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#!/usr/bin/env python
import sys
import optparse
import time
import os
import multiprocessing
import detectors
import optics
import gpu
import g4gen
from fileio import root
import numpy as np
import math
import ROOT
def pick_seed():
'''Returns a seed for a random number generator selected using
a mixture of the current time and the current process ID.'''
return int(time.time()) ^ (os.getpid() << 16)
def info(type, value, tb):
if hasattr(sys, 'ps1') or not sys.stderr.isatty():
# we are in interactive mode or we don't have a tty-like
# device, so we call the default hook
sys.__excepthook__(type, value, tb)
else:
import traceback, pdb
# we are NOT in interactive mode, print the exception...
traceback.print_exception(type, value, tb)
print
# ...then start the debugger in post-mortem mode.
pdb.pm()
class GeneratorProcess(multiprocessing.Process):
def __init__(self, particle, energy, position, direction, nevents, material, seed=None):
multiprocessing.Process.__init__(self)
self.particle = particle
self.energy = energy
self.position = position
self.direction = direction
self.nevents = nevents
self.material = material
self.seed = seed
self.queue = multiprocessing.Queue()
self.daemon = True
def run(self):
print >>sys.stderr, 'Starting generator thread...'
generator = g4gen.G4Generator(self.material, seed=self.seed)
for i in xrange(self.nevents):
photons = generator.generate_photons(particle_name=self.particle,
total_energy=self.energy,
position=self.position,
direction=self.direction)
self.queue.put(photons)
# Allow profile decorator to exist, but do nothing if not running under kernprof
try:
profile = profile
except NameError:
profile = lambda x: x
@profile
def main():
parser = optparse.OptionParser('%prog')
parser.add_option('-b', type='int', dest='nbits', default=10)
parser.add_option('-j', type='int', dest='device', default=None)
parser.add_option('-n', type='int', dest='nblocks', default=64)
parser.add_option('-s', type='int', dest='seed', default=None,
help='Set random number generator seed')
parser.add_option('--detector', type='string', dest='detector', default='microlbne')
parser.add_option('--nevents', type='int', dest='nevents', default=100)
parser.add_option('--particle', type='string', dest='particle', default='e-')
parser.add_option('--energy', type='float', dest='energy', default=100.0)
parser.add_option('--pos', type='string', dest='pos', default='(0,0,0)')
parser.add_option('--dir', type='string', dest='dir', default='(1,0,0)')
parser.add_option('--save-photon-start', action='store_true',
dest='save_photon_start', default=False,
help='Save initial photon vertices to disk')
parser.add_option('--save-photon-stop', action='store_true',
dest='save_photon_stop', default=False,
help='Save final photon vertices to disk')
options, args = parser.parse_args()
if len(args) != 1:
print 'Must specify output filename!'
sys.exit(1)
else:
output_filename = args[0]
if options.nevents <= 0:
print '--nevents must be greater than 0!'
sys.exit(1)
position = np.array(eval(options.pos), dtype=float)
direction = np.array(eval(options.dir), dtype=float)
detector = detectors.find(options.detector)
if options.seed is None:
options.seed = pick_seed()
print >>sys.stderr, 'RNG seed:', options.seed
print >>sys.stderr, 'Creating generator...'
detector_material = optics.water_wcsim
generator_thread = GeneratorProcess(particle=options.particle,
energy=options.energy,
position=position,
direction=direction,
nevents=options.nevents,
material=detector_material,
seed=options.seed)
print >>sys.stderr, 'WARNING: ASSUMING DETECTOR IS WCSIM WATER!!'
# Do this now so we can get ahead of the photon propagation
print >>sys.stderr, 'Starting GEANT4 generator...'
generator_thread.start()
print >>sys.stderr, 'Creating BVH for detector "%s" with %d bits...' % (options.detector, options.nbits)
detector.build(bits=options.nbits)
print >>sys.stderr, 'Initializing GPU...'
gpu_worker = gpu.GPU(options.device)
print >>sys.stderr, 'Loading detector onto GPU...'
gpu_worker.load_geometry(detector)
print >>sys.stderr, 'Initializing random numbers generators...'
gpu_worker.setup_propagate(seed=options.seed)
gpu_worker.setup_daq(max(detector.pmtids))
# Create output file
writer = root.RootWriter(output_filename)
# Set generator info
writer.set_generated_particle(name=options.particle, position=position,
direction=direction, total_e=options.energy)
print >>sys.stderr, 'Starting simulation...'
start_sim = time.time()
nphotons = 0
for i in xrange(options.nevents):
photons = generator_thread.queue.get()
assert len(photons['pos']) > 0, 'GEANT4 generated event with no photons!'
nphotons += len(photons['pos'])
gpu_worker.load_photons(**photons)
gpu_worker.propagate()
gpu_worker.run_daq()
hits = gpu_worker.get_hits()
if options.save_photon_start:
photon_start = photons
else:
photon_start = None
if options.save_photon_stop:
photon_stop = gpu_worker.get_photons()
else:
photon_stop = None
writer.write_event(i, hits, photon_start=photon_start, photon_stop=photon_stop)
if i % 10 == 0:
print >>sys.stderr, "\rEvent:", i,
end_sim = time.time()
print >>sys.stderr, "\rEvent:", options.nevents - 1
writer.close()
print >>sys.stderr, 'Done. %1.1f events/sec, %1.0f photons/sec.' % (options.nevents/(end_sim - start_sim), nphotons/(end_sim - start_sim))
if __name__ == '__main__':
sys.excepthook = info
main()
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