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- ******
- Neo IO
- ******
- .. currentmodule:: neo
- Preamble
- ========
- The Neo :mod:`io` module aims to provide an exhaustive way of loading and saving several widely used data formats in electrophysiology.
- The more these heterogeneous formats are supported, the easier it will be to manipulate them as Neo objects in a similar way.
- Therefore the IO set of classes propose a simple and flexible IO API that fits many format specifications.
- It is not only file-oriented, it can also read/write objects from a database.
- At the moment, there are 3 families of IO modules:
- 1. for reading closed manufacturers' formats (Spike2, Plexon, AlphaOmega, BlackRock, Axon, ...)
- 2. for reading(/writing) formats from open source tools (KlustaKwik, Elan, WinEdr, WinWcp, ...)
- 3. for reading/writing Neo structure in neutral formats (HDF5, .mat, ...) but with Neo structure inside (NeoHDF5, NeoMatlab, ...)
- Combining **1** for reading and **3** for writing is a good example of use: converting your datasets
- to a more standard format when you want to share/collaborate.
- Introduction
- ============
- There is an intrinsic structure in the different Neo objects, that could be seen as a hierachy with cross-links. See :doc:`core`.
- The highest level object is the :class:`Block` object, which is the high level container able to encapsulate all the others.
- A :class:`Block` has therefore a list of :class:`Segment` objects, that can, in some file formats, be accessed individually.
- Depending on the file format, i.e. if it is streamable or not, the whole :class:`Block` may need to be loaded, but sometimes
- particular :class:`Segment` objects can be accessed individually.
- Within a :class:`Segment`, the same hierarchical organisation applies.
- A :class:`Segment` embeds several objects, such as :class:`SpikeTrain`,
- :class:`AnalogSignal`, :class:`IrregularlySampledSignal`, :class:`Epoch`, :class:`Event`
- (basically, all the different Neo objects).
- Depending on the file format, these objects can sometimes be loaded separately, without the need to load the whole file.
- If possible, a file IO therefore provides distinct methods allowing to load only particular objects that may be present in the file.
- The basic idea of each IO file format is to have, as much as possible, read/write methods for the individual encapsulated objects,
- and otherwise to provide a read/write method that will return the object at the highest level of hierarchy
- (by default, a :class:`Block` or a :class:`Segment`).
- The :mod:`neo.io` API is a balance between full flexibility for the user (all :meth:`read_XXX` methods are enabled)
- and simple, clean and understandable code for the developer (few :meth:`read_XXX` methods are enabled).
- This means that not all IOs offer the full flexibility for partial reading of data files.
- One format = one class
- ======================
- The basic syntax is as follows. If you want to load a file format that is implemented in a generic :class:`MyFormatIO` class::
- >>> from neo.io import MyFormatIO
- >>> reader = MyFormatIO(filename="myfile.dat")
- you can replace :class:`MyFormatIO` by any implemented class, see :ref:`list_of_io`
- Modes
- ======
- IO can be based on a single file, a directory containing files, or a database.
- This is described in the :attr:`mode` attribute of the IO class.
- >>> from neo.io import MyFormatIO
- >>> print MyFormatIO.mode
- 'file'
- For *file* mode the *filename* keyword argument is necessary.
- For *directory* mode the *dirname* keyword argument is necessary.
- Ex:
- >>> reader = io.PlexonIO(filename='File_plexon_1.plx')
- >>> reader = io.TdtIO(dirname='aep_05')
- Supported objects/readable objects
- ==================================
- To know what types of object are supported by a given IO interface::
- >>> MyFormatIO.supported_objects
- [Segment , AnalogSignal , SpikeTrain, Event, Spike]
- Supported objects does not mean objects that you can read directly. For instance, many formats support :class:`AnalogSignal`
- but don't allow them to be loaded directly, rather to access the :class:`AnalogSignal` objects, you must read a :class:`Segment`::
- >>> seg = reader.read_segment()
- >>> print(seg.analogsignals)
- >>> print(seg.analogsignals[0])
- To get a list of directly readable objects ::
- >>> MyFormatIO.readable_objects
- [Segment]
- The first element of the previous list is the highest level for reading the file. This mean that the IO has a :meth:`read_segment` method::
- >>> seg = reader.read_segment()
- >>> type(seg)
- neo.core.Segment
- All IOs have a read() method that returns a list of :class:`Block` objects (representing the whole content of the file)::
- >>> bl = reader.read()
- >>> print bl[0].segments[0]
- neo.core.Segment
- Lazy option (deprecated)
- ========================
- In some cases you may not want to load everything in memory because it could be too big.
- For this scenario, some IOs implement ``lazy=True/False``. With ``lazy=True`` all arrays will have a size of zero,
- but all the metadata will be loaded. The *lazy_shape* attribute is added to all array-like objects
- (AnalogSignal, IrregularlySampledSignal, SpikeTrain, Epoch, Event).
- In this case, *lazy_shape* is a tuple that has the same value as *shape* with ``lazy=False``.
- To know if a class supports lazy mode use ``ClassIO.support_lazy``.
- By default (if not specified), ``lazy=False``, i.e. all data is loaded.
- The lazy option will be removed in future Neo versions. Similar functionality will be
- implemented using proxy objects.
- Example of lazy loading::
- >>> seg = reader.read_segment(lazy=False)
- >>> print(seg.analogsignals[0].shape) # this is (N, M)
- >>> seg = reader.read_segment(lazy=True)
- >>> print(seg.analogsignals[0].shape) # this is 0, the AnalogSignal is empty
- >>> print(seg.analogsignals[0].lazy_shape) # this is (N, M)
- .. _neo_io_API:
- Details of API
- ==============
- The :mod:`neo.io` API is designed to be simple and intuitive:
- - each file format has an IO class (for example for Spike2 files you have a :class:`Spike2IO` class).
- - each IO class inherits from the :class:`BaseIO` class.
- - each IO class can read or write directly one or several Neo objects (for example :class:`Segment`, :class:`Block`, ...): see the :attr:`readable_objects` and :attr:`writable_objects` attributes of the IO class.
- - each IO class supports part of the :mod:`neo.core` hierachy, though not necessarily all of it (see :attr:`supported_objects`).
- - each IO class has a :meth:`read()` method that returns a list of :class:`Block` objects. If the IO only supports :class:`Segment` reading, the list will contain one block with all segments from the file.
- - each IO class that supports writing has a :meth:`write()` method that takes as a parameter a list of blocks, a single block or a single segment, depending on the IO's :attr:`writable_objects`.
- - each IO is able to do a *lazy* load: all metadata (e.g. :attr:`sampling_rate`) are read, but not the actual numerical data. lazy_shape attribute is added to provide information on real size.
- - each IO is able to save and load all required attributes (metadata) of the objects it supports.
- - each IO can freely add user-defined or manufacturer-defined metadata to the :attr:`annotations` attribute of an object.
- If you want to develop your own IO
- ==================================
- See :doc:`io_developers_guide` for information on how to implement a new IO.
- .. _list_of_io:
- List of implemented formats
- ===========================
- .. automodule:: neo.io
- Logging
- =======
- :mod:`neo` uses the standard Python :mod:`logging` module for logging.
- All :mod:`neo.io` classes have logging set up by default, although not all classes produce log messages.
- The logger name is the same as the full qualified class name, e.g. :class:`neo.io.hdf5io.NeoHdf5IO`.
- By default, only log messages that are critically important for users are displayed, so users should not disable log messages unless they are sure they know what they are doing.
- However, if you wish to disable the messages, you can do so::
- >>> import logging
- >>>
- >>> logger = logging.getLogger('neo')
- >>> logger.setLevel(100)
- Some io classes provide additional information that might be interesting to advanced users.
- To enable these messages, do the following::
- >>> import logging
- >>>
- >>> logger = logging.getLogger('neo')
- >>> logger.setLevel(logging.INFO)
- It is also possible to log to a file in addition to the terminal::
- >>> import logging
- >>>
- >>> logger = logging.getLogger('neo')
- >>> handler = logging.FileHandler('filename.log')
- >>> logger.addHandler(handler)
- To only log to the terminal::
- >>> import logging
- >>> from neo import logging_handler
- >>>
- >>> logger = logging.getLogger('neo')
- >>> handler = logging.FileHandler('filename.log')
- >>> logger.addHandler(handler)
- >>>
- >>> logging_handler.setLevel(100)
- This can also be done for individual IO classes::
- >>> import logging
- >>>
- >>> logger = logging.getLogger('neo.io.hdf5io.NeoHdf5IO')
- >>> handler = logging.FileHandler('filename.log')
- >>> logger.addHandler(handler)
- Individual IO classes can have their loggers disabled as well::
- >>> import logging
- >>>
- >>> logger = logging.getLogger('neo.io.hdf5io.NeoHdf5IO')
- >>> logger.setLevel(100)
- And more detailed logging messages can be enabled for individual IO classes::
- >>> import logging
- >>>
- >>> logger = logging.getLogger('neo.io.hdf5io.NeoHdf5IO')
- >>> logger.setLevel(logging.INFO)
- The default handler, which is used to print logs to the command line, is stored in :attr:`neo.logging_handler`.
- This example changes how the log text is displayed::
- >>> import logging
- >>> from neo import logging_handler
- >>>
- >>> formatter = logging.Formatter('%(asctime)s - %(name)s - %(levelname)s - %(message)s')
- >>> logging_handler.setFormatter(formatter)
- For more complex logging, please see the documentation for the logging_ module.
- .. note:: If you wish to implement more advanced logging as describe in the documentation for the logging_ module or elsewhere on the internet, please do so before calling any :mod:`neo` functions or initializing any :mod:`neo` classes.
- This is because the default handler is created when :mod:`neo` is imported, but it is not attached to the :mod:`neo` logger until a class that uses logging is initialized or a function that uses logging is called.
- Further, the handler is only attached if there are no handlers already attached to the root logger or the :mod:`neo` logger, so adding your own logger will override the default one.
- Additional functions and/or classes may get logging during bugfix releases, so code relying on particular modules not having logging may break at any time without warning.
- .. _`logging`: http://docs.python.org/library/logging.html
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