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authorWillem Jan Palenstijn <Willem.Jan.Palenstijn@cwi.nl>2019-01-25 14:08:33 +0100
committerWillem Jan Palenstijn <Willem.Jan.Palenstijn@cwi.nl>2019-01-30 17:07:55 +0100
commit22342b7a1bd169c474cf323709e36f553ac4aee1 (patch)
tree63b9edf1c08fdbc50acdb61c737417b56aa7e7d1 /tests/python/test_line2d.py
parent37643b309520bcd12afcee430210632db305d21f (diff)
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test_line2d: Add tests for distance_driven projector
Diffstat (limited to 'tests/python/test_line2d.py')
-rw-r--r--tests/python/test_line2d.py247
1 files changed, 174 insertions, 73 deletions
diff --git a/tests/python/test_line2d.py b/tests/python/test_line2d.py
index de68033..7b46458 100644
--- a/tests/python/test_line2d.py
+++ b/tests/python/test_line2d.py
@@ -58,6 +58,53 @@ def intersect_line_rectangle_interval(src, det, xmin, xmax, ymin, ymax, f):
c = intersect_line_rectangle_feather(src, det, xmin, xmax, ymin, ymax, f)
return (a,b,c)
+
+# x-coord of intersection of the line (src, det) with the horizontal line at y
+def intersect_line_horizontal(src, det, y):
+ EPS = 1e-5
+
+ if np.abs(src[1] - det[1]) < EPS:
+ return np.nan
+
+ t = (y - src[1]) / (det[1] - src[1])
+
+ return src[0] + t * (det[0] - src[0])
+
+
+# length of the intersection of the strip with boundaries edge1, edge2 with the horizontal
+# segment at y, with horizontal extent x_seg
+def intersect_ray_horizontal_segment(edge1, edge2, y, x_seg):
+ e1 = intersect_line_horizontal(edge1[0], edge1[1], y)
+ e2 = intersect_line_horizontal(edge2[0], edge2[1], y)
+
+ if not (np.isfinite(e1) and np.isfinite(e2)):
+ return np.nan
+
+ (e1, e2) = np.sort([e1, e2])
+ (x1, x2) = np.sort(x_seg)
+ l = np.max([e1, x1])
+ r = np.min([e2, x2])
+ #print(edge1, edge2, y, x_seg, r-l)
+ return np.max([r-l, 0.0])
+
+def intersect_ray_vertical_segment(edge1, edge2, x, y_seg):
+ # mirror edge1 and edge2
+ edge1 = [ (a[1], a[0]) for a in edge1 ]
+ edge2 = [ (a[1], a[0]) for a in edge2 ]
+ return intersect_ray_horizontal_segment(edge1, edge2, x, y_seg)
+
+
+
+
+
+
+# LINE GENERATORS
+# ---------------
+#
+# Per ray these yield three lines, at respectively the center and two edges of the detector pixel.
+# Each line is given by two points on the line.
+# ( ( (p0x, p0y), (q0x, q0y) ), ( (p1x, p1y), (q1x, q1y) ), ( (p2x, p2y), (q2x, q2y) ) )
+
def gen_lines_fanflat(proj_geom):
angles = proj_geom['ProjectionAngles']
for theta in angles:
@@ -76,7 +123,9 @@ def gen_lines_fanflat(proj_geom):
detb= detc + (0.5 - 0.5*proj_geom['DetectorCount']) * detu
for i in range(proj_geom['DetectorCount']):
- yield (src, detb + i * detu)
+ yield ((src, detb + i * detu),
+ (src, detb + (i - 0.5) * detu),
+ (src, detb + (i + 0.5) * detu))
def gen_lines_fanflat_vec(proj_geom):
v = proj_geom['Vectors']
@@ -87,7 +136,9 @@ def gen_lines_fanflat_vec(proj_geom):
detb = detc + (0.5 - 0.5*proj_geom['DetectorCount']) * detu
for i in range(proj_geom['DetectorCount']):
- yield (src, detb + i * detu)
+ yield ((src, detb + i * detu),
+ (src, detb + (i - 0.5) * detu),
+ (src, detb + (i + 0.5) * detu))
def gen_lines_parallel(proj_geom):
angles = proj_geom['ProjectionAngles']
@@ -106,7 +157,10 @@ def gen_lines_parallel(proj_geom):
detb= detc + (0.5 - 0.5*proj_geom['DetectorCount']) * detu
for i in range(proj_geom['DetectorCount']):
- yield (detb + i * detu - ray, detb + i * detu)
+ yield ((detb + i * detu - ray, detb + i * detu),
+ (detb + (i - 0.5) * detu - ray, detb + (i - 0.5) * detu),
+ (detb + (i + 0.5) * detu - ray, detb + (i + 0.5) * detu))
+
def gen_lines_parallel_vec(proj_geom):
v = proj_geom['Vectors']
@@ -118,7 +172,9 @@ def gen_lines_parallel_vec(proj_geom):
detb = detc + (0.5 - 0.5*proj_geom['DetectorCount']) * detu
for i in range(proj_geom['DetectorCount']):
- yield (detb + i * detu - ray, detb + i * detu)
+ yield ((detb + i * detu - ray, detb + i * detu),
+ (detb + (i - 0.5) * detu - ray, detb + (i - 0.5) * detu),
+ (detb + (i + 0.5) * detu - ray, detb + (i + 0.5) * detu))
def gen_lines(proj_geom):
@@ -179,8 +235,8 @@ def gen_random_geometry_parallel_vec():
nloops = 50
seed = 123
-class TestLineKernel(unittest.TestCase):
- def single_test(self, type):
+class Test2DKernel(unittest.TestCase):
+ def single_test(self, type, proj_type):
shape = np.random.randint(*range2d, size=2)
# these rectangles are biased, but that shouldn't matter
rect_min = [ np.random.randint(0, a) for a in shape ]
@@ -201,16 +257,16 @@ class TestLineKernel(unittest.TestCase):
if type == 'parallel':
pg = gen_random_geometry_parallel()
- projector_id = astra.create_projector('line', pg, vg)
+ projector_id = astra.create_projector(proj_type, pg, vg)
elif type == 'parallel_vec':
pg = gen_random_geometry_parallel_vec()
- projector_id = astra.create_projector('line', pg, vg)
+ projector_id = astra.create_projector(proj_type, pg, vg)
elif type == 'fanflat':
pg = gen_random_geometry_fanflat()
- projector_id = astra.create_projector('line_fanflat', pg, vg)
+ projector_id = astra.create_projector(proj_type + '_fanflat', pg, vg)
elif type == 'fanflat_vec':
pg = gen_random_geometry_fanflat_vec()
- projector_id = astra.create_projector('line_fanflat', pg, vg)
+ projector_id = astra.create_projector(proj_type + '_fanflat', pg, vg)
data = np.zeros((shape[1], shape[0]), dtype=np.float32)
@@ -225,84 +281,129 @@ class TestLineKernel(unittest.TestCase):
astra.projector.delete(projector_id)
- a = np.zeros(np.prod(astra.functions.geom_size(pg)), dtype=np.float32)
- b = np.zeros(np.prod(astra.functions.geom_size(pg)), dtype=np.float32)
- c = np.zeros(np.prod(astra.functions.geom_size(pg)), dtype=np.float32)
-
- i = 0
- #print( origin[0] + (-0.5 * shape[0] + rect_min[0]) * pixsize[0], origin[0] + (-0.5 * shape[0] + rect_max[0]) * pixsize[0], origin[1] + (-0.5 * shape[1] + rect_min[1]) * pixsize[1], origin[1] + (-0.5 * shape[1] + rect_max[1]) * pixsize[1])
- for src, det in gen_lines(pg):
- #print(src,det)
-
- # NB: Flipped y-axis here, since that is how astra interprets 2D volumes
- # We compute line intersections with slightly bigger (cw) and
- # smaller (aw) rectangles, and see if the kernel falls
- # between these two values.
- (aw,bw,cw) = intersect_line_rectangle_interval(src, det,
- origin[0] + (-0.5 * shape[0] + rect_min[0]) * pixsize[0],
- origin[0] + (-0.5 * shape[0] + rect_max[0]) * pixsize[0],
- origin[1] + (+0.5 * shape[1] - rect_max[1]) * pixsize[1],
- origin[1] + (+0.5 * shape[1] - rect_min[1]) * pixsize[1],
- 1e-3)
- a[i] = aw
- b[i] = bw
- c[i] = cw
- i += 1
- # Add weight for pixel / voxel size
- try:
- detweight = pg['DetectorWidth']
- except KeyError:
- detweight = np.sqrt(pg['Vectors'][0,4]*pg['Vectors'][0,4] + pg['Vectors'][0,5]*pg['Vectors'][0,5] )
- a *= detweight
- b *= detweight
- c *= detweight
- a = a.reshape(astra.functions.geom_size(pg))
- b = b.reshape(astra.functions.geom_size(pg))
- c = c.reshape(astra.functions.geom_size(pg))
-
- # Check if sinogram lies between a and c
- y = np.min(sinogram-a)
- z = np.min(c-sinogram)
- x = np.max(np.abs(sinogram-b)) # ideally this is small, but can be large
- # due to discontinuities in line kernel
- self.assertFalse(z < 0 or y < 0)
- if z < 0 or y < 0:
- print(y,z,x)
- pylab.gray()
- pylab.imshow(data)
- pylab.figure()
- pylab.imshow(sinogram)
- pylab.figure()
- pylab.imshow(b)
- pylab.figure()
- pylab.imshow(a)
- pylab.figure()
- pylab.imshow(c)
- pylab.figure()
- pylab.imshow(sinogram-a)
- pylab.figure()
- pylab.imshow(c-sinogram)
- pylab.show()
+ if proj_type == 'line':
+
+ a = np.zeros(np.prod(astra.functions.geom_size(pg)), dtype=np.float32)
+ b = np.zeros(np.prod(astra.functions.geom_size(pg)), dtype=np.float32)
+ c = np.zeros(np.prod(astra.functions.geom_size(pg)), dtype=np.float32)
+
+ i = 0
+ #print( origin[0] + (-0.5 * shape[0] + rect_min[0]) * pixsize[0], origin[0] + (-0.5 * shape[0] + rect_max[0]) * pixsize[0], origin[1] + (-0.5 * shape[1] + rect_min[1]) * pixsize[1], origin[1] + (-0.5 * shape[1] + rect_max[1]) * pixsize[1])
+ for center, edge1, edge2 in gen_lines(pg):
+ (src, det) = center
+ #print(src,det)
+
+ # NB: Flipped y-axis here, since that is how astra interprets 2D volumes
+ # We compute line intersections with slightly bigger (cw) and
+ # smaller (aw) rectangles, and see if the kernel falls
+ # between these two values.
+ (aw,bw,cw) = intersect_line_rectangle_interval(src, det,
+ origin[0] + (-0.5 * shape[0] + rect_min[0]) * pixsize[0],
+ origin[0] + (-0.5 * shape[0] + rect_max[0]) * pixsize[0],
+ origin[1] + (+0.5 * shape[1] - rect_max[1]) * pixsize[1],
+ origin[1] + (+0.5 * shape[1] - rect_min[1]) * pixsize[1],
+ 1e-3)
+ a[i] = aw
+ b[i] = bw
+ c[i] = cw
+ i += 1
+ # Add weight for pixel / voxel size
+ try:
+ detweight = pg['DetectorWidth']
+ except KeyError:
+ detweight = np.sqrt(pg['Vectors'][0,4]*pg['Vectors'][0,4] + pg['Vectors'][0,5]*pg['Vectors'][0,5] )
+ a *= detweight
+ b *= detweight
+ c *= detweight
+ a = a.reshape(astra.functions.geom_size(pg))
+ b = b.reshape(astra.functions.geom_size(pg))
+ c = c.reshape(astra.functions.geom_size(pg))
+
+ # Check if sinogram lies between a and c
+ y = np.min(sinogram-a)
+ z = np.min(c-sinogram)
+ x = np.max(np.abs(sinogram-b)) # ideally this is small, but can be large
+ # due to discontinuities in line kernel
+ self.assertFalse(z < 0 or y < 0)
+ if z < 0 or y < 0:
+ print(y,z,x)
+ pylab.gray()
+ pylab.imshow(data)
+ pylab.figure()
+ pylab.imshow(sinogram)
+ pylab.figure()
+ pylab.imshow(b)
+ pylab.figure()
+ pylab.imshow(a)
+ pylab.figure()
+ pylab.imshow(c)
+ pylab.figure()
+ pylab.imshow(sinogram-a)
+ pylab.figure()
+ pylab.imshow(c-sinogram)
+ pylab.show()
+ elif proj_type == 'distance_driven':
+ a = np.zeros(np.prod(astra.functions.geom_size(pg)), dtype=np.float32)
+ i = 0
+ for center, edge1, edge2 in gen_lines(pg):
+ (xd, yd) = center[1] - center[0]
+ l = 0.0
+ if np.abs(xd) > np.abs(yd): # horizontal ray
+ y_seg = (origin[1] + (+0.5 * shape[1] - rect_max[1]) * pixsize[1],
+ origin[1] + (+0.5 * shape[1] - rect_min[1]) * pixsize[1])
+ for j in range(rect_min[0], rect_max[0]):
+ x = origin[0] + (-0.5 * shape[0] + j + 0.5) * pixsize[0]
+ l += intersect_ray_vertical_segment(edge1, edge2, x, y_seg) * pixsize[0]
+ else:
+ x_seg = (origin[0] + (-0.5 * shape[0] + rect_max[0]) * pixsize[0],
+ origin[0] + (-0.5 * shape[0] + rect_min[0]) * pixsize[0])
+ for j in range(rect_min[1], rect_max[1]):
+ y = origin[1] + (+0.5 * shape[1] - j - 0.5) * pixsize[1]
+ l += intersect_ray_horizontal_segment(edge1, edge2, y, x_seg) * pixsize[1]
+ a[i] = l
+ i += 1
+ a = a.reshape(astra.functions.geom_size(pg))
+ x = np.max(np.abs(sinogram-a))
+ if x > 2e-3:
+ pylab.gray()
+ pylab.imshow(data)
+ pylab.figure()
+ pylab.imshow(sinogram)
+ pylab.figure()
+ pylab.imshow(a)
+ pylab.figure()
+ pylab.imshow(sinogram-a)
+ pylab.show()
+ self.assertFalse(x > 2e-3)
+
def test_par(self):
np.random.seed(seed)
for _ in range(nloops):
- self.single_test('parallel')
+ self.single_test('parallel', 'line')
+ def test_par_dd(self):
+ np.random.seed(seed)
+ for _ in range(nloops):
+ self.single_test('parallel', 'distance_driven')
def test_fan(self):
np.random.seed(seed)
for _ in range(nloops):
- self.single_test('fanflat')
+ self.single_test('fanflat', 'line')
def test_parvec(self):
np.random.seed(seed)
for _ in range(nloops):
- self.single_test('parallel_vec')
+ self.single_test('parallel_vec', 'line')
+ def test_parvec_dd(self):
+ np.random.seed(seed)
+ for _ in range(nloops):
+ self.single_test('parallel_vec', 'distance_driven')
def test_fanvec(self):
np.random.seed(seed)
for _ in range(nloops):
- self.single_test('fanflat_vec')
+ self.single_test('fanflat_vec', 'line')
+
-
if __name__ == '__main__':
unittest.main()