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unit='LENGTH',
description="Length"
)
Simple_rounded : FloatProperty(
name="Rounded",
default=0.0,
min=0.0, soft_min=0.0,
unit='LENGTH',
description="Rounded corners"
)
# Curve Options
shapeItems = [
('2D', "2D", "2D shape Curve"),
('3D', "3D", "3D shape Curve")]
name="2D / 3D",
items=shapeItems,
description="2D or 3D Curve"
)
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outputType : EnumProperty(
name="Output splines",
description="Type of splines to output",
items=[
('POLY', "Poly", "Poly Spline type"),
('NURBS', "Nurbs", "Nurbs Spline type"),
('BEZIER', "Bezier", "Bezier Spline type")],
default='BEZIER'
)
use_cyclic_u : BoolProperty(
name="Cyclic",
default=True,
description="make curve closed"
)
endp_u : BoolProperty(
name="Use endpoint u",
default=True,
description="stretch to endpoints"
)
order_u : IntProperty(
name="Order u",
default=4,
min=2, soft_min=2,
max=6, soft_max=6,
description="Order of nurbs spline"
)
handleType : EnumProperty(
name="Handle type",
default='VECTOR',
description="Bezier handles type",
items=[
('VECTOR', "Vector", "Vector type Bezier handles"),
('AUTO', "Auto", "Automatic type Bezier handles")]
)
def draw(self, context):
layout = self.layout
# general options
col = layout.column()
col.prop(self, "Simple_Type")
l = 0
s = 0
if self.Simple_Type == 'Line':
box = layout.box()
col = box.column(align=True)
col.label(text=self.Simple_Type + " Options:")
col.prop(self, "Simple_endlocation")
v = Vector(self.Simple_endlocation) - Vector(self.Simple_startlocation)
l = v.length
if self.Simple_Type == 'Distance':
box = layout.box()
col = box.column(align=True)
col.label(text=self.Simple_Type + " Options:")
col.prop(self, "Simple_length")
col.prop(self, "Simple_center")
l = self.Simple_length
if self.Simple_Type == 'Angle':
box = layout.box()
col = box.column(align=True)
col.label(text=self.Simple_Type + " Options:")
col.prop(self, "Simple_length")
col.prop(self, "Simple_angle")
#row = layout.row()
#row.prop(self, "Simple_degrees_or_radians", expand=True)
if self.Simple_Type == 'Circle':
box = layout.box()
col = box.column(align=True)
col.label(text=self.Simple_Type + " Options:")
col.prop(self, "Simple_sides")
col.prop(self, "Simple_radius")
l = 2 * pi * abs(self.Simple_radius)
s = pi * self.Simple_radius * self.Simple_radius
if self.Simple_Type == 'Ellipse':
box = layout.box()
col = box.column(align=True)
col.label(text=self.Simple_Type + " Options:")
col.prop(self, "Simple_a", text="Radius a")
col.prop(self, "Simple_b", text="Radius b")
l = pi * (3 * (self.Simple_a + self.Simple_b) -
sqrt((3 * self.Simple_a + self.Simple_b) *
(self.Simple_a + 3 * self.Simple_b)))
s = pi * abs(self.Simple_b) * abs(self.Simple_a)
if self.Simple_Type == 'Arc':
box = layout.box()
col = box.column(align=True)
col.label(text=self.Simple_Type + " Options:")
col.prop(self, "Simple_sides")
col.prop(self, "Simple_radius")
col = box.column(align=True)
col.prop(self, "Simple_startangle")
col.prop(self, "Simple_endangle")
#row = layout.row()
#row.prop(self, "Simple_degrees_or_radians", expand=True)
l = abs(pi * self.Simple_radius * (self.Simple_endangle - self.Simple_startangle) / 180)
if self.Simple_Type == 'Sector':
box = layout.box()
col = box.column(align=True)
col.label(text=self.Simple_Type + " Options:")
col.prop(self, "Simple_sides")
col.prop(self, "Simple_radius")
col = box.column(align=True)
col.prop(self, "Simple_startangle")
col.prop(self, "Simple_endangle")
#row = layout.row()
#row.prop(self, "Simple_degrees_or_radians", expand=True)
l = abs(pi * self.Simple_radius *
(self.Simple_endangle - self.Simple_startangle) / 180) + self.Simple_radius * 2
s = pi * self.Simple_radius * self.Simple_radius * \
abs(self.Simple_endangle - self.Simple_startangle) / 360
if self.Simple_Type == 'Segment':
box = layout.box()
col = box.column(align=True)
col.label(text=self.Simple_Type + " Options:")
col.prop(self, "Simple_sides")
col.prop(self, "Simple_a", text="Radius a")
col.prop(self, "Simple_b", text="Radius b")
col = box.column(align=True)
col.prop(self, "Simple_startangle")
col.prop(self, "Simple_endangle")
#row = layout.row()
#row.prop(self, "Simple_degrees_or_radians", expand=True)
la = abs(pi * self.Simple_a * (self.Simple_endangle - self.Simple_startangle) / 180)
lb = abs(pi * self.Simple_b * (self.Simple_endangle - self.Simple_startangle) / 180)
l = abs(self.Simple_a - self.Simple_b) * 2 + la + lb
sa = pi * self.Simple_a * self.Simple_a * \
abs(self.Simple_endangle - self.Simple_startangle) / 360
sb = pi * self.Simple_b * self.Simple_b * \
abs(self.Simple_endangle - self.Simple_startangle) / 360
s = abs(sa - sb)
if self.Simple_Type == 'Rectangle':
box = layout.box()
col = box.column(align=True)
col.label(text=self.Simple_Type + " Options:")
col.prop(self, "Simple_width")
col.prop(self, "Simple_length")
col.prop(self, "Simple_rounded")
box.prop(self, "Simple_center")
l = 2 * abs(self.Simple_width) + 2 * abs(self.Simple_length)
s = abs(self.Simple_width) * abs(self.Simple_length)
if self.Simple_Type == 'Rhomb':
box = layout.box()
col = box.column(align=True)
col.label(text=self.Simple_Type + " Options:")
col.prop(self, "Simple_width")
col.prop(self, "Simple_length")
col.prop(self, "Simple_center")
g = hypot(self.Simple_width / 2, self.Simple_length / 2)
l = 4 * g
s = self.Simple_width * self.Simple_length / 2
if self.Simple_Type == 'Polygon':
box = layout.box()
col = box.column(align=True)
col.label(text=self.Simple_Type + " Options:")
col.prop(self, "Simple_sides")
col.prop(self, "Simple_radius")
if self.Simple_Type == 'Polygon_ab':
box = layout.box()
col = box.column(align=True)
col.label(text="Polygon ab Options:")
col.prop(self, "Simple_sides")
col.prop(self, "Simple_a")
col.prop(self, "Simple_b")
if self.Simple_Type == 'Trapezoid':
box = layout.box()
col = box.column(align=True)
col.label(text=self.Simple_Type + " Options:")
col.prop(self, "Simple_a")
col.prop(self, "Simple_b")
col.prop(self, "Simple_h")
box.prop(self, "Simple_center")
g = hypot(self.Simple_h, (self.Simple_a - self.Simple_b) / 2)
l = self.Simple_a + self.Simple_b + g * 2
s = (abs(self.Simple_a) + abs(self.Simple_b)) / 2 * self.Simple_h
row = layout.row()
row.prop(self, "shape", expand=True)
# output options
col = layout.column()
col.label(text="Output Curve Type:")
col.row().prop(self, "outputType", expand=True)
if self.outputType == 'NURBS':
col.prop(self, "order_u")
elif self.outputType == 'BEZIER':
col.row().prop(self, 'handleType', expand=True)
col = layout.column()
col.row().prop(self, "use_cyclic_u", expand=True)
box.prop(self, "Simple_startlocation")
box.prop(self, "Simple_rotation_euler")
if l != 0 or s != 0:
box = layout.box()
box.label(text="Statistics:", icon="INFO")
if l != 0:
l_str = str(round(l, 4))
box.label(text="Length: " + l_str)
if s != 0:
s_str = str(round(s, 4))
box.label(text="Area: " + s_str)
@classmethod
def poll(cls, context):
return context.scene is not None
def execute(self, context):
# main function
self.align_matrix = align_matrix(context, self.Simple_startlocation)
main(context, self, self.align_matrix)
return {'FINISHED'}
# ------------------------------------------------------------
# Fillet
class BezierPointsFillet(Operator):
bl_idname = "curve.bezier_points_fillet"
bl_label = "Bezier points Fillet"
bl_description = "Bezier points Fillet"
bl_options = {'REGISTER', 'UNDO', 'PRESET'}
name="Radius",
default=0.25,
unit='LENGTH',
description="Radius"
)
Types = [('Round', "Round", "Round"),
('Chamfer', "Chamfer", "Chamfer")]
name="Type",
description="Fillet type",
items=Types
)
def draw(self, context):
layout = self.layout
# general options
col = layout.column()
col.prop(self, "Fillet_radius")
col.prop(self, "Fillet_Type", expand=True)
@classmethod
def poll(cls, context):
return context.scene is not None
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def execute(self, context):
# main function
spline = bpy.context.object.data.splines.active
selected = [p for p in spline.bezier_points if p.select_control_point]
bpy.ops.curve.handle_type_set(type='VECTOR')
n = 0
ii = []
for p in spline.bezier_points:
if p.select_control_point:
ii.append(n)
n += 1
else:
n += 1
if n > 2:
jn = 0
for j in ii:
j += jn
selected_all = [p for p in spline.bezier_points]
bpy.ops.curve.select_all(action='DESELECT')
if j != 0 and j != n - 1:
selected_all[j].select_control_point = True
selected_all[j + 1].select_control_point = True
bpy.ops.curve.subdivide()
selected_all = [p for p in spline.bezier_points]
selected4 = [selected_all[j - 1], selected_all[j],
selected_all[j + 1], selected_all[j + 2]]
jn += 1
n += 1
elif j == 0:
selected_all[j].select_control_point = True
selected_all[j + 1].select_control_point = True
bpy.ops.curve.subdivide()
selected_all = [p for p in spline.bezier_points]
selected4 = [selected_all[n], selected_all[0],
selected_all[1], selected_all[2]]
jn += 1
n += 1
elif j == n - 1:
selected_all[j].select_control_point = True
selected_all[j - 1].select_control_point = True
bpy.ops.curve.subdivide()
selected_all = [p for p in spline.bezier_points]
selected4 = [selected_all[0], selected_all[n],
selected_all[n - 1], selected_all[n - 2]]
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selected4[2].co = selected4[1].co
s1 = Vector(selected4[0].co) - Vector(selected4[1].co)
s2 = Vector(selected4[3].co) - Vector(selected4[2].co)
s1.normalize()
s11 = Vector(selected4[1].co) + s1 * self.Fillet_radius
selected4[1].co = s11
s2.normalize()
s22 = Vector(selected4[2].co) + s2 * self.Fillet_radius
selected4[2].co = s22
if self.Fillet_Type == 'Round':
if j != n - 1:
selected4[2].handle_right_type = 'VECTOR'
selected4[1].handle_left_type = 'VECTOR'
selected4[1].handle_right_type = 'ALIGNED'
selected4[2].handle_left_type = 'ALIGNED'
else:
selected4[1].handle_right_type = 'VECTOR'
selected4[2].handle_left_type = 'VECTOR'
selected4[2].handle_right_type = 'ALIGNED'
selected4[1].handle_left_type = 'ALIGNED'
if self.Fillet_Type == 'Chamfer':
selected4[2].handle_right_type = 'VECTOR'
selected4[1].handle_left_type = 'VECTOR'
selected4[1].handle_right_type = 'VECTOR'
selected4[2].handle_left_type = 'VECTOR'
bpy.ops.curve.select_all(action='SELECT')
bpy.ops.curve.spline_type_set(type='BEZIER')
return {'FINISHED'}
def subdivide_cubic_bezier(p1, p2, p3, p4, t):
p12 = (p2 - p1) * t + p1
p23 = (p3 - p2) * t + p2
p34 = (p4 - p3) * t + p3
p123 = (p23 - p12) * t + p12
p234 = (p34 - p23) * t + p23
p1234 = (p234 - p123) * t + p123
return [p12, p123, p1234, p234, p34]
# ------------------------------------------------------------
# BezierDivide Operator
class BezierDivide(Operator):
bl_idname = "curve.bezier_spline_divide"
bl_label = "Bezier Spline Divide"
bl_description = "Bezier Divide (enters edit mode) for Fillet Curves"
bl_options = {'REGISTER', 'UNDO'}
# align_matrix for the invoke
name="t (0% - 100%)",
default=50.0,
min=0.0, soft_min=0.0,
max=100.0, soft_max=100.0,
description="t (0% - 100%)"
)
@classmethod
def poll(cls, context):
return context.scene is not None
def execute(self, context):
# main function
spline = bpy.context.object.data.splines.active
selected_all = [p for p in spline.bezier_points if p.select_control_point]
Spivak Vladimir (cwolf3d)
committed
selected = []
n = 0
for j in spline.bezier_points:
n += 1
if j.select_control_point:
selected.append(n)
selected_all[0].handle_right_type = 'FREE'
selected_all[0].handle_left_type = 'FREE'
selected_all[1].handle_right_type = 'FREE'
selected_all[1].handle_left_type = 'FREE'
Spivak Vladimir (cwolf3d)
committed
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if abs(selected[0] - selected[1]) == 1:
h = subdivide_cubic_bezier(
selected_all[0].co, selected_all[0].handle_right,
selected_all[1].handle_left, selected_all[1].co, self.Bezier_t / 100
)
bpy.ops.curve.subdivide(1)
selected_all = [p for p in spline.bezier_points if p.select_control_point]
selected_all[0].handle_right = h[0]
selected_all[1].co = h[2]
selected_all[1].handle_left = h[1]
selected_all[1].handle_right = h[3]
selected_all[2].handle_left = h[4]
else:
h = subdivide_cubic_bezier(
selected_all[1].co, selected_all[1].handle_right,
selected_all[0].handle_left, selected_all[0].co, self.Bezier_t / 100
)
bpy.ops.curve.subdivide(1)
selected_all = [p for p in spline.bezier_points if p.select_control_point]
selected_all[1].handle_right = h[0]
selected_all[2].co = h[2]
selected_all[2].handle_left = h[1]
selected_all[2].handle_right = h[3]
selected_all[0].handle_left = h[4]
return {'FINISHED'}
classes = [
Simple,
BezierDivide,
BezierPointsFillet
]
from bpy.utils import register_class
for cls in classes:
register_class(cls)
bpy.types.VIEW3D_MT_curve_add.append(menu)
bpy.types.VIEW3D_MT_edit_curve_context_menu.prepend(Simple_curve_edit_menu)
from bpy.utils import unregister_class
for cls in reversed(classes):
unregister_class(cls)
bpy.types.VIEW3D_MT_curve_add.remove(menu)
bpy.types.VIEW3D_MT_edit_curve_context_menu.remove(Simple_curve_edit_menu)
if __name__ == "__main__":
register()