def test_radius(setup):
s0 = setup["beam"].get_s0()
m2 = setup["gonio"].get_rotation_axis()
s0_length = matrix.col(setup["beam"].get_s0()).length()
width, height = setup["detector"][0].get_image_size()
radius12 = setup["delta_divergence"]
for i in range(1000):
# Get random x, y, z
x = random.uniform(0, 2000)
y = random.uniform(0, 2000)
z = random.uniform(0, 9)
# Get random s1, phi, panel
s1 = (
matrix.col(setup["detector"][0].get_pixel_lab_coord((x, y))).normalize()
* s0_length
)
phi = setup["scan"].get_angle_from_array_index(z, deg=False)
panel = 0
# Calculate the bounding box
bbox = setup["calculate_bbox"](s1, z, panel)
# Create the XDS coordinate system
xcs = CoordinateSystem(m2, s0, s1, phi)
# Check vertical edges
for j in range(bbox[2], bbox[3] + 1):
xyz1 = setup["detector"][0].get_pixel_lab_coord((bbox[0], j))
xyz2 = setup["detector"][0].get_pixel_lab_coord((bbox[1] + 1, j))
sdash1 = matrix.col(xyz1).normalize() * s0_length
sdash2 = matrix.col(xyz2).normalize() * s0_length
e11, e21, e31 = xcs.from_beam_vector_and_rotation_angle(sdash1, phi)
e12, e22, e31 = xcs.from_beam_vector_and_rotation_angle(sdash2, phi)
if bbox[0] > 0 and bbox[1] < width:
assert math.sqrt(e11 ** 2 + e21 ** 2) >= radius12
assert math.sqrt(e12 ** 2 + e22 ** 2) >= radius12
# Check horizontal edges
for i in range(bbox[0], bbox[1] + 1):
xyz1 = setup["detector"][0].get_pixel_lab_coord((i, bbox[2]))
xyz2 = setup["detector"][0].get_pixel_lab_coord((i, bbox[3] + 1))
sdash1 = matrix.col(xyz1).normalize() * s0_length
sdash2 = matrix.col(xyz2).normalize() * s0_length
e11, e21, e32 = xcs.from_beam_vector_and_rotation_angle(sdash1, phi)
e12, e22, e32 = xcs.from_beam_vector_and_rotation_angle(sdash2, phi)
if bbox[2] > 0 and bbox[3] < height:
assert math.sqrt(e11 ** 2 + e21 ** 2) >= radius12
assert math.sqrt(e12 ** 2 + e22 ** 2) >= radius12
def __call__(self):
from scitbx import matrix
from random import uniform
from dials.algorithms.profile_model.gaussian_rs import CoordinateSystem
s0 = self.beam.get_s0()
m2 = self.gonio.get_rotation_axis()
s0_length = matrix.col(self.beam.get_s0()).length()
for i in range(100):
# Get random x, y, z
x = uniform(0, 2000)
y = uniform(0, 2000)
z = uniform(0, 9)
# Get random s1, phi, panel
s1 = matrix.col(self.detector[0].get_pixel_lab_coord(
(x, y))).normalize() * s0_length
phi = self.scan.get_angle_from_array_index(z, deg=False)
panel = 0
# Calculate the bounding box
bbox = self.calculate_bbox(s1, phi, panel)
x1, x2 = bbox[0], bbox[1]
y1, y2 = bbox[2], bbox[3]
z1, z2 = bbox[4], bbox[5]
# Create the XDS coordinate system
xcs = CoordinateSystem(m2, s0, s1, phi)
# Calculate the transform fraction
forward_fraction = self.transform_forward(bbox[4:], phi,
xcs.zeta())
# Calculate the transform fraction
reverse_fraction = self.transform_reverse(bbox[4:], phi,
xcs.zeta())
# Check the same points are non-zero
eps = 1e-7
for j in range(forward_fraction.all()[0]):
for i in range(forward_fraction.all()[1]):
if forward_fraction[j, i] > 0.0:
assert (reverse_fraction[i, j] > 0.0)
else:
assert (reverse_fraction[i, j] < eps)
# Test passed
print 'OK'
def __call__(self):
from scitbx import matrix
from random import uniform
from dials.algorithms.profile_model.gaussian_rs import CoordinateSystem
s0 = self.beam.get_s0()
m2 = self.gonio.get_rotation_axis()
s0_length = matrix.col(self.beam.get_s0()).length()
for i in range(100):
# Get random x, y, z
x = uniform(0, 2000)
y = uniform(0, 2000)
z = uniform(0, 9)
# Get random s1, phi, panel
s1 = matrix.col(self.detector[0].get_pixel_lab_coord(
(x, y))).normalize() * s0_length
phi = self.scan.get_angle_from_array_index(z, deg=False)
panel = 0
# Calculate the bounding box
bbox = self.calculate_bbox(s1, phi, panel)
x1, x2 = bbox[0], bbox[1]
y1, y2 = bbox[2], bbox[3]
z1, z2 = bbox[4], bbox[5]
# Create the XDS coordinate system
xcs = CoordinateSystem(m2, s0, s1, phi)
# Calculate the transform fraction
forward_fraction = self.transform_forward(bbox[4:], phi, xcs.zeta())
# Calculate the transform fraction
reverse_fraction = self.transform_reverse(bbox[4:], phi, xcs.zeta())
# Check the same points are non-zero
eps = 1e-7
for j in range(forward_fraction.all()[0]):
for i in range(forward_fraction.all()[1]):
if forward_fraction[j,i] > 0.0:
assert(reverse_fraction[i,j] > 0.0)
else:
assert(reverse_fraction[i,j] < eps)
# Test passed
print 'OK'
class Test(object):
def __init__(self):
from dials.algorithms.profile_model.gaussian_rs import transform
from dials.algorithms.profile_model.gaussian_rs import CoordinateSystem
import os
import libtbx.load_env
from math import floor
from scitbx import matrix
from dials.model.serialize import load
from random import uniform
try:
dials_regression = libtbx.env.dist_path('dials_regression')
except KeyError, e:
print 'FAIL: dials_regression not configured'
exit(0)
# Set the sweep filename and load the sweep
filename = os.path.join(dials_regression, 'centroid_test_data',
'sweep.json')
self.sweep = load.sweep(filename)
# Get the models
self.beam = self.sweep.get_beam()
self.detector = self.sweep.get_detector()
self.gonio = self.sweep.get_goniometer()
assert (len(self.detector) == 1)
# Get some stuff
self.s0 = self.beam.get_s0()
self.m2 = self.gonio.get_rotation_axis()
self.image_size = self.detector[0].get_image_size()
# Get a random s1/phi
i = uniform(0, self.image_size[0])
j = uniform(1, self.image_size[1])
self.s1 = matrix.col(self.detector[0].get_pixel_lab_coord((i, j)))
self.s1 = self.s1.normalize() * matrix.col(self.s0).length()
self.phi = uniform(0, 5)
self.x0 = int(floor(i - 10))
self.y0 = int(floor(j - 10))
# Set some parameters
self.sigma_divergence = self.beam.get_sigma_divergence(deg=False)
self.delta_divergence = 3 * self.sigma_divergence
self.grid_half_size = 4
self.step_size = (self.delta_divergence / self.grid_half_size,
self.delta_divergence / self.grid_half_size)
# Create the coordinate system
self.cs = CoordinateSystem(self.m2, self.s0, self.s1, self.phi)
# Create the map of s1 coordinates
self.s1_map = transform.beam_vector_map(self.detector[0], self.beam,
True)
# Create the grid index generator
self.generate_indices = transform.GridIndexGenerator(
self.cs, self.x0, self.y0, self.step_size, self.grid_half_size,
self.s1_map)
def compute_profile(experiments, reflection, reference, N):
from dials.array_family import flex
from dials.algorithms.profile_model.gaussian_rs import CoordinateSystem
from dials.algorithms.profile_model.modeller import GridSampler
from dials_scratch.jmp.sim import compute_profile_internal
from random import uniform
sbox = reflection["shoebox"]
bbox = sbox.bbox
zs = sbox.zsize()
ys = sbox.ysize()
xs = sbox.xsize()
profile = flex.double(flex.grid(zs, ys, xs))
m2 = experiments[0].goniometer.get_rotation_axis_datum()
s0 = experiments[0].beam.get_s0()
s1 = reflection["s1"]
phi = reflection["xyzcal.mm"][2]
detector = experiments[0].detector
scan = experiments[0].scan
cs = CoordinateSystem(m2, s0, s1, phi)
scan_range = scan.get_array_range()
image_size = detector[0].get_image_size()
grid_size = (3, 3, 40)
assert grid_size[0] * grid_size[1] * grid_size[2] == len(reference[0])
sampler = GridSampler(image_size, scan_range, grid_size)
xyz = reflection["xyzcal.px"]
index = sampler.nearest(0, xyz)
for g in reference[0]:
assert abs(flex.sum(g) - 1.0) < 1e-7
grid = reference[0][index]
sigma_d = experiments[0].profile.sigma_b(deg=False)
sigma_m = experiments[0].profile.sigma_m(deg=False)
delta_d = 3.0 * sigma_d
delta_m = 3.0 * sigma_m
profile = compute_profile_internal(grid, bbox, zs, ys, xs, N, delta_d,
delta_m, detector, scan, cs)
# from dials_scratch.jmp.viewer import show_image_stack_multi_view
# show_image_stack_multi_view(profile.as_numpy_array(), vmax=max(profile))
sum_p = flex.sum(profile)
print("Partiality: %f" % sum_p)
try:
assert sum_p > 0, "sum_p == 0"
except Exception as e:
print(e)
return None
return profile
def beamvector():
"""Initialise the transform"""
bv = {
"s0": (0.013141995425357206, 0.002199999234194632, 1.4504754950989514),
"s1": (-0.01752795848400313, -0.24786554213968193, 1.4290948735525306),
"m2": (0.999975, -0.001289, -0.006968),
"phi": 5.83575672475 * math.pi / 180,
}
bv["cs"] = CoordinateSystem(bv["m2"], bv["s0"], bv["s1"], bv["phi"])
return bv
def xdscoordinates():
"""Initialise the coordinate system"""
# Coordinate sensitive to length of vectors, so need to ensure that
# lengths of both s0 and s1 are equal
coords = {
"s0": (0.013141995425357206, 0.002199999234194632, 1.4504754950989514),
"s1": (-0.01752795848400313, -0.24786554213968193, 1.4290948735525306),
"m2": (0.999975, -0.001289, -0.006968),
"phi": 5.83575672475 * math.pi / 180,
}
coords["cs"] = CoordinateSystem(coords["m2"], coords["s0"], coords["s1"],
coords["phi"])
return coords
def test_outer_bounds(setup):
assert len(setup["detector"]) == 1
s0 = setup["beam"].get_s0()
m2 = setup["gonio"].get_rotation_axis()
s0_length = matrix.col(setup["beam"].get_s0()).length()
width, height = setup["detector"][0].get_image_size()
zrange = setup["scan"].get_array_range()
for i in range(1000):
# Get random x, y, z
x = random.uniform(0, 2000)
y = random.uniform(0, 2000)
z = random.uniform(0, 9)
# Get random s1, phi, panel
s1 = (
matrix.col(setup["detector"][0].get_pixel_lab_coord((x, y))).normalize()
* s0_length
)
phi = setup["scan"].get_angle_from_array_index(z, deg=False)
panel = 0
# Calculate the bounding box
bbox = setup["calculate_bbox"](s1, z, panel)
z1, z2 = bbox[4], bbox[5]
# Calculate the rotation angle for each point
phi_dash1 = setup["scan"].get_angle_from_array_index(z1, deg=False)
phi_dash2 = setup["scan"].get_angle_from_array_index(z2, deg=False)
# Create the XDS coordinate system
xcs = CoordinateSystem(m2, s0, s1, phi)
# Calculate reciprocal space coordinates at each point
e11, e21, e31 = xcs.from_beam_vector_and_rotation_angle(s1, phi_dash1)
e12, e22, e32 = xcs.from_beam_vector_and_rotation_angle(s1, phi_dash2)
# Check vertical edges
for j in range(bbox[2], bbox[3] + 1):
xyz1 = setup["detector"][0].get_pixel_lab_coord((bbox[0], j))
xyz2 = setup["detector"][0].get_pixel_lab_coord((bbox[1] + 1, j))
sdash1 = matrix.col(xyz1).normalize() * s0_length
sdash2 = matrix.col(xyz2).normalize() * s0_length
e11, e21, e3 = xcs.from_beam_vector_and_rotation_angle(sdash1, phi)
e12, e22, e3 = xcs.from_beam_vector_and_rotation_angle(sdash2, phi)
if bbox[0] > 0 and bbox[1] < width:
assert (
abs(e11) >= setup["delta_divergence"]
or abs(e21) >= setup["delta_divergence"]
)
assert (
abs(e12) >= setup["delta_divergence"]
or abs(e22) >= setup["delta_divergence"]
)
# Check horizontal edges
for i in range(bbox[0], bbox[1] + 1):
xyz1 = setup["detector"][0].get_pixel_lab_coord((i, bbox[2]))
xyz2 = setup["detector"][0].get_pixel_lab_coord((i, bbox[3] + 1))
sdash1 = matrix.col(xyz1).normalize() * s0_length
sdash2 = matrix.col(xyz2).normalize() * s0_length
e11, e21, e3 = xcs.from_beam_vector_and_rotation_angle(sdash1, phi)
e12, e22, e3 = xcs.from_beam_vector_and_rotation_angle(sdash2, phi)
if bbox[2] > 0 and bbox[3] < height:
assert (
abs(e11) >= setup["delta_divergence"]
or abs(e21) >= setup["delta_divergence"]
)
assert (
abs(e12) >= setup["delta_divergence"]
or abs(e22) >= setup["delta_divergence"]
)
# All e3 coords >= delta_mosaicity
if bbox[4] > zrange[0] and bbox[5] < zrange[1]:
assert abs(e31) >= setup["delta_mosaicity"]
assert abs(e32) >= setup["delta_mosaicity"]
def integrate_job(block,
experiments,
reflections,
reference,
grid_size=5,
detector_space=False):
from dials.algorithms.profile_model.modeller import CircleSampler
from dials.array_family import flex
from dials.algorithms.profile_model.gaussian_rs.transform import TransformReverse
from dials.algorithms.profile_model.gaussian_rs.transform import TransformForward
from dials.algorithms.profile_model.gaussian_rs.transform import (
TransformReverseNoModel, )
from dials.algorithms.profile_model.gaussian_rs.transform import TransformSpec
from dials.algorithms.profile_model.gaussian_rs import CoordinateSystem
from dials.algorithms.integration.fit import ProfileFitter
from dials.array_family import flex
from dials.model.data import make_image
reflections["shoebox"] = flex.shoebox(reflections["panel"],
reflections["bbox"],
allocate=True)
frame0, frame1 = experiments[0].scan.get_array_range()
frame0 = frame0 + block[0]
frame1 = frame0 + block[1]
reflections["shoebox"] = flex.shoebox(reflections["panel"],
reflections["bbox"],
allocate=True)
extractor = flex.ShoeboxExtractor(reflections, 1, frame0, frame1)
iset = experiments[0].imageset[block[0]:block[1]]
for i in range(len(iset)):
print("Reading image %d" % i)
data = iset.get_raw_data(i)
mask = iset.get_mask(i)
extractor.next(make_image(data, mask))
print("Computing mask")
reflections.compute_mask(experiments)
print("Computing background")
reflections.compute_background(experiments)
print("Computing centroid")
reflections.compute_centroid(experiments)
print("Computing summed intensity")
reflections.compute_summed_intensity()
assert len(reference) % 9 == 0
num_scan_points = len(reference) // 9
sampler = CircleSampler(
experiments[0].detector[0].get_image_size(),
experiments[0].scan.get_array_range(),
num_scan_points,
)
spec = TransformSpec(
experiments[0].beam,
experiments[0].detector,
experiments[0].goniometer,
experiments[0].scan,
experiments[0].profile.sigma_b(deg=False),
experiments[0].profile.sigma_m(deg=False),
experiments[0].profile.n_sigma() * 1.5,
grid_size,
)
m2 = experiments[0].goniometer.get_rotation_axis()
s0 = experiments[0].beam.get_s0()
Iprf = flex.double(len(reflections))
Vprf = flex.double(len(reflections))
Cprf = flex.double(len(reflections))
Fprf = flex.bool(len(reflections))
Part = reflections["partiality"]
reflections["intensity.prf_old.value"] = reflections["intensity.prf.value"]
reflections["intensity.prf_old.variance"] = reflections[
"intensity.prf.variance"]
selection = reflections.get_flags(reflections.flags.integrated_prf)
reflections.unset_flags(~Fprf, reflections.flags.integrated_prf)
for i, r in enumerate(reflections):
if selection[i] == False:
continue
s1 = r["s1"]
phi = r["xyzcal.mm"][2]
xyz = r["xyzcal.px"]
bbox = r["bbox"]
panel = r["panel"]
image = r["shoebox"].data.as_double()
background = r["shoebox"].background.as_double()
mask = r["shoebox"].mask.as_1d(
) == 5 # | (r['shoebox'].mask.as_1d() == 3)
mask.reshape(image.accessor())
cs = CoordinateSystem(m2, s0, s1, phi)
index = sampler.nearest(0, xyz)
profile, profile_mask = reference[index]
# print flex.sum(profile)
# print r['partiality']
if detector_space:
transform = TransformReverseNoModel(spec, cs, bbox, panel, profile)
p = transform.profile()
d = image
m = mask
b = background
# print flex.sum(p)
Part[i] = flex.sum(p)
# ysize, xsize = p.all()[1:3]
# p1 = flex.double(flex.grid(1, ysize , xsize))
# d1 = flex.double(flex.grid(1, ysize , xsize))
# b1 = flex.double(flex.grid(1, ysize , xsize))
# m1 = flex.double(flex.grid(1, ysize , xsize))
# for k in range(p.all()[0]):
# p1 += p[k:k+1,:,:]
# d1 += d[k:k+1,:,:]
# b1 += b[k:k+1,:,:]
# m1 = m[k:k+1,:,:]
try:
fit = ProfileFitter(d, b, m, p, 1e-3, 100)
assert fit.niter() < 100
Iprf[i] = fit.intensity()
Vprf[i] = fit.variance()
Cprf[i] = fit.correlation()
Fprf[i] = True
# if r['intensity.sum.value'] > 10 and abs(fit.intensity()) < 1e-3:
print(
r["miller_index"],
i,
fit.intensity(),
r["intensity.sum.value"],
r["intensity.prf_old.value"],
Part[i],
fit.niter(),
)
# from matplotlib import pylab
# pylab.imshow(p1.as_numpy_array()[0,:,:], interpolation='none')
# pylab.show()
except Exception as e:
print(e)
pass
else:
try:
transform = TransformForward(spec, cs, bbox, panel, image,
background, mask)
p = profile
d = transform.profile()
b = transform.background()
m = transform.mask() & profile_mask
# if r['miller_index'] == (9, -25, 74):
# print list(p)
# print list(m)
# print list(b)
# print list(d)
# exit(0)
fit = ProfileFitter(d, b, m, p, 1e-3, 100)
assert fit.niter() < 100
Iprf[i] = fit.intensity()[0]
Vprf[i] = fit.variance()[0]
Cprf[i] = fit.correlation()
Fprf[i] = True
print(r["miller_index"], i, fit.intensity(),
r["intensity.prf_old.value"])
# from matplotlib import pylab
# pylab.imshow(p1.as_numpy_array()[0,:,:], interpolation='none')
# pylab.show()
except Exception as e:
pass
reflections["intensity.prf.value"] = Iprf
reflections["intensity.prf.variance"] = Vprf
reflections["intensity.prf.correlation"] = Cprf
reflections.set_flags(Fprf, reflections.flags.integrated_prf)
del reflections["shoebox"]
return reflections
def compute_reference(experiments, reflections):
from dials.algorithms.profile_model.modeller import CircleSampler
from dials.array_family import flex
from dials.algorithms.profile_model.gaussian_rs.transform import TransformForward
from dials.algorithms.profile_model.gaussian_rs.transform import TransformSpec
from dials.algorithms.profile_model.gaussian_rs import CoordinateSystem
reflections = select_strong(reflections)
print("Selected %d strong spots" % len(reflections))
sampler = CircleSampler(
experiments[0].detector[0].get_image_size(),
experiments[0].scan.get_array_range(),
1,
)
n_sigma = 4.0
grid_size = 25
spec = TransformSpec(
experiments[0].beam,
experiments[0].detector,
experiments[0].goniometer,
experiments[0].scan,
experiments[0].profile.sigma_b(deg=False),
experiments[0].profile.sigma_m(deg=False),
n_sigma,
grid_size,
)
m2 = experiments[0].goniometer.get_rotation_axis()
s0 = experiments[0].beam.get_s0()
reference = [
flex.double(
flex.grid(1 + 2 * grid_size, 1 + 2 * grid_size, 1 + 2 * grid_size))
for i in range(len(sampler))
]
count = [0] * len(sampler)
for r in reflections:
s1 = r["s1"]
phi = r["xyzcal.mm"][2]
xyz = r["xyzcal.px"]
bbox = r["bbox"]
panel = r["panel"]
image = r["shoebox"].data.as_double()
mask = r["shoebox"].mask.as_1d() == 5
mask.reshape(image.accessor())
cs = CoordinateSystem(m2, s0, s1, phi)
try:
transform = TransformForward(spec, cs, bbox, panel, image, mask)
d = transform.profile()
d /= flex.sum(d)
index = sampler.nearest(0, xyz)
indices = sampler.nearest_n(0, xyz)
for i in indices:
w = sampler.weight(i, 0, xyz)
reference[i] += w * d
count[i] += 1
except Exception:
pass
for i in range(len(reference)):
r = reference[i]
if flex.sum(r) > 0:
print(flex.max(r))
g = r.accessor()
r = r.as_1d()
s = r > 0.02 * flex.max(r)
r.set_selected(~s, flex.double(len(r), 0))
r = r / flex.sum(r)
r.reshape(g)
reference[i] = r
for i in range(len(reference)):
from matplotlib import pylab
print(count[i])
r = reference[i]
d = r.as_numpy_array()[11, :, :]
pylab.imshow(d, interpolation="None")
pylab.show()
return reference
def tst_outer_bounds(self):
from scitbx import matrix
from random import uniform
from dials.algorithms.profile_model.gaussian_rs import CoordinateSystem
assert(len(self.detector) == 1)
s0 = self.beam.get_s0()
m2 = self.gonio.get_rotation_axis()
s0_length = matrix.col(self.beam.get_s0()).length()
width, height = self.detector[0].get_image_size()
zrange = self.scan.get_array_range()
for i in range(1000):
# Get random x, y, z
x = uniform(0, 2000)
y = uniform(0, 2000)
z = uniform(0, 9)
# Get random s1, phi, panel
s1 = matrix.col(self.detector[0].get_pixel_lab_coord(
(x, y))).normalize() * s0_length
phi = self.scan.get_angle_from_array_index(z, deg=False)
panel = 0
# Calculate the bounding box
bbox = self.calculate_bbox(s1, z, panel)
x1, x2 = bbox[0], bbox[1]
y1, y2 = bbox[2], bbox[3]
z1, z2 = bbox[4], bbox[5]
# Calculate the rotation angle for each point
phi_dash1 = self.scan.get_angle_from_array_index(z1, deg = False)
phi_dash2 = self.scan.get_angle_from_array_index(z2, deg = False)
# Create the XDS coordinate system
xcs = CoordinateSystem(m2, s0, s1, phi)
# Calculate reciprocal space coordinates at each point
e11, e21, e31 = xcs.from_beam_vector_and_rotation_angle(s1, phi_dash1)
e12, e22, e32 = xcs.from_beam_vector_and_rotation_angle(s1, phi_dash2)
# Check vertical edges
for j in range(bbox[2], bbox[3] + 1):
xyz1 = self.detector[0].get_pixel_lab_coord((bbox[0], j))
xyz2 = self.detector[0].get_pixel_lab_coord((bbox[1] + 1, j))
sdash1 = matrix.col(xyz1).normalize() * s0_length
sdash2 = matrix.col(xyz2).normalize() * s0_length
e11, e21, e3 = xcs.from_beam_vector_and_rotation_angle(sdash1, phi)
e12, e22, e3 = xcs.from_beam_vector_and_rotation_angle(sdash2, phi)
if bbox[0] > 0 and bbox[1] < width:
assert(abs(e11) >= self.delta_divergence or
abs(e21) >= self.delta_divergence)
assert(abs(e12) >= self.delta_divergence or
abs(e22) >= self.delta_divergence)
# Check horizontal edges
for i in range(bbox[0], bbox[1] + 1):
xyz1 = self.detector[0].get_pixel_lab_coord((i, bbox[2]))
xyz2 = self.detector[0].get_pixel_lab_coord((i, bbox[3] + 1))
sdash1 = matrix.col(xyz1).normalize() * s0_length
sdash2 = matrix.col(xyz2).normalize() * s0_length
e11, e21, e3 = xcs.from_beam_vector_and_rotation_angle(sdash1, phi)
e12, e22, e3 = xcs.from_beam_vector_and_rotation_angle(sdash2, phi)
if bbox[2] > 0 and bbox[3] < height:
assert(abs(e11) >= self.delta_divergence or
abs(e21) >= self.delta_divergence)
assert(abs(e12) >= self.delta_divergence or
abs(e22) >= self.delta_divergence)
# All e3 coords >= delta_mosaicity
if bbox[4] > zrange[0] and bbox[5] < zrange[1]:
assert(abs(e31) >= self.delta_mosaicity)
assert(abs(e32) >= self.delta_mosaicity)
print 'OK'
def test(dials_data):
experiment = ExperimentList.from_file(
dials_data("centroid_test_data").join("experiments.json"))
beam = experiment[0].beam
detector = experiment[0].detector
goniometer = experiment[0].goniometer
scan = experiment[0].scan
delta_b = experiment[0].profile.delta_b()
delta_m = experiment[0].profile.delta_m()
assert len(detector) == 1
# Get the function object to mask the foreground
mask_foreground = MaskCalculator3D(beam, detector, goniometer, scan,
delta_b, delta_m)
s0 = beam.get_s0()
m2 = goniometer.get_rotation_axis()
s0_length = matrix.col(beam.get_s0()).length()
width, height = detector[0].get_image_size()
zrange = scan.get_array_range()
phi0, dphi = scan.get_oscillation(deg=False)
# Generate some reflections
reflections = generate_reflections(detector, beam, scan, experiment, 10)
# Mask the foreground in each
mask_foreground(
reflections["shoebox"],
reflections["s1"],
reflections["xyzcal.px"].parts()[2],
reflections["panel"],
)
# Loop through all the reflections and check the mask values
shoebox = reflections["shoebox"]
beam_vector = reflections["s1"]
rotation_angle = reflections["xyzcal.mm"].parts()[2]
for l in range(len(reflections)):
mask = shoebox[l].mask
x0, x1, y0, y1, z0, z1 = shoebox[l].bbox
s1 = beam_vector[l]
phi = rotation_angle[l]
cs = CoordinateSystem(m2, s0, s1, phi)
def rs_coord(i, j, k):
s1d = detector[0].get_pixel_lab_coord((i, j))
s1d = matrix.col(s1d).normalize() * s0_length
e1, e2 = cs.from_beam_vector(s1d)
e3 = cs.from_rotation_angle_fast(phi0 + (k - zrange[0]) * dphi)
return e1, e2, e3
new_mask = flex.int(mask.accessor(), 0)
for k in range(z1 - z0):
for j in range(y1 - y0):
for i in range(x1 - x0):
# value1 = mask[k, j, i]
e11, e12, e13 = rs_coord(x0 + i, y0 + j, z0 + k)
e21, e22, e23 = rs_coord(x0 + i + 1, y0 + j, z0 + k)
e31, e32, e33 = rs_coord(x0 + i, y0 + j + 1, z0 + k)
e41, e42, e43 = rs_coord(x0 + i, y0 + j, z0 + k + 1)
e51, e52, e53 = rs_coord(x0 + i + 1, y0 + j + 1, z0 + k)
e61, e62, e63 = rs_coord(x0 + i + 1, y0 + j, z0 + k + 1)
e71, e72, e73 = rs_coord(x0 + i, y0 + j + 1, z0 + k + 1)
e81, e82, e83 = rs_coord(x0 + i + 1, y0 + j + 1,
z0 + k + 1)
de1 = (e11 / delta_b)**2 + (
e12 / delta_b)**2 # +(e13/delta_m)**2
de2 = (e21 / delta_b)**2 + (
e22 / delta_b)**2 # +(e23/delta_m)**2
de3 = (e31 / delta_b)**2 + (
e32 / delta_b)**2 # +(e33/delta_m)**2
de4 = (e41 / delta_b)**2 + (
e42 / delta_b)**2 # +(e43/delta_m)**2
de5 = (e51 / delta_b)**2 + (
e52 / delta_b)**2 # +(e53/delta_m)**2
de6 = (e61 / delta_b)**2 + (
e62 / delta_b)**2 # +(e63/delta_m)**2
de7 = (e71 / delta_b)**2 + (
e72 / delta_b)**2 # +(e73/delta_m)**2
de8 = (e81 / delta_b)**2 + (
e82 / delta_b)**2 # +(e83/delta_m)**2
de = math.sqrt(
min([de1, de2, de3, de4, de5, de6, de7, de8]))
if (x0 + i < 0 or y0 + j < 0 or x0 + i >= width
or y0 + j >= height or z0 + k < zrange[0]
or z0 + k >= zrange[1]):
value2 = MaskCode.Valid
else:
if de <= 1.0:
value2 = MaskCode.Valid | MaskCode.Foreground
else:
value2 = MaskCode.Valid | MaskCode.Background
new_mask[k, j, i] = value2
if not all(m1 == m2 for m1, m2 in zip(mask, new_mask)):
np.set_printoptions(threshold=10000)
diff = (mask == new_mask).as_numpy_array()
print(diff.astype(int))
# print mask.as_numpy_array()
# print new_mask.as_numpy_array()
# print (new_mask.as_numpy_array()[:,:,:] %2) * (new_mask.as_numpy_array() == 5)
assert False
def test_run(dials_data):
from dials.algorithms.profile_model.gaussian_rs import transform
from dials.algorithms.profile_model.gaussian_rs import CoordinateSystem
from scitbx import matrix
from dials.model.serialize import load
sequence = load.sequence(
dials_data("centroid_test_data").join("sweep.json").strpath)
# Get the models
beam = sequence.get_beam()
detector = sequence.get_detector()
gonio = sequence.get_goniometer()
assert len(detector) == 1
# Get some stuff
s0 = beam.get_s0()
m2 = gonio.get_rotation_axis()
image_size = detector[0].get_image_size()
# Get a random s1/phi
i = random.uniform(0, image_size[0])
j = random.uniform(1, image_size[1])
s1 = matrix.col(detector[0].get_pixel_lab_coord((i, j)))
s1 = s1.normalize() * matrix.col(s0).length()
phi = random.uniform(0, 5)
x0 = int(math.floor(i - 10))
y0 = int(math.floor(j - 10))
# Set some parameters
sigma_divergence = beam.get_sigma_divergence(deg=False)
delta_divergence = 3 * sigma_divergence
grid_half_size = 4
step_size = (delta_divergence / grid_half_size,
delta_divergence / grid_half_size)
# Create the coordinate system
cs = CoordinateSystem(m2, s0, s1, phi)
# Create the map of s1 coordinates
s1_map = transform.beam_vector_map(detector[0], beam, True)
# Create the grid index generator
generate_indices = transform.GridIndexGenerator(cs, x0, y0, step_size,
grid_half_size, s1_map)
for j in range(0, 20):
for i in range(0, 20):
xx = x0 + i
yy = y0 + j
if xx < 0 or yy < 0 or xx >= image_size[0] or yy >= image_size[0]:
continue
# Get the grid indices
gi_1, gj_1 = generate_indices(j, i)
# Get the grid indices
xyz = matrix.col(detector[0].get_pixel_lab_coord((x0 + i, y0 + j)))
xyz = xyz.normalize() * matrix.col(s0).length()
c1, c2 = matrix.col(cs.from_beam_vector(xyz))
gi_2 = grid_half_size + c1 / step_size[0] + 0.5
gj_2 = grid_half_size + c2 / step_size[1] + 0.5
# Check both are the same
eps = 1e-7
assert abs(gj_1 - gj_2) <= eps, (gi_1, gi_2, gj_1, gj_2)
assert abs(gi_1 - gi_2) <= eps, (gi_1, gi_2, gj_1, gj_2)
def test_forward_no_model(dials_data):
sequence = load.imageset(
dials_data("centroid_test_data").join("sweep.json").strpath)
# Get the models
beam = sequence.get_beam()
detector = sequence.get_detector()
gonio = sequence.get_goniometer()
scan = sequence.get_scan()
scan.set_image_range((0, 1000))
# Set some parameters
sigma_divergence = beam.get_sigma_divergence(deg=False)
mosaicity = 0.157 * math.pi / 180
n_sigma = 3
grid_size = 20
delta_divergence = n_sigma * sigma_divergence
step_size = delta_divergence / grid_size
delta_divergence2 = delta_divergence + step_size * 0.5
delta_mosaicity = n_sigma * mosaicity
# Create the bounding box calculator
calculate_bbox = BBoxCalculator3D(beam, detector, gonio, scan,
delta_divergence2, delta_mosaicity)
# Initialise the transform
spec = transform.TransformSpec(beam, detector, gonio, scan,
sigma_divergence, mosaicity, n_sigma + 1,
grid_size)
# tst_conservation_of_counts(self):
random.seed(0)
assert len(detector) == 1
s0 = beam.get_s0()
m2 = gonio.get_rotation_axis()
s0_length = matrix.col(beam.get_s0()).length()
# Create an s1 map
s1_map = transform.beam_vector_map(detector[0], beam, True)
for i in range(100):
# Get random x, y, z
x = random.uniform(300, 1800)
y = random.uniform(300, 1800)
z = random.uniform(500, 600)
# Get random s1, phi, panel
s1 = matrix.col(detector[0].get_pixel_lab_coord(
(x, y))).normalize() * s0_length
phi = scan.get_angle_from_array_index(z, deg=False)
panel = 0
# Calculate the bounding box
bbox = calculate_bbox(s1, z, panel)
x0, x1, y0, y1, z0, z1 = bbox
# Create the coordinate system
cs = CoordinateSystem(m2, s0, s1, phi)
if abs(cs.zeta()) < 0.1:
continue
# The grid index generator
step_size = delta_divergence / grid_size
grid_index = transform.GridIndexGenerator(cs, x0, y0,
(step_size, step_size),
grid_size, s1_map)
# Create the image
# image = flex.double(flex.grid(z1 - z0, y1 - y0, x1 - x0), 1)
image = gaussian((z1 - z0, y1 - y0, x1 - x0), 10.0,
(z - z0, y - y0, x - x0), (2.0, 2.0, 2.0))
mask = flex.bool(flex.grid(image.all()), False)
for j in range(y1 - y0):
for i in range(x1 - x0):
inside = False
gx00, gy00 = grid_index(j, i)
gx01, gy01 = grid_index(j, i + 1)
gx10, gy10 = grid_index(j + 1, i)
gx11, gy11 = grid_index(j + 1, i + 1)
mingx = min([gx00, gx01, gx10, gx11])
maxgx = max([gx00, gx01, gx10, gx11])
mingy = min([gy00, gy01, gy10, gy11])
maxgy = max([gy00, gy01, gy10, gy11])
if (mingx >= 0 and maxgx < 2 * grid_size + 1 and mingy >= 0
and maxgy < 2 * grid_size + 1):
inside = True
for k in range(1, z1 - z0 - 1):
mask[k, j, i] = inside
# Transform the image to the grid
transformed = transform.TransformForwardNoModel(
spec, cs, bbox, 0, image.as_double(), mask)
grid = transformed.profile()
# Get the sums and ensure they're the same
eps = 1e-7
sum_grid = flex.sum(grid)
sum_image = flex.sum(flex.double(flex.select(image, flags=mask)))
assert abs(sum_grid - sum_image) <= eps
mask = flex.bool(flex.grid(image.all()), True)
transformed = transform.TransformForwardNoModel(
spec, cs, bbox, 0, image.as_double(), mask)
grid = transformed.profile()
# Boost the bbox to make sure all intensity is included
x0, x1, y0, y1, z0, z1 = bbox
bbox2 = (x0 - 10, x1 + 10, y0 - 10, y1 + 10, z0 - 10, z1 + 10)
# Do the reverse transform
transformed = transform.TransformReverseNoModel(
spec, cs, bbox2, 0, grid)
image2 = transformed.profile()
# Check the sum of pixels are the same
sum_grid = flex.sum(grid)
sum_image = flex.sum(image2)
assert abs(sum_grid - sum_image) <= eps
# Do the reverse transform
transformed = transform.TransformReverseNoModel(
spec, cs, bbox, 0, grid)
image2 = transformed.profile()
from dials.algorithms.statistics import pearson_correlation_coefficient
cc = pearson_correlation_coefficient(image.as_1d().as_double(),
image2.as_1d())
assert cc >= 0.99
def __call__(self):
from scitbx import matrix
from random import uniform
from dials.algorithms.profile_model.gaussian_rs import CoordinateSystem
from scitbx.array_family import flex
assert (len(self.detector) == 1)
s0 = self.beam.get_s0()
m2 = self.gonio.get_rotation_axis()
s0_length = matrix.col(self.beam.get_s0()).length()
for i in range(100):
# Get random x, y, z
x = uniform(0, 2000)
y = uniform(0, 2000)
z = uniform(0, 9)
# Get random s1, phi, panel
s1 = matrix.col(self.detector[0].get_pixel_lab_coord(
(x, y))).normalize() * s0_length
phi = self.scan.get_angle_from_array_index(z, deg=False)
panel = 0
# Calculate the bounding box
bbox = self.calculate_bbox(s1, z, panel)
x1, x2 = bbox[0], bbox[1]
y1, y2 = bbox[2], bbox[3]
z1, z2 = bbox[4], bbox[5]
# Create the XDS coordinate system
xcs = CoordinateSystem(m2, s0, s1, phi)
# Calculate the transform fraction
fraction = self.transform(bbox[4:], phi, xcs.zeta())
# Ensure the minimum and maximum are 0 < 1
fmax = flex.max(fraction)
fmin = flex.min(fraction)
assert (fmax <= (1.0 + 5e-15)
and fmax > 0.0), "%.16f not between 0 and 1" % fmax
assert (fmin >= 0.0 and fmin <= 1.0)
# Ensure the fraction for each image frame adds up to 1.0 for
# all those frames completely within the grid
for j in range(1, fraction.all()[0] - 1):
tot = flex.sum(fraction[j:j + 1, :])
assert (abs(tot - 1.0) < 1e-7)
# Ensure the frames follow a progression through the grid. I.e,
# check that values increase then decrease and don't jump around
for j in range(fraction.all()[0]):
f = fraction[j:j + 1, :]
last = f[0]
rev = False
for i in range(1, len(f)):
curr = f[1]
if rev == False:
if curr < last:
rev = True
else:
assert (curr <= last)
last = curr
# Test passed
print 'OK'
def __call__(self):
from scitbx import matrix
from random import uniform
from dials.algorithms.profile_model.gaussian_rs import CoordinateSystem
from scitbx.array_family import flex
assert(len(self.detector) == 1)
s0 = self.beam.get_s0()
m2 = self.gonio.get_rotation_axis()
s0_length = matrix.col(self.beam.get_s0()).length()
for i in range(100):
# Get random x, y, z
x = uniform(0, 2000)
y = uniform(0, 2000)
z = uniform(0, 9)
# Get random s1, phi, panel
s1 = matrix.col(self.detector[0].get_pixel_lab_coord(
(x, y))).normalize() * s0_length
phi = self.scan.get_angle_from_array_index(z, deg=False)
panel = 0
# Calculate the bounding box
bbox = self.calculate_bbox(s1, z, panel)
x1, x2 = bbox[0], bbox[1]
y1, y2 = bbox[2], bbox[3]
z1, z2 = bbox[4], bbox[5]
# Create the XDS coordinate system
xcs = CoordinateSystem(m2, s0, s1, phi)
# Calculate the transform fraction
fraction = self.transform(bbox[4:], phi, xcs.zeta())
# Ensure the minimum and maximum are 0 < 1
fmax = flex.max(fraction)
fmin = flex.min(fraction)
assert(fmax <= (1.0 + 5e-15) and fmax > 0.0), "%.16f not between 0 and 1" % fmax
assert(fmin >= 0.0 and fmin <= 1.0)
# Ensure the fraction for each image frame adds up to 1.0 for
# all those frames completely within the grid
for j in range(1, fraction.all()[0]-1):
tot = flex.sum(fraction[j:j+1,:])
assert(abs(tot - 1.0) < 1e-7)
# Ensure the frames follow a progression through the grid. I.e,
# check that values increase then decrease and don't jump around
for j in range(fraction.all()[0]):
f = fraction[j:j+1,:]
last = f[0]
rev = False
for i in range(1,len(f)):
curr = f[1]
if rev == False:
if curr < last:
rev = True
else:
assert(curr <= last)
last = curr
# Test passed
print 'OK'
def test_forward_panel_edge(dials_data):
expt = ExperimentList.from_file(
dials_data("centroid_test_data").join(
"imported_experiments.json").strpath)[0]
# Get the models
beam = expt.beam
detector = expt.detector
gonio = expt.goniometer
scan = expt.scan
# Set some parameters
sigma_divergence = 0.00101229
mosaicity = 0.157 * math.pi / 180
n_sigma = 3
grid_size = 7
delta_divergence = n_sigma * sigma_divergence
step_size = delta_divergence / grid_size
delta_divergence2 = delta_divergence + step_size * 0.5
delta_mosaicity = n_sigma * mosaicity
# Create the bounding box calculator
calculate_bbox = BBoxCalculator3D(beam, detector, gonio, scan,
delta_divergence2, delta_mosaicity)
# Initialise the transform
spec = transform.TransformSpec(beam, detector, gonio, scan,
sigma_divergence, mosaicity, n_sigma + 1,
grid_size)
assert len(detector) == 1
s0 = beam.get_s0()
m2 = gonio.get_rotation_axis()
s0_length = matrix.col(beam.get_s0()).length()
image_size = detector[0].get_image_size()
refl_xy = [
(0, 0),
(2, 3),
(4, 1000),
(1000, 5),
(image_size[0] - 1, image_size[1] - 1),
(image_size[0] - 2, 1),
(1, image_size[1] - 5),
(1000, image_size[1] - 4),
(image_size[0] - 3, 1000),
]
for x, y in refl_xy:
z = random.uniform(0, 9)
# Get random s1, phi, panel
s1 = matrix.col(detector[0].get_pixel_lab_coord(
(x, y))).normalize() * s0_length
phi = scan.get_angle_from_array_index(z, deg=False)
panel = 0
# Calculate the bounding box
bbox = calculate_bbox(s1, z, panel)
x0, x1, y0, y1, z0, z1 = bbox
# Create the coordinate system
cs = CoordinateSystem(m2, s0, s1, phi)
# Create the image
image = gaussian((z1 - z0, y1 - y0, x1 - x0), 10.0,
(z - z0, y - y0, x - x0), (2.0, 2.0, 2.0))
# Mask for the foreground pixels
refl_mask = image > 1e-3
bg = flex.double(image.accessor())
# Shoebox mask, i.e. mask out pixels that are outside the panel bounds
shoebox_mask = flex.bool(image.accessor(), False)
for j in range(y1 - y0):
for i in range(x1 - x0):
if (j + y0 >= 0 and j + y0 < image_size[1] and i + x0 >= 0
and i + x0 < image_size[0]):
for k in range(z1 - z0):
shoebox_mask[k, j, i] = True
mask = refl_mask & shoebox_mask
# from matplotlib import pyplot as plt
# fig, axes = plt.subplots(ncols=refl_mask.focus()[0], nrows=4)
# for i in range(refl_mask.focus()[0]):
# axes[0, i].imshow(image.as_numpy_array()[i])
# axes[1, i].imshow(refl_mask.as_numpy_array()[i])
# axes[2, i].imshow(shoebox_mask.as_numpy_array()[i])
# axes[3, i].imshow(mask.as_numpy_array()[i])
# plt.show()
# Transform the image to the grid
transformed = transform.TransformForward(spec, cs, bbox, 0,
image.as_double(), bg,
refl_mask)
grid = transformed.profile()
mask = refl_mask & shoebox_mask
# assert only pixels within the panel were transformed
assert flex.sum(grid) == pytest.approx(flex.sum(
image.select(mask.as_1d())),
rel=0.01)
# The total transformed counts should be less than the (unmasked) image counts
assert flex.sum(grid) < flex.sum(image)
# Transform the image to the grid, this time without a background
transformed = transform.TransformForward(spec, cs, bbox, 0,
image.as_double(), refl_mask)
grid = transformed.profile()
mask = refl_mask & shoebox_mask
# assert only pixels within the panel were transformed
assert flex.sum(grid) == pytest.approx(flex.sum(
image.select(mask.as_1d())),
rel=0.01)
# The total transformed counts should be less than the (unmasked) image counts
assert flex.sum(grid) < flex.sum(image)
def test_forward(dials_data):
from dials.model.serialize import load
from dials.algorithms.profile_model.gaussian_rs import transform
from dials.algorithms.profile_model.gaussian_rs import BBoxCalculator3D
sweep = load.sweep(
dials_data("centroid_test_data").join("sweep.json").strpath)
# Get the models
beam = sweep.get_beam()
detector = sweep.get_detector()
gonio = sweep.get_goniometer()
scan = sweep.get_scan()
# beam.set_direction((0.0, 0.0, 1.0))
# gonio.set_rotation_axis((1.0, 0.0, 0.0))
# detector.set_frame((1.0, 0.0, 0.0),
# (0.0, 1.0, 0.0),
# (-150, -150, -200))
# Set some parameters
sigma_divergence = beam.get_sigma_divergence(deg=False)
mosaicity = 0.157 * math.pi / 180
n_sigma = 3
grid_size = 7
delta_divergence = n_sigma * sigma_divergence
step_size = delta_divergence / grid_size
delta_divergence2 = delta_divergence + step_size * 0.5
delta_mosaicity = n_sigma * mosaicity
# Create the bounding box calculator
calculate_bbox = BBoxCalculator3D(beam, detector, gonio, scan,
delta_divergence2, delta_mosaicity)
# Initialise the transform
spec = transform.TransformSpec(beam, detector, gonio, scan,
sigma_divergence, mosaicity, n_sigma + 1,
grid_size)
# tst_conservation_of_counts(self):
from scitbx import matrix
from dials.algorithms.profile_model.gaussian_rs import CoordinateSystem
from dials.algorithms.profile_model.gaussian_rs import transform
from scitbx.array_family import flex
assert len(detector) == 1
s0 = beam.get_s0()
m2 = gonio.get_rotation_axis()
s0_length = matrix.col(beam.get_s0()).length()
# Create an s1 map
s1_map = transform.beam_vector_map(detector[0], beam, True)
for i in range(100):
# Get random x, y, z
x = random.uniform(300, 1800)
y = random.uniform(300, 1800)
z = random.uniform(0, 9)
# Get random s1, phi, panel
s1 = matrix.col(detector[0].get_pixel_lab_coord(
(x, y))).normalize() * s0_length
phi = scan.get_angle_from_array_index(z, deg=False)
panel = 0
# Calculate the bounding box
bbox = calculate_bbox(s1, z, panel)
x0, x1, y0, y1, z0, z1 = bbox
# Create the coordinate system
cs = CoordinateSystem(m2, s0, s1, phi)
# The grid index generator
step_size = delta_divergence / grid_size
grid_index = transform.GridIndexGenerator(cs, x0, y0,
(step_size, step_size),
grid_size, s1_map)
# Create the image
# image = flex.double(flex.grid(z1 - z0, y1 - y0, x1 - x0), 1)
image = gaussian((z1 - z0, y1 - y0, x1 - x0), 10.0,
(z - z0, y - y0, x - x0), (2.0, 2.0, 2.0))
mask = flex.bool(flex.grid(image.all()), False)
for j in range(y1 - y0):
for i in range(x1 - x0):
inside = False
gx00, gy00 = grid_index(j, i)
gx01, gy01 = grid_index(j, i + 1)
gx10, gy10 = grid_index(j + 1, i)
gx11, gy11 = grid_index(j + 1, i + 1)
mingx = min([gx00, gx01, gx10, gx11])
maxgx = max([gx00, gx01, gx10, gx11])
mingy = min([gy00, gy01, gy10, gy11])
maxgy = max([gy00, gy01, gy10, gy11])
if (mingx >= 0 and maxgx < 2 * grid_size + 1 and mingy >= 0
and maxgy < 2 * grid_size + 1):
inside = True
for k in range(1, z1 - z0 - 1):
mask[k, j, i] = inside
# Transform the image to the grid
transformed = transform.TransformForward(spec, cs, bbox, 0,
image.as_double(), mask)
grid = transformed.profile()
# Get the sums and ensure they're the same
eps = 1e-7
sum_grid = flex.sum(grid)
sum_image = flex.sum(flex.double(flex.select(image, flags=mask)))
assert abs(sum_grid - sum_image) <= eps
# Test passed
# def tst_transformed_centroid(self):
# from scitbx import matrix
# from random import uniform
# from dials.algorithms.profile_model.gaussian_rs import CoordinateSystem
# from dials.algorithms.profile_model.gaussian_rs import transform
# from scitbx.array_family import flex
# from time import time
# s0 = beam.get_s0()
# m2 = gonio.get_rotation_axis()
# s0_length = matrix.col(beam.get_s0()).length()
# # Create an s1 map
# s1_map = transform.beam_vector_map(detector, beam, True)
# # Get random x, y, z
# x = random.uniform(300, 1800)
# y = random.uniform(300, 1800)
# z = random.uniform(-10, 0)
# # Get random s1, phi, panel
# s1 = matrix.col(detector.get_pixel_lab_coord(
# (x, y))).normalize() * s0_length
# phi = scan.get_angle_from_array_index(z, deg=False)
# panel = 0
# # Calculate the bounding box
# bbox = calculate_bbox(s1, z, panel)
# x0, x1, y0, y1, z0, z1 = bbox
# # Create the coordinate system
# cs = CoordinateSystem(m2, s0, s1, phi)
# # The grid index generator
# step_size = delta_divergence / grid_size
# grid_index = transform.GridIndexGenerator(cs, x0, y0,
# (step_size, step_size), grid_size, s1_map)
# # Create the image
# image = gaussian((z1 - z0, y1 - y0, x1 - x0), 10.0,
# (z - z0, y - y0, x - x0), (2.0, 2.0, 2.0))
# print x, y, z, bbox
# print (z1 - z0, y1 - y0, x1 - x0), (z - z0, y - y0, x - x0)
# mask = flex.bool(flex.grid(image.all()), False)
# for j in range(y1 - y0):
# for i in range(x1 - x0):
# inside = False
# gx00, gy00 = grid_index(j, i)
# gx01, gy01 = grid_index(j, i+1)
# gx10, gy10 = grid_index(j+1, i)
# gx11, gy11 = grid_index(j+1, i+1)
# mingx = min([gx00, gx01, gx10, gx11])
# maxgx = max([gx00, gx01, gx10, gx11])
# mingy = min([gy00, gy01, gy10, gy11])
# maxgy = max([gy00, gy01, gy10, gy11])
# if (mingx >= 0 and maxgx <= 2 * grid_size + 1 and
# mingy >= 0 and maxgy <= 2 * grid_size + 1):
# inside = True
# for k in range(1, z1 - z0 - 1):
# mask[k,j,i] = inside
# #image[k,j,i] *= inside
# from matplotlib import pylab
# pylab.imshow(image.as_numpy_array()[(z1 - z0) / 2,:,:], interpolation='none')
# pylab.show()
# # Transform the image to the grid
# grid = transform(cs, bbox, image, mask)
# from matplotlib import pylab
# pylab.imshow(grid.as_numpy_array()[7,:,:], interpolation='none')
# pylab.show()
# # Get the sums and ensure they're the same
# eps = 1e-7
# sum_grid = flex.sum(grid)
# sum_image = flex.sum(flex.double(flex.select(image, flags=mask)))
# assert(abs(sum_grid - sum_image) <= eps)
# # Check the centroid
# sz = grid_size * 2 + 1
# grid_x = flex.double(flex.grid(sz, sz, sz))
# grid_y = flex.double(flex.grid(sz, sz, sz))
# grid_z = flex.double(flex.grid(sz, sz, sz))
# for k in range(sz):
# for j in range(sz):
# for i in range(sz):
# grid_x[k,j,i] = i + 0.5
# grid_y[k,j,i] = j + 0.5
# grid_z[k,j,i] = k + 0.5
#
# sum_grid_x = flex.sum(grid * grid_x)
# sum_grid_y = flex.sum(grid * grid_y)
# sum_grid_z = flex.sum(grid * grid_z)
# xc = sum_grid_x / sum_grid
# yc = sum_grid_y / sum_grid
# zc = sum_grid_z / sum_grid
# print xc, yc, zc
# assert(abs(xc - grid_size + 0.5) <= 0.5)
# assert(abs(yc - grid_size + 0.5) <= 0.5)
# assert(abs(zc - grid_size + 0.5) <= 0.5)
# # Test passed
# print 'OK'
# tst_transform_with_background(self):
from scitbx import matrix
from dials.algorithms.profile_model.gaussian_rs import CoordinateSystem
from dials.algorithms.profile_model.gaussian_rs import transform
from scitbx.array_family import flex
assert len(detector) == 1
s0 = beam.get_s0()
m2 = gonio.get_rotation_axis()
s0_length = matrix.col(beam.get_s0()).length()
# Create an s1 map
s1_map = transform.beam_vector_map(detector[0], beam, True)
for i in range(100):
# Get random x, y, z
x = random.uniform(300, 1800)
y = random.uniform(300, 1800)
z = random.uniform(0, 9)
# Get random s1, phi, panel
s1 = matrix.col(detector[0].get_pixel_lab_coord(
(x, y))).normalize() * s0_length
phi = scan.get_angle_from_array_index(z, deg=False)
panel = 0
# Calculate the bounding box
bbox = calculate_bbox(s1, z, panel)
x0, x1, y0, y1, z0, z1 = bbox
# Create the coordinate system
cs = CoordinateSystem(m2, s0, s1, phi)
# The grid index generator
step_size = delta_divergence / grid_size
grid_index = transform.GridIndexGenerator(cs, x0, y0,
(step_size, step_size),
grid_size, s1_map)
# Create the image
# image = flex.double(flex.grid(z1 - z0, y1 - y0, x1 - x0), 1)
image = gaussian((z1 - z0, y1 - y0, x1 - x0), 10.0,
(z - z0, y - y0, x - x0), (2.0, 2.0, 2.0))
background = flex.random_double(len(image))
background.resize(image.accessor())
mask = flex.bool(flex.grid(image.all()), False)
for j in range(y1 - y0):
for i in range(x1 - x0):
inside = False
gx00, gy00 = grid_index(j, i)
gx01, gy01 = grid_index(j, i + 1)
gx10, gy10 = grid_index(j + 1, i)
gx11, gy11 = grid_index(j + 1, i + 1)
mingx = min([gx00, gx01, gx10, gx11])
maxgx = max([gx00, gx01, gx10, gx11])
mingy = min([gy00, gy01, gy10, gy11])
maxgy = max([gy00, gy01, gy10, gy11])
if (mingx >= 0 and maxgx <= 2 * grid_size + 1 and mingy >= 0
and maxgy <= 2 * grid_size + 1):
inside = True
for k in range(1, z1 - z0 - 1):
mask[k, j, i] = inside
# Transform the image to the grid
transformed = transform.TransformForward(spec, cs, bbox, 0,
image.as_double(),
background.as_double(), mask)
igrid = transformed.profile()
bgrid = transformed.background()
# Get the sums and ensure they're the same
eps = 1e-7
sum_igrid = flex.sum(igrid)
sum_bgrid = flex.sum(bgrid)
sum_image = flex.sum(flex.double(flex.select(image, flags=mask)))
sum_bkgrd = flex.sum(flex.double(flex.select(background, flags=mask)))
try:
assert abs(sum_igrid - sum_image) <= eps
assert abs(sum_bgrid - sum_bkgrd) <= eps
except Exception:
print("Failed for: ", (x, y, z))
raise
def test_map_frames_forward(dials_data):
sequence = load.imageset(
dials_data("centroid_test_data").join("sweep.json").strpath)
# Get the models
beam = sequence.get_beam()
detector = sequence.get_detector()
gonio = sequence.get_goniometer()
scan = sequence.get_scan()
# Set the delta_divergence/mosaicity
n_sigma = 3
sigma_divergence = 0.060 * math.pi / 180
mosaicity = 0.154 * math.pi / 180
delta_divergence = n_sigma * sigma_divergence
delta_mosaicity = n_sigma * mosaicity
# Set the grid size
grid_size = (4, 4, 4)
# Create the E3 fraction object
transform = MapFramesForward(
scan.get_array_range()[0],
scan.get_oscillation(deg=False)[0],
scan.get_oscillation(deg=False)[1],
mosaicity,
n_sigma,
grid_size[2],
)
# Create the bounding box calculator
calculate_bbox = BBoxCalculator3D(beam, detector, gonio, scan,
delta_divergence, delta_mosaicity)
assert len(detector) == 1
s0 = beam.get_s0()
m2 = gonio.get_rotation_axis()
s0_length = matrix.col(beam.get_s0()).length()
for i in range(100):
# Get random x, y, z
x = random.uniform(0, 2000)
y = random.uniform(0, 2000)
z = random.uniform(0, 9)
# Get random s1, phi, panel
s1 = matrix.col(detector[0].get_pixel_lab_coord(
(x, y))).normalize() * s0_length
phi = scan.get_angle_from_array_index(z, deg=False)
panel = 0
# Calculate the bounding box
bbox = calculate_bbox(s1, z, panel)
# Create the XDS coordinate system
xcs = CoordinateSystem(m2, s0, s1, phi)
# Calculate the transform fraction
fraction = transform(bbox[4:], phi, xcs.zeta())
# Ensure the minimum and maximum are 0 < 1
fmax = flex.max(fraction)
fmin = flex.min(fraction)
assert fmax <= (
1.0 + 5e-15) and fmax > 0.0, f"{fmax:.16f} not between 0 and 1"
assert fmin >= 0.0 and fmin <= 1.0
# Ensure the fraction for each image frame adds up to 1.0 for
# all those frames completely within the grid
for j in range(1, fraction.all()[0] - 1):
tot = flex.sum(fraction[j:j + 1, :])
assert abs(tot - 1.0) < 1e-7
# Ensure the frames follow a progression through the grid. I.e,
# check that values increase then decrease and don't jump around
for j in range(fraction.all()[0]):
f = fraction[j:j + 1, :]
last = f[0]
rev = False
for i in range(1, len(f)):
curr = f[1]
if rev is False:
if curr < last:
rev = True
else:
assert curr <= last
last = curr
class Test(object):
def __init__(self):
from dials.algorithms.profile_model.gaussian_rs import transform
from dials.algorithms.profile_model.gaussian_rs import CoordinateSystem
import os
import libtbx.load_env
from math import floor
from scitbx import matrix
from dials.model.serialize import load
from random import uniform
try:
dials_regression = libtbx.env.dist_path('dials_regression')
except KeyError:
print 'FAIL: dials_regression not configured'
exit(0)
# Set the sweep filename and load the sweep
filename = os.path.join(
dials_regression,
'centroid_test_data',
'sweep.json')
self.sweep = load.sweep(filename)
# Get the models
self.beam = self.sweep.get_beam()
self.detector = self.sweep.get_detector()
self.gonio = self.sweep.get_goniometer()
assert(len(self.detector) == 1)
# Get some stuff
self.s0 = self.beam.get_s0()
self.m2 = self.gonio.get_rotation_axis()
self.image_size = self.detector[0].get_image_size()
# Get a random s1/phi
i = uniform(0, self.image_size[0])
j = uniform(1, self.image_size[1])
self.s1 = matrix.col(self.detector[0].get_pixel_lab_coord((i, j)))
self.s1 = self.s1.normalize() * matrix.col(self.s0).length()
self.phi = uniform(0, 5)
self.x0 = int(floor(i - 10))
self.y0 = int(floor(j - 10))
# Set some parameters
self.sigma_divergence = self.beam.get_sigma_divergence(deg=False)
self.delta_divergence = 3 * self.sigma_divergence
self.grid_half_size = 4
self.step_size = (self.delta_divergence / self.grid_half_size,
self.delta_divergence / self.grid_half_size)
# Create the coordinate system
self.cs = CoordinateSystem(self.m2, self.s0, self.s1, self.phi)
# Create the map of s1 coordinates
self.s1_map = transform.beam_vector_map(self.detector[0], self.beam, True)
# Create the grid index generator
self.generate_indices = transform.GridIndexGenerator(
self.cs,
self.x0,
self.y0,
self.step_size,
self.grid_half_size,
self.s1_map)
def run(self):
from scitbx import matrix
for j in range(0, 20):
for i in range(0, 20):
xx = self.x0 + i
yy = self.y0 + j
if xx < 0 or yy < 0 or xx >= self.image_size[0] or yy >= self.image_size[0]:
continue
# Get the grid indices
gi_1, gj_1 = self.generate_indices(j, i)
# Get the grid indices
xyz = matrix.col(self.detector[0].get_pixel_lab_coord(
(self.x0 + i, self.y0 + j)))
xyz = xyz.normalize() * matrix.col(self.s0).length()
c1, c2 = matrix.col(self.cs.from_beam_vector(xyz))
gi_2 = self.grid_half_size + c1 / self.step_size[0] + 0.5
gj_2 = self.grid_half_size + c2 / self.step_size[1] + 0.5
# Check both are the same
eps = 1e-7
try:
assert(abs(gj_1 - gj_2) <= eps)
assert(abs(gi_1 - gi_2) <= eps)
except Exception:
print gi_1, gi_2, gj_1, gj_2
raise
# Test passed
print 'OK'
def test_map_forward_reverse(dials_data):
sequence = load.imageset(
dials_data("centroid_test_data").join("sweep.json").strpath)
# Get the models
beam = sequence.get_beam()
detector = sequence.get_detector()
gonio = sequence.get_goniometer()
scan = sequence.get_scan()
# Set the delta_divergence/mosaicity
n_sigma = 3
sigma_divergence = 0.060 * math.pi / 180
mosaicity = 0.154 * math.pi / 180
delta_divergence = n_sigma * sigma_divergence
delta_mosaicity = n_sigma * mosaicity
# Set the grid size
grid_size = (4, 4, 4)
# Create the E3 fraction object
transform_forward = MapFramesForward(
scan.get_array_range()[0],
scan.get_oscillation(deg=False)[0],
scan.get_oscillation(deg=False)[1],
mosaicity,
n_sigma,
grid_size[2],
)
# Create the E3 fraction object
transform_reverse = MapFramesReverse(
scan.get_array_range()[0],
scan.get_oscillation(deg=False)[0],
scan.get_oscillation(deg=False)[1],
mosaicity,
n_sigma,
grid_size[2],
)
# Create the bounding box calculator
calculate_bbox = BBoxCalculator3D(beam, detector, gonio, scan,
delta_divergence, delta_mosaicity)
s0 = beam.get_s0()
m2 = gonio.get_rotation_axis()
s0_length = matrix.col(beam.get_s0()).length()
for i in range(100):
# Get random x, y, z
x = random.uniform(0, 2000)
y = random.uniform(0, 2000)
z = random.uniform(0, 9)
# Get random s1, phi, panel
s1 = matrix.col(detector[0].get_pixel_lab_coord(
(x, y))).normalize() * s0_length
phi = scan.get_angle_from_array_index(z, deg=False)
panel = 0
# Calculate the bounding box
bbox = calculate_bbox(s1, phi, panel)
# Create the XDS coordinate system
xcs = CoordinateSystem(m2, s0, s1, phi)
# Calculate the transform fraction
forward_fraction = transform_forward(bbox[4:], phi, xcs.zeta())
# Calculate the transform fraction
reverse_fraction = transform_reverse(bbox[4:], phi, xcs.zeta())
# Check the same points are non-zero
eps = 1e-7
for j in range(forward_fraction.all()[0]):
for i in range(forward_fraction.all()[1]):
if forward_fraction[j, i] > 0.0:
assert reverse_fraction[i, j] > 0.0
else:
assert reverse_fraction[i, j] < eps
def tst_conservation_of_counts(self):
from scitbx import matrix
from random import uniform
from dials.algorithms.profile_model.gaussian_rs import CoordinateSystem
from dials.algorithms.profile_model.gaussian_rs import transform
from scitbx.array_family import flex
assert (len(self.detector) == 1)
s0 = self.beam.get_s0()
m2 = self.gonio.get_rotation_axis()
s0_length = matrix.col(self.beam.get_s0()).length()
# Create an s1 map
s1_map = transform.beam_vector_map(self.detector[0], self.beam, True)
for i in range(100):
# Get random x, y, z
x = uniform(300, 1800)
y = uniform(300, 1800)
z = uniform(0, 9)
# Get random s1, phi, panel
s1 = matrix.col(self.detector[0].get_pixel_lab_coord(
(x, y))).normalize() * s0_length
phi = self.scan.get_angle_from_array_index(z, deg=False)
panel = 0
# Calculate the bounding box
bbox = self.calculate_bbox(s1, z, panel)
x0, x1, y0, y1, z0, z1 = bbox
# Create the coordinate system
cs = CoordinateSystem(m2, s0, s1, phi)
# The grid index generator
step_size = self.delta_divergence / self.grid_size
grid_index = transform.GridIndexGenerator(cs, x0, y0,
(step_size, step_size),
self.grid_size, s1_map)
# Create the image
#image = flex.double(flex.grid(z1 - z0, y1 - y0, x1 - x0), 1)
image = gaussian((z1 - z0, y1 - y0, x1 - x0), 10.0,
(z - z0, y - y0, x - x0), (2.0, 2.0, 2.0))
mask = flex.bool(flex.grid(image.all()), False)
for j in range(y1 - y0):
for i in range(x1 - x0):
inside = False
gx00, gy00 = grid_index(j, i)
gx01, gy01 = grid_index(j, i + 1)
gx10, gy10 = grid_index(j + 1, i)
gx11, gy11 = grid_index(j + 1, i + 1)
mingx = min([gx00, gx01, gx10, gx11])
maxgx = max([gx00, gx01, gx10, gx11])
mingy = min([gy00, gy01, gy10, gy11])
maxgy = max([gy00, gy01, gy10, gy11])
if (mingx >= 0 and maxgx < 2 * self.grid_size + 1
and mingy >= 0 and maxgy < 2 * self.grid_size + 1):
inside = True
for k in range(1, z1 - z0 - 1):
mask[k, j, i] = inside
# Transform the image to the grid
transformed = transform.TransformForward(self.spec, cs, bbox, 0,
image.as_double(), mask)
grid = transformed.profile()
# Get the sums and ensure they're the same
eps = 1e-7
sum_grid = flex.sum(grid)
sum_image = flex.sum(flex.double(flex.select(image, flags=mask)))
assert (abs(sum_grid - sum_image) <= eps)
# Test passed
print 'OK'
def test_forward(dials_data):
sequence = load.imageset(
dials_data("centroid_test_data").join("sweep.json").strpath)
# Get the models
beam = sequence.get_beam()
detector = sequence.get_detector()
gonio = sequence.get_goniometer()
scan = sequence.get_scan()
# Set some parameters
sigma_divergence = beam.get_sigma_divergence(deg=False)
mosaicity = 0.157 * math.pi / 180
n_sigma = 3
grid_size = 7
delta_divergence = n_sigma * sigma_divergence
step_size = delta_divergence / grid_size
delta_divergence2 = delta_divergence + step_size * 0.5
delta_mosaicity = n_sigma * mosaicity
# Create the bounding box calculator
calculate_bbox = BBoxCalculator3D(beam, detector, gonio, scan,
delta_divergence2, delta_mosaicity)
# Initialise the transform
spec = transform.TransformSpec(beam, detector, gonio, scan,
sigma_divergence, mosaicity, n_sigma + 1,
grid_size)
# tst_conservation_of_counts(self):
assert len(detector) == 1
s0 = beam.get_s0()
m2 = gonio.get_rotation_axis()
s0_length = matrix.col(beam.get_s0()).length()
# Create an s1 map
s1_map = transform.beam_vector_map(detector[0], beam, True)
for i in range(100):
# Get random x, y, z
x = random.uniform(300, 1800)
y = random.uniform(300, 1800)
z = random.uniform(0, 9)
# Get random s1, phi, panel
s1 = matrix.col(detector[0].get_pixel_lab_coord(
(x, y))).normalize() * s0_length
phi = scan.get_angle_from_array_index(z, deg=False)
panel = 0
# Calculate the bounding box
bbox = calculate_bbox(s1, z, panel)
x0, x1, y0, y1, z0, z1 = bbox
# Create the coordinate system
cs = CoordinateSystem(m2, s0, s1, phi)
# The grid index generator
step_size = delta_divergence / grid_size
grid_index = transform.GridIndexGenerator(cs, x0, y0,
(step_size, step_size),
grid_size, s1_map)
# Create the image
# image = flex.double(flex.grid(z1 - z0, y1 - y0, x1 - x0), 1)
image = gaussian((z1 - z0, y1 - y0, x1 - x0), 10.0,
(z - z0, y - y0, x - x0), (2.0, 2.0, 2.0))
mask = flex.bool(flex.grid(image.all()), False)
for j in range(y1 - y0):
for i in range(x1 - x0):
inside = False
gx00, gy00 = grid_index(j, i)
gx01, gy01 = grid_index(j, i + 1)
gx10, gy10 = grid_index(j + 1, i)
gx11, gy11 = grid_index(j + 1, i + 1)
mingx = min([gx00, gx01, gx10, gx11])
maxgx = max([gx00, gx01, gx10, gx11])
mingy = min([gy00, gy01, gy10, gy11])
maxgy = max([gy00, gy01, gy10, gy11])
if (mingx >= 0 and maxgx < 2 * grid_size + 1 and mingy >= 0
and maxgy < 2 * grid_size + 1):
inside = True
for k in range(1, z1 - z0 - 1):
mask[k, j, i] = inside
# Transform the image to the grid
transformed = transform.TransformForward(spec, cs, bbox, 0,
image.as_double(), mask)
grid = transformed.profile()
# Get the sums and ensure they're the same
eps = 1e-7
sum_grid = flex.sum(grid)
sum_image = flex.sum(flex.double(flex.select(image, flags=mask)))
assert abs(sum_grid - sum_image) <= eps
# Test passed
# tst_transform_with_background(self):
assert len(detector) == 1
s0 = beam.get_s0()
m2 = gonio.get_rotation_axis()
s0_length = matrix.col(beam.get_s0()).length()
# Create an s1 map
s1_map = transform.beam_vector_map(detector[0], beam, True)
for i in range(100):
# Get random x, y, z
x = random.uniform(300, 1800)
y = random.uniform(300, 1800)
z = random.uniform(0, 9)
# Get random s1, phi, panel
s1 = matrix.col(detector[0].get_pixel_lab_coord(
(x, y))).normalize() * s0_length
phi = scan.get_angle_from_array_index(z, deg=False)
panel = 0
# Calculate the bounding box
bbox = calculate_bbox(s1, z, panel)
x0, x1, y0, y1, z0, z1 = bbox
# Create the coordinate system
cs = CoordinateSystem(m2, s0, s1, phi)
# The grid index generator
step_size = delta_divergence / grid_size
grid_index = transform.GridIndexGenerator(cs, x0, y0,
(step_size, step_size),
grid_size, s1_map)
# Create the image
# image = flex.double(flex.grid(z1 - z0, y1 - y0, x1 - x0), 1)
image = gaussian((z1 - z0, y1 - y0, x1 - x0), 10.0,
(z - z0, y - y0, x - x0), (2.0, 2.0, 2.0))
background = flex.random_double(len(image))
background.resize(image.accessor())
mask = flex.bool(flex.grid(image.all()), False)
for j in range(y1 - y0):
for i in range(x1 - x0):
inside = False
gx00, gy00 = grid_index(j, i)
gx01, gy01 = grid_index(j, i + 1)
gx10, gy10 = grid_index(j + 1, i)
gx11, gy11 = grid_index(j + 1, i + 1)
mingx = min([gx00, gx01, gx10, gx11])
maxgx = max([gx00, gx01, gx10, gx11])
mingy = min([gy00, gy01, gy10, gy11])
maxgy = max([gy00, gy01, gy10, gy11])
if (mingx >= 0 and maxgx <= 2 * grid_size + 1 and mingy >= 0
and maxgy <= 2 * grid_size + 1):
inside = True
for k in range(1, z1 - z0 - 1):
mask[k, j, i] = inside
# Transform the image to the grid
transformed = transform.TransformForward(spec, cs, bbox, 0,
image.as_double(),
background.as_double(), mask)
igrid = transformed.profile()
bgrid = transformed.background()
# Get the sums and ensure they're the same
eps = 1e-7
sum_igrid = flex.sum(igrid)
sum_bgrid = flex.sum(bgrid)
sum_image = flex.sum(flex.double(flex.select(image, flags=mask)))
sum_bkgrd = flex.sum(flex.double(flex.select(background, flags=mask)))
try:
assert abs(sum_igrid - sum_image) <= eps
assert abs(sum_bgrid - sum_bkgrd) <= eps
except Exception:
print("Failed for: ", (x, y, z))
raise
def tst_conservation_of_counts(self):
from scitbx import matrix
from random import uniform, seed
from dials.algorithms.profile_model.gaussian_rs import CoordinateSystem
from dials.algorithms.profile_model.gaussian_rs import transform
from scitbx.array_family import flex
seed(0)
assert len(self.detector) == 1
s0 = self.beam.get_s0()
m2 = self.gonio.get_rotation_axis()
s0_length = matrix.col(self.beam.get_s0()).length()
# Create an s1 map
s1_map = transform.beam_vector_map(self.detector[0], self.beam, True)
for i in range(100):
# Get random x, y, z
x = uniform(300, 1800)
y = uniform(300, 1800)
z = uniform(500, 600)
# Get random s1, phi, panel
s1 = matrix.col(self.detector[0].get_pixel_lab_coord((x, y))).normalize() * s0_length
phi = self.scan.get_angle_from_array_index(z, deg=False)
panel = 0
# Calculate the bounding box
bbox = self.calculate_bbox(s1, z, panel)
x0, x1, y0, y1, z0, z1 = bbox
# Create the coordinate system
cs = CoordinateSystem(m2, s0, s1, phi)
if abs(cs.zeta()) < 0.1:
continue
# The grid index generator
step_size = self.delta_divergence / self.grid_size
grid_index = transform.GridIndexGenerator(cs, x0, y0, (step_size, step_size), self.grid_size, s1_map)
# Create the image
# image = flex.double(flex.grid(z1 - z0, y1 - y0, x1 - x0), 1)
image = gaussian((z1 - z0, y1 - y0, x1 - x0), 10.0, (z - z0, y - y0, x - x0), (2.0, 2.0, 2.0))
mask = flex.bool(flex.grid(image.all()), False)
for j in range(y1 - y0):
for i in range(x1 - x0):
inside = False
gx00, gy00 = grid_index(j, i)
gx01, gy01 = grid_index(j, i + 1)
gx10, gy10 = grid_index(j + 1, i)
gx11, gy11 = grid_index(j + 1, i + 1)
mingx = min([gx00, gx01, gx10, gx11])
maxgx = max([gx00, gx01, gx10, gx11])
mingy = min([gy00, gy01, gy10, gy11])
maxgy = max([gy00, gy01, gy10, gy11])
if mingx >= 0 and maxgx < 2 * self.grid_size + 1 and mingy >= 0 and maxgy < 2 * self.grid_size + 1:
inside = True
for k in range(1, z1 - z0 - 1):
mask[k, j, i] = inside
# Transform the image to the grid
transformed = transform.TransformForwardNoModel(self.spec, cs, bbox, 0, image.as_double(), mask)
grid = transformed.profile()
# Get the sums and ensure they're the same
eps = 1e-7
sum_grid = flex.sum(grid)
sum_image = flex.sum(flex.double(flex.select(image, flags=mask)))
assert abs(sum_grid - sum_image) <= eps
mask = flex.bool(flex.grid(image.all()), True)
transformed = transform.TransformForwardNoModel(self.spec, cs, bbox, 0, image.as_double(), mask)
grid = transformed.profile()
# Boost the bbox to make sure all intensity is included
x0, x1, y0, y1, z0, z1 = bbox
bbox2 = (x0 - 10, x1 + 10, y0 - 10, y1 + 10, z0 - 10, z1 + 10)
# Do the reverse transform
transformed = transform.TransformReverseNoModel(self.spec, cs, bbox2, 0, grid)
image2 = transformed.profile()
# Check the sum of pixels are the same
sum_grid = flex.sum(grid)
sum_image = flex.sum(image2)
assert abs(sum_grid - sum_image) <= eps
# Do the reverse transform
transformed = transform.TransformReverseNoModel(self.spec, cs, bbox, 0, grid)
image2 = transformed.profile()
from dials.algorithms.statistics import pearson_correlation_coefficient
cc = pearson_correlation_coefficient(image.as_1d().as_double(), image2.as_1d())
assert cc >= 0.99
# if cc < 0.99:
# print cc, bbox
# from matplotlib import pylab
# pylab.plot(image.as_numpy_array()[(z1-z0)/2,(y1-y0)/2,:])
# pylab.show()
# pylab.plot(image2.as_numpy_array()[(z1-z0)/2,(y1-y0)/2,:])
# pylab.show()
# pylab.plot((image.as_double()-image2).as_numpy_array()[(z1-z0)/2,(y1-y0)/2,:])
# pylab.show()
# Test passed
print "OK"
def run(self):
from scitbx import matrix
from scitbx.array_family import flex
from dials.algorithms.shoebox import MaskCode
from dials.algorithms.profile_model.gaussian_rs import CoordinateSystem
from math import sqrt
assert (len(self.detector) == 1)
s0 = self.beam.get_s0()
m2 = self.goniometer.get_rotation_axis()
s0_length = matrix.col(self.beam.get_s0()).length()
width, height = self.detector[0].get_image_size()
zrange = self.scan.get_array_range()
phi0, dphi = self.scan.get_oscillation(deg=False)
# Generate some reflections
reflections = self.generate_reflections(10)
# Mask the foreground in each
self.mask_foreground(reflections['shoebox'], reflections['s1'],
reflections['xyzcal.px'].parts()[2],
reflections['panel'])
# Loop through all the reflections and check the mask values
shoebox = reflections['shoebox']
beam_vector = reflections['s1']
rotation_angle = reflections['xyzcal.mm'].parts()[2]
for l in range(len(reflections)):
mask = shoebox[l].mask
x0, x1, y0, y1, z0, z1 = shoebox[l].bbox
s1 = beam_vector[l]
phi = rotation_angle[l]
cs = CoordinateSystem(m2, s0, s1, phi)
def rs_coord(i, j, k):
s1d = self.detector[0].get_pixel_lab_coord((i, j))
s1d = matrix.col(s1d).normalize() * s0_length
e1, e2 = cs.from_beam_vector(s1d)
e3 = cs.from_rotation_angle_fast(phi0 + (k - zrange[0]) * dphi)
return e1, e2, e3
new_mask = flex.int(mask.accessor(), 0)
for k in range(z1 - z0):
for j in range(y1 - y0):
for i in range(x1 - x0):
#value1 = mask[k, j, i]
e11, e12, e13 = rs_coord(x0 + i, y0 + j, z0 + k)
e21, e22, e23 = rs_coord(x0 + i + 1, y0 + j, z0 + k)
e31, e32, e33 = rs_coord(x0 + i, y0 + j + 1, z0 + k)
e41, e42, e43 = rs_coord(x0 + i, y0 + j, z0 + k + 1)
e51, e52, e53 = rs_coord(x0 + i + 1, y0 + j + 1,
z0 + k)
e61, e62, e63 = rs_coord(x0 + i + 1, y0 + j,
z0 + k + 1)
e71, e72, e73 = rs_coord(x0 + i, y0 + j + 1,
z0 + k + 1)
e81, e82, e83 = rs_coord(x0 + i + 1, y0 + j + 1,
z0 + k + 1)
de1 = (e11 / self.delta_d)**2 + (
e12 / self.delta_d)**2 #+(e13/self.delta_m)**2
de2 = (e21 / self.delta_d)**2 + (
e22 / self.delta_d)**2 #+(e23/self.delta_m)**2
de3 = (e31 / self.delta_d)**2 + (
e32 / self.delta_d)**2 #+(e33/self.delta_m)**2
de4 = (e41 / self.delta_d)**2 + (
e42 / self.delta_d)**2 #+(e43/self.delta_m)**2
de5 = (e51 / self.delta_d)**2 + (
e52 / self.delta_d)**2 #+(e53/self.delta_m)**2
de6 = (e61 / self.delta_d)**2 + (
e62 / self.delta_d)**2 #+(e63/self.delta_m)**2
de7 = (e71 / self.delta_d)**2 + (
e72 / self.delta_d)**2 #+(e73/self.delta_m)**2
de8 = (e81 / self.delta_d)**2 + (
e82 / self.delta_d)**2 #+(e83/self.delta_m)**2
de = sqrt(min([de1, de2, de3, de4, de5, de6, de7,
de8]))
gx = min([e11, e21, e31, e41, e51, e61, e71, e81])
gy = min([e12, e22, e32, e42, e52, e62, e72, e82])
gz = min([e13, e23, e33, e43, e53, e63, e73, e83])
dee = (gx / self.delta_d)**2 + (
gy / self.delta_d)**2 # + (gz/self.delta_m)**2
#print sqrt(dee), de
if (x0 + i < 0 or y0 + j < 0 or x0 + i >= width
or y0 + j >= height or z0 + k < zrange[0]
or z0 + k >= zrange[1]):
value2 = MaskCode.Valid
else:
if de <= 1.0:
value2 = MaskCode.Valid | MaskCode.Foreground
else:
value2 = MaskCode.Valid | MaskCode.Background
new_mask[k, j, i] = value2
try:
assert (all(m1 == m2 for m1, m2 in zip(mask, new_mask)))
except Exception:
import numpy
numpy.set_printoptions(threshold=10000)
diff = (mask == new_mask).as_numpy_array()
print diff.astype(numpy.int)
#print mask.as_numpy_array()
#print new_mask.as_numpy_array()
#print (new_mask.as_numpy_array()[:,:,:] %2) * (new_mask.as_numpy_array() == 5)
raise
# Test passed
print 'OK'
def integrate(experiments, reflections, reference):
from dials.algorithms.profile_model.modeller import CircleSampler
from dials.array_family import flex
from dials.algorithms.profile_model.gaussian_rs.transform import TransformReverse
from dials.algorithms.profile_model.gaussian_rs.transform import TransformForward
from dials.algorithms.profile_model.gaussian_rs.transform import (
TransformReverseNoModel, )
from dials.algorithms.profile_model.gaussian_rs.transform import TransformSpec
from dials.algorithms.profile_model.gaussian_rs import CoordinateSystem
selection = reflections.get_flags(reflections.flags.integrated_sum)
reflections = reflections.select(selection)
print("Selected %d reflections to integrate" % len(reflections))
sampler = CircleSampler(
experiments[0].detector[0].get_image_size(),
experiments[0].scan.get_array_range(),
1,
)
n_sigma = 4.0
grid_size = 25
spec = TransformSpec(
experiments[0].beam,
experiments[0].detector,
experiments[0].goniometer,
experiments[0].scan,
experiments[0].profile.sigma_b(deg=False),
experiments[0].profile.sigma_m(deg=False),
n_sigma,
grid_size,
)
m2 = experiments[0].goniometer.get_rotation_axis()
s0 = experiments[0].beam.get_s0()
Iprf = flex.double(len(reflections))
Vprf = flex.double(len(reflections))
Cprf = flex.double(len(reflections))
Fprf = flex.bool(len(reflections))
for i, r in enumerate(reflections):
s1 = r["s1"]
phi = r["xyzcal.mm"][2]
xyz = r["xyzcal.px"]
bbox = r["bbox"]
panel = r["panel"]
image = r["shoebox"].data.as_double()
background = r["shoebox"].background.as_double()
mask = r["shoebox"].mask.as_1d(
) == 5 # | (r['shoebox'].mask.as_1d() == 3)
mask.reshape(image.accessor())
cs = CoordinateSystem(m2, s0, s1, phi)
index = sampler.nearest(0, xyz)
profile = reference[index]
# print flex.sum(profile)
# print r['partiality']
if False:
from dials.algorithms.integration.maximum_likelihood import (
ProfileFittingDouble as ProfileFitting, )
transform = TransformReverseNoModel(spec, cs, bbox, panel, profile)
p = transform.profile()
d = image
m = mask
b = background
# print flex.sum(p)
ysize, xsize = p.all()[1:3]
p1 = flex.double(flex.grid(1, ysize, xsize))
d1 = flex.double(flex.grid(1, ysize, xsize))
b1 = flex.double(flex.grid(1, ysize, xsize))
m1 = flex.double(flex.grid(1, ysize, xsize))
for k in range(p.all()[0]):
p1 += p[k:k + 1, :, :]
d1 += d[k:k + 1, :, :]
b1 += b[k:k + 1, :, :]
m1 = m[k:k + 1, :, :]
try:
fit = ProfileFitting(p1, m1, d1, b1, 1e-3, 1000)
assert fit.niter() < 1000
Iprf[i] = fit.intensity()
Vprf[i] = fit.variance()
Cprf[i] = fit.correlation()
Fprf[i] = True
print(i, fit.intensity(), flex.sum(p1))
# from matplotlib import pylab
# pylab.imshow(p1.as_numpy_array()[0,:,:], interpolation='none')
# pylab.show()
except Exception:
pass
else:
from dials.algorithms.integration.fit import (
ProfileFittingDouble as ProfileFitting, )
try:
transform = TransformForward(spec, cs, bbox, panel, image,
background, mask)
index = sampler.nearest(0, xyz)
p = reference[index]
d = transform.profile()
b = transform.background()
m = p > 0
fit = ProfileFitting(p, m, d, b, 1e-3, 1000)
assert fit.niter() < 1000
Iprf[i] = fit.intensity()
Vprf[i] = fit.variance()
Cprf[i] = fit.correlation()
Fprf[i] = True
print(i, fit.intensity(), flex.sum(p))
# from matplotlib import pylab
# pylab.imshow(p1.as_numpy_array()[0,:,:], interpolation='none')
# pylab.show()
except Exception:
pass
reflections["intensity.prf.value"] = Iprf
reflections["intensity.prf.variance"] = Vprf
reflections["intensity.prf.correlation"] = Cprf
reflections.set_flags(Fprf, reflections.flags.integrated_prf)
return reflections
def tst_conservation_of_counts(self):
from scitbx import matrix
from random import uniform, seed
from dials.algorithms.profile_model.gaussian_rs import CoordinateSystem
from dials.algorithms.profile_model.gaussian_rs import transform
from scitbx.array_family import flex
seed(0)
assert (len(self.detector) == 1)
s0 = self.beam.get_s0()
m2 = self.gonio.get_rotation_axis()
s0_length = matrix.col(self.beam.get_s0()).length()
# Create an s1 map
s1_map = transform.beam_vector_map(self.detector[0], self.beam, True)
for i in range(100):
# Get random x, y, z
x = uniform(300, 1800)
y = uniform(300, 1800)
z = uniform(500, 600)
# Get random s1, phi, panel
s1 = matrix.col(self.detector[0].get_pixel_lab_coord(
(x, y))).normalize() * s0_length
phi = self.scan.get_angle_from_array_index(z, deg=False)
panel = 0
# Calculate the bounding box
bbox = self.calculate_bbox(s1, z, panel)
x0, x1, y0, y1, z0, z1 = bbox
# Create the coordinate system
cs = CoordinateSystem(m2, s0, s1, phi)
if abs(cs.zeta()) < 0.1:
continue
# The grid index generator
step_size = self.delta_divergence / self.grid_size
grid_index = transform.GridIndexGenerator(cs, x0, y0,
(step_size, step_size),
self.grid_size, s1_map)
# Create the image
#image = flex.double(flex.grid(z1 - z0, y1 - y0, x1 - x0), 1)
image = gaussian((z1 - z0, y1 - y0, x1 - x0), 10.0,
(z - z0, y - y0, x - x0), (2.0, 2.0, 2.0))
mask = flex.bool(flex.grid(image.all()), False)
for j in range(y1 - y0):
for i in range(x1 - x0):
inside = False
gx00, gy00 = grid_index(j, i)
gx01, gy01 = grid_index(j, i + 1)
gx10, gy10 = grid_index(j + 1, i)
gx11, gy11 = grid_index(j + 1, i + 1)
mingx = min([gx00, gx01, gx10, gx11])
maxgx = max([gx00, gx01, gx10, gx11])
mingy = min([gy00, gy01, gy10, gy11])
maxgy = max([gy00, gy01, gy10, gy11])
if (mingx >= 0 and maxgx < 2 * self.grid_size + 1
and mingy >= 0 and maxgy < 2 * self.grid_size + 1):
inside = True
for k in range(1, z1 - z0 - 1):
mask[k, j, i] = inside
# Transform the image to the grid
transformed = transform.TransformForwardNoModel(
self.spec, cs, bbox, 0, image.as_double(), mask)
grid = transformed.profile()
# Get the sums and ensure they're the same
eps = 1e-7
sum_grid = flex.sum(grid)
sum_image = flex.sum(flex.double(flex.select(image, flags=mask)))
assert (abs(sum_grid - sum_image) <= eps)
mask = flex.bool(flex.grid(image.all()), True)
transformed = transform.TransformForwardNoModel(
self.spec, cs, bbox, 0, image.as_double(), mask)
grid = transformed.profile()
# Boost the bbox to make sure all intensity is included
x0, x1, y0, y1, z0, z1 = bbox
bbox2 = (x0 - 10, x1 + 10, y0 - 10, y1 + 10, z0 - 10, z1 + 10)
# Do the reverse transform
transformed = transform.TransformReverseNoModel(
self.spec, cs, bbox2, 0, grid)
image2 = transformed.profile()
# Check the sum of pixels are the same
sum_grid = flex.sum(grid)
sum_image = flex.sum(image2)
assert (abs(sum_grid - sum_image) <= eps)
# Do the reverse transform
transformed = transform.TransformReverseNoModel(
self.spec, cs, bbox, 0, grid)
image2 = transformed.profile()
from dials.algorithms.statistics import pearson_correlation_coefficient
cc = pearson_correlation_coefficient(image.as_1d().as_double(),
image2.as_1d())
assert (cc >= 0.99)
# if cc < 0.99:
# print cc, bbox
# from matplotlib import pylab
# pylab.plot(image.as_numpy_array()[(z1-z0)/2,(y1-y0)/2,:])
# pylab.show()
# pylab.plot(image2.as_numpy_array()[(z1-z0)/2,(y1-y0)/2,:])
# pylab.show()
# pylab.plot((image.as_double()-image2).as_numpy_array()[(z1-z0)/2,(y1-y0)/2,:])
# pylab.show()
# Test passed
print 'OK'
def test_map_frames_reverse(dials_data):
from dials.model.serialize import load
from dials.algorithms.profile_model.gaussian_rs.transform import MapFramesReverse
from dials.algorithms.profile_model.gaussian_rs import BBoxCalculator3D
sequence = load.sequence(
dials_data("centroid_test_data").join("sweep.json").strpath)
# Get the models
beam = sequence.get_beam()
detector = sequence.get_detector()
gonio = sequence.get_goniometer()
scan = sequence.get_scan()
# Set the delta_divergence/mosaicity
n_sigma = 3
sigma_divergence = 0.060 * math.pi / 180
mosaicity = 0.154 * math.pi / 180
delta_divergence = n_sigma * sigma_divergence
delta_mosaicity = n_sigma * mosaicity
# Set the grid size
grid_size = (4, 4, 4)
# Create the E3 fraction object
transform = MapFramesReverse(
scan.get_array_range()[0],
scan.get_oscillation(deg=False)[0],
scan.get_oscillation(deg=False)[1],
mosaicity,
n_sigma,
grid_size[2],
)
# Create the bounding box calculator
calculate_bbox = BBoxCalculator3D(beam, detector, gonio, scan,
delta_divergence, delta_mosaicity)
from dials.algorithms.profile_model.gaussian_rs import CoordinateSystem
from scitbx.array_family import flex
s0 = beam.get_s0()
m2 = gonio.get_rotation_axis()
s0_length = matrix.col(beam.get_s0()).length()
for i in range(100):
# Get random x, y, z
x = random.uniform(0, 2000)
y = random.uniform(0, 2000)
z = random.uniform(0, 9)
# Get random s1, phi, panel
s1 = matrix.col(detector[0].get_pixel_lab_coord(
(x, y))).normalize() * s0_length
phi = scan.get_angle_from_array_index(z, deg=False)
panel = 0
# Calculate the bounding box
bbox = calculate_bbox(s1, phi, panel)
x1, x2 = bbox[0], bbox[1]
y1, y2 = bbox[2], bbox[3]
z1, z2 = bbox[4], bbox[5]
if x1 == 0 or y1 == 0 or z1 == 0:
continue
if x2 == 2000 or y2 == 2000 or z2 == 9:
continue
# Create the XDS coordinate system
xcs = CoordinateSystem(m2, s0, s1, phi)
# Calculate the transform fraction
fraction = transform(bbox[4:], phi, xcs.zeta())
# Ensure the minimum and maximum are 0 < 1
fmax = flex.max(fraction)
fmin = flex.min(fraction)
assert fmax <= 1.0 and fmax > 0.0
assert fmin >= 0.0 and fmin <= 1.0
# Ensure the fraction for image adds up to 1.0 for
# all those images completely within the image
for v3 in range(fraction.all()[0]):
tot = flex.sum(fraction[v3:v3 + 1, :])
assert abs(tot - 1.0) < 1e-7
# Ensure the frames follow a progression through the grid. I.e,
# check that values increase then decrease and don't jump around
for v3 in range(fraction.all()[0]):
f = fraction[v3:v3 + 1, :]
last = f[0]
rev = False
for i in range(1, len(f)):
curr = f[1]
if rev is False:
if curr < last:
rev = True
else:
assert curr <= last
last = curr
def test(dials_data):
from dxtbx.model.experiment_list import Experiment, ExperimentList
from dxtbx.serialize import load
from dials.algorithms.profile_model.gaussian_rs import MaskCalculator3D, Model
sequence = load.imageset(
dials_data("centroid_test_data").join("sweep.json").strpath)
crystal = load.crystal(
dials_data("centroid_test_data").join("crystal.json").strpath)
beam = sequence.get_beam()
detector = sequence.get_detector()
goniometer = sequence.get_goniometer()
scan = sequence.get_scan()
delta_d = 3 * beam.get_sigma_divergence(deg=False)
try:
mosaicity = crystal.get_mosaicity(deg=False)
except AttributeError:
mosaicity = 0
delta_m = 3 * mosaicity
nsigma = 3
profile_model = Model(None, nsigma, beam.get_sigma_divergence(deg=False),
mosaicity)
experiment = ExperimentList()
experiment.append(
Experiment(
imageset=sequence,
beam=beam,
detector=detector,
goniometer=goniometer,
scan=scan,
crystal=crystal,
profile=profile_model,
))
assert len(detector) == 1
# Get the function object to mask the foreground
mask_foreground = MaskCalculator3D(beam, detector, goniometer, scan,
delta_d, delta_m)
from scitbx.array_family import flex
from dials.algorithms.profile_model.gaussian_rs import CoordinateSystem
from dials.algorithms.shoebox import MaskCode
s0 = beam.get_s0()
m2 = goniometer.get_rotation_axis()
s0_length = matrix.col(beam.get_s0()).length()
width, height = detector[0].get_image_size()
zrange = scan.get_array_range()
phi0, dphi = scan.get_oscillation(deg=False)
# Generate some reflections
reflections = generate_reflections(detector, beam, scan, experiment, 10)
# Mask the foreground in each
mask_foreground(
reflections["shoebox"],
reflections["s1"],
reflections["xyzcal.px"].parts()[2],
reflections["panel"],
)
# Loop through all the reflections and check the mask values
shoebox = reflections["shoebox"]
beam_vector = reflections["s1"]
rotation_angle = reflections["xyzcal.mm"].parts()[2]
for l in range(len(reflections)):
mask = shoebox[l].mask
x0, x1, y0, y1, z0, z1 = shoebox[l].bbox
s1 = beam_vector[l]
phi = rotation_angle[l]
cs = CoordinateSystem(m2, s0, s1, phi)
def rs_coord(i, j, k):
s1d = detector[0].get_pixel_lab_coord((i, j))
s1d = matrix.col(s1d).normalize() * s0_length
e1, e2 = cs.from_beam_vector(s1d)
e3 = cs.from_rotation_angle_fast(phi0 + (k - zrange[0]) * dphi)
return e1, e2, e3
new_mask = flex.int(mask.accessor(), 0)
for k in range(z1 - z0):
for j in range(y1 - y0):
for i in range(x1 - x0):
# value1 = mask[k, j, i]
e11, e12, e13 = rs_coord(x0 + i, y0 + j, z0 + k)
e21, e22, e23 = rs_coord(x0 + i + 1, y0 + j, z0 + k)
e31, e32, e33 = rs_coord(x0 + i, y0 + j + 1, z0 + k)
e41, e42, e43 = rs_coord(x0 + i, y0 + j, z0 + k + 1)
e51, e52, e53 = rs_coord(x0 + i + 1, y0 + j + 1, z0 + k)
e61, e62, e63 = rs_coord(x0 + i + 1, y0 + j, z0 + k + 1)
e71, e72, e73 = rs_coord(x0 + i, y0 + j + 1, z0 + k + 1)
e81, e82, e83 = rs_coord(x0 + i + 1, y0 + j + 1,
z0 + k + 1)
de1 = (e11 / delta_d)**2 + (
e12 / delta_d)**2 # +(e13/delta_m)**2
de2 = (e21 / delta_d)**2 + (
e22 / delta_d)**2 # +(e23/delta_m)**2
de3 = (e31 / delta_d)**2 + (
e32 / delta_d)**2 # +(e33/delta_m)**2
de4 = (e41 / delta_d)**2 + (
e42 / delta_d)**2 # +(e43/delta_m)**2
de5 = (e51 / delta_d)**2 + (
e52 / delta_d)**2 # +(e53/delta_m)**2
de6 = (e61 / delta_d)**2 + (
e62 / delta_d)**2 # +(e63/delta_m)**2
de7 = (e71 / delta_d)**2 + (
e72 / delta_d)**2 # +(e73/delta_m)**2
de8 = (e81 / delta_d)**2 + (
e82 / delta_d)**2 # +(e83/delta_m)**2
de = math.sqrt(
min([de1, de2, de3, de4, de5, de6, de7, de8]))
if (x0 + i < 0 or y0 + j < 0 or x0 + i >= width
or y0 + j >= height or z0 + k < zrange[0]
or z0 + k >= zrange[1]):
value2 = MaskCode.Valid
else:
if de <= 1.0:
value2 = MaskCode.Valid | MaskCode.Foreground
else:
value2 = MaskCode.Valid | MaskCode.Background
new_mask[k, j, i] = value2
if not all(m1 == m2 for m1, m2 in zip(mask, new_mask)):
np.set_printoptions(threshold=10000)
diff = (mask == new_mask).as_numpy_array()
print(diff.astype(np.int))
# print mask.as_numpy_array()
# print new_mask.as_numpy_array()
# print (new_mask.as_numpy_array()[:,:,:] %2) * (new_mask.as_numpy_array() == 5)
assert False
def tst_outer_bounds(self):
from scitbx import matrix
from random import uniform
from dials.algorithms.profile_model.gaussian_rs import CoordinateSystem
assert (len(self.detector) == 1)
s0 = self.beam.get_s0()
m2 = self.gonio.get_rotation_axis()
s0_length = matrix.col(self.beam.get_s0()).length()
width, height = self.detector[0].get_image_size()
zrange = self.scan.get_array_range()
for i in range(1000):
# Get random x, y, z
x = uniform(0, 2000)
y = uniform(0, 2000)
z = uniform(0, 9)
# Get random s1, phi, panel
s1 = matrix.col(self.detector[0].get_pixel_lab_coord(
(x, y))).normalize() * s0_length
phi = self.scan.get_angle_from_array_index(z, deg=False)
panel = 0
# Calculate the bounding box
bbox = self.calculate_bbox(s1, z, panel)
x1, x2 = bbox[0], bbox[1]
y1, y2 = bbox[2], bbox[3]
z1, z2 = bbox[4], bbox[5]
# Calculate the rotation angle for each point
phi_dash1 = self.scan.get_angle_from_array_index(z1, deg=False)
phi_dash2 = self.scan.get_angle_from_array_index(z2, deg=False)
# Create the XDS coordinate system
xcs = CoordinateSystem(m2, s0, s1, phi)
# Calculate reciprocal space coordinates at each point
e11, e21, e31 = xcs.from_beam_vector_and_rotation_angle(
s1, phi_dash1)
e12, e22, e32 = xcs.from_beam_vector_and_rotation_angle(
s1, phi_dash2)
# Check vertical edges
for j in range(bbox[2], bbox[3] + 1):
xyz1 = self.detector[0].get_pixel_lab_coord((bbox[0], j))
xyz2 = self.detector[0].get_pixel_lab_coord((bbox[1] + 1, j))
sdash1 = matrix.col(xyz1).normalize() * s0_length
sdash2 = matrix.col(xyz2).normalize() * s0_length
e11, e21, e3 = xcs.from_beam_vector_and_rotation_angle(
sdash1, phi)
e12, e22, e3 = xcs.from_beam_vector_and_rotation_angle(
sdash2, phi)
if bbox[0] > 0 and bbox[1] < width:
assert (abs(e11) >= self.delta_divergence
or abs(e21) >= self.delta_divergence)
assert (abs(e12) >= self.delta_divergence
or abs(e22) >= self.delta_divergence)
# Check horizontal edges
for i in range(bbox[0], bbox[1] + 1):
xyz1 = self.detector[0].get_pixel_lab_coord((i, bbox[2]))
xyz2 = self.detector[0].get_pixel_lab_coord((i, bbox[3] + 1))
sdash1 = matrix.col(xyz1).normalize() * s0_length
sdash2 = matrix.col(xyz2).normalize() * s0_length
e11, e21, e3 = xcs.from_beam_vector_and_rotation_angle(
sdash1, phi)
e12, e22, e3 = xcs.from_beam_vector_and_rotation_angle(
sdash2, phi)
if bbox[2] > 0 and bbox[3] < height:
assert (abs(e11) >= self.delta_divergence
or abs(e21) >= self.delta_divergence)
assert (abs(e12) >= self.delta_divergence
or abs(e22) >= self.delta_divergence)
# All e3 coords >= delta_mosaicity
if bbox[4] > zrange[0] and bbox[5] < zrange[1]:
assert (abs(e31) >= self.delta_mosaicity)
assert (abs(e32) >= self.delta_mosaicity)
print 'OK'
