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- """
- Module for reading data from files in the Blackrock format.
- This module is an older implementation with old neo.io API.
- A new class Blackrock compunded by BlackrockRawIO and BaseFromIO
- superseed this one.
- This work is based on:
- * Chris Rodgers - first version
- * Michael Denker, Lyuba Zehl - second version
- * Samuel Garcia - third version
- * Lyuba Zehl, Michael Denker - fourth version
- This IO supports reading only.
- This IO is able to read:
- * the nev file which contains spikes
- * ns1, ns2, .., ns6 files that contain signals at different sampling rates
- This IO can handle the following Blackrock file specifications:
- * 2.1
- * 2.2
- * 2.3
- The neural data channels are 1 - 128.
- The analog inputs are 129 - 144. (129 - 137 AC coupled, 138 - 144 DC coupled)
- spike- and event-data; 30000 Hz
- "ns1": "analog data: 500 Hz",
- "ns2": "analog data: 1000 Hz",
- "ns3": "analog data: 2000 Hz",
- "ns4": "analog data: 10000 Hz",
- "ns5": "analog data: 30000 Hz",
- "ns6": "analog data: 30000 Hz (no digital filter)"
- TODO:
- * videosync events (file spec 2.3)
- * tracking events (file spec 2.3)
- * buttontrigger events (file spec 2.3)
- * config events (file spec 2.3)
- * check left sweep settings of Blackrock
- * check nsx offsets (file spec 2.1)
- * add info of nev ext header (NSASEXEX) to non-neural events
- (file spec 2.1 and 2.2)
- * read sif file information
- * read ccf file information
- * fix reading of periodic sampling events (non-neural event type)
- (file spec 2.1 and 2.2)
- """
- import datetime
- import os
- import re
- import warnings
- import numpy as np
- import quantities as pq
- import neo.io.blackrockio
- from neo.io.baseio import BaseIO
- from neo.core import (Block, Segment, SpikeTrain, Unit, Event,
- ChannelIndex, AnalogSignal)
- if __name__ == '__main__':
- pass
- class BlackrockIO(BaseIO):
- """
- Class for reading data in from a file set recorded by the Blackrock
- (Cerebus) recording system.
- Upon initialization, the class is linked to the available set of Blackrock
- files. Data can be read as a neo Block or neo Segment object using the
- read_block or read_segment function, respectively.
- Note: This routine will handle files according to specification 2.1, 2.2,
- and 2.3. Recording pauses that may occur in file specifications 2.2 and
- 2.3 are automatically extracted and the data set is split into different
- segments.
- Inherits from:
- neo.io.BaseIO
- The Blackrock data format consists not of a single file, but a set of
- different files. This constructor associates itself with a set of files
- that constitute a common data set. By default, all files belonging to
- the file set have the same base name, but different extensions.
- However, by using the override parameters, individual filenames can
- be set.
- Args:
- filename (string):
- File name (without extension) of the set of Blackrock files to
- associate with. Any .nsX or .nev, .sif, or .ccf extensions are
- ignored when parsing this parameter.
- nsx_override (string):
- File name of the .nsX files (without extension). If None,
- filename is used.
- Default: None.
- nev_override (string):
- File name of the .nev file (without extension). If None,
- filename is used.
- Default: None.
- sif_override (string):
- File name of the .sif file (without extension). If None,
- filename is used.
- Default: None.
- ccf_override (string):
- File name of the .ccf file (without extension). If None,
- filename is used.
- Default: None.
- verbose (boolean):
- If True, the class will output additional diagnostic
- information on stdout.
- Default: False
- Returns:
- -
- Examples:
- >>> a = BlackrockIO('myfile')
- Loads a set of file consisting of files myfile.ns1, ...,
- myfile.ns6, and myfile.nev
- >>> b = BlackrockIO('myfile', nev_override='sorted')
- Loads the analog data from the set of files myfile.ns1, ...,
- myfile.ns6, but reads spike/event data from sorted.nev
- """
- # Class variables demonstrating capabilities of this IO
- is_readable = True
- is_writable = False
- # This IO can only manipulate continuous data, spikes, and events
- supported_objects = [
- Block, Segment, Event, AnalogSignal, SpikeTrain, Unit, ChannelIndex]
- readable_objects = [Block, Segment]
- writeable_objects = []
- has_header = False
- is_streameable = False
- read_params = {
- Block: [
- ('nsx_to_load', {
- 'value': 'none',
- 'label': "List of nsx files (ids, int) to read."}),
- ('n_starts', {
- 'value': None,
- 'label': "List of n_start points (Quantity) to create "
- "segments from."}),
- ('n_stops', {
- 'value': None,
- 'label': "List of n_stop points (Quantity) to create "
- "segments from."}),
- ('channels', {
- 'value': 'none',
- 'label': "List of channels (ids, int) to load data from."}),
- ('units', {
- 'value': 'none',
- 'label': "Dictionary for units (values, list of int) to load "
- "for each channel (key, int)."}),
- ('load_waveforms', {
- 'value': False,
- 'label': "States if waveforms should be loaded and attached "
- "to spiketrain"}),
- ('load_events', {
- 'value': False,
- 'label': "States if events should be loaded."})],
- Segment: [
- ('n_start', {
- 'label': "Start time point (Quantity) for segment"}),
- ('n_stop', {
- 'label': "Stop time point (Quantity) for segment"}),
- ('nsx_to_load', {
- 'value': 'none',
- 'label': "List of nsx files (ids, int) to read."}),
- ('channels', {
- 'value': 'none',
- 'label': "List of channels (ids, int) to load data from."}),
- ('units', {
- 'value': 'none',
- 'label': "Dictionary for units (values, list of int) to load "
- "for each channel (key, int)."}),
- ('load_waveforms', {
- 'value': False,
- 'label': "States if waveforms should be loaded and attached "
- "to spiketrain"}),
- ('load_events', {
- 'value': False,
- 'label': "States if events should be loaded."})]}
- write_params = {}
- name = 'Blackrock IO'
- description = "This IO reads .nev/.nsX file of the Blackrock " + \
- "(Cerebus) recordings system."
- # The possible file extensions of the Cerebus system and their content:
- # ns1: contains analog data; sampled at 500 Hz (+ digital filters)
- # ns2: contains analog data; sampled at 1000 Hz (+ digital filters)
- # ns3: contains analog data; sampled at 2000 Hz (+ digital filters)
- # ns4: contains analog data; sampled at 10000 Hz (+ digital filters)
- # ns5: contains analog data; sampled at 30000 Hz (+ digital filters)
- # ns6: contains analog data; sampled at 30000 Hz (no digital filters)
- # nev: contains spike- and event-data; sampled at 30000 Hz
- # sif: contains institution and patient info (XML)
- # ccf: contains Cerebus configurations
- extensions = ['ns' + str(_) for _ in range(1, 7)]
- extensions.extend(['nev', 'sif', 'ccf'])
- mode = 'file'
- def __init__(self, filename, nsx_override=None, nev_override=None,
- sif_override=None, ccf_override=None, verbose=False):
- """
- Initialize the BlackrockIO class.
- """
- warnings.warn('{} is deprecated and will be removed in neo version 0.10. Use {} instead.'
- ''.format(self.__class__, neo.io.blackrockio.BlackrockIO), FutureWarning)
- BaseIO.__init__(self)
- # Used to avoid unnecessary repetition of verbose messages
- self.__verbose_messages = []
- # remove extension from base _filenames
- for ext in self.extensions:
- self.filename = re.sub(
- os.path.extsep + ext + '$', '', filename)
- # remove extensions from overrides
- self._filenames = {}
- if nsx_override:
- self._filenames['nsx'] = re.sub(
- os.path.extsep + r'ns[1,2,3,4,5,6]$', '', nsx_override)
- else:
- self._filenames['nsx'] = self.filename
- if nev_override:
- self._filenames['nev'] = re.sub(
- os.path.extsep + r'nev$', '', nev_override)
- else:
- self._filenames['nev'] = self.filename
- if sif_override:
- self._filenames['sif'] = re.sub(
- os.path.extsep + r'sif$', '', sif_override)
- else:
- self._filenames['sif'] = self.filename
- if ccf_override:
- self._filenames['ccf'] = re.sub(
- os.path.extsep + r'ccf$', '', ccf_override)
- else:
- self._filenames['ccf'] = self.filename
- # check which files are available
- self._avail_files = dict.fromkeys(self.extensions, False)
- self._avail_nsx = []
- for ext in self.extensions:
- if ext.startswith('ns'):
- file2check = ''.join(
- [self._filenames['nsx'], os.path.extsep, ext])
- else:
- file2check = ''.join(
- [self._filenames[ext], os.path.extsep, ext])
- if os.path.exists(file2check):
- self._print_verbose("Found " + file2check + ".")
- self._avail_files[ext] = True
- if ext.startswith('ns'):
- self._avail_nsx.append(int(ext[-1]))
- # check if there are any files present
- if not any(list(self._avail_files.values())):
- raise IOError(
- 'No Blackrock files present at {}'.format(filename))
- # check if manually specified files were found
- exts = ['nsx', 'nev', 'sif', 'ccf']
- ext_overrides = [nsx_override, nev_override, sif_override, ccf_override]
- for ext, ext_override in zip(exts, ext_overrides):
- if ext_override is not None and self._avail_files[ext] is False:
- raise ValueError('Specified {} file {} could not be '
- 'found.'.format(ext, ext_override))
- # These dictionaries are used internally to map the file specification
- # revision of the nsx and nev files to one of the reading routines
- self.__nsx_header_reader = {
- '2.1': self.__read_nsx_header_variant_a,
- '2.2': self.__read_nsx_header_variant_b,
- '2.3': self.__read_nsx_header_variant_b}
- self.__nsx_dataheader_reader = {
- '2.1': self.__read_nsx_dataheader_variant_a,
- '2.2': self.__read_nsx_dataheader_variant_b,
- '2.3': self.__read_nsx_dataheader_variant_b}
- self.__nsx_data_reader = {
- '2.1': self.__read_nsx_data_variant_a,
- '2.2': self.__read_nsx_data_variant_b,
- '2.3': self.__read_nsx_data_variant_b}
- self.__nev_header_reader = {
- '2.1': self.__read_nev_header_variant_a,
- '2.2': self.__read_nev_header_variant_b,
- '2.3': self.__read_nev_header_variant_c}
- self.__nev_data_reader = {
- '2.1': self.__read_nev_data_variant_a,
- '2.2': self.__read_nev_data_variant_a,
- '2.3': self.__read_nev_data_variant_b}
- self.__nsx_params = {
- '2.1': self.__get_nsx_param_variant_a,
- '2.2': self.__get_nsx_param_variant_b,
- '2.3': self.__get_nsx_param_variant_b}
- self.__nsx_databl_param = {
- '2.1': self.__get_nsx_databl_param_variant_a,
- '2.2': self.__get_nsx_databl_param_variant_b,
- '2.3': self.__get_nsx_databl_param_variant_b}
- self.__waveform_size = {
- '2.1': self.__get_waveform_size_variant_a,
- '2.2': self.__get_waveform_size_variant_a,
- '2.3': self.__get_waveform_size_variant_b}
- self.__channel_labels = {
- '2.1': self.__get_channel_labels_variant_a,
- '2.2': self.__get_channel_labels_variant_b,
- '2.3': self.__get_channel_labels_variant_b}
- self.__nsx_rec_times = {
- '2.1': self.__get_nsx_rec_times_variant_a,
- '2.2': self.__get_nsx_rec_times_variant_b,
- '2.3': self.__get_nsx_rec_times_variant_b}
- self.__nonneural_evtypes = {
- '2.1': self.__get_nonneural_evtypes_variant_a,
- '2.2': self.__get_nonneural_evtypes_variant_a,
- '2.3': self.__get_nonneural_evtypes_variant_b}
- # Load file spec and headers of available nev file
- if self._avail_files['nev']:
- # read nev file specification
- self.__nev_spec = self.__extract_nev_file_spec()
- self._print_verbose('Specification Version ' + self.__nev_spec)
- # read nev headers
- self.__nev_basic_header, self.__nev_ext_header = \
- self.__nev_header_reader[self.__nev_spec]()
- # Load file spec and headers of available nsx files
- self.__nsx_spec = {}
- self.__nsx_basic_header = {}
- self.__nsx_ext_header = {}
- self.__nsx_data_header = {}
- for nsx_nb in self._avail_nsx:
- # read nsx file specification
- self.__nsx_spec[nsx_nb] = self.__extract_nsx_file_spec(nsx_nb)
- # read nsx headers
- self.__nsx_basic_header[nsx_nb], self.__nsx_ext_header[nsx_nb] = \
- self.__nsx_header_reader[self.__nsx_spec[nsx_nb]](nsx_nb)
- # Read nsx data header(s) for nsx
- self.__nsx_data_header[nsx_nb] = self.__nsx_dataheader_reader[
- self.__nsx_spec[nsx_nb]](nsx_nb)
- def _print_verbose(self, text):
- """
- Print a verbose diagnostic message (string).
- """
- if self.__verbose_messages:
- if text not in self.__verbose_messages:
- self.__verbose_messages.append(text)
- print(str(self.__class__.__name__) + ': ' + text)
- def __extract_nsx_file_spec(self, nsx_nb):
- """
- Extract file specification from an .nsx file.
- """
- filename = '.'.join([self._filenames['nsx'], 'ns%i' % nsx_nb])
- # Header structure of files specification 2.2 and higher. For files 2.1
- # and lower, the entries ver_major and ver_minor are not supported.
- dt0 = [
- ('file_id', 'S8'),
- ('ver_major', 'uint8'),
- ('ver_minor', 'uint8')]
- nsx_file_id = np.fromfile(filename, count=1, dtype=dt0)[0]
- if nsx_file_id['file_id'].decode() == 'NEURALSG':
- spec = '2.1'
- elif nsx_file_id['file_id'].decode() == 'NEURALCD':
- spec = '{}.{}'.format(
- nsx_file_id['ver_major'], nsx_file_id['ver_minor'])
- else:
- raise IOError('Unsupported NSX file type.')
- return spec
- def __extract_nev_file_spec(self):
- """
- Extract file specification from an .nev file
- """
- filename = '.'.join([self._filenames['nev'], 'nev'])
- # Header structure of files specification 2.2 and higher. For files 2.1
- # and lower, the entries ver_major and ver_minor are not supported.
- dt0 = [
- ('file_id', 'S8'),
- ('ver_major', 'uint8'),
- ('ver_minor', 'uint8')]
- nev_file_id = np.fromfile(filename, count=1, dtype=dt0)[0]
- if nev_file_id['file_id'].decode() == 'NEURALEV':
- spec = '{}.{}'.format(
- nev_file_id['ver_major'], nev_file_id['ver_minor'])
- else:
- raise IOError('NEV file type {} is not supported'.format(
- nev_file_id['file_id']))
- return spec
- def __read_nsx_header_variant_a(self, nsx_nb):
- """
- Extract nsx header information from a 2.1 .nsx file
- """
- filename = '.'.join([self._filenames['nsx'], 'ns%i' % nsx_nb])
- # basic header (file_id: NEURALCD)
- dt0 = [
- ('file_id', 'S8'),
- # label of sampling groun (e.g. "1kS/s" or "LFP Low")
- ('label', 'S16'),
- # number of 1/30000 seconds between data points
- # (e.g., if sampling rate "1 kS/s", period equals "30")
- ('period', 'uint32'),
- ('channel_count', 'uint32')]
- nsx_basic_header = np.fromfile(filename, count=1, dtype=dt0)[0]
- # "extended" header (last field of file_id: NEURALCD)
- # (to facilitate compatibility with higher file specs)
- offset_dt0 = np.dtype(dt0).itemsize
- shape = nsx_basic_header['channel_count']
- # originally called channel_id in Blackrock user manual
- # (to facilitate compatibility with higher file specs)
- dt1 = [('electrode_id', 'uint32')]
- nsx_ext_header = np.memmap(
- filename, mode='r', shape=shape, offset=offset_dt0, dtype=dt1)
- return nsx_basic_header, nsx_ext_header
- def __read_nsx_header_variant_b(self, nsx_nb):
- """
- Extract nsx header information from a 2.2 or 2.3 .nsx file
- """
- filename = '.'.join([self._filenames['nsx'], 'ns%i' % nsx_nb])
- # basic header (file_id: NEURALCD)
- dt0 = [
- ('file_id', 'S8'),
- # file specification split into major and minor version number
- ('ver_major', 'uint8'),
- ('ver_minor', 'uint8'),
- # bytes of basic & extended header
- ('bytes_in_headers', 'uint32'),
- # label of the sampling group (e.g., "1 kS/s" or "LFP low")
- ('label', 'S16'),
- ('comment', 'S256'),
- ('period', 'uint32'),
- ('timestamp_resolution', 'uint32'),
- # time origin: 2byte uint16 values for ...
- ('year', 'uint16'),
- ('month', 'uint16'),
- ('weekday', 'uint16'),
- ('day', 'uint16'),
- ('hour', 'uint16'),
- ('minute', 'uint16'),
- ('second', 'uint16'),
- ('millisecond', 'uint16'),
- # number of channel_count match number of extended headers
- ('channel_count', 'uint32')]
- nsx_basic_header = np.fromfile(filename, count=1, dtype=dt0)[0]
- # extended header (type: CC)
- offset_dt0 = np.dtype(dt0).itemsize
- shape = nsx_basic_header['channel_count']
- dt1 = [
- ('type', 'S2'),
- ('electrode_id', 'uint16'),
- ('electrode_label', 'S16'),
- # used front-end amplifier bank (e.g., A, B, C, D)
- ('physical_connector', 'uint8'),
- # used connector pin (e.g., 1-37 on bank A, B, C or D)
- ('connector_pin', 'uint8'),
- # digital and analog value ranges of the signal
- ('min_digital_val', 'int16'),
- ('max_digital_val', 'int16'),
- ('min_analog_val', 'int16'),
- ('max_analog_val', 'int16'),
- # units of the analog range values ("mV" or "uV")
- ('units', 'S16'),
- # filter settings used to create nsx from source signal
- ('hi_freq_corner', 'uint32'),
- ('hi_freq_order', 'uint32'),
- ('hi_freq_type', 'uint16'), # 0=None, 1=Butterworth
- ('lo_freq_corner', 'uint32'),
- ('lo_freq_order', 'uint32'),
- ('lo_freq_type', 'uint16')] # 0=None, 1=Butterworth
- nsx_ext_header = np.memmap(
- filename, mode='r', shape=shape, offset=offset_dt0, dtype=dt1)
- return nsx_basic_header, nsx_ext_header
- def __read_nsx_dataheader(self, nsx_nb, offset):
- """
- Reads data header following the given offset of an nsx file.
- """
- filename = '.'.join([self._filenames['nsx'], 'ns%i' % nsx_nb])
- # dtypes data header
- dt2 = [
- ('header', 'uint8'),
- ('timestamp', 'uint32'),
- ('nb_data_points', 'uint32')]
- return np.memmap(
- filename, mode='r', dtype=dt2, shape=1, offset=offset)[0]
- def __read_nsx_dataheader_variant_a(
- self, nsx_nb, filesize=None, offset=None):
- """
- Reads None for the nsx data header of file spec 2.1. Introduced to
- facilitate compatibility with higher file spec.
- """
- return None
- def __read_nsx_dataheader_variant_b(
- self, nsx_nb, filesize=None, offset=None, ):
- """
- Reads the nsx data header for each data block following the offset of
- file spec 2.2 and 2.3.
- """
- filename = '.'.join([self._filenames['nsx'], 'ns%i' % nsx_nb])
- filesize = self.__get_file_size(filename)
- data_header = {}
- index = 0
- if offset is None:
- offset = self.__nsx_basic_header[nsx_nb]['bytes_in_headers']
- while offset < filesize:
- index += 1
- dh = self.__read_nsx_dataheader(nsx_nb, offset)
- data_header[index] = {
- 'header': dh['header'],
- 'timestamp': dh['timestamp'],
- 'nb_data_points': dh['nb_data_points'],
- 'offset_to_data_block': offset + dh.dtype.itemsize}
- # data size = number of data points * (2bytes * number of channels)
- # use of `int` avoids overflow problem
- data_size = int(dh['nb_data_points']) * \
- int(self.__nsx_basic_header[nsx_nb]['channel_count']) * 2
- # define new offset (to possible next data block)
- offset = data_header[index]['offset_to_data_block'] + data_size
- return data_header
- def __read_nsx_data_variant_a(self, nsx_nb):
- """
- Extract nsx data from a 2.1 .nsx file
- """
- filename = '.'.join([self._filenames['nsx'], 'ns%i' % nsx_nb])
- # get shape of data
- shape = (
- self.__nsx_databl_param['2.1']('nb_data_points', nsx_nb),
- self.__nsx_basic_header[nsx_nb]['channel_count'])
- offset = self.__nsx_params['2.1']('bytes_in_headers', nsx_nb)
- # read nsx data
- # store as dict for compatibility with higher file specs
- data = {1: np.memmap(
- filename, mode='r', dtype='int16', shape=shape, offset=offset)}
- return data
- def __read_nsx_data_variant_b(self, nsx_nb):
- """
- Extract nsx data (blocks) from a 2.2 or 2.3 .nsx file. Blocks can arise
- if the recording was paused by the user.
- """
- filename = '.'.join([self._filenames['nsx'], 'ns%i' % nsx_nb])
- data = {}
- for data_bl in self.__nsx_data_header[nsx_nb].keys():
- # get shape and offset of data
- shape = (
- self.__nsx_data_header[nsx_nb][data_bl]['nb_data_points'],
- self.__nsx_basic_header[nsx_nb]['channel_count'])
- offset = \
- self.__nsx_data_header[nsx_nb][data_bl]['offset_to_data_block']
- # read data
- data[data_bl] = np.memmap(
- filename, mode='r', dtype='int16', shape=shape, offset=offset)
- return data
- def __read_nev_header(self, ext_header_variants):
- """
- Extract nev header information from a 2.1 .nsx file
- """
- filename = '.'.join([self._filenames['nev'], 'nev'])
- # basic header
- dt0 = [
- # Set to "NEURALEV"
- ('file_type_id', 'S8'),
- ('ver_major', 'uint8'),
- ('ver_minor', 'uint8'),
- # Flags
- ('additionnal_flags', 'uint16'),
- # File index of first data sample
- ('bytes_in_headers', 'uint32'),
- # Number of bytes per data packet (sample)
- ('bytes_in_data_packets', 'uint32'),
- # Time resolution of time stamps in Hz
- ('timestamp_resolution', 'uint32'),
- # Sampling frequency of waveforms in Hz
- ('sample_resolution', 'uint32'),
- ('year', 'uint16'),
- ('month', 'uint16'),
- ('weekday', 'uint16'),
- ('day', 'uint16'),
- ('hour', 'uint16'),
- ('minute', 'uint16'),
- ('second', 'uint16'),
- ('millisecond', 'uint16'),
- ('application_to_create_file', 'S32'),
- ('comment_field', 'S256'),
- # Number of extended headers
- ('nb_ext_headers', 'uint32')]
- nev_basic_header = np.fromfile(filename, count=1, dtype=dt0)[0]
- # extended header
- # this consist in N block with code 8bytes + 24 data bytes
- # the data bytes depend on the code and need to be converted
- # cafilename_nsx, segse by case
- shape = nev_basic_header['nb_ext_headers']
- offset_dt0 = np.dtype(dt0).itemsize
- # This is the common structure of the beginning of extended headers
- dt1 = [
- ('packet_id', 'S8'),
- ('info_field', 'S24')]
- raw_ext_header = np.memmap(
- filename, mode='r', offset=offset_dt0, dtype=dt1, shape=shape)
- nev_ext_header = {}
- for packet_id in ext_header_variants.keys():
- mask = (raw_ext_header['packet_id'] == packet_id)
- dt2 = self.__nev_ext_header_types()[packet_id][
- ext_header_variants[packet_id]]
- nev_ext_header[packet_id] = raw_ext_header.view(dt2)[mask]
- return nev_basic_header, nev_ext_header
- def __read_nev_header_variant_a(self):
- """
- Extract nev header information from a 2.1 .nev file
- """
- ext_header_variants = {
- b'NEUEVWAV': 'a',
- b'ARRAYNME': 'a',
- b'ECOMMENT': 'a',
- b'CCOMMENT': 'a',
- b'MAPFILE': 'a',
- b'NSASEXEV': 'a'}
- return self.__read_nev_header(ext_header_variants)
- def __read_nev_header_variant_b(self):
- """
- Extract nev header information from a 2.2 .nev file
- """
- ext_header_variants = {
- b'NEUEVWAV': 'b',
- b'ARRAYNME': 'a',
- b'ECOMMENT': 'a',
- b'CCOMMENT': 'a',
- b'MAPFILE': 'a',
- b'NEUEVLBL': 'a',
- b'NEUEVFLT': 'a',
- b'DIGLABEL': 'a',
- b'NSASEXEV': 'a'}
- return self.__read_nev_header(ext_header_variants)
- def __read_nev_header_variant_c(self):
- """
- Extract nev header information from a 2.3 .nev file
- """
- ext_header_variants = {
- b'NEUEVWAV': 'b',
- b'ARRAYNME': 'a',
- b'ECOMMENT': 'a',
- b'CCOMMENT': 'a',
- b'MAPFILE': 'a',
- b'NEUEVLBL': 'a',
- b'NEUEVFLT': 'a',
- b'DIGLABEL': 'a',
- b'VIDEOSYN': 'a',
- b'TRACKOBJ': 'a'}
- return self.__read_nev_header(ext_header_variants)
- def __read_nev_data(self, nev_data_masks, nev_data_types):
- """
- Extract nev data from a 2.1 or 2.2 .nev file
- """
- filename = '.'.join([self._filenames['nev'], 'nev'])
- data_size = self.__nev_basic_header['bytes_in_data_packets']
- header_size = self.__nev_basic_header['bytes_in_headers']
- # read all raw data packets and markers
- dt0 = [
- ('timestamp', 'uint32'),
- ('packet_id', 'uint16'),
- ('value', 'S{}'.format(data_size - 6))]
- raw_data = np.memmap(filename, mode='r', offset=header_size, dtype=dt0)
- masks = self.__nev_data_masks(raw_data['packet_id'])
- types = self.__nev_data_types(data_size)
- data = {}
- for k, v in nev_data_masks.items():
- data[k] = raw_data.view(types[k][nev_data_types[k]])[masks[k][v]]
- return data
- def __read_nev_data_variant_a(self):
- """
- Extract nev data from a 2.1 & 2.2 .nev file
- """
- nev_data_masks = {
- 'NonNeural': 'a',
- 'Spikes': 'a'}
- nev_data_types = {
- 'NonNeural': 'a',
- 'Spikes': 'a'}
- return self.__read_nev_data(nev_data_masks, nev_data_types)
- def __read_nev_data_variant_b(self):
- """
- Extract nev data from a 2.3 .nev file
- """
- nev_data_masks = {
- 'NonNeural': 'a',
- 'Spikes': 'b',
- 'Comments': 'a',
- 'VideoSync': 'a',
- 'TrackingEvents': 'a',
- 'ButtonTrigger': 'a',
- 'ConfigEvent': 'a'}
- nev_data_types = {
- 'NonNeural': 'b',
- 'Spikes': 'a',
- 'Comments': 'a',
- 'VideoSync': 'a',
- 'TrackingEvents': 'a',
- 'ButtonTrigger': 'a',
- 'ConfigEvent': 'a'}
- return self.__read_nev_data(nev_data_masks, nev_data_types)
- def __nev_ext_header_types(self):
- """
- Defines extended header types for different .nev file specifications.
- """
- nev_ext_header_types = {
- b'NEUEVWAV': {
- # Version>=2.1
- 'a': [
- ('packet_id', 'S8'),
- ('electrode_id', 'uint16'),
- ('physical_connector', 'uint8'),
- ('connector_pin', 'uint8'),
- ('digitization_factor', 'uint16'),
- ('energy_threshold', 'uint16'),
- ('hi_threshold', 'int16'),
- ('lo_threshold', 'int16'),
- ('nb_sorted_units', 'uint8'),
- # number of bytes per waveform sample
- ('bytes_per_waveform', 'uint8'),
- ('unused', 'S10')],
- # Version>=2.3
- 'b': [
- ('packet_id', 'S8'),
- ('electrode_id', 'uint16'),
- ('physical_connector', 'uint8'),
- ('connector_pin', 'uint8'),
- ('digitization_factor', 'uint16'),
- ('energy_threshold', 'uint16'),
- ('hi_threshold', 'int16'),
- ('lo_threshold', 'int16'),
- ('nb_sorted_units', 'uint8'),
- # number of bytes per waveform sample
- ('bytes_per_waveform', 'uint8'),
- # number of samples for each waveform
- ('spike_width', 'uint16'),
- ('unused', 'S8')]},
- b'ARRAYNME': {
- 'a': [
- ('packet_id', 'S8'),
- ('electrode_array_name', 'S24')]},
- b'ECOMMENT': {
- 'a': [
- ('packet_id', 'S8'),
- ('extra_comment', 'S24')]},
- b'CCOMMENT': {
- 'a': [
- ('packet_id', 'S8'),
- ('continued_comment', 'S24')]},
- b'MAPFILE': {
- 'a': [
- ('packet_id', 'S8'),
- ('mapFile', 'S24')]},
- b'NEUEVLBL': {
- 'a': [
- ('packet_id', 'S8'),
- ('electrode_id', 'uint16'),
- # label of this electrode
- ('label', 'S16'),
- ('unused', 'S6')]},
- b'NEUEVFLT': {
- 'a': [
- ('packet_id', 'S8'),
- ('electrode_id', 'uint16'),
- ('hi_freq_corner', 'uint32'),
- ('hi_freq_order', 'uint32'),
- # 0=None 1=Butterworth
- ('hi_freq_type', 'uint16'),
- ('lo_freq_corner', 'uint32'),
- ('lo_freq_order', 'uint32'),
- # 0=None 1=Butterworth
- ('lo_freq_type', 'uint16'),
- ('unused', 'S2')]},
- b'DIGLABEL': {
- 'a': [
- ('packet_id', 'S8'),
- # Read name of digital
- ('label', 'S16'),
- # 0=serial, 1=parallel
- ('mode', 'uint8'),
- ('unused', 'S7')]},
- b'NSASEXEV': {
- 'a': [
- ('packet_id', 'S8'),
- # Read frequency of periodic packet generation
- ('frequency', 'uint16'),
- # Read if digital input triggers events
- ('digital_input_config', 'uint8'),
- # Read if analog input triggers events
- ('analog_channel_1_config', 'uint8'),
- ('analog_channel_1_edge_detec_val', 'uint16'),
- ('analog_channel_2_config', 'uint8'),
- ('analog_channel_2_edge_detec_val', 'uint16'),
- ('analog_channel_3_config', 'uint8'),
- ('analog_channel_3_edge_detec_val', 'uint16'),
- ('analog_channel_4_config', 'uint8'),
- ('analog_channel_4_edge_detec_val', 'uint16'),
- ('analog_channel_5_config', 'uint8'),
- ('analog_channel_5_edge_detec_val', 'uint16'),
- ('unused', 'S6')]},
- b'VIDEOSYN': {
- 'a': [
- ('packet_id', 'S8'),
- ('video_source_id', 'uint16'),
- ('video_source', 'S16'),
- ('frame_rate', 'float32'),
- ('unused', 'S2')]},
- b'TRACKOBJ': {
- 'a': [
- ('packet_id', 'S8'),
- ('trackable_type', 'uint16'),
- ('trackable_id', 'uint16'),
- ('point_count', 'uint16'),
- ('video_source', 'S16'),
- ('unused', 'S2')]}}
- return nev_ext_header_types
- def __nev_data_masks(self, packet_ids):
- """
- Defines data masks for different .nev file specifications depending on
- the given packet identifiers.
- """
- __nev_data_masks = {
- 'NonNeural': {
- 'a': (packet_ids == 0)},
- 'Spikes': {
- # Version 2.1 & 2.2
- 'a': (0 < packet_ids) & (packet_ids <= 255),
- # Version>=2.3
- 'b': (0 < packet_ids) & (packet_ids <= 2048)},
- 'Comments': {
- 'a': (packet_ids == 0xFFFF)},
- 'VideoSync': {
- 'a': (packet_ids == 0xFFFE)},
- 'TrackingEvents': {
- 'a': (packet_ids == 0xFFFD)},
- 'ButtonTrigger': {
- 'a': (packet_ids == 0xFFFC)},
- 'ConfigEvent': {
- 'a': (packet_ids == 0xFFFB)}}
- return __nev_data_masks
- def __nev_data_types(self, data_size):
- """
- Defines data types for different .nev file specifications depending on
- the given packet identifiers.
- """
- __nev_data_types = {
- 'NonNeural': {
- # Version 2.1 & 2.2
- 'a': [
- ('timestamp', 'uint32'),
- ('packet_id', 'uint16'),
- ('packet_insertion_reason', 'uint8'),
- ('reserved', 'uint8'),
- ('digital_input', 'uint16'),
- ('analog_input_channel_1', 'int16'),
- ('analog_input_channel_2', 'int16'),
- ('analog_input_channel_3', 'int16'),
- ('analog_input_channel_4', 'int16'),
- ('analog_input_channel_5', 'int16'),
- ('unused', 'S{}'.format(data_size - 20))],
- # Version>=2.3
- 'b': [
- ('timestamp', 'uint32'),
- ('packet_id', 'uint16'),
- ('packet_insertion_reason', 'uint8'),
- ('reserved', 'uint8'),
- ('digital_input', 'uint16'),
- ('unused', 'S{}'.format(data_size - 10))]},
- 'Spikes': {
- 'a': [
- ('timestamp', 'uint32'),
- ('packet_id', 'uint16'),
- ('unit_class_nb', 'uint8'),
- ('reserved', 'uint8'),
- ('waveform', 'S{}'.format(data_size - 8))]},
- 'Comments': {
- 'a': [
- ('timestamp', 'uint32'),
- ('packet_id', 'uint16'),
- ('char_set', 'uint8'),
- ('flag', 'uint8'),
- ('data', 'uint32'),
- ('comment', 'S{}'.format(data_size - 12))]},
- 'VideoSync': {
- 'a': [
- ('timestamp', 'uint32'),
- ('packet_id', 'uint16'),
- ('video_file_nb', 'uint16'),
- ('video_frame_nb', 'uint32'),
- ('video_elapsed_time', 'uint32'),
- ('video_source_id', 'uint32'),
- ('unused', 'int8', (data_size - 20,))]},
- 'TrackingEvents': {
- 'a': [
- ('timestamp', 'uint32'),
- ('packet_id', 'uint16'),
- ('parent_id', 'uint16'),
- ('node_id', 'uint16'),
- ('node_count', 'uint16'),
- ('point_count', 'uint16'),
- ('tracking_points', 'uint16', ((data_size - 14) // 2,))]},
- 'ButtonTrigger': {
- 'a': [
- ('timestamp', 'uint32'),
- ('packet_id', 'uint16'),
- ('trigger_type', 'uint16'),
- ('unused', 'int8', (data_size - 8,))]},
- 'ConfigEvent': {
- 'a': [
- ('timestamp', 'uint32'),
- ('packet_id', 'uint16'),
- ('config_change_type', 'uint16'),
- ('config_changed', 'S{}'.format(data_size - 8))]}}
- return __nev_data_types
- def __nev_params(self, param_name):
- """
- Returns wanted nev parameter.
- """
- nev_parameters = {
- 'bytes_in_data_packets':
- self.__nev_basic_header['bytes_in_data_packets'],
- 'rec_datetime': datetime.datetime(
- year=self.__nev_basic_header['year'],
- month=self.__nev_basic_header['month'],
- day=self.__nev_basic_header['day'],
- hour=self.__nev_basic_header['hour'],
- minute=self.__nev_basic_header['minute'],
- second=self.__nev_basic_header['second'],
- microsecond=self.__nev_basic_header['millisecond']),
- 'max_res': self.__nev_basic_header['timestamp_resolution'],
- 'channel_ids': self.__nev_ext_header[b'NEUEVWAV']['electrode_id'],
- 'channel_labels': self.__channel_labels[self.__nev_spec](),
- 'event_unit': pq.CompoundUnit("1.0/{} * s".format(
- self.__nev_basic_header['timestamp_resolution'])),
- 'nb_units': dict(zip(
- self.__nev_ext_header[b'NEUEVWAV']['electrode_id'],
- self.__nev_ext_header[b'NEUEVWAV']['nb_sorted_units'])),
- 'digitization_factor': dict(zip(
- self.__nev_ext_header[b'NEUEVWAV']['electrode_id'],
- self.__nev_ext_header[b'NEUEVWAV']['digitization_factor'])),
- 'data_size': self.__nev_basic_header['bytes_in_data_packets'],
- 'waveform_size': self.__waveform_size[self.__nev_spec](),
- 'waveform_dtypes': self.__get_waveforms_dtype(),
- 'waveform_sampling_rate':
- self.__nev_basic_header['sample_resolution'] * pq.Hz,
- 'waveform_time_unit': pq.CompoundUnit("1.0/{} * s".format(
- self.__nev_basic_header['sample_resolution'])),
- 'waveform_unit': pq.uV}
- return nev_parameters[param_name]
- def __get_file_size(self, filename):
- """
- Returns the file size in bytes for the given file.
- """
- filebuf = open(filename, 'rb')
- filebuf.seek(0, os.SEEK_END)
- file_size = filebuf.tell()
- filebuf.close()
- return file_size
- def __get_min_time(self):
- """
- Returns the smallest time that can be determined from the recording for
- use as the lower bound n in an interval [n,m).
- """
- tp = []
- if self._avail_files['nev']:
- tp.extend(self.__get_nev_rec_times()[0])
- for nsx_i in self._avail_nsx:
- tp.extend(self.__nsx_rec_times[self.__nsx_spec[nsx_i]](nsx_i)[0])
- return min(tp)
- def __get_max_time(self):
- """
- Returns the largest time that can be determined from the recording for
- use as the upper bound m in an interval [n,m).
- """
- tp = []
- if self._avail_files['nev']:
- tp.extend(self.__get_nev_rec_times()[1])
- for nsx_i in self._avail_nsx:
- tp.extend(self.__nsx_rec_times[self.__nsx_spec[nsx_i]](nsx_i)[1])
- return max(tp)
- def __get_nev_rec_times(self):
- """
- Extracts minimum and maximum time points from a nev file.
- """
- filename = '.'.join([self._filenames['nev'], 'nev'])
- dt = [('timestamp', 'uint32')]
- offset = \
- self.__get_file_size(filename) - \
- self.__nev_params('bytes_in_data_packets')
- last_data_packet = np.memmap(
- filename, mode='r', offset=offset, dtype=dt)[0]
- n_starts = [0 * self.__nev_params('event_unit')]
- n_stops = [
- last_data_packet['timestamp'] * self.__nev_params('event_unit')]
- return n_starts, n_stops
- def __get_nsx_rec_times_variant_a(self, nsx_nb):
- """
- Extracts minimum and maximum time points from a 2.1 nsx file.
- """
- filename = '.'.join([self._filenames['nsx'], 'ns%i' % nsx_nb])
- t_unit = self.__nsx_params[self.__nsx_spec[nsx_nb]](
- 'time_unit', nsx_nb)
- highest_res = self.__nev_params('event_unit')
- bytes_in_headers = self.__nsx_params[self.__nsx_spec[nsx_nb]](
- 'bytes_in_headers', nsx_nb)
- nb_data_points = int(
- (self.__get_file_size(filename) - bytes_in_headers)
- / (2 * self.__nsx_basic_header[nsx_nb]['channel_count']) - 1)
- # add n_start
- n_starts = [(0 * t_unit).rescale(highest_res)]
- # add n_stop
- n_stops = [(nb_data_points * t_unit).rescale(highest_res)]
- return n_starts, n_stops
- def __get_nsx_rec_times_variant_b(self, nsx_nb):
- """
- Extracts minimum and maximum time points from a 2.2 or 2.3 nsx file.
- """
- t_unit = self.__nsx_params[self.__nsx_spec[nsx_nb]](
- 'time_unit', nsx_nb)
- highest_res = self.__nev_params('event_unit')
- n_starts = []
- n_stops = []
- # add n-start and n_stop for all data blocks
- for data_bl in self.__nsx_data_header[nsx_nb].keys():
- ts0 = self.__nsx_data_header[nsx_nb][data_bl]['timestamp']
- nbdp = self.__nsx_data_header[nsx_nb][data_bl]['nb_data_points']
- # add n_start
- start = ts0 * t_unit
- n_starts.append(start.rescale(highest_res))
- # add n_stop
- stop = start + nbdp * t_unit
- n_stops.append(stop.rescale(highest_res))
- return sorted(n_starts), sorted(n_stops)
- def __get_waveforms_dtype(self):
- """
- Extracts the actual waveform dtype set for each channel.
- """
- # Blackrock code giving the approiate dtype
- conv = {0: 'int8', 1: 'int8', 2: 'int16', 4: 'int32'}
- # get all electrode ids from nev ext header
- all_el_ids = self.__nev_ext_header[b'NEUEVWAV']['electrode_id']
- # get the dtype of waveform (this is stupidly complicated)
- if self.__is_set(
- np.array(self.__nev_basic_header['additionnal_flags']), 0):
- dtype_waveforms = {k: 'int16' for k in all_el_ids}
- else:
- # extract bytes per waveform
- waveform_bytes = \
- self.__nev_ext_header[b'NEUEVWAV']['bytes_per_waveform']
- # extract dtype for waveforms fro each electrode
- dtype_waveforms = dict(zip(all_el_ids, conv[waveform_bytes]))
- return dtype_waveforms
- def __get_channel_labels_variant_a(self):
- """
- Returns labels for all channels for file spec 2.1
- """
- elids = self.__nev_ext_header[b'NEUEVWAV']['electrode_id']
- labels = []
- for elid in elids:
- if elid < 129:
- labels.append('chan%i' % elid)
- else:
- labels.append('ainp%i' % (elid - 129 + 1))
- return dict(zip(elids, labels))
- def __get_channel_labels_variant_b(self):
- """
- Returns labels for all channels for file spec 2.2 and 2.3
- """
- elids = self.__nev_ext_header[b'NEUEVWAV']['electrode_id']
- labels = self.__nev_ext_header[b'NEUEVLBL']['label']
- return dict(zip(elids, labels)) if len(labels) > 0 else None
- def __get_waveform_size_variant_a(self):
- """
- Returns wavform sizes for all channels for file spec 2.1 and 2.2
- """
- wf_dtypes = self.__get_waveforms_dtype()
- nb_bytes_wf = self.__nev_basic_header['bytes_in_data_packets'] - 8
- wf_sizes = {
- ch: int(nb_bytes_wf / np.dtype(dt).itemsize) for ch, dt in
- wf_dtypes.items()}
- return wf_sizes
- def __get_waveform_size_variant_b(self):
- """
- Returns wavform sizes for all channels for file spec 2.3
- """
- elids = self.__nev_ext_header[b'NEUEVWAV']['electrode_id']
- spike_widths = self.__nev_ext_header[b'NEUEVWAV']['spike_width']
- return dict(zip(elids, spike_widths))
- def __get_left_sweep_waveforms(self):
- """
- Returns left sweep of waveforms for each channel. Left sweep is defined
- as the time from the beginning of the waveform to the trigger time of
- the corresponding spike.
- """
- # TODO: Double check if this is the actual setting for Blackrock
- wf_t_unit = self.__nev_params('waveform_time_unit')
- all_ch = self.__nev_params('channel_ids')
- # TODO: Double check if this is the correct assumption (10 samples)
- # default value: threshold crossing after 10 samples of waveform
- wf_left_sweep = {ch: 10 * wf_t_unit for ch in all_ch}
- # non-default: threshold crossing at center of waveform
- # wf_size = self.__nev_params('waveform_size')
- # wf_left_sweep = dict(
- # [(ch, (wf_size[ch] / 2) * wf_t_unit) for ch in all_ch])
- return wf_left_sweep
- def __get_nsx_param_variant_a(self, param_name, nsx_nb):
- """
- Returns parameter (param_name) for a given nsx (nsx_nb) for file spec
- 2.1.
- """
- # Here, min/max_analog_val and min/max_digital_val are not available in
- # the nsx, so that we must estimate these parameters from the
- # digitization factor of the nev (information by Kian Torab, Blackrock
- # Microsystems). Here dig_factor=max_analog_val/max_digital_val. We set
- # max_digital_val to 1000, and max_analog_val=dig_factor. dig_factor is
- # given in nV by definition, so the units turn out to be uV.
- labels = []
- dig_factor = []
- for elid in self.__nsx_ext_header[nsx_nb]['electrode_id']:
- if self._avail_files['nev']:
- # This is a workaround for the DigitalFactor overflow in NEV
- # files recorded with buggy Cerebus system.
- # Fix taken from: NMPK toolbox by Blackrock,
- # file openNEV, line 464,
- # git rev. d0a25eac902704a3a29fa5dfd3aed0744f4733ed
- df = self.__nev_params('digitization_factor')[elid]
- if df == 21516:
- df = 152592.547
- dig_factor.append(df)
- else:
- dig_factor.append(None)
- if elid < 129:
- labels.append('chan%i' % elid)
- else:
- labels.append('ainp%i' % (elid - 129 + 1))
- nsx_parameters = {
- 'labels': labels,
- 'units': np.array(
- [b'uV']
- * self.__nsx_basic_header[nsx_nb]['channel_count']),
- 'min_analog_val': -1 * np.array(dig_factor),
- 'max_analog_val': np.array(dig_factor),
- 'min_digital_val': np.array(
- [-1000] * self.__nsx_basic_header[nsx_nb]['channel_count']),
- 'max_digital_val': np.array(
- [1000] * self.__nsx_basic_header[nsx_nb]['channel_count']),
- 'timestamp_resolution': 30000,
- 'bytes_in_headers':
- self.__nsx_basic_header[nsx_nb].dtype.itemsize
- + self.__nsx_ext_header[nsx_nb].dtype.itemsize
- * self.__nsx_basic_header[nsx_nb]['channel_count'],
- 'sampling_rate':
- 30000 / self.__nsx_basic_header[nsx_nb]['period'] * pq.Hz,
- 'time_unit': pq.CompoundUnit("1.0/{}*s".format(
- 30000 / self.__nsx_basic_header[nsx_nb]['period']))}
- return nsx_parameters[param_name]
- def __get_nsx_param_variant_b(self, param_name, nsx_nb):
- """
- Returns parameter (param_name) for a given nsx (nsx_nb) for file spec
- 2.2 and 2.3.
- """
- nsx_parameters = {
- 'labels':
- self.__nsx_ext_header[nsx_nb]['electrode_label'],
- 'units':
- self.__nsx_ext_header[nsx_nb]['units'],
- 'min_analog_val':
- self.__nsx_ext_header[nsx_nb]['min_analog_val'],
- 'max_analog_val':
- self.__nsx_ext_header[nsx_nb]['max_analog_val'],
- 'min_digital_val':
- self.__nsx_ext_header[nsx_nb]['min_digital_val'],
- 'max_digital_val':
- self.__nsx_ext_header[nsx_nb]['max_digital_val'],
- 'timestamp_resolution':
- self.__nsx_basic_header[nsx_nb]['timestamp_resolution'],
- 'bytes_in_headers':
- self.__nsx_basic_header[nsx_nb]['bytes_in_headers'],
- 'sampling_rate':
- self.__nsx_basic_header[nsx_nb]['timestamp_resolution']
- / self.__nsx_basic_header[nsx_nb]['period'] * pq.Hz,
- 'time_unit': pq.CompoundUnit("1.0/{}*s".format(
- self.__nsx_basic_header[nsx_nb]['timestamp_resolution']
- / self.__nsx_basic_header[nsx_nb]['period']))}
- return nsx_parameters[param_name]
- def __get_nsx_databl_param_variant_a(
- self, param_name, nsx_nb, n_start=None, n_stop=None):
- """
- Returns data block parameter (param_name) for a given nsx (nsx_nb) for
- file spec 2.1. Arg 'n_start' should not be specified! It is only set
- for compatibility reasons with higher file spec.
- """
- filename = '.'.join([self._filenames['nsx'], 'ns%i' % nsx_nb])
- t_starts, t_stops = \
- self.__nsx_rec_times[self.__nsx_spec[nsx_nb]](nsx_nb)
- bytes_in_headers = self.__nsx_params[self.__nsx_spec[nsx_nb]](
- 'bytes_in_headers', nsx_nb)
- # extract parameters from nsx basic extended and data header
- data_parameters = {
- 'nb_data_points': int(
- (self.__get_file_size(filename) - bytes_in_headers)
- / (2 * self.__nsx_basic_header[nsx_nb]['channel_count']) - 1),
- 'databl_idx': 1,
- 'databl_t_start': t_starts[0],
- 'databl_t_stop': t_stops[0]}
- return data_parameters[param_name]
- def __get_nsx_databl_param_variant_b(
- self, param_name, nsx_nb, n_start, n_stop):
- """
- Returns data block parameter (param_name) for a given nsx (nsx_nb) with
- a wanted n_start for file spec 2.2 and 2.3.
- """
- t_starts, t_stops = \
- self.__nsx_rec_times[self.__nsx_spec[nsx_nb]](nsx_nb)
- # data header
- for d_bl in self.__nsx_data_header[nsx_nb].keys():
- # from "data header" with corresponding t_start and t_stop
- data_parameters = {
- 'nb_data_points':
- self.__nsx_data_header[nsx_nb][d_bl]['nb_data_points'],
- 'databl_idx': d_bl,
- 'databl_t_start': t_starts[d_bl - 1],
- 'databl_t_stop': t_stops[d_bl - 1]}
- if t_starts[d_bl - 1] <= n_start < n_stop <= t_stops[d_bl - 1]:
- return data_parameters[param_name]
- elif n_start < t_starts[d_bl - 1] < n_stop <= t_stops[d_bl - 1]:
- self._print_verbose(
- "User n_start ({}) is smaller than the corresponding "
- "t_start of the available ns{} datablock "
- "({}).".format(n_start, nsx_nb, t_starts[d_bl - 1]))
- return data_parameters[param_name]
- elif t_starts[d_bl - 1] <= n_start < t_stops[d_bl - 1] < n_stop:
- self._print_verbose(
- "User n_stop ({}) is larger than the corresponding "
- "t_stop of the available ns{} datablock "
- "({}).".format(n_stop, nsx_nb, t_stops[d_bl - 1]))
- return data_parameters[param_name]
- elif n_start < t_starts[d_bl - 1] < t_stops[d_bl - 1] < n_stop:
- self._print_verbose(
- "User n_start ({}) is smaller than the corresponding "
- "t_start and user n_stop ({}) is larger than the "
- "corresponding t_stop of the available ns{} datablock "
- "({}).".format(
- n_start, n_stop, nsx_nb,
- (t_starts[d_bl - 1], t_stops[d_bl - 1])))
- return data_parameters[param_name]
- else:
- continue
- raise ValueError(
- "User n_start and n_stop are all smaller or larger than the "
- "t_start and t_stops of all available ns%i datablocks" % nsx_nb)
- def __get_nonneural_evtypes_variant_a(self, data):
- """
- Defines event types and the necessary parameters to extract them from
- a 2.1 and 2.2 nev file.
- """
- # TODO: add annotations of nev ext header (NSASEXEX) to event types
- # digital events
- event_types = {
- 'digital_input_port': {
- 'name': 'digital_input_port',
- 'field': 'digital_input',
- 'mask': self.__is_set(data['packet_insertion_reason'], 0),
- 'desc': "Events of the digital input port"},
- 'serial_input_port': {
- 'name': 'serial_input_port',
- 'field': 'digital_input',
- 'mask':
- self.__is_set(data['packet_insertion_reason'], 0)
- & self.__is_set(data['packet_insertion_reason'], 7),
- 'desc': "Events of the serial input port"}}
- # analog input events via threshold crossings
- for ch in range(5):
- event_types.update({
- 'analog_input_channel_{}'.format(ch + 1): {
- 'name': 'analog_input_channel_{}'.format(ch + 1),
- 'field': 'analog_input_channel_{}'.format(ch + 1),
- 'mask': self.__is_set(
- data['packet_insertion_reason'], ch + 1),
- 'desc': "Values of analog input channel {} in mV "
- "(+/- 5000)".format(ch + 1)}})
- # TODO: define field and desc
- event_types.update({
- 'periodic_sampling_events': {
- 'name': 'periodic_sampling_events',
- 'field': 'digital_input',
- 'mask': self.__is_set(data['packet_insertion_reason'], 6),
- 'desc': 'Periodic sampling event of a certain frequency'}})
- return event_types
- def __get_nonneural_evtypes_variant_b(self, data):
- """
- Defines event types and the necessary parameters to extract them from
- a 2.3 nev file.
- """
- # digital events
- event_types = {
- 'digital_input_port': {
- 'name': 'digital_input_port',
- 'field': 'digital_input',
- 'mask': self.__is_set(data['packet_insertion_reason'], 0),
- 'desc': "Events of the digital input port"},
- 'serial_input_port': {
- 'name': 'serial_input_port',
- 'field': 'digital_input',
- 'mask':
- self.__is_set(data['packet_insertion_reason'], 0)
- & self.__is_set(data['packet_insertion_reason'], 7),
- 'desc': "Events of the serial input port"}}
- return event_types
- def __get_unit_classification(self, un_id):
- """
- Returns the Blackrock unit classification of an online spike sorting
- for the given unit id (un_id).
- """
- # Blackrock unit classification
- if un_id == 0:
- return 'unclassified'
- elif 1 <= un_id <= 16:
- return '{}'.format(un_id)
- elif 17 <= un_id <= 244:
- raise ValueError(
- "Unit id {} is not used by daq system".format(un_id))
- elif un_id == 255:
- return 'noise'
- else:
- raise ValueError("Unit id {} cannot be classified".format(un_id))
- def __is_set(self, flag, pos):
- """
- Checks if bit is set at the given position for flag. If flag is an
- array, an array will be returned.
- """
- return flag & (1 << pos) > 0
- def __transform_nsx_to_load(self, nsx_to_load):
- """
- Transforms the input argument nsx_to_load to a list of integers.
- """
- if hasattr(nsx_to_load, "__len__") and len(nsx_to_load) == 0:
- nsx_to_load = None
- if isinstance(nsx_to_load, int):
- nsx_to_load = [nsx_to_load]
- if isinstance(nsx_to_load, str):
- if nsx_to_load.lower() == 'none':
- nsx_to_load = None
- elif nsx_to_load.lower() == 'all':
- nsx_to_load = self._avail_nsx
- else:
- raise ValueError("Invalid specification of nsx_to_load.")
- if nsx_to_load:
- for nsx_nb in nsx_to_load:
- if not self._avail_files['ns' + str(nsx_nb)]:
- raise ValueError("ns%i is not available" % nsx_nb)
- return nsx_to_load
- def __transform_channels(self, channels, nsx_to_load):
- """
- Transforms the input argument channels to a list of integers.
- """
- all_channels = []
- nsx_to_load = self.__transform_nsx_to_load(nsx_to_load)
- if nsx_to_load is not None:
- for nsx_nb in nsx_to_load:
- all_channels.extend(
- self.__nsx_ext_header[nsx_nb]['electrode_id'].astype(int))
- elec_id = self.__nev_ext_header[b'NEUEVWAV']['electrode_id']
- all_channels.extend(elec_id.astype(int))
- all_channels = np.unique(all_channels).tolist()
- if hasattr(channels, "__len__") and len(channels) == 0:
- channels = None
- if isinstance(channels, int):
- channels = [channels]
- if isinstance(channels, str):
- if channels.lower() == 'none':
- channels = None
- elif channels.lower() == 'all':
- channels = all_channels
- else:
- raise ValueError("Invalid channel specification.")
- if channels:
- if len(set(all_channels) & set(channels)) < len(channels):
- self._print_verbose(
- "Ignoring unknown channel ID(s) specified in in channels.")
- # Make sure, all channels are valid and contain no duplicates
- channels = list(set(all_channels).intersection(set(channels)))
- else:
- self._print_verbose("No channel is specified, therefore no "
- "time series and unit data is loaded.")
- return channels
- def __transform_units(self, units, channels):
- """
- Transforms the input argument nsx_to_load to a dictionary, where keys
- (channels) are int, and values (units) are lists of integers.
- """
- if isinstance(units, dict):
- for ch, u in units.items():
- if ch not in channels:
- self._print_verbose(
- "Units contain a channel id which is not listed in "
- "channels")
- if isinstance(u, int):
- units[ch] = [u]
- if hasattr(u, '__len__') and len(u) == 0:
- units[ch] = None
- if isinstance(u, str):
- if u.lower() == 'none':
- units[ch] = None
- elif u.lower() == 'all':
- units[ch] = list(range(17))
- units[ch].append(255)
- else:
- raise ValueError("Invalid unit specification.")
- else:
- if hasattr(units, "__len__") and len(units) == 0:
- units = None
- if isinstance(units, str):
- if units.lower() == 'none':
- units = None
- elif units.lower() == 'all':
- units = list(range(17))
- units.append(255)
- else:
- raise ValueError("Invalid unit specification.")
- if isinstance(units, int):
- units = [units]
- if (channels is None) and (units is not None):
- raise ValueError(
- 'At least one channel needs to be loaded to load units')
- if units:
- units = dict(zip(channels, [units] * len(channels)))
- if units is None:
- self._print_verbose("No units are specified, therefore no "
- "unit or spiketrain is loaded.")
- return units
- def __transform_times(self, n, default_n):
- """
- Transforms the input argument n_start or n_stop (n) to a list of
- quantities. In case n is None, it is set to a default value provided by
- the given function (default_n).
- """
- highest_res = self.__nev_params('event_unit')
- if isinstance(n, pq.Quantity):
- n = [n.rescale(highest_res)]
- elif hasattr(n, "__len__"):
- n = [tp.rescale(highest_res) if tp is not None
- else default_n for tp in n]
- elif n is None:
- n = [default_n]
- else:
- raise ValueError('Invalid specification of n_start/n_stop.')
- return n
- def __merge_time_ranges(
- self, user_n_starts, user_n_stops, nsx_to_load):
- """
- Merges after a validation the user specified n_starts and n_stops with
- the intrinsically given n_starts and n_stops (from e.g, recording
- pauses) of the file set.
- Final n_starts and n_stops are chosen, so that the time range of each
- resulting segment is set to the best meaningful maximum. This means
- that the duration of the signals stored in the segments might be
- smaller than the actually set duration of the segment.
- """
- # define the higest time resolution
- # (for accurate manipulations of the time settings)
- max_time = self.__get_max_time()
- min_time = self.__get_min_time()
- highest_res = self.__nev_params('event_unit')
- user_n_starts = self.__transform_times(
- user_n_starts, min_time)
- user_n_stops = self.__transform_times(
- user_n_stops, max_time)
- # check if user provided as many n_starts as n_stops
- if len(user_n_starts) != len(user_n_stops):
- raise ValueError("n_starts and n_stops must be of equal length")
- # if necessary reset max n_stop to max time of file set
- start_stop_id = 0
- while start_stop_id < len(user_n_starts):
- if user_n_starts[start_stop_id] < min_time:
- user_n_starts[start_stop_id] = min_time
- self._print_verbose(
- "Entry of n_start '{}' is smaller than min time of the file "
- "set: n_start set to min time of file set"
- "".format(user_n_starts[start_stop_id]))
- if user_n_stops[start_stop_id] > max_time:
- user_n_stops[start_stop_id] = max_time
- self._print_verbose(
- "Entry of n_stop '{}' is larger than max time of the file "
- "set: n_stop set to max time of file set"
- "".format(user_n_stops[start_stop_id]))
- if (user_n_stops[start_stop_id] < min_time
- or user_n_starts[start_stop_id] > max_time):
- user_n_stops.pop(start_stop_id)
- user_n_starts.pop(start_stop_id)
- self._print_verbose(
- "Entry of n_start is larger than max time or entry of "
- "n_stop is smaller than min time of the "
- "file set: n_start and n_stop are ignored")
- continue
- start_stop_id += 1
- # get intrinsic time settings of nsx files (incl. rec pauses)
- n_starts_files = []
- n_stops_files = []
- if nsx_to_load is not None:
- for nsx_nb in nsx_to_load:
- start_stop = \
- self.__nsx_rec_times[self.__nsx_spec[nsx_nb]](nsx_nb)
- n_starts_files.append(start_stop[0])
- n_stops_files.append(start_stop[1])
- # reducing n_starts from wanted nsx files to minima
- # (keep recording pause if it occurs)
- if len(n_starts_files) > 0:
- if np.shape(n_starts_files)[1] > 1:
- n_starts_files = [
- tp * highest_res for tp in np.min(n_starts_files, axis=1)]
- else:
- n_starts_files = [
- tp * highest_res for tp in np.min(n_starts_files, axis=0)]
- # reducing n_starts from wanted nsx files to maxima
- # (keep recording pause if it occurs)
- if len(n_stops_files) > 0:
- if np.shape(n_stops_files)[1] > 1:
- n_stops_files = [
- tp * highest_res for tp in np.max(n_stops_files, axis=1)]
- else:
- n_stops_files = [
- tp * highest_res for tp in np.max(n_stops_files, axis=0)]
- # merge user time settings with intrinsic nsx time settings
- n_starts = []
- n_stops = []
- for start, stop in zip(user_n_starts, user_n_stops):
- # check if start and stop of user create a positive time interval
- if not start < stop:
- raise ValueError(
- "t(i) in n_starts has to be smaller than t(i) in n_stops")
- # Reduce n_starts_files to given intervals of user & add start
- if len(n_starts_files) > 0:
- mask = (n_starts_files > start) & (n_starts_files < stop)
- red_n_starts_files = np.array(n_starts_files)[mask]
- merged_n_starts = [start] + [
- tp * highest_res for tp in red_n_starts_files]
- else:
- merged_n_starts = [start]
- # Reduce n_stops_files to given intervals of user & add stop
- if len(n_stops_files) > 0:
- mask = (n_stops_files > start) & (n_stops_files < stop)
- red_n_stops_files = np.array(n_stops_files)[mask]
- merged_n_stops = [
- tp * highest_res for tp in red_n_stops_files] + [stop]
- else:
- merged_n_stops = [stop]
- # Define combined user and file n_starts and n_stops
- # case one:
- if len(merged_n_starts) == len(merged_n_stops):
- if len(merged_n_starts) + len(merged_n_stops) == 2:
- n_starts.extend(merged_n_starts)
- n_stops.extend(merged_n_stops)
- if len(merged_n_starts) + len(merged_n_stops) > 2:
- merged_n_starts.remove(merged_n_starts[1])
- n_starts.extend([merged_n_starts])
- merged_n_stops.remove(merged_n_stops[-2])
- n_stops.extend(merged_n_stops)
- # case two:
- elif len(merged_n_starts) < len(merged_n_stops):
- n_starts.extend(merged_n_starts)
- merged_n_stops.remove(merged_n_stops[-2])
- n_stops.extend(merged_n_stops)
- # case three:
- elif len(merged_n_starts) > len(merged_n_stops):
- merged_n_starts.remove(merged_n_starts[1])
- n_starts.extend(merged_n_starts)
- n_stops.extend(merged_n_stops)
- if len(n_starts) > len(user_n_starts) and \
- len(n_stops) > len(user_n_stops):
- self._print_verbose(
- "Additional recording pauses were detected. There will be "
- "more segments than the user expects.")
- return n_starts, n_stops
- def __read_event(self, n_start, n_stop, data, ev_dict, lazy=False):
- """
- Creates an event for non-neural experimental events in nev data.
- """
- event_unit = self.__nev_params('event_unit')
- if lazy:
- times = []
- labels = np.array([], dtype='S')
- else:
- times = data['timestamp'][ev_dict['mask']] * event_unit
- labels = data[ev_dict['field']][ev_dict['mask']].astype(str)
- # mask for given time interval
- mask = (times >= n_start) & (times < n_stop)
- if np.sum(mask) > 0:
- ev = Event(
- times=times[mask].astype(float),
- labels=labels[mask],
- name=ev_dict['name'],
- description=ev_dict['desc'])
- if lazy:
- ev.lazy_shape = np.sum(mask)
- else:
- ev = None
- return ev
- def __read_spiketrain(
- self, n_start, n_stop, spikes, channel_id, unit_id,
- load_waveforms=False, scaling='raw', lazy=False):
- """
- Creates spiketrains for Spikes in nev data.
- """
- event_unit = self.__nev_params('event_unit')
- # define a name for spiketrain
- # (unique identifier: 1000 * elid + unit_nb)
- name = "Unit {}".format(1000 * channel_id + unit_id)
- # define description for spiketrain
- desc = 'SpikeTrain from channel: {}, unit: {}'.format(
- channel_id, self.__get_unit_classification(unit_id))
- # get spike times for given time interval
- if not lazy:
- times = spikes['timestamp'] * event_unit
- mask = (times >= n_start) & (times <= n_stop)
- times = times[mask].astype(float)
- else:
- times = np.array([]) * event_unit
- st = SpikeTrain(
- times=times,
- name=name,
- description=desc,
- file_origin='.'.join([self._filenames['nev'], 'nev']),
- t_start=n_start,
- t_stop=n_stop)
- if lazy:
- st.lazy_shape = np.shape(times)
- # load waveforms if requested
- if load_waveforms and not lazy:
- wf_dtype = self.__nev_params('waveform_dtypes')[channel_id]
- wf_size = self.__nev_params('waveform_size')[channel_id]
- waveforms = spikes['waveform'].flatten().view(wf_dtype)
- waveforms = waveforms.reshape(int(spikes.size), 1, int(wf_size))
- if scaling == 'voltage':
- st.waveforms = (
- waveforms[mask] * self.__nev_params('waveform_unit')
- * self.__nev_params('digitization_factor')[channel_id]
- / 1000.)
- elif scaling == 'raw':
- st.waveforms = waveforms[mask] * pq.dimensionless
- else:
- raise ValueError(
- 'Unkown option {1} for parameter scaling.'.format(scaling))
- st.sampling_rate = self.__nev_params('waveform_sampling_rate')
- st.left_sweep = self.__get_left_sweep_waveforms()[channel_id]
- # add additional annotations
- st.annotate(
- unit_id=int(unit_id),
- channel_id=int(channel_id))
- return st
- def __read_analogsignal(
- self, n_start, n_stop, signal, channel_id, nsx_nb,
- scaling='raw', lazy=False):
- """
- Creates analogsignal for signal of channel in nsx data.
- """
- # TODO: The following part is extremely slow, since the memmaps for the
- # headers are created again and again. In particular, this makes lazy
- # loading slow as well. Solution would be to create header memmaps up
- # front.
- # get parameters
- sampling_rate = self.__nsx_params[self.__nsx_spec[nsx_nb]](
- 'sampling_rate', nsx_nb)
- nsx_time_unit = self.__nsx_params[self.__nsx_spec[nsx_nb]](
- 'time_unit', nsx_nb)
- max_ana = self.__nsx_params[self.__nsx_spec[nsx_nb]](
- 'max_analog_val', nsx_nb)
- min_ana = self.__nsx_params[self.__nsx_spec[nsx_nb]](
- 'min_analog_val', nsx_nb)
- max_dig = self.__nsx_params[self.__nsx_spec[nsx_nb]](
- 'max_digital_val', nsx_nb)
- min_dig = self.__nsx_params[self.__nsx_spec[nsx_nb]](
- 'min_digital_val', nsx_nb)
- units = self.__nsx_params[self.__nsx_spec[nsx_nb]](
- 'units', nsx_nb)
- labels = self.__nsx_params[self.__nsx_spec[nsx_nb]](
- 'labels', nsx_nb)
- dbl_idx = self.__nsx_databl_param[self.__nsx_spec[nsx_nb]](
- 'databl_idx', nsx_nb, n_start, n_stop)
- t_start = self.__nsx_databl_param[self.__nsx_spec[nsx_nb]](
- 'databl_t_start', nsx_nb, n_start, n_stop)
- t_stop = self.__nsx_databl_param[self.__nsx_spec[nsx_nb]](
- 'databl_t_stop', nsx_nb, n_start, n_stop)
- elids_nsx = list(self.__nsx_ext_header[nsx_nb]['electrode_id'])
- if channel_id in elids_nsx:
- idx_ch = elids_nsx.index(channel_id)
- else:
- return None
- description = \
- "AnalogSignal from channel: {}, label: {}, nsx: {}".format(
- channel_id, labels[idx_ch], nsx_nb)
- # TODO: Find a more time/memory efficient way to handle lazy loading
- data_times = np.arange(
- t_start.item(), t_stop.item(),
- self.__nsx_basic_header[nsx_nb]['period']) * t_start.units
- mask = (data_times >= n_start) & (data_times < n_stop)
- if lazy:
- lazy_shape = (np.sum(mask),)
- sig_ch = np.array([], dtype='float32')
- sig_unit = pq.dimensionless
- t_start = n_start.rescale('s')
- else:
- data_times = data_times[mask].astype(float)
- if scaling == 'voltage':
- if not self._avail_files['nev']:
- raise ValueError(
- 'Cannot convert signals in filespec 2.1 nsX '
- 'files to voltage without nev file.')
- sig_ch = signal[dbl_idx][:, idx_ch][mask].astype('float32')
- # transform dig value to physical value
- sym_ana = (max_ana[idx_ch] == -min_ana[idx_ch])
- sym_dig = (max_dig[idx_ch] == -min_dig[idx_ch])
- if sym_ana and sym_dig:
- sig_ch *= float(max_ana[idx_ch]) / float(max_dig[idx_ch])
- else:
- # general case (same result as above for symmetric input)
- sig_ch -= min_dig[idx_ch]
- sig_ch *= float(max_ana[idx_ch] - min_ana[idx_ch]) / \
- float(max_dig[idx_ch] - min_dig[idx_ch])
- sig_ch += float(min_ana[idx_ch])
- sig_unit = units[idx_ch].decode()
- elif scaling == 'raw':
- sig_ch = signal[dbl_idx][:, idx_ch][mask].astype(int)
- sig_unit = pq.dimensionless
- else:
- raise ValueError(
- 'Unkown option {1} for parameter '
- 'scaling.'.format(scaling))
- t_start = data_times[0].rescale(nsx_time_unit)
- anasig = AnalogSignal(
- signal=pq.Quantity(sig_ch, sig_unit, copy=False),
- sampling_rate=sampling_rate,
- t_start=t_start,
- name=labels[idx_ch],
- description=description,
- file_origin='.'.join([self._filenames['nsx'], 'ns%i' % nsx_nb]))
- if lazy:
- anasig.lazy_shape = lazy_shape
- anasig.annotate(
- nsx=nsx_nb,
- channel_id=int(channel_id))
- return anasig
- def __read_unit(self, unit_id, channel_id):
- """
- Creates unit with unit id for given channel id.
- """
- # define a name for spiketrain
- # (unique identifier: 1000 * elid + unit_nb)
- name = "Unit {}".format(1000 * channel_id + unit_id)
- # define description for spiketrain
- desc = 'Unit from channel: {}, id: {}'.format(
- channel_id, self.__get_unit_classification(unit_id))
- un = Unit(
- name=name,
- description=desc,
- file_origin='.'.join([self._filenames['nev'], 'nev']))
- # add additional annotations
- un.annotate(
- unit_id=int(unit_id),
- channel_id=int(channel_id))
- return un
- def __read_channelindex(
- self, channel_id, index=None, channel_units=None, cascade=True):
- """
- Returns a ChannelIndex with the given index for the given channels
- containing a neo.core.unit.Unit object list of the given units.
- """
- flt_type = {0: 'None', 1: 'Butterworth'}
- chidx = ChannelIndex(
- np.array([channel_id]),
- file_origin=self.filename)
- if index is not None:
- chidx.index = np.array(index, np.dtype('i'))
- chidx.name = "ChannelIndex {}".format(chidx.index)
- else:
- chidx.name = "ChannelIndex"
- if self._avail_files['nev']:
- channel_labels = self.__nev_params('channel_labels')
- if channel_labels is not None:
- chidx.channel_names = np.array([channel_labels[channel_id]])
- chidx.channel_ids = np.array([channel_id])
- # additional annotations from nev
- if channel_id in self.__nev_ext_header[b'NEUEVWAV']['electrode_id']:
- get_idx = list(
- self.__nev_ext_header[b'NEUEVWAV']['electrode_id']).index(
- channel_id)
- chidx.annotate(
- connector_ID=self.__nev_ext_header[
- b'NEUEVWAV']['physical_connector'][get_idx],
- connector_pinID=self.__nev_ext_header[
- b'NEUEVWAV']['connector_pin'][get_idx],
- nev_dig_factor=self.__nev_ext_header[
- b'NEUEVWAV']['digitization_factor'][get_idx],
- nev_energy_threshold=self.__nev_ext_header[
- b'NEUEVWAV']['energy_threshold'][get_idx] * pq.uV,
- nev_hi_threshold=self.__nev_ext_header[
- b'NEUEVWAV']['hi_threshold'][get_idx] * pq.uV,
- nev_lo_threshold=self.__nev_ext_header[
- b'NEUEVWAV']['lo_threshold'][get_idx] * pq.uV,
- nb_sorted_units=self.__nev_ext_header[
- b'NEUEVWAV']['nb_sorted_units'][get_idx],
- waveform_size=self.__waveform_size[self.__nev_spec](
- )[channel_id] * self.__nev_params('waveform_time_unit'))
- # additional annotations from nev (only for file_spec > 2.1)
- if self.__nev_spec in ['2.2', '2.3']:
- get_idx = list(
- self.__nev_ext_header[
- b'NEUEVFLT']['electrode_id']).index(
- channel_id)
- # filter type codes (extracted from blackrock manual)
- chidx.annotate(
- nev_hi_freq_corner=self.__nev_ext_header[b'NEUEVFLT'][
- 'hi_freq_corner'][get_idx]
- / 1000. * pq.Hz,
- nev_hi_freq_order=self.__nev_ext_header[b'NEUEVFLT'][
- 'hi_freq_order'][get_idx],
- nev_hi_freq_type=flt_type[self.__nev_ext_header[
- b'NEUEVFLT']['hi_freq_type'][get_idx]],
- nev_lo_freq_corner=self.__nev_ext_header[
- b'NEUEVFLT']['lo_freq_corner'][get_idx]
- / 1000. * pq.Hz,
- nev_lo_freq_order=self.__nev_ext_header[
- b'NEUEVFLT']['lo_freq_order'][get_idx],
- nev_lo_freq_type=flt_type[self.__nev_ext_header[
- b'NEUEVFLT']['lo_freq_type'][get_idx]])
- # additional information about the LFP signal
- if self.__nev_spec in ['2.2', '2.3'] and self.__nsx_ext_header:
- # It does not matter which nsX file to ask for this info
- k = list(self.__nsx_ext_header.keys())[0]
- if channel_id in self.__nsx_ext_header[k]['electrode_id']:
- get_idx = list(
- self.__nsx_ext_header[k]['electrode_id']).index(
- channel_id)
- chidx.annotate(
- nsx_hi_freq_corner=self.__nsx_ext_header[k][
- 'hi_freq_corner'][get_idx] / 1000. * pq.Hz,
- nsx_lo_freq_corner=self.__nsx_ext_header[k][
- 'lo_freq_corner'][get_idx] / 1000. * pq.Hz,
- nsx_hi_freq_order=self.__nsx_ext_header[k][
- 'hi_freq_order'][get_idx],
- nsx_lo_freq_order=self.__nsx_ext_header[k][
- 'lo_freq_order'][get_idx],
- nsx_hi_freq_type=flt_type[
- self.__nsx_ext_header[k]['hi_freq_type'][get_idx]],
- nsx_lo_freq_type=flt_type[
- self.__nsx_ext_header[k]['hi_freq_type'][get_idx]])
- chidx.description = \
- "Container for units and groups analogsignals of one recording " \
- "channel across segments."
- if not cascade:
- return chidx
- if self._avail_files['nev']:
- # read nev data
- nev_data = self.__nev_data_reader[self.__nev_spec]()
- if channel_units is not None:
- # extract first data for channel
- ch_mask = (nev_data['Spikes']['packet_id'] == channel_id)
- data_ch = nev_data['Spikes'][ch_mask]
- for un_id in channel_units:
- if un_id in np.unique(data_ch['unit_class_nb']):
- un = self.__read_unit(
- unit_id=un_id, channel_id=channel_id)
- chidx.units.append(un)
- chidx.create_many_to_one_relationship()
- return chidx
- def read_segment(
- self, n_start, n_stop, name=None, description=None, index=None,
- nsx_to_load='none', channels='none', units='none',
- load_waveforms=False, load_events=False, scaling='raw',
- lazy=False, cascade=True):
- """
- Returns an annotated neo.core.segment.Segment.
- Args:
- n_start (Quantity):
- Start time of maximum time range of signals contained in this
- segment.
- n_stop (Quantity):
- Stop time of maximum time range of signals contained in this
- segment.
- name (None, string):
- If None, name is set to default, otherwise it is set to user
- input.
- description (None, string):
- If None, description is set to default, otherwise it is set to
- user input.
- index (None, int):
- If not None, index of segment is set to user index.
- nsx_to_load (int, list, str):
- ID(s) of nsx file(s) from which to load data, e.g., if set to
- 5 only data from the ns5 file are loaded. If 'none' or empty
- list, no nsx files and therefore no analog signals are loaded.
- If 'all', data from all available nsx are loaded.
- channels (int, list, str):
- Channel id(s) from which to load data. If 'none' or empty list,
- no channels and therefore no analog signal or spiketrains are
- loaded. If 'all', all available channels are loaded.
- units (int, list, str, dict):
- ID(s) of unit(s) to load. If 'none' or empty list, no units and
- therefore no spiketrains are loaded. If 'all', all available
- units are loaded. If dict, the above can be specified
- individually for each channel (keys), e.g. {1: 5, 2: 'all'}
- loads unit 5 from channel 1 and all units from channel 2.
- load_waveforms (boolean):
- If True, waveforms are attached to all loaded spiketrains.
- load_events (boolean):
- If True, all recorded events are loaded.
- scaling (str):
- Determines whether time series of individual
- electrodes/channels are returned as AnalogSignals containing
- raw integer samples ('raw'), or scaled to arrays of floats
- representing voltage ('voltage'). Note that for file
- specification 2.1 and lower, the option 'voltage' requires a
- nev file to be present.
- lazy (boolean):
- If True, only the shape of the data is loaded.
- cascade (boolean):
- If True, only the segment without children is returned.
- Returns:
- Segment (neo.Segment):
- Returns the specified segment. See documentation of
- `read_block()` for a full list of annotations of all child
- objects.
- """
- # Make sure that input args are transformed into correct instances
- nsx_to_load = self.__transform_nsx_to_load(nsx_to_load)
- channels = self.__transform_channels(channels, nsx_to_load)
- units = self.__transform_units(units, channels)
- seg = Segment(file_origin=self.filename)
- # set user defined annotations if they were provided
- if index is None:
- seg.index = 0
- else:
- seg.index = index
- if name is None:
- seg.name = "Segment {}".format(seg.index)
- else:
- seg.name = name
- if description is None:
- seg.description = "Segment containing data from t_min to t_max."
- else:
- seg.description = description
- if not cascade:
- return seg
- if self._avail_files['nev']:
- # filename = self._filenames['nev'] + '.nev'
- # annotate segment according to file headers
- seg.rec_datetime = datetime.datetime(
- year=self.__nev_basic_header['year'],
- month=self.__nev_basic_header['month'],
- day=self.__nev_basic_header['day'],
- hour=self.__nev_basic_header['hour'],
- minute=self.__nev_basic_header['minute'],
- second=self.__nev_basic_header['second'],
- microsecond=self.__nev_basic_header['millisecond'])
- # read nev data
- nev_data = self.__nev_data_reader[self.__nev_spec]()
- # read non-neural experimental events
- if load_events:
- ev_dict = self.__nonneural_evtypes[self.__nev_spec](
- nev_data['NonNeural'])
- for ev_type in ev_dict.keys():
- ev = self.__read_event(
- n_start=n_start,
- n_stop=n_stop,
- data=nev_data['NonNeural'],
- ev_dict=ev_dict[ev_type],
- lazy=lazy)
- if ev is not None:
- seg.events.append(ev)
- # TODO: not yet implemented (only avail in nev_spec 2.3)
- # videosync events
- # trackingevents events
- # buttontrigger events
- # configevent events
- # get spiketrain
- if units is not None:
- not_existing_units = []
- for ch_id in units.keys():
- # extract first data for channel
- ch_mask = (nev_data['Spikes']['packet_id'] == ch_id)
- data_ch = nev_data['Spikes'][ch_mask]
- if units[ch_id] is not None:
- for un_id in units[ch_id]:
- if un_id in np.unique(data_ch['unit_class_nb']):
- # extract then data for unit if unit exists
- un_mask = (data_ch['unit_class_nb'] == un_id)
- data_un = data_ch[un_mask]
- st = self.__read_spiketrain(
- n_start=n_start,
- n_stop=n_stop,
- spikes=data_un,
- channel_id=ch_id,
- unit_id=un_id,
- load_waveforms=load_waveforms,
- scaling=scaling,
- lazy=lazy)
- seg.spiketrains.append(st)
- else:
- not_existing_units.append(un_id)
- if not_existing_units:
- self._print_verbose(
- "Units {} on channel {} do not "
- "exist".format(not_existing_units, ch_id))
- else:
- self._print_verbose(
- "There are no units specified for channel "
- "{}".format(ch_id))
- if nsx_to_load is not None:
- for nsx_nb in nsx_to_load:
- # read nsx data
- nsx_data = \
- self.__nsx_data_reader[self.__nsx_spec[nsx_nb]](nsx_nb)
- # read Analogsignals
- for ch_id in channels:
- anasig = self.__read_analogsignal(
- n_start=n_start,
- n_stop=n_stop,
- signal=nsx_data,
- channel_id=ch_id,
- nsx_nb=nsx_nb,
- scaling=scaling,
- lazy=lazy)
- if anasig is not None:
- seg.analogsignals.append(anasig)
- # TODO: not yet implemented
- # if self._avail_files['sif']:
- # sif_header = self._read_sif(self._filenames['sif'] + '.sif')
- # TODO: not yet implemented
- # if self._avail_files['ccf']:
- # ccf_header = self._read_sif(self._filenames['ccf'] + '.ccf')
- seg.create_many_to_one_relationship()
- return seg
- def read_block(
- self, index=None, name=None, description=None, nsx_to_load='none',
- n_starts=None, n_stops=None, channels='none', units='none',
- load_waveforms=False, load_events=False, scaling='raw',
- lazy=False, cascade=True):
- """
- Args:
- index (None, int):
- If not None, index of block is set to user input.
- name (None, str):
- If None, name is set to default, otherwise it is set to user
- input.
- description (None, str):
- If None, description is set to default, otherwise it is set to
- user input.
- nsx_to_load (int, list, str):
- ID(s) of nsx file(s) from which to load data, e.g., if set to
- 5 only data from the ns5 file are loaded. If 'none' or empty
- list, no nsx files and therefore no analog signals are loaded.
- If 'all', data from all available nsx are loaded.
- n_starts (None, Quantity, list):
- Start times for data in each segment. Number of entries must be
- equal to length of n_stops. If None, intrinsic recording start
- times of files set are used.
- n_stops (None, Quantity, list):
- Stop times for data in each segment. Number of entries must be
- equal to length of n_starts. If None, intrinsic recording stop
- times of files set are used.
- channels (int, list, str):
- Channel id(s) from which to load data. If 'none' or empty list,
- no channels and therefore no analog signal or spiketrains are
- loaded. If 'all', all available channels are loaded.
- units (int, list, str, dict):
- ID(s) of unit(s) to load. If 'none' or empty list, no units and
- therefore no spiketrains are loaded. If 'all', all available
- units are loaded. If dict, the above can be specified
- individually for each channel (keys), e.g. {1: 5, 2: 'all'}
- loads unit 5 from channel 1 and all units from channel 2.
- load_waveforms (boolean):
- If True, waveforms are attached to all loaded spiketrains.
- load_events (boolean):
- If True, all recorded events are loaded.
- scaling (str):
- Determines whether time series of individual
- electrodes/channels are returned as AnalogSignals containing
- raw integer samples ('raw'), or scaled to arrays of floats
- representing voltage ('voltage'). Note that for file
- specification 2.1 and lower, the option 'voltage' requires a
- nev file to be present.
- lazy (bool):
- If True, only the shape of the data is loaded.
- cascade (bool or "lazy"):
- If True, only the block without children is returned.
- Returns:
- Block (neo.segment.Block):
- Block linking all loaded Neo objects.
- Block annotations:
- avail_file_set (list):
- List of extensions of all available files for the given
- recording.
- avail_nsx (list of int):
- List of integers specifying the .nsX files available,
- e.g., [2, 5] indicates that an ns2 and and ns5 file are
- available.
- avail_nev (bool):
- True if a .nev file is available.
- avail_ccf (bool):
- True if a .ccf file is available.
- avail_sif (bool):
- True if a .sif file is available.
- rec_pauses (bool):
- True if the session contains a recording pause (i.e.,
- multiple segments).
- nb_segments (int):
- Number of segments created after merging recording
- times specified by user with the intrinsic ones of the
- file set.
- Segment annotations:
- None.
- ChannelIndex annotations:
- waveform_size (Quantitiy):
- Length of time used to save spike waveforms (in units
- of 1/30000 s).
- nev_hi_freq_corner (Quantitiy),
- nev_lo_freq_corner (Quantitiy),
- nev_hi_freq_order (int), nev_lo_freq_order (int),
- nev_hi_freq_type (str), nev_lo_freq_type (str),
- nev_hi_threshold, nev_lo_threshold,
- nev_energy_threshold (quantity):
- Indicates parameters of spike detection.
- nsx_hi_freq_corner (Quantity),
- nsx_lo_freq_corner (Quantity)
- nsx_hi_freq_order (int), nsx_lo_freq_order (int),
- nsx_hi_freq_type (str), nsx_lo_freq_type (str)
- Indicates parameters of the filtered signal in one of
- the files ns1-ns5 (ns6, if available, is not filtered).
- nev_dig_factor (int):
- Digitization factor in microvolts of the nev file, used
- to convert raw samples to volt.
- connector_ID, connector_pinID (int):
- ID of connector and pin on the connector where the
- channel was recorded from.
- nb_sorted_units (int):
- Number of sorted units on this channel (noise, mua and
- sua).
- Unit annotations:
- unit_id (int):
- ID of the unit.
- channel_id (int):
- Channel ID (Blackrock ID) from which the unit was
- loaded (equiv. to the single list entry in the
- attribute channel_ids of ChannelIndex parent).
- AnalogSignal annotations:
- nsx (int):
- nsX file the signal was loaded from, e.g., 5 indicates
- the .ns5 file.
- channel_id (int):
- Channel ID (Blackrock ID) from which the signal was
- loaded.
- Spiketrain annotations:
- unit_id (int):
- ID of the unit from which the spikes were recorded.
- channel_id (int):
- Channel ID (Blackrock ID) from which the spikes were
- loaded.
- Event annotations:
- The resulting Block contains one Event object with the name
- `digital_input_port`. It contains all digitally recorded
- events, with the event code coded in the labels of the
- Event. The Event object contains no further annotation.
- """
- # Make sure that input args are transformed into correct instances
- nsx_to_load = self.__transform_nsx_to_load(nsx_to_load)
- channels = self.__transform_channels(channels, nsx_to_load)
- units = self.__transform_units(units, channels)
- # Create block
- bl = Block(file_origin=self.filename)
- # set user defined annotations if they were provided
- if index is not None:
- bl.index = index
- if name is None:
- bl.name = "Blackrock Data Block"
- else:
- bl.name = name
- if description is None:
- bl.description = "Block of data from Blackrock file set."
- else:
- bl.description = description
- if self._avail_files['nev']:
- bl.rec_datetime = self.__nev_params('rec_datetime')
- bl.annotate(
- avail_file_set=[k for k, v in self._avail_files.items() if v])
- bl.annotate(avail_nsx=self._avail_nsx)
- bl.annotate(avail_nev=self._avail_files['nev'])
- bl.annotate(avail_sif=self._avail_files['sif'])
- bl.annotate(avail_ccf=self._avail_files['ccf'])
- bl.annotate(rec_pauses=False)
- # Test n_starts and n_stops user requirements and combine them if
- # possible with file internal n_starts and n_stops from rec pauses.
- n_starts, n_stops = \
- self.__merge_time_ranges(n_starts, n_stops, nsx_to_load)
- bl.annotate(nb_segments=len(n_starts))
- if not cascade:
- return bl
- # read segment
- for seg_idx, (n_start, n_stop) in enumerate(zip(n_starts, n_stops)):
- seg = self.read_segment(
- n_start=n_start,
- n_stop=n_stop,
- index=seg_idx,
- nsx_to_load=nsx_to_load,
- channels=channels,
- units=units,
- load_waveforms=load_waveforms,
- load_events=load_events,
- scaling=scaling,
- lazy=lazy,
- cascade=cascade)
- bl.segments.append(seg)
- # read channelindexes
- if channels:
- for ch_id in channels:
- if units and ch_id in units.keys():
- ch_units = units[ch_id]
- else:
- ch_units = None
- chidx = self.__read_channelindex(
- channel_id=ch_id,
- index=0,
- channel_units=ch_units,
- cascade=cascade)
- for seg in bl.segments:
- if ch_units:
- for un in chidx.units:
- sts = seg.filter(
- targdict={'name': un.name},
- objects='SpikeTrain')
- for st in sts:
- un.spiketrains.append(st)
- anasigs = seg.filter(
- targdict={'channel_id': ch_id},
- objects='AnalogSignal')
- for anasig in anasigs:
- chidx.analogsignals.append(anasig)
- bl.channel_indexes.append(chidx)
- bl.create_many_to_one_relationship()
- return bl
- def __str__(self):
- """
- Prints summary of the Blackrock data file set.
- """
- output = "\nFile Origins for Blackrock File Set\n" \
- "====================================\n"
- for ftype in self._filenames.keys():
- output += ftype + ':' + self._filenames[ftype] + '\n'
- if self._avail_files['nev']:
- output += "\nEvent Parameters (NEV)\n" \
- "====================================\n" \
- "Timestamp resolution (Hz): " + \
- str(self.__nev_basic_header['timestamp_resolution']) + \
- "\nWaveform resolution (Hz): " + \
- str(self.__nev_basic_header['sample_resolution'])
- if b'NEUEVWAV' in self.__nev_ext_header.keys():
- avail_el = \
- self.__nev_ext_header[b'NEUEVWAV']['electrode_id']
- con = \
- self.__nev_ext_header[b'NEUEVWAV']['physical_connector']
- pin = \
- self.__nev_ext_header[b'NEUEVWAV']['connector_pin']
- nb_units = \
- self.__nev_ext_header[b'NEUEVWAV']['nb_sorted_units']
- output += "\n\nAvailable electrode IDs:\n" \
- "====================================\n"
- for i, el in enumerate(avail_el):
- output += "Electrode ID %i: " % el
- channel_labels = self.__nev_params('channel_labels')
- if channel_labels is not None:
- output += "label %s: " % channel_labels[el]
- output += "connector: %i, " % con[i]
- output += "pin: %i, " % pin[i]
- output += 'nb_units: %i\n' % nb_units[i]
- for nsx_nb in self._avail_nsx:
- analog_res = self.__nsx_params[self.__nsx_spec[nsx_nb]](
- 'sampling_rate', nsx_nb)
- avail_el = [
- el for el in self.__nsx_ext_header[nsx_nb]['electrode_id']]
- output += "\nAnalog Parameters (NS" \
- + str(nsx_nb) + ")\n===================================="
- output += "\nResolution (Hz): %i" % analog_res
- output += "\nAvailable channel IDs: " + \
- ", ".join(["%i" % a for a in avail_el]) + "\n"
- return output
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