Exemplo n.º 1
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 def setUp(self):
     envelope_tool.set_share_dirs()
     self.red_dict = {
         'pid': 13,
         'px': 1.,
         'py': 2.,
         'pz': 3.,
         'x': -1,
         'y': -2,
         'z': -3
     }
     self.hit_red = Hit.new_from_dict(self.red_dict)
     self.hit_full = Hit.new_from_dict(
         {
             'pid': 13,
             'px': 1.,
             'py': 2.,
             'pz': 3.,
             'x': -1,
             'y': -2,
             'z': -3,
             'mass': common.pdg_pid_to_mass[13],
             'charge': common.pdg_pid_to_charge[13]
         }, 'energy')
     self.main_window = envelope_tool.MainWindow()
     self.main_window.window.get_frame("&Beam Setup", "button").Clicked()
     self.beam_setup = self.main_window.beam_setup
     self.cov = CovarianceMatrix()
     for i in range(1, 7):
         for j in range(1, 7):
             self.cov.set_element(i, j, i * j)
         self.cov.set_element(i, i, i * i + 50.)
Exemplo n.º 2
0
 def test_track_many(self):
     """
     Test MatrixTracking.track_many
     """
     tracking = MatrixTracking(self.matrix_list, self.offset_list,
                               self.offset_in)
     hit_in = Hit.new_from_dict(
         {
             "mass": Common.pdg_pid_to_mass[2212],
             "charge": 1.,
             "pid": 2212,
             "pz": 1.,
             "x": 1.,
             "py": 1.,
             "energy": 1001.
         }, "pz")
     hit_in_2 = Hit.new_from_dict(
         {
             "mass": Common.pdg_pid_to_mass[2212],
             "charge": 1.,
             "pid": 2212,
             "pz": 1.,
             "x": 1.,
             "py": 1.,
             "energy": 1002.
         }, "pz")
     hit_list_of_lists = tracking.track_many([hit_in] * 3 + [hit_in_2])
     for hit_list in hit_list_of_lists[1:-1]:
         self.assertEqual(hit_list, hit_list_of_lists[0])
     self.assertNotEqual(hit_list_of_lists[-1], hit_list_of_lists[0])
     self.assertEqual(tracking.last, hit_list_of_lists)
Exemplo n.º 3
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    def plot_decoupled_da(self, row_data, da_key, index, axis1, axis2,
                          max_n_points, variables, acceptance):
        hit_data = row_data[da_key]
        da_row = self.get_da_row(hit_data, max_n_points)
        tm = row_data["ref_track"][0]
        tm = copy.deepcopy(row_data["tm"])
        for i, row in enumerate(tm):
            tm[i] = row[1:5]
        tm = DecoupledTransferMatrix(tm)
        name = da_key + "_" + axis1 + " vs " + axis2
        u_data, v_data, au_data, av_data, a4_data = [], [], [], [], []

        closed_orbit = Hit.new_from_dict(row_data["ref_track"][0])
        for i, hit_list in enumerate(hit_data):
            hit_list = [
                Hit.new_from_dict(hit_dict) for hit_dict in hit_list[1]
            ]
            seed_list = [self.get_seed(hit, closed_orbit) for hit in hit_list]
            seed_list = [tm.decoupled(seed) for seed in seed_list]
            u = [seed[0] for seed in seed_list]
            pu = [seed[1] for seed in seed_list]
            v = [seed[2] for seed in seed_list]
            pv = [seed[3] for seed in seed_list]
            u_data.append((u, pu))
            v_data.append((v, pv))

            #turns = range(len(seed_list))
            #amp_data_u = [self.get_amplitude(tm, seed, [0, 1]) for seed in seed_list]
            ##amp_data_v = [self.get_amplitude(tm, seed, [2, 3]) for seed in seed_list]
            #amp_data_4d = [self.get_amplitude(tm, seed, [0, 1, 2, 3]) for seed in seed_list]
        self.make_plot(u_data, da_row, da_key + " " + str(index) + ": u vs pu",
                       "u", "pu")
        self.make_plot(v_data, da_row, da_key + " " + str(index) + ": v vs pv",
                       "v", "pv")
    def get_toy_fets_ring(self):
        """Parameters version 0.5 N=15 FETS ring"""
        self.toy = ToyLongitudinal()
        self.start = Hit.new_from_dict(self.co_list[0]['hits'][0])
        self.end = Hit.new_from_dict(self.co_list[-1]['hits'][0])
        self.toy.r0 = self.start['r']
        self.toy.p0 = self.start['p']
        self.toy.k = 7.1
        self.toy.n_stations = 4
        self.toy.v_eff = 5e-3
        self.toy.phi_s = 0.1
        self.toy.n_turns = 2000
        self.toy.p1 = self.end['p']
        self.toy.scallop_factor = 1073.47 / self.toy.tof(self.toy.p0)
        self.toy.omega = 2. * math.pi * 0.001 / self.toy.tof(self.toy.p0)
        self.toy.cavity_phase = [0., 0.25, 0.5,
                                 0.75]  # fixed actual phase of cavity
        self.toy.azimuthal_angle = [0.] + [0., 0.25, 0.5, 0.75
                                           ] + [1.]  # position of cavity
        self.toy.setup_lookup(self.co_file, n_cells=15)
        print("Built ring with frequency", self.toy.omega/2./math.pi, \
              "scallop factor", self.toy.scallop_factor)

        self.toy.plot_dir = self.plot_dir
        self.toy.output_dir = self.tmp_dir

        self.toy.print_radius()
        self.toy.setup_phi_eff()
        canvas = None
        for station, color in [(0, ROOT.kRed), (1, ROOT.kGreen),
                               (2, ROOT.kBlue), (3, ROOT.kMagenta)]:
            canvas, hist, graph = self.toy.plot_radial_dependence(
                color, station, canvas)
Exemplo n.º 5
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 def get_co(self, item):
     var_list = ["x", "x'", "y", "y'"]
     units = {"x":1., "x'":1e3, "y":1., "y'":1e3}
     print("Ref track length", len(item["ref_track"]), item["ref_track"][0])
     print(item.keys())
     ref_0 = Hit.new_from_dict(item["ref_track"][0])
     ref_1 = Hit.new_from_dict(item["ref_track"][2])
     delta = [(ref_0[var]-ref_1[var])*units[var] for var in var_list]
     delta_mag = sum([x*x for x in delta])**0.5
     return delta_mag
Exemplo n.º 6
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def hit_global_weight_test():
    Hit.clear_global_weights()
    hit = Hit.new_from_dict({
        "spill": 1,
        "event_number": 2,
        "particle_number": 3
    })
    if (abs(hit.get("global_weight") - 1.) > 1e-9): return 'fail'
    hit.set('global_weight', 0.5)
    if (abs(hit.get_global_weight() - 0.5) > 1e-9): return 'fail'
    Hitcore.clear_global_weights()
    if (abs(hit.get_global_weight() - 1.) > 1e-9): return 'fail'
    return 'pass'
Exemplo n.º 7
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 def get_new_seed(self, config_seed):
     if len(self.output_list) == 0 or len(self.output_list[-1]) == 0:
         return config_seed
     elif len(self.output_list[-1]) == 1:
         seed = Hit.new_from_dict(self.output_list[-1][-1]["seed_hit"])
         return [seed[var] for var in self.var_list]
     else:
         seed0 = Hit.new_from_dict(self.output_list[-1][-2]["seed_hit"])
         seed1 = Hit.new_from_dict(self.output_list[-1][-1]["seed_hit"])
         s0 = [seed0[var] for var in self.var_list]
         s1 = [seed1[var] for var in self.var_list]
         s2 = [2 * s1[i] - s0[i] for i in range(4)]
         return s2
Exemplo n.º 8
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    def load_tracks(self, track_vector):
        loaded_track_vector = []
        for track in track_vector:
            if abs(track.GetParticleId()
                   ) == 211 and track.GetKillReason() != "":
                print "Pion killed because", track.GetKillReason()
            hit = {}
            hit["x"] = track.GetInitialPosition().x()
            hit["y"] = track.GetInitialPosition().y()
            hit["z"] = track.GetInitialPosition().z()
            hit["px"] = track.GetInitialMomentum().x()
            hit["py"] = track.GetInitialMomentum().y()
            hit["pz"] = track.GetInitialMomentum().z()
            hit["pid"] = track.GetParticleId()
            try:
                hit["mass"] = xboa.common.pdg_pid_to_mass[abs(hit["pid"])]
            except KeyError:
                hit["mass"] = 0.
            try:
                hit["charge"] = xboa.common.pdg_pid_to_charge[hit["charge"]]
            except KeyError:
                hit["charge"] = 0.

            hit = {}
            hit["x"] = track.GetFinalPosition().x()
            hit["y"] = track.GetFinalPosition().y()
            hit["z"] = track.GetFinalPosition().z()
            hit["px"] = track.GetFinalMomentum().x()
            hit["py"] = track.GetFinalMomentum().y()
            hit["pz"] = track.GetFinalMomentum().z()
            hit["pid"] = track.GetParticleId()
            try:
                hit["mass"] = xboa.common.pdg_pid_to_mass[abs(hit["pid"])]
            except KeyError:
                hit["mass"] = 0.
            try:
                hit["charge"] = xboa.common.pdg_pid_to_charge[hit["charge"]]
            except KeyError:
                hit["charge"] = 0.

            loaded_track_initial = {
                "hit": Hit.new_from_dict(hit, "energy"),
                "detector": "mc_track_initial"
            }
            loaded_track_final = {
                "hit": Hit.new_from_dict(hit, "energy"),
                "detector": "mc_track_final",
            }
            loaded_track_vector += [loaded_track_initial, loaded_track_final]
        return {}, loaded_track_vector
 def _test_content_hypersphere(self):
     # disabled because it is slow
     print("Test content hypersphere")
     for i in range(5):
         numpy.seterr(all='ignore')
         test_bunch = Bunch()
         content_predicted = numpy.linalg.det(self.diag)*math.pi**2/2.
         test_bunch = Bunch.new_hit_shell(7,
                                          4.*self.diag,
                                          ['x', 'y', 'px', 'py'],
                                          '')
         test_bunch.append(Hit.new_from_dict({'x':0., 'y':0., 'px':0., 'py':0.}))
         for hit in test_bunch:
             hit['x'] += 1.*i
             hit['px'] += 2.*i
             hit['y'] += 3.*i
             hit['py'] += 4.*i
         my_weights = VoronoiWeighting(['x', 'y', 'px', 'py'],
                                       numpy.array([[2., 0., 0., 0.],
                                                    [0., 1., 0., 0.],
                                                    [0., 0., 1., 0.],
                                                    [0., 0., 0., 1.],]))
         my_weights.apply_weights(test_bunch, False)
         my_weights.plot_two_d_projection(['x', 'y'])
         my_weights.plot_two_d_projection(['px', 'py'])
         #self.assertEqual(len(my_weights.tile_content_list), len(test_bunch)+1)
         content_actual = sum(my_weights.tile_content_list)
         print("Content", content_actual, "Predicted", content_predicted)
         self.assertAlmostEqual(content_actual, content_predicted, 0)
     input()
Exemplo n.º 10
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def get_tracking_object():
    """
    Create a tracking object. This tracking object uses a list of matrices to
    generate tracking. The tracking goes like
    - x is a conventional phase space ellipse
    - y has phase advance of exactly pi
    - t has phase advance is complex i.e. on a resonance.
    Each cell or turn we advance through another transfer matrix. The closed 
    orbit is generated by a hard coded offset.

    Return value is a tuple consisting of a hit object on the closed_orbit and
    a tracking object that will propagate hit objects through the matrices.
    """
    number_of_turns = 5
    # x is conventional ellipse
    # y is phase advance = pi
    # t is phase advance = complex
    data = [[1.0, 0.5, 0.0, 0.0, 0.0, 0.0], [-0.5, 0.75, 0.0, 0.0, 0.0, 0.0],
            [0.0, 0.0, 0.0, -1.0, 0.0, 0.0], [0.0, 0.0, 1.0, 0.0, 0.0, 0.0],
            [0.0, 0.0, 0.0, 0.0, 2.0, 2.0], [0.0, 0.0, 0.0, 0.0, 2.0, 2.5]]
    matrix = numpy.matrix(data)
    matrix_list = [matrix**(i + 1) for i in range(number_of_turns)]
    offset = numpy.matrix([10., 7., 0., 0., 0., 1000.])
    offset_list = [offset] * number_of_turns
    offset_in = numpy.matrix([10., 7., 0., 0., 0., 1000.])
    tracking = MatrixTracking(matrix_list, offset_list, offset_in)
    closed_orbit_hit = Hit.new_from_dict(
        {
            'x': 10.,
            'px': 7.,
            'energy': 1000.,
            'pid': 2212,
            'mass': common.pdg_pid_to_mass[2212]
        }, 'pz')
    return closed_orbit_hit, tracking
Exemplo n.º 11
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 def generate_h5_step(self, h5_file, station):
     for key in h5_file.keys():
         if key[:5] != "Step#":
             if self.verbose > 10:
                 print("Skipping", key)
             continue
         n_steps = len(h5_file[key]["x"])
         if self.verbose > 10:
             print("Found", key, "in", n_steps, "events in", h5_file.filename)
         h5_step = h5_file[key]
         for i in range(n_steps):
             hit_dict = {}
             for key in "pid", "mass", "charge":
                 hit_dict[key] = self.ref[key]
             for h5_key, xboa_key in self.h5_key_to_xboa_key.items():
                 hit_dict[xboa_key] = h5_step[h5_key][i]
                 if xboa_key in self.units:
                     hit_dict[xboa_key] *= self.units[xboa_key]
             for key in ["px", "py", "pz"]:
                 hit_dict[key] *= self.ref["mass"]
             hit_dict["station"] = station
             hit = Hit.new_from_dict(hit_dict, "energy")
             if self.verbose > 10:
                 print("  h5", format(hit["event_number"], "4d"), end=' ')
                 for key in self.print_keys:
                     print(str(round(hit[key], 3)).ljust(8), end=' ')
                 print()
             yield hit["event_number"], hit
Exemplo n.º 12
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 def test_track_many(self):
     """
     Test MAUSTracking.track_many
     """
     tracking = MAUSTracking(self.config)
     hit_in = Hit.new_from_dict(
         {
             "mass": Common.pdg_pid_to_mass[13],
             "charge": 1.,
             "energy": 226.,
             "pid": -13,
             "pz": 200.
         }, "energy")
     hit_list_of_lists = tracking.track_many([hit_in] * 5)
     self.assertEqual(len(hit_list_of_lists), 5)
     for i, hit_list in enumerate(hit_list_of_lists):
         for j, hit_out in enumerate(hit_list):
             for key in [
                     "pid", "mass", "charge", "x", "y", "energy", "px",
                     "py", "pz"
             ]:
                 mess = "Failed on "+key+" "+\
                        str(hit_in[key])+", "+str(hit_out[key])
                 self.assertAlmostEqual(hit_in[key],
                                        hit_out[key],
                                        3,
                                        msg=mess)
             self.assertEqual(hit_out["z"], j * 1000.)
             self.assertEqual(hit_out["event_number"], i)
             self.assertEqual(hit_out["particle_number"], 1)
             self.assertEqual(hit_out["spill"], 0)
     self.assertEqual(tracking.last, hit_list_of_lists)
 def setUp(self):
     """Setup the EllipseClosedOrbitFinder"""
     self.num_turns = 5
     # x is conventional ellipse
     # y is phase advance = pi
     # t is phase advance = complex
     data = [[1.0, 0.5, 0.0, 0.0, 0.0,
              0.0], [-0.5, 0.75, 0.0, 0.0, 0.0, 0.0],
             [0.0, 0.0, 0.0, -1.0, 0.0, 0.0],
             [0.0, 0.0, 1.0, 0.0, 0.0, 0.0], [0.0, 0.0, 0.0, 0.0, 2.0, 2.0],
             [0.0, 0.0, 0.0, 0.0, 2.0, 2.5]]
     matrix = numpy.matrix(data)
     self.matrix_list = [matrix**(i + 1) for i in range(self.num_turns)]
     offset = numpy.matrix([10., 7., 0., 0., 0., 1000.])
     self.offset_list = [offset] * self.num_turns
     self.offset_in = numpy.matrix([10., 7., 0., 0., 0., 1000.])
     self.tracking = MatrixTracking(self.matrix_list, self.offset_list,
                                    self.offset_in)
     self.co = Hit.new_from_dict({
         'x': 10.,
         'px': 7.,
         'energy': 1000.,
         'pid': 2212,
         'mass': common.pdg_pid_to_mass[2212]
     })
     if abs(numpy.linalg.det(matrix) - 1.0) > 1e-9:
         raise ValueError("TM determinant should be 1, got "+\
                           str(numpy.linalg.det(matrix)))
Exemplo n.º 14
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 def make_hit_list(self, deltas):
     defaults = {
         'pz': self.pz,
         'mass': self.m_mu,
         'charge': 1.,
         'pid': -13,
         'z': self.z_start
     }
     hit_list = [Hit.new_from_dict(defaults, 'energy')]
     delta_keys = ['x', 'y', 'px', 'py']
     for parity in [-1., +1.]:
         for i in range(4):
             defaults[delta_keys[i]] = parity * deltas[i]
             hit_list.append(Hit.new_from_dict(defaults, 'energy'))
             defaults[delta_keys[i]] = 0.
     return hit_list
Exemplo n.º 15
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 def load_tof_sp(self, tof_sp, station):
     xerr = tof_sp.GetGlobalPosXErr()
     yerr = tof_sp.GetGlobalPosYErr()
     cov = [
         [0.0025, 0., 0., 0., 0., 0.],
         [0., xerr, 0., 0., 0., 0.],
         [0., 0., yerr, 0., 0., 0.],
         [0., 0., 0., 0., 0., 0.],
         [0., 0., 0., 0., 0., 0.],
         [0., 0., 0., 0., 0., 0.],
     ]
     sp_dict = {
         "x": tof_sp.GetGlobalPosX(),
         "y": tof_sp.GetGlobalPosY(),
         "z": tof_sp.GetGlobalPosZ(),
         "t": tof_sp.GetTime() + self.time_offsets[station],
     }
     loaded_sp = {
         "hit": Hit.new_from_dict(sp_dict),
         "detector": station,
         "covariance": cov,
         "dt": tof_sp.GetDt(),
         "charge_product": tof_sp.GetChargeProduct(),
         "charge": tof_sp.GetCharge(),
     }
     return loaded_sp
Exemplo n.º 16
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 def test_track_one(self):
     """
     Test MAUSTracking.track_one
     """
     # BUG: G4 does not reinitialise properly if run after test_tracking_init
     tracking = MAUSTracking(self.config, 99)
     hit_in = Hit.new_from_dict(
         {
             "mass": Common.pdg_pid_to_mass[2212],
             "charge": 1.,
             "energy": 10000.,
             "pid": 2212,
             "pz": 1.
         }, "pz")
     hit_list = tracking.track_one(hit_in)
     self.assertEqual(len(hit_list), 6)
     for i, hit_out in enumerate(hit_list):
         for key in [
                 "pid", "mass", "charge", "x", "y", "energy", "px", "py",
                 "pz"
         ]:
             mess = "Failed on "+key+" "+\
                    str(hit_in[key])+", "+str(hit_out[key])
             self.assertAlmostEqual(hit_in[key], hit_out[key], 3, msg=mess)
         self.assertEqual(hit_out["z"], i * 1000.)
         self.assertEqual(hit_out["event_number"], 0)
         self.assertEqual(hit_out["particle_number"], 1)
         self.assertEqual(hit_out["spill"], 0)
     hit_list = tracking.track_one(hit_in)
     self.assertEqual(len(hit_list), 6)
     for i, hit_out in enumerate(hit_list):
         self.assertEqual(hit_out["event_number"], 0)
         self.assertEqual(hit_out["particle_number"], 1)
         self.assertEqual(hit_out["spill"], 1)
     self.assertEqual(tracking.last, [hit_list])
Exemplo n.º 17
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 def read_one_line(self, line, station):
     words = line.split()
     hit_dict = {}
     for key in "pid", "mass", "charge":
         hit_dict[key] = self.ref[key]
     for i, key in enumerate(["x", "z", "y"]):
         hit_dict[key] = float(words[i + 1])
     for i, key in enumerate(["px", "pz", "py"]):
         hit_dict[key] = float(words[i + 4]) * self.ref["mass"]
     event = int(words[7])
     hit_dict["event_number"] = int(words[7])
     hit_dict["station"] = station
     x = hit_dict["x"]
     y = hit_dict["z"]
     px = hit_dict["px"]
     py = hit_dict["pz"]
     phi = math.atan2(y, x)
     hit_dict["t"] = float(words[9])
     hit_dict["x"] = +x * math.cos(phi) + y * math.sin(phi)
     hit_dict["z"] = -x * math.sin(phi) + y * math.cos(phi)
     hit_dict["px"] = +px * math.cos(phi) + py * math.sin(phi)
     # go through file line by line reading hit data
     hit_dict["pz"] = -px * math.sin(phi) + py * math.cos(phi)
     hit = Hit.new_from_dict(hit_dict, "energy")
     return event, hit
Exemplo n.º 18
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def calculate_da(row_data, da_key, n_points):
    axis1, axis2 = {"x_da": ("x", "x'"), "y_da": ("y", "y'")}[da_key]
    points = []
    mass = common.pdg_pid_to_mass[2212]
    hit_list = []
    for i, tmp_list in enumerate(row_data[da_key]):
        print(len(tmp_list), tmp_list[0])
        # hit_list[0] is the x/y offset in mm; hit_list[1] is the corresponding
        # set of probe hits
        if len(tmp_list[1]) < n_points:
            break
        hit_list = tmp_list
    hit_list = [Hit.new_from_dict(hit_dict) for hit_dict in hit_list[1]]
    points = numpy.array([[hit[axis1], hit[axis2]] for hit in hit_list])
    x_list = [hit[axis1] for hit in hit_list]
    print(min(x_list), max(x_list))
    y_list = [hit[axis2] for hit in hit_list]
    print(min(y_list), max(y_list))
    pz = hit_list[0]['pz']
    print(math.pi * (max(x_list) - min(x_list)) * (max(y_list) - min(y_list)) /
          4. * mass / pz)
    if len(points):
        geometric_acceptance = get_area(points) / math.pi
        # beta gamma * geometric emittance
        normalised_acceptance = geometric_acceptance * pz / mass
        return normalised_acceptance
    else:
        return 0.
Exemplo n.º 19
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 def test_make_hit(self):
     format_list = ['', 'x', 'y', 'z', 'energy', 'pid']
     format_units_dict = {
         'x': 'mm',
         'y': 'm',
         'z': 'cm',
         'energy': '',
         'pz': '',
         'pid': ''
     }
     filehandle = open(tmp_name(), 'w')
     if not filehandle:
         raise unittest.SkipTest("Failed to open filehandle")
     filehandle.write('-99. 1. 2. 3. 4. -13\n')
     filehandle.write('-99. 1. 2. 3. 4. -13\n')
     filehandle.write('-99. 1. 2. 3. 4.')
     filehandle.close()
     ref_hit = Hit.new_from_dict(
         {
             'x': 1.,
             'y': 2000.,
             'z': 30.,
             'energy': 4.,
             'pid': -13,
             'charge': 1.,
             'mass': common.pdg_pid_to_mass[13]
         }, 'pz')
     filehandle = open(tmp_name(), 'r')
     fac = UserHitFactory(format_list, format_units_dict, filehandle, 'pz')
     test_hit = fac.make_hit()
     self.assertEqual(test_hit, ref_hit)
     test_hit = fac.make_hit()
     self.assertEqual(test_hit, ref_hit)
     self.assertRaises(IOError, fac.make_hit)
     filehandle.close()
Exemplo n.º 20
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 def get_da(self, co_element, axis, seed_x):
     is_ref = abs(seed_x) < 1e-6
     self.setup_tracking(co_element)
     self.data = []
     co_delta = {"x": 0, "y": 0}
     iteration = 0
     while seed_x != None and iteration < self.max_iterations:
         co_delta[axis] = seed_x
         my_time = time.time()
         a_hit = Hit.new_from_dict(co_element["hits"][0])
         a_hit[axis] += seed_x
         try:
             hits = self.tracking.track_one(a_hit)
         except RuntimeError:
             sys.excepthook(*sys.exc_info())
             print("Never mind, keep on going...")
         self.data.append(
             [co_delta[axis], [a_hit.dict_from_hit() for a_hit in hits]])
         self.data = sorted(self.data)
         print("Axis", axis, "Seed", seed_x, "Number of cells hit",
               len(hits), "in",
               time.time() - my_time, "[s]")
         sys.stdout.flush()
         seed_x = self.new_seed()
         if is_ref:
             seed_x = None
         iteration += 1
     self.data = [list(item) for item in self.data]
     return self.data
Exemplo n.º 21
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 def setup_lookup(self, filename, n_cells):
     json_in = [json.loads(line) for line in open(filename).readlines()]
     my_list = []
     for json_line in json_in:
         hits = [Hit.new_from_dict(item) for item in json_line['hits']]
         r = numpy.mean([hit['r'] for hit in hits])
         p = numpy.mean([hit['p'] for hit in hits])
         tof_list = [
             hits[i + 1]['t'] - hits[i]['t']
             for i, hit in enumerate(hits[1:])
         ]
         mean_tof = numpy.mean(tof_list)
         tof_list = [
             tof for tof in tof_list if abs(tof - mean_tof) < mean_tof / 2.
         ]
         mean_tof = numpy.mean(tof_list)
         print("Mean tof", mean_tof, "rms tof", numpy.std(tof_list))
         t = mean_tof * n_cells
         my_list.append((r, p, t))
     my_list = sorted(my_list)
     r_list, p_list, t_list = list(zip(*my_list))
     for i, p in enumerate(p_list):
         print(i, format(p, "8.4g"), format(r_list[i], "8.4g"),
               format(t_list[i], "8.4g"))
     self.lookup_tof = interp1d(p_list, t_list, kind='cubic')
     self.lookup_tof.bounds_error = False
     self.lookup_tof.fill_value = 'extrapolate'
     self.lookup_radius = interp1d(p_list, r_list, kind='cubic')
     self.lookup_radius.bounds_error = False
     self.lookup_radius.fill_value = 'extrapolate'
Exemplo n.º 22
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 def load_closed_orbits(self):
     for i, ref_subs in enumerate(self.config.substitution_list):
         fin = open(self.config.run_control["output_dir"] +
                    "/find_rf_closed_orbits/find_rf_time_" + str(i) +
                    ".out")
         co_list = [json.loads(line) for line in fin.readlines()]
         et_list = []
         self.closed_orbit_list.append(
             [Hit.new_from_dict(item["hits"][0]) for item in co_list])
         for co in co_list:
             energy = co["hits"][0]["energy"] - self.mass
             hit_times = [hit["t"] for hit in co["hits"][1:]]
             delta_times = [
                 t1 - hit_times[i] for i, t1 in enumerate(hit_times[1:])
             ]
             mean_time = numpy.mean(delta_times)  #]
             delta_times = [
                 time for time in delta_times
                 if abs(time - mean_time) < mean_time / 2.
             ]
             print("One Cell Time", mean_time, "Sigma",
                   numpy.std(delta_times))
             mean_time = numpy.mean(
                 delta_times) * self.config.find_rf_parameters["n_cells"]
             et_list.append((energy, mean_time))
         self.energy_time_list.append(et_list)
Exemplo n.º 23
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 def load_scifi_space_points(self, scifi_event):
     space_points_out = []
     for space_point in scifi_event.spacepoints():
         # if we require triplets and space point is not a triplet, skip it
         if self.config.will_require_triplets and \
             space_point.get_channels().GetEntries() != 3:
             continue
         position = space_point.get_global_position()
         sp_dict = {
             "x": position.x(),
             "y": position.y(),
             "z": position.z(),
         }
         space_points_out.append({
             "hit":
             Hit.new_from_dict(sp_dict),
             "detector": ["tku_sp_", "tkd_sp_"][space_point.get_tracker()],
             "n_channels":
             space_point.get_channels().GetEntries(),
             "is_used":
             space_point.is_used(),
             "channels":
             [chan.get_channel() for chan in space_point.get_channels()],
             "npe": [chan.get_npe() for chan in space_point.get_channels()],
         })
         space_points_out[-1]["detector"] += str(space_point.get_station())
     return space_points_out
Exemplo n.º 24
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def load_json(file_name):
    print "Loading", file_name
    fin = open(file_name)
    data = [json.loads(line) for line in fin.readlines()]
    for item in data:
        item["seed"] = [Hit.new_from_dict(a_dict) for a_dict in item["seed"]]
    print "Loaded"
    return data
Exemplo n.º 25
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 def reference(self, hit_dict):
     """
     Generate a reference particle
     """
     hit = Hit.new_from_dict(hit_dict)
     hit["x"] = 0.
     hit["px"] = 0.
     return hit
Exemplo n.º 26
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 def setUp(self):
     offset_in = numpy.matrix(numpy.zeros([1, 6]))
     offset_out = [numpy.matrix(numpy.zeros([1, 6]))]
     matrices = [numpy.matrix(numpy.zeros([6, 6]))]
     for i in range(6):
         matrices[0][i, i] = i
     self.tracking = TimeoutTracking(matrices, offset_out, offset_in, 0)
     self.hit_list = [Hit.new_from_dict({'x':i}) for i in range(1000)]
def load_json(file_name):
    print "Loading", file_name
    fin = open(file_name)
    data = [json.loads(line) for line in fin.readlines()]
    for item in data:
        item["seed"] = [Hit.new_from_dict(a_dict) for a_dict in item["seed"]]
    print "Loaded"
    return data
Exemplo n.º 28
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def plot_one_phi(row_data, da_key, axis1, axis2, max_n_points, variables):
    global ROOT_OBJECTS
    hit_data = row_data[da_key]
    name = "phi_" + da_key + "_" + axis1 + " vs " + axis2
    title = get_title(variables)
    name += " " + title
    canvas = None
    tune_data = []
    area_data = []
    da_row = get_da_row(hit_data, max_n_points)
    print("Plot on phi")
    cholesky_canvas = common.make_root_canvas(name + "_cholesky")
    cholesky_canvas.SetCanvasSize(1000, 1000)
    delta = (da_row + 1) * 0.4 + 1.
    hist = common.make_root_histogram("", [-100.],
                                      "u",
                                      100, [-100.],
                                      "u'",
                                      100,
                                      xmin=-delta,
                                      xmax=+delta,
                                      ymin=-delta,
                                      ymax=+delta)
    hist.Draw()
    for i, hit_list in enumerate(hit_data[:da_row + 1]):
        hit_list = [Hit.new_from_dict(hit_dict) for hit_dict in hit_list[1]]
        finder = DPhiTuneFinder()
        finder.u = [hit[axis1] for hit in hit_list[1:]]
        finder.up = [hit[axis2] for hit in hit_list[1:]]
        area_src = numpy.array([[hit[axis1], hit[axis2]] for hit in hit_list])
        try:
            finder.get_tune()
            an_area = get_area(area_src)
        except Exception:
            print("Failed to unpack data for phi da plot")
            continue
        cholesky_canvas, hist, graph = finder.plot_cholesky_space(
            cholesky_canvas, 1. + i * 0.2)
        if i < da_row:
            color = ROOT.TColor(10000 + len(ROOT_OBJECTS), 0.,
                                1. - i * 1. / da_row, 0.)
            ROOT_OBJECTS.append(color)
            graph.SetMarkerColor(ROOT.kGreen)
        ROOT_OBJECTS += [hist, graph]
        tune_data += copy.deepcopy(finder.dphi)
        area_data += [an_area for i in finder.dphi]
        print("    Area", an_area, end=' ')
        print(" tune", numpy.mean(tune_data), "+/-", numpy.std(tune_data))
    canvas = common.make_root_canvas(name)
    canvas.Draw()
    hist, graph = common.make_root_graph(name, area_data, "Amplitude [mm]",
                                         tune_data, "Fractional tune")
    ROOT_OBJECTS += [hist, graph]
    hist.SetTitle(da_key)
    hist.Draw()
    graph.SetMarkerStyle(24)
    graph.Draw("p same")
    return canvas, cholesky_canvas
Exemplo n.º 29
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 def setUp(self):
     envelope_tool.set_share_dirs()
     self.red_dict = {'pid':13, 'px':1., 'py':2., 'pz':3., 
                      'x':-1, 'y':-2, 'z':-3}
     self.hit_red = Hit.new_from_dict(self.red_dict)
     self.hit_full = Hit.new_from_dict({'pid':13, 'px':1., 'py':2., 'pz':3.,
                                 'x':-1, 'y':-2, 'z':-3,
                                 'mass':common.pdg_pid_to_mass[13],
                                 'charge':common.pdg_pid_to_charge[13]},
                                 'energy')
     self.main_window = envelope_tool.MainWindow()
     self.main_window.window.get_frame("&Beam Setup", "button").Clicked()
     self.beam_setup = self.main_window.beam_setup
     self.cov = CovarianceMatrix()
     for i in range(1, 7):
         for j in range(1, 7):
             self.cov.set_element(i, j, i*j)
         self.cov.set_element(i, i, i*i+50.)
Exemplo n.º 30
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 def _reference(self, energy):
     """Generate a reference particle"""
     hit_dict = {}
     hit_dict["pid"] = 2212
     hit_dict["mass"] = common.pdg_pid_to_mass[2212]
     hit_dict["charge"] = 1
     hit_dict["x"] = 4600.
     hit_dict["kinetic_energy"] = energy
     return Hit.new_from_dict(hit_dict, "pz")
 def write(self):
     hit_list = []
     for item in self.tgt_dist:
         my_dict = {"mass": self.mu_mass, "pid": -13}
         for i, key in enumerate(self.keys):
             my_dict[key] = item[i]
         hit_list.append(Hit.new_from_dict(my_dict, "energy"))
     bunch = Bunch.new_from_hits(hit_list)
     bunch.hit_write_builtin(self.format, self.output_file)
     print "Writing bunch of length", len(bunch)
Exemplo n.º 32
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 def setUp(self):
     offset_in = numpy.matrix(numpy.zeros([1, 6]))
     offset_out = [numpy.matrix(numpy.zeros([1, 6]))]
     matrices = [numpy.matrix(numpy.zeros([6, 6]))]
     for i in range(6):
         matrices[0][i, i] = i
     self.tracking = TimeoutTracking(matrices, offset_out, offset_in, 0)
     self.hit_list = [Hit.new_from_dict({'x':1, 'y':2})]
     self.tracking_process = ThisNodeProcess(self.tracking)
     self.time_constant = 10
Exemplo n.º 33
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def reference(energy):
    """
    Generate a reference particle
    """
    hit_dict = {}
    hit_dict["pid"] = CONFIG.tracking["pdg_pid"]
    hit_dict["mass"] = common.pdg_pid_to_mass[abs(hit_dict["pid"])]
    hit_dict["charge"] = 1
    hit_dict["x"] = 0.
    hit_dict["kinetic_energy"] = energy
    return Hit.new_from_dict(hit_dict, "pz")
def get_hit(x, y, z, t, px, py, pz):
    hit_dict = {
        'mass':common.pdg_pid_to_mass[13],
        'pid':-13,
        'x':x,
        'y':y,
        'z':z,
        'px':px,
        'py':py,
        'pz':pz,
        't':0.
    }
    hit = Hit.new_from_dict(hit_dict, 'energy')
    return hit
Exemplo n.º 35
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 def test_beam_setup_cancel(self):
     """Test beam_setup cancel button"""
     test_matrix = self.beam_setup.get_matrix()
     test_ref = self.beam_setup.get_reference()
     self.beam_setup.window.get_frame("&Okay", "button").Clicked()
     self.main_window.window.get_frame("&Beam Setup", "button").Clicked()
     self.beam_setup = self.main_window.beam_setup
     self.beam_setup.set_matrix(self.cov)
     self.beam_setup.set_reference(self.hit_red)
     self.beam_setup.window.get_frame("&Cancel", "button").Clicked()
     for var in Hit.get_variables():
         self.assertAlmostEqual(self.main_window.lattice.ref_list[0][var],
                                test_ref[var], 3)
     self._ell_equal(self.main_window.lattice.ellipse_list[0], test_matrix)
Exemplo n.º 36
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    def process(self, json_spill_doc):
        """
        Generate primary particles for a spill.

        @param json_spill_doc unicode string containing the json spill

        - In counter mode, iterates over each beam and samples required number 
        of particles from the parent distribution.
        - In overwrite_existing or binomial mode, randomly samples from each of
        the available beam distributions according to the relative weight of
        each beam.

        @returns a string with the json spill
        """
        spill = {}
        try:
            spill = json.loads(json_spill_doc)
            spill = self.__process_check_spill(spill)
            new_particles = self.__process_gen_empty(spill)
            for index, particle in enumerate(new_particles):
                # if beam IO, then read hits from file and fill spill
                if (self.use_beam_file):
                    spill_hit = Hit.new_from_read_builtin(self.beam_file_format,
                                                        self.bm_fh)
                    primary = spill_hit.get_maus_dict('maus_json_primary')[0]
                    self.beam_seed = self.beam_seed + 1
                    primary["random_seed"] = self.beam_seed
                    primary['position']['x'] += \
                                            self.beam_file_insert_position['x']
                    primary['position']['y'] += \
                                            self.beam_file_insert_position['y']
                    primary['position']['z'] += \
                                            self.beam_file_insert_position['z']
                    particle["primary"] = primary
                else:
                    a_beam = self.__process_choose_beam(index)
                    particle["primary"] = a_beam.make_one_primary()
                if "spin" not in particle["primary"]:
                    particle["primary"]["spin"] = {"x":0., "y":0., "z":1.}
        except Exception: #pylint: disable=W0703
            ErrorHandler.HandleException(spill, self)
        return json.dumps(spill)
Exemplo n.º 37
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 def test_process_a_p_correlation(self):
     """Test beam.py a-p correlation routine"""
     self._beam.beam_matrix = numpy.diag([0.1]*6)
     self._beam.beam_mean = numpy.zeros((6))
     self._beam.a_p_correlation = {"momentum_variable":"pz", "magnitude":0.5}
     ref_pz = 200.
     hit1 = Hit.new_from_dict({"pz":ref_pz, "mass":105.658}, "energy")
     hit2  = hit1.deepcopy()
     self._beam._Beam__process_a_p_correlation(hit2)
     self.assertEqual(hit1, hit2)
     for matrix in [numpy.diag([0.1]*6), numpy.diag([0.2]*6)]:
         self._beam.beam_matrix = matrix
         hit2 = hit1.deepcopy()
         hit3 = hit1.deepcopy()
         hit2['x'] = 2.
         hit3['px'] = 2.
         self._beam._Beam__process_a_p_correlation(hit2)
         self._beam._Beam__process_a_p_correlation(hit3)
         self.assertAlmostEqual(hit2['pz'], hit3['pz'])
         self.assertAlmostEqual(hit2['pz']-ref_pz, ref_pz*0.5*4.*105.658**2)
Exemplo n.º 38
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    def get_reference(self):
        """
        Get the reference particle (reading from GUI elements)

        Returns an xboa.Hit.Hit object
        """
        ref_dict = {}
        for var in ["x", "y", "z", "px", "py", "pz"]: 
            var_dict = self.window.get_frame_dict(var, "named_text_entry")
            ref_dict[var] = float(var_dict["text_entry"].text_entry.GetText())
        pid_dict = self.window.get_frame_dict("pid", "named_text_entry")
        try:
            ref_dict["pid"] = int(pid_dict["text_entry"].text_entry.GetText())
            ref_dict["mass"] = common.pdg_pid_to_mass[abs(ref_dict["pid"])]
            ref_dict["charge"] = common.pdg_pid_to_charge[abs(ref_dict["pid"])]
        except KeyError:
            raise GuiError("Did not recognise reference particle pid")
        try:
            hit = Hit.new_from_dict(ref_dict, "energy")
        except Exception:
            raise GuiError("Failed to generate a reference particle")
        return hit
 def _read_probes(self):
     hit_dict_of_lists = {} # maps event number to a list of hit_dicts
     # loop over files in the glob, read events and sort by event number
     file_list = glob.glob(self.output_name)
     for file_name in file_list:
         fin = open(file_name)
         fin.readline()
         # go through file line by line reading hit data
         for line in fin.readlines():
             words = line.split()
             hit_dict = {}
             for key in "pid", "mass", "charge":
                 hit_dict[key] = self.ref[key]
             for i, key in enumerate(["x", "z", "y"]):
                 hit_dict[key] = float(words[i+1])
             for i, key in enumerate(["px", "pz", "py"]):
                 hit_dict[key] = float(words[i+4])*self.ref["mass"]
             event = int(words[7])
             hit_dict["event_number"] = int(words[7])
             hit_dict["station"] = int(words[8])
             hit_dict["t"] = float(words[9])
             hit_dict["x"] = (hit_dict["x"]**2.+hit_dict["z"]**2.)**0.5
             hit_dict["z"] = 0.
             if not event in hit_dict_of_lists:
                 hit_dict_of_lists[event] = []
             hit_dict_of_lists[event].append(Hit.new_from_dict(hit_dict, "energy"))
     # convert from a dict of list of hits to a list of list of hits
     # one list per event
     # each list contains one hit per station
     events = sorted(hit_dict_of_lists.keys())
     hit_list_of_lists = [hit_dict_of_lists[ev] for ev in events]
     # sort by time within each event
     for i, hit_list in enumerate(hit_list_of_lists):
         hit_list_of_lists[i] = sorted(hit_list, key = lambda hit: hit['t'])        
     self.last = hit_list_of_lists
     return hit_list_of_lists
Exemplo n.º 40
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    def setUp(self): # pylint: disable=C0103
        ref = Hit.new_from_dict({'pid':13, 'px':1., 'py':2., 'pz':3.,
                                'x':-1, 'y':-2, 'z':-3,
                                'mass':Common.pdg_pid_to_mass[13],
                                'charge':Common.pdg_pid_to_charge[13]},
                                'energy')
        self.ref_list = [ref]*4

        self.p_dict = {
          'e_t':1.,
          'b_t':2.,
          'e_l':3.,
          'b_l':4.,
          'a_t':5.,
          'a_l':6.,
          'l_t':7.,
          'd_x':8.,
          'dp_x':9.,
          'd_y':10.,
          'dp_y':11.,
        }
        self.penn_ellipses = [
            maus_cpp.covariance_matrix.create_from_penn_parameters(
                mass = ref['mass'],
                momentum = ref['p'],
                emittance_t = self.p_dict['e_t']+i*12.,
                beta_t = self.p_dict["b_t"]+i*12.,
                emittance_l = self.p_dict["e_l"]+i*12.,
                beta_l = self.p_dict["b_l"]+i*12.,
                alpha_t = self.p_dict["a_t"]+i*12.,
                alpha_l = self.p_dict["a_l"]+i*12.,
                charge = ref["charge"],
                bz = 0.,
                ltwiddle = self.p_dict["l_t"]+i*12.,
                dispersion_x = self.p_dict["d_x"]+i*12.,
                dispersion_prime_x = self.p_dict["dp_x"]+i*12.,
                dispersion_y = self.p_dict["d_y"]+i*12.,
                dispersion_prime_y = self.p_dict["dp_y"]+i*12.,
            ) for i in range(3)]
        self.t_dict = {
          'e_x':1.,
          'b_x':2.,
          'e_y':3.,
          'b_y':4.,
          'e_l':5.,
          'b_l':6.,
          'a_x':7.,
          'a_y':8.,
          'a_l':9.,
          'd_x':10.,
          'dp_x':11.,
          'd_y':12.,
          'dp_y':13.,
        }
        self.twiss_ellipses = [
            maus_cpp.covariance_matrix.create_from_twiss_parameters(
                mass = ref['mass'],
                momentum = ref['p'],
                emittance_x = self.t_dict['e_x']+i*14.,
                beta_x = self.t_dict["b_x"]+i*14.,
                emittance_y = self.t_dict['e_y']+i*14.,
                beta_y = self.t_dict["b_y"]+i*14.,
                emittance_l = self.t_dict["e_l"]+i*14.,
                beta_l = self.t_dict["b_l"]+i*14.,
                alpha_x = self.t_dict["a_x"]+i*14.,
                alpha_y = self.t_dict["a_y"]+i*14.,
                alpha_l = self.t_dict["a_l"]+i*14.,
                dispersion_x = self.t_dict["d_x"]+i*14.,
                dispersion_prime_x = self.t_dict["dp_x"]+i*14.,
                dispersion_y = self.t_dict["d_y"]+i*14.,
                dispersion_prime_y = self.t_dict["dp_y"]+i*14.,
            ) for i in range(3)]

        self.field_list = [{
          'field_type': 'Multipole',
          'position': {'x': 5.0, 'y': 4.0, 'z': 6.0},
          'aperture': {'x': 8.0, 'y': 7.0, 'z': 9.0},
          'outer': {'x': 10.0, 'y': 11.0, 'z': 12.0},
          'scale_factor': -0.5,
          'rotation': {'x':math.pi/6., 'y': 0.0, 'z': 0.0},
          'field_name': 'D1'
        }, {
          'field_type': 'Solenoid',
          'position': {'x': 5.0, 'y': 4.0, 'z': 6.0},
          'aperture': {'x': 8.0, 'y': 7.0, 'z': 9.0},
          'outer': {'x': 11.0, 'y': 12.0, 'z': 13.0},
          'scale_factor': 0.5,
          'rotation': {'x':0.0, 'y': math.pi/6., 'z': 0.0},
          'field_name': 'D2'
        }]