def setup_models(args):
"""setup the experimental models"""
# Setup experimental models
master_phil = parse(
"""
include scope dials.test.algorithms.refinement.geometry_phil
""",
process_includes=True,
)
models = setup_geometry.Extract(master_phil, cmdline_args=args)
detector = models.detector
goniometer = models.goniometer
crystal = models.crystal
beam = models.beam
# Build a mock scan for a 180 degree sequence
sf = ScanFactory()
scan = sf.make_scan(
image_range=(1, 180),
exposure_times=0.1,
oscillation=(0, 1.0),
epochs=list(range(180)),
deg=True,
)
sequence_range = scan.get_oscillation_range(deg=False)
im_width = scan.get_oscillation(deg=False)[1]
assert sequence_range == (0.0, math.pi)
assert approx_equal(im_width, 1.0 * math.pi / 180.0)
experiments = ExperimentList()
experiments.append(
Experiment(
beam=beam,
detector=detector,
goniometer=goniometer,
scan=scan,
crystal=crystal,
imageset=None,
)
)
return experiments
DEG2RAD = pi / 180.0
RAD2DEG = 180.0 / pi
master_phil = parse("""
include scope dials.test.algorithms.refinement.geometry_phil
include scope dials.test.algorithms.refinement.minimiser_phil
""",
process_includes=True)
# make cell more oblique
args = [
"a.direction.close_to.sd=5", "b.direction.close_to.sd=5",
"c.direction.close_to.sd=5"
]
models = setup_geometry.Extract(master_phil, cmdline_args=args)
crystal = models.crystal
# a hexagonal crystal is a good test case for behaviour of oblique cells
do_hexagonal = True
if do_hexagonal:
import libtbx.load_env, os
from dxtbx.model.experiment_list import ExperimentListFactory
try:
dials_regression = libtbx.env.dist_path('dials_regression')
except KeyError, e:
print 'Skipped: dials_regression not configured'
exit(0)
data_dir = os.path.join(dials_regression, "refinement_test_data",
"multi_stills")
experiments_path = os.path.join(data_dir, "combined_experiments.json")
args = sys.argv[1:]
master_phil = parse("""
include scope dials.test.algorithms.refinement.geometry_phil
include scope dials.test.algorithms.refinement.minimiser_phil
""",
process_includes=True)
# build models, with a larger crystal than default in order to get enough
# reflections on the 'still' image
param = """
geometry.parameters.crystal.a.length.range=40 50;
geometry.parameters.crystal.b.length.range=40 50;
geometry.parameters.crystal.c.length.range=40 50;
geometry.parameters.random_seed = 42"""
models = setup_geometry.Extract(master_phil,
cmdline_args=args,
local_overrides=param)
crystal = models.crystal
mydetector = models.detector
mygonio = models.goniometer
mybeam = models.beam
# Build a mock scan for a 1.5 degree wedge. Only used for generating indices near
# the Ewald sphere
sf = ScanFactory()
myscan = sf.make_scan(image_range=(1, 1),
exposure_times=0.1,
oscillation=(0, 1.5),
epochs=range(1),
deg=True)
def test2():
"""Test on simulated data"""
# Get models for reflection prediction
import dials.test.algorithms.refinement.setup_geometry as setup_geometry
from libtbx.phil import parse
overrides = """geometry.parameters.crystal.a.length.value = 77
geometry.parameters.crystal.b.length.value = 77
geometry.parameters.crystal.c.length.value = 37"""
master_phil = parse(
"""
include scope dials.test.algorithms.refinement.geometry_phil
""",
process_includes=True,
)
from dxtbx.model import Crystal
models = setup_geometry.Extract(master_phil)
crystal = Crystal(
real_space_a=(2.62783398111729, -63.387215823567125,
-45.751375737456975),
real_space_b=(15.246640559660356, -44.48254330406616,
62.50501032727026),
real_space_c=(-76.67246874451074, -11.01804131886244,
10.861322446352226),
space_group_symbol="I 2 3",
)
detector = models.detector
goniometer = models.goniometer
beam = models.beam
# Build a mock scan for a 180 degree sweep
from dxtbx.model import ScanFactory
sf = ScanFactory()
scan = sf.make_scan(
image_range=(1, 1800),
exposure_times=0.1,
oscillation=(0, 0.1),
epochs=range(1800),
deg=True,
)
# Build an experiment list
from dxtbx.model.experiment_list import ExperimentList, Experiment
experiments = ExperimentList()
experiments.append(
Experiment(
beam=beam,
detector=detector,
goniometer=goniometer,
scan=scan,
crystal=crystal,
imageset=None,
))
# Generate all indices in a 1.5 Angstrom sphere
from dials.algorithms.spot_prediction import IndexGenerator
from cctbx.sgtbx import space_group, space_group_symbols
resolution = 1.5
index_generator = IndexGenerator(
crystal.get_unit_cell(),
space_group(space_group_symbols(1).hall()).type(),
resolution,
)
indices = index_generator.to_array()
# Predict rays within the sweep range
from dials.algorithms.refinement.prediction import ScansRayPredictor
sweep_range = scan.get_oscillation_range(deg=False)
ray_predictor = ScansRayPredictor(experiments, sweep_range)
obs_refs = ray_predictor(indices)
# Take only those rays that intersect the detector
from dials.algorithms.spot_prediction import ray_intersection
intersects = ray_intersection(detector, obs_refs)
obs_refs = obs_refs.select(intersects)
# Make a reflection predictor and re-predict for all these reflections. The
# result is the same, but we gain also the flags and xyzcal.px columns
from dials.algorithms.refinement.prediction import ExperimentsPredictor
ref_predictor = ExperimentsPredictor(experiments)
obs_refs["id"] = flex.int(len(obs_refs), 0)
obs_refs = ref_predictor(obs_refs)
# Copy 'observed' centroids from the predicted ones, applying sinusoidal
# offsets
obs_x, obs_y, obs_z = obs_refs["xyzcal.mm"].parts()
# obs_z is in range (0, pi). Calculate offsets for phi at twice that
# frequency
im_width = scan.get_oscillation(deg=False)[1]
z_off = flex.sin(2 * obs_z) * im_width
obs_z += z_off
# Calculate offsets for x
pixel_size = detector[0].get_pixel_size()
x_off = flex.sin(20 * obs_z) * pixel_size[0]
# Calculate offsets for y with a phase-shifted sine wave
from math import pi
y_off = flex.sin(4 * obs_z + pi / 6) * pixel_size[1]
# Incorporate the offsets into the 'observed' centroids
obs_z += z_off
obs_x += x_off
obs_y += y_off
obs_refs["xyzobs.mm.value"] = flex.vec3_double(obs_x, obs_y, obs_z)
# Now do centroid analysis of the residuals
results = CentroidAnalyser(obs_refs, debug=True)()
# FIXME this test shows that the suggested interval width heuristic is not
# yet robust. This simulation function seems a useful direction to proceed
# in though
raise RuntimeError("test2 failed")
print("OK")
return
def test(args=[]):
#############################
# Setup experimental models #
#############################
master_phil = parse(
"""
include scope dials.test.algorithms.refinement.geometry_phil
include scope dials.test.algorithms.refinement.minimiser_phil
""",
process_includes=True,
)
models = setup_geometry.Extract(master_phil, cmdline_args=args)
single_panel_detector = models.detector
mygonio = models.goniometer
mycrystal = models.crystal
mybeam = models.beam
# Make a 3x3 multi panel detector filling the same space as the existing
# single panel detector. Each panel of the multi-panel detector has pixels with
# 1/3 the length dimensions of the single panel.
multi_panel_detector = Detector()
for x in range(3):
for y in range(3):
new_panel = make_panel_in_array((x, y), single_panel_detector[0])
multi_panel_detector.add_panel(new_panel)
# Build a mock scan for a 180 degree sweep
sf = ScanFactory()
myscan = sf.make_scan(
image_range=(1, 1800),
exposure_times=0.1,
oscillation=(0, 0.1),
epochs=list(range(1800)),
deg=True,
)
sweep_range = myscan.get_oscillation_range(deg=False)
im_width = myscan.get_oscillation(deg=False)[1]
assert sweep_range == (0.0, pi)
assert approx_equal(im_width, 0.1 * pi / 180.0)
# Build ExperimentLists
experiments_single_panel = ExperimentList()
experiments_multi_panel = ExperimentList()
experiments_single_panel.append(
Experiment(
beam=mybeam,
detector=single_panel_detector,
goniometer=mygonio,
scan=myscan,
crystal=mycrystal,
imageset=None,
))
experiments_multi_panel.append(
Experiment(
beam=mybeam,
detector=multi_panel_detector,
goniometer=mygonio,
scan=myscan,
crystal=mycrystal,
imageset=None,
))
###########################
# Parameterise the models #
###########################
det_param = DetectorParameterisationSinglePanel(single_panel_detector)
s0_param = BeamParameterisation(mybeam, mygonio)
xlo_param = CrystalOrientationParameterisation(mycrystal)
xluc_param = CrystalUnitCellParameterisation(mycrystal)
multi_det_param = DetectorParameterisationMultiPanel(
multi_panel_detector, mybeam)
# Fix beam to the X-Z plane (imgCIF geometry), fix wavelength
s0_param.set_fixed([True, False, True])
# Fix crystal parameters
# xluc_param.set_fixed([True, True, True, True, True, True])
########################################################################
# Link model parameterisations together into a parameterisation of the #
# prediction equation #
########################################################################
pred_param = XYPhiPredictionParameterisation(experiments_single_panel,
[det_param], [s0_param],
[xlo_param], [xluc_param])
pred_param2 = XYPhiPredictionParameterisation(
experiments_multi_panel,
[multi_det_param],
[s0_param],
[xlo_param],
[xluc_param],
)
################################
# Apply known parameter shifts #
################################
# shift detectors by 1.0 mm each translation and 2 mrad each rotation
det_p_vals = det_param.get_param_vals()
p_vals = [
a + b for a, b in zip(det_p_vals, [1.0, 1.0, 1.0, 2.0, 2.0, 2.0])
]
det_param.set_param_vals(p_vals)
multi_det_p_vals = multi_det_param.get_param_vals()
p_vals = [
a + b for a, b in zip(multi_det_p_vals, [1.0, 1.0, 1.0, 2.0, 2.0, 2.0])
]
multi_det_param.set_param_vals(p_vals)
# shift beam by 2 mrad in free axis
s0_p_vals = s0_param.get_param_vals()
p_vals = list(s0_p_vals)
p_vals[0] += 2.0
s0_param.set_param_vals(p_vals)
# rotate crystal a bit (=2 mrad each rotation)
xlo_p_vals = xlo_param.get_param_vals()
p_vals = [a + b for a, b in zip(xlo_p_vals, [2.0, 2.0, 2.0])]
xlo_param.set_param_vals(p_vals)
# change unit cell a bit (=0.1 Angstrom length upsets, 0.1 degree of
# gamma angle)
xluc_p_vals = xluc_param.get_param_vals()
cell_params = mycrystal.get_unit_cell().parameters()
cell_params = [
a + b for a, b in zip(cell_params, [0.1, 0.1, 0.1, 0.0, 0.0, 0.1])
]
new_uc = unit_cell(cell_params)
newB = matrix.sqr(new_uc.fractionalization_matrix()).transpose()
S = symmetrize_reduce_enlarge(mycrystal.get_space_group())
S.set_orientation(orientation=newB)
X = tuple([e * 1.0e5 for e in S.forward_independent_parameters()])
xluc_param.set_param_vals(X)
#############################
# Generate some reflections #
#############################
# All indices in a 2.0 Angstrom sphere
resolution = 2.0
index_generator = IndexGenerator(
mycrystal.get_unit_cell(),
space_group(space_group_symbols(1).hall()).type(),
resolution,
)
indices = index_generator.to_array()
# for the reflection predictor, it doesn't matter which experiment list is
# passed, as the detector is not used
ref_predictor = ScansRayPredictor(experiments_single_panel, sweep_range)
# get two sets of identical reflections
obs_refs = ref_predictor(indices)
obs_refs2 = ref_predictor(indices)
for r1, r2 in zip(obs_refs, obs_refs2):
assert r1["s1"] == r2["s1"]
# get the panel intersections
sel = ray_intersection(single_panel_detector, obs_refs)
obs_refs = obs_refs.select(sel)
sel = ray_intersection(multi_panel_detector, obs_refs2)
obs_refs2 = obs_refs2.select(sel)
assert len(obs_refs) == len(obs_refs2)
# Set 'observed' centroids from the predicted ones
obs_refs["xyzobs.mm.value"] = obs_refs["xyzcal.mm"]
obs_refs2["xyzobs.mm.value"] = obs_refs2["xyzcal.mm"]
# Invent some variances for the centroid positions of the simulated data
im_width = 0.1 * pi / 180.0
px_size = single_panel_detector[0].get_pixel_size()
var_x = flex.double(len(obs_refs), (px_size[0] / 2.0)**2)
var_y = flex.double(len(obs_refs), (px_size[1] / 2.0)**2)
var_phi = flex.double(len(obs_refs), (im_width / 2.0)**2)
# set the variances and frame numbers
obs_refs["xyzobs.mm.variance"] = flex.vec3_double(var_x, var_y, var_phi)
obs_refs2["xyzobs.mm.variance"] = flex.vec3_double(var_x, var_y, var_phi)
# Add in flags and ID columns by copying into standard reflection tables
tmp = flex.reflection_table.empty_standard(len(obs_refs))
tmp.update(obs_refs)
obs_refs = tmp
tmp = flex.reflection_table.empty_standard(len(obs_refs2))
tmp.update(obs_refs2)
obs_refs2 = tmp
###############################
# Undo known parameter shifts #
###############################
s0_param.set_param_vals(s0_p_vals)
det_param.set_param_vals(det_p_vals)
multi_det_param.set_param_vals(det_p_vals)
xlo_param.set_param_vals(xlo_p_vals)
xluc_param.set_param_vals(xluc_p_vals)
#####################################
# Select reflections for refinement #
#####################################
refman = ReflectionManager(obs_refs, experiments_single_panel)
refman2 = ReflectionManager(obs_refs, experiments_multi_panel)
###############################
# Set up the target functions #
###############################
mytarget = LeastSquaresPositionalResidualWithRmsdCutoff(
experiments_single_panel,
ScansExperimentsPredictor(experiments_single_panel),
refman,
pred_param,
restraints_parameterisation=None,
)
mytarget2 = LeastSquaresPositionalResidualWithRmsdCutoff(
experiments_multi_panel,
ScansExperimentsPredictor(experiments_multi_panel),
refman2,
pred_param2,
restraints_parameterisation=None,
)
#################################
# Set up the refinement engines #
#################################
refiner = setup_minimiser.Extract(master_phil,
mytarget,
pred_param,
cmdline_args=args).refiner
refiner2 = setup_minimiser.Extract(master_phil,
mytarget2,
pred_param2,
cmdline_args=args).refiner
refiner.run()
# reset parameters and run refinement with the multi panel detector
s0_param.set_param_vals(s0_p_vals)
multi_det_param.set_param_vals(det_p_vals)
xlo_param.set_param_vals(xlo_p_vals)
xluc_param.set_param_vals(xluc_p_vals)
refiner2.run()
# same number of steps
assert refiner.get_num_steps() == refiner2.get_num_steps()
# same rmsds
for rmsd, rmsd2 in zip(refiner.history["rmsd"], refiner2.history["rmsd"]):
assert approx_equal(rmsd, rmsd2)
# same parameter values each step
for params, params2 in zip(refiner.history["parameter_vector"],
refiner.history["parameter_vector"]):
assert approx_equal(params, params2)
def test(args=[]):
# Python and cctbx imports
from math import pi
from scitbx import matrix
from scitbx.array_family import flex
from libtbx.phil import parse
from libtbx.test_utils import approx_equal
# Get module to build models using PHIL
import dials.test.algorithms.refinement.setup_geometry as setup_geometry
# We will set up a mock scan and a mock experiment list
from dxtbx.model import ScanFactory
from dxtbx.model.experiment_list import ExperimentList, Experiment
# Model parameterisations
from dials.algorithms.refinement.parameterisation.detector_parameters import \
DetectorParameterisationSinglePanel
from dials.algorithms.refinement.parameterisation.beam_parameters import \
BeamParameterisation
from dials.algorithms.refinement.parameterisation.crystal_parameters import \
CrystalOrientationParameterisation, CrystalUnitCellParameterisation
# Symmetry constrained parameterisation for the unit cell
from cctbx.uctbx import unit_cell
from rstbx.symmetry.constraints.parameter_reduction import \
symmetrize_reduce_enlarge
# Reflection prediction
from dials.algorithms.spot_prediction import IndexGenerator
from dials.algorithms.refinement.prediction import ScansRayPredictor, \
ExperimentsPredictor
from dials.algorithms.spot_prediction import ray_intersection
from cctbx.sgtbx import space_group, space_group_symbols
# Parameterisation of the prediction equation
from dials.algorithms.refinement.parameterisation.prediction_parameters import \
XYPhiPredictionParameterisation # implicit import
# Imports for the target function
from dials.algorithms.refinement.target import \
LeastSquaresPositionalResidualWithRmsdCutoff # implicit import
#############################
# Setup experimental models #
#############################
master_phil = parse("""
include scope dials.test.algorithms.refinement.geometry_phil
include scope dials.test.algorithms.refinement.minimiser_phil
""",
process_includes=True)
models = setup_geometry.Extract(
master_phil,
cmdline_args=args,
local_overrides="geometry.parameters.random_seed = 1")
crystal1 = models.crystal
models = setup_geometry.Extract(
master_phil,
cmdline_args=args,
local_overrides="geometry.parameters.random_seed = 2")
mydetector = models.detector
mygonio = models.goniometer
crystal2 = models.crystal
mybeam = models.beam
# Build a mock scan for a 180 degree sweep
sf = ScanFactory()
myscan = sf.make_scan(image_range=(1, 1800),
exposure_times=0.1,
oscillation=(0, 0.1),
epochs=range(1800),
deg=True)
sweep_range = myscan.get_oscillation_range(deg=False)
im_width = myscan.get_oscillation(deg=False)[1]
assert sweep_range == (0., pi)
assert approx_equal(im_width, 0.1 * pi / 180.)
# Build an experiment list
experiments = ExperimentList()
experiments.append(
Experiment(beam=mybeam,
detector=mydetector,
goniometer=mygonio,
scan=myscan,
crystal=crystal1,
imageset=None))
experiments.append(
Experiment(beam=mybeam,
detector=mydetector,
goniometer=mygonio,
scan=myscan,
crystal=crystal2,
imageset=None))
assert len(experiments.detectors()) == 1
##########################################################
# Parameterise the models (only for perturbing geometry) #
##########################################################
det_param = DetectorParameterisationSinglePanel(mydetector)
s0_param = BeamParameterisation(mybeam, mygonio)
xl1o_param = CrystalOrientationParameterisation(crystal1)
xl1uc_param = CrystalUnitCellParameterisation(crystal1)
xl2o_param = CrystalOrientationParameterisation(crystal2)
xl2uc_param = CrystalUnitCellParameterisation(crystal2)
# Fix beam to the X-Z plane (imgCIF geometry), fix wavelength
s0_param.set_fixed([True, False, True])
# Fix crystal parameters
#xluc_param.set_fixed([True, True, True, True, True, True])
########################################################################
# Link model parameterisations together into a parameterisation of the #
# prediction equation #
########################################################################
#pred_param = XYPhiPredictionParameterisation(experiments,
# [det_param], [s0_param], [xlo_param], [xluc_param])
################################
# Apply known parameter shifts #
################################
# shift detector by 1.0 mm each translation and 2 mrad each rotation
det_p_vals = det_param.get_param_vals()
p_vals = [a + b for a, b in zip(det_p_vals, [1.0, 1.0, 1.0, 2., 2., 2.])]
det_param.set_param_vals(p_vals)
# shift beam by 2 mrad in free axis
s0_p_vals = s0_param.get_param_vals()
p_vals = list(s0_p_vals)
p_vals[0] += 2.
s0_param.set_param_vals(p_vals)
# rotate crystal a bit (=2 mrad each rotation)
xlo_p_vals = []
for xlo in (xl1o_param, xl2o_param):
p_vals = xlo.get_param_vals()
xlo_p_vals.append(p_vals)
new_p_vals = [a + b for a, b in zip(p_vals, [2., 2., 2.])]
xlo.set_param_vals(new_p_vals)
# change unit cell a bit (=0.1 Angstrom length upsets, 0.1 degree of
# gamma angle)
xluc_p_vals = []
for xluc, xl in ((xl1uc_param, crystal1), ((xl2uc_param, crystal2))):
p_vals = xluc.get_param_vals()
xluc_p_vals.append(p_vals)
cell_params = xl.get_unit_cell().parameters()
cell_params = [
a + b for a, b in zip(cell_params, [0.1, 0.1, 0.1, 0.0, 0.0, 0.1])
]
new_uc = unit_cell(cell_params)
newB = matrix.sqr(new_uc.fractionalization_matrix()).transpose()
S = symmetrize_reduce_enlarge(xl.get_space_group())
S.set_orientation(orientation=newB)
X = tuple([e * 1.e5 for e in S.forward_independent_parameters()])
xluc.set_param_vals(X)
#############################
# Generate some reflections #
#############################
#print "Reflections will be generated with the following geometry:"
#print mybeam
#print mydetector
#print crystal1
#print crystal2
# All indices in a 2.0 Angstrom sphere for crystal1
resolution = 2.0
index_generator = IndexGenerator(
crystal1.get_unit_cell(),
space_group(space_group_symbols(1).hall()).type(), resolution)
indices1 = index_generator.to_array()
# All indices in a 2.0 Angstrom sphere for crystal2
resolution = 2.0
index_generator = IndexGenerator(
crystal2.get_unit_cell(),
space_group(space_group_symbols(1).hall()).type(), resolution)
indices2 = index_generator.to_array()
# Predict rays within the sweep range. Set experiment IDs
ray_predictor = ScansRayPredictor(experiments, sweep_range)
obs_refs1 = ray_predictor(indices1, experiment_id=0)
obs_refs1['id'] = flex.int(len(obs_refs1), 0)
obs_refs2 = ray_predictor(indices1, experiment_id=1)
obs_refs2['id'] = flex.int(len(obs_refs2), 1)
# Take only those rays that intersect the detector
intersects = ray_intersection(mydetector, obs_refs1)
obs_refs1 = obs_refs1.select(intersects)
intersects = ray_intersection(mydetector, obs_refs2)
obs_refs2 = obs_refs2.select(intersects)
# Make a reflection predictor and re-predict for all these reflections. The
# result is the same, but we gain also the flags and xyzcal.px columns
ref_predictor = ExperimentsPredictor(experiments)
obs_refs1 = ref_predictor(obs_refs1)
obs_refs2 = ref_predictor(obs_refs2)
# Set 'observed' centroids from the predicted ones
obs_refs1['xyzobs.mm.value'] = obs_refs1['xyzcal.mm']
obs_refs2['xyzobs.mm.value'] = obs_refs2['xyzcal.mm']
# Invent some variances for the centroid positions of the simulated data
im_width = 0.1 * pi / 180.
px_size = mydetector[0].get_pixel_size()
var_x = flex.double(len(obs_refs1), (px_size[0] / 2.)**2)
var_y = flex.double(len(obs_refs1), (px_size[1] / 2.)**2)
var_phi = flex.double(len(obs_refs1), (im_width / 2.)**2)
obs_refs1['xyzobs.mm.variance'] = flex.vec3_double(var_x, var_y, var_phi)
var_x = flex.double(len(obs_refs2), (px_size[0] / 2.)**2)
var_y = flex.double(len(obs_refs2), (px_size[1] / 2.)**2)
var_phi = flex.double(len(obs_refs2), (im_width / 2.)**2)
obs_refs2['xyzobs.mm.variance'] = flex.vec3_double(var_x, var_y, var_phi)
#print "Total number of reflections excited for crystal1", len(obs_refs1)
#print "Total number of reflections excited for crystal2", len(obs_refs2)
# concatenate reflection lists
obs_refs1.extend(obs_refs2)
obs_refs = obs_refs1
###############################
# Undo known parameter shifts #
###############################
s0_param.set_param_vals(s0_p_vals)
det_param.set_param_vals(det_p_vals)
xl1o_param.set_param_vals(xlo_p_vals[0])
xl2o_param.set_param_vals(xlo_p_vals[1])
xl1uc_param.set_param_vals(xluc_p_vals[0])
xl2uc_param.set_param_vals(xluc_p_vals[1])
#print "Initial values of parameters are"
#msg = "Parameters: " + "%.5f " * len(pred_param)
#print msg % tuple(pred_param.get_param_vals())
#print
# make a refiner
from dials.algorithms.refinement.refiner import phil_scope
params = phil_scope.fetch(source=parse('')).extract()
# in case we want a plot
params.refinement.refinery.journal.track_parameter_correlation = True
# scan static first
from dials.algorithms.refinement.refiner import RefinerFactory
refiner = RefinerFactory.from_parameters_data_experiments(params,
obs_refs,
experiments,
verbosity=0)
history = refiner.run()
# scan varying
params.refinement.parameterisation.scan_varying = True
refiner = RefinerFactory.from_parameters_data_experiments(params,
obs_refs,
experiments,
verbosity=0)
history = refiner.run()
from dials.algorithms.refinement.target import \
LeastSquaresPositionalResidualWithRmsdCutoff # implicit import
#############################
# Setup experimental models #
#############################
args = sys.argv[1:]
master_phil = parse("""
include scope dials.test.algorithms.refinement.geometry_phil
include scope dials.test.algorithms.refinement.minimiser_phil
""",
process_includes=True)
models = setup_geometry.Extract(
master_phil,
cmdline_args=args,
local_overrides="geometry.parameters.random_seed = 1")
crystal1 = models.crystal
models = setup_geometry.Extract(
master_phil,
cmdline_args=args,
local_overrides="geometry.parameters.random_seed = 2")
mydetector = models.detector
mygonio = models.goniometer
crystal2 = models.crystal
mybeam = models.beam
# Build a mock scan for a 180 degree sweep
def test():
# Python and cctbx imports
from math import pi
from scitbx import matrix
from scitbx.array_family import flex
from libtbx.phil import parse
from libtbx.test_utils import approx_equal
# Get modules to build models and minimiser using PHIL
import dials.test.algorithms.refinement.setup_geometry as setup_geometry
import dials.test.algorithms.refinement.setup_minimiser as setup_minimiser
# We will set up a mock scan and a mock experiment list
from dxtbx.model import ScanFactory
from dxtbx.model.experiment_list import ExperimentList, Experiment
# Model parameterisations
from dials.algorithms.refinement.parameterisation.detector_parameters import (
DetectorParameterisationSinglePanel, )
from dials.algorithms.refinement.parameterisation.beam_parameters import (
BeamParameterisation, )
from dials.algorithms.refinement.parameterisation.crystal_parameters import (
CrystalOrientationParameterisation,
CrystalUnitCellParameterisation,
)
# Symmetry constrained parameterisation for the unit cell
from cctbx.uctbx import unit_cell
from rstbx.symmetry.constraints.parameter_reduction import symmetrize_reduce_enlarge
# Reflection prediction
from dials.algorithms.spot_prediction import IndexGenerator, ray_intersection
from dials.algorithms.refinement.prediction.managed_predictors import (
ScansRayPredictor,
ScansExperimentsPredictor,
)
from cctbx.sgtbx import space_group, space_group_symbols
# Parameterisation of the prediction equation
from dials.algorithms.refinement.parameterisation.prediction_parameters import (
XYPhiPredictionParameterisation, )
# Imports for the target function
from dials.algorithms.refinement.target import (
LeastSquaresPositionalResidualWithRmsdCutoff, )
from dials.algorithms.refinement.reflection_manager import ReflectionManager
#############################
# Setup experimental models #
#############################
override = """geometry.parameters
{
beam.wavelength.random=False
beam.wavelength.value=1.0
beam.direction.inclination.random=False
crystal.a.length.random=False
crystal.a.length.value=12.0
crystal.a.direction.method=exactly
crystal.a.direction.exactly.direction=1.0 0.002 -0.004
crystal.b.length.random=False
crystal.b.length.value=14.0
crystal.b.direction.method=exactly
crystal.b.direction.exactly.direction=-0.002 1.0 0.002
crystal.c.length.random=False
crystal.c.length.value=13.0
crystal.c.direction.method=exactly
crystal.c.direction.exactly.direction=0.002 -0.004 1.0
detector.directions.method=exactly
detector.directions.exactly.dir1=0.99 0.002 -0.004
detector.directions.exactly.norm=0.002 -0.001 0.99
detector.centre.method=exactly
detector.centre.exactly.value=1.0 -0.5 199.0
}"""
master_phil = parse(
"""
include scope dials.test.algorithms.refinement.geometry_phil
include scope dials.test.algorithms.refinement.minimiser_phil
""",
process_includes=True,
)
models = setup_geometry.Extract(master_phil,
local_overrides=override,
verbose=False)
mydetector = models.detector
mygonio = models.goniometer
mycrystal = models.crystal
mybeam = models.beam
###########################
# Parameterise the models #
###########################
det_param = DetectorParameterisationSinglePanel(mydetector)
s0_param = BeamParameterisation(mybeam, mygonio)
xlo_param = CrystalOrientationParameterisation(mycrystal)
xluc_param = CrystalUnitCellParameterisation(mycrystal)
# Fix beam to the X-Z plane (imgCIF geometry), fix wavelength
s0_param.set_fixed([True, False, True])
########################################################################
# Link model parameterisations together into a parameterisation of the #
# prediction equation #
########################################################################
# Build a mock scan for a 180 degree sweep
sf = ScanFactory()
myscan = sf.make_scan(
image_range=(1, 1800),
exposure_times=0.1,
oscillation=(0, 0.1),
epochs=list(range(1800)),
deg=True,
)
# Build an ExperimentList
experiments = ExperimentList()
experiments.append(
Experiment(
beam=mybeam,
detector=mydetector,
goniometer=mygonio,
scan=myscan,
crystal=mycrystal,
imageset=None,
))
# Create the PredictionParameterisation
pred_param = XYPhiPredictionParameterisation(experiments, [det_param],
[s0_param], [xlo_param],
[xluc_param])
################################
# Apply known parameter shifts #
################################
# shift detector by 1.0 mm each translation and 4 mrad each rotation
det_p_vals = det_param.get_param_vals()
p_vals = [
a + b for a, b in zip(det_p_vals, [1.0, 1.0, 1.0, 4.0, 4.0, 4.0])
]
det_param.set_param_vals(p_vals)
# shift beam by 4 mrad in free axis
s0_p_vals = s0_param.get_param_vals()
p_vals = list(s0_p_vals)
p_vals[0] += 4.0
s0_param.set_param_vals(p_vals)
# rotate crystal a bit (=3 mrad each rotation)
xlo_p_vals = xlo_param.get_param_vals()
p_vals = [a + b for a, b in zip(xlo_p_vals, [3.0, 3.0, 3.0])]
xlo_param.set_param_vals(p_vals)
# change unit cell a bit (=0.1 Angstrom length upsets, 0.1 degree of
# alpha and beta angles)
xluc_p_vals = xluc_param.get_param_vals()
cell_params = mycrystal.get_unit_cell().parameters()
cell_params = [
a + b for a, b in zip(cell_params, [0.1, -0.1, 0.1, 0.1, -0.1, 0.0])
]
new_uc = unit_cell(cell_params)
newB = matrix.sqr(new_uc.fractionalization_matrix()).transpose()
S = symmetrize_reduce_enlarge(mycrystal.get_space_group())
S.set_orientation(orientation=newB)
X = tuple([e * 1.0e5 for e in S.forward_independent_parameters()])
xluc_param.set_param_vals(X)
#############################
# Generate some reflections #
#############################
# All indices in a 2.0 Angstrom sphere
resolution = 2.0
index_generator = IndexGenerator(
mycrystal.get_unit_cell(),
space_group(space_group_symbols(1).hall()).type(),
resolution,
)
indices = index_generator.to_array()
sweep_range = myscan.get_oscillation_range(deg=False)
im_width = myscan.get_oscillation(deg=False)[1]
assert sweep_range == (0.0, pi)
assert approx_equal(im_width, 0.1 * pi / 180.0)
# Predict rays within the sweep range
ray_predictor = ScansRayPredictor(experiments, sweep_range)
obs_refs = ray_predictor(indices)
# Take only those rays that intersect the detector
intersects = ray_intersection(mydetector, obs_refs)
obs_refs = obs_refs.select(intersects)
# Make a reflection predictor and re-predict for all these reflections. The
# result is the same, but we gain also the flags and xyzcal.px columns
ref_predictor = ScansExperimentsPredictor(experiments)
obs_refs["id"] = flex.int(len(obs_refs), 0)
obs_refs = ref_predictor(obs_refs)
# Set 'observed' centroids from the predicted ones
obs_refs["xyzobs.mm.value"] = obs_refs["xyzcal.mm"]
# Invent some variances for the centroid positions of the simulated data
im_width = 0.1 * pi / 180.0
px_size = mydetector[0].get_pixel_size()
var_x = flex.double(len(obs_refs), (px_size[0] / 2.0)**2)
var_y = flex.double(len(obs_refs), (px_size[1] / 2.0)**2)
var_phi = flex.double(len(obs_refs), (im_width / 2.0)**2)
obs_refs["xyzobs.mm.variance"] = flex.vec3_double(var_x, var_y, var_phi)
# The total number of observations should be 1128
assert len(obs_refs) == 1128
###############################
# Undo known parameter shifts #
###############################
s0_param.set_param_vals(s0_p_vals)
det_param.set_param_vals(det_p_vals)
xlo_param.set_param_vals(xlo_p_vals)
xluc_param.set_param_vals(xluc_p_vals)
#####################################
# Select reflections for refinement #
#####################################
refman = ReflectionManager(obs_refs,
experiments,
outlier_detector=None,
close_to_spindle_cutoff=0.1)
##############################
# Set up the target function #
##############################
# The current 'achieved' criterion compares RMSD against 1/3 the pixel size and
# 1/3 the image width in radians. For the simulated data, these are just made up
mytarget = LeastSquaresPositionalResidualWithRmsdCutoff(
experiments,
ref_predictor,
refman,
pred_param,
restraints_parameterisation=None)
######################################
# Set up the LSTBX refinement engine #
######################################
overrides = """minimiser.parameters.engine=GaussNewton
minimiser.parameters.logfile=None"""
refiner = setup_minimiser.Extract(master_phil,
mytarget,
pred_param,
local_overrides=overrides).refiner
refiner.run()
assert mytarget.achieved()
assert refiner.get_num_steps() == 1
assert approx_equal(
mytarget.rmsds(),
(0.00508252354876, 0.00420954552156, 8.97303428289e-05))
###############################
# Undo known parameter shifts #
###############################
s0_param.set_param_vals(s0_p_vals)
det_param.set_param_vals(det_p_vals)
xlo_param.set_param_vals(xlo_p_vals)
xluc_param.set_param_vals(xluc_p_vals)
######################################################
# Set up the LBFGS with curvatures refinement engine #
######################################################
overrides = """minimiser.parameters.engine=LBFGScurvs
minimiser.parameters.logfile=None"""
refiner = setup_minimiser.Extract(master_phil,
mytarget,
pred_param,
local_overrides=overrides).refiner
refiner.run()
assert mytarget.achieved()
assert refiner.get_num_steps() == 9
assert approx_equal(mytarget.rmsds(),
(0.0558857700305, 0.0333446685335, 0.000347402754278))
def test(dials_regression):
from scitbx import matrix
from libtbx.phil import parse
from libtbx.test_utils import approx_equal
from scitbx.array_family import flex
# Get modules to build models and minimiser using PHIL
from dials.test.algorithms.refinement import setup_geometry
from dials.test.algorithms.refinement import setup_minimiser
from dials.algorithms.refinement.parameterisation.crystal_parameters import (
CrystalOrientationParameterisation,
CrystalUnitCellParameterisation,
)
# Symmetry constrained parameterisation for the unit cell
from cctbx.uctbx import unit_cell
from rstbx.symmetry.constraints.parameter_reduction import symmetrize_reduce_enlarge
DEG2RAD = math.pi / 180.0
RAD2DEG = 180.0 / math.pi
master_phil = parse(
"""
include scope dials.test.algorithms.refinement.geometry_phil
include scope dials.test.algorithms.refinement.minimiser_phil
""",
process_includes=True,
)
# make cell more oblique
args = [
"a.direction.close_to.sd=5",
"b.direction.close_to.sd=5",
"c.direction.close_to.sd=5",
]
models = setup_geometry.Extract(master_phil, cmdline_args=args)
crystal = models.crystal
# a hexagonal crystal is a good test case for behaviour of oblique cells
do_hexagonal = True
if do_hexagonal:
from dxtbx.model.experiment_list import ExperimentListFactory
experiments = ExperimentListFactory.from_json_file(
os.path.join(
dials_regression,
"refinement_test_data",
"multi_stills",
"combined_experiments.json",
),
check_format=False,
)
crystal = experiments[0].crystal
# derive finite difference gradients of various quantities wrt each param
def check_fd_gradients(parameterisation):
mp = parameterisation
p_vals = mp.get_param_vals()
deltas = [1.0e-7 for p in p_vals]
assert len(deltas) == len(p_vals)
fd_grad = []
# get matrix to unset rotations of unit cell vectors
Ut = matrix.sqr(mp.get_model().get_U()).transpose()
for i, delta in enumerate(deltas):
val = p_vals[i]
p_vals[i] -= delta / 2.0
mp.set_param_vals(p_vals)
rev_uc = mp.get_model().get_unit_cell().parameters()
rev_vec = mp.get_model().get_real_space_vectors()
rev_vec = [Ut * vec for vec in rev_vec]
rev_B = matrix.sqr(mp.get_model().get_B())
rev_O = rev_B.transpose().inverse()
p_vals[i] += delta
mp.set_param_vals(p_vals)
fwd_uc = mp.get_model().get_unit_cell().parameters()
fwd_vec = mp.get_model().get_real_space_vectors()
fwd_vec = [Ut * vec for vec in fwd_vec]
fwd_B = matrix.sqr(mp.get_model().get_B())
fwd_O = fwd_B.transpose().inverse()
fd_uc = [(f - r) / delta for f, r in zip(fwd_uc, rev_uc)]
fd_vec = [(f - r) / delta for f, r in zip(fwd_vec, rev_vec)]
fd_B = (fwd_B - rev_B) / delta
fd_O = (fwd_O - rev_O) / delta
fd_grad.append({
"da_dp": fd_uc[0],
"db_dp": fd_uc[1],
"dc_dp": fd_uc[2],
"daa_dp": fd_uc[3],
"dbb_dp": fd_uc[4],
"dcc_dp": fd_uc[5],
"davec_dp": fd_vec[0],
"dbvec_dp": fd_vec[1],
"dcvec_dp": fd_vec[2],
"dB_dp": fd_B,
"dO_dp": fd_O,
})
p_vals[i] = val
# return to the initial state
mp.set_param_vals(p_vals)
return fd_grad
xlo_param = CrystalOrientationParameterisation(crystal)
xluc_param = CrystalUnitCellParameterisation(crystal)
from dials.algorithms.refinement.restraints.restraints import SingleUnitCellTie
uct = SingleUnitCellTie(xluc_param, [None] * 6, [None] * 6)
from scitbx.math import angle_derivative_wrt_vectors
B = matrix.sqr(crystal.get_B())
O = (B.transpose()).inverse()
a, b, c, aa, bb, cc = crystal.get_unit_cell().parameters()
aa *= DEG2RAD
bb *= DEG2RAD
cc *= DEG2RAD
Ut = matrix.sqr(crystal.get_U()).transpose()
avec, bvec, cvec = [Ut * vec for vec in crystal.get_real_space_vectors()]
# calculate d[B^T]/dp
dB_dp = xluc_param.get_ds_dp()
dBT_dp = [dB.transpose() for dB in dB_dp]
# calculate d[O]/dp
dO_dp = [-O * dBT * O for dBT in dBT_dp]
# function to get analytical derivative of angles wrt vectors
def dangle(u, v):
return [matrix.col(e) for e in angle_derivative_wrt_vectors(u, v)]
dalpha_db, dalpha_dc = dangle(bvec, cvec)
dbeta_da, dbeta_dc = dangle(avec, cvec)
dgamma_da, dgamma_db = dangle(avec, bvec)
# get all FD derivatives
fd_grad = check_fd_gradients(xluc_param)
# look at each parameter
for i, dO in enumerate(dO_dp):
# print
# print "***** PARAMETER {0} *****".format(i)
# print "dB_dp analytical"
# print dB_dp[i]
# print "dB_dp FD"
# print fd_grad[i]['dB_dp']
# print
# dB_dp is good. What about dO_dp?
# print "O MATRIX"
# print "dO_dp analytical"
# print dO.round(6)
# print "dO_dp FD"
# print fd_grad[i]['dO_dp'].round(6)
# print
assert approx_equal(dO, fd_grad[i]["dO_dp"])
# extract derivatives of each unit cell vector wrt p
dav_dp, dbv_dp, dcv_dp = dO.transpose().as_list_of_lists()
dav_dp = matrix.col(dav_dp)
dbv_dp = matrix.col(dbv_dp)
dcv_dp = matrix.col(dcv_dp)
# check these are correct vs FD
# print "CELL VECTORS"
# diff = dav_dp - fd_grad[i]['davec_dp']
# print 2 * diff.length() / (dav_dp.length() + fd_grad[i]['davec_dp'].length()) * 100
# print 'davec_dp analytical: {0:.5f} {1:.5f} {2:.5f}'.format(*dav_dp.elems)
# print 'davec_dp finite diff: {0:.5f} {1:.5f} {2:.5f}'.format(*fd_grad[i]['davec_dp'].elems)
assert approx_equal(dav_dp, fd_grad[i]["davec_dp"])
# diff = dbv_dp - fd_grad[i]['dbvec_dp']
# print 2 * diff.length() / (dbv_dp.length() + fd_grad[i]['dbvec_dp'].length()) * 100
# print 'dbvec_dp analytical: {0:.5f} {1:.5f} {2:.5f}'.format(*dbv_dp.elems)
# print 'dbvec_dp finite diff: {0:.5f} {1:.5f} {2:.5f}'.format(*fd_grad[i]['dbvec_dp'].elems)
assert approx_equal(dbv_dp, fd_grad[i]["dbvec_dp"])
# diff = dcv_dp - fd_grad[i]['dcvec_dp']
# print 2 * diff.length() / (dcv_dp.length() + fd_grad[i]['dcvec_dp'].length()) * 100
# print 'dcvec_dp analytical: {0:.5f} {1:.5f} {2:.5f}'.format(*dcv_dp.elems)
# print 'dcvec_dp finite diff: {0:.5f} {1:.5f} {2:.5f}'.format(*fd_grad[i]['dcvec_dp'].elems)
# print
assert approx_equal(dcv_dp, fd_grad[i]["dcvec_dp"])
# print "CELL LENGTHS"
da_dp = 1.0 / a * avec.dot(dav_dp)
# print "d[a]/dp{2} analytical: {0:.5f} FD: {1:.5f}".format(da_dp, fd_grad[i]['da_dp'], i)
assert approx_equal(da_dp, fd_grad[i]["da_dp"])
db_dp = 1.0 / b * bvec.dot(dbv_dp)
# print "d[b]/dp{2} analytical: {0:.5f} FD: {1:.5f}".format(db_dp, fd_grad[i]['db_dp'], i)
assert approx_equal(db_dp, fd_grad[i]["db_dp"])
dc_dp = 1.0 / c * cvec.dot(dcv_dp)
# print "d[c]/dp{2} analytical: {0:.5f} FD: {1:.5f}".format(dc_dp, fd_grad[i]['dc_dp'], i)
assert approx_equal(dc_dp, fd_grad[i]["dc_dp"])
# print
# print "CELL ANGLES"
daa_dp = RAD2DEG * (dbv_dp.dot(dalpha_db) + dcv_dp.dot(dalpha_dc))
dbb_dp = RAD2DEG * (dav_dp.dot(dbeta_da) + dcv_dp.dot(dbeta_dc))
dcc_dp = RAD2DEG * (dav_dp.dot(dgamma_da) + dbv_dp.dot(dgamma_db))
# print "d[alpha]/dp{2} analytical: {0:.5f} FD: {1:.5f}".format(daa_dp, fd_grad[i]['daa_dp'], i)
# print "d[beta]/dp{2} analytical: {0:.5f} FD: {1:.5f}".format(dbb_dp, fd_grad[i]['dbb_dp'], i)
# print "d[gamma]/dp{2} analytical: {0:.5f} FD: {1:.5f}".format(dcc_dp, fd_grad[i]['dcc_dp'], i)
assert approx_equal(daa_dp, fd_grad[i]["daa_dp"])
assert approx_equal(dbb_dp, fd_grad[i]["dbb_dp"])
assert approx_equal(dcc_dp, fd_grad[i]["dcc_dp"])
def test(args=[]):
# Python and cctbx imports
from math import pi
from scitbx import matrix
from libtbx.phil import parse
from libtbx.test_utils import approx_equal
# Import for surgery on reflection_tables
from dials.array_family import flex
# Get module to build models using PHIL
import dials.test.algorithms.refinement.setup_geometry as setup_geometry
# We will set up a mock scan and a mock experiment list
from dxtbx.model import ScanFactory
from dxtbx.model.experiment_list import ExperimentList, Experiment
# Crystal parameterisations
from dials.algorithms.refinement.parameterisation.crystal_parameters import (
CrystalOrientationParameterisation,
CrystalUnitCellParameterisation,
)
# Symmetry constrained parameterisation for the unit cell
from cctbx.uctbx import unit_cell
from rstbx.symmetry.constraints.parameter_reduction import symmetrize_reduce_enlarge
# Reflection prediction
from dials.algorithms.spot_prediction import IndexGenerator
from dials.algorithms.refinement.prediction.managed_predictors import (
ScansRayPredictor,
StillsExperimentsPredictor,
)
from dials.algorithms.spot_prediction import ray_intersection
from cctbx.sgtbx import space_group, space_group_symbols
#############################
# Setup experimental models #
#############################
master_phil = parse(
"""
include scope dials.test.algorithms.refinement.geometry_phil
include scope dials.test.algorithms.refinement.minimiser_phil
""",
process_includes=True,
)
# build models, with a larger crystal than default in order to get enough
# reflections on the 'still' image
param = """
geometry.parameters.crystal.a.length.range=40 50;
geometry.parameters.crystal.b.length.range=40 50;
geometry.parameters.crystal.c.length.range=40 50;
geometry.parameters.random_seed = 42"""
models = setup_geometry.Extract(master_phil,
cmdline_args=args,
local_overrides=param)
crystal = models.crystal
mydetector = models.detector
mygonio = models.goniometer
mybeam = models.beam
# Build a mock scan for a 1.5 degree wedge. Only used for generating indices near
# the Ewald sphere
sf = ScanFactory()
myscan = sf.make_scan(
image_range=(1, 1),
exposure_times=0.1,
oscillation=(0, 1.5),
epochs=list(range(1)),
deg=True,
)
sweep_range = myscan.get_oscillation_range(deg=False)
im_width = myscan.get_oscillation(deg=False)[1]
assert approx_equal(im_width, 1.5 * pi / 180.0)
# Build experiment lists
stills_experiments = ExperimentList()
stills_experiments.append(
Experiment(beam=mybeam,
detector=mydetector,
crystal=crystal,
imageset=None))
scans_experiments = ExperimentList()
scans_experiments.append(
Experiment(
beam=mybeam,
detector=mydetector,
crystal=crystal,
goniometer=mygonio,
scan=myscan,
imageset=None,
))
##########################################################
# Parameterise the models (only for perturbing geometry) #
##########################################################
xlo_param = CrystalOrientationParameterisation(crystal)
xluc_param = CrystalUnitCellParameterisation(crystal)
################################
# Apply known parameter shifts #
################################
# rotate crystal (=5 mrad each rotation)
xlo_p_vals = []
p_vals = xlo_param.get_param_vals()
xlo_p_vals.append(p_vals)
new_p_vals = [a + b for a, b in zip(p_vals, [5.0, 5.0, 5.0])]
xlo_param.set_param_vals(new_p_vals)
# change unit cell (=1.0 Angstrom length upsets, 0.5 degree of
# gamma angle)
xluc_p_vals = []
p_vals = xluc_param.get_param_vals()
xluc_p_vals.append(p_vals)
cell_params = crystal.get_unit_cell().parameters()
cell_params = [
a + b for a, b in zip(cell_params, [1.0, 1.0, -1.0, 0.0, 0.0, 0.5])
]
new_uc = unit_cell(cell_params)
newB = matrix.sqr(new_uc.fractionalization_matrix()).transpose()
S = symmetrize_reduce_enlarge(crystal.get_space_group())
S.set_orientation(orientation=newB)
X = tuple([e * 1.0e5 for e in S.forward_independent_parameters()])
xluc_param.set_param_vals(X)
# keep track of the target crystal model to compare with refined
from copy import deepcopy
target_crystal = deepcopy(crystal)
#############################
# Generate some reflections #
#############################
# All indices in a 2.0 Angstrom sphere for crystal
resolution = 2.0
index_generator = IndexGenerator(
crystal.get_unit_cell(),
space_group(space_group_symbols(1).hall()).type(),
resolution,
)
indices = index_generator.to_array()
# Build a ray predictor and predict rays close to the Ewald sphere by using
# the narrow rotation scan
ref_predictor = ScansRayPredictor(scans_experiments, sweep_range)
obs_refs = ref_predictor(indices, experiment_id=0)
# Take only those rays that intersect the detector
intersects = ray_intersection(mydetector, obs_refs)
obs_refs = obs_refs.select(intersects)
# Add in flags and ID columns by copying into standard reflection table
tmp = flex.reflection_table.empty_standard(len(obs_refs))
tmp.update(obs_refs)
obs_refs = tmp
# Invent some variances for the centroid positions of the simulated data
im_width = 0.1 * pi / 180.0
px_size = mydetector[0].get_pixel_size()
var_x = flex.double(len(obs_refs), (px_size[0] / 2.0)**2)
var_y = flex.double(len(obs_refs), (px_size[1] / 2.0)**2)
var_phi = flex.double(len(obs_refs), (im_width / 2.0)**2)
obs_refs["xyzobs.mm.variance"] = flex.vec3_double(var_x, var_y, var_phi)
# Re-predict using the stills reflection predictor
stills_ref_predictor = StillsExperimentsPredictor(stills_experiments)
obs_refs_stills = stills_ref_predictor(obs_refs)
# Set 'observed' centroids from the predicted ones
obs_refs_stills["xyzobs.mm.value"] = obs_refs_stills["xyzcal.mm"]
###############################
# Undo known parameter shifts #
###############################
xlo_param.set_param_vals(xlo_p_vals[0])
xluc_param.set_param_vals(xluc_p_vals[0])
# make a refiner
from dials.algorithms.refinement.refiner import phil_scope
params = phil_scope.fetch(source=parse("")).extract()
# Change this to get a plot
do_plot = False
if do_plot:
params.refinement.refinery.journal.track_parameter_correlation = True
from dials.algorithms.refinement.refiner import RefinerFactory
# decrease bin_size_fraction to terminate on RMSD convergence
params.refinement.target.bin_size_fraction = 0.01
params.refinement.parameterisation.beam.fix = "all"
params.refinement.parameterisation.detector.fix = "all"
refiner = RefinerFactory.from_parameters_data_experiments(
params, obs_refs_stills, stills_experiments)
# run refinement
history = refiner.run()
# regression tests
assert len(history["rmsd"]) == 9
refined_crystal = refiner.get_experiments()[0].crystal
uc1 = refined_crystal.get_unit_cell()
uc2 = target_crystal.get_unit_cell()
assert uc1.is_similar_to(uc2)
if do_plot:
plt = refiner.parameter_correlation_plot(
len(history["parameter_correlation"]) - 1)
plt.show()
def init_test():
models = setup_geometry.Extract(master_phil)
single_panel_detector = models.detector
gonio = models.goniometer
crystal = models.crystal
beam = models.beam
# Make a 3x3 multi panel detector filling the same space as the existing
# single panel detector. Each panel of the multi-panel detector has pixels
# with 1/3 the length dimensions of the single panel.
multi_panel_detector = Detector()
for x in range(3):
for y in range(3):
new_panel = make_panel_in_array((x, y), single_panel_detector[0])
multi_panel_detector.add_panel(new_panel)
# Build a mock scan for a 180 degree sequence
sf = ScanFactory()
scan = sf.make_scan(
image_range=(1, 1800),
exposure_times=0.1,
oscillation=(0, 0.1),
epochs=list(range(1800)),
deg=True,
)
sequence_range = scan.get_oscillation_range(deg=False)
im_width = scan.get_oscillation(deg=False)[1]
assert sequence_range == (0.0, pi)
assert approx_equal(im_width, 0.1 * pi / 180.0)
# Build ExperimentLists
experiments_single_panel = ExperimentList()
experiments_multi_panel = ExperimentList()
experiments_single_panel.append(
Experiment(
beam=beam,
detector=single_panel_detector,
goniometer=gonio,
scan=scan,
crystal=crystal,
imageset=None,
)
)
experiments_multi_panel.append(
Experiment(
beam=beam,
detector=multi_panel_detector,
goniometer=gonio,
scan=scan,
crystal=crystal,
imageset=None,
)
)
# Generate some reflections
# All indices in a 2.0 Angstrom sphere
resolution = 2.0
index_generator = IndexGenerator(
crystal.get_unit_cell(),
space_group(space_group_symbols(1).hall()).type(),
resolution,
)
indices = index_generator.to_array()
# for the reflection predictor, it doesn't matter which experiment list is
# passed, as the detector is not used
ref_predictor = ScansRayPredictor(
experiments_single_panel, scan.get_oscillation_range(deg=False)
)
# get two sets of identical reflections
obs_refs_single = ref_predictor(indices)
obs_refs_multi = ref_predictor(indices)
for r1, r2 in zip(obs_refs_single.rows(), obs_refs_multi.rows()):
assert r1["s1"] == r2["s1"]
# get the panel intersections
sel = ray_intersection(single_panel_detector, obs_refs_single)
obs_refs_single = obs_refs_single.select(sel)
sel = ray_intersection(multi_panel_detector, obs_refs_multi)
obs_refs_multi = obs_refs_multi.select(sel)
assert len(obs_refs_single) == len(obs_refs_multi)
# Set 'observed' centroids from the predicted ones
obs_refs_single["xyzobs.mm.value"] = obs_refs_single["xyzcal.mm"]
obs_refs_multi["xyzobs.mm.value"] = obs_refs_multi["xyzcal.mm"]
# Invent some variances for the centroid positions of the simulated data
im_width = 0.1 * pi / 180.0
px_size = single_panel_detector[0].get_pixel_size()
var_x = flex.double(len(obs_refs_single), (px_size[0] / 2.0) ** 2)
var_y = flex.double(len(obs_refs_single), (px_size[1] / 2.0) ** 2)
var_phi = flex.double(len(obs_refs_single), (im_width / 2.0) ** 2)
# set the variances and frame numbers
obs_refs_single["xyzobs.mm.variance"] = flex.vec3_double(var_x, var_y, var_phi)
obs_refs_multi["xyzobs.mm.variance"] = flex.vec3_double(var_x, var_y, var_phi)
# Add in flags and ID columns by copying into standard reflection tables
tmp = flex.reflection_table.empty_standard(len(obs_refs_single))
tmp.update(obs_refs_single)
obs_refs_single = tmp
tmp = flex.reflection_table.empty_standard(len(obs_refs_multi))
tmp.update(obs_refs_multi)
obs_refs_multi = tmp
test_data = namedtuple(
"test_data",
[
"experiments_single_panel",
"experiments_multi_panel",
"observations_single_panel",
"observations_multi_panel",
],
)
return test_data(
experiments_single_panel,
experiments_multi_panel,
obs_refs_single,
obs_refs_multi,
)
crystal.c.length.value=13.0
crystal.c.direction.method=exactly
crystal.c.direction.exactly.direction=0.002 -0.004 1.0
detector.directions.method=exactly
detector.directions.exactly.dir1=0.99 0.002 -0.004
detector.directions.exactly.norm=0.002 -0.001 0.99
detector.centre.method=exactly
detector.centre.exactly.value=1.0 -0.5 199.0
}"""
master_phil = parse("""
include scope dials.test.algorithms.refinement.geometry_phil
include scope dials.test.algorithms.refinement.minimiser_phil
""", process_includes=True)
models = setup_geometry.Extract(master_phil, local_overrides=override,
verbose=False)
mydetector = models.detector
mygonio = models.goniometer
mycrystal = models.crystal
mybeam = models.beam
###########################
# Parameterise the models #
###########################
det_param = DetectorParameterisationSinglePanel(mydetector)
s0_param = BeamParameterisation(mybeam, mygonio)
xlo_param = CrystalOrientationParameterisation(mycrystal)
xluc_param = CrystalUnitCellParameterisation(mycrystal)
def test(args=[]):
from math import pi
from scitbx import matrix
from scitbx.array_family import flex
from libtbx.phil import parse
from libtbx.test_utils import approx_equal
# Get modules to build models and minimiser using PHIL
import dials.test.algorithms.refinement.setup_geometry as setup_geometry
import dials.test.algorithms.refinement.setup_minimiser as setup_minimiser
# We will set up a mock scan and a mock experiment list
from dxtbx.model import ScanFactory
from dxtbx.model.experiment_list import ExperimentList, Experiment
# Model parameterisations
from dials.algorithms.refinement.parameterisation.detector_parameters import (
DetectorParameterisationSinglePanel, )
from dials.algorithms.refinement.parameterisation.beam_parameters import (
BeamParameterisation, )
from dials.algorithms.refinement.parameterisation.crystal_parameters import (
CrystalOrientationParameterisation,
CrystalUnitCellParameterisation,
)
# Symmetry constrained parameterisation for the unit cell
from cctbx.uctbx import unit_cell
from rstbx.symmetry.constraints.parameter_reduction import symmetrize_reduce_enlarge
# Reflection prediction
from dials.algorithms.spot_prediction import IndexGenerator
from dials.algorithms.refinement.prediction.managed_predictors import (
ScansRayPredictor,
ScansExperimentsPredictor,
)
from dials.algorithms.spot_prediction import ray_intersection
from cctbx.sgtbx import space_group, space_group_symbols
# Parameterisation of the prediction equation
from dials.algorithms.refinement.parameterisation.prediction_parameters import (
XYPhiPredictionParameterisation, )
# Imports for the target function
from dials.algorithms.refinement.target import (
LeastSquaresPositionalResidualWithRmsdCutoff, )
from dials.algorithms.refinement.reflection_manager import ReflectionManager
#############################
# Setup experimental models #
#############################
master_phil = parse(
"""
include scope dials.test.algorithms.refinement.geometry_phil
include scope dials.test.algorithms.refinement.minimiser_phil
""",
process_includes=True,
)
models = setup_geometry.Extract(master_phil, cmdline_args=args)
mydetector = models.detector
mygonio = models.goniometer
mycrystal = models.crystal
mybeam = models.beam
# Build a mock scan for a 180 degree sequence
sf = ScanFactory()
myscan = sf.make_scan(
image_range=(1, 1800),
exposure_times=0.1,
oscillation=(0, 0.1),
epochs=list(range(1800)),
deg=True,
)
sequence_range = myscan.get_oscillation_range(deg=False)
im_width = myscan.get_oscillation(deg=False)[1]
assert sequence_range == (0.0, pi)
assert approx_equal(im_width, 0.1 * pi / 180.0)
# Build an experiment list
experiments = ExperimentList()
experiments.append(
Experiment(
beam=mybeam,
detector=mydetector,
goniometer=mygonio,
scan=myscan,
crystal=mycrystal,
imageset=None,
))
###########################
# Parameterise the models #
###########################
det_param = DetectorParameterisationSinglePanel(mydetector)
s0_param = BeamParameterisation(mybeam, mygonio)
xlo_param = CrystalOrientationParameterisation(mycrystal)
xluc_param = CrystalUnitCellParameterisation(mycrystal)
# Fix beam to the X-Z plane (imgCIF geometry), fix wavelength
s0_param.set_fixed([True, False, True])
# Fix crystal parameters
# xluc_param.set_fixed([True, True, True, True, True, True])
########################################################################
# Link model parameterisations together into a parameterisation of the #
# prediction equation #
########################################################################
pred_param = XYPhiPredictionParameterisation(experiments, [det_param],
[s0_param], [xlo_param],
[xluc_param])
################################
# Apply known parameter shifts #
################################
# shift detector by 1.0 mm each translation and 2 mrad each rotation
det_p_vals = det_param.get_param_vals()
p_vals = [
a + b for a, b in zip(det_p_vals, [1.0, 1.0, 1.0, 2.0, 2.0, 2.0])
]
det_param.set_param_vals(p_vals)
# shift beam by 2 mrad in free axis
s0_p_vals = s0_param.get_param_vals()
p_vals = list(s0_p_vals)
p_vals[0] += 2.0
s0_param.set_param_vals(p_vals)
# rotate crystal a bit (=2 mrad each rotation)
xlo_p_vals = xlo_param.get_param_vals()
p_vals = [a + b for a, b in zip(xlo_p_vals, [2.0, 2.0, 2.0])]
xlo_param.set_param_vals(p_vals)
# change unit cell a bit (=0.1 Angstrom length upsets, 0.1 degree of
# gamma angle)
xluc_p_vals = xluc_param.get_param_vals()
cell_params = mycrystal.get_unit_cell().parameters()
cell_params = [
a + b for a, b in zip(cell_params, [0.1, 0.1, 0.1, 0.0, 0.0, 0.1])
]
new_uc = unit_cell(cell_params)
newB = matrix.sqr(new_uc.fractionalization_matrix()).transpose()
S = symmetrize_reduce_enlarge(mycrystal.get_space_group())
S.set_orientation(orientation=newB)
X = tuple([e * 1.0e5 for e in S.forward_independent_parameters()])
xluc_param.set_param_vals(X)
#############################
# Generate some reflections #
#############################
print("Reflections will be generated with the following geometry:")
print(mybeam)
print(mydetector)
print(mycrystal)
print("Target values of parameters are")
msg = "Parameters: " + "%.5f " * len(pred_param)
print(msg % tuple(pred_param.get_param_vals()))
print()
# All indices in a 2.0 Angstrom sphere
resolution = 2.0
index_generator = IndexGenerator(
mycrystal.get_unit_cell(),
space_group(space_group_symbols(1).hall()).type(),
resolution,
)
indices = index_generator.to_array()
# Predict rays within the sequence range
ray_predictor = ScansRayPredictor(experiments, sequence_range)
obs_refs = ray_predictor(indices)
print("Total number of reflections excited", len(obs_refs))
# Take only those rays that intersect the detector
intersects = ray_intersection(mydetector, obs_refs)
obs_refs = obs_refs.select(intersects)
# Make a reflection predictor and re-predict for all these reflections. The
# result is the same, but we gain also the flags and xyzcal.px columns
ref_predictor = ScansExperimentsPredictor(experiments)
obs_refs["id"] = flex.int(len(obs_refs), 0)
obs_refs = ref_predictor(obs_refs)
# Set 'observed' centroids from the predicted ones
obs_refs["xyzobs.mm.value"] = obs_refs["xyzcal.mm"]
# Invent some variances for the centroid positions of the simulated data
im_width = 0.1 * pi / 180.0
px_size = mydetector[0].get_pixel_size()
var_x = flex.double(len(obs_refs), (px_size[0] / 2.0)**2)
var_y = flex.double(len(obs_refs), (px_size[1] / 2.0)**2)
var_phi = flex.double(len(obs_refs), (im_width / 2.0)**2)
obs_refs["xyzobs.mm.variance"] = flex.vec3_double(var_x, var_y, var_phi)
print("Total number of observations made", len(obs_refs))
###############################
# Undo known parameter shifts #
###############################
s0_param.set_param_vals(s0_p_vals)
det_param.set_param_vals(det_p_vals)
xlo_param.set_param_vals(xlo_p_vals)
xluc_param.set_param_vals(xluc_p_vals)
print("Initial values of parameters are")
msg = "Parameters: " + "%.5f " * len(pred_param)
print(msg % tuple(pred_param.get_param_vals()))
print()
#####################################
# Select reflections for refinement #
#####################################
refman = ReflectionManager(obs_refs, experiments)
##############################
# Set up the target function #
##############################
# The current 'achieved' criterion compares RMSD against 1/3 the pixel size and
# 1/3 the image width in radians. For the simulated data, these are just made up
mytarget = LeastSquaresPositionalResidualWithRmsdCutoff(
experiments,
ref_predictor,
refman,
pred_param,
restraints_parameterisation=None)
################################
# Set up the refinement engine #
################################
refiner = setup_minimiser.Extract(master_phil,
mytarget,
pred_param,
cmdline_args=args).refiner
print("Prior to refinement the experimental model is:")
print(mybeam)
print(mydetector)
print(mycrystal)
refiner.run()
print()
print("Refinement has completed with the following geometry:")
print(mybeam)
print(mydetector)
print(mycrystal)
