path: root/release/scripts/startup/bl_operators/add_mesh_torus.py

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# <pep8-80 compliant>
import bpy
from bpy.types import Operator

from bpy.props import (
        FloatProperty,
        IntProperty,
        )
from bpy.app.translations import pgettext_data as data_

from bpy_extras import object_utils


def add_torus(major_rad, minor_rad, major_seg, minor_seg):
    from math import cos, sin, pi
    from mathutils import Vector, Quaternion

    PI_2 = pi * 2.0
    z_axis = 0.0, 0.0, 1.0

    verts = []
    faces = []
    i1 = 0
    tot_verts = major_seg * minor_seg
    for major_index in range(major_seg):
        quat = Quaternion(z_axis, (major_index / major_seg) * PI_2)

        for minor_index in range(minor_seg):
            angle = 2 * pi * minor_index / minor_seg

            vec = quat * Vector((major_rad + (cos(angle) * minor_rad),
                                 0.0,
                                 (sin(angle) * minor_rad),
                                 ))

            verts.extend(vec[:])

            if minor_index + 1 == minor_seg:
                i2 = (major_index) * minor_seg
                i3 = i1 + minor_seg
                i4 = i2 + minor_seg

            else:
                i2 = i1 + 1
                i3 = i1 + minor_seg
                i4 = i3 + 1

            if i2 >= tot_verts:
                i2 = i2 - tot_verts
            if i3 >= tot_verts:
                i3 = i3 - tot_verts
            if i4 >= tot_verts:
                i4 = i4 - tot_verts

            # stupid eekadoodle
            if i2:
                faces.extend([i1, i3, i4, i2])
            else:
                faces.extend([i2, i1, i3, i4])

            i1 += 1

    return verts, faces


class AddTorus(Operator, object_utils.AddObjectHelper):
    """Add a torus mesh"""
    bl_idname = "mesh.primitive_torus_add"
    bl_label = "Add Torus"
    bl_options = {'REGISTER', 'UNDO', 'PRESET'}

    def mode_update_callback(self, context):
        if self.mode == 'EXT_INT':
            self.abso_major_rad = self.major_radius + self.minor_radius
            self.abso_minor_rad = self.major_radius - self.minor_radius

    major_segments = IntProperty(
            name="Major Segments",
            description="Number of segments for the main ring of the torus",
            min=3, max=256,
            default=48,
            )
    minor_segments = IntProperty(
            name="Minor Segments",
            description="Number of segments for the minor ring of the torus",
            min=3, max=256,
            default=12,
            )
    mode = bpy.props.EnumProperty(
            name="Torus Dimensions",
            items=(("MAJOR_MINOR", "Major/Minor",
                    "Use the major/minor radii for torus dimensions"),
                   ("EXT_INT", "Exterior/Interior",
                    "Use the exterior/interior radii for torus dimensions")),
            update=mode_update_callback,
            )
    major_radius = FloatProperty(
            name="Major Radius",
            description=("Radius from the origin to the "
                         "center of the cross sections"),
            min=0.01, max=100.0,
            default=1.0,
            subtype='DISTANCE',
            unit='LENGTH',
            )
    minor_radius = FloatProperty(
            name="Minor Radius",
            description="Radius of the torus' cross section",
            min=0.01, max=100.0,
            default=0.25,
            subtype='DISTANCE',
            unit='LENGTH',
            )
    abso_major_rad = FloatProperty(
            name="Exterior Radius",
            description="Total Exterior Radius of the torus",
            min=0.01, max=100.0,
            default=1.25,
            subtype='DISTANCE',
            unit='LENGTH',
            )
    abso_minor_rad = FloatProperty(
            name="Interior Radius",
            description="Total Interior Radius of the torus",
            min=0.01, max=100.0,
            default=0.75,
            subtype='DISTANCE',
            unit='LENGTH',
            )

    def draw(self, context):
        layout = self.layout
        col = layout.column(align=True)
        col.prop(self, 'view_align')

        col = layout.column(align=True)
        col.label(text="Location")
        col.prop(self, "location", text="")

        col = layout.column(align=True)
        col.label(text="Rotation")
        col.prop(self, "rotation", text="")

        col = layout.column(align=True)
        col.label(text="Major Segments")
        col.prop(self, "major_segments", text="")

        col = layout.column(align=True)
        col.label(text="Minor Segments")
        col.prop(self, "minor_segments", text="")

        col = layout.column(align=True)
        col.label(text="Torus Dimensions")
        col.row().prop(self, "mode", expand=True)

        if self.mode == 'MAJOR_MINOR':
            col = layout.column(align=True)
            col.label(text="Major Radius")
            col.prop(self, "major_radius", text="")

            col = layout.column(align=True)
            col.label(text="Minor Radius")
            col.prop(self, "minor_radius", text="")
        else:
            col = layout.column(align=True)
            col.label(text="Exterior Radius")
            col.prop(self, "abso_major_rad", text="")

            col = layout.column(align=True)
            col.label(text="Interior Radius")
            col.prop(self, "abso_minor_rad", text="")

    def invoke(self, context, event):
        object_utils.object_add_grid_scale_apply_operator(self, context)
        return self.execute(context)

    def execute(self, context):

        if self.mode == 'EXT_INT':
            extra_helper = (self.abso_major_rad - self.abso_minor_rad) * 0.5
            self.major_radius = self.abso_minor_rad + extra_helper
            self.minor_radius = extra_helper

        verts_loc, faces = add_torus(self.major_radius,
                                     self.minor_radius,
                                     self.major_segments,
                                     self.minor_segments)

        mesh = bpy.data.meshes.new(data_("Torus"))

        mesh.vertices.add(len(verts_loc) // 3)

        nbr_loops = len(faces)
        nbr_polys = nbr_loops // 4
        mesh.loops.add(nbr_loops)
        mesh.polygons.add(nbr_polys)

        mesh.vertices.foreach_set("co", verts_loc)
        mesh.polygons.foreach_set("loop_start", range(0, nbr_loops, 4))
        mesh.polygons.foreach_set("loop_total", (4,) * nbr_polys)
        mesh.loops.foreach_set("vertex_index", faces)
        mesh.update()

        object_utils.object_data_add(context, mesh, operator=self)

        return {'FINISHED'}