def create_uv_tree(obj, quantity, uv_center, mean = [0.0, 0.0], variance = [0.005, 0.005], balancing_factor = 0.0, build_type = 'CURVE', interpolation_resolution = 0):
# Generate scattered points
x = [uv_center[0]]
y = [uv_center[1]]
x = np.concatenate((x, np.random.normal(uv_center[0], variance[0], quantity) + mean[0]))
y = np.concatenate((y, np.random.normal(uv_center[1], variance[1], quantity) + mean[1]))
points = np.dstack((x, y))
np.clip(points, 0., 1., out = points)
# all items are stored in the first list-item of the output
points = points[0]
# Run mstree
root_point = mstree.mstree(points, balancing_factor)
# Convert node positions from uv to 3d
nodes = mstree.tree_to_list(root_point)
interpolated_nodes = []
for node in nodes:
parent = node.parent
interpolated_nodes.append(node)
if parent is None:
continue
points = interpolate(parent.pos, node.pos, interpolation_resolution)[1:-1]
print(len(points))
parent.children.remove(node)
active_parent = parent
for point in points:
new_node = mstree.Node(active_parent, np.array(point), -1)
interpolated_nodes.append(new_node)
active_parent = new_node
node.parent = active_parent
active_parent.children.append(node)
node_uv_points = [mathutils.Vector((node.pos[0], node.pos[1])) for node in interpolated_nodes]
print(len(node_uv_points))
node_3d_points = pam.mapUVPointTo3d(obj, node_uv_points)
print(len(node_3d_points))
for i, node in enumerate(interpolated_nodes):
node.pos = node_3d_points[i]
if build_type == 'CURVE':
curve_obj = mst_blender.buildTreeCurve(root_point)
curve_obj.data.bevel_depth = 0.002
elif build_type == 'MESH':
mesh_obj = mst_blender.buildTreeMesh(root_point)
def export_swc(root_node, outfilename, structure_identifier = 2):
nodes = mstree.tree_to_list(root_node)
f = open(outfilename, 'w')
index = 0
for node in nodes:
node.index = index
index += 1
if node.parent is not None:
parent_index = node.parent.index
else:
parent_index = -1
f.write(' '.join((str(node.index), str(structure_identifier), str(node.pos[0]), str(node.pos[1]), str(node.pos[2]), str(0), str(parent_index))))
f.write('\n')
f.close()
def export_swc(root_node, outfilename, structure_identifier=2):
nodes = mstree.tree_to_list(root_node)
f = open(outfilename, 'w')
index = 0
for node in nodes:
node.index = index
index += 1
if node.parent is not None:
parent_index = node.parent.index
else:
parent_index = -1
f.write(' '.join(
(str(node.index), str(structure_identifier), str(node.pos[0]),
str(node.pos[1]), str(node.pos[2]), str(0), str(parent_index))))
f.write('\n')
f.close()
def create_uv_tree(obj,
quantity,
uv_center,
mean=[0.0, 0.0],
variance=[0.005, 0.005],
balancing_factor=0.0,
build_type='CURVE',
interpolation_resolution=0):
# Generate scattered points
x = [uv_center[0]]
y = [uv_center[1]]
x = np.concatenate(
(x, np.random.normal(uv_center[0], variance[0], quantity) + mean[0]))
y = np.concatenate(
(y, np.random.normal(uv_center[1], variance[1], quantity) + mean[1]))
points = np.dstack((x, y))
np.clip(points, 0., 1., out=points)
# all items are stored in the first list-item of the output
points = points[0]
# Run mstree
root_point = mstree.mstree(points, balancing_factor)
# Convert node positions from uv to 3d
nodes = mstree.tree_to_list(root_point)
interpolated_nodes = []
for node in nodes:
parent = node.parent
interpolated_nodes.append(node)
if parent is None:
continue
points = interpolate(parent.pos, node.pos,
interpolation_resolution)[1:-1]
print(len(points))
parent.children.remove(node)
active_parent = parent
for point in points:
new_node = mstree.Node(active_parent, np.array(point), -1)
interpolated_nodes.append(new_node)
active_parent = new_node
node.parent = active_parent
active_parent.children.append(node)
node_uv_points = [
mathutils.Vector((node.pos[0], node.pos[1]))
for node in interpolated_nodes
]
print(len(node_uv_points))
node_3d_points = pam.mapUVPointTo3d(obj, node_uv_points)
print(len(node_3d_points))
for i, node in enumerate(interpolated_nodes):
node.pos = node_3d_points[i]
if build_type == 'CURVE':
curve_obj = mst_blender.buildTreeCurve(root_point)
curve_obj.data.bevel_depth = 0.002
elif build_type == 'MESH':
mesh_obj = mst_blender.buildTreeMesh(root_point)
