コード例 #1
0
    def subtract_signal(self, tod, cworld, rank, masksampler, mapsampler,
                        local_intervals):
        """ Subtract a signal estimate from the TOD and update the
        flags for noise estimation.
        """

        start_signal_subtract = MPI.Wtime()
        for det in tod.local_dets:
            if rank == 0:
                print('Subtracting signal for {}'.format(det), flush=True)
                tod.cache.report()
            fsample = self._rimo[det].fsample
            epsilon = self._rimo[det].epsilon
            eta = (1 - epsilon) / (1 + epsilon)
            signal = tod.local_signal(det, name=self._signal)
            flags = tod.local_flags(det, name=self._flags)
            flags &= self._detmask
            for ival in local_intervals:
                ind = slice(ival.first, ival.last + 1)
                sig = signal[ind]
                flg = flags[ind]
                quat = tod.local_pointing(det)[ind]
                if self._pol:
                    theta, phi, psi = qa.to_angles(quat)
                    iw = np.ones_like(theta)
                    qw = eta * np.cos(2 * psi)
                    uw = eta * np.sin(2 * psi)
                    iquw = np.column_stack([iw, qw, uw])
                else:
                    theta, phi = qa.to_position(quat)
                if masksampler is not None:
                    maskflg = masksampler.at(theta, phi) < 0.5
                    flg[maskflg] |= 255
                if mapsampler is not None:
                    if self._pol:
                        bg = mapsampler.atpol(theta, phi, iquw)
                    else:
                        bg = mapsampler.at(theta, phi)
                    if self._calibrate_signal_estimate:
                        good = flg == 0
                        ngood = np.sum(good)
                        if ngood > 1:
                            templates = np.vstack([np.ones(ngood), bg[good]])
                            invcov = np.dot(templates, templates.T)
                            cov = np.linalg.inv(invcov)
                            proj = np.dot(templates, sig[good])
                            coeff = np.dot(cov, proj)
                            bg = coeff[0] + coeff[1] * bg
                    sig -= bg
        cworld.barrier()
        stop_signal_subtract = MPI.Wtime()
        if rank == 0:
            print('TOD signal-subtracted in {:.2f} s'.format(
                stop_signal_subtract - start_signal_subtract),
                  flush=True)
        return fsample
コード例 #2
0
ファイル: h_n.py プロジェクト: simonsobs/sotodlib
 def _get_h_n(self, data, n, detector):
     """ Compute and store the next order of h_n
     """
     for obs in data.obs:
         tod = obs["tod"]
         focalplane = obs["focalplane"]
         # HWP angle is not yet used but will be needed soon
         try:
             hwpang = tod.local_hwp_angle()
         except:
             hwpang = None
         if n == 1:
             nsample = tod.local_samples[1]
             hweight = np.ones(nsample, dtype=np.float64)
             tod.cache.put(self.hweight_name, hweight, replace=True)
         for det in tod.local_dets:
             if det != detector:
                 continue
             cos_1_name = "{}_{}".format(self.cos_1_prefix, det)
             sin_1_name = "{}_{}".format(self.sin_1_prefix, det)
             cos_n_name = "{}_{}".format(self.cos_n_prefix, det)
             sin_n_name = "{}_{}".format(self.sin_n_prefix, det)
             if n == 1:
                 quats = tod.local_pointing(det)
                 theta, phi, psi = qa.to_angles(quats)
                 cos_n_new = np.cos(psi)
                 sin_n_new = np.sin(psi)
                 tod.cache.put(cos_1_name, cos_n_new, replace=True)
                 tod.cache.put(sin_1_name, sin_n_new, replace=True)
                 weight_name = "{}_{}".format(self.hweight_name, det)
                 tod.cache.add_alias(weight_name, self.hweight_name)
             else:
                 # Use the angle sum identities to evaluate the
                 # next cos(n * psi) and sin(n * psi)
                 cos_1 = tod.cache.reference(cos_1_name)
                 sin_1 = tod.cache.reference(sin_1_name)
                 cos_n_old = tod.cache.reference(cos_n_name).copy()
                 sin_n_old = tod.cache.reference(sin_n_name).copy()
                 cos_n_new = cos_n_old * cos_1 - sin_n_old * sin_1
                 sin_n_new = sin_n_old * cos_1 + cos_n_old * sin_1
             tod.cache.put(cos_n_name, cos_n_new, replace=True)
             tod.cache.put(sin_n_name, sin_n_new, replace=True)
     return
コード例 #3
0
ファイル: sim_det_atm.py プロジェクト: zonca/toast
    def exec(self, data):
        """
        Generate atmosphere timestreams.

        This iterates over all observations and detectors and generates
        the atmosphere timestreams.

        Args:
            data (toast.Data): The distributed data.
        """
        autotimer = timing.auto_timer(type(self).__name__)
        group = data.comm.group
        for obs in data.obs:
            try:
                obsname = obs['name']
            except Exception:
                obsname = 'observation'
            prefix = '{} : {} : '.format(group, obsname)
            tod = self._get_from_obs('tod', obs)
            comm = tod.mpicomm
            obsindx = self._get_from_obs('id', obs)
            telescope = self._get_from_obs('telescope_id', obs)
            site = self._get_from_obs('site_id', obs)
            altitude = self._get_from_obs('altitude', obs)
            weather = self._get_from_obs('weather', obs)
            fp_radius = np.radians(self._get_from_obs('fpradius', obs))

            # Get the observation time span and initialize the weather
            # object if one is provided.
            times = tod.local_times()
            tmin = times[0]
            tmax = times[-1]
            tmin_tot = comm.allreduce(tmin, op=MPI.MIN)
            tmax_tot = comm.allreduce(tmax, op=MPI.MAX)
            weather.set(site, self._realization, tmin_tot)
            """
            The random number generator accepts a key and a counter,
            each made of two 64bit integers.
            Following tod_math.py we set
            key1 = realization * 2^32 + telescope * 2^16 + component
            key2 = obsindx * 2^32
            counter1 = currently unused (0)
            counter2 = sample in stream (incremented internally in the atm code)
            """
            key1 = self._realization * 2 ** 32 + telescope * 2 ** 16 \
                + self._component
            key2 = site * 2**16 + obsindx
            counter1 = 0
            counter2 = 0

            if self._freq is not None:
                absorption = atm_get_absorption_coefficient(
                    altitude, weather.air_temperature,
                    weather.surface_pressure, weather.pwv, self._freq)
                loading = atm_get_atmospheric_loading(altitude,
                                                      weather.air_temperature,
                                                      weather.surface_pressure,
                                                      weather.pwv, self._freq)
                tod.meta['loading'] = loading
            else:
                absorption = None

            if self._cachedir is None:
                cachedir = None
            else:
                # The number of atmospheric realizations can be large.  Use
                # sub-directories under cachedir.
                subdir = str(int((obsindx % 1000) // 100))
                subsubdir = str(int((obsindx % 100) // 10))
                subsubsubdir = str(obsindx % 10)
                cachedir = os.path.join(self._cachedir, subdir, subsubdir,
                                        subsubsubdir)
                if comm.rank == 0:
                    try:
                        os.makedirs(cachedir)
                    except FileExistsError:
                        pass

            comm.Barrier()
            if comm.rank == 0:
                print(prefix + 'Setting up atmosphere simulation',
                      flush=self._flush)
            comm.Barrier()

            # Cache the output common flags
            common_ref = tod.local_common_flags(self._common_flag_name)

            # Read the extent of the AZ/EL boresight pointing, and use that
            # to compute the range of angles needed for simulating the slab.

            (min_az_bore, max_az_bore, min_el_bore,
             max_el_bore) = tod.scan_range
            # print("boresight scan range = {}, {}, {}, {}".format(
            # min_az_bore, max_az_bore, min_el_bore, max_el_bore))

            # Use a fixed focal plane radius so that changing the actual
            # set of detectors will not affect the simulated atmosphere.

            elfac = 1 / np.cos(max_el_bore + fp_radius)
            azmin = min_az_bore - fp_radius * elfac
            azmax = max_az_bore + fp_radius * elfac
            if azmin < -2 * np.pi:
                azmin += 2 * np.pi
                azmax += 2 * np.pi
            elif azmax > 2 * np.pi:
                azmin -= 2 * np.pi
                azmax -= 2 * np.pi
            elmin = min_el_bore - fp_radius
            elmax = max_el_bore + fp_radius

            azmin = comm.allreduce(azmin, op=MPI.MIN)
            azmax = comm.allreduce(azmax, op=MPI.MAX)
            elmin = comm.allreduce(elmin, op=MPI.MIN)
            elmax = comm.allreduce(elmax, op=MPI.MAX)

            if elmin < 0 or elmax > np.pi / 2:
                raise RuntimeError(
                    'Error in CES elevation: elmin = {:.2f}, elmax = {:.2f}'
                    ''.format(elmin, elmax))

            comm.Barrier()

            # Loop over the time span in "wind_time"-sized chunks.
            # wind_time is intended to reflect the correlation length
            # in the atmospheric noise.

            tmin = tmin_tot
            istart = 0
            while tmin < tmax_tot:
                while times[istart] < tmin:
                    istart += 1

                tmax = tmin + self._wind_time
                if tmax < tmax_tot:
                    # Extend the scan to the next turnaround
                    istop = istart
                    while istop < times.size and times[istop] < tmax:
                        istop += 1
                    while istop < times.size and (common_ref[istop]
                                                  | tod.TURNAROUND == 0):
                        istop += 1
                    if istop < times.size:
                        tmax = times[istop]
                    else:
                        tmax = tmax_tot
                else:
                    tmax = tmax_tot
                    istop = times.size

                ind = slice(istart, istop)
                nind = istop - istart

                if self._report_timing:
                    comm.Barrier()
                    tstart = MPI.Wtime()

                comm.Barrier()
                if comm.rank == 0:
                    print(prefix + 'Instantiating the atmosphere for t = {}'
                          ''.format(tmin - tmin_tot),
                          flush=self._flush)
                comm.Barrier()

                T0_center = weather.air_temperature
                wx = weather.west_wind
                wy = weather.south_wind
                w_center = np.sqrt(wx**2 + wy**2)
                wdir_center = np.arctan2(wy, wx)

                sim = atm_sim_alloc(
                    azmin, azmax, elmin, elmax, tmin, tmax, self._lmin_center,
                    self._lmin_sigma, self._lmax_center, self._lmax_sigma,
                    w_center, 0, wdir_center, 0, self._z0_center,
                    self._z0_sigma, T0_center, 0, self._zatm, self._zmax,
                    self._xstep, self._ystep, self._zstep, self._nelem_sim_max,
                    self._verbosity, comm, self._gangsize, key1, key2,
                    counter1, counter2, cachedir)
                if sim == 0:
                    raise RuntimeError(prefix +
                                       'Failed to allocate simulation')

                if self._report_timing:
                    comm.Barrier()
                    tstop = MPI.Wtime()
                    if comm.rank == 0 and tstop - tstart > 1:
                        print(prefix + 'OpSimAtmosphere: Initialized '
                              'atmosphere in {:.2f} s'.format(tstop - tstart),
                              flush=self._flush)
                    tstart = tstop

                comm.Barrier()

                use_cache = cachedir is not None
                if comm.rank == 0:
                    fname = os.path.join(
                        cachedir, '{}_{}_{}_{}_metadata.txt'.format(
                            key1, key2, counter1, counter2))
                    if use_cache and os.path.isfile(fname):
                        print(prefix + 'Loading the atmosphere for t = {} '
                              'from {}'.format(tmin - tmin_tot, fname),
                              flush=self._flush)
                        cached = True
                    else:
                        print(prefix + 'Simulating the atmosphere for t = {}'
                              ''.format(tmin - tmin_tot),
                              flush=self._flush)
                        cached = False

                err = atm_sim_simulate(sim, use_cache)
                if err != 0:
                    raise RuntimeError(prefix + 'Simulation failed.')

                # Advance the sample counter in case wind_time broke the
                # observation in parts

                counter2 += 100000000

                if self._report_timing:
                    comm.Barrier()
                    tstop = MPI.Wtime()
                    if comm.rank == 0 and tstop - tstart > 1:
                        if cached:
                            op = 'Loaded'
                        else:
                            op = 'Simulated'
                        print(prefix + 'OpSimAtmosphere: {} atmosphere in '
                              '{:.2f} s'.format(op, tstop - tstart),
                              flush=self._flush)
                    tstart = tstop

                if self._verbosity > 0:
                    self._plot_snapshots(sim, prefix, obsname, azmin, azmax,
                                         elmin, elmax, tmin, tmax, comm)

                nsamp = tod.local_samples[1]

                if self._report_timing:
                    comm.Barrier()
                    tstart = MPI.Wtime()

                if comm.rank == 0:
                    print(prefix + 'Observing the atmosphere',
                          flush=self._flush)

                for det in tod.local_dets:

                    # Cache the output signal
                    cachename = '{}_{}'.format(self._out, det)
                    if tod.cache.exists(cachename):
                        ref = tod.cache.reference(cachename)
                    else:
                        ref = tod.cache.create(cachename, np.float64,
                                               (nsamp, ))

                    # Cache the output flags
                    flag_ref = tod.local_flags(det, self._flag_name)

                    if self._apply_flags:
                        good = np.logical_and(
                            common_ref[ind] & self._common_flag_mask == 0,
                            flag_ref[ind] & self._flag_mask == 0)
                        ngood = np.sum(good)
                        if ngood == 0:
                            continue
                        azelquat = tod.read_pntg(detector=det,
                                                 local_start=istart,
                                                 n=nind,
                                                 azel=True)[good]
                        atmdata = np.zeros(ngood, dtype=np.float64)
                    else:
                        ngood = nind
                        azelquat = tod.read_pntg(detector=det,
                                                 local_start=istart,
                                                 n=nind,
                                                 azel=True)
                        atmdata = np.zeros(nind, dtype=np.float64)

                    # Convert Az/El quaternion of the detector back into
                    # angles for the simulation.

                    theta, phi, _ = qa.to_angles(azelquat)
                    # Azimuth is measured in the opposite direction
                    # than longitude
                    az = 2 * np.pi - phi
                    el = np.pi / 2 - theta

                    if np.ptp(az) < np.pi:
                        azmin_det = np.amin(az)
                        azmax_det = np.amax(az)
                    else:
                        # Scanning across the zero azimuth.
                        azmin_det = np.amin(az[az > np.pi]) - 2 * np.pi
                        azmax_det = np.amax(az[az < np.pi])
                    elmin_det = np.amin(el)
                    elmax_det = np.amax(el)
                    if ((not (azmin <= azmin_det and azmax_det <= azmax)
                         and not (azmin <= azmin_det - 2 * np.pi
                                  and azmax_det - 2 * np.pi <= azmax)) or
                            not (elmin <= elmin_det and elmin_det <= elmax)):
                        raise RuntimeError(
                            prefix + 'Detector Az/El: [{:.5f}, {:.5f}], '
                            '[{:.5f}, {:.5f}] is not contained in '
                            '[{:.5f}, {:.5f}], [{:.5f} {:.5f}]'
                            ''.format(azmin_det, azmax_det, elmin_det,
                                      elmax_det, azmin, azmax, elmin, elmax))

                    # Integrate detector signal

                    err = atm_sim_observe(sim, times[ind], az, el, atmdata,
                                          ngood, 0)
                    if err != 0:
                        # Observing failed
                        print(prefix + 'OpSimAtmosphere: Observing FAILED. '
                              'det = {}, rank = {}'.format(det, comm.rank),
                              flush=self._flush)
                        atmdata[:] = 0
                        flag_ref[ind] = 255

                    if self._gain:
                        atmdata *= self._gain

                    if absorption is not None:
                        # Apply the frequency-dependent absorption-coefficient
                        atmdata *= absorption

                    if self._apply_flags:
                        ref[ind][good] += atmdata
                    else:
                        ref[ind] += atmdata

                    del ref

                err = atm_sim_free(sim)
                if err != 0:
                    raise RuntimeError(prefix + 'Failed to free simulation.')

                if self._report_timing:
                    comm.Barrier()
                    tstop = MPI.Wtime()
                    if comm.rank == 0 and tstop - tstart > 1:
                        print(prefix + 'OpSimAtmosphere: Observed atmosphere '
                              'in {:.2f} s'.format(tstop - tstart),
                              flush=self._flush)

                tmin = tmax

        return
コード例 #4
0
ファイル: frame_utils.py プロジェクト: simonsobs/sotodlib
def tod_to_frames(
    tod,
    start_frame,
    n_frames,
    frame_offsets,
    frame_sizes,
    cache_signal=None,
    cache_flags=None,
    cache_common_flags=None,
    copy_common=None,
    copy_detector=None,
    mask_flag_common=255,
    mask_flag=255,
    units=None,
    dets=None,
    compress=False,
):
    """Gather all data from the distributed TOD cache for a set of frames.

    Args:
        tod (toast.TOD): instance of a TOD class.
        start_frame (int): the first frame index.
        n_frames (int): the number of frames.
        frame_offsets (array_like): list of the first samples of all frames.
        frame_sizes (list): list of the number of samples in each frame.
        cache_signal (str): if None, read signal from TOD.  Otherwise use this
            cache prefix for the detector signal timestreams.
        cache_flags (str): if None read det flags from TOD.  Otherwise use
            this cache prefix for the detector flag timestreams.
        cache_common_flags (str): if None, read common flags from TOD.
            Otherwise use this cache prefix.
        copy_common (tuple): (cache name, G3 type, frame name) of each extra
            common field to copy from cache.
        copy_detector (tuple): (cache name prefix, G3 type, G3 map type,
            frame name) of each distributed detector field (excluding the
            "signal") to copy from cache.
        mask_flag_common (int):  Bitmask to apply to common flags.
        mask_flag (int):  Bitmask to apply to per-detector flags.
        units: G3 units of the detector data.
        dets (list):  List of detectors to include in the frame.  If None,
            use all of the detectors in the TOD object.
        compress (bool or dict):  If True or a dictionary of compression parameters,
            store the timestreams as FLAC-compressed, 24-bit integers instead of
            uncompressed doubles.

    Returns:
        (list): List of frames on rank zero.  Other processes have a list of
            None values.

    """
    comm = tod.mpicomm
    rank = 0
    if comm is not None:
        rank = comm.rank
    comm_row = tod.grid_comm_row

    # Detector names
    if dets is None:
        detnames = tod.detectors
    else:
        detnames = []
        use_dets = set(dets)
        for det in tod.detectors:
            if det in use_dets:
                detnames.append(det)

    # Local sample range
    local_first = tod.local_samples[0]
    nlocal = tod.local_samples[1]

    # The process grid
    detranks, sampranks = tod.grid_size
    rankdet, ranksamp = tod.grid_ranks

    def get_local_cache(prow, field, cacheoff, ncache):
        """Read a local slice of a cache field.
        """
        mtype = None
        pdata = None
        nnz = 0
        if rankdet == prow:
            ref = tod.cache.reference(field)
            nnz = 1
            if (len(ref.shape) > 1) and (ref.shape[1] > 0):
                nnz = ref.shape[1]
            if comm is not None:
                if ref.dtype == np.dtype(np.float64):
                    mtype = MPI.DOUBLE
                elif ref.dtype == np.dtype(np.int64):
                    mtype = MPI.INT64_T
                elif ref.dtype == np.dtype(np.int32):
                    mtype = MPI.INT32_T
                elif ref.dtype == np.dtype(np.uint8):
                    mtype = MPI.UINT8_T
                else:
                    msg = "Cannot use cache field {} of type {}"\
                        .format(field, ref.dtype)
                    raise RuntimeError(msg)
            if cacheoff is not None:
                pdata = ref.flatten()[nnz * cacheoff:nnz * (cacheoff + ncache)]
            else:
                pdata = np.zeros(0, dtype=ref.dtype)
        return (pdata, nnz, mtype)

    def gather_field(prow, pdata, nnz, mpitype, cacheoff, ncache, tag):
        """Gather a single timestream buffer to the root process.
        """
        is_none = pdata is None
        all_none = comm.allreduce(is_none, MPI.LAND)
        if all_none:
            # This situation arises at least when gathering HWP angle from LAT
            return None
        gdata = None
        # We are going to allreduce this later, so that every process
        # knows the dimensions of the field.
        gproc = 0
        allnnz = 0

        # Size of the local buffer
        pz = 0
        if pdata is not None:
            pz = len(pdata)

        if rankdet == prow:
            psizes = None
            if comm_row is None:
                psizes = [pz]
            else:
                psizes = comm_row.gather(pz, root=0)
            disp = None
            totsize = None
            if ranksamp == 0:
                # We are the process collecting the gathered data.
                allnnz = nnz
                gproc = rank
                # Compute the displacements into the receive buffer.
                disp = [0]
                for ps in psizes[:-1]:
                    last = disp[-1]
                    disp.append(last + ps)
                totsize = np.sum(psizes)
                # allocate receive buffer
                gdata = np.zeros(totsize, dtype=pdata.dtype)

            if comm_row is None:
                pdata[:] = gdata
            else:
                comm_row.Gatherv(pdata, [gdata, psizes, disp, mpitype], root=0)
            del disp
            del psizes

        # Now send this data to the root process of the whole communicator.
        # Only one process (the first one in process row "prow") has data
        # to send.

        if comm is not None:
            # All processes find out which one did the gather
            gproc = comm.allreduce(gproc, MPI.SUM)
            # All processes find out the field dimensions
            allnnz = comm.allreduce(allnnz, MPI.SUM)

        mtag = 10 * tag

        rdata = None
        if gproc == 0:
            if gdata is not None:
                if allnnz == 1:
                    rdata = gdata
                else:
                    rdata = gdata.reshape((-1, allnnz))
        else:
            # Data not yet on rank 0
            if rank == 0:
                # Receive data from the first process in this row
                rtype = comm.recv(source=gproc, tag=(mtag + 1))
                rsize = comm.recv(source=gproc, tag=(mtag + 2))
                rdata = np.zeros(rsize, dtype=np.dtype(rtype))
                comm.Recv(rdata, source=gproc, tag=mtag)
                # Reshape if needed
                if allnnz > 1:
                    rdata = rdata.reshape((-1, allnnz))
            elif (rank == gproc):
                # Send our data
                comm.send(gdata.dtype.char, dest=0, tag=(mtag + 1))
                comm.send(len(gdata), dest=0, tag=(mtag + 2))
                comm.Send(gdata, 0, tag=mtag)
        return rdata

    # For efficiency, we are going to gather the data for all frames at once.
    # Then we will split those up when doing the write.

    # Frame offsets relative to the memory buffers we are gathering
    fdataoff = [0]
    for f in frame_sizes[:-1]:
        last = fdataoff[-1]
        fdataoff.append(last + f)

    # The list of frames- only on the root process.
    fdata = None
    if rank == 0:
        fdata = [
            core3g.G3Frame(core3g.G3FrameType.Scan) for f in range(n_frames)
        ]
    else:
        fdata = [None for f in range(n_frames)]

    def split_field(data,
                    g3t,
                    framefield,
                    mapfield=None,
                    g3units=units,
                    times=None):
        """Split a gathered data buffer into frames- only on root process.
        """
        if data is None:
            return
        if g3t == core3g.G3VectorTime:
            # Special case for time values stored as int64_t, but
            # wrapped in a class.
            for f in range(n_frames):
                dataoff = fdataoff[f]
                ndata = frame_sizes[f]
                g3times = list()
                for t in range(ndata):
                    g3times.append(core3g.G3Time(data[dataoff + t]))
                if mapfield is None:
                    fdata[f][framefield] = core3g.G3VectorTime(g3times)
                else:
                    fdata[f][framefield][mapfield] = \
                        core3g.G3VectorTime(g3times)
                del g3times
        elif g3t == so3g.IntervalsInt:
            # Flag vector is written as a simple boolean.
            for f in range(n_frames):
                dataoff = fdataoff[f]
                ndata = frame_sizes[f]
                # Extract flag vector (0 or 1) for this frame
                frame_flags = (data[dataoff:dataoff + ndata] != 0).astype(int)
                # Convert bit 0 to an IntervalsInt.
                ival = so3g.IntervalsInt.from_mask(frame_flags, 1)[0]
                if mapfield is None:
                    fdata[f][framefield] = ival
                else:
                    fdata[f][framefield][mapfield] = ival
        elif g3t == core3g.G3Timestream:
            if times is None:
                raise RuntimeError(
                    "You must provide the time stamp vector with a "
                    "Timestream object")
            for f in range(n_frames):
                dataoff = fdataoff[f]
                ndata = frame_sizes[f]
                timeslice = times[cacheoff + dataoff:cacheoff + dataoff +
                                  ndata]
                tstart = timeslice[0] * 1e8
                tstop = timeslice[-1] * 1e8
                if mapfield is None:
                    if g3units is None:
                        fdata[f][framefield] = \
                            g3t(data[dataoff : dataoff + ndata])
                    else:
                        fdata[f][framefield] = \
                            g3t(data[dataoff : dataoff + ndata], g3units)
                    fdata[f][framefield].start = core3g.G3Time(tstart)
                    fdata[f][framefield].stop = core3g.G3Time(tstop)
                else:
                    # Individual detector data.  The only fields that
                    # we (optionally) compress.
                    if g3units is None:
                        tstream = g3t(data[dataoff:dataoff + ndata])
                    else:
                        tstream = g3t(data[dataoff:dataoff + ndata], g3units)
                    if compress and "compressor_gain_" + framefield in fdata[f]:
                        (tstream, gain,
                         offset) = recode_timestream(tstream, compress)
                        fdata[f]["compressor_gain_" +
                                 framefield][mapfield] = gain
                        fdata[f]["compressor_offset_" +
                                 framefield][mapfield] = offset
                    fdata[f][framefield][mapfield] = tstream
                    fdata[f][framefield][mapfield].start = core3g.G3Time(
                        tstart)
                    fdata[f][framefield][mapfield].stop = core3g.G3Time(tstop)
        else:
            # The bindings of G3Vector seem to only work with
            # lists.  This is probably horribly inefficient.
            for f in range(n_frames):
                dataoff = fdataoff[f]
                ndata = frame_sizes[f]
                if len(data.shape) == 1:
                    fdata[f][framefield] = \
                        g3t(data[dataoff : dataoff + ndata].tolist())
                else:
                    # We have a 2D quantity
                    fdata[f][framefield] = \
                        g3t(data[dataoff : dataoff + ndata, :].flatten()
                            .tolist())
        return

    # Compute the overlap of all frames with the local process.  We want to
    # to find the full sample range that this process overlaps the total set
    # of frames.

    cacheoff = None
    ncache = 0

    for f in range(n_frames):
        # Compute overlap of the frame with the local samples.
        fcacheoff, froff, nfr = s3utils.local_frame_indices(
            local_first, nlocal, frame_offsets[f], frame_sizes[f])
        if fcacheoff is not None:
            if cacheoff is None:
                cacheoff = fcacheoff
                ncache = nfr
            else:
                ncache += nfr

    # Now gather the full sample data one field at a time.  The root process
    # splits up the results into frames.

    # First collect boresight data.  In addition to quaternions for the Az/El
    # pointing, we convert this back into angles that follow the specs
    # for telescope pointing.

    times = None
    if rankdet == 0:
        times = tod.local_times()
    if comm is not None:
        times = gather_field(0, times, 1, MPI.DOUBLE, cacheoff, ncache, 0)

    bore = None
    if rankdet == 0:
        bore = tod.read_boresight(local_start=cacheoff, n=ncache).flatten()
    if comm is not None:
        bore = gather_field(0, bore, 4, MPI.DOUBLE, cacheoff, ncache, 0)
    if rank == 0:
        split_field(bore.reshape(-1, 4), core3g.G3VectorDouble,
                    "boresight_radec")

    bore = None
    if rankdet == 0:
        bore = tod.read_boresight_azel(local_start=cacheoff,
                                       n=ncache).flatten()
    if comm is not None:
        bore = gather_field(0, bore, 4, MPI.DOUBLE, cacheoff, ncache, 1)
    if rank == 0:
        split_field(bore.reshape(-1, 4), core3g.G3VectorDouble,
                    "boresight_azel")

    corotator_angle = None
    if rankdet == 0:
        cache_name = "corotator_angle_deg"
        if tod.cache.exists(cache_name):
            corotator_angle = np.radians(tod.cache.reference(cache_name))
    if comm is not None:
        corotator_angle = gather_field(0, corotator_angle, 1, MPI.DOUBLE,
                                       cacheoff, ncache, 0)
    if rank == 0:
        split_field(corotator_angle,
                    core3g.G3VectorDouble,
                    "corotator_angle",
                    times=times)

    if rank == 0:
        for f in range(n_frames):
            fdata[f]["boresight"] = core3g.G3TimestreamMap()
        ang_theta, ang_phi, ang_psi = qa.to_angles(bore)
        # Astronomical convention for azimuth is opposite to spherical
        # coordinate phi.
        ang_az = -ang_phi
        ang_el = (np.pi / 2.0) - ang_theta
        ang_roll = ang_psi
        split_field(ang_az,
                    core3g.G3Timestream,
                    "boresight",
                    "az",
                    None,
                    times=times)
        split_field(ang_el,
                    core3g.G3Timestream,
                    "boresight",
                    "el",
                    None,
                    times=times)
        split_field(ang_roll,
                    core3g.G3Timestream,
                    "boresight",
                    "roll",
                    None,
                    times=times)

    hwp_angle = None
    if rankdet == 0:
        hwp_angle = tod.local_hwp_angle()
    if comm is not None:
        hwp_angle = gather_field(0, hwp_angle, 1, MPI.DOUBLE, cacheoff, ncache,
                                 0)
    if rank == 0:
        split_field(hwp_angle, core3g.G3VectorDouble, "hwp_angle", times=times)

    # Now the position and velocity information

    pos = None
    if rankdet == 0:
        pos = tod.read_position(local_start=cacheoff, n=ncache).flatten()
    if comm is not None:
        pos = gather_field(0, pos, 3, MPI.DOUBLE, cacheoff, ncache, 2)
    if rank == 0:
        split_field(pos.reshape(-1, 3), core3g.G3VectorDouble, "site_position")

    vel = None
    if rankdet == 0:
        vel = tod.read_velocity(local_start=cacheoff, n=ncache).flatten()
    if comm is not None:
        vel = gather_field(0, vel, 3, MPI.DOUBLE, cacheoff, ncache, 3)
    if rank == 0:
        split_field(vel.reshape(-1, 3), core3g.G3VectorDouble, "site_velocity")

    # Now handle the common flags- either from a cache object or from the
    # TOD methods

    cflags = None
    nnz = 1
    if cache_common_flags is None:
        if rankdet == 0:
            cflags = np.array(
                tod.read_common_flags(local_start=cacheoff, n=ncache))
            cflags &= mask_flag_common
    else:
        cflags, nnz, mtype = get_local_cache(0, cache_common_flags, cacheoff,
                                             ncache)
        if cflags is not None:
            cflags &= mask_flag_common
    if comm is not None:
        mtype = MPI.UINT8_T
        cflags = gather_field(0, cflags, nnz, mtype, cacheoff, ncache, 4)
    if rank == 0:
        split_field(cflags, so3g.IntervalsInt, "flags_common")

    # Any extra common fields

    if comm is not None:
        comm.barrier()

    if copy_common is not None:
        for cindx, (cname, g3typ, fname) in enumerate(copy_common):
            cdata, nnz, mtype = get_local_cache(0, cname, cacheoff, ncache)
            cdata = gather_field(0, cdata, nnz, mtype, cacheoff, ncache, cindx)
            if rank == 0:
                split_field(cdata, g3typ, fname)

    # Now read all per-detector quantities.

    # For each detector field, processes which have the detector
    # in their local_dets should be in the same process row.

    if rank == 0:
        for f in range(n_frames):
            fdata[f]["signal"] = core3g.G3TimestreamMap()
            if compress:
                fdata[f]["compressor_gain_signal"] = core3g.G3MapDouble()
                fdata[f]["compressor_offset_signal"] = core3g.G3MapDouble()
            fdata[f]["flags"] = so3g.MapIntervalsInt()
            if copy_detector is not None:
                for cname, g3typ, g3maptyp, fnm in copy_detector:
                    fdata[f][fnm] = g3maptyp()
                    if compress:
                        fdata[f]["compressor_gain_" +
                                 fnm] = core3g.G3MapDouble()
                        fdata[f]["compressor_offset_" +
                                 fnm] = core3g.G3MapDouble()

    for dindx, dname in enumerate(detnames):
        drow = -1
        # Demodulation may have synthesized new detector names
        dnames = []
        for x in tod.local_dets:
            if x.endswith(dname):
                dnames.append(x)
        if dnames:
            drow = rankdet

        # As a sanity check, verify that every process which
        # has this detector is in the same process row.
        rowcheck = None
        if comm is None:
            rowcheck = [drow]
        else:
            rowcheck = comm.gather(drow, root=0)
        prow = 0
        if rank == 0:
            rc = np.array([x for x in rowcheck if (x >= 0)], dtype=np.int32)
            prow = np.max(rc)
            if np.min(rc) != prow:
                msg = "Processes with detector {} are not in the "\
                    "same row of the process grid\n".format(dname)
                sys.stderr.write(msg)
                if comm is not None:
                    comm.abort()

        # Every process finds out which process row is participating.
        if comm is not None:
            prow = comm.bcast(prow, root=0)
            all_dnames = comm.allgather(dnames)
            dnames = list(set(np.concatenate(all_dnames).flat))

        # "signal"

        for dname in dnames:
            detdata = None
            nnz = 1
            if cache_signal is None:
                if rankdet == prow:
                    detdata = tod.local_signal(dname)[cacheoff:cacheoff +
                                                      ncache]
            else:
                cache_det = "{}_{}".format(cache_signal, dname)
                detdata, nnz, mtype = get_local_cache(prow, cache_det,
                                                      cacheoff, ncache)

            if comm is not None:
                mtype = MPI.DOUBLE
                detdata = gather_field(prow, detdata, nnz, mtype, cacheoff,
                                       ncache, dindx)
            if rank == 0:
                split_field(detdata,
                            core3g.G3Timestream,
                            "signal",
                            mapfield=dname,
                            times=times)

        # "flags"

        for dname in dnames:
            detdata = None
            nnz = 1
            if cache_flags is None:
                if rankdet == prow:
                    detdata = tod.local_flags(dname)[cacheoff:cacheoff +
                                                     ncache]
                    detdata &= mask_flag
            else:
                cache_det = "{}_{}".format(cache_flags, dname)
                detdata, nnz, mtype = get_local_cache(prow, cache_det,
                                                      cacheoff, ncache)
                if detdata is not None:
                    detdata &= mask_flag
            if comm is not None:
                mtype = MPI.UINT8_T
                detdata = gather_field(prow, detdata, nnz, mtype, cacheoff,
                                       ncache, dindx)
            if rank == 0:
                split_field(detdata,
                            so3g.IntervalsInt,
                            "flags",
                            mapfield=dname)

        # Now copy any additional fields.

        for dname in dnames:
            if copy_detector is not None:
                for cname, g3typ, g3maptyp, fnm in copy_detector:
                    cache_det = "{}_{}".format(cname, dname)
                    detdata, nnz, mtype = get_local_cache(
                        prow, cache_det, cacheoff, ncache)
                    if comm is not None:
                        detdata = gather_field(prow, detdata, nnz, mtype,
                                               cacheoff, ncache, dindx)
                    if rank == 0:
                        split_field(detdata,
                                    g3typ,
                                    fnm,
                                    mapfield=dname,
                                    times=times)

    return fdata
コード例 #5
0
    def exec(self, data):

        for obs in data.obs:
            tod = obs["tod"]
            focalplane = obs["focalplane"]
            # Get HWP angle
            chi = tod.local_hwp_angle()
            for det in tod.local_dets:
                signal = tod.local_signal(det, self._name)
                band = focalplane[det]["band"]
                freq = {
                    "SAT_f030": "027",
                    "SAT_f040": "039",
                    "SAT_f090": "093",
                    "SAT_f150": "145",
                    "SAT_f230": "225",
                    "SAT_f290": "278",
                }[band]

                # Get incident angle

                det_quat = focalplane[det]["quat"]
                det_theta, det_phi, det_psi = qa.to_angles(det_quat)

                # Get observing elevation

                azelquat = tod.read_pntg(detector=det, azel=True)
                el = np.pi / 2 - qa.to_position(azelquat)[0]

                # Get polarization weights

                iweights = np.ones(signal.size)
                qweights = np.cos(2 * det_psi)
                uweights = np.sin(2 * det_psi)

                # Interpolate HWPSS to incident angle

                theta_deg = np.degrees(det_theta)
                itheta_high = np.searchsorted(self.thetas, theta_deg)
                itheta_low = itheta_high - 1

                theta_low = self.thetas[itheta_low]
                theta_high = self.thetas[itheta_high]
                r = (theta_deg - theta_low) / (theta_high - theta_low)

                transmission = (
                    (1 - r) * self.all_stokes[freq]["transmission"][itheta_low]
                    + r * self.all_stokes[freq]["transmission"][itheta_high])
                reflection = (
                    (1 - r) * self.all_stokes[freq]["reflection"][itheta_low] +
                    r * self.all_stokes[freq]["reflection"][itheta_high])
                emission = (
                    (1 - r) * self.all_stokes[freq]["emission"][itheta_low] +
                    r * self.all_stokes[freq]["emission"][itheta_high])

                # Scale HWPSS for observing elevation

                el_ref = np.radians(50)
                scale = np.sin(el_ref) / np.sin(el)

                # Observe HWPSS with the detector

                iquv = (transmission + reflection).T
                iquss = (iweights * np.interp(chi, self.chis, iquv[0]) +
                         qweights * np.interp(chi, self.chis, iquv[1]) +
                         uweights * np.interp(chi, self.chis, iquv[2])) * scale

                iquv = emission.T
                iquss += (iweights * np.interp(chi, self.chis, iquv[0]) +
                          qweights * np.interp(chi, self.chis, iquv[1]) +
                          uweights * np.interp(chi, self.chis, iquv[2]))

                iquss -= np.median(iquss)

                # Co-add with the cached signal

                signal += iquss

        return
コード例 #6
0
ファイル: pointing.py プロジェクト: planck-npipe/toast-npipe
    def exec(self, data):
        xaxis, _, zaxis = np.eye(3, dtype=np.float64)
        nullquat = np.array([0, 0, 0, 1], dtype=np.float64)

        # Read velocity

        for obs in data.obs:
            tod = obs["tod"]
            vel = tod.local_velocity(margin=self._margin)
            if self._single_precision:
                vel = vel.astype(np.float32)
                vel = tod.cache.put(tod.VELOCITY_NAME, vel, replace=True)
            del vel

        for obs in data.obs:
            tod = obs["tod"]
            tod.purge_eff_cache()

        # Read position

        if self._keep_pos:
            for obs in data.obs:
                tod = obs["tod"]
                try:  # LFI pointing files are missing the position
                    pos = tod.local_position_position(margin=self._margin)
                except Exception:
                    pos = None
                if pos is not None and self._single_precision:
                    pos = pos.astype(np.float32)
                    tod.cache.put(tod.POSITION_NAME, pos, replace=True)
                del pos
            for obs in data.obs:
                tod = obs["tod"]
                tod.purge_eff_cache()

        # Read phase

        if self._keep_phase:
            for obs in data.obs:
                tod = obs["tod"]
                phase = tod.local_phase(margin=self._margin)
                if self._single_precision:
                    phase = phase.astype(np.float32)
                    tod.cache.put(tod.PHASE_NAME, phase, replace=True)
                del phase
            for obs in data.obs:
                tod = obs["tod"]
                tod.purge_eff_cache()

        # Generate attitude

        for obs in data.obs:
            tod = obs["tod"]
            nsamp = tod.local_samples[1]
            commonflags = tod.local_common_flags(margin=self._margin)
            satquats = None
            for detector in tod.local_dets:
                if detector[-1] in "01" and detector[-2] != "-":
                    # Single diode, share pointing with the other diode
                    # in the same radiometer arm
                    if detector[-1] == "1":
                        # We may not need to process this diode
                        detector2 = detector[:-1] + "0"
                        if detector2 in tod.local_dets:
                            continue
                    det = to_radiometer(detector)
                    diodes = to_diodes(det)
                else:
                    det = detector
                    diodes = []

                vel = tod.local_velocity()
                if len(vel) != nsamp + 2 * self._margin:
                    raise Exception("Cached velocities do not include margins.")
                if satquats is None:
                    pdata, satquats = tod.read_pntg(
                        detector=detector,
                        margin=self._margin,
                        deaberrate=True,
                        velocity=vel,
                        full_output=True,
                    )
                else:
                    pdata = tod.read_pntg(
                        detector=detector,
                        margin=self._margin,
                        deaberrate=True,
                        velocity=vel,
                        satquats=satquats,
                    )
                del vel
                if len(pdata) != nsamp + 2 * self._margin:
                    raise Exception("Cached quats do not include margins.")

                if self._apply_flags:
                    flags = tod.local_flags(det, margin=self._margin)
                    if len(flags) != nsamp + 2 * self._margin:
                        raise Exception("Cached flags do not include margins.")
                    totflags = flags != 0
                    totflags[commonflags != 0] = True

                if self._single_precision:
                    cachename = "{}_{}".format(tod.POINTING_NAME, det)
                    tod.cache.put(cachename, pdata.astype(np.float32), replace=True)
                    for diode in diodes:
                        alias = "{}_{}".format(tod.POINTING_NAME, diode)
                        tod.cache.add_alias(alias, cachename)

                if self._apply_flags:
                    pdata[totflags, :] = nullquat

                theta, phi, psi = qa.to_angles(pdata)

                pixels = hp.ang2pix(self._nside, theta, phi, nest=True)
                if self._apply_flags:
                    pixels[totflags] = -1

                epsilon = self.RIMO[det].epsilon
                eta = (1 - epsilon) / (1 + epsilon)

                weights = None
                if self._mode == "I":
                    weights = np.ones([nsamp + 2 * self._margin, 1], dtype=np.float64)
                elif self._mode == "IQU":
                    Ival = np.ones(nsamp + 2 * self._margin)
                    Qval = eta * np.cos(2 * psi)
                    Uval = eta * np.sin(2 * psi)

                    weights = np.column_stack((Ival, Qval, Uval))
                else:
                    raise RuntimeError("invalid mode for Planck Pointing")

                pixelsname = "{}_{}".format(tod.PIXEL_NAME, det)
                if self._single_precision:
                    tod.cache.put(pixelsname, pixels.astype(np.int32), replace=True)
                else:
                    tod.cache.put(pixelsname, pixels.astype(np.int64), replace=True)
                for diode in diodes:
                    alias = "{}_{}".format(tod.PIXEL_NAME, diode)
                    tod.cache.add_alias(alias, pixelsname)

                weightsname = "{}_{}".format(tod.WEIGHT_NAME, det)
                if self._single_precision:
                    tod.cache.put(weightsname, weights.astype(np.float32), replace=True)
                else:
                    tod.cache.put(weightsname, weights.astype(np.float64), replace=True)
                for diode in diodes:
                    alias = "{}_{}".format(tod.WEIGHT_NAME, diode)
                    tod.cache.add_alias(alias, weightsname)

        for obs in data.obs:
            tod = obs["tod"]
            tod.purge_eff_cache()

        if not self._keep_vel:
            for obs in data.obs:
                tod = obs["tod"]
                tod.cache.destroy(tod.VELOCITY_NAME)

        return
コード例 #7
0
ファイル: toast.py プロジェクト: giuspugl/sotodlib
def tod_to_frames(tod,
                  start_frame,
                  n_frames,
                  frame_offsets,
                  frame_sizes,
                  cache_signal=None,
                  cache_flags=None,
                  cache_common_flags=None,
                  copy_common=None,
                  copy_detector=None,
                  mask_flag_common=255,
                  mask_flag=255,
                  units=None):
    """Gather all data from the distributed TOD cache for a set of frames.

    Args:
        tod (toast.TOD): instance of a TOD class.
        start_frame (int): the first frame index.
        n_frames (int): the number of frames.
        frame_offsets (array_like): list of the first samples of all frames.
        frame_sizes (list): list of the number of samples in each frame.
        cache_signal (str): if None, read signal from TOD.  Otherwise use this
            cache prefix for the detector signal timestreams.
        cache_flags (str): if None read det flags from TOD.  Otherwise use
            this cache prefix for the detector flag timestreams.
        cache_common_flags (str): if None, read common flags from TOD.
            Otherwise use this cache prefix.
        copy_common (tuple): (cache name, G3 type, frame name) of each extra
            common field to copy from cache.
        copy_detector (tuple): (cache name prefix, G3 type, G3 map type,
            frame name) of each distributed detector field (excluding the
            "signal") to copy from cache.
        mask_flag_common (int):  Bitmask to apply to common flags.
        mask_flag (int):  Bitmask to apply to per-detector flags.
        units: G3 units of the detector data.

    Returns:
        (list): List of frames on rank zero.  Other processes have a list of
            None values.

    """
    # Detector names
    detnames = tod.detectors

    # Local sample range
    local_first = tod.local_samples[0]
    nlocal = tod.local_samples[1]

    # The process grid
    detranks, sampranks = tod.grid_size
    rankdet, ranksamp = tod.grid_ranks

    def get_local_cache(prow, fld, cacheoff, ncache):
        """Read a local slice of a cache field.
        """
        mtype = None
        pdata = None
        if rankdet == prow:
            ref = tod.cache.reference(fld)
            nnz = 1
            if (len(ref.shape) > 1) and (ref.shape[1] > 0):
                nnz = ref.shape[1]
            if ref.dtype == np.dtype(np.float64):
                mtype = MPI.DOUBLE
            elif ref.dtype == np.dtype(np.int64):
                mtype = MPI.INT64_T
            elif ref.dtype == np.dtype(np.int32):
                mtype = MPI.INT32_T
            elif ref.dtype == np.dtype(np.uint8):
                mtype = MPI.UINT8_T
            else:
                msg = "Cannot use cache field {} of type {}"\
                    .format(fld, ref.dtype)
                raise RuntimeError(msg)
            if cacheoff is not None:
                pdata = ref.flatten()[nnz * cacheoff:nnz * (cacheoff + ncache)]
            else:
                pdata = np.zeros(0, dtype=ref.dtype)
        return (pdata, nnz, mtype)

    def gather_field(prow, pdata, nnz, mpitype, cacheoff, ncache, tag):
        """Gather a single timestream buffer to the root process.
        """
        gdata = None
        # We are going to allreduce this later, so that every process
        # knows the dimensions of the field.
        gproc = 0
        allnnz = 0

        # Size of the local buffer
        pz = len(pdata)

        if rankdet == prow:
            psizes = tod.grid_comm_row.gather(pz, root=0)
            disp = None
            totsize = None
            if ranksamp == 0:
                # We are the process collecting the gathered data.
                allnnz = nnz
                gproc = tod.mpicomm.rank
                # Compute the displacements into the receive buffer.
                disp = [0]
                for ps in psizes[:-1]:
                    last = disp[-1]
                    disp.append(last + ps)
                totsize = np.sum(psizes)
                # allocate receive buffer
                gdata = np.zeros(totsize, dtype=pdata.dtype)

            tod.grid_comm_row.Gatherv(pdata, [gdata, psizes, disp, mpitype],
                                      root=0)
            del disp
            del psizes

        # Now send this data to the root process of the whole communicator.
        # Only one process (the first one in process row "prow") has data
        # to send.

        # All processes find out which one did the gather
        gproc = tod.mpicomm.allreduce(gproc, MPI.SUM)
        # All processes find out the field dimensions
        allnnz = tod.mpicomm.allreduce(allnnz, MPI.SUM)

        mtag = 10 * tag

        rdata = None
        if gproc == 0:
            if gdata is not None:
                if allnnz == 1:
                    rdata = gdata
                else:
                    rdata = gdata.reshape((-1, allnnz))
        else:
            # Data not yet on rank 0
            if tod.mpicomm.rank == 0:
                # Receive data from the first process in this row
                rtype = tod.mpicomm.recv(source=gproc, tag=(mtag + 1))
                rsize = tod.mpicomm.recv(source=gproc, tag=(mtag + 2))
                rdata = np.zeros(rsize, dtype=np.dtype(rtype))
                tod.mpicomm.Recv(rdata, source=gproc, tag=mtag)
                # Reshape if needed
                if allnnz > 1:
                    rdata = rdata.reshape((-1, allnnz))
            elif (tod.mpicomm.rank == gproc):
                # Send our data
                tod.mpicomm.send(gdata.dtype.char, dest=0, tag=(mtag + 1))
                tod.mpicomm.send(len(gdata), dest=0, tag=(mtag + 2))
                tod.mpicomm.Send(gdata, 0, tag=mtag)
        return rdata

    # For efficiency, we are going to gather the data for all frames at once.
    # Then we will split those up when doing the write.

    # Frame offsets relative to the memory buffers we are gathering
    fdataoff = [0]
    for f in frame_sizes[:-1]:
        last = fdataoff[-1]
        fdataoff.append(last + f)

    # The list of frames- only on the root process.
    fdata = None
    if tod.mpicomm.rank == 0:
        fdata = [
            core3g.G3Frame(core3g.G3FrameType.Scan) for f in range(n_frames)
        ]
    else:
        fdata = [None for f in range(n_frames)]

    def flags_to_intervals(flgs):
        """Convert a flag vector to an interval list.
        """
        groups = [[i for i, value in it]
                  for key, it in itertools.groupby(enumerate(flgs),
                                                   key=operator.itemgetter(1))
                  if key != 0]
        chunks = list()
        for grp in groups:
            chunks.append([grp[0], grp[-1]])
        return chunks

    def split_field(data, g3t, framefield, mapfield=None, g3units=units):
        """Split a gathered data buffer into frames.
        """
        if tod.mpicomm.rank == 0:
            if g3t == core3g.G3VectorTime:
                # Special case for time values stored as int64_t, but
                # wrapped in a class.
                for f in range(n_frames):
                    dataoff = fdataoff[f]
                    ndata = frame_sizes[f]
                    g3times = list()
                    for t in range(ndata):
                        g3times.append(core3g.G3Time(data[dataoff + t]))
                    if mapfield is None:
                        fdata[f][framefield] = core3g.G3VectorTime(g3times)
                    else:
                        fdata[f][framefield][mapfield] = \
                            core3g.G3VectorTime(g3times)
                    del g3times
            elif g3t == so3g.IntervalsInt:
                # This means that the data is actually flags
                # and we should convert it into a list of intervals.
                fint = flags_to_intervals(data)
                for f in range(n_frames):
                    dataoff = fdataoff[f]
                    ndata = frame_sizes[f]
                    datalast = dataoff + ndata
                    chunks = list()
                    idomain = (0, ndata - 1)
                    for intr in fint:
                        # Interval sample ranges are defined relative to the
                        # frame itself.
                        cfirst = None
                        clast = None
                        if (intr[0] < datalast) and (intr[1] >= dataoff):
                            # there is some overlap...
                            if intr[0] < dataoff:
                                cfirst = 0
                            else:
                                cfirst = intr[0] - dataoff
                            if intr[1] >= datalast:
                                clast = ndata - 1
                            else:
                                clast = intr[1] - dataoff
                            chunks.append([cfirst, clast])
                    if mapfield is None:
                        if len(chunks) == 0:
                            fdata[f][framefield] = \
                                so3g.IntervalsInt()
                        else:
                            fdata[f][framefield] = \
                                so3g.IntervalsInt.from_array(
                                    np.array(chunks, dtype=np.int64))
                        fdata[f][framefield].domain = idomain
                    else:
                        if len(chunks) == 0:
                            fdata[f][framefield][mapfield] = \
                                so3g.IntervalsInt()
                        else:
                            fdata[f][framefield][mapfield] = \
                                so3g.IntervalsInt.from_array(
                                    np.array(chunks, dtype=np.int64))
                            fdata[f][framefield][mapfield].domain = idomain
                del fint
            elif g3t == core3g.G3Timestream:
                for f in range(n_frames):
                    dataoff = fdataoff[f]
                    ndata = frame_sizes[f]
                    if mapfield is None:
                        if g3units is None:
                            fdata[f][framefield] = \
                                g3t(data[dataoff:dataoff+ndata])
                        else:
                            fdata[f][framefield] = \
                                g3t(data[dataoff:dataoff+ndata], g3units)
                    else:
                        if g3units is None:
                            fdata[f][framefield][mapfield] = \
                                g3t(data[dataoff:dataoff+ndata])
                        else:
                            fdata[f][framefield][mapfield] = \
                                g3t(data[dataoff:dataoff+ndata], g3units)
            else:
                # The bindings of G3Vector seem to only work with
                # lists.  This is probably horribly inefficient.
                for f in range(n_frames):
                    dataoff = fdataoff[f]
                    ndata = frame_sizes[f]
                    if len(data.shape) == 1:
                        fdata[f][framefield] = \
                            g3t(data[dataoff:dataoff+ndata].tolist())
                    else:
                        # We have a 2D quantity
                        fdata[f][framefield] = \
                            g3t(data[dataoff:dataoff+ndata, :].flatten()
                                .tolist())
        return

    # Compute the overlap of all frames with the local process.  We want to
    # to find the full sample range that this process overlaps the total set
    # of frames.

    cacheoff = None
    ncache = 0

    for f in range(n_frames):
        # Compute overlap of the frame with the local samples.
        fcacheoff, froff, nfr = s3utils.local_frame_indices(
            local_first, nlocal, frame_offsets[f], frame_sizes[f])
        if fcacheoff is not None:
            if cacheoff is None:
                cacheoff = fcacheoff
                ncache = nfr
            else:
                ncache += nfr

    # Now gather the full sample data one field at a time.  The root process
    # splits up the results into frames.

    # First collect boresight data.  In addition to quaternions for the Az/El
    # pointing, we convert this back into angles that follow the specs
    # for telescope pointing.

    bore = None
    if rankdet == 0:
        bore = tod.read_boresight(local_start=cacheoff, n=ncache)
    bore = gather_field(0, bore.flatten(), 4, MPI.DOUBLE, cacheoff, ncache, 0)
    split_field(bore.reshape(-1, 4), core3g.G3VectorDouble, "qboresight_radec")

    bore = None
    if rankdet == 0:
        bore = tod.read_boresight_azel(local_start=cacheoff, n=ncache)
    bore = gather_field(0, bore.flatten(), 4, MPI.DOUBLE, cacheoff, ncache, 1)
    split_field(bore.reshape(-1, 4), core3g.G3VectorDouble, "qboresight_azel")

    if tod.mpicomm.rank == 0:
        for f in range(n_frames):
            fdata[f]["boresight"] = core3g.G3TimestreamMap()

    ang_theta, ang_phi, ang_psi = qa.to_angles(bore)
    ang_az = ang_phi
    ang_el = (np.pi / 2.0) - ang_theta
    ang_roll = ang_psi
    split_field(ang_az, core3g.G3Timestream, "boresight", "az", None)
    split_field(ang_el, core3g.G3Timestream, "boresight", "el", None)
    split_field(ang_roll, core3g.G3Timestream, "boresight", "roll", None)

    # Now the position and velocity information

    pos = None
    if rankdet == 0:
        pos = tod.read_position(local_start=cacheoff, n=ncache)
    pos = gather_field(0, pos.flatten(), 3, MPI.DOUBLE, cacheoff, ncache, 2)
    split_field(pos.reshape(-1, 3), core3g.G3VectorDouble, "site_position")

    vel = None
    if rankdet == 0:
        vel = tod.read_velocity(local_start=cacheoff, n=ncache)
    vel = gather_field(0, vel.flatten(), 3, MPI.DOUBLE, cacheoff, ncache, 3)
    split_field(vel.reshape(-1, 3), core3g.G3VectorDouble, "site_velocity")

    # Now handle the common flags- either from a cache object or from the
    # TOD methods

    cflags = None
    nnz = 1
    mtype = MPI.UINT8_T
    if cache_common_flags is None:
        if rankdet == 0:
            cflags = tod.read_common_flags(local_start=cacheoff, n=ncache)
            cflags &= mask_flag_common
    else:
        cflags, nnz, mtype = get_local_cache(0, cache_common_flags, cacheoff,
                                             ncache)
        cflags &= mask_flag_common
    cflags = gather_field(0, cflags, nnz, mtype, cacheoff, ncache, 4)
    split_field(cflags, so3g.IntervalsInt, "flags_common")

    # Any extra common fields

    tod.mpicomm.barrier()

    if copy_common is not None:
        for cindx, (cname, g3typ, fname) in enumerate(copy_common):
            cdata, nnz, mtype = get_local_cache(0, cname, cacheoff, ncache)
            cdata = gather_field(0, cdata, nnz, mtype, cacheoff, ncache, cindx)
            split_field(cdata, g3typ, fname)

    # Now read all per-detector quantities.

    # For each detector field, processes which have the detector
    # in their local_dets should be in the same process row.

    if tod.mpicomm.rank == 0:
        for f in range(n_frames):
            fdata[f]["signal"] = core3g.G3TimestreamMap()
            fdata[f]["flags"] = so3g.MapIntervalsInt()
            if copy_detector is not None:
                for cname, g3typ, g3maptyp, fnm in copy_detector:
                    fdata[f][fnm] = g3maptyp()

    for dindx, dname in enumerate(detnames):
        drow = -1
        if dname in tod.local_dets:
            drow = rankdet
        # As a sanity check, verify that every process which
        # has this detector is in the same process row.
        rowcheck = tod.mpicomm.gather(drow, root=0)
        prow = 0
        if tod.mpicomm.rank == 0:
            rc = np.array([x for x in rowcheck if (x >= 0)], dtype=np.int32)
            prow = np.max(rc)
            if np.min(rc) != prow:
                msg = "Processes with detector {} are not in the "\
                    "same row of the process grid\n".format(dname)
                sys.stderr.write(msg)
                tod.mpicomm.abort()

        # Every process finds out which process row is participating.
        prow = tod.mpicomm.bcast(prow, root=0)

        # "signal"

        detdata = None
        nnz = 1
        mtype = MPI.DOUBLE
        if cache_signal is None:
            if rankdet == prow:
                detdata = tod.read(detector=dname,
                                   local_start=cacheoff,
                                   n=ncache)
        else:
            cache_det = "{}_{}".format(cache_signal, dname)
            detdata, nnz, mtype = get_local_cache(prow, cache_det, cacheoff,
                                                  ncache)
        detdata = gather_field(prow, detdata, nnz, mtype, cacheoff, ncache,
                               dindx)
        split_field(detdata, core3g.G3Timestream, "signal", mapfield=dname)

        # "flags"

        detdata = None
        nnz = 1
        mtype = MPI.UINT8_T
        if cache_flags is None:
            if rankdet == prow:
                detdata = tod.read_flags(detector=dname,
                                         local_start=cacheoff,
                                         n=ncache)
                detdata &= mask_flag
        else:
            cache_det = "{}_{}".format(cache_flags, dname)
            detdata, nnz, mtype = get_local_cache(prow, cache_det, cacheoff,
                                                  ncache)
            detdata &= mask_flag
        detdata = gather_field(prow, detdata, nnz, mtype, cacheoff, ncache,
                               dindx)
        split_field(detdata, so3g.IntervalsInt, "flags", mapfield=dname)

        # Now copy any additional fields.

        if copy_detector is not None:
            for cname, g3typ, g3maptyp, fnm in copy_detector:
                cache_det = "{}_{}".format(cname, dname)
                detdata, nnz, mtype = get_local_cache(prow, cache_det,
                                                      cacheoff, ncache)
                detdata = gather_field(prow, detdata, nnz, mtype, cacheoff,
                                       ncache, dindx)
                split_field(detdata, g3typ, fnm, mapfield=dname)

    return fdata
コード例 #8
0
def main():
    log = Logger.get()
    gt = GlobalTimers.get()
    gt.start("toast_planck_reduce (total)")

    mpiworld, procs, rank, comm = get_comm()

    if comm.world_rank == 0:
        print("Running with {} processes at {}".format(
            procs, str(datetime.datetime.now())))

    parser = argparse.ArgumentParser(description='Simple dipole pipeline',
                                     fromfile_prefix_chars='@')
    parser.add_argument('--rimo', required=True, help='RIMO file')
    parser.add_argument('--freq', required=True, type=np.int, help='Frequency')
    parser.add_argument('--dets',
                        required=False,
                        default=None,
                        help='Detector list (comma separated)')
    parser.add_argument('--effdir',
                        required=True,
                        help='Input Exchange Format File directory')
    parser.add_argument('--effdir_pntg',
                        required=False,
                        help='Input Exchange Format File directory for '
                        'pointing')
    parser.add_argument('--obtmask',
                        required=False,
                        default=1,
                        type=np.int,
                        help='OBT flag mask')
    parser.add_argument('--flagmask',
                        required=False,
                        default=1,
                        type=np.int,
                        help='Quality flag mask')
    parser.add_argument('--pntflagmask',
                        required=False,
                        default=0,
                        type=np.int,
                        help='Which OBT flag bits to raise for HCM maneuvers')
    parser.add_argument('--ringdb', required=True, help='Ring DB file')
    parser.add_argument('--odfirst',
                        required=False,
                        default=None,
                        help='First OD to use')
    parser.add_argument('--odlast',
                        required=False,
                        default=None,
                        help='Last OD to use')
    parser.add_argument('--ringfirst',
                        required=False,
                        default=None,
                        help='First ring to use')
    parser.add_argument('--ringlast',
                        required=False,
                        default=None,
                        help='Last ring to use')
    parser.add_argument('--obtfirst',
                        required=False,
                        default=None,
                        help='First OBT to use')
    parser.add_argument('--obtlast',
                        required=False,
                        default=None,
                        help='Last OBT to use')
    parser.add_argument('--out',
                        required=False,
                        default='.',
                        help='Output directory')
    # Dipole parameters
    dipogroup = parser.add_mutually_exclusive_group()
    dipogroup.add_argument('--dipole',
                           dest='dipole',
                           required=False,
                           default=False,
                           action='store_true',
                           help='Simulate dipole')
    dipogroup.add_argument('--solsys-dipole',
                           required=False,
                           default=False,
                           action='store_true',
                           help='Simulate solar system dipole')
    dipogroup.add_argument('--orbital-dipole',
                           required=False,
                           default=False,
                           action='store_true',
                           help='Simulate orbital dipole')
    dipo_parameters_group = parser.add_argument_group('dipole_parameters')
    dipo_parameters_group.add_argument(
        '--solsys_speed',
        required=False,
        type=np.float,
        default=DEFAULT_PARAMETERS["solsys_speed"],
        help='Solar system speed wrt. CMB rest frame in km/s. Default is '
        'Planck 2015 best fit value')
    dipo_parameters_group.add_argument(
        '--solsys-glon',
        required=False,
        type=np.float,
        default=DEFAULT_PARAMETERS["solsys_glon"],
        help='Solar system velocity direction longitude in degrees')
    dipo_parameters_group.add_argument(
        '--solsys-glat',
        required=False,
        type=np.float,
        default=DEFAULT_PARAMETERS["solsys_glat"],
        help='Solar system velocity direction latitude in degrees')

    try:
        args = parser.parse_args()
    except SystemExit:
        sys.exit(0)

    if comm.world_rank == 0:
        print('All parameters:')
        print(args, flush=True)

    timer = Timer()
    timer.start()

    do_dipole = args.dipole or args.solsys_dipole or args.orbital_dipole
    if not do_dipole:
        raise RuntimeError(
            "You have to set dipole, solsys-dipole or orbital-dipole")

    nrange = 1

    odranges = None
    if args.odfirst is not None and args.odlast is not None:
        odranges = []
        firsts = [int(i) for i in str(args.odfirst).split(',')]
        lasts = [int(i) for i in str(args.odlast).split(',')]
        for odfirst, odlast in zip(firsts, lasts):
            odranges.append((odfirst, odlast))
        nrange = len(odranges)

    ringranges = None
    if args.ringfirst is not None and args.ringlast is not None:
        ringranges = []
        firsts = [int(i) for i in str(args.ringfirst).split(',')]
        lasts = [int(i) for i in str(args.ringlast).split(',')]
        for ringfirst, ringlast in zip(firsts, lasts):
            ringranges.append((ringfirst, ringlast))
        nrange = len(ringranges)

    obtranges = None
    if args.obtfirst is not None and args.obtlast is not None:
        obtranges = []
        firsts = [float(i) for i in str(args.obtfirst).split(',')]
        lasts = [float(i) for i in str(args.obtlast).split(',')]
        for obtfirst, obtlast in zip(firsts, lasts):
            obtranges.append((obtfirst, obtlast))
        nrange = len(obtranges)

    if odranges is None:
        odranges = [None] * nrange

    if ringranges is None:
        ringranges = [None] * nrange

    if obtranges is None:
        obtranges = [None] * nrange

    detectors = None
    if args.dets is not None:
        detectors = re.split(',', args.dets)

    # create the TOD for this observation

    tods = []

    for obtrange, ringrange, odrange in zip(obtranges, ringranges, odranges):
        # create the TOD for this observation
        tods.append(
            tp.Exchange(comm=comm.comm_group,
                        detectors=detectors,
                        ringdb=args.ringdb,
                        effdir_in=args.effdir,
                        effdir_pntg=args.effdir_pntg,
                        obt_range=obtrange,
                        ring_range=ringrange,
                        od_range=odrange,
                        freq=args.freq,
                        RIMO=args.rimo,
                        obtmask=args.obtmask,
                        flagmask=args.flagmask,
                        pntflagmask=args.pntflagmask,
                        do_eff_cache=False))

    # Make output directory

    if not os.path.isdir(args.out) and comm.world_rank == 0:
        os.makedirs(args.out)

    # This is the distributed data, consisting of one or
    # more observations, each distributed over a communicator.
    data = toast.Data(comm)

    for iobs, tod in enumerate(tods):
        ob = {}
        ob['name'] = 'observation{:04}'.format(iobs)
        ob['id'] = 0
        ob['tod'] = tod
        ob['intervals'] = tod.valid_intervals
        ob['baselines'] = None
        ob['noise'] = tod.noise
        ob['noise_simu'] = tod.noise

        data.obs.append(ob)

    rimo = tods[0].rimo

    if mpiworld is not None:
        mpiworld.barrier()
    if comm.world_rank == 0:
        timer.report_clear("Metadata queries")

    # Always read the signal and flags, even if the signal is later
    # overwritten.  There is no overhead for the signal because it is
    # interlaced with the flags.

    tod_name = 'signal'
    timestamps_name = 'timestamps'
    flags_name = 'flags'
    common_flags_name = 'common_flags'
    reader = tp.OpInputPlanck(signal_name=tod_name,
                              flags_name=flags_name,
                              timestamps_name=timestamps_name,
                              commonflags_name=common_flags_name)
    if comm.world_rank == 0:
        print('Reading input signal from {}'.format(args.effdir), flush=True)
    reader.exec(data)
    if mpiworld is not None:
        mpiworld.barrier()
    if comm.world_rank == 0:
        timer.report_clear("Read")
    """
    # Clear the signal

    eraser = tp.OpCacheMath(in1=tod_name, in2=0, multiply=True,
                            out=tod_name)
    if comm.world_rank == 0:
        print('Erasing TOD', flush=True)
    eraser.exec(data)
    if mpiworld is not None:
        mpiworld.barrier()
    if comm.world_rank == 0:
        timer.report_clear("Erase")
    """

    # make a planck Healpix pointing matrix

    mode = 'IQU'
    nside = 512

    pointing = tp.OpPointingPlanck(nside=nside,
                                   mode=mode,
                                   RIMO=rimo,
                                   margin=0,
                                   apply_flags=True,
                                   keep_vel=do_dipole,
                                   keep_pos=False,
                                   keep_phase=False,
                                   keep_quats=do_dipole)
    pointing.exec(data)
    if mpiworld is not None:
        mpiworld.barrier()
    if comm.world_rank == 0:
        timer.report_clear("Pointing Matrix")

    flags_name = 'flags'
    common_flags_name = 'common_flags'

    # Simulate the dipole
    if args.dipole:
        dipomode = 'total'
    elif args.solsys_dipole:
        dipomode = 'solsys'
    else:
        dipomode = 'orbital'
    dipo = tp.OpDipolePlanck(args.freq,
                             solsys_speed=args.solsys_speed,
                             solsys_glon=args.solsys_glon,
                             solsys_glat=args.solsys_glat,
                             mode=dipomode,
                             output='dipole',
                             keep_quats=False,
                             npipe_mode=True)
    dipo.exec(data)
    dipo = tp.OpDipolePlanck(args.freq,
                             solsys_speed=args.solsys_speed,
                             solsys_glon=args.solsys_glon,
                             solsys_glat=args.solsys_glat,
                             mode=dipomode,
                             output='dipole4pi',
                             keep_quats=False,
                             npipe_mode=False,
                             lfi_mode=False)
    dipo.exec(data)
    if mpiworld is not None:
        mpiworld.barrier()
    if comm.world_rank == 0:
        timer.report_clear("Dipole")

    # Write out the values in ASCII
    for iobs, obs in enumerate(data.obs):
        tod = obs["tod"]
        times = tod.local_times()
        velocity = tod.local_velocity()
        for det in tod.local_dets:
            quat = tod.local_pointing(det)
            angles = np.vstack(qarray.to_angles(quat)).T
            signal = tod.local_signal(det)
            dipole = tod.local_signal(det, "dipole")
            dipole4pi = tod.local_signal(det, "dipole4pi")
            fname_out = os.path.join(
                args.out,
                "{}_dipole.{}.{}.{}.txt".format(dipomode, comm.world_rank,
                                                iobs, det))
            with open(fname_out, "w") as fout:
                for t, ang, vel, sig, dipo, dipo4pi in zip(
                        times, angles, velocity, signal, dipole, dipole4pi):
                    fout.write(
                        (10 * " {}" + "\n").format(t, *ang, *vel, sig, dipo,
                                                   dipo4pi))
            print("{} : Wrote {}".format(comm.world_rank, fname_out))

    if comm.world_rank == 0:
        timer.report_clear("Write dipole")

    gt.stop_all()
    if mpiworld is not None:
        mpiworld.barrier()
    timer = Timer()
    timer.start()
    alltimers = gather_timers(comm=mpiworld)
    if comm.world_rank == 0:
        out = os.path.join(args.out, "timing")
        dump_timing(alltimers, out)
        timer.stop()
        timer.report("Gather and dump timing info")
    return