Exemplo n.º 1
0
    def _initialize_default_detectors(self):

        self._default_detectors = []

        for detector_name in ['EBeam', 'PhaseCavity', 'FEEGasDetEnergy']:
            try:
                det = Detector(detector_name)
                self._default_detectors.append(det)
            except KeyError as e:
                pass

        # add all Evrs (there may be more than one)
        self._evr_cfgcodes = []
        for n in DetNames():
            if ':Evr.' in n[0]:
                det = Detector(n[0])
                self._default_detectors.append(det)

                cfg = det._fetch_configs()
                assert len(cfg) == 1
                self._evr_cfgcodes += [e.code() for e in cfg[0].eventcodes()]

        self._evr_cfgcodes = set(self._evr_cfgcodes)
        self._evr_cfgcodes = list(self._evr_cfgcodes)
        self._evr_cfgcodes.sort()

        return
Exemplo n.º 2
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def get_calib_file_path(env, address, run):
  """ Findes the path to the SLAC metrology file stored in a psana environment
      object's calibration store
      @param env psana environment object
      @param address address string for a detector
      @param run psana run object or run number
  """
  from psana import Detector
  try:
    # try to get it from the detector interface
    psana_det = Detector(address, run.env())
    return psana_det.pyda.geoaccess(run).path
  except Exception, e:
    pass
Exemplo n.º 3
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def env_dxtbx_from_slac_metrology(run, address, metro=None):
  """ Loads a dxtbx cspad cbf header only object from the metrology path stored
      in a psana run object's calibration store
      @param env psana run object
      @param address address string for a detector
  """
  if metro is not None:
    # FIXME: get metrology from a pickle file until det interface is ready
    cbf = get_cspad_cbf_handle(None, metro, 'cbf', None, "test", None, 100, verbose = True, header_only = True)

    from dxtbx.format.FormatCBFCspad import FormatCBFCspadInMemory
    return FormatCBFCspadInMemory(cbf)

  from psana import Detector
  try:
    # try to load the geometry from the detector interface
    psana_det = Detector(address, run.env())
    geometry = psana_det.pyda.geoaccess(run)
  except Exception, e:
    geometry = None
Exemplo n.º 4
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def get_calib_file_path(env, address, run):
    """ Findes the path to the SLAC metrology file stored in a psana
    environment object's calibration store
    @param env psana environment object
    @param address address string for a detector
    @param run psana run object or run number
    """

    from psana import Detector

    #
    # try to get it from the detector interface
    #

    try:
        start("load geometry from detector")
        psana_det = Detector(address, run.env())
        ret = psana_det.pyda.geoaccess(run.run()).path
        stop("load geometry from detector")

        return ret
    except Exception as e:
        pass

    #
    # try to get it from the calib store directly
    #

    from psana import ndarray_uint8_1, Source

    start("load geometry from calib store")
    cls = env.calibStore()
    src = Source('DetInfo(%s)' % address)
    path_nda = cls.get(ndarray_uint8_1, src, 'geometry-calib')
    stop("load geometry from calib store")

    if path_nda is None:
        return None
    return ''.join(map(chr, path_nda))
Exemplo n.º 5
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def env_dxtbx_from_slac_metrology(run, address):
  """ Loads a dxtbx cspad cbf header only object from the metrology path stored
      in a psana run object's calibration store
      @param env psana run object
      @param address address string for a detector
  """
  from xfel.command_line.xtc_process import PSANA2_VERSION
  if PSANA2_VERSION:
    det = run.ds.Detector(address)
    geometry = det.geometry(run)
  else:
    from psana import Detector
    try:
      # try to load the geometry from the detector interface
      psana_det = Detector(address, run.env())
      geometry = psana_det.pyda.geoaccess(run.run())
    except Exception as e:
      geometry = None

  if geometry is None:
    metro_path = get_calib_file_path(run.env(), address, run)
  elif geometry.valid:
    metro_path = None
  else:
    from libtbx.utils import Sorry
    import socket, os
    raise Sorry("Could not read geometry, hostname: %s"%socket.gethostname())

  if metro_path is None and geometry is None:
    return None

  metro = read_slac_metrology(metro_path, geometry)

  cbf = get_cspad_cbf_handle(None, metro, 'cbf', None, "test", None, 100, verbose = True, header_only = True)

  from dxtbx.format.FormatCBFCspad import FormatCBFCspadInMemory
  return FormatCBFCspadInMemory(cbf)
Exemplo n.º 6
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#!/usr/bin/env python
#--------------------

import numpy as np
from psana import DataSource, Detector 

ds = DataSource('exp=amox27716:run=100')
det = Detector('AmoEndstation.0:Acqiris.1')

myrun = next(ds.runs())
for n,evt in enumerate(myrun.events()):
    v = det.raw(evt)
    print 'Event:%03d'%n, '\n' if v is not None else '', v
    if v is not None : break

nda = np.array(v)
print 'raw.shape:', nda.shape

#nbins = nda.shape[-1]; img.shape = (nda.size/nbins, nbins)

import matplotlib.pyplot as plt
style = ('b-', 'r-', 'g-', 'k-', 'm-', 'y-', 'c-', )
plt.figure(figsize=(16,4))
for ch in range(2,7) :
    w = nda[0,ch,5000:30000]
    print 'ch:%02d wave.shape: %s'%(ch,str(w.shape))
    plt.plot(w, style[ch])
    #t = nda[1,ch,5000:30000]
    #plt.plot(t, w, style[ch])
    plt.xlabel('bin', fontsize=14)
    plt.ylabel('intensity', fontsize=14)
Exemplo n.º 7
0
#!/usr/bin/env python
#--------------------

import sys
import numpy as np
from psana import DataSource, Detector
from pypsalg import find_edges

#dsname = 'exp=xpptut15:run=280'
dsname = 'exp=amox27716:run=100'
detname = 'AmoEndstation.0:Acqiris.1'
#detname = 'AmoEndstation.0:Acqiris.2' # for xpptut15 ch:0 - MCP

ds = DataSource(dsname)
det = Detector(detname)

ch = int(sys.argv[1]) if len(sys.argv) > 1 else 2  # Acqiris chanel

for nevent, evt in enumerate(ds.events()):
    r = det.raw(evt)
    nda = np.array(r)
    print 'Event:%03d' % nevent, '\n' if r is not None else '', r
    if r is None: continue
    waveforms, times = r
    # find edges for channel 0
    # parameters: baseline, threshold, fraction, deadtime, leading_edges
    edges = find_edges(waveforms[ch], 0.0, -0.05, 1.0, 5.0, True)
    # pairs of (amplitude,sampleNumber)
    print 'edges for channel %02d:' % ch
    for n, (v, bin) in enumerate(edges):
        print '  edge:%02d  bin:%05d  value:%6.3f' % (n, bin, v)