def test_convertDatetime(self):
"""
Tests all time conversion methods.
"""
# These values are created using the Linux "date -u -d @TIMESTRING"
# command. These values are assumed to be correct.
timesdict = {
1234567890: UTCDateTime(2009, 2, 13, 23, 31, 30),
1111111111: UTCDateTime(2005, 3, 18, 1, 58, 31),
1212121212: UTCDateTime(2008, 5, 30, 4, 20, 12),
1313131313: UTCDateTime(2011, 8, 12, 6, 41, 53),
100000: UTCDateTime(1970, 1, 2, 3, 46, 40),
100000.111112: UTCDateTime(1970, 1, 2, 3, 46, 40, 111112),
200000000: UTCDateTime(1976, 5, 3, 19, 33, 20)
}
# Loop over timesdict.
for ts, dt in timesdict.iteritems():
self.assertEqual(dt, util._convertMSTimeToDatetime(ts * 1000000L))
self.assertEqual(ts * 1000000L, util._convertDatetimeToMSTime(dt))
# Additional sanity tests.
# Today.
now = UTCDateTime()
self.assertEqual(now, util._convertMSTimeToDatetime(
util._convertDatetimeToMSTime(now)))
# Some random date.
random.seed(815) # make test reproducable
timestring = random.randint(0, 2000000) * 1e6
self.assertEqual(timestring, util._convertDatetimeToMSTime(
util._convertMSTimeToDatetime(timestring)))
def test_convertDatetime(self):
"""
Tests all time conversion methods.
"""
# These values are created using the Linux "date -u -d @TIMESTRING"
# command. These values are assumed to be correct.
timesdict = {
1234567890: UTCDateTime(2009, 2, 13, 23, 31, 30),
1111111111: UTCDateTime(2005, 3, 18, 1, 58, 31),
1212121212: UTCDateTime(2008, 5, 30, 4, 20, 12),
1313131313: UTCDateTime(2011, 8, 12, 6, 41, 53),
100000: UTCDateTime(1970, 1, 2, 3, 46, 40),
100000.111112: UTCDateTime(1970, 1, 2, 3, 46, 40, 111112),
200000000: UTCDateTime(1976, 5, 3, 19, 33, 20)
}
# Loop over timesdict.
for ts, dt in timesdict.iteritems():
self.assertEqual(dt, util._convertMSTimeToDatetime(ts * 1000000L))
self.assertEqual(ts * 1000000L, util._convertDatetimeToMSTime(dt))
# Additional sanity tests.
# Today.
now = UTCDateTime()
self.assertEqual(
now,
util._convertMSTimeToDatetime(util._convertDatetimeToMSTime(now)))
# Some random date.
random.seed(815) # make test reproducable
timestring = random.randint(0, 2000000) * 1e6
self.assertEqual(
timestring,
util._convertDatetimeToMSTime(
util._convertMSTimeToDatetime(timestring)))
def readMSEED(mseed_object,
starttime=None,
endtime=None,
headonly=False,
sourcename=None,
reclen=None,
details=False,
header_byteorder=None,
verbose=None,
**kwargs):
"""
Reads a Mini-SEED file and returns a Stream object.
.. warning::
This function should NOT be called directly, it registers via the
ObsPy :func:`~obspy.core.stream.read` function, call this instead.
:param mseed_object: Filename or open file like object that contains the
binary Mini-SEED data. Any object that provides a read() method will be
considered to be a file like object.
:type starttime: :class:`~obspy.core.utcdatetime.UTCDateTime`
:param starttime: Only read data samples after or at the start time.
:type endtime: :class:`~obspy.core.utcdatetime.UTCDateTime`
:param endtime: Only read data samples before or at the end time.
:param headonly: Determines whether or not to unpack the data or just
read the headers.
:type sourcename: str
:param sourcename: Source name has to have the structure
'network.station.location.channel' and can contain globbing characters.
Defaults to ``None``.
:param reclen: If it is None, it will be automatically determined for every
record. If it is known, just set it to the record length in bytes which
will increase the reading speed slightly.
:type details: bool, optional
:param details: If ``True`` read additional information: timing quality
and availability of calibration information.
Note, that the traces are then also split on these additional
information. Thus the number of traces in a stream will change.
Details are stored in the mseed stats AttribDict of each trace.
-1 specifies for both cases, that these information is not available.
``timing_quality`` specifies the timing quality from 0 to 100 [%].
``calibration_type`` specifies the type of available calibration
information: 1 == Step Calibration, 2 == Sine Calibration, 3 ==
Pseudo-random Calibration, 4 == Generic Calibration and -2 ==
Calibration Abort.
:type header_byteorder: int or str, optional
:param header_byteorder: Must be either ``0`` or ``'<'`` for LSBF or
little-endian, ``1`` or ``'>'`` for MBF or big-endian. ``'='`` is the
native byte order. Used to enforce the header byte order. Useful in
some rare cases where the automatic byte order detection fails.
.. rubric:: Example
>>> from obspy import read
>>> st = read("/path/to/two_channels.mseed")
>>> print(st) # doctest: +ELLIPSIS
2 Trace(s) in Stream:
BW.UH3..EHE | 2010-06-20T00:00:00.279999Z - ... | 200.0 Hz, 386 samples
BW.UH3..EHZ | 2010-06-20T00:00:00.279999Z - ... | 200.0 Hz, 386 samples
>>> from obspy import UTCDateTime
>>> st = read("/path/to/test.mseed",
... starttime=UTCDateTime("2003-05-29T02:16:00"),
... selection="NL.*.*.?HZ")
>>> print(st) # doctest: +ELLIPSIS
1 Trace(s) in Stream:
NL.HGN.00.BHZ | 2003-05-29T02:15:59.993400Z - ... | 40.0 Hz, 5629 samples
"""
# Parse the headonly and reclen flags.
if headonly is True:
unpack_data = 0
else:
unpack_data = 1
if reclen is None:
reclen = -1
elif reclen not in VALID_RECORD_LENGTHS:
msg = 'Invalid record length. Autodetection will be used.'
warnings.warn(msg)
reclen = -1
# Determine the byte order.
if header_byteorder == "=":
header_byteorder = NATIVE_BYTEORDER
if header_byteorder is None:
header_byteorder = -1
elif header_byteorder in [0, "0", "<"]:
header_byteorder = 0
elif header_byteorder in [1, "1", ">"]:
header_byteorder = 1
# The quality flag is no more supported. Raise a warning.
if 'quality' in kwargs:
msg = 'The quality flag is no longer supported in this version of ' + \
'obspy.mseed. obspy.mseed.util has some functions with similar' + \
' behavior.'
warnings.warn(msg, category=DeprecationWarning)
# Parse some information about the file.
if header_byteorder == 0:
bo = "<"
elif header_byteorder > 0:
bo = ">"
else:
bo = None
info = util.getRecordInformation(mseed_object, endian=bo)
# Map the encoding to a readable string value.
if info["encoding"] in ENCODINGS:
info['encoding'] = ENCODINGS[info['encoding']][0]
elif info["encoding"] in UNSUPPORTED_ENCODINGS:
msg = ("Encoding '%s' (%i) is not supported by ObsPy. Please send "
"the file to the ObsPy developers so that we can add "
"support for it.") % \
(UNSUPPORTED_ENCODINGS[info['encoding']], info['encoding'])
raise ValueError(msg)
else:
msg = "Encoding '%i' is not a valid MiniSEED encoding." % \
info['encoding']
raise ValueError(msg)
# Only keep information relevant for the whole file.
info = {
'encoding': info['encoding'],
'filesize': info['filesize'],
'record_length': info['record_length'],
'byteorder': info['byteorder'],
'number_of_records': info['number_of_records']
}
# If its a filename just read it.
if isinstance(mseed_object, (str, native_str)):
# Read to NumPy array which is used as a buffer.
buffer = np.fromfile(mseed_object, dtype=np.int8)
elif hasattr(mseed_object, 'read'):
buffer = np.fromstring(mseed_object.read(), dtype=np.int8)
# Get the record length
try:
record_length = pow(2, int(''.join([chr(_i) for _i in buffer[19:21]])))
except ValueError:
record_length = 4096
# Search for data records and pass only the data part to the underlying C
# routine.
offset = 0
# 0 to 9 are defined in a row in the ASCII charset.
min_ascii = ord('0')
# Small function to check whether an array of ASCII values contains only
# digits.
isdigit = lambda x: True if (x - min_ascii).max() <= 9 else False
while True:
# This should never happen
if (isdigit(buffer[offset:offset + 6]) is False) or \
(buffer[offset + 6] not in VALID_CONTROL_HEADERS):
msg = 'Not a valid (Mini-)SEED file'
raise Exception(msg)
elif buffer[offset + 6] in SEED_CONTROL_HEADERS:
offset += record_length
continue
break
buffer = buffer[offset:]
buflen = len(buffer)
# If no selection is given pass None to the C function.
if starttime is None and endtime is None and sourcename is None:
selections = None
else:
select_time = SelectTime()
selections = Selections()
selections.timewindows.contents = select_time
if starttime is not None:
if not isinstance(starttime, UTCDateTime):
msg = 'starttime needs to be a UTCDateTime object'
raise ValueError(msg)
selections.timewindows.contents.starttime = \
util._convertDatetimeToMSTime(starttime)
else:
# HPTERROR results in no starttime.
selections.timewindows.contents.starttime = HPTERROR
if endtime is not None:
if not isinstance(endtime, UTCDateTime):
msg = 'endtime needs to be a UTCDateTime object'
raise ValueError(msg)
selections.timewindows.contents.endtime = \
util._convertDatetimeToMSTime(endtime)
else:
# HPTERROR results in no starttime.
selections.timewindows.contents.endtime = HPTERROR
if sourcename is not None:
if not isinstance(sourcename, (str, native_str)):
msg = 'sourcename needs to be a string'
raise ValueError(msg)
# libmseed uses underscores as separators and allows filtering
# after the dataquality which is disabled here to not confuse
# users. (* == all data qualities)
selections.srcname = (sourcename.replace('.', '_') + '_*').\
encode('ascii', 'ignore')
else:
selections.srcname = b'*'
all_data = []
# Use a callback function to allocate the memory and keep track of the
# data.
def allocate_data(samplecount, sampletype):
# Enhanced sanity checking for libmseed 2.10 can result in the
# sampletype not being set. Just return an empty array in this case.
if sampletype == b"\x00":
data = np.empty(0)
else:
data = np.empty(samplecount, dtype=DATATYPES[sampletype])
all_data.append(data)
return data.ctypes.data
# XXX: Do this properly!
# Define Python callback function for use in C function. Return a long so
# it hopefully works on 32 and 64 bit systems.
allocData = C.CFUNCTYPE(C.c_long, C.c_int, C.c_char)(allocate_data)
def log_error_or_warning(msg):
if msg.startswith(b"ERROR: "):
raise InternalMSEEDReadingError(msg[7:].strip())
if msg.startswith(b"INFO: "):
msg = msg[6:].strip()
# Append the offset of the full SEED header if necessary. That way
# the C code does not have to deal with it.
if offset and "offset" in msg:
msg = ("%s The file contains a %i byte dataless part at the "
"beginning. Make sure to add that to the reported "
"offset to get the actual location in the file." %
(msg, offset))
warnings.warn(msg, InternalMSEEDReadingWarning)
diag_print = C.CFUNCTYPE(C.c_void_p, C.c_char_p)(log_error_or_warning)
def log_message(msg):
print(msg[6:].strip())
log_print = C.CFUNCTYPE(C.c_void_p, C.c_char_p)(log_message)
try:
verbose = int(verbose)
except:
verbose = 0
lil = clibmseed.readMSEEDBuffer(buffer, buflen, selections,
C.c_int8(unpack_data), reclen,
C.c_int8(verbose), C.c_int8(details),
header_byteorder, allocData, diag_print,
log_print)
# XXX: Check if the freeing works.
del selections
traces = []
try:
currentID = lil.contents
# Return stream if not traces are found.
except ValueError:
clibmseed.lil_free(lil)
del lil
return Stream()
while True:
# Init header with the essential information.
header = {
'network': currentID.network.strip(),
'station': currentID.station.strip(),
'location': currentID.location.strip(),
'channel': currentID.channel.strip(),
'mseed': {
'dataquality': currentID.dataquality
}
}
# Loop over segments.
try:
currentSegment = currentID.firstSegment.contents
except ValueError:
break
while True:
header['sampling_rate'] = currentSegment.samprate
header['starttime'] = \
util._convertMSTimeToDatetime(currentSegment.starttime)
# TODO: write support is missing
if details:
timing_quality = currentSegment.timing_quality
if timing_quality == 0xFF: # 0xFF is mask for not known timing
timing_quality = -1
header['mseed']['timing_quality'] = timing_quality
header['mseed']['calibration_type'] = \
currentSegment.calibration_type
if headonly is False:
# The data always will be in sequential order.
data = all_data.pop(0)
header['npts'] = len(data)
else:
data = np.array([])
header['npts'] = currentSegment.samplecnt
# Make sure to init the number of samples.
# Py3k: convert to unicode
header['mseed'] = dict(
(k, v.decode()) if isinstance(v, bytes) else (k, v)
for k, v in header['mseed'].items())
header = dict((k, v.decode()) if isinstance(v, bytes) else (k, v)
for k, v in header.items())
trace = Trace(header=header, data=data)
# Append information.
for key, value in info.items():
setattr(trace.stats.mseed, key, value)
traces.append(trace)
# A Null pointer access results in a ValueError
try:
currentSegment = currentSegment.next.contents
except ValueError:
break
try:
currentID = currentID.next.contents
except ValueError:
break
clibmseed.lil_free(lil) # NOQA
del lil # NOQA
return Stream(traces=traces)
def readMSEED(mseed_object, starttime=None, endtime=None, headonly=False,
sourcename=None, reclen=None, details=False,
header_byteorder=None, verbose=None, **kwargs):
"""
Reads a Mini-SEED file and returns a Stream object.
.. warning::
This function should NOT be called directly, it registers via the
ObsPy :func:`~obspy.core.stream.read` function, call this instead.
:param mseed_object: Filename or open file like object that contains the
binary Mini-SEED data. Any object that provides a read() method will be
considered to be a file like object.
:type starttime: :class:`~obspy.core.utcdatetime.UTCDateTime`
:param starttime: Only read data samples after or at the start time.
:type endtime: :class:`~obspy.core.utcdatetime.UTCDateTime`
:param endtime: Only read data samples before or at the end time.
:param headonly: Determines whether or not to unpack the data or just
read the headers.
:type sourcename: str
:param sourcename: Source name has to have the structure
'network.station.location.channel' and can contain globbing characters.
Defaults to ``None``.
:param reclen: If it is None, it will be automatically determined for every
record. If it is known, just set it to the record length in bytes which
will increase the reading speed slightly.
:type details: bool, optional
:param details: If ``True`` read additional information: timing quality
and availability of calibration information.
Note, that the traces are then also split on these additional
information. Thus the number of traces in a stream will change.
Details are stored in the mseed stats AttribDict of each trace.
``False`` specifies for both cases, that this information is not
available. ``blkt1001.timing_quality`` specifies the timing quality
from 0 to 100 [%]. ``calibration_type`` specifies the type of available
calibration information blockettes:
- ``1``: Step Calibration (Blockette 300)
- ``2``: Sine Calibration (Blockette 310)
- ``3``: Pseudo-random Calibration (Blockette 320)
- ``4``: Generic Calibration (Blockette 390)
- ``-2``: Calibration Abort (Blockette 395)
:type header_byteorder: int or str, optional
:param header_byteorder: Must be either ``0`` or ``'<'`` for LSBF or
little-endian, ``1`` or ``'>'`` for MBF or big-endian. ``'='`` is the
native byte order. Used to enforce the header byte order. Useful in
some rare cases where the automatic byte order detection fails.
.. rubric:: Example
>>> from obspy import read
>>> st = read("/path/to/two_channels.mseed")
>>> print(st) # doctest: +ELLIPSIS
2 Trace(s) in Stream:
BW.UH3..EHE | 2010-06-20T00:00:00.279999Z - ... | 200.0 Hz, 386 samples
BW.UH3..EHZ | 2010-06-20T00:00:00.279999Z - ... | 200.0 Hz, 386 samples
>>> from obspy import UTCDateTime
>>> st = read("/path/to/test.mseed",
... starttime=UTCDateTime("2003-05-29T02:16:00"),
... selection="NL.*.*.?HZ")
>>> print(st) # doctest: +ELLIPSIS
1 Trace(s) in Stream:
NL.HGN.00.BHZ | 2003-05-29T02:15:59.993400Z - ... | 40.0 Hz, 5629 samples
Read with ``details=True`` to read more details of the file if present.
>>> st = read("/path/to/timingquality.mseed", details=True)
>>> print(st[0].stats.mseed.blkt1001.timing_quality)
55
``False`` means that the necessary information could not be found in the
file.
>>> print(st[0].stats.mseed.calibration_type)
False
Note that each change in timing quality from record to record may trigger a
new Trace object to be created so the Stream object may contain many Trace
objects if ``details=True`` is used.
>>> print(len(st))
101
"""
# Parse the headonly and reclen flags.
if headonly is True:
unpack_data = 0
else:
unpack_data = 1
if reclen is None:
reclen = -1
elif reclen not in VALID_RECORD_LENGTHS:
msg = 'Invalid record length. Autodetection will be used.'
warnings.warn(msg)
reclen = -1
# Determine the byte order.
if header_byteorder == "=":
header_byteorder = NATIVE_BYTEORDER
if header_byteorder is None:
header_byteorder = -1
elif header_byteorder in [0, "0", "<"]:
header_byteorder = 0
elif header_byteorder in [1, "1", ">"]:
header_byteorder = 1
# The quality flag is no more supported. Raise a warning.
if 'quality' in kwargs:
msg = 'The quality flag is no longer supported in this version of ' + \
'obspy.mseed. obspy.mseed.util has some functions with similar' + \
' behavior.'
warnings.warn(msg, category=DeprecationWarning)
# Parse some information about the file.
if header_byteorder == 0:
bo = "<"
elif header_byteorder > 0:
bo = ">"
else:
bo = None
info = util.getRecordInformation(mseed_object, endian=bo)
# Map the encoding to a readable string value.
if info["encoding"] in ENCODINGS:
info['encoding'] = ENCODINGS[info['encoding']][0]
elif info["encoding"] in UNSUPPORTED_ENCODINGS:
msg = ("Encoding '%s' (%i) is not supported by ObsPy. Please send "
"the file to the ObsPy developers so that we can add "
"support for it.") % \
(UNSUPPORTED_ENCODINGS[info['encoding']], info['encoding'])
raise ValueError(msg)
else:
msg = "Encoding '%i' is not a valid MiniSEED encoding." % \
info['encoding']
raise ValueError(msg)
# Only keep information relevant for the whole file.
info = {'encoding': info['encoding'],
'filesize': info['filesize'],
'record_length': info['record_length'],
'byteorder': info['byteorder'],
'number_of_records': info['number_of_records']}
# If it's a file name just read it.
if isinstance(mseed_object, (str, native_str)):
# Read to NumPy array which is used as a buffer.
bfrNp = np.fromfile(mseed_object, dtype=np.int8)
elif hasattr(mseed_object, 'read'):
bfrNp = np.fromstring(mseed_object.read(), dtype=np.int8)
# Get the record length
try:
record_length = pow(2, int(''.join([chr(_i) for _i in bfrNp[19:21]])))
except ValueError:
record_length = 4096
# Search for data records and pass only the data part to the underlying C
# routine.
offset = 0
# 0 to 9 are defined in a row in the ASCII charset.
min_ascii = ord('0')
# Small function to check whether an array of ASCII values contains only
# digits.
isdigit = lambda x: True if (x - min_ascii).max() <= 9 else False
while True:
# This should never happen
if (isdigit(bfrNp[offset:offset + 6]) is False) or \
(bfrNp[offset + 6] not in VALID_CONTROL_HEADERS):
msg = 'Not a valid (Mini-)SEED file'
raise Exception(msg)
elif bfrNp[offset + 6] in SEED_CONTROL_HEADERS:
offset += record_length
continue
break
bfrNp = bfrNp[offset:]
buflen = len(bfrNp)
# If no selection is given pass None to the C function.
if starttime is None and endtime is None and sourcename is None:
selections = None
else:
select_time = SelectTime()
selections = Selections()
selections.timewindows.contents = select_time
if starttime is not None:
if not isinstance(starttime, UTCDateTime):
msg = 'starttime needs to be a UTCDateTime object'
raise ValueError(msg)
selections.timewindows.contents.starttime = \
util._convertDatetimeToMSTime(starttime)
else:
# HPTERROR results in no starttime.
selections.timewindows.contents.starttime = HPTERROR
if endtime is not None:
if not isinstance(endtime, UTCDateTime):
msg = 'endtime needs to be a UTCDateTime object'
raise ValueError(msg)
selections.timewindows.contents.endtime = \
util._convertDatetimeToMSTime(endtime)
else:
# HPTERROR results in no starttime.
selections.timewindows.contents.endtime = HPTERROR
if sourcename is not None:
if not isinstance(sourcename, (str, native_str)):
msg = 'sourcename needs to be a string'
raise ValueError(msg)
# libmseed uses underscores as separators and allows filtering
# after the dataquality which is disabled here to not confuse
# users. (* == all data qualities)
selections.srcname = (sourcename.replace('.', '_') + '_*').\
encode('ascii', 'ignore')
else:
selections.srcname = b'*'
all_data = []
# Use a callback function to allocate the memory and keep track of the
# data.
def allocate_data(samplecount, sampletype):
# Enhanced sanity checking for libmseed 2.10 can result in the
# sampletype not being set. Just return an empty array in this case.
if sampletype == b"\x00":
data = np.empty(0)
else:
data = np.empty(samplecount, dtype=DATATYPES[sampletype])
all_data.append(data)
return data.ctypes.data
# XXX: Do this properly!
# Define Python callback function for use in C function. Return a long so
# it hopefully works on 32 and 64 bit systems.
allocData = C.CFUNCTYPE(C.c_long, C.c_int, C.c_char)(allocate_data)
def log_error_or_warning(msg):
if msg.startswith(b"ERROR: "):
raise InternalMSEEDReadingError(msg[7:].strip())
if msg.startswith(b"INFO: "):
msg = msg[6:].strip()
# Append the offset of the full SEED header if necessary. That way
# the C code does not have to deal with it.
if offset and "offset" in msg:
msg = ("%s The file contains a %i byte dataless part at the "
"beginning. Make sure to add that to the reported "
"offset to get the actual location in the file." % (
msg, offset))
warnings.warn(msg, InternalMSEEDReadingWarning)
diag_print = C.CFUNCTYPE(C.c_void_p, C.c_char_p)(log_error_or_warning)
def log_message(msg):
print(msg[6:].strip())
log_print = C.CFUNCTYPE(C.c_void_p, C.c_char_p)(log_message)
try:
verbose = int(verbose)
except:
verbose = 0
lil = clibmseed.readMSEEDBuffer(
bfrNp, buflen, selections, C.c_int8(unpack_data),
reclen, C.c_int8(verbose), C.c_int8(details), header_byteorder,
allocData, diag_print, log_print)
# XXX: Check if the freeing works.
del selections
traces = []
try:
currentID = lil.contents
# Return stream if not traces are found.
except ValueError:
clibmseed.lil_free(lil)
del lil
return Stream()
while True:
# Init header with the essential information.
header = {'network': currentID.network.strip(),
'station': currentID.station.strip(),
'location': currentID.location.strip(),
'channel': currentID.channel.strip(),
'mseed': {'dataquality': currentID.dataquality}}
# Loop over segments.
try:
currentSegment = currentID.firstSegment.contents
except ValueError:
break
while True:
header['sampling_rate'] = currentSegment.samprate
header['starttime'] = \
util._convertMSTimeToDatetime(currentSegment.starttime)
if details:
timing_quality = currentSegment.timing_quality
if timing_quality == 0xFF: # 0xFF is mask for not known timing
timing_quality = False
header['mseed']['blkt1001'] = {}
header['mseed']['blkt1001']['timing_quality'] = timing_quality
header['mseed']['calibration_type'] = \
currentSegment.calibration_type \
if currentSegment.calibration_type != -1 else False
if headonly is False:
# The data always will be in sequential order.
data = all_data.pop(0)
header['npts'] = len(data)
else:
data = np.array([])
header['npts'] = currentSegment.samplecnt
# Make sure to init the number of samples.
# Py3k: convert to unicode
header['mseed'] = dict((k, v.decode())
if isinstance(v, bytes) else (k, v)
for k, v in header['mseed'].items())
header = dict((k, v.decode()) if isinstance(v, bytes) else (k, v)
for k, v in header.items())
trace = Trace(header=header, data=data)
# Append information.
for key, value in info.items():
setattr(trace.stats.mseed, key, value)
traces.append(trace)
# A Null pointer access results in a ValueError
try:
currentSegment = currentSegment.next.contents
except ValueError:
break
try:
currentID = currentID.next.contents
except ValueError:
break
clibmseed.lil_free(lil) # NOQA
del lil # NOQA
return Stream(traces=traces)
