script:

$ mrcfile-validate tests/test_data/EMD-3197.map
Checking if tests/test_data/EMD-3197.map is a valid MRC2014 file...
File does not declare MRC format version 20140 or 20141: nversion = 0
$ # Exit status is 1 if file is invalid
$ echo $?
1


This script wraps the mrcfile.validator module, which can also be called directly:

$ python -m mrcfile.validator valid_file.mrc
Checking if valid_file.mrc is a valid MRC2014 file...
File appears to be valid.
$ echo $?
0


Multiple file names can be passed to either form of the command, and because these commands call mrcfile.validate() behind the scenes, gzip- and bzip2-compressed files can be validated as well:

$ mrcfile-validate valid_file_1.mrc valid_file_2.mrc.gz valid_file_3.mrc.bz2
Checking if valid_file_1.mrc is a valid MRC2014 file...
File appears to be valid.
Checking if valid_file_2.mrc is a valid MRC2014 file...
File appears to be valid.
Checking if valid_file_3.mrc is a valid MRC2014 file...
File appears to be valid.


MRC file headers can be printed to the console with the mrcfile-header script:

$ mrcfile-header tests/test_data/EMD-3197.map
MRC header for tests/test_data/EMD-3197.map:
nx              : 20
ny              : 20
nz              : 20
mode            : 2
nxstart         : -2
nystart         : 0
nzstart         : 0
mx              : 20
my              : 20
mz              : 20
cella           : (228.0, 228.0, 228.0)
cellb           : (90.0, 90.0, 90.0)
...
...


Like mrcfile-validate, this also works for multiple files. If you want to access the same functionality from within Python, call print_header() on an open MrcFile object, or mrcfile.command_line.print_headers() with a list of file names.

The following classes are provided by the mrcfile.py library:

  • MrcObject: Represents a generic MRC-like data object in memory, and provides header, extended header and data arrays and methods for operating on them.
  • MrcInterpreter: Subclass of MrcObject that can read and/or write its MRC data from arbitrary byte I/O streams (including Python file objects).
  • MrcFile: Subclass of MrcInterpreter that opens a file from disk to use as its I/O stream. This is the normal class used for most interactions with MRC files.
  • GzipMrcFile: Reads and writes MRC data using compressed gzip files.
  • Bzip2MrcFile: Reads and writes MRC data using compressed bzip2 files.
  • MrcMemmap: Uses a memory-mapped data array, for fast random access to very large data files. MrcMemmap overrides various parts of the MrcFile implementation to ensure that the memory-mapped data array is opened, closed and moved correctly when the data or extended header array sizes are changed.

Attributes:

  • header
  • extended_header
  • data
  • voxel_size

Methods:

  • set_extended_header()
  • set_data()
  • is_single_image()
  • is_image_stack()
  • is_volume()
  • is_volume_stack()
  • set_image_stack()
  • set_volume()
  • update_header_from_data()
  • update_header_stats()
  • reset_header_stats()
  • print_header()
  • validate()
  • flush()
  • close()

A pure Python implementation of the MRC2014 file format.

For a full introduction and documentation, see http://mrcfile.readthedocs.io/

  • new(): Create a new MRC file.
  • open(): Open an MRC file.
  • open_async(): Open an MRC file asynchronously.
  • mmap(): Open a memory-mapped MRC file (fast for large files).
  • new_mmap(): Create a new empty memory-mapped MRC file (fast for large files).
  • validate(): Validate an MRC file

Basic usage

Examples assume that this package has been imported as mrcfile and numpy has been imported as np.

To open an MRC file and read a slice of data:

>>> with mrcfile.open('tests/test_data/EMD-3197.map') as mrc:
...     mrc.data[10,10]
...
array([ 2.58179283,  3.1406002 ,  3.64495397,  3.63812137,  3.61837363,

4.0115056 , 3.66981959, 2.07317996, 0.1251585 , -0.87975615,
0.12517013, 2.07319379, 3.66982722, 4.0115037 , 3.61837196,
3.6381247 , 3.64495087, 3.14059472, 2.58178973, 1.92690361], dtype=float32)

To create a new file with a 2D data array, and change some values:

>>> with mrcfile.new('tmp.mrc') as mrc:
...     mrc.set_data(np.zeros((5, 5), dtype=np.int8))
...     mrc.data[1:4,1:4] = 10
...     mrc.data
...
array([[ 0,  0,  0,  0,  0],

[ 0, 10, 10, 10, 0],
[ 0, 10, 10, 10, 0],
[ 0, 10, 10, 10, 0],
[ 0, 0, 0, 0, 0]], dtype=int8)

The MRC2014 format was described in the Journal of Structural Biology: http://dx.doi.org/10.1016/j.jsb.2015.04.002

The format specification is available on the CCP-EM website: http://www.ccpem.ac.uk/mrc_format/mrc2014.php

Create a new MRC file.
  • name -- The file name to use, as a string or Path.
  • data -- Data to put in the file, as a numpy array. The default is None, to create an empty file.
  • compression -- The compression format to use. Acceptable values are: None (the default; for no compression), 'gzip' or 'bzip2'. It's good practice to name compressed files with an appropriate extension (for example, .mrc.gz for gzip) but this is not enforced.
  • overwrite -- Flag to force overwriting of an existing file. If False and a file of the same name already exists, the file is not overwritten and an exception is raised.

An MrcFile object (or a subclass of it if compression is specified).
  • ValueError -- If the file already exists and overwrite is
    False.
  • ValueError -- If the compression format is not recognised.

RuntimeWarning -- If the data array contains Inf or NaN values.


Open an MRC file.

This function opens both normal and compressed MRC files. Supported compression formats are: gzip, bzip2.

It is possible to use this function to create new MRC files (using mode w+) but the new() function is more flexible.

This function offers a permissive read mode for attempting to open corrupt or invalid files. In permissive mode, warnings are issued instead of exceptions if problems with the file are encountered. See MrcInterpreter or the usage guide for more information.

  • name -- The file name to open, as a string or Path.
  • mode -- The file mode to use. This should be one of the following: r for read-only, r+ for read and write, or w+ for a new empty file. The default is r.
  • permissive -- Read the file in permissive mode. The default is False.
  • header_only -- Only read the header (and extended header) from the file. The default is False.

An MrcFile object (or a GzipMrcFile object if the file is gzipped).
  • ValueError -- If the mode is not one of r, r+ or w+.
  • ValueError -- If the file is not a valid MRC file and
    permissive is False.
  • ValueError -- If the mode is w+ and the file already exists.
    (Call new() with overwrite=True to deliberately overwrite
    an existing file.)
  • OSError -- If the mode is r or r+ and the file does not
    exist.

  • RuntimeWarning -- If the file appears to be a valid MRC file but the data block is longer than expected from the dimensions in the header.
  • RuntimeWarning -- If the file is not a valid MRC file and permissive is True.
  • RuntimeWarning -- If the header's exttyp field is set to a known value but the extended header's size is not a multiple of the number of bytes in the corresponding dtype.



Read an MRC file's data into a numpy array.

This is a convenience function to read the data from an MRC file when there is no need for the file's header information. To read the headers as well, or if you need access to an MrcFile object representing the file, use mrcfile.open() instead.

name -- The file name to read, as a string or Path.
A numpy array containing the data from the file.


Write a new MRC file.

This is a convenience function to allow data to be quickly written to a file (with optional compression) using just a single function call. However, there is no control over the file's metadata except for optionally setting the voxel size. For more control, or if you need access to an MrcFile object representing the new file, use mrcfile.new() instead.

  • name -- The file name to use, as a string or Path. If the name ends with .gz or .bz2, the file will be compressed using gzip or bzip2 respectively.
  • data -- Data to put in the file, as a numpy array. The default is None, to create an empty file.
  • overwrite -- Flag to force overwriting of an existing file. If False and a file of the same name already exists, the file is not overwritten and an exception is raised.
  • voxel_size -- float | 3-tuple The voxel size to be written in the file header.

ValueError -- If the file already exists and overwrite is
False.
RuntimeWarning -- If the data array contains Inf or NaN values.


Open an MRC file asynchronously in a separate thread.

This allows a file to be opened in the background while the main thread continues with other work. This can be a good way to improve performance if the main thread is busy with intensive computation, but will be less effective if the main thread is itself busy with disk I/O.

Multiple files can be opened in the background simultaneously. However, this implementation is relatively crude; each call to this function will start a new thread and immediately use it to start opening a file. If you try to open many large files at the same time, performance will decrease as all of the threads attempt to access the disk at once. You'll also risk running out of memory to store the data from all the files.

This function returns a FutureMrcFile object, which deliberately mimics the API of the Future object from Python 3's concurrent.futures module. (Future versions of this library might return genuine Future objects instead.)

To get the real MrcFile object from a FutureMrcFile, call result(). This will block until the file has been read and the MrcFile object is ready. To check if the MrcFile is ready without blocking, call running() or done().

  • name -- The file name to open, as a string or Path.
  • mode -- The file mode (one of r, r+ or w+).
  • permissive -- Read the file in permissive mode. The default is False.

A FutureMrcFile object.


Open a memory-mapped MRC file.

This allows much faster opening of large files, because the data is only accessed on disk when a slice is read or written from the data array. See the MrcMemmap class documentation for more information.

Because the memory-mapped data array accesses the disk directly, compressed files cannot be opened with this function. In all other ways, mmap() behaves in exactly the same way as open(). The MrcMemmap object returned by this function can be used in exactly the same way as a normal MrcFile object.

  • name -- The file name to open, as a string or Path.
  • mode -- The file mode (one of r, r+ or w+).
  • permissive -- Read the file in permissive mode. The default is False.

An MrcMemmap object.


Create a new, empty memory-mapped MRC file.

This function is useful for creating very large files. The initial contents of the data array can be set with the fill parameter if needed, but be aware that filling a large array can take a long time.

If fill is not set, the new data array's contents are unspecified and system-dependent. (Some systems fill a new empty mmap with zeros, others fill it with the bytes from the disk at the newly-mapped location.) If you are definitely going to fill the entire array with new data anyway you can safely leave fill as None, otherwise it is advised to use a sensible fill value (or ensure you are on a system that fills new mmaps with a reasonable default value).

  • name -- The file name to use, as a string or Path.
  • shape -- The shape of the data array to open, as a 2-, 3- or 4-tuple of ints. For example, (nz, ny, nx) for a new 3D volume, or (ny, nx) for a new 2D image.
  • mrc_mode --

    The MRC mode to use for the new file. One of 0, 1, 2, 4 or 6, which correspond to numpy dtypes as follows:

  • mode 0 -> int8
  • mode 1 -> int16
  • mode 2 -> float32
  • mode 4 -> complex64
  • mode 6 -> uint16

The default is 0.

  • fill -- An optional value to use to fill the new data array. If None, the data array will not be filled and its contents are unspecified. Numpy's usual rules for rounding or rejecting values apply, according to the dtype of the array.
  • overwrite -- Flag to force overwriting of an existing file. If False and a file of the same name already exists, the file is not overwritten and an exception is raised.
  • extended_header -- The extended header object
  • exttyp -- The extended header type

A new MrcMemmap object.
  • ValueError -- If the MRC mode is invalid.
  • ValueError -- If the file already exists and overwrite is
    False.



Validate an MRC file.

This function first opens the file by calling open() (with permissive=True), then calls validate(), which runs a series of tests to check whether the file complies with the MRC2014 format specification.

If the file is completely valid, this function returns True, otherwise it returns False. Messages explaining the validation result will be printed to sys.stdout by default, but if a text stream is given (using the print_file argument) output will be printed to that instead.

Badly invalid files will also cause warning messages to be issued, which will be written to sys.stderr by default. See the documentation of the warnings module for information on how to suppress or capture warning output.

Because the file is opened by calling open(), gzip- and bzip2-compressed MRC files can be validated easily using this function.

After the file has been opened, it is checked for problems. The tests are:

1.
MRC format ID string: The map field in the header should contain "MAP ".
2.
Machine stamp: The machine stamp should contain one of 0x44 0x44 0x00 0x00, 0x44 0x41 0x00 0x00 or 0x11 0x11 0x00 0x00.
3.
MRC mode: the mode field should be one of the supported mode numbers: 0, 1, 2, 4, 6 or 12. (Note that MRC modes 3 and 101 are also valid according to the MRC 2014 specification but are not supported by mrcfile.)
4.
Map and cell dimensions: The header fields nx, ny, nz, mx, my, mz, cella.x, cella.y and cella.z must all be positive numbers.
5.
Axis mapping: Header fields mapc, mapr and maps must contain the values 1, 2, and 3 (in any order).
6.
Volume stack dimensions: If the spacegroup is in the range 401--630, representing a volume stack, the nz field should be exactly divisible by mz to represent the number of volumes in the stack.
7.
Header labels: The nlabl field should be set to indicate the number of labels in use, and the labels in use should appear first in the label array.
8.
MRC format version: The nversion field should be 20140 or 20141 for compliance with the MRC2014 standard.
9.
Extended header type: If an extended header is present, the exttyp field should be set to indicate the type of extended header.
10.
Data statistics: The statistics in the header should be correct for the actual data in the file, or marked as undetermined.
11.
File size: The size of the file on disk should match the expected size calculated from the MRC header.

  • name -- The file name to open and validate.
  • print_file -- The output text stream to use for printing messages about the validation. This is passed directly to the file argument of Python's print() function. The default is None, which means output will be printed to sys.stdout.

True if the file is valid, or False if the file does not meet the MRC format specification in any way.
OSError -- If the file does not exist or cannot be opened.
RuntimeWarning -- If the file is seriously invalid because it has no map ID string, an incorrect machine stamp, an unknown mode number, or is not the same size as expected from the header.


Module which exports the Bzip2MrcFile class.

Bzip2MrcFile: An object which represents a bzip2-compressed MRC file.

Bases: MrcFile

MrcFile subclass for handling bzip2-compressed files.

Usage is the same as for MrcFile.

_open_file(name)
Override _open_file() to open a bzip2 file.

_read(header_only=False)
Override _read() to ensure bzip2 file is in read mode.

_ensure_readable_bzip2_stream()
Make sure _iostream is a bzip2 stream that can be read.

_get_file_size()
Override _get_file_size() to ensure stream is readable first.

_read_bytearray_from_stream(number_of_bytes)
Override because BZ2File in Python 2 does not support readinto().

Override flush() since BZ2File objects need special handling.


Module for functions used as command line entry points.

The names of the corresponding command line scripts can be found in the entry_points section of setup.py.

Print the MRC header contents from a list of files.

This function opens files in permissive mode to allow headers of invalid files to be examined.

  • names -- A list of file names. If not given or None, the names are taken from the command line arguments.
  • print_file -- The output text stream to use for printing the headers. This is passed directly to the print_file argument of print_header(). The default is None, which means output will be printed to sys.stdout.



Constants used by the mrcfile.py library.

numpy dtypes used by the mrcfile.py library.

The dtypes are defined in a separate module because they do not interact nicely with the from __future__ import unicode_literals feature used in the rest of the package.

Get a dtype for an extended header.
  • exttyp -- One of b'FEI1' or b'FEI2', which are currently the only supported extended header types.
  • byte_order -- One of =, < or >.

A numpy dtype object for the extended header, or None
ValueError -- If byte_order is not one of =, < or >.


Module which exports the FutureMrcFile class.


Bases: object

Object representing an MRC file being opened asynchronously.

This API deliberately mimics a Future object from the concurrent.futures module in Python 3.2+ (which we do not use directly because this code still needs to run in Python 2.7).

__init__(open_function, args=(), kwargs={})
Initialise a new FutureMrcFile object.

This constructor starts a new thread which will invoke the callable given in open_function with the given arguments.

  • open_function -- The callable to use to open the MRC file. (This will normally be mrcfile.open(), but could also be MrcFile or any of its subclasses.)
  • args -- A tuple of positional arguments to use when open_function is called. (Normally a 1-tuple containing the name of the file to open.)
  • kwargs -- A dictionary of keyword arguments to use when open_function is called.



_run(*args, **kwargs)
Call the open function and store the result in the holder list.

(For internal use only.)


Return False.

(See concurrent.futures.Future.cancel() for more details. This implementation does not allow jobs to be cancelled.)


Return False.

(See concurrent.futures.Future.cancelled() for more details. This implementation does not allow jobs to be cancelled.)


Return True if the MrcFile is currently being opened.

(See concurrent.futures.Future.running() for more details.)


Return True if the file opening has finished.

(See concurrent.futures.Future.done() for more details.)


Return the MrcFile that has been opened.

(See concurrent.futures.Future.result() for more details.)

timeout -- Time to wait (in seconds) for the file opening to finish. If timeout is not specified or is None, there is no limit to the wait time.
An MrcFile object (or one of its subclasses).
  • RuntimeError -- If the operation has not finished within the
    time limit set by timeout. (Note that the type of this
    exception will change in future if this class is replaced by
    concurrent.futures.Future.)
  • Exception -- Any exception raised by the
    MrcFile opening operation will be
    re-raised here.



Return the exception raised by the file opening operation.

(See concurrent.futures.Future.exception() for more details.)

timeout -- Time to wait (in seconds) for the operation to finish. If timeout is not specified or is None, there is no limit to the wait time.
An Exception, if one was raised by the file opening operation, or None if no exception was raised.
RuntimeError -- If the operation has not finished within the
time limit set by timeout. (Note that the type of this
exception will change in future if this class is replaced by
concurrent.futures.Future.)


_get_result(timeout)
Return the result or exception from the file opening operation.

(For internal use only.)


Not implemented.

(See concurrent.futures.Future.add_done_callback() for more details.)



Module which exports the GzipMrcFile class.

GzipMrcFile: An object which represents a gzipped MRC file.

Bases: MrcFile

MrcFile subclass for handling gzipped files.

Usage is the same as for MrcFile.

_open_file(name)
Override _open_file() to open both normal and gzip files.

_close_file()
Override _close_file() to close both normal and gzip files.

_read(header_only=False)
Override _read() to ensure gzip file is in read mode.

_ensure_readable_gzip_stream()
Make sure _iostream is a gzip stream that can be read.

_get_file_size()
Override _get_file_size() to avoid seeking from end.

Override flush() since GzipFile objects need special handling.


Module for top-level functions that open MRC files and form the main API of the package.

Create a new MRC file.
  • name -- The file name to use, as a string or Path.
  • data -- Data to put in the file, as a numpy array. The default is None, to create an empty file.
  • compression -- The compression format to use. Acceptable values are: None (the default; for no compression), 'gzip' or 'bzip2'. It's good practice to name compressed files with an appropriate extension (for example, .mrc.gz for gzip) but this is not enforced.
  • overwrite -- Flag to force overwriting of an existing file. If False and a file of the same name already exists, the file is not overwritten and an exception is raised.

An MrcFile object (or a subclass of it if compression is specified).
  • ValueError -- If the file already exists and overwrite is
    False.
  • ValueError -- If the compression format is not recognised.

RuntimeWarning -- If the data array contains Inf or NaN values.


Open an MRC file.

This function opens both normal and compressed MRC files. Supported compression formats are: gzip, bzip2.

It is possible to use this function to create new MRC files (using mode w+) but the new() function is more flexible.

This function offers a permissive read mode for attempting to open corrupt or invalid files. In permissive mode, warnings are issued instead of exceptions if problems with the file are encountered. See MrcInterpreter or the usage guide for more information.

  • name -- The file name to open, as a string or Path.
  • mode -- The file mode to use. This should be one of the following: r for read-only, r+ for read and write, or w+ for a new empty file. The default is r.
  • permissive -- Read the file in permissive mode. The default is False.
  • header_only -- Only read the header (and extended header) from the file. The default is False.

An MrcFile object (or a GzipMrcFile object if the file is gzipped).
  • ValueError -- If the mode is not one of r, r+ or w+.
  • ValueError -- If the file is not a valid MRC file and
    permissive is False.
  • ValueError -- If the mode is w+ and the file already exists.
    (Call new() with overwrite=True to deliberately overwrite
    an existing file.)
  • OSError -- If the mode is r or r+ and the file does not
    exist.

  • RuntimeWarning -- If the file appears to be a valid MRC file but the data block is longer than expected from the dimensions in the header.
  • RuntimeWarning -- If the file is not a valid MRC file and permissive is True.
  • RuntimeWarning -- If the header's exttyp field is set to a known value but the extended header's size is not a multiple of the number of bytes in the corresponding dtype.



Read an MRC file's data into a numpy array.

This is a convenience function to read the data from an MRC file when there is no need for the file's header information. To read the headers as well, or if you need access to an MrcFile object representing the file, use mrcfile.open() instead.

name -- The file name to read, as a string or Path.
A numpy array containing the data from the file.


Write a new MRC file.

This is a convenience function to allow data to be quickly written to a file (with optional compression) using just a single function call. However, there is no control over the file's metadata except for optionally setting the voxel size. For more control, or if you need access to an MrcFile object representing the new file, use mrcfile.new() instead.

  • name -- The file name to use, as a string or Path. If the name ends with .gz or .bz2, the file will be compressed using gzip or bzip2 respectively.
  • data -- Data to put in the file, as a numpy array. The default is None, to create an empty file.
  • overwrite -- Flag to force overwriting of an existing file. If False and a file of the same name already exists, the file is not overwritten and an exception is raised.
  • voxel_size -- float | 3-tuple The voxel size to be written in the file header.

ValueError -- If the file already exists and overwrite is
False.
RuntimeWarning -- If the data array contains Inf or NaN values.


Open an MRC file asynchronously in a separate thread.

This allows a file to be opened in the background while the main thread continues with other work. This can be a good way to improve performance if the main thread is busy with intensive computation, but will be less effective if the main thread is itself busy with disk I/O.

Multiple files can be opened in the background simultaneously. However, this implementation is relatively crude; each call to this function will start a new thread and immediately use it to start opening a file. If you try to open many large files at the same time, performance will decrease as all of the threads attempt to access the disk at once. You'll also risk running out of memory to store the data from all the files.

This function returns a FutureMrcFile object, which deliberately mimics the API of the Future object from Python 3's concurrent.futures module. (Future versions of this library might return genuine Future objects instead.)

To get the real MrcFile object from a FutureMrcFile, call result(). This will block until the file has been read and the MrcFile object is ready. To check if the MrcFile is ready without blocking, call running() or done().

  • name -- The file name to open, as a string or Path.
  • mode -- The file mode (one of r, r+ or w+).
  • permissive -- Read the file in permissive mode. The default is False.

A FutureMrcFile object.


Open a memory-mapped MRC file.

This allows much faster opening of large files, because the data is only accessed on disk when a slice is read or written from the data array. See the MrcMemmap class documentation for more information.

Because the memory-mapped data array accesses the disk directly, compressed files cannot be opened with this function. In all other ways, mmap() behaves in exactly the same way as open(). The MrcMemmap object returned by this function can be used in exactly the same way as a normal MrcFile object.

  • name -- The file name to open, as a string or Path.
  • mode -- The file mode (one of r, r+ or w+).
  • permissive -- Read the file in permissive mode. The default is False.

An MrcMemmap object.


Create a new, empty memory-mapped MRC file.

This function is useful for creating very large files. The initial contents of the data array can be set with the fill parameter if needed, but be aware that filling a large array can take a long time.

If fill is not set, the new data array's contents are unspecified and system-dependent. (Some systems fill a new empty mmap with zeros, others fill it with the bytes from the disk at the newly-mapped location.) If you are definitely going to fill the entire array with new data anyway you can safely leave fill as None, otherwise it is advised to use a sensible fill value (or ensure you are on a system that fills new mmaps with a reasonable default value).

  • name -- The file name to use, as a string or Path.
  • shape -- The shape of the data array to open, as a 2-, 3- or 4-tuple of ints. For example, (nz, ny, nx) for a new 3D volume, or (ny, nx) for a new 2D image.
  • mrc_mode --

    The MRC mode to use for the new file. One of 0, 1, 2, 4 or 6, which correspond to numpy dtypes as follows:

  • mode 0 -> int8
  • mode 1 -> int16
  • mode 2 -> float32
  • mode 4 -> complex64
  • mode 6 -> uint16

The default is 0.

  • fill -- An optional value to use to fill the new data array. If None, the data array will not be filled and its contents are unspecified. Numpy's usual rules for rounding or rejecting values apply, according to the dtype of the array.
  • overwrite -- Flag to force overwriting of an existing file. If False and a file of the same name already exists, the file is not overwritten and an exception is raised.
  • extended_header -- The extended header object
  • exttyp -- The extended header type

A new MrcMemmap object.
  • ValueError -- If the MRC mode is invalid.
  • ValueError -- If the file already exists and overwrite is
    False.



Module which exports the MrcFile class.

MrcFile: An object which represents an MRC file.

Bases: MrcInterpreter

An object which represents an MRC file.

The header and data are handled as numpy arrays - see MrcObject for details.

MrcFile supports a permissive read mode for attempting to open corrupt or invalid files. See mrcfile.mrcinterpreter.MrcInterpreter or the usage guide for more information.

To create a new MrcFile object, pass a file name and optional mode. To ensure the file is written to disk and closed correctly, it's best to use the with statement:

>>> with MrcFile('tmp.mrc', 'w+') as mrc:
...     mrc.set_data(np.zeros((10, 10), dtype=np.int8))
    

In mode r or r+, the named file is opened from disk and read. In mode w+ a new empty file is created and will be written to disk at the end of the with block (or when flush() or close() is called).


__init__(name, mode='r', overwrite=False, permissive=False, header_only=False, **kwargs)
Initialise a new MrcFile object.

The given file name is opened in the given mode. For mode r or r+ the header, extended header and data are read from the file. For mode w+ a new file is created with a default header and empty extended header and data arrays.

  • name -- The file name to open, as a string or pathlib Path.
  • mode -- The file mode to use. This should be one of the following: r for read-only, r+ for read and write, or w+ for a new empty file. The default is r.
  • overwrite -- Flag to force overwriting of an existing file if the mode is w+. If False and a file of the same name already exists, the file is not overwritten and an exception is raised. The default is False.
  • permissive -- Read the file in permissive mode. (See mrcfile.mrcinterpreter.MrcInterpreter for details.) The default is False.
  • header_only -- Only read the header (and extended header) from the file. The default is False.

  • ValueError -- If the mode is not one of r, r+ or
    w+.
  • ValueError -- If the file is not a valid MRC file and
    permissive is False.
  • ValueError -- If the mode is w+, the file already exists
    and overwrite is False.
  • OSError -- If the mode is r or r+ and the file does
    not exist.

  • RuntimeWarning -- If the file appears to be a valid MRC file but the data block is longer than expected from the dimensions in the header.
  • RuntimeWarning -- If the file is not a valid MRC file and permissive is True.
  • RuntimeWarning -- If the header's exttyp field is set to a known value but the extended header's size is not a multiple of the number of bytes in the corresponding dtype.



_open_file(name)
Open a file object to use as the I/O stream.

_read(header_only=False)
Override _read() to move back to start of file first.

_read_data()
Override _read_data() to check file size matches data block size.

_get_file_size()
Return the size of the underlying file object, in bytes.

Flush any changes to disk and close the file.

This override calls MrcInterpreter.close() to ensure the stream is flushed and closed, then closes the file object.


_close_file()
Close the file object.

Validate this MRC file.

The tests are:

1.
MRC format ID string: The map field in the header should contain "MAP ".
2.
Machine stamp: The machine stamp should contain one of 0x44 0x44 0x00 0x00, 0x44 0x41 0x00 0x00 or 0x11 0x11 0x00 0x00.
3.
MRC mode: the mode field should be one of the supported mode numbers: 0, 1, 2, 4, 6 or 12. (Note that MRC modes 3 and 101 are also valid according to the MRC 2014 specification but are not supported by mrcfile.)
4.
Map and cell dimensions: The header fields nx, ny, nz, mx, my, mz, cella.x, cella.y and cella.z must all be positive numbers.
5.
Axis mapping: Header fields mapc, mapr and maps must contain the values 1, 2, and 3 (in any order).
6.
Volume stack dimensions: If the spacegroup is in the range 401--630, representing a volume stack, the nz field should be exactly divisible by mz to represent the number of volumes in the stack.
7.
Header labels: The nlabl field should be set to indicate the number of labels in use, and the labels in use should appear first in the label array.
8.
MRC format version: The nversion field should be 20140 or 20141 for compliance with the MRC2014 standard.
9.
Extended header type: If an extended header is present, the exttyp field should be set to indicate the type of extended header.
10.
Data statistics: The statistics in the header should be correct for the actual data in the file, or marked as undetermined.
11.
File size: The size of the file on disk should match the expected size calculated from the MRC header.

print_file -- The output text stream to use for printing messages about the validation. This is passed directly to the file argument of Python's print() function. The default is None, which means output will be printed to sys.stdout.
True if the file is valid, or False if the file does not meet the MRC format specification in any way.



Module which exports the MrcInterpreter class.

MrcInterpreter: An object which can interpret an I/O stream as MRC data.

Bases: MrcObject

An object which interprets an I/O stream as MRC / CCP4 map data.

The header and data are handled as numpy arrays - see MrcObject for details.

MrcInterpreter can be used directly, but it is mostly intended as a superclass to provide common stream-handling functionality. This can be used by subclasses which will handle opening and closing the stream.

This class implements the __enter__() and __exit__() special methods which allow it to be used by the Python context manager in a with block. This ensures that close() is called after the object is finished with.

When reading the I/O stream, a ValueError is raised if the data is invalid in one of the following ways:

1.
The header's map field is not set correctly to confirm the file type.
2.
The machine stamp is invalid and so the data's byte order cannot be determined.
3.
The mode number is not recognised. Currently accepted modes are 0, 1, 2, 4 and 6.
4.
The file is not large enough for the specified extended header size.
5.
The data block is not large enough for the specified data type and dimensions.

MrcInterpreter offers a permissive read mode for handling problematic files. If permissive is set to True and any of the validity checks fails, a warning is issued instead of an exception, and file interpretation continues. If the mode number is invalid or the data block is too small, the data attribute will be set to None. In this case, it might be possible to inspect and correct the header, and then call _read() again to read the data correctly. See the usage guide for more details.

Methods:

  • flush()
  • close()

Methods relevant to subclasses:

  • _read()
  • _read_data()
  • _read_bytearray_from_stream()

__init__(iostream=None, permissive=False, header_only=False, **kwargs)
Initialise a new MrcInterpreter object.

This initialiser reads the stream if it is given. In general, subclasses should call __init__() without giving an iostream argument, then set the _iostream attribute themselves and call _read() when ready.

To use the MrcInterpreter class directly, pass a stream when creating the object (or for a write-only stream, create an MrcInterpreter with no stream, call _create_default_attributes() and set the _iostream attribute directly).

  • iostream -- The I/O stream to use to read and write MRC data. The default is None.
  • permissive -- Read the stream in permissive mode. The default is False.
  • header_only -- Only read the header (and extended header) from the file. The default is False.

ValueError -- If iostream is given, the data it contains
cannot be interpreted as a valid MRC file and permissive
is False.
  • RuntimeWarning -- If iostream is given, the data it contains cannot be interpreted as a valid MRC file and permissive is True.
  • RuntimeWarning -- If the header's exttyp field is set to a known value but the extended header's size is not a multiple of the number of bytes in the corresponding dtype.



_read(header_only=False)
Read the header, extended header and data from the I/O stream.

Before calling this method, the stream should be open and positioned at the start of the header. This method will advance the stream to the end of the data block (or the end of the extended header if header_only is True.

header_only -- Only read the header and extended header from the stream. The default is False.
ValueError -- If the data in the stream cannot be interpreted
as a valid MRC file and permissive is False.
RuntimeWarning -- If the data in the stream cannot be interpreted as a valid MRC file and permissive is True.


_read_header()
Read the MRC header from the I/O stream.

The header will be read from the current stream position, and the stream will be advanced by 1024 bytes.

ValueError -- If the data in the stream cannot be interpreted
as a valid MRC file and permissive is False.
RuntimeWarning -- If the data in the stream cannot be interpreted as a valid MRC file and permissive is True.


_read_extended_header()
Read the extended header from the stream.

If there is no extended header, a zero-length array is assigned to the extended_header attribute.

If the extended header is recognised as FEI microscope metadata (by 'FEI1' or 'FEI2' in the header's exttyp field), its dtype is set appropriately. Otherwise, the dtype is set as void ('V1').

ValueError -- If the stream is not long enough to contain the
extended header indicated by the header and permissive
is False.
  • RuntimeWarning -- If the header's exttyp field is set to 'FEI1' or 'FEI2' but the extended header's size is not a multiple of the number of bytes in the FEI metadata dtype.
  • RuntimeWarning -- If the stream is not long enough to contain the extended header indicated by the header and permissive is True.



_read_data(max_bytes=0)
Read the data array from the stream.

This method uses information from the header to set the data array's shape and dtype.

max_bytes -- Read at most this many bytes from the stream. If zero or negative, the full size of the data block as defined in the header will be read, even if this is very large.
ValueError -- If the stream is not long enough to contain the
data indicated by the header and permissive is
False.
RuntimeWarning -- If the stream is not long enough to contain the data indicated by the header and permissive is True.


_read_bytearray_from_stream(number_of_bytes)
Read a bytearray from the stream.

This default implementation relies on the stream implementing the readinto() method to avoid copying the new array while creating the mutable bytearray. Subclasses should override this if their stream does not support readinto().

A 2-tuple of the bytearray and the number of bytes that were read from the stream.


Flush to the stream and clear the header and data attributes.

Flush the header and data arrays to the I/O stream.

This implementation seeks to the start of the stream, writes the header, extended header and data arrays, and then truncates the stream.

Subclasses should override this implementation for streams which do not support seek() or truncate().



Module which exports the MrcMemmap class.

MrcMemmap: An MrcFile subclass that uses a memory-mapped data array.

Bases: MrcFile

MrcFile subclass that uses a numpy memmap array for the data.

Using a memmap means that the disk access is done lazily: the data array will only be read or written in small chunks when required. To access the contents of the array, use the array slice operator.

Usage is the same as for MrcFile.

Note that memmap arrays use a fairly small chunk size and so performance could be poor on file systems that are optimised for infrequent large I/O operations.

If required, it is possible to create a very large empty file by creating a new MrcMemmap and then calling _open_memmap() to create the memmap array, which can then be filled slice-by-slice. Be aware that the contents of a new, empty memmap array depend on your platform: the data values could be garbage or zeros.

Replace the file's extended header.

Note that the file's entire data block must be moved if the extended header size changes. Setting a new extended header can therefore be very time consuming with large files, if the new extended header occupies a different number of bytes than the previous one.


Flush the header and data arrays to the file buffer.

_read_data()
Read the data block from the file.

This method first calculates the parameters needed to read the data (block start position, endian-ness, file mode, array shape) and then opens the data as a numpy memmap array.


_open_memmap(dtype, shape)
Open a new memmap array pointing at the file's data block.

_close_data()
Delete the existing memmap array, if it exists.

The array is flagged as read-only before deletion, so if a reference to it has been kept elsewhere, changes to it should no longer be able to change the file contents.


_set_new_data(data)
Override of _set_new_data() to handle opening a new memmap and copying data into it.


Module which exports the MrcObject class.

MrcObject: An object representing image or volume data in the MRC format.

Bases: object

An object representing image or volume data in the MRC format.

The header, extended header and data are stored as numpy arrays and exposed as read-only attributes. To replace the data or extended header, call set_data() or set_extended_header(). The header cannot be replaced but can be modified in place.

Voxel size is exposed as a writeable attribute, but is calculated on-the-fly from the header's cella and mx/my/mz fields.

Three-dimensional data can represent either a stack of 2D images, or a 3D volume. This is indicated by the header's ispg (space group) field, which is set to 0 for image data and >= 1 for volume data. The is_single_image(), is_image_stack(), is_volume() and is_volume_stack() methods can be used to identify the type of information stored in the data array. For 3D data, the set_image_stack() and set_volume() methods can be used to switch between image stack and volume interpretations of the data.

If the data contents have been changed, you can use the update_header_from_data() and update_header_stats() methods to make the header consistent with the data. These methods are called automatically if the data array is replaced by calling set_data(). update_header_from_data() is fast, even with very large data arrays, because it only examines the shape and type of the data array. update_header_stats() calculates statistics from all items in the data array and so can be slow for very large arrays. If necessary, the reset_header_stats() method can be called to set the header fields to indicate that the statistics are undetermined.

Attributes:

  • header
  • extended_header
  • data
  • voxel_size
  • nstart

Methods:

  • set_extended_header()
  • set_data()
  • is_single_image()
  • is_image_stack()
  • is_volume()
  • is_volume_stack()
  • set_image_stack()
  • set_volume()
  • update_header_from_data()
  • update_header_stats()
  • reset_header_stats()
  • print_header()
  • get_labels()
  • add_label()

Attributes and methods relevant to subclasses:

  • _read_only
  • _check_writeable()
  • _create_default_attributes()
  • _close_data()
  • _set_new_data()

__init__(**kwargs)
Initialise a new MrcObject.

This initialiser deliberately avoids creating any arrays and simply sets the header, extended header and data attributes to None. This allows subclasses to call __init__() at the start of their initialisers and then set the attributes themselves, probably by reading from a file, or by calling _create_default_attributes() for a new empty object.

Note that this behaviour might change in future: this initialiser could take optional arguments to allow the header and data to be provided by the caller, or might create the standard empty defaults rather than setting the attributes to None.


_check_writeable()
Check that this MRC object is writeable.
ValueError -- If this object is read-only.


_create_default_attributes()
Set valid default values for the header and data attributes.

_create_default_header()
Create a default MRC file header.

The header is initialised with standard file type and version information, default values for some essential fields, and zeros elsewhere. The first text label is also set to indicate the file was created by this module.


Get the header as a numpy record array.

Get the extended header as a numpy array.

If this MrcObject was read from a file and the extended header type was recognised, its dtype will be set appropriately. (Currently the only supported types are 'FEI1' and 'FEI2'.) Otherwise, the dtype will be void (raw data, dtype 'V'). If the actual data type of the extended header is known, the dtype of the array can be changed to match.

The extended header may be modified in place. To replace it completely, call set_extended_header().


Replace the extended header.

If you set the extended header you should also set the header.exttyp field to indicate the type of extended header.


Get the data as a numpy array.

Replace the data array.

This replaces the current data with the given array (or a copy of it), and updates the header to match the new data dimensions. The data statistics (min, max, mean and rms) stored in the header will also be updated.

RuntimeWarning -- If the data array contains Inf or NaN values.


_close_data()
Close the data array.

_set_new_data(data)
Replace the data array with a new one.

The new data array is not checked - it must already be valid for use in an MRC file.


Get or set the voxel size in angstroms.

The voxel size is returned as a structured NumPy record array with three fields (x, y and z). For example:

>>> mrc.voxel_size
rec.array((0.44825, 0.3925, 0.45874998),

dtype=[('x', '<f4'), ('y', '<f4'), ('z', '<f4')]) >>> mrc.voxel_size.x array(0.44825, dtype=float32)

Note that changing the voxel_size array in-place will not change the voxel size in the file -- to prevent this being overlooked accidentally, the writeable flag is set to False on the voxel_size array.

To set the voxel size, assign a new value to the voxel_size attribute. You may give a single number, a 3-tuple (x, y ,z) or a modified version of the voxel_size array. The following examples are all equivalent:

>>> mrc.voxel_size = 1.0
    

>>> mrc.voxel_size = (1.0, 1.0, 1.0)
    

>>> vox_sizes = mrc.voxel_size
>>> vox_sizes.flags.writeable = True
>>> vox_sizes.x = 1.0
>>> vox_sizes.y = 1.0
>>> vox_sizes.z = 1.0
>>> mrc.voxel_size = vox_sizes
    

_set_voxel_size(x_size, y_size, z_size)
Set the voxel size.
  • x_size -- The voxel size in the X direction, in angstroms
  • y_size -- The voxel size in the Y direction, in angstroms
  • z_size -- The voxel size in the Z direction, in angstroms



Get or set the grid start locations.

This provides a convenient way to get and set the values of the header's nxstart, nystart and nzstart fields. Note that these fields are integers and are measured in voxels, not angstroms. The start locations are returned as a structured NumPy record array with three fields (x, y and z). For example:

>>> mrc.header.nxstart
array(0, dtype=int32)
>>> mrc.header.nystart
array(-21, dtype=int32)
>>> mrc.header.nzstart
array(-12, dtype=int32)
>>> mrc.nstart
rec.array((0, -21, -12),

dtype=[('x', '<i4'), ('y', '<i4'), ('z', '<i4')]) >>> mrc.nstart.y array(-21, dtype=int32)

Note that changing the nstart array in-place will not change the values in the file -- to prevent this being overlooked accidentally, the writeable flag is set to False on the nstart array.

To set the start locations, assign a new value to the nstart attribute. You may give a single number, a 3-tuple (x, y ,z) or a modified version of the nstart array. The following examples are all equivalent:

>>> mrc.nstart = -150
    

>>> mrc.nstart = (-150, -150, -150)
    

>>> starts = mrc.nstart
>>> starts.flags.writeable = True
>>> starts.x = -150
>>> starts.y = -150
>>> starts.z = -150
>>> mrc.nstart = starts
    

_set_nstart(nxstart, nystart, nzstart)
Set the grid start locations.
  • nxstart -- The location of the first column in the unit cell
  • nystart -- The location of the first row in the unit cell
  • nzstart -- The location of the first section in the unit cell



Identify whether the file represents a single image.
True if the data array is two-dimensional.


Identify whether the file represents a stack of images.
True if the data array is three-dimensional and the space group is zero.


Identify whether the file represents a volume.
True if the data array is three-dimensional and the space group is not zero.


Identify whether the file represents a stack of volumes.
True if the data array is four-dimensional.


Change three-dimensional data to represent an image stack.

This method changes the space group number (header.ispg) to zero.

ValueError -- If the data array is not three-dimensional.


Change three-dimensional data to represent a volume.

If the space group was previously zero (representing an image stack), this method sets it to one. Otherwise the space group is not changed.

ValueError -- If the data array is not three-dimensional.


Update the header from the data array.

This function updates the header byte order and machine stamp to match the byte order of the data. It also updates the file mode, space group and the dimension fields nx, ny, nz, mx, my and mz.

If the data is 2D, the space group is set to 0 (image stack). For 3D data the space group is not changed, and for 4D data the space group is set to 401 (simple P1 volume stack) unless it is already in the volume stack range (401--630).

This means that new 3D data will be treated as an image stack if the previous data was a single image or image stack, or as a volume if the previous data was a volume or volume stack.

Note that this function does not update the data statistics fields in the header (dmin, dmax, dmean and rms). Use the update_header_stats() function to update the statistics. (This is for performance reasons -- updating the statistics can take a long time for large data sets, but updating the other header information is always fast because only the type and shape of the data array need to be inspected.)


Update the header's dmin, dmax, dmean and rms fields from the data.

Note that this can take some time with large files, particularly with files larger than the currently available memory.

RuntimeWarning -- If the data array contains Inf or NaN values.


Set the header statistics to indicate that the values are unknown.

Print the contents of all header fields.
print_file -- The output text stream to use for printing the header. This is passed directly to the file argument of Python's print() function. The default is None, which means output will be printed to sys.stdout.


Get the labels from the MRC header.

Up to ten labels are stored in the header as arrays of 80 bytes. This method returns the labels as Python strings, filtered to remove non-printable characters. To access the raw bytes (including any non-printable characters) use the header.label attribute (and note that header.nlabl stores the number of labels currently set).

The labels, as a list of strings. The list will contain between 0 and 10 items, each containing up to 80 characters.


Add a label to the MRC header.

The new label will be stored after any labels already in the header. If all ten labels are already in use, an exception will be raised.

Future versions of this method might add checks to ensure that labels containing valid text are not overwritten even if the nlabl value is incorrect.

label -- The label value to store, as a string containing only printable ASCII characters.
  • ValueError -- If the label is longer than 80 bytes or contains
    non-printable or non-ASCII characters.
  • IndexError -- If the file already contains 10 labels and so an
    additional label cannot be stored.



Validate this MrcObject.

This method runs a series of tests to check whether this object complies strictly with the MRC2014 format specification:

1.
MRC format ID string: The header's map field must contain "MAP ".
2.
Machine stamp: The machine stamp should contain one of 0x44 0x44 0x00 0x00, 0x44 0x41 0x00 0x00 or 0x11 0x11 0x00 0x00.
3.
MRC mode: the mode field should be one of the supported mode numbers: 0, 1, 2, 4, 6 or 12. (Note that MRC modes 3 and 101 are also valid according to the MRC 2014 specification but are not supported by mrcfile.)
4.
Map and cell dimensions: The header fields nx, ny, nz, mx, my, mz, cella.x, cella.y and cella.z must all be positive numbers.
5.
Axis mapping: Header fields mapc, mapr and maps must contain the values 1, 2, and 3 (in any order).
6.
Volume stack dimensions: If the spacegroup is in the range 401--630, representing a volume stack, the nz field should be exactly divisible by mz to represent the number of volumes in the stack.
7.
Header labels: The nlabl field should be set to indicate the number of labels in use, and the labels in use should appear first in the label array (that is, there should be no blank labels between text-filled ones).
8.
MRC format version: The nversion field should be 20140 or 20141 for compliance with the MRC2014 standard.
9.
Extended header type: If an extended header is present, the exttyp field should be set to indicate the type of extended header.
10.
Data statistics: The statistics in the header should be correct for the actual data, or marked as undetermined.

print_file -- The output text stream to use for printing messages about the validation. This is passed directly to the file argument of Python's print() function. The default is None, which means output will be printed to sys.stdout.
True if this MrcObject is valid, or False if it does not meet the MRC format specification in any way.



Utility functions used by the other modules in the mrcfile package.

  • data_dtype_from_header(): Work out the data dtype from an MRC header.
  • data_shape_from_header(): Work out the data array shape from an MRC header
  • mode_from_dtype(): Convert a numpy dtype to an MRC mode number.
  • dtype_from_mode(): Convert an MRC mode number to a numpy dtype.
  • pretty_machine_stamp(): Get a nicely-formatted string from a machine stamp.
  • machine_stamp_from_byte_order(): Get a machine stamp from a byte order indicator.
  • byte_orders_equal(): Compare two byte order indicators for equal endianness.
  • normalise_byte_order(): Convert a byte order indicator to < or >.
  • spacegroup_is_volume_stack(): Identify if a space group number represents a volume stack.

Return the data dtype indicated by the given header.

This function calls dtype_from_mode() to get the basic dtype, and then makes sure that the byte order of the new dtype matches the byte order of the header's mode field.

header -- An MRC header as a numpy record array.
The numpy dtype object for the data array corresponding to the given header.
ValueError -- If there is no corresponding dtype for the given
mode.


Return the data shape indicated by the given header.
header -- An MRC header as a numpy record array.
The shape tuple for the data array corresponding to the given header.


Return the MRC mode number corresponding to the given numpy dtype.

The conversion is as follows:

  • float16 -> mode 12
  • float32 -> mode 2
  • int8 -> mode 0
  • int16 -> mode 1
  • uint8 -> mode 6 (data will be widened to 16 bits in the file)
  • uint16 -> mode 6
  • complex64 -> mode 4

Note that there is no numpy dtype which corresponds to MRC mode 3.

dtype -- A numpy dtype object.
The MRC mode number.
ValueError -- If there is no corresponding MRC mode for the given
dtype.


Return the numpy dtype corresponding to the given MRC mode number.

The mode parameter may be given as a Python scalar, numpy scalar or single-item numpy array.

The conversion is as follows:

  • mode 0 -> int8
  • mode 1 -> int16
  • mode 2 -> float32
  • mode 4 -> complex64
  • mode 6 -> uint16
  • mode 12 -> float16

Note that modes 3 and 101 are not supported as there is no matching numpy dtype.

mode -- The MRC mode number. This may be given as any type which can be converted to an int, for example a Python scalar (int or float), a numpy scalar or a single-item numpy array.
The numpy dtype object corresponding to the given mode.
ValueError -- If there is no corresponding dtype for the given
mode.


Return a human-readable hex string for a machine stamp.

Return the byte order corresponding to the given machine stamp.
machst -- The machine stamp, as a bytearray or a numpy array of bytes.
< if the machine stamp represents little-endian data, or > if it represents big-endian.
ValueError -- If the machine stamp is invalid.


Return the machine stamp corresponding to the given byte order indicator.
byte_order -- The byte order indicator: one of =, < or >, as defined and used by numpy dtype objects.
The machine stamp which corresponds to the given byte order, as a bytearray. This will be either (0x44, 0x44, 0, 0) for little-endian or (0x11, 0x11, 0, 0) for big-endian. If the given byte order indicator is =, the native byte order is used.
ValueError -- If the byte order indicator is unrecognised.


Work out if the byte order indicators represent the same endianness.
  • a -- The first byte order indicator: one of =, < or >, as defined and used by numpy dtype objects.
  • b -- The second byte order indicator.

True if the byte order indicators represent the same endianness.
ValueError -- If the byte order indicator is not recognised.


Convert a numpy byte order indicator to one of < or >.
byte_order -- One of =, < or >.
< if the byte order indicator represents little-endian data, or > if it represents big-endian. Therefore on a little-endian machine, = will be converted to <, but on a big-endian machine it will be converted to >.
ValueError -- If byte_order is not one of =, < or
>.


Identify if the given space group number represents a volume stack.
ispg -- The space group number, as an integer, numpy scalar or single- element numpy array.
True if the space group number is in the range 401--630.


Check if a string is entirely composed of printable ASCII characters.

Convert bytes into a printable ASCII string by removing non-printable characters.

Convert a string to bytes.

Even though this is a one-liner, the details are tricky to get right so things work properly in both Python 2 and 3. It's broken out as a separate function so it can be thoroughly tested.

UnicodeError -- If the input contains non-ASCII characters.


Module for top-level functions that validate MRC files.

This module is runnable to allow files to be validated easily from the command line.

Validate a list of MRC files given as command arguments.

The return value is used as the process exit code when this function is called by running this module or from the corresponding console_scripts entry point.

0 if all command arguments are names of valid MRC files. 1 if no file names are given or any of the files is not a valid MRC file.


Validate a list of MRC files.

This function calls validate() for each file name in the given list.

  • names -- A sequence of file names to open and validate.
  • print_file -- The output text stream to use for printing messages about the validation. This is passed directly to the print_file argument of the validate() function. The default is None, which means output will be printed to sys.stdout.

True if all of the files are valid, or False if any of the files do not meet the MRC format specification in any way.
OSError -- If one of the files does not exist or cannot be opened.
RuntimeWarning -- If one of the files is seriously invalid because it has no map ID string, an incorrect machine stamp, an unknown mode number, or is not the same size as expected from the header.


Validate an MRC file.

This function first opens the file by calling open() (with permissive=True), then calls validate(), which runs a series of tests to check whether the file complies with the MRC2014 format specification.

If the file is completely valid, this function returns True, otherwise it returns False. Messages explaining the validation result will be printed to sys.stdout by default, but if a text stream is given (using the print_file argument) output will be printed to that instead.

Badly invalid files will also cause warning messages to be issued, which will be written to sys.stderr by default. See the documentation of the warnings module for information on how to suppress or capture warning output.

Because the file is opened by calling open(), gzip- and bzip2-compressed MRC files can be validated easily using this function.

After the file has been opened, it is checked for problems. The tests are:

1.
MRC format ID string: The map field in the header should contain "MAP ".
2.
Machine stamp: The machine stamp should contain one of 0x44 0x44 0x00 0x00, 0x44 0x41 0x00 0x00 or 0x11 0x11 0x00 0x00.
3.
MRC mode: the mode field should be one of the supported mode numbers: 0, 1, 2, 4, 6 or 12. (Note that MRC modes 3 and 101 are also valid according to the MRC 2014 specification but are not supported by mrcfile.)
4.
Map and cell dimensions: The header fields nx, ny, nz, mx, my, mz, cella.x, cella.y and cella.z must all be positive numbers.
5.
Axis mapping: Header fields mapc, mapr and maps must contain the values 1, 2, and 3 (in any order).
6.
Volume stack dimensions: If the spacegroup is in the range 401--630, representing a volume stack, the nz field should be exactly divisible by mz to represent the number of volumes in the stack.
7.
Header labels: The nlabl field should be set to indicate the number of labels in use, and the labels in use should appear first in the label array.
8.
MRC format version: The nversion field should be 20140 or 20141 for compliance with the MRC2014 standard.
9.
Extended header type: If an extended header is present, the exttyp field should be set to indicate the type of extended header.
10.
Data statistics: The statistics in the header should be correct for the actual data in the file, or marked as undetermined.
11.
File size: The size of the file on disk should match the expected size calculated from the MRC header.

  • name -- The file name to open and validate.
  • print_file -- The output text stream to use for printing messages about the validation. This is passed directly to the file argument of Python's print() function. The default is None, which means output will be printed to sys.stdout.

True if the file is valid, or False if the file does not meet the MRC format specification in any way.
OSError -- If the file does not exist or cannot be opened.
RuntimeWarning -- If the file is seriously invalid because it has no map ID string, an incorrect machine stamp, an unknown mode number, or is not the same size as expected from the header.


Colin Palmer

2023, Science and Technology Facilities Council

February 14, 2023 1.4.3