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- '''
- Class for reading from Brainware F32 files
- F32 files are simplified binary files for holding spike data. Unlike SRC
- files, F32 files carry little metadata. This also means, however, that the
- file format does not change, unlike SRC files whose format changes periodically
- (although ideally SRC files are backwards-compatible).
- Each F32 file only holds a single Block.
- The only metadata stored in the file is the length of a single repetition
- of the stimulus and the values of the stimulus parameters (but not the names
- of the parameters).
- Brainware was developed by Dr. Jan Schnupp and is availabe from
- Tucker Davis Technologies, Inc.
- http://www.tdt.com/downloads.htm
- Neither Dr. Jan Schnupp nor Tucker Davis Technologies, Inc. had any part in the
- development of this code
- The code is implemented with the permission of Dr. Jan Schnupp
- Author: Todd Jennings
- '''
- # import needed core python modules
- from os import path
- # numpy and quantities are already required by neo
- import numpy as np
- import quantities as pq
- # needed core neo modules
- from neo.core import Block, Group, Segment, SpikeTrain, Unit
- # need to subclass BaseIO
- from neo.io.baseio import BaseIO
- class BrainwareF32IO(BaseIO):
- '''
- Class for reading Brainware Spike ReCord files with the extension '.f32'
- The read_block method returns the first Block of the file. It will
- automatically close the file after reading.
- The read method is the same as read_block.
- The read_all_blocks method automatically reads all Blocks. It will
- automatically close the file after reading.
- The read_next_block method will return one Block each time it is called.
- It will automatically close the file and reset to the first Block
- after reading the last block.
- Call the close method to close the file and reset this method
- back to the first Block.
- The isopen property tells whether the file is currently open and
- reading or closed.
- Note 1:
- There is always only one Group.
- Usage:
- >>> from neo.io.brainwaref32io import BrainwareF32IO
- >>> f32file = BrainwareF32IO(filename='multi_500ms_mulitrep_ch1.f32')
- >>> blk1 = f32file.read()
- >>> blk2 = f32file.read_block()
- >>> print blk1.segments
- >>> print blk1.segments[0].spiketrains
- >>> print blk1.units
- >>> print blk1.units[0].name
- >>> print blk2
- >>> print blk2[0].segments
- '''
- is_readable = True # This class can only read data
- is_writable = False # write is not supported
- # This class is able to directly or indirectly handle the following objects
- # You can notice that this greatly simplifies the full Neo object hierarchy
- supported_objects = [Block, Group,
- Segment, SpikeTrain, Unit]
- readable_objects = [Block]
- writeable_objects = []
- has_header = False
- is_streameable = False
- # This is for GUI stuff: a definition for parameters when reading.
- # This dict should be keyed by object (`Block`). Each entry is a list
- # of tuple. The first entry in each tuple is the parameter name. The
- # second entry is a dict with keys 'value' (for default value),
- # and 'label' (for a descriptive name).
- # Note that if the highest-level object requires parameters,
- # common_io_test will be skipped.
- read_params = {Block: []}
- # does not support write so no GUI stuff
- write_params = None
- name = 'Brainware F32 File'
- extensions = ['f32']
- mode = 'file'
- def __init__(self, filename=None):
- '''
- Arguments:
- filename: the filename
- '''
- BaseIO.__init__(self)
- self._path = filename
- self._filename = path.basename(filename)
- self._fsrc = None
- self._blk = None
- self.__unit_group = None
- self.__t_stop = None
- self.__params = None
- self.__seg = None
- self.__spiketimes = None
- def read_block(self, lazy=False, **kargs):
- '''
- Reads a block from the simple spike data file "fname" generated
- with BrainWare
- '''
- assert not lazy, 'Do not support lazy'
- # there are no keyargs implemented to so far. If someone tries to pass
- # them they are expecting them to do something or making a mistake,
- # neither of which should pass silently
- if kargs:
- raise NotImplementedError('This method does not have any '
- 'argument implemented yet')
- self._fsrc = None
- self._blk = Block(file_origin=self._filename)
- block = self._blk
- # create the objects to store other objects
- self.__unit_group = Group(file_origin=self._filename)
- block.groups.append(self.__unit_group)
- # initialize values
- self.__t_stop = None
- self.__params = None
- self.__seg = None
- self.__spiketimes = None
- # open the file
- with open(self._path, 'rb') as self._fsrc:
- res = True
- # while the file is not done keep reading segments
- while res:
- res = self.__read_id()
- block.create_many_to_one_relationship()
- # cleanup attributes
- self._fsrc = None
- self._blk = None
- self.__t_stop = None
- self.__params = None
- self.__seg = None
- self.__spiketimes = None
- return block
- # -------------------------------------------------------------------------
- # -------------------------------------------------------------------------
- # IMPORTANT!!!
- # These are private methods implementing the internal reading mechanism.
- # Due to the way BrainWare DAM files are structured, they CANNOT be used
- # on their own. Calling these manually will almost certainly alter your
- # position in the file in an unrecoverable manner, whether they throw
- # an exception or not.
- # -------------------------------------------------------------------------
- # -------------------------------------------------------------------------
- def __read_id(self):
- '''
- Read the next ID number and do the appropriate task with it.
- Returns nothing.
- '''
- try:
- # float32 -- ID of the first data sequence
- objid = np.fromfile(self._fsrc, dtype=np.float32, count=1)[0]
- except IndexError:
- # if we have a previous segment, save it
- self.__save_segment()
- # if there are no more Segments, return
- return False
- if objid == -2:
- self.__read_condition()
- elif objid == -1:
- self.__read_segment()
- else:
- self.__spiketimes.append(objid)
- return True
- def __read_condition(self):
- '''
- Read the parameter values for a single stimulus condition.
- Returns nothing.
- '''
- # float32 -- SpikeTrain length in ms
- self.__t_stop = np.fromfile(self._fsrc, dtype=np.float32, count=1)[0]
- # float32 -- number of stimulus parameters
- numelements = int(np.fromfile(self._fsrc, dtype=np.float32,
- count=1)[0])
- # [float32] * numelements -- stimulus parameter values
- paramvals = np.fromfile(self._fsrc, dtype=np.float32,
- count=numelements).tolist()
- # organize the parameers into a dictionary with arbitrary names
- paramnames = ['Param%s' % i for i in range(len(paramvals))]
- self.__params = dict(zip(paramnames, paramvals))
- def __read_segment(self):
- '''
- Setup the next Segment.
- Returns nothing.
- '''
- # if we have a previous segment, save it
- self.__save_segment()
- # create the segment
- self.__seg = Segment(file_origin=self._filename,
- **self.__params)
- # create an empy array to save the spike times
- # this needs to be converted to a SpikeTrain before it can be used
- self.__spiketimes = []
- def __save_segment(self):
- '''
- Write the segment to the Block if it exists
- '''
- # if this is the beginning of the first condition, then we don't want
- # to save, so exit
- # but set __seg from None to False so we know next time to create a
- # segment even if there are no spike in the condition
- if self.__seg is None:
- self.__seg = False
- return
- if not self.__seg:
- # create dummy values if there are no SpikeTrains in this condition
- self.__seg = Segment(file_origin=self._filename,
- **self.__params)
- self.__spiketimes = []
- times = pq.Quantity(self.__spiketimes, dtype=np.float32,
- units=pq.ms)
- train = SpikeTrain(times,
- t_start=0 * pq.ms, t_stop=self.__t_stop * pq.ms,
- file_origin=self._filename)
- self.__seg.spiketrains = [train]
- self.__unit_group.spiketrains.append(train)
- self._blk.segments.append(self.__seg)
- # set an empty segment
- # from now on, we need to set __seg to False rather than None so
- # that if there is a condition with no SpikeTrains we know
- # to create an empty Segment
- self.__seg = False
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