Exemple #1
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    def test_frametype(self):
        """
        Test for valid frame type.
        """

        frametype = 1.0
        with pytest.raises(TypeError):
            Heterodyne(frametype=frametype)

        het = Heterodyne()
        assert het.frametype is None

        frametype = "H1_R"
        het.frametype = frametype
        assert het.frametype == frametype
Exemple #2
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    def test_framecache(self):
        """
        Test frame cache file setting.
        """

        with pytest.raises(TypeError):
            Heterodyne(framecache=1.2)

        with pytest.raises(ValueError):
            Heterodyne(framecache="lsgdfklg")

        with pytest.raises(TypeError):
            Heterodyne(framecache=[1, 2])

        het = Heterodyne(framecache=self.dummy_cache_files[0])
        assert het.framecache == self.dummy_cache_files[0]

        het.framecache = self.dummy_cache_files
        assert len(het.framecache) == len(self.dummy_cache_files)
        for i, df in enumerate(self.dummy_cache_files):
            assert df == het.framecache[i]
Exemple #3
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    def test_host(self):
        """
        Test host name.
        """

        with pytest.raises(TypeError):
            Heterodyne(host=1.2)

        with pytest.raises(RuntimeError):
            Heterodyne(host="+0--23oiyds")

        het = Heterodyne()

        assert het.host is None

        host = "https://www.google.com"
        het.host = host

        assert het.host == host

        host = "www.google.com"
        het.host = host
        assert het.host == host
Exemple #4
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    def test_heterodyne(self):
        """
        Test heterodyning on fake data.
        """

        segments = [(time, time + self.fakedataduration)
                    for time in self.fakedatastarts]

        het = Heterodyne(
            pulsarfiles=self.fakeparfile,
            pulsars=["J0000+0000"],
            segmentlist=segments,
            framecache=self.fakedatadir,
            channel=self.fakedatachannels[0],
        )

        with pytest.raises(TypeError):
            het.stride = "ksgdk"

        with pytest.raises(TypeError):
            het.stride = 4.5

        with pytest.raises(ValueError):
            het.stride = -1

        with pytest.raises(TypeError):
            het.filterknee = "lshdl"

        with pytest.raises(ValueError):
            het.filterknee = 0

        with pytest.raises(TypeError):
            het.freqfactor = "ldkme"

        with pytest.raises(ValueError):
            het.freqfactor = -2.3

        with pytest.raises(ValueError):
            # test that not setting an output gives a error
            het.heterodyne()

        # test setting an output directory
        outdir = os.path.join(self.fakedatadir, "heterodyne_output")
        het.outputfiles = outdir

        assert len(het.outputfiles) == 1
        assert list(het.outputfiles.keys()) == ["J0000+0000"]
        assert list(
            het.outputfiles.values()) == [os.path.join(outdir, het.label)]

        with pytest.raises(ValueError):
            # attempt to include glitch evolution without setting includessb to True
            het.heterodyne(includeglitch=True)

        # perform first stage heterodyne
        het = Heterodyne(
            starttime=segments[0][0],
            endtime=segments[-1][-1],
            pulsarfiles=self.fakeparfile,
            segmentlist=segments,
            framecache=self.fakedatadir,
            channel=self.fakedatachannels[0],
            freqfactor=2,
            stride=self.fakedataduration // 2,
            output=outdir,
            resamplerate=1,
        )

        het.heterodyne()

        labeldict = {
            "det": het.detector,
            "gpsstart": int(het.starttime),
            "gpsend": int(het.endtime),
            "freqfactor": int(het.freqfactor),
        }

        # expected length (after cropping)
        length = (het.resamplerate * np.diff(segments).sum() -
                  2 * len(segments) * het.crop)

        # expected start time (after cropping)
        t0 = segments[0][0] + het.crop + 0.5 / het.resamplerate

        # expected end time (after croppping)
        tend = segments[-1][-1] - het.crop - 0.5 / het.resamplerate

        # check output
        for psr in ["J0000+0000", "J1111+1111", "J2222+2222"]:
            assert os.path.isfile(het.outputfiles[psr].format(**labeldict,
                                                              psr=psr))

            hetdata = HeterodynedData.read(
                het.outputfiles[psr].format(**labeldict, psr=psr))

            assert len(hetdata) == length
            assert het.resamplerate == hetdata.dt.value
            assert t0 == hetdata.times.value[0]
            assert tend == hetdata.times.value[-1]
            assert het.detector == hetdata.detector

        # perform second stage of heterodyne
        with pytest.raises(TypeError):
            Heterodyne(heterodyneddata=0)

        fineoutdir = os.path.join(self.fakedatadir, "fine_heterodyne_output")

        # first heterodyne without SSB
        het2 = Heterodyne(
            detector=self.fakedatadetectors[0],
            heterodyneddata=outdir,  # pass previous output directory
            pulsarfiles=self.fakeparfile,
            freqfactor=2,
            resamplerate=1 / 60,
            includessb=False,
            output=fineoutdir,
            label="heterodyne_{psr}_{det}_{freqfactor}.hdf5",
        )
        het2.heterodyne()

        models = []
        for i, psr in enumerate(["J0000+0000", "J1111+1111", "J2222+2222"]):
            # load data
            hetdata = HeterodynedData.read(
                het2.outputfiles[psr].format(**labeldict, psr=psr))

            assert het2.resamplerate == 1 / hetdata.dt.value
            assert len(hetdata) == int(length * het2.resamplerate)

            # set expected model
            sim = HeterodynedCWSimulator(
                hetdata.par,
                hetdata.detector,
                times=hetdata.times.value,
                earth_ephem=hetdata.ephemearth,
                sun_ephem=hetdata.ephemsun,
            )

            # due to how the HeterodynedCWSimulator works we need to set
            # updateglphase = True for the glitching signal to generate a
            # signal without the glitch phase included!
            models.append(
                sim.model(
                    usephase=True,
                    freqfactor=hetdata.freq_factor,
                    updateglphase=(True if psr == "J2222+2222" else False),
                ))

            # without inclusion of SSB model should not match
            assert np.any(
                np.abs(hetdata.data - models[i]) / np.abs(models[i]) > 5e-3)

        # now heterodyne with SSB
        del het2
        het2 = Heterodyne(
            detector=self.fakedatadetectors[0],
            heterodyneddata=outdir,  # pass previous output directory
            pulsarfiles=self.fakeparfile,
            freqfactor=2,
            resamplerate=1 / 60,
            includessb=True,
            output=fineoutdir,
            label="heterodyne_{psr}_{det}_{freqfactor}.hdf5",
        )
        het2.heterodyne()

        for i, psr in enumerate(["J0000+0000", "J1111+1111", "J2222+2222"]):
            # load data
            hetdata = HeterodynedData.read(
                het2.outputfiles[psr].format(**labeldict, psr=psr))

            assert het2.resamplerate == 1 / hetdata.dt.value
            assert len(hetdata) == int(length * het2.resamplerate)

            if psr == "J0000+0000":  # isolated pulsar
                assert np.all(
                    np.abs(hetdata.data - models[i]) /
                    np.abs(models[i]) < 5e-3)
            else:
                # without inclusion of BSB/glitch phase model should not match
                assert np.any(
                    np.abs(hetdata.data - models[i]) /
                    np.abs(models[i]) > 5e-3)

        # now heterodyne with SSB and BSB
        del het2
        het2 = Heterodyne(
            detector=self.fakedatadetectors[0],
            heterodyneddata={
                psr: het.outputfiles[psr].format(**labeldict, psr=psr)
                for psr in ["J0000+0000", "J1111+1111", "J2222+2222"]
            },  # test using dictionary
            pulsarfiles=self.fakeparfile,
            freqfactor=2,
            resamplerate=1 / 60,
            includessb=True,
            includebsb=True,
            output=fineoutdir,
            label="heterodyne_{psr}_{det}_{freqfactor}.hdf5",
        )
        het2.heterodyne()

        for i, psr in enumerate(["J0000+0000", "J1111+1111", "J2222+2222"]):
            # load data
            hetdata = HeterodynedData.read(
                het2.outputfiles[psr].format(**labeldict, psr=psr))

            assert het2.resamplerate == 1 / hetdata.dt.value
            assert len(hetdata) == int(length * het2.resamplerate)

            if psr in [
                    "J0000+0000",
                    "J1111+1111",
            ]:  # isolated and binary pulsar (non-glitching)
                assert np.all(
                    np.abs(hetdata.data - models[i]) /
                    np.abs(models[i]) < 1e-2)
            else:
                # without inclusion glitch phase model should not match
                assert np.any(
                    np.abs(hetdata.data - models[i]) /
                    np.abs(models[i]) > 1e-2)

        # now heterodyne with SSB, BSB and glitch phase
        del het2
        het2 = Heterodyne(
            detector=self.fakedatadetectors[0],
            heterodyneddata={
                psr: het.outputfiles[psr].format(**labeldict, psr=psr)
                for psr in ["J0000+0000", "J1111+1111", "J2222+2222"]
            },  # test using dictionary
            pulsarfiles=self.fakeparfile,
            freqfactor=2,
            resamplerate=1 / 60,
            includessb=True,
            includebsb=True,
            includeglitch=True,
            output=fineoutdir,
            label="heterodyne_{psr}_{det}_{freqfactor}.hdf5",
        )
        het2.heterodyne()

        for i, psr in enumerate(["J0000+0000", "J1111+1111", "J2222+2222"]):
            # load data
            hetdata = HeterodynedData.read(
                het2.outputfiles[psr].format(**labeldict, psr=psr))

            assert het2.resamplerate == 1 / hetdata.dt.value
            assert len(hetdata) == int(length * het2.resamplerate)

            # increase tolerance for acceptance due to small outliers (still
            # equivalent at the ~2% level)
            assert np.all(
                np.abs(hetdata.data - models[i]) / np.abs(models[i]) < 2e-2)
Exemple #5
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    def test_set_pulsars(self, capsys):
        """
        Test setting of pulsar parameter files.
        """

        with pytest.raises(TypeError):
            Heterodyne(pulsarfiles=1.2)

        het = Heterodyne(pulsarfiles=self.fakepardir)

        assert sorted(list(het.pulsarfiles.keys())) == [
            "J0000+0000",
            "J1111+1111",
            "J2222+2222",
        ]
        assert sorted(list(het.pulsarfiles.values())) == sorted([
            os.path.realpath(self.fakeparfile[0]),
            os.path.realpath(self.fakeparfile[1]),
            os.path.realpath(self.fakeparfile[2]),
        ])
        assert sorted(
            het.pulsars) == ["J0000+0000", "J1111+1111", "J2222+2222"]

        het = Heterodyne(pulsarfiles=self.fakeparfile[0])
        assert het.pulsarfiles == {"J0000+0000": self.fakeparfile[0]}
        assert het.pulsars == ["J0000+0000"]

        het = Heterodyne(pulsarfiles=self.fakeparfile[1])
        assert het.pulsarfiles == {"J1111+1111": self.fakeparfile[1]}
        assert het.pulsars == ["J1111+1111"]

        het = Heterodyne(pulsarfiles=self.fakeparfile[2])
        assert het.pulsarfiles == {"J2222+2222": self.fakeparfile[2]}
        assert het.pulsars == ["J2222+2222"]

        het = Heterodyne(pulsarfiles=[self.fakeparfile[0]])

        assert het.pulsarfiles == {"J0000+0000": self.fakeparfile[0]}
        assert het.pulsars == ["J0000+0000"]

        het = Heterodyne(pulsarfiles=self.fakeparfile)

        assert sorted(list(het.pulsarfiles.keys())) == [
            "J0000+0000",
            "J1111+1111",
            "J2222+2222",
        ]
        assert list(het.pulsarfiles.values()) == [
            self.fakeparfile[0],
            self.fakeparfile[1],
            self.fakeparfile[2],
        ]
        assert sorted(
            het.pulsars) == ["J0000+0000", "J1111+1111", "J2222+2222"]

        with pytest.raises(TypeError):
            Heterodyne(pulsarfiles=self.fakeparfile, pulsars=3.4)

        het = Heterodyne(pulsarfiles=self.fakeparfile, pulsars="J0328+5323")
        captured = capsys.readouterr()

        assert len(het.pulsars) == 0
        assert (
            captured.out ==
            "Pulsars '['J0328+5323']' not included as no parameter files have been given for them\n"
        )

        het = Heterodyne(pulsarfiles=[self.fakeparfile[0]],
                         pulsars=["J0000+0000"])

        assert het.pulsarfiles == {"J0000+0000": self.fakeparfile[0]}
        assert het.pulsars == ["J0000+0000"]

        with pytest.raises(TypeError):
            het.pulsars = 453

        pulsarfiles = {}
        pulsarfiles["J0000+0000"] = "kgsdkgf"
        het = Heterodyne(pulsarfiles=pulsarfiles)
        captured = capsys.readouterr()
        assert len(het.pulsarfiles) == 0
        assert (
            captured.out ==
            "Pulsar file 'kgsdkgf' could not be read. This pulsar will be ignored.\n"
        )

        pulsarfiles = {}
        pulsarfiles["J0000+0001"] = os.path.realpath(self.fakeparfile[0])
        het = Heterodyne(pulsarfiles=pulsarfiles)
        captured = capsys.readouterr()
        assert len(het.pulsarfiles) == 1
        assert (
            captured.out ==
            "Inconsistent naming in pulsarfile dictionary. Using pulsar name 'J0000+0000' from parameter file\n"
        )

        pulsarfiles = {}
        pulsarfiles["J0000+0000"] = os.path.realpath(self.fakeparfile[0])
        het = Heterodyne(pulsarfiles=pulsarfiles)
        assert het.pulsarfiles == {
            "J0000+0000": os.path.realpath(self.fakeparfile[0])
        }
        assert het.pulsars == ["J0000+0000"]
Exemple #6
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    def test_get_segments(self):
        """
        Test reading segment list file.
        """

        het = Heterodyne()

        segments = het.get_segment_list(segmentfile=self.dummysegmentfile)

        assert len(segments) == len(self.dummysegments)
        for sega, segb in zip(segments, self.dummysegments):
            for sa, sb in zip(sega, segb):
                assert sa == sb

        het = Heterodyne(segmentlist=self.dummysegments)

        assert len(segments) == len(self.dummysegments)
        for sega, segb in zip(segments, self.dummysegments):
            for sa, sb in zip(sega, segb):
                assert sa == sb

        with pytest.raises(IOError):
            # no existent segment file
            Heterodyne(segmentlist="klsghdfkdgskd")

        with pytest.raises(TypeError):
            Heterodyne(outputsegmentlist=1)

        with pytest.raises(TypeError):
            Heterodyne(appendsegmentlist=1.1)

        with pytest.raises(TypeError):
            Heterodyne(includeflags=1)

        with pytest.raises(TypeError):
            Heterodyne(excludeflags=1)

        with pytest.raises(TypeError):
            Heterodyne(segmentserver=1)

        het = Heterodyne(starttime=900000000,
                         endtime=910000000,
                         segmentlist=self.dummysegmentfile)

        assert len(het.segments) == 0

        het = Heterodyne(starttime=1000000850,
                         endtime=1000001000,
                         segmentlist=self.dummysegmentfile)

        assert len(het.segments) == 1
        assert het.segments[0][0] == 1000000850
        assert het.segments[0][1] == 1000000900

        het = Heterodyne(starttime=1000000100,
                         endtime=1000000700,
                         segmentlist=self.dummysegmentfile)

        assert len(het.segments) == 1
        assert het.segments[0][0] == 1000000100
        assert het.segments[0][1] == 1000000600
Exemple #7
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    def test_get_frame_data(self):
        """
        Test reading of local frame data.
        """

        het = Heterodyne()

        with pytest.raises(ValueError):
            # no start or end time set
            het.get_frame_data()

        with pytest.raises(ValueError):
            # no start time set
            het.get_frame_data(endtime=1000000000)

        with pytest.raises(ValueError):
            # no channel set
            het.get_frame_data(starttime=1000000000, endtime=1000084600)

        with pytest.raises(IOError):
            # invalid file name
            het.get_frame_data(
                starttime=1000000000,
                endtime=1000084600,
                channel=self.fakedatachannels[0],
                framecache="jhsdklgdks.txt",
            )

        with pytest.raises(IOError):
            # cache file contains invalid frames
            het.get_frame_data(
                starttime=1000000000,
                endtime=1000000000 + 3 * 86400,
                framecache=self.dummy_cache_files[0],
                site="H1",
                channel=self.fakedatachannels[0],
            )

        # test reading files/generating a local cache list (all files)
        cachefile = os.path.join(self.fakedatadir, "frcache.txt")
        data = het.get_frame_data(
            starttime=1000000000,
            endtime=1000000000 + 86400,
            framecache=self.fakedatadir,
            site="H1",
            outputframecache=cachefile,
            channel=self.fakedatachannels[0],
        )

        assert int(data.t0.value) == self.fakedatastarts[0]
        assert data.dt.value == 1 / (2 * (self.fakedatabandwidth))

        with open(cachefile, "r") as fp:
            cachedata = [fl.strip() for fl in fp.readlines()]

        assert len(cachedata) == 1
        for i in range(len(cachedata)):
            assert ("{}-{}_{}-{}-{}.gwf".format(
                self.fakedatadetectors[0][0],
                self.fakedatadetectors[0],
                self.fakedataname,
                self.fakedatastarts[i],
                self.fakedataduration,
            ) == os.path.basename(cachedata[i]))

        # test reading files from cache file
        data = het.get_frame_data(
            starttime=1000000000,
            endtime=1000000000 + 86400,
            framecache=cachefile,
            site="H1",
            channel=self.fakedatachannels[0],
        )

        assert int(data.t0.value) == self.fakedatastarts[0]
        assert data.dt.value == 1 / (2 * (self.fakedatabandwidth))

        with pytest.raises(IOError):
            # try reading data outside of range
            het.get_frame_data(
                starttime=900000000,
                endtime=900000000 + 2 * 86400,
                framecache=cachefile,
                site="H1",
                channel=self.fakedatachannels[0],
            )

        with pytest.raises(IOError):
            # try reading data from the wrong channel
            het.get_frame_data(
                starttime=1000000000,
                endtime=1000000000 + 86400,
                framecache=cachefile,
                site="H1",
                channel=self.fakedatachannels[1],
            )

        del het
        del data

        # test reading from GWOSC
        het = Heterodyne()
        data = het.get_frame_data(starttime=1126259460,
                                  endtime=1126259464,
                                  host=GWOSC_DEFAULT_HOST,
                                  site="H1")

        assert int(data.t0.value) == 1126259460
        assert data.dt.value == 1 / 4096
        assert len(data) == 16384
Exemple #8
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    def test_start_end(self):
        """
        Test for valid start and end times.
        """

        starttime = "blah"
        endtime = "blah"

        with pytest.raises(TypeError):
            Heterodyne(starttime, endtime)

        starttime = 100000000.0
        with pytest.raises(TypeError):
            Heterodyne(starttime, endtime)

        endtime = 100
        with pytest.raises(ValueError):
            Heterodyne(starttime, endtime)

        endtime = starttime + 86400
        het = Heterodyne(starttime, endtime)

        assert type(het.starttime) is int
        assert type(het.endtime) is int
        assert int(starttime) == het.starttime
        assert int(endtime) == het.endtime

        het = Heterodyne()
        assert het.starttime is None
        assert het.endtime is None

        # try setter
        het.starttime = 1000000001.1
        assert het.starttime == int(1000000001.1)

        # try setter
        het.endtime = 1000000002.1
        assert het.endtime == int(1000000002.1)

        # test the stride (default value)
        assert het.stride == 3600

        with pytest.raises(TypeError):
            het.stride = "kgsdg"

        with pytest.raises(TypeError):
            het.stride = 1.5

        with pytest.raises(ValueError):
            het.stride = 0

        stride = 1
        het.stride = stride
        assert het.stride == stride
Exemple #9
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    def test_full_heterodyne(self):
        """
        Test heterodyning on fake data, performing the heterodyne in one step.
        """

        segments = [(time, time + self.fakedataduration)
                    for time in self.fakedatastarts]

        # perform heterodyne in one step
        fulloutdir = os.path.join(self.fakedatadir, "full_heterodyne_output")

        het = Heterodyne(
            starttime=segments[0][0],
            endtime=segments[-1][-1],
            pulsarfiles=self.fakeparfile,
            segmentlist=segments,
            framecache=self.fakedatadir,
            channel=self.fakedatachannels[0],
            freqfactor=2,
            stride=self.fakedataduration // 2,
            resamplerate=1 / 60,
            includessb=True,
            includebsb=True,
            includeglitch=True,
            output=fulloutdir,
            label="heterodyne_{psr}_{det}_{freqfactor}.hdf5",
        )

        het.heterodyne()

        labeldict = {
            "det": het.detector,
            "gpsstart": int(het.starttime),
            "gpsend": int(het.endtime),
            "freqfactor": int(het.freqfactor),
        }

        # compare against model
        for i, psr in enumerate(["J0000+0000", "J1111+1111", "J2222+2222"]):
            # load data
            hetdata = HeterodynedData.read(
                het.outputfiles[psr].format(**labeldict, psr=psr))

            assert het.resamplerate == 1 / hetdata.dt.value

            # set expected model
            sim = HeterodynedCWSimulator(
                hetdata.par,
                hetdata.detector,
                times=hetdata.times.value,
                earth_ephem=hetdata.ephemearth,
                sun_ephem=hetdata.ephemsun,
            )

            # due to how the HeterodynedCWSimulator works we need to set
            # updateglphase = True for the glitching signal to generate a
            # signal without the glitch phase included!
            model = sim.model(
                usephase=True,
                freqfactor=hetdata.freq_factor,
                updateglphase=(True if psr == "J2222+2222" else False),
            )

            # increase tolerance for acceptance due to small outliers (still
            # equivalent at the ~2% level)
            assert np.all(np.abs(hetdata.data - model) / np.abs(model) < 2e-2)