io_scene_fbx/export_fbx_bin.py

@@ -931,6 +931,26 @@ def fbx_data_mesh_elements(root, me_obj, scene_data, done_meshes):
     me.edges.foreach_get("vertices", t_ev)
     me.loops.foreach_get("edge_index", t_lei)
 
+    # Polygons might not be in the same order as loops. To export per-loop and per-polygon data in a matching order,
+    # one must be set into the order of the other. Since there are fewer polygons than loops and there are usually
+    # more geometry layers exported that are per-loop than per-polygon, it's more efficient to re-order polygons and
+    # per-polygon data.
+    perm_polygons_to_loop_order = None
+    # t_ls indicates the ordering of polygons compared to loops. When t_ls is sorted, polygons and loops are in the same
+    # order. Since each loop must be assigned to exactly one polygon for the mesh to be valid, every value in t_ls must
+    # be unique, so t_ls will be monotonically increasing when sorted.
+    # t_ls is expected to be in the same order as loops in most cases since exiting Edit mode will sort t_ls, so do an
+    # initial check for any element being smaller than the previous element to determine if sorting is required.
+    sort_polygon_data = np.any(t_ls[1:] < t_ls[:-1])
+    if sort_polygon_data:
+        # t_ls is not sorted, so get the indices that would sort t_ls using argsort, these will be re-used to sort
+        # per-polygon data.
+        # Using 'stable' for radix sort, which performs much better with partially ordered data and slightly worse with
+        # completely random data, compared to the default of 'quicksort' for introsort.
+        perm_polygons_to_loop_order = np.argsort(t_ls, kind='stable')
+        # Sort t_ls into the same order as loops.
+        t_ls = t_ls[perm_polygons_to_loop_order]
+
     # Add "fake" faces for loose edges. Each "fake" face consists of two loops creating a new 2-sided polygon.
     if scene_data.settings.use_mesh_edges:
         bl_edge_is_loose_dtype = bool
@@ -1031,6 +1051,8 @@ def fbx_data_mesh_elements(root, me_obj, scene_data, done_meshes):
         if smooth_type == 'FACE':
             t_ps = np.empty(len(me.polygons), dtype=poly_use_smooth_dtype)
             me.polygons.foreach_get("use_smooth", t_ps)
+            if sort_polygon_data:
+                t_ps = t_ps[perm_polygons_to_loop_order]
             _map = b"ByPolygon"
         else:  # EDGE
             _map = b"ByEdge"
@@ -1049,14 +1071,17 @@ def fbx_data_mesh_elements(root, me_obj, scene_data, done_meshes):
                 # Get the 'use_smooth' attribute of all polygons.
                 p_use_smooth_mask = np.empty(mesh_poly_nbr, dtype=poly_use_smooth_dtype)
                 me.polygons.foreach_get('use_smooth', p_use_smooth_mask)
+                if sort_polygon_data:
+                    p_use_smooth_mask = p_use_smooth_mask[perm_polygons_to_loop_order]
                 # Invert to get all flat shaded polygons.
                 p_flat_mask = np.invert(p_use_smooth_mask, out=p_use_smooth_mask)
                 # Convert flat shaded polygons to flat shaded loops by repeating each element by the number of sides of
                 # that polygon.
-                # Polygon sides can be calculated from the element-wise difference of loop starts appended by the number
+                # Polygon sides can be calculated from the element-wise difference of sorted loop starts appended by the
-                # of loops. Alternatively, polygon sides can be retrieved directly from the 'loop_total' attribute of
+                # number of loops. Alternatively, polygon sides can be retrieved directly from the 'loop_total'
-                # polygons, but since we already have t_ls, it tends to be quicker to calculate from t_ls when above
+                # attribute of polygons, but that might need to be sorted, and we already have t_ls which is sorted loop
-                # around 10_000 polygons.
+                # starts. It tends to be quicker to calculate from t_ls when above around 10_000 polygons even when the
+                # 'loop_total' array wouldn't need sorting.
                 polygon_sides = np.diff(mesh_t_ls_view, append=mesh_loop_nbr)
                 p_flat_loop_mask = np.repeat(p_flat_mask, polygon_sides)
                 # Convert flat shaded loops to flat shaded (sharp) edge indices.
@@ -1417,6 +1442,8 @@ def fbx_data_mesh_elements(root, me_obj, scene_data, done_meshes):
                 fbx_pm_dtype = np.int32
                 t_pm = np.empty(len(me.polygons), dtype=bl_pm_dtype)
                 me.polygons.foreach_get("material_index", t_pm)
+                if sort_polygon_data:
+                    t_pm = t_pm[perm_polygons_to_loop_order]
 
                 # We have to validate mat indices, and map them to FBX indices.
                 # Note a mat might not be in me_fbxmaterials_idx (e.g. node mats are ignored).
@@ -1447,6 +1474,7 @@ def fbx_data_mesh_elements(root, me_obj, scene_data, done_meshes):
                 elem_data_single_string(lay_ma, b"MappingInformationType", b"AllSame")
                 elem_data_single_string(lay_ma, b"ReferenceInformationType", b"IndexToDirect")
                 elem_data_single_int32_array(lay_ma, b"Materials", [0])
+    del perm_polygons_to_loop_order
 
     # And the "layer TOC"...
 

node_wrangler/operators.py

@@ -1304,6 +1304,8 @@ class NWMergeNodes(Operator, NWBase):
             if tree_type == 'GEOMETRY':
                 if nodes_list is selected_math or nodes_list is selected_vector or nodes_list is selected_mix:
                     node_type = 'ShaderNode'
+                    if mode == 'MIX':
+                        mode = 'ADD'
                 else:
                     node_type = 'GeometryNode'
             if merge_position == 'CENTER':

sun_position/__init__.py

@@ -15,8 +15,8 @@
 
 bl_info = {
     "name": "Sun Position",
-    "author": "Michael Martin",
+    "author": "Michael Martin, Damien Picard",
-    "version": (3, 2, 2),
+    "version": (3, 3, 0),
     "blender": (3, 0, 0),
     "location": "World > Sun Position",
     "description": "Show sun position with objects and/or sky texture",
@@ -63,6 +63,7 @@ def register():
     bpy.app.handlers.load_post.append(sun_scene_handler)
     bpy.app.translations.register(__name__, translations.translations_dict)
 
+
 def unregister():
     bpy.app.translations.unregister(__name__)
     bpy.app.handlers.frame_change_post.remove(sun_calc.sun_handler)

sun_position/draw.py

@@ -23,10 +23,6 @@ else:
     shader_info.vertex_out(shader_interface)
 
     shader_info.vertex_source(
-        # uniform mat4 u_ViewProjectionMatrix;
-        # in vec3 position;
-        # flat out vec2 v_StartPos;
-        # out vec4 v_VertPos;
         '''
         void main()
         {
@@ -40,11 +36,6 @@ else:
 
     shader_info.fragment_out(0, 'VEC4', "FragColor")
     shader_info.fragment_source(
-        # uniform vec4 u_Color;
-        # uniform vec2 u_Resolution;
-        # flat in vec2 v_StartPos;
-        # in vec4 v_VertPos;
-        # out vec4 FragColor;
         '''
         void main()
         {

sun_position/geo.py

@@ -51,7 +51,7 @@ class Parser:
         # do matching
         m = re.match(pattern, text)
 
-        if m == None:
+        if m is None:
             return None
 
         # build tree recursively by parsing subgroups
@@ -59,7 +59,7 @@ class Parser:
 
         for i in range(len(subpattern_names)):
             text_part = m.group(i + 1)
-            if not text_part == None:
+            if text_part is not None:
                 subpattern = subpattern_names[i]
                 tree[subpattern] = self.parse(subpattern, text_part)
 
@@ -158,7 +158,8 @@ def parse_position(s):
     Tries to be as tolerant as possible with input. Returns None if parsing doesn't succeed. """
 
     parse_tree = position_parser.parse("position", s)
-    if parse_tree == None: return None
+    if parse_tree is None:
+        return None
 
     lat_sign = +1.
     if parse_tree.get(

sun_position/hdr.py

@@ -64,8 +64,7 @@ def draw_callback_px(self, context):
     coords = ((-0.5, -0.5), (0.5, -0.5), (0.5, 0.5), (-0.5, 0.5))
     uv_coords = ((0, 0), (1, 0), (1, 1), (0, 1))
     batch = batch_for_shader(shader, 'TRI_FAN',
-        {"pos" : coords,
+                             {"pos": coords, "texCoord": uv_coords})
-         "texCoord" : uv_coords})
 
     with gpu.matrix.push_pop():
         gpu.matrix.translate(position)
@@ -134,7 +133,9 @@ class SUNPOS_OT_ShowHdr(bpy.types.Operator):
             self.mouse_position = Vector((mouse_position_abs.x - self.area.x,
                                           mouse_position_abs.y - self.area.y))
 
-            self.selected_point = (self.mouse_position - self.offset - Vector((self.right, self.top))/2) / self.scale
+            self.selected_point = (self.mouse_position
+                                   - self.offset
+                                   - Vector((self.right, self.top)) / 2) / self.scale
             u = self.selected_point.x / self.area.width + 0.5
             v = (self.selected_point.y) / (self.area.width / 2) + 0.5
 
@@ -275,10 +276,13 @@ class SUNPOS_OT_ShowHdr(bpy.types.Operator):
         self.initial_elevation = context.scene.sun_pos_properties.hdr_elevation
         self.initial_azimuth = context.scene.sun_pos_properties.hdr_azimuth
 
-        context.workspace.status_text_set("Enter/LMB: confirm, Esc/RMB: cancel, MMB: pan, mouse wheel: zoom, Ctrl + mouse wheel: set exposure")
+        context.workspace.status_text_set(
+            "Enter/LMB: confirm, Esc/RMB: cancel,"
+            " MMB: pan, mouse wheel: zoom, Ctrl + mouse wheel: set exposure")
 
-        self._handle = bpy.types.SpaceView3D.draw_handler_add(draw_callback_px,
+        self._handle = bpy.types.SpaceView3D.draw_handler_add(
-            (self, context), 'WINDOW', 'POST_PIXEL')
+            draw_callback_px, (self, context), 'WINDOW', 'POST_PIXEL'
+        )
         context.window_manager.modal_handler_add(self)
 
         return {'RUNNING_MODAL'}

sun_position/properties.py

@@ -5,7 +5,7 @@ from bpy.types import AddonPreferences, PropertyGroup
 from bpy.props import (StringProperty, EnumProperty, IntProperty,
                        FloatProperty, BoolProperty, PointerProperty)
 
-from .sun_calc import sun_update, parse_coordinates, surface_update, analemmas_update
+from .sun_calc import sun_update, parse_coordinates, surface_update, analemmas_update, sun
 from .draw import north_update
 
 from math import pi
@@ -19,7 +19,7 @@ TODAY = datetime.today()
 
 class SunPosProperties(PropertyGroup):
     usage_mode: EnumProperty(
-        name="Usage mode",
+        name="Usage Mode",
         description="Operate in normal mode or environment texture mode",
         items=(
             ('NORMAL', "Normal", ""),
@@ -29,14 +29,14 @@ class SunPosProperties(PropertyGroup):
         update=sun_update)
 
     use_daylight_savings: BoolProperty(
-        name="Daylight savings",
+        name="Daylight Savings",
         description="Daylight savings time adds 1 hour to standard time",
         default=False,
         update=sun_update)
 
     use_refraction: BoolProperty(
-        name="Use refraction",
+        name="Use Refraction",
-        description="Show apparent sun position due to refraction",
+        description="Show apparent Sun position due to refraction",
         default=True,
         update=sun_update)
 
@@ -81,6 +81,34 @@ class SunPosProperties(PropertyGroup):
         default=0.0,
         update=sun_update)
 
+    sunrise_time: FloatProperty(
+        name="Sunrise Time",
+        description="Time at which the Sun rises",
+        soft_min=0.0, soft_max=24.0,
+        default=0.0,
+        get=lambda _: sun.sunrise.time)
+
+    sunset_time: FloatProperty(
+        name="Sunset Time",
+        description="Time at which the Sun sets",
+        soft_min=0.0, soft_max=24.0,
+        default=0.0,
+        get=lambda _: sun.sunset.time)
+
+    sun_azimuth: FloatProperty(
+        name="Sun Azimuth",
+        description="Rotation angle of the Sun from the north direction",
+        soft_min=-pi, soft_max=pi,
+        default=0.0,
+        get=lambda _: sun.azimuth)
+
+    sun_elevation: FloatProperty(
+        name="Sunset Time",
+        description="Elevation angle of the Sun",
+        soft_min=-pi/2, soft_max=pi/2,
+        default=0.0,
+        get=lambda _: sun.elevation)
+
     co_parser: StringProperty(
         name="Enter coordinates",
         description="Enter coordinates from an online map",

sun_position/sun_calc.py

@@ -4,9 +4,10 @@ import bpy
 from bpy.app.handlers import persistent
 import gpu
 from gpu_extras.batch import batch_for_shader
+
 from mathutils import Euler, Vector
-import math
+
-from math import degrees, radians, pi
+from math import degrees, radians, pi, sin, cos, asin, acos, tan, floor
 import datetime
 from .geo import parse_position
 
@@ -47,6 +48,7 @@ class SunInfo:
     sun_distance = 0.0
     use_daylight_savings = False
 
+
 sun = SunInfo()
 
 
@@ -78,8 +80,8 @@ def parse_coordinates(self, context):
 
 def move_sun(context):
     """
-    Cycle through all the selected objects and call set_sun_location and
+    Cycle through all the selected objects and set their position and rotation
-    set_sun_rotations to place them in the sky
+    in the sky.
     """
     addon_prefs = context.preferences.addons[__package__].preferences
     sun_props = context.scene.sun_pos_properties
@@ -100,11 +102,11 @@ def move_sun(context):
             env_tex.texture_mapping.rotation.z = az
 
         if sun_props.sun_object:
-            theta = math.pi / 2 - sun_props.hdr_elevation
+            theta = pi / 2 - sun_props.hdr_elevation
             phi = -sun_props.hdr_azimuth
 
             obj = sun_props.sun_object
-            obj.location = get_sun_vector(theta, phi) * sun_props.sun_distance
+            obj.location = get_sun_vector(azimuth, elevation, north_offset) * sun_props.sun_distance
 
             rotation_euler = Euler((sun_props.hdr_elevation - pi/2,
                                     0, -sun_props.hdr_azimuth))
@@ -118,15 +120,15 @@ def move_sun(context):
     if sun.use_daylight_savings:
         zone -= 1
 
-    north_offset = degrees(sun_props.north_offset)
+    north_offset = sun_props.north_offset
 
     if addon_prefs.show_rise_set:
         calc_sunrise_sunset(rise=True)
         calc_sunrise_sunset(rise=False)
 
-    az_north, theta, phi, azimuth, elevation = get_sun_coordinates(
+    azimuth, elevation = get_sun_coordinates(
         local_time, sun_props.latitude, sun_props.longitude,
-        north_offset, zone, sun_props.month, sun_props.day, sun_props.year,
+        zone, sun_props.month, sun_props.day, sun_props.year,
         sun_props.sun_distance)
     sun.azimuth = azimuth
     sun.elevation = elevation
@@ -135,17 +137,16 @@ def move_sun(context):
         sky_node = bpy.context.scene.world.node_tree.nodes.get(sun_props.sky_texture)
         if sky_node is not None and sky_node.type == "TEX_SKY":
             sky_node.texture_mapping.rotation.z = 0.0
-            sky_node.sun_direction = get_sun_vector(theta, phi)
+            sky_node.sun_direction = get_sun_vector(azimuth, elevation, north_offset)
-            sky_node.sun_elevation = math.radians(elevation)
+            sky_node.sun_elevation = elevation
-            sky_node.sun_rotation = math.radians(az_north)
+            sky_node.sun_rotation = azimuth
 
     # Sun object
     if (sun_props.sun_object is not None
             and sun_props.sun_object.name in context.view_layer.objects):
         obj = sun_props.sun_object
-        obj.location = get_sun_vector(theta, phi) * sun_props.sun_distance
+        obj.location = get_sun_vector(azimuth, elevation, north_offset) * sun_props.sun_distance
-        rotation_euler = Euler((math.radians(elevation - 90), 0,
+        rotation_euler = Euler((elevation - pi/2, 0, -azimuth))
-                                math.radians(-az_north)))
         set_sun_rotations(obj, rotation_euler)
 
     # Sun collection
@@ -161,16 +162,14 @@ def move_sun(context):
                 time_increment = sun_props.time_spread
 
             for obj in sun_objects:
-                az_north, theta, phi, azimuth, elevation = get_sun_coordinates(
+                azimuth, elevation = get_sun_coordinates(
                     local_time, sun_props.latitude,
-                    sun_props.longitude, north_offset, zone,
+                    sun_props.longitude, zone,
                     sun_props.month, sun_props.day,
                     sun_props.year, sun_props.sun_distance)
-                obj.location = get_sun_vector(theta, phi) * sun_props.sun_distance
+                obj.location = get_sun_vector(azimuth, elevation, north_offset) * sun_props.sun_distance
                 local_time -= time_increment
-                obj.rotation_euler = (
+                obj.rotation_euler = ((elevation - pi/2, 0, -azimuth))
-                    (math.radians(elevation - 90), 0,
-                     math.radians(-az_north)))
         else:
             # Analemma
             day_increment = 365 / object_count
@@ -178,22 +177,21 @@ def move_sun(context):
             for obj in sun_objects:
                 dt = (datetime.date(sun_props.year, 1, 1) +
                       datetime.timedelta(day - 1))
-                az_north, theta, phi, azimuth, elevation = get_sun_coordinates(
+                azimuth, elevation = get_sun_coordinates(
                     local_time, sun_props.latitude,
-                    sun_props.longitude, north_offset, zone,
+                    sun_props.longitude, zone,
                     dt.month, dt.day, sun_props.year,
                     sun_props.sun_distance)
-                obj.location = get_sun_vector(theta, phi) * sun_props.sun_distance
+                obj.location = get_sun_vector(azimuth, elevation, north_offset) * sun_props.sun_distance
                 day -= day_increment
-                obj.rotation_euler = (
+                obj.rotation_euler = (elevation - pi/2, 0, -azimuth)
-                    (math.radians(elevation - 90), 0,
-                     math.radians(-az_north)))
 
 
 def day_of_year_to_month_day(year, day_of_year):
     dt = (datetime.date(year, 1, 1) + datetime.timedelta(day_of_year - 1))
     return dt.day, dt.month
 
+
 def month_day_to_day_of_year(year, month, day):
     dt = datetime.date(year, month, day)
     return dt.timetuple().tm_yday
@@ -275,7 +273,7 @@ def format_lat_long(lat_long, is_latitude):
     return hh + "° " + mm + "' " + ss + '"' + coord_tag
 
 
-def get_sun_coordinates(local_time, latitude, longitude, north_offset,
+def get_sun_coordinates(local_time, latitude, longitude,
                         utc_zone, month, day, year, distance):
     """
     Calculate the actual position of the sun based on input parameters.
@@ -319,31 +317,31 @@ def get_sun_coordinates(local_time, latitude, longitude, north_offset,
     if hour_angle < -180.0:
         hour_angle += 360.0
 
-    csz = (math.sin(latitude) * math.sin(solar_dec) +
+    csz = (sin(latitude) * sin(solar_dec) +
-           math.cos(latitude) * math.cos(solar_dec) *
+           cos(latitude) * cos(solar_dec) *
-           math.cos(radians(hour_angle)))
+           cos(radians(hour_angle)))
     if csz > 1.0:
         csz = 1.0
     elif csz < -1.0:
         csz = -1.0
 
-    zenith = math.acos(csz)
+    zenith = acos(csz)
 
-    az_denom = math.cos(latitude) * math.sin(zenith)
+    az_denom = cos(latitude) * sin(zenith)
 
     if abs(az_denom) > 0.001:
-        az_rad = ((math.sin(latitude) *
+        az_rad = ((sin(latitude) *
-                  math.cos(zenith)) - math.sin(solar_dec)) / az_denom
+                  cos(zenith)) - sin(solar_dec)) / az_denom
         if abs(az_rad) > 1.0:
             az_rad = -1.0 if (az_rad < 0.0) else 1.0
-        azimuth = 180.0 - degrees(math.acos(az_rad))
+        azimuth = pi - acos(az_rad)
         if hour_angle > 0.0:
             azimuth = -azimuth
     else:
-        azimuth = 180.0 if (latitude > 0.0) else 0.0
+        azimuth = pi if (latitude > 0.0) else 0.0
 
     if azimuth < 0.0:
-        azimuth = azimuth + 360.0
+        azimuth += 2*pi
 
     exoatm_elevation = 90.0 - degrees(zenith)
 
@@ -351,43 +349,37 @@ def get_sun_coordinates(local_time, latitude, longitude, north_offset,
         if exoatm_elevation > 85.0:
             refraction_correction = 0.0
         else:
-            te = math.tan(radians(exoatm_elevation))
+            te = tan(radians(exoatm_elevation))
             if exoatm_elevation > 5.0:
                 refraction_correction = (
                     58.1 / te - 0.07 / (te ** 3) + 0.000086 / (te ** 5))
-            elif (exoatm_elevation > -0.575):
+            elif exoatm_elevation > -0.575:
-                s1 = (-12.79 + exoatm_elevation * 0.711)
+                s1 = -12.79 + exoatm_elevation * 0.711
-                s2 = (103.4 + exoatm_elevation * (s1))
+                s2 = 103.4 + exoatm_elevation * s1
-                s3 = (-518.2 + exoatm_elevation * (s2))
+                s3 = -518.2 + exoatm_elevation * s2
                 refraction_correction = 1735.0 + exoatm_elevation * (s3)
             else:
                 refraction_correction = -20.774 / te
 
-        refraction_correction = refraction_correction / 3600
+        refraction_correction /= 3600
-        solar_elevation = 90.0 - (degrees(zenith) - refraction_correction)
+        elevation = pi/2 - (zenith - radians(refraction_correction))
 
     else:
-        solar_elevation = 90.0 - degrees(zenith)
+        elevation = pi/2 - zenith
 
-    solar_azimuth = azimuth
+    return azimuth, elevation
-    solar_azimuth += north_offset
-
-    az_north = solar_azimuth
-    theta = math.pi / 2 - radians(solar_elevation)
-    phi = radians(solar_azimuth) * -1
-    azimuth = azimuth
-    elevation = solar_elevation
-
-    return az_north, theta, phi, azimuth, elevation
 
 
-def get_sun_vector(theta, phi):
+def get_sun_vector(azimuth, elevation, north_offset):
     """
     Convert the sun coordinates to cartesian
     """
-    loc_x = math.sin(phi) * math.sin(-theta)
+    phi = -(azimuth + north_offset)
-    loc_y = math.sin(theta) * math.cos(phi)
+    theta = pi/2 - elevation
-    loc_z = math.cos(theta)
+
+    loc_x = sin(phi) * sin(-theta)
+    loc_y = sin(theta) * cos(phi)
+    loc_z = cos(theta)
     return Vector((loc_x, loc_y, loc_z))
 
 
@@ -426,14 +418,14 @@ def calc_sun_declination(t):
 
 def calc_hour_angle_sunrise(lat, solar_dec):
     lat_rad = radians(lat)
-    HAarg = (math.cos(radians(90.833)) /
+    HAarg = (cos(radians(90.833)) /
-            (math.cos(lat_rad) * math.cos(solar_dec))
+             (cos(lat_rad) * cos(solar_dec))
-            - math.tan(lat_rad) * math.tan(solar_dec))
+             - tan(lat_rad) * tan(solar_dec))
     if HAarg < -1.0:
         HAarg = -1.0
     elif HAarg > 1.0:
         HAarg = 1.0
-    HA = math.acos(HAarg)
+    HA = acos(HAarg)
     return HA
 
 
@@ -458,8 +450,8 @@ def calc_sunrise_sunset(rise):
                                         sun.latitude, sun.longitude)
     time_local = new_time_UTC + (-zone * 60.0)
     tl = time_local / 60.0
-    az_north, theta, phi, azimuth, elevation = get_sun_coordinates(
+    azimuth, elevation = get_sun_coordinates(
-        tl, sun.latitude, sun.longitude, 0.0,
+        tl, sun.latitude, sun.longitude,
         zone, sun.month, sun.day, sun.year,
         sun.sun_distance)
     if sun.use_daylight_savings:
@@ -491,10 +483,10 @@ def get_julian_day(year, month, day):
     if month <= 2:
         year -= 1
         month += 12
-    A = math.floor(year / 100)
+    A = floor(year / 100)
-    B = 2 - A + math.floor(A / 4.0)
+    B = 2 - A + floor(A / 4.0)
-    jd = (math.floor((365.25 * (year + 4716.0))) +
+    jd = (floor((365.25 * (year + 4716.0))) +
-          math.floor(30.6001 * (month + 1)) + day + B - 1524.5)
+          floor(30.6001 * (month + 1)) + day + B - 1524.5)
     return jd
 
 
@@ -504,7 +496,7 @@ def calc_time_julian_cent(jd):
 
 
 def sun_declination(e, L):
-    return (math.asin(math.sin(e) * math.sin(L)))
+    return (asin(sin(e) * sin(L)))
 
 
 def calc_equation_of_time(t):
@@ -512,13 +504,13 @@ def calc_equation_of_time(t):
     ml = radians(mean_longitude_sun(t))
     e = eccentricity_earth_orbit(t)
     m = radians(mean_anomaly_sun(t))
-    y = math.tan(radians(epsilon) / 2.0)
+    y = tan(radians(epsilon) / 2.0)
     y = y * y
-    sin2ml = math.sin(2.0 * ml)
+    sin2ml = sin(2.0 * ml)
-    cos2ml = math.cos(2.0 * ml)
+    cos2ml = cos(2.0 * ml)
-    sin4ml = math.sin(4.0 * ml)
+    sin4ml = sin(4.0 * ml)
-    sinm = math.sin(m)
+    sinm = sin(m)
-    sin2m = math.sin(2.0 * m)
+    sin2m = sin(2.0 * m)
     etime = (y * sin2ml - 2.0 * e * sinm + 4.0 * e * y *
              sinm * cos2ml - 0.5 * y ** 2 * sin4ml - 1.25 * e ** 2 * sin2m)
     return (degrees(etime) * 4)
@@ -527,7 +519,7 @@ def calc_equation_of_time(t):
 def obliquity_correction(t):
     ec = obliquity_of_ecliptic(t)
     omega = 125.04 - 1934.136 * t
-    return (ec + 0.00256 * math.cos(radians(omega)))
+    return (ec + 0.00256 * cos(radians(omega)))
 
 
 def obliquity_of_ecliptic(t):
@@ -542,13 +534,13 @@ def true_longitude_of_sun(t):
 def calc_sun_apparent_long(t):
     o = true_longitude_of_sun(t)
     omega = 125.04 - 1934.136 * t
-    lamb = o - 0.00569 - 0.00478 * math.sin(radians(omega))
+    lamb = o - 0.00569 - 0.00478 * sin(radians(omega))
     return lamb
 
 
 def apparent_longitude_of_sun(t):
     return (radians(true_longitude_of_sun(t) - 0.00569 - 0.00478 *
-            math.sin(radians(125.04 - 1934.136 * t))))
+            sin(radians(125.04 - 1934.136 * t))))
 
 
 def mean_longitude_sun(t):
@@ -557,9 +549,9 @@ def mean_longitude_sun(t):
 
 def equation_of_sun_center(t):
     m = radians(mean_anomaly_sun(t))
-    c = ((1.914602 - 0.004817 * t - 0.000014 * t**2) * math.sin(m) +
+    c = ((1.914602 - 0.004817 * t - 0.000014 * t**2) * sin(m) +
-         (0.019993 - 0.000101 * t) * math.sin(m * 2) +
+         (0.019993 - 0.000101 * t) * sin(m * 2) +
-         0.000289 * math.sin(m * 3))
+         0.000289 * sin(m * 3))
     return c
 
 
@@ -575,13 +567,13 @@ def calc_surface(context):
     coords = []
     sun_props = context.scene.sun_pos_properties
     zone = -sun_props.UTC_zone
-    north_offset = degrees(sun_props.north_offset)
+    north_offset = sun_props.north_offset
 
     def get_surface_coordinates(time, month):
-        _, theta, phi, _, _ = get_sun_coordinates(
+        azimuth, elevation = get_sun_coordinates(
-            time, sun_props.latitude, sun_props.longitude, north_offset,
+            time, sun_props.latitude, sun_props.longitude,
             zone, month, 1, sun_props.year, sun_props.sun_distance)
-        sun_vector = get_sun_vector(theta, phi) * sun_props.sun_distance
+        sun_vector = get_sun_vector(azimuth, elevation, north_offset) * sun_props.sun_distance
         sun_vector.z = max(0, sun_vector.z)
         return sun_vector
 
@@ -601,21 +593,20 @@ def calc_analemma(context, h):
     vertices = []
     sun_props = context.scene.sun_pos_properties
     zone = -sun_props.UTC_zone
-    north_offset = degrees(sun_props.north_offset)
+    north_offset = sun_props.north_offset
     for day_of_year in range(1, 367, 5):
         day, month = day_of_year_to_month_day(sun_props.year, day_of_year)
-        _, theta, phi, _, _ = get_sun_coordinates(
+        azimuth, elevation = get_sun_coordinates(
             h, sun_props.latitude, sun_props.longitude,
-            north_offset, zone, month, day, sun_props.year,
+            zone, month, day, sun_props.year,
             sun_props.sun_distance)
-        sun_vector = get_sun_vector(theta, phi) * sun_props.sun_distance
+        sun_vector = get_sun_vector(azimuth, elevation, north_offset) * sun_props.sun_distance
         if sun_vector.z > 0:
             vertices.append(sun_vector)
     return vertices
 
 
 def draw_surface(batch, shader):
-
     blend = gpu.state.blend_get()
     gpu.state.blend_set("ALPHA")
     shader.uniform_float("color", (.8, .6, 0, 0.2))
@@ -630,6 +621,7 @@ def draw_analemmas(batch, shader):
 
 _handle_surface = None
 
+
 def surface_update(self, context):
     global _handle_surface
     if self.show_surface:
@@ -648,6 +640,7 @@ def surface_update(self, context):
 
 _handle_analemmas = None
 
+
 def analemmas_update(self, context):
     global _handle_analemmas
     if self.show_analemmas:

sun_position/ui_sun.py

@@ -4,6 +4,7 @@ import bpy
 from bpy.types import Operator, Menu
 from bl_operators.presets import AddPresetBase
 import os
+from math import degrees
 
 from .sun_calc import (format_lat_long, format_time, format_hms, sun)
 
@@ -153,6 +154,7 @@ class SUNPOS_PT_Panel(bpy.types.Panel):
             col.label(text="Please select World in the World panel.",
                       icon="ERROR")
 
+
 class SUNPOS_PT_Location(bpy.types.Panel):
     bl_space_type = "PROPERTIES"
     bl_region_type = "WINDOW"
@@ -211,10 +213,10 @@ class SUNPOS_PT_Location(bpy.types.Panel):
             col = flow.column(align=True)
             split = col.split(factor=0.4, align=True)
             split.label(text="Azimuth:")
-            split.label(text=str(round(sun.azimuth, 3)) + "°")
+            split.label(text=str(round(degrees(sun.azimuth), 3)) + "°")
             split = col.split(factor=0.4, align=True)
             split.label(text="Elevation:")
-            split.label(text=str(round(sun.elevation, 3)) + "°")
+            split.label(text=str(round(degrees(sun.elevation), 3)) + "°")
             col.separator()
 
         if p.show_refraction:
@@ -282,7 +284,6 @@ class SUNPOS_PT_Time(bpy.types.Panel):
         split.label(text=ut)
         col.separator()
 
-
         col = flow.column(align=True)
         col.alignment = 'CENTER'
         if p.show_rise_set: