コード例 #1
0
def snr_series_to_xml(snr_series, document, sngl_inspiral_id):
    """Save an SNR time series into an XML document, in a format compatible
    with BAYESTAR.
    """
    snr_lal = snr_series.lal()
    snr_lal.name = 'snr'
    snr_lal.sampleUnits = ''
    snr_xml = _build_series(snr_lal, ('Time', 'Time,Real,Imaginary'), None,
                            'deltaT', 's')
    snr_node = document.childNodes[-1].appendChild(snr_xml)
    eid_param = LIGOLWParam.from_pyvalue('event_id', sngl_inspiral_id)
    snr_node.appendChild(eid_param)
コード例 #2
0
ファイル: live.py プロジェクト: rpfisher/pycbc
def make_psd_xmldoc(psddict, xmldoc=None):
    """Add a set of PSDs to a LIGOLW XML document. If the document is not
    given, a new one is created first.
    """
    xmldoc = ligolw.Document() if xmldoc is None else xmldoc.childNodes[0]

    # the PSDs must be children of a LIGO_LW with name "psd"
    root_name = u"psd"
    Attributes = ligolw.sax.xmlreader.AttributesImpl
    lw = xmldoc.appendChild(ligolw.LIGO_LW(Attributes({u"Name": root_name})))

    for instrument, psd in psddict.items():
        xmlseries = _build_series(psd, (u"Frequency,Real", u"Frequency"), None,
                                  'deltaF', 's^-1')
        fs = lw.appendChild(xmlseries)
        fs.appendChild(LIGOLWParam.from_pyvalue(u'instrument', instrument))
    return xmldoc
コード例 #3
0
def _build_series(series, dim_names, comment, delta_name, delta_unit):
    Attributes = ligolw.sax.xmlreader.AttributesImpl
    elem = ligolw.LIGO_LW(
            Attributes({'Name': str(series.__class__.__name__)}))
    if comment is not None:
        elem.appendChild(ligolw.Comment()).pcdata = comment
    elem.appendChild(ligolw.Time.from_gps(series.epoch, 'epoch'))
    elem.appendChild(LIGOLWParam.from_pyvalue('f0', series.f0, unit='s^-1'))
    delta = getattr(series, delta_name)
    if numpy.iscomplexobj(series.data.data):
        data = numpy.row_stack((numpy.arange(len(series.data.data)) * delta,
                             series.data.data.real, series.data.data.imag))
    else:
        data = numpy.row_stack((numpy.arange(len(series.data.data)) * delta,
                                series.data.data))
    a = LIGOLWArray.build(series.name, data, dim_names=dim_names)
    a.Unit = str(series.sampleUnits)
    dim0 = a.getElementsByTagName(ligolw.Dim.tagName)[0]
    dim0.Unit = delta_unit
    dim0.Start = series.f0
    dim0.Scale = delta
    elem.appendChild(a)
    return elem
コード例 #4
0
def main(args=None):
    p = parser()
    opts = p.parse_args(args)

    # LIGO-LW XML imports.
    from glue.ligolw import ligolw
    from glue.ligolw.param import Param
    from glue.ligolw.utils import process as ligolw_process
    from glue.ligolw.utils.search_summary import append_search_summary
    from glue.ligolw import utils as ligolw_utils
    from glue.ligolw.lsctables import (New, CoincDefTable, CoincID,
                                       CoincInspiralTable, CoincMapTable,
                                       CoincTable, ProcessParamsTable,
                                       ProcessTable, SimInspiralTable,
                                       SnglInspiralTable, TimeSlideTable)

    # glue, LAL and pylal imports.
    from ligo import segments
    import glue.lal
    import lal.series
    import lalsimulation
    from lalinspiral.inspinjfind import InspiralSCExactCoincDef
    from lalinspiral.thinca import InspiralCoincDef
    from tqdm import tqdm

    # FIXME: disable progress bar monitor thread.
    #
    # I was getting error messages that look like this:
    #
    # Traceback (most recent call last):
    #   File "/tqdm/_tqdm.py", line 885, in __del__
    #     self.close()
    #   File "/tqdm/_tqdm.py", line 1090, in close
    #     self._decr_instances(self)
    #   File "/tqdm/_tqdm.py", line 454, in _decr_instances
    #     cls.monitor.exit()
    #   File "/tqdm/_monitor.py", line 52, in exit
    #     self.join()
    #   File "/usr/lib64/python3.6/threading.py", line 1053, in join
    #     raise RuntimeError("cannot join current thread")
    # RuntimeError: cannot join current thread
    #
    # I don't know what causes this... maybe a race condition in tqdm's cleanup
    # code. Anyway, this should disable the tqdm monitor thread entirely.
    tqdm.monitor_interval = 0

    # BAYESTAR imports.
    from ..io.events.ligolw import ContentHandler
    from ..bayestar import filter

    # Read PSDs.
    xmldoc, _ = ligolw_utils.load_fileobj(
        opts.reference_psd, contenthandler=lal.series.PSDContentHandler)
    psds = lal.series.read_psd_xmldoc(xmldoc, root_name=None)
    psds = {
        key: filter.InterpolatedPSD(filter.abscissa(psd), psd.data.data)
        for key, psd in psds.items() if psd is not None
    }
    psds = [psds[ifo] for ifo in opts.detector]

    # Extract simulation table from injection file.
    inj_xmldoc, _ = ligolw_utils.load_fileobj(opts.input,
                                              contenthandler=ContentHandler)
    orig_sim_inspiral_table = SimInspiralTable.get_table(inj_xmldoc)

    # Prune injections that are outside distance limits.
    orig_sim_inspiral_table[:] = [
        row for row in orig_sim_inspiral_table
        if opts.min_distance <= row.distance <= opts.max_distance
    ]

    # Open output file.
    xmldoc = ligolw.Document()
    xmlroot = xmldoc.appendChild(ligolw.LIGO_LW())

    # Create tables. Process and ProcessParams tables are copied from the
    # injection file.
    coinc_def_table = xmlroot.appendChild(New(CoincDefTable))
    coinc_inspiral_table = xmlroot.appendChild(New(CoincInspiralTable))
    coinc_map_table = xmlroot.appendChild(New(CoincMapTable))
    coinc_table = xmlroot.appendChild(New(CoincTable))
    xmlroot.appendChild(ProcessParamsTable.get_table(inj_xmldoc))
    xmlroot.appendChild(ProcessTable.get_table(inj_xmldoc))
    sim_inspiral_table = xmlroot.appendChild(New(SimInspiralTable))
    sngl_inspiral_table = xmlroot.appendChild(New(SnglInspiralTable))
    time_slide_table = xmlroot.appendChild(New(TimeSlideTable))

    # Write process metadata to output file.
    process = register_to_xmldoc(xmldoc,
                                 p,
                                 opts,
                                 ifos=opts.detector,
                                 comment="Simulated coincidences")

    # Add search summary to output file.
    all_time = segments.segment(
        [glue.lal.LIGOTimeGPS(0),
         glue.lal.LIGOTimeGPS(2e9)])
    append_search_summary(xmldoc, process, inseg=all_time, outseg=all_time)

    # Create a time slide entry.  Needed for coinc_event rows.
    time_slide_id = time_slide_table.get_time_slide_id(
        {ifo: 0
         for ifo in opts.detector}, create_new=process)

    # Populate CoincDef table.
    inspiral_coinc_def = copy.copy(InspiralCoincDef)
    inspiral_coinc_def.coinc_def_id = coinc_def_table.get_next_id()
    coinc_def_table.append(inspiral_coinc_def)
    found_coinc_def = copy.copy(InspiralSCExactCoincDef)
    found_coinc_def.coinc_def_id = coinc_def_table.get_next_id()
    coinc_def_table.append(found_coinc_def)

    # Precompute values that are common to all simulations.
    detectors = [
        lalsimulation.DetectorPrefixToLALDetector(ifo) for ifo in opts.detector
    ]
    responses = [det.response for det in detectors]
    locations = [det.location for det in detectors]

    if opts.jobs == 1:
        pool_map = map
    else:
        from .. import omp
        from multiprocessing import Pool
        omp.num_threads = 1  # disable OpenMP parallelism
        pool_map = Pool(opts.jobs).imap

    func = functools.partial(simulate,
                             psds=psds,
                             responses=responses,
                             locations=locations,
                             measurement_error=opts.measurement_error,
                             f_low=opts.f_low,
                             waveform=opts.waveform)

    # Make sure that each thread gets a different random number state.
    # We start by drawing a random integer s in the main thread, and
    # then the i'th subprocess will seed itself with the integer i + s.
    #
    # The seed must be an unsigned 32-bit integer, so if there are n
    # threads, then s must be drawn from the interval [0, 2**32 - n).
    #
    # Note that *we* are thread 0, so there are a total of
    # n=1+len(sim_inspiral_table) threads.
    seed = np.random.randint(0, 2**32 - len(sim_inspiral_table) - 1)
    np.random.seed(seed)

    count_coincs = 0

    with tqdm(total=len(orig_sim_inspiral_table)) as progress:
        for sim_inspiral, simulation in zip(
                orig_sim_inspiral_table,
                pool_map(
                    func,
                    zip(
                        np.arange(len(orig_sim_inspiral_table)) + seed + 1,
                        orig_sim_inspiral_table))):
            progress.update()

            sngl_inspirals = []
            used_snr_series = []
            net_snr = 0.0
            count_triggers = 0

            # Loop over individual detectors and create SnglInspiral entries.
            for ifo, (horizon, abs_snr, arg_snr, toa, series) \
                    in zip(opts.detector, simulation):

                if np.random.uniform() > opts.duty_cycle:
                    continue
                elif abs_snr >= opts.snr_threshold:
                    # If SNR < threshold, then the injection is not found.
                    # Skip it.
                    count_triggers += 1
                    net_snr += np.square(abs_snr)
                elif not opts.keep_subthreshold:
                    continue

                # Create SnglInspiral entry.
                used_snr_series.append(series)
                sngl_inspirals.append(
                    sngl_inspiral_table.RowType(**dict(
                        dict.fromkeys(sngl_inspiral_table.validcolumns, None),
                        process_id=process.process_id,
                        ifo=ifo,
                        mass1=sim_inspiral.mass1,
                        mass2=sim_inspiral.mass2,
                        spin1x=sim_inspiral.spin1x,
                        spin1y=sim_inspiral.spin1y,
                        spin1z=sim_inspiral.spin1z,
                        spin2x=sim_inspiral.spin2x,
                        spin2y=sim_inspiral.spin2y,
                        spin2z=sim_inspiral.spin2z,
                        end=toa,
                        snr=abs_snr,
                        coa_phase=arg_snr,
                        eff_distance=horizon / abs_snr)))

            net_snr = np.sqrt(net_snr)

            # If too few triggers were found, then skip this event.
            if count_triggers < opts.min_triggers:
                continue

            # If network SNR < threshold, then the injection is not found.
            # Skip it.
            if net_snr < opts.net_snr_threshold:
                continue

            # Add Coinc table entry.
            coinc = coinc_table.appendRow(
                coinc_event_id=coinc_table.get_next_id(),
                process_id=process.process_id,
                coinc_def_id=inspiral_coinc_def.coinc_def_id,
                time_slide_id=time_slide_id,
                insts=opts.detector,
                nevents=len(opts.detector),
                likelihood=None)

            # Add CoincInspiral table entry.
            coinc_inspiral_table.appendRow(
                coinc_event_id=coinc.coinc_event_id,
                instruments=[
                    sngl_inspiral.ifo for sngl_inspiral in sngl_inspirals
                ],
                end=lal.LIGOTimeGPS(1e-9 * np.mean([
                    sngl_inspiral.end.ns() for sngl_inspiral in sngl_inspirals
                    if sngl_inspiral.end is not None
                ])),
                mass=sim_inspiral.mass1 + sim_inspiral.mass2,
                mchirp=sim_inspiral.mchirp,
                combined_far=0.0,  # Not provided
                false_alarm_rate=0.0,  # Not provided
                minimum_duration=None,  # Not provided
                snr=net_snr)

            # Record all sngl_inspiral records and associate them with coincs.
            for sngl_inspiral, series in zip(sngl_inspirals, used_snr_series):
                # Give this sngl_inspiral record an id and add it to the table.
                sngl_inspiral.event_id = sngl_inspiral_table.get_next_id()
                sngl_inspiral_table.append(sngl_inspiral)

                if opts.enable_snr_series:
                    elem = lal.series.build_COMPLEX8TimeSeries(series)
                    elem.appendChild(
                        Param.from_pyvalue(u'event_id',
                                           sngl_inspiral.event_id))
                    xmlroot.appendChild(elem)

                # Add CoincMap entry.
                coinc_map_table.appendRow(
                    coinc_event_id=coinc.coinc_event_id,
                    table_name=sngl_inspiral_table.tableName,
                    event_id=sngl_inspiral.event_id)

            # Record injection
            if not opts.preserve_ids:
                sim_inspiral.simulation_id = sim_inspiral_table.get_next_id()
            sim_inspiral_table.append(sim_inspiral)

            count_coincs += 1
            progress.set_postfix(saved=count_coincs)

    # Record coincidence associating injections with events.
    for i, sim_inspiral in enumerate(sim_inspiral_table):
        coinc = coinc_table.appendRow(
            coinc_event_id=coinc_table.get_next_id(),
            process_id=process.process_id,
            coinc_def_id=found_coinc_def.coinc_def_id,
            time_slide_id=time_slide_id,
            instruments=None,
            nevents=None,
            likelihood=None)
        coinc_map_table.appendRow(coinc_event_id=coinc.coinc_event_id,
                                  table_name=sim_inspiral_table.tableName,
                                  event_id=sim_inspiral.simulation_id)
        coinc_map_table.appendRow(coinc_event_id=coinc.coinc_event_id,
                                  table_name=coinc_table.tableName,
                                  event_id=CoincID(i))

    # Record process end time.
    ligolw_process.set_process_end_time(process)

    # Write output file.
    write_fileobj(xmldoc, opts.output)