1.8.3 L1960-Tools Release

New: - Enhanced texture import for Dekogon Assets - Merge 4 Materials in Multi-Mats by one click Other fixes and tweaks
2025-10-03 11:44:58 +02:00
parent a60ae1c1ea
commit c68d02dc50
14 changed files with 3297 additions and 0 deletions
--- a/Blender/AR_WorkbenchCustomScripts.zip
+++ b/Blender/AR_WorkbenchCustomScripts.zip
--- a/Blender/L1960_Tools/_Release/L1960_Tools_1_8_3.zip
+++ b/Blender/L1960_Tools/_Release/L1960_Tools_1_8_3.zip
--- a/Blender/L1960_Tools/_Source/L1960_Tools_1_8_3/AutoColorPalette.py
+++ b/Blender/L1960_Tools/_Source/L1960_Tools_1_8_3/AutoColorPalette.py
@@ -0,0 +1,333 @@
 import bpy
 import math
 import csv
 import os
 import json
 from mathutils import Vector
 ### GENRATE MLOD ###
 plugin_dir = bpy.utils.user_resource('SCRIPTS')
 plugin_path = "addons\L1960Tools"
 L1960_path = os.path.join(plugin_dir, plugin_path)
 colorpalettes = [
    json.dumps(["ColorPalette_01.png", "BF1BC94A0DE4398F"]),
    json.dumps(["ColorPalette_02.png", "A95B2794A0EE8340"])
 ]
 enum_palettes = []
 for palettes in colorpalettes:
    file = json.loads(palettes)[0]
    enum_palettes.append((palettes, file[:-4], "Select " + file[:-4] + " for MLOD"))
 class EnumColorPalettes(bpy.types.PropertyGroup):
    mlod_enum_selection: bpy.props.EnumProperty(name="Color Palettes for MLOD", items = enum_palettes, description = "Choose a palette", default = 0)
 class MESH_OT_set_up_mlod(bpy.types.Operator):
    """Set´s up a material to be used for MLOD´s"""
    bl_idname = "mesh.set_up_mlod"
    bl_label = "Set´s up a material to be used for MLOD´s"
    bl_options = {"REGISTER", "UNDO"}
    def execute(self, context):
        #Load Color Palettes
        self.import_palettes_textures()
        #Selected Mesh
        obj = bpy.context.active_object
        if obj not in bpy.context.selected_objects or obj.type != "MESH":
            self.report({'WARNING'}, 'Select a Mesh to continue')
            return {"CANCELLED"}
        arr_layers = obj.data.uv_layers
        if not arr_layers.get("MLOD") or len(arr_layers) > 1:
            for uv_layer in reversed(arr_layers):
                arr_layers.remove(uv_layer)
            arr_layers.new(name = 'MLOD')
        if not len(obj.data.materials) == 0:
            obj.data.materials.clear()
        palette_enum_selection = json.loads(context.scene.color_palettes.mlod_enum_selection)
        mlod_material_name = "MLOD_" + palette_enum_selection[0][:-4] + "_" + palette_enum_selection[1]
        if not bpy.data.materials.get(mlod_material_name):
            material = bpy.data.materials.new(name=mlod_material_name)
            material.use_nodes = True
            bsdf_node = material.node_tree.nodes["Principled BSDF"]
            texImage = material.node_tree.nodes.new('ShaderNodeTexImage')
            texImage.image = bpy.data.images.get(palette_enum_selection[0])
            material.node_tree.links.new(bsdf_node.inputs['Base Color'], texImage.outputs['Color'])
        obj.data.materials.append(bpy.data.materials.get(mlod_material_name))
        self.report({'INFO'}, 'Mesh configured like MLOD')
        return {"FINISHED"}
    def import_palettes_textures(self):
        for image_name in colorpalettes:
            image_name = json.loads(image_name)[0]
            texture_name = image_name.split(".")[0]
            if texture_name not in bpy.data.textures:
                texture = bpy.data.textures.new(name=texture_name, type='IMAGE')
            else:
                texture = bpy.data.textures.get(texture_name)
            if image_name not in bpy.data.images:
                image = bpy.data.images.load(os.path.join(L1960_path, image_name))
            else:
                image = bpy.data.images.get(image_name)
            texture.image = image
 # texture_filepath = os.path.join(L1960_path, colorpalettes[1])
 ### Palette MLOD ###
 # class MESH_OT_bake_basic_mlod(bpy.types.Operator):
 #     """Set´s up a basic MLOD via Bake"""
 #     bl_idname = "mesh.bake_basic_mlod"
 #     bl_label = "Set´s up a basic MLOD via Bake"
 #     bl_options = {"REGISTER", "UNDO"}
 #     def execute(self, context):
 #         obj = context.active_object
 #         #Palette selection
 #         palette_enum_selection = json.loads(context.scene.color_palettes.mlod_enum_selection)
 #         if obj not in bpy.context.selected_objects or obj.type != "MESH":
 #             self.report({'WARNING'}, 'Select a Mesh to continue')
 #             return {"CANCELLED"}
 #         faces_with_color = self.get_faces_with_color(obj)
 #         grouped_colors = self.groupe_colors(faces_with_color, threshold=50)
 #         matched_colors = self.find_matching_color(grouped_colors, palette_enum_selection[0][:-4])
 #         self.adjust_UV(obj, matched_colors)
 #         #Entfernen des referenz Bake Image
 #         #bpy.data.images.remove(bpy.data.images["MLOD_Temp"])
 #         # Entfernen aller Meterials
 #         if not len(obj.data.materials) == 0:
 #             obj.data.materials.clear()
 #         # Create new Material with selected Palette
 #         mlod_material_name = "MLOD_" + palette_enum_selection[0][:-4] + palette_enum_selection[1]
 #         texture_filepath = os.path.join(L1960_path, palette_enum_selection[0])
 #         image = bpy.data.images.load(texture_filepath)
 #         if not bpy.data.materials.get(mlod_material_name):
 #             material = bpy.data.materials.new(name=mlod_material_name)
 #             material.use_nodes = True
 #             bsdf_node = material.node_tree.nodes["Principled BSDF"]
 #             texImage = material.node_tree.nodes.new('ShaderNodeTexImage')
 #             texImage.image = image
 #             material.node_tree.links.new(bsdf_node.inputs['Base Color'], texImage.outputs['Color'])
 #         obj.data.materials.append(bpy.data.materials.get(mlod_material_name))
 #         self.report({'INFO'}, f'MLOD sucessfully created with {palette_enum_selection[0][:-4]}.')
 #         return {"FINISHED"}
 #     def get_faces_with_color(self, obj):
 #         #Bake Image
 #         image = self.bake_diffuse(obj)
 #         mesh = obj.data
 #         uv_layer = mesh.uv_layers.active.data  # direct UV access
 #         colors = []
 #         for poly in mesh.polygons:  # same as "face" in BMesh
 #             # Durchschnittliche UV-Koordinaten berechnen
 #             uv = Vector((0.0, 0.0))
 #             for loop_index in poly.loop_indices:
 #                 uv += uv_layer[loop_index].uv
 #             uv /= len(poly.loop_indices)
 #             # UV → Pixel-Koordinaten (Bildgröße)
 #             x = int(uv.x * (image.size[0] - 1))
 #             y = int(uv.y * (image.size[1] - 1))
 #             # RGBA Pixel holen
 #             index = (y * image.size[0] + x) * 4
 #             pixel = image.pixels[index:index+4]
 #             # In 0–255 Werte umwandeln
 #             rgb_255 = [round(c * 255) for c in pixel][:3]
 #             colors.append({
 #                 "face": poly.index,
 #                 "rgb": rgb_255
 #             })
 #             # print(colors[-1]) # -> [{'face': <BMFace(0x000002B417086A30), index=0, totverts=4>, 'rgb': [0, 0, 0]}]
 #         return colors
 #     def groupe_colors(self, color_list, threshold = 10):
 #         groups = []
 #         for color in color_list:
 #             found_group = False
 #             for group in groups:
 #                 # Compute average color of the group
 #                 avg_color = [sum(c["rgb"][i] for c in group)/len(group) for i in range(3)]
 #                 if self.color_distance(color["rgb"], avg_color) <= threshold:
 #                     group.append(color)
 #                     found_group = True
 #                     break
 #             if not found_group:
 #                 groups.append([color])
 #         # Compute the average color for each group
 #         grouped_colors = [{
 #             "face": [c["face"] for c in group],
 #             "rgb": [round(sum(c["rgb"][i] for c in group) / len(group)) for i in range(3)]
 #             }
 #             for group in groups
 #         ]
 #         return grouped_colors
 #     def color_distance(self, c1, c2):
 #         return math.sqrt(
 #             (c1[0]-c2[0])**2 +
 #             (c1[1]-c2[1])**2 +
 #             (c1[2]-c2[2])**2
 #         )
 #     def read_color_csv(self, palette):
 #         colors = []
 #         try:
 #             with open(f"{palette}.csv", newline="") as datei:
 #                 reader = csv.DictReader(datei)
 #                 for row in reader:
 #                     colors.append({
 #                         "rgb": [int(row["r"]), int(row["g"]), int(row["b"])],
 #                         "norm_x": float(row["norm_x"]),
 #                         "norm_y": float(row["norm_y"])
 #                     })
 #             return colors
 #         except:
 #             return []
 #     def find_matching_color(self, colors, palette):
 #         match = []
 #         for color in colors:
 #             best = None
 #             min_dist = float("inf")
 #             for target in self.read_color_csv(palette):
 #                 dist = self.color_distance(target["rgb"], color["rgb"])
 #                 if dist < min_dist:
 #                     min_dist = dist
 #                     best = {
 #                         "face": color["face"],
 #                         "rgb": color["rgb"],
 #                         "norm_x": target["norm_x"],
 #                         "norm_y": target["norm_y"]
 #                     }
 #             match.append(best)
 #         return match
 #     def adjust_UV(self, obj, new_face_coords):
 #         scale = 0.001    # Skalierung
 #         mesh = obj.data
 #         arr_layers = obj.data.uv_layers
 #         if not arr_layers.get("MLOD") or len(arr_layers) > 1:
 #             for uv_layer in reversed(arr_layers):
 #                 arr_layers.remove(uv_layer)
 #             arr_layers.new(name = 'MLOD')
 #         uv_layer = arr_layers.get("MLOD")
 #         mesh.uv_layers.active = uv_layer
 #         for poly in mesh.polygons:
 #             for coords in new_face_coords:
 #                 if poly.index in coords["face"]:
 #                     # Mittelpunkt der UVs dieses Polygons berechnen
 #                     uvs = [uv_layer.data[i].uv.copy() for i in poly.loop_indices]
 #                     center = sum(uvs, Vector((0.0, 0.0))) / len(uvs)
 #                     # Skalieren + Verschieben
 #                     for i in poly.loop_indices:
 #                         uv = uv_layer.data[i].uv
 #                         uv -= center
 #                         uv *= scale
 #                         uv += Vector((float(coords["norm_x"]), float(coords["norm_y"])))
 #         # Mesh updaten
 #         mesh.update()
 #     def bake_diffuse(self, selected_obj, res = 1024):
 #         source_obj = None
 #         for obj in bpy.data.objects:
 #             if obj.type == 'MESH' and obj.name.endswith("_LOD0"):
 #                 print(obj.name)                
 #                 source_obj = obj.copy()
 #                 source_obj.data = obj.data.copy()
 #                 bpy.context.collection.objects.link(source_obj)
 #                 break
 #         if source_obj is None:
 #             source_obj = selected_obj.copy()
 #             source_obj.data = selected_obj.data.copy()
 #             bpy.context.collection.objects.link(source_obj)
 #         # Material erstellen
 #         if "MLOD_Temp" in bpy.data.materials:
 #             mat = bpy.data.materials.remove["MLOD_Temp"]
 #         mat = bpy.data.materials.new(name="MLOD_Temp")
 #         source_obj.data.materials.clear()
 #         source_obj.data.materials.append(mat)
 #         # WICHTIG: Material als aktives Material setzen
 #         mat.use_nodes = True
 #         source_obj.active_material = mat
 #         # Ziel Image Node konfigurieren
 #         nodes = mat.node_tree.nodes
 #         links = mat.node_tree.links
 #         nodes.clear()
 #         tex_node = nodes.new(type="ShaderNodeTexImage")
 #         bsdf = nodes.new(type="ShaderNodeBsdfPrincipled")
 #         output = nodes.new(type="ShaderNodeOutputMaterial")
 #         links.new(bsdf.outputs["BSDF"], output.inputs["Surface"])
 #         links.new(tex_node.outputs["Color"], bsdf.inputs["Base Color"])
 #         nodes.active = tex_node
 #         # Erstellen des Images
 #         if "MLOD_Temp" in bpy.data.images:
 #             bpy.data.images.remove(bpy.data.images["MLOD_Temp"])
 #         image = bpy.data.images.new("MLOD_Temp", res, res)
 #         tex_node.image = image
 #         # Selected Object = Quelle
 #         bpy.context.view_layer.objects.active = source_obj
 #         # Active Object = Ziel
 #         selected_obj.select_set(True)
 #         # Bake
 #         bpy.context.scene.render.engine = 'CYCLES'
 #         bpy.ops.object.bake(type='COMBINED', width=512, height=512, cage_extrusion=0.5, pass_filter={'COLOR'}, margin=16, use_selected_to_active=True)
 #         # Temporäre Helfer entfernen
 #         bpy.data.objects.remove(source_obj, do_unlink=True)
 #         if "MLOD_Temp" in bpy.data.materials:
 #             bpy.data.materials.remove(mat)
 #         bpy.context.view_layer.objects.active = selected_obj
 #         return image
--- a/Blender/L1960_Tools/_Source/L1960_Tools_1_8_3/ColorPalette_01.csv
+++ b/Blender/L1960_Tools/_Source/L1960_Tools_1_8_3/ColorPalette_01.csv
--- a/Blender/L1960_Tools/_Source/L1960_Tools_1_8_3/ColorPalette_01.png
+++ b/Blender/L1960_Tools/_Source/L1960_Tools_1_8_3/ColorPalette_01.png
--- a/Blender/L1960_Tools/_Source/L1960_Tools_1_8_3/ColorPalette_02.csv
+++ b/Blender/L1960_Tools/_Source/L1960_Tools_1_8_3/ColorPalette_02.csv
--- a/Blender/L1960_Tools/_Source/L1960_Tools_1_8_3/ColorPalette_02.png
+++ b/Blender/L1960_Tools/_Source/L1960_Tools_1_8_3/ColorPalette_02.png
--- a/Blender/L1960_Tools/_Source/L1960_Tools_1_8_3/CubeProjection.py
+++ b/Blender/L1960_Tools/_Source/L1960_Tools_1_8_3/CubeProjection.py
@@ -0,0 +1,94 @@
 import bpy
 from math import pi
 L1960_Arr_PlainData = [
    ["Proj_Empty_01",    (0, 0, 2),     (0, 0, 0)],
    ["Proj_Empty_02",    (2, 0, 0),     ((pi * 90 / 180), 0, (pi * 90 / 180))],
    ["Proj_Empty_03",    (0, 2, 0),     ((pi * 90 / 180), 0, (pi * 180 / 180))],
    ["Proj_Empty_04",    (0, 0, -2),    ((pi * 180 / 180), 0, 0)],
    ["Proj_Empty_05",    (-2, 0, 0),    ((pi * 90 / 180), 0, (pi * -90 / 180))],
    ["Proj_Empty_06",    (0, -2, 0),    ((pi * 90 / 180), 0, 0)]
 ]
 class MESH_OT_add_auto_cube_projection(bpy.types.Operator):
    """Check Empty´s for projecting, if not existing create new one´s"""
    bl_idname = "mesh.add_auto_cube_projection"
    bl_label = "Add Plain_Axes to scene"
    bl_options = {"REGISTER", "UNDO"}
    def execute(self, context):
        scene = context.scene
        oldSelection = context.selected_objects
        oldActive = context.active_object
        for EmptyData in L1960_Arr_PlainData:
            EmptyName = EmptyData[0]
            EmptyLocation = EmptyData[1]
            EmptyRotation = EmptyData[2]
            if not scene.objects.get(EmptyName):
                bpy.ops.object.empty_add(type='PLAIN_AXES', align='WORLD', location=EmptyLocation, scale=(1, 1, 1), rotation=EmptyRotation)
                empty = context.active_object
                empty.name = EmptyName
                empty.hide_select = True
                empty.hide_set(True)
        #Change back to old selection and select old active
        for obj in oldSelection:
            obj.select_set(True)
        context.view_layer.objects.active = oldActive
        self.report({'INFO'}, 'Added/Fixed Emptys for Projection to Scene')
        return {"FINISHED"}
 class MESH_OT_add_modifier_to_mesh(bpy.types.Operator):
    """Add Modifier to selected Mesh´s and prepare UV-Maps"""
    bl_idname = "mesh.add_modifier_to_mesh"
    bl_label = "Add Modifier to selected Mesh"
    bl_options = {"REGISTER", "UNDO"}
    def execute(self, context):     
        newModifierName = "CubeTexModifier"
        arr_obj = context.selected_objects
        if not arr_obj:
            self.report({'WARNING'}, 'Select a mesh to add the UVProject-Modifier')
            return {"CANCELLED"}
        empty_objs = [emp_obj for emp_obj in context.scene.objects if emp_obj.name.startswith("Proj_Empty")]
        if len(empty_objs) < 6:
            self.report({'WARNING'}, 'Create/Recreate projectors, they need to be set up first!')
            return {"CANCELLED"};
        for obj in arr_obj:
            if obj.data.uv_layers.get("UVMap"):
                obj.data.uv_layers['UVMap'].name = 'UVMap0'
            if not obj.data.uv_layers.get("UVMap0"):
                obj.data.uv_layers.new(name = 'UVMap0')
            if not obj.data.uv_layers.get("UVMap1"):
                obj.data.uv_layers.new(name = 'UVMap1')
            if obj.type == "MESH" and newModifierName not in obj.modifiers:
                obj.modifiers.new(type='UV_PROJECT', name=newModifierName)
                mod = obj.modifiers[newModifierName]
                mod.uv_layer = "UVMap1"
                mod.projector_count = 6
                i = 0
                for p in mod.projectors:
                    p.object = bpy.data.objects[L1960_Arr_PlainData[i][0]]
                    i = i+1
            else:
                self.report({'INFO'}, 'UVProject-Modifier allready set')
                return {"FINISHED"}
        self.report({'INFO'}, 'Added UVProject-Modifier to mesh')
        return {"FINISHED"}
--- a/Blender/L1960_Tools/_Source/L1960_Tools_1_8_3/Dekogon.py
+++ b/Blender/L1960_Tools/_Source/L1960_Tools_1_8_3/Dekogon.py
@@ -0,0 +1,187 @@
 import bpy
 import re
 import os
 ### GROUP OBJECTS TO COLLECTIONS ###
 class MESH_OT_group_objects_in_collections(bpy.types.Operator):
    """Groups objects by name into seperate collections, usefull for Unreal Decogon import"""
    bl_idname = "mesh.group_objects_in_collections"
    bl_label = "Groups objects by name into seperate collections, usefull for Unreal Decogon import"
    bl_options = {"REGISTER", "UNDO"}
    def execute(self, context):
        # Erstellen einer leeren Dictionary zur Speicherung der Collections nach Basisnamen
        collection_dict = {}
        # Durchlaufen aller Objekte in der Szene
        for obj in context.scene.objects:
            # Überprüfen, ob das Objekt ein leeres Elternobjekt ist
            if obj.type == 'EMPTY':
                # Anwenden der Regex auf den Objektnamen
                match = re.match(r'^(.*?)_(.*?)_(\d+)([a-zA-Z]+)$', obj.name)
                if match:
                    prefix = match.group(1)
                    name = match.group(2)
                    number = match.group(3)
                    letter = match.group(4)
                    # Extrahieren des Basisnamens für die Collection
                    base_name = f"L1960_{name}"
                    # Hinzufügen des Objekts zur entsprechenden Liste in der Dictionary
                    if base_name not in collection_dict:
                        collection_dict[base_name] = {}
                    if number not in collection_dict[base_name]:
                        collection_dict[base_name][number] = {}
                    if letter not in collection_dict[base_name][number]:
                        collection_dict[base_name][number][letter] = {'empty': obj, 'children': []}
        # Durchlaufen der Dictionary und Erstellen der Collections
        for base_name, number_dict in collection_dict.items():
            # Erstellen einer neuen Collection für den Basisnamen
            base_collection = bpy.data.collections.new(base_name)
            bpy.context.scene.collection.children.link(base_collection)
            # Durchlaufen der sortierten Liste der Objekte und Verschieben in die Collections
            for number, letter_dict in number_dict.items():
                # Erstellen einer Collection für die Nummer und Verschieben des leeren Elternobjekts dorthin
                number_collection = bpy.data.collections.new(f"{base_name}_{number}")
                base_collection.children.link(number_collection)
                # Durchlaufen der Buchstaben und Erstellen der Buchstaben-Collection unter der Nummer
                for letter, obj_data in letter_dict.items():
                    empty = obj_data['empty']
                    children = empty.children
                    letter_collection = bpy.data.collections.new(f"{base_name}_{number}{letter}")
                    number_collection.children.link(letter_collection)
                    # Verschieben des leeren Elternobjekts in die entsprechende Collection
                    letter_collection.objects.link(empty)
                    # Verschieben der Kinder des leeren Elternobjekts in die entsprechende Collection
                    for child in children:
                        letter_collection.objects.link(child)
                    # Entfernen des leeren Elternobjekts und seiner Kinder aus der Szene
                    bpy.context.collection.objects.unlink(empty)
                    for child in children:
                        bpy.context.collection.objects.unlink(child)
        # -------------------------------------------------------------------------------------------
        # Regular expression pattern to match any _LOD1, _LOD2, etc., but not _LOD0
        pattern = re.compile(r"_LOD[1-9]\d*$")
        # Loop through all objects in the scene
        for obj in bpy.context.scene.objects:
            # If the object name matches the pattern, hide it
            if pattern.search(obj.name):
                obj.hide_set(True)  # This hides the object in the viewport
            else:
                obj.hide_set(False)  # Ensure _LOD0 objects remain visible
        # Update the view layer to reflect changes
        bpy.context.view_layer.update()
        self.report({'INFO'}, 'All objects sorted')
        return {"FINISHED"}
 ### ASSIGN TEXTURES ###
 class MESH_OT_assign_textures(bpy.types.Operator):
    """Assign Textures to Mesh´s, usefull for Unreal Decogon import"""
    bl_idname = "mesh.assign_textures"
    bl_label = "Assign Textures to Mesh´s, usefull for Unreal Decogon import"
    bl_options = {"REGISTER", "UNDO"}
    def execute(self, context):
        # Define the path to the folder containing your textures
        texture_folder_path = context.scene.dekogon_file_path
        texture_prefix = context.scene.dekogon_settings_prefix
        if texture_prefix != "":
            if texture_prefix[-1] != "_":
                texture_prefix = texture_prefix + "_"
        texture_suffix = context.scene.dekogon_settings_suffix
        if texture_suffix != "":
            if texture_suffix[0] != "_":
                texture_suffix = "_" + texture_suffix
        texture_filetype = context.scene.dekogon_settings_filetype
        if not os.path.exists(texture_folder_path):
            self.report({'ERROR'}, f"The texture folder path '{texture_folder_path}' does not exist.")
            return {"FINISHED"}
        else:
            self.report({'INFO'}, f"Texture folder path: {texture_folder_path}")
            # List all files in the texture folder for debugging purposes
            #texture_files = os.listdir(texture_folder_path)
            #self.report({'INFO'}, "Files in texture folder:")
            #for f in texture_files:
            #    print(f"  - {f}")
        # Iterate over all materials in the Blender file
        for material in bpy.data.materials:
            self.report({'INFO'}, f"Processing material: {material.name}")
            # Ensure the material uses nodes
            if not material.use_nodes:
                material.use_nodes = True
                self.report({'INFO'}, f"Enabled nodes for material: {material.name}")
            # Get the node tree of the material
            if material.node_tree is None:
                self.report({'WARNING'}, f"Material {material.name} has no node tree.")
                continue
            nodes = material.node_tree.nodes
            # Find or create an Image Texture node
            image_texture_node = None
            for node in nodes:
                if node.type == 'TEX_IMAGE':
                    image_texture_node = node
                    break
            if image_texture_node is None:
                image_texture_node = nodes.new(type='ShaderNodeTexImage')
                self.report({'INFO'}, f"Created new Image Texture node for material: {material.name}")
            else:
                self.report({'INFO'}, f"Found existing Image Texture node for material: {material.name}")
            # Construct the expected texture filename based on the material name
            texture_filename = f"{texture_prefix}{material.name}{texture_suffix}.{texture_filetype}"
            texture_filepath = os.path.join(texture_folder_path, texture_filename)
            self.report({'INFO'}, f"Looking for texture: {texture_filepath}")
            # Check if the texture file exists
            if os.path.exists(texture_filepath):
                try:
                    # Load the image and assign it to the Image Texture node
                    image = bpy.data.images.load(texture_filepath)
                    image_texture_node.image = image
                    self.report({'INFO'}, f"Loaded texture: {texture_filename} for material: {material.name}")
                    # Link the Image Texture node to the Base Color of the Principled BSDF shader
                    principled_node = None
                    for node in nodes:
                        if node.type == 'BSDF_PRINCIPLED':
                            principled_node = node
                            break
                    if principled_node is not None:
                        links = material.node_tree.links
                        links.new(image_texture_node.outputs['Color'], principled_node.inputs['Base Color'])
                        self.report({'INFO'}, f"Linked texture to Principled BSDF for material: {material.name}")
                    else:
                        self.report({'WARNING'}, f"No Principled BSDF node found for material: {material.name}")
                except RuntimeError as e:
                    self.report({'ERROR'}, f"Failed to load image {texture_filename}: {e}")
            else:
                self.report({'WARNING'}, "Texture file not found for material {material.name}: {texture_filename}")
        self.report({'INFO'}, 'Texture assignment complete.')
        return {"FINISHED"}
--- a/Blender/L1960_Tools/_Source/L1960_Tools_1_8_3/Helper.py
+++ b/Blender/L1960_Tools/_Source/L1960_Tools_1_8_3/Helper.py
@@ -0,0 +1,139 @@
 import bpy
 import bmesh
 ### FIX MATERIALS ###
 class MESH_OT_fix_material_names(bpy.types.Operator):
    """Fixes the material naming, if duplicated are present e.g. Material.001, Material.002 ..."""
    bl_idname = "mesh.fix_material_names"
    bl_label = "Fixes the material naming, if duplicated are present"
    bl_options = {"REGISTER", "UNDO"}
    def execute(self, context):
        #Remove all duplicated materials
        self.merge_duplicated_materials()
        #Merge material slots for every mesh in the scene
        for obj in bpy.context.scene.objects:
            if obj.type == "MESH":
                self.merge_material_slots(obj)
        self.report({'INFO'}, 'All duplicated Materials fixed')
        return {"FINISHED"}
    def merge_duplicated_materials(self):
        for material in bpy.data.materials:
            #Remove MI for Dekogon material names
            if material.name.split('_')[0] == 'MI':
                material.name = material.name[3:]
            #Check for .001 at end and remove
            if material.name[-3:].isnumeric():
                opti_matName = material.name[:-4]
                if bpy.data.materials.get(opti_matName): #check if og_mat exists
                    material.user_remap(bpy.data.materials.get(opti_matName))
                    print("Removed Material: " + material.name)
                    bpy.data.materials.remove(material)
                else:
                    material.name = opti_matName
    def merge_material_slots(self, obj):
        duplicated_material_list = []
        #create list with indexes of material slots with the same name and merge them
        for og_slot in obj.material_slots:
            for slot in obj.material_slots:
                if slot.name == og_slot.name:
                    if slot.slot_index == og_slot.slot_index:
                        continue
                    if og_slot.slot_index in duplicated_material_list:
                        continue
                    duplicated_material_list.append(int(slot.slot_index))
        #delete all material slots within list
        for slot_index in sorted(duplicated_material_list, reverse=True):
            obj.data.materials.pop(index = slot_index)
 ### FIX NAMING CONVENTIONS ###
 class MESH_OT_fix_naming_conventions(bpy.types.Operator):
    """Changes . to _ to solve naming issues with workbench"""
    bl_idname = "mesh.fix_naming_convention"
    bl_label = "Changes . to _ to solve naming issues with workbench"
    bl_options = {"REGISTER", "UNDO"}
    def execute(self, context):
        for obj in bpy.data.objects:
            obj.name = obj.name.replace(".","_")
        self.report({'INFO'}, 'Fixed Naming')
        return {"FINISHED"}
 class MESH_OT_generate_empty_for_mesh(bpy.types.Operator):
    """Generates a Empty with the objects name at it´s position"""
    bl_idname = "mesh.generate_empty_for_mesh"
    bl_label = "Generates a Empty with the objects name at it´s position"
    bl_options = {"REGISTER", "UNDO"}
    def execute(self, context):
        scene = bpy.context.scene
        Selection = bpy.context.selected_objects
        FilteredSelection = [obj for obj in Selection if obj.type != 'EMPTY']
        ActiveObj = bpy.context.active_object
        for obj in FilteredSelection:
            oldEmpty = scene.objects.get("Socket_" + obj.name)
            if oldEmpty:
                oldEmpty.location = obj.location
                oldEmpty.rotation_euler  = obj.rotation_euler 
            else:
                obj.select_set(True)
                bpy.ops.object.empty_add(type='PLAIN_AXES', align='WORLD', location=obj.location, scale=(1, 1, 1), rotation=obj.rotation_euler)
                empty = bpy.context.active_object
                empty.name = "Socket_" + obj.name
        #Change back to selection and select old active
        bpy.ops.object.select_all(action='DESELECT')
        self.report({'INFO'}, 'Generated Emptys for selectes Meshes in Scene')
        return {"FINISHED"}
 class MESH_OT_select_face_id(bpy.types.Operator):
    """Highlights Face with given ID"""
    bl_idname = "mesh.select_face_id"
    bl_label = "Highlight/Select Face with given Index"
    bl_options = {"REGISTER", "UNDO"}
    def execute(self, context):
        EditObj = bpy.context.active_object
        face_Index = int(context.scene.face_id_field)
        if EditObj != None:
            bpy.ops.object.mode_set(mode='EDIT')
            bpy.ops.mesh.select_all(action='DESELECT')
            bm = bmesh.from_edit_mesh(EditObj.data)
            bm.faces.ensure_lookup_table()
            for area in bpy.context.screen.areas:
                if area.type == 'VIEW_3D':
                    for space in area.spaces:
                        if space.type == 'VIEW_3D':
                            space.shading.type = 'WIREFRAME'
            try:
                bm.faces[face_Index].select = True
                bmesh.update_edit_mesh(EditObj.data)
                self.report({'INFO'}, f'Highlighted Face with Index: {face_Index}')
                return {"FINISHED"}
            except IndexError:
                self.report({'INFO'}, f'Index: {face_Index} out of range!')
                return {"FINISHED"}
        else:
            self.report({'INFO'}, 'Please select a Mesh first.')
            return {"FINISHED"}
--- a/Blender/L1960_Tools/_Source/L1960_Tools_1_8_3/MaterialToMask.py
+++ b/Blender/L1960_Tools/_Source/L1960_Tools_1_8_3/MaterialToMask.py
@@ -0,0 +1,215 @@
 import bpy
 import bmesh
 # Callback for Enum Items
 def get_uv_layers(self, context):
    items = []
    obj = context.object
    if obj and obj.type == 'MESH' and obj.data.uv_layers:
        for i, uv in enumerate(obj.data.uv_layers):
            items.append((str(i), uv.name, f"UV Layer {i}"))
    else:
        items.append(("NONE", "No UVs", "No UV available within Mesh"))
    return items
 class UVEnumProperties(bpy.types.PropertyGroup):
    uv_enum: bpy.props.EnumProperty(name="UV Map", description="Select UV-Layer", items=get_uv_layers, default=0)
 class MESH_OT_merge_materials_to_mask(bpy.types.Operator):
    """Merges 4 Materials into one Material (Mask)"""
    bl_idname = "mesh.merge_materials_to_mask"
    bl_label = "Merges 4 Materials into one Material (Mask)"
    bl_options = {"REGISTER", "UNDO"}
    def execute(self, context):         
        scene = context.scene
        arr_obj = context.selected_objects
        activeObj = context.active_object
        ignore_custom = context.scene.settings_multi_ignor
        island_margin_custom = context.scene.uv_island_margin_slider
        # Scale and offset for UV allignment
        SCALE = 0.5
        OFFSETS = [
                (0.0, 0.5),
                (0.5, 0.5),
                (0.0, 0.0),
                (0.5, 0.0)
        ]
        IGNORE = ["glass", "glas", "grass", "gras"] + ignore_custom.split(",")
        # No Mesh selected
        if not arr_obj:
            self.report({'WARNING'}, 'Select one mesh')
            return {"CANCELLED"}
        # Only one Mesh selected?
        if len(arr_obj) > 1:
            self.report({'WARNING'}, 'Only one Mesh can be selected')
            return {"CANCELLED"}
        obj = arr_obj[0]
        selected_uv = context.scene.uv_enum_props.uv_enum
        # UV Maps present?
        if not obj.data.uv_layers or not selected_uv:
            self.report({'WARNING'}, 'No UV-Map selected')
            return {"CANCELLED"}
        obj.data.uv_layers.active_index = int(selected_uv)
        skip = 0
        idx_multi = None
        delete = []
        # Loop through all Materials
        for i, slot in enumerate(obj.material_slots):
            # Skip Materials in static ignore list or user ignore list
            if any(name in slot.material.name.lower() for name in IGNORE):
                self.report({'INFO'}, f'Material "{slot.material.name}" skipped.')
                skip += 1
                continue
            # Switch to edit mode
            bpy.ops.object.mode_set(mode='EDIT')
            # Create bmesh to work with
            bm = bmesh.from_edit_mesh(obj.data)
            uv_layer = bm.loops.layers.uv.active
            # Deselect all
            bpy.ops.mesh.select_all(action='DESELECT')
            if slot.material:
                # Select Mat slot
                obj.active_material_index = i
                # Select all Faces of Mat
                bpy.ops.object.material_slot_select()
                # If UV has assigned faces
                if any(f.select for f in bm.faces):
                    # Repack UV Islands
                    bpy.ops.uv.select_all(action='SELECT')
                    bpy.ops.uv.pack_islands(margin=island_margin_custom)
                    # Select Offset
                    group = (i - skip) % len(OFFSETS)
                    offset = OFFSETS[group]
                    # Scale and offset UV
                    for f in bm.faces:
                        if f.select:
                            for loop in f.loops:
                                uv = loop[uv_layer].uv
                                uv[0] = offset[0] + uv[0] * SCALE
                                uv[1] = offset[1] + uv[1] * SCALE
                # Apply Changes
                bmesh.update_edit_mesh(obj.data)
                # Create Texture Attributes with previous material names 
                match group:
                    case 0:
                        mat = bpy.data.materials.get(obj.material_slots[i].name)
                        mat["Black  "] = mat.name
                        # Change name and use as base to merge
                        mat.name = "Multi_" + mat.name
                        idx_multi = i
                        self.report({'INFO'}, f'Material "{mat.name}" created.')
                        continue
                    case 1:
                        mat = bpy.data.materials.get(obj.material_slots[idx_multi].name)
                        mat["Red     "] = slot.material.name
                    case 2:
                        mat = bpy.data.materials.get(obj.material_slots[idx_multi].name)
                        mat["Green "] = slot.material.name
                    case 3:
                        mat = bpy.data.materials.get(obj.material_slots[idx_multi].name)
                        mat["Blue    "] = slot.material.name
                    case _:
                        pass
                # Merge Material A -> B
                self.merge_mat_A_to_B(obj, i, idx_multi)
                # Add Material B to delete list
                delete.insert(0, i)
        # Switch to object mode
        bpy.ops.object.mode_set(mode='OBJECT')
        # Delete not used materials from list
        for mat in delete:
            obj.active_material_index = mat
            bpy.ops.object.material_slot_remove()
        # Put UV first
        self.put_UV_first(obj, selected_uv)
        # Change UV names like in Reforger Tools
        mesh = obj.data
        uv_layers = mesh.uv_layers
        for i, layer in enumerate(uv_layers):
            layer.name = f"UVMap{i + 1}"
        self.report({'INFO'}, 'Merged Materials to Multitextures.')
        return {"FINISHED"}
    def merge_mat_A_to_B(self, obj, mat_A, mat_B):
        # check if Mat Name is index or string and convert
        if type(mat_A) is str:
            mat_A = bpy.data.materials.get(mat_A)
            mat_A = obj.material_slots.find(mat_A)
        if type(mat_B) is str:
            mat_B = bpy.data.materials.get(mat_B)
            mat_B = obj.material_slots.find(mat_B)
        # Change to Edit Mode
        bpy.ops.object.mode_set(mode='EDIT')
        bpy.ops.mesh.select_all(action='DESELECT')
        # Select all Faces from Mat B
        obj.active_material_index = mat_A
        bpy.ops.object.material_slot_select()
        # Select Mat A and assign Faces from Mat B
        obj.active_material_index = mat_B
        bpy.ops.object.material_slot_assign()  # Faces from B → A
        # Switch to object mode
        bpy.ops.object.mode_set(mode='OBJECT')
    def put_UV_first(self, obj, target_index):
        mesh = obj.data
        uv_layers = mesh.uv_layers
        if len(uv_layers) > 1:
            # Transform UV-Layers to dict
            uv_data_dict = {i: [loop_uv.uv.copy() for loop_uv in layer.data] for i, layer in enumerate(uv_layers)}
            # Order: target_index -> first
            indices = list(range(len(uv_layers)))
            new_order = [target_index] + [i for i in indices if i != target_index]
            # Delete all UV-layers
            while len(uv_layers) > 0:
                uv_layers.remove(uv_layers[0])
            # write new order of UV´s 
            new_layers = []
            for old_idx in new_order:
                new_layer = uv_layers.new(name=f"Temp_{old_idx}")  # temp Name
                old_data = uv_data_dict[old_idx]
                for j, loop_uv in enumerate(old_data):
                    new_layer.data[j].uv = loop_uv
                new_layers.append(new_layer)
        # Set active UV
        uv_layers.active_index = 0
--- a/Blender/L1960_Tools/_Source/L1960_Tools_1_8_3/PrepareLods.py
+++ b/Blender/L1960_Tools/_Source/L1960_Tools_1_8_3/PrepareLods.py
@@ -0,0 +1,42 @@
 import bpy
 ### PREPARE LODS ###
 class MESH_OT_prepare_lods_decimate(bpy.types.Operator):
    """Copy current Mesh and apply decimate Modifier"""
    bl_idname = "mesh.prepare_lods_decimate"
    bl_label = "Copy current Mesh and apply decimate Modifier"
    bl_options = {"REGISTER", "UNDO"}
    def execute(self, context):
        #Selected Mesh
        obj = bpy.context.active_object
        if obj not in bpy.context.selected_objects or obj.type != "MESH":
            self.report({'WARNING'}, 'Select a Mesh to continue')
            return {"CANCELLED"}
        if not obj.name[:-1].endswith('LOD'):
            obj.name = obj.name + '_LOD0'
        LODnumber = context.scene.lod_slider #Get from Slider
        startLODcount = int(obj.name[-1])
        endLODcount = startLODcount + LODnumber
        for i in range (startLODcount + 1, endLODcount):
            new_obj = obj.copy()
            new_obj.data = obj.data.copy()
            new_obj.name = obj.name[:-1] + str(i)
            bpy.context.collection.objects.link(new_obj)
            for t in range (startLODcount, i):
                newModifierName = 'LOD_Decimate_' + str(t)
                new_obj.modifiers.new(type='DECIMATE', name=newModifierName)
                mod = new_obj.modifiers[newModifierName]
                mod.ratio = 0.49
                mod.use_collapse_triangulate = True
        self.report({'INFO'}, 'LOD´s created')
        return {"FINISHED"}
--- a/Blender/L1960_Tools/_Source/L1960_Tools_1_8_3/_CreateColorPaletteMatrix.py
+++ b/Blender/L1960_Tools/_Source/L1960_Tools_1_8_3/_CreateColorPaletteMatrix.py
@@ -0,0 +1,30 @@
 from PIL import Image
 import csv
 palettes = ["ColorPalette_01", "ColorPalette_02"]
 for palette in palettes:
    # Bild öffnen (Pfad anpassen)
    bild = Image.open(f"{palette}.png").convert("RGB")
    breite, hoehe = bild.size
    tiles_x, tiles_y = 32, 32
    # Auf 32x32 verkleinern (nimmt repräsentative Pixel pro Kachel)
    klein = bild.resize((32, 32), Image.NEAREST)
    # CSV-Datei schreiben
    with open(f"{palette}.csv", mode="w", newline="") as datei:
        writer = csv.writer(datei)
        writer.writerow(["norm_x", "norm_y", "r", "g", "b"])
        for py in range(tiles_y):
            for px in range(tiles_x):
                # Farbe an diesem Pixel holen
                r, g, b = bild.getpixel((int(px), int(py)))
                # Normalisierung [0,1]
                norm_x = (px / (breite)) + 1/64
                norm_y = 1.0 - ((py / (hoehe))) - 1/64
                writer.writerow([f"{norm_x:.6f}", f"{norm_y:.6f}", r, g, b])
--- a/Blender/L1960_Tools/_Source/L1960_Tools_1_8_3/init.py
+++ b/Blender/L1960_Tools/_Source/L1960_Tools_1_8_3/init.py
@@ -0,0 +1,207 @@
 bl_info = {
    "name": "L1960 Tools",
    "author": "Prodeath21",
    "version": (1, 8, 3),
    "blender": (4, 2, 0),
    "location": "3D Viewport > Sidebar > 1960Life category",
    "description": "Set´s up the Projection-Modifier automatically and add´s in the Emptys if not allready created.",
    "category": "Object",
 }
 # ----------------------------------------------
 # Import modules
 # ----------------------------------------------
 if "bpy" in locals():
    import imp
    imp.reload(Dekogon)
    imp.reload(CubeProjection)
    imp.reload(Helper)
    imp.reload(PrepareLods)
    imp.reload(AutoColorPalette)
    imp.reload(MaterialToMask)
    print("L1960 Tools: Reloaded multifiles")
 else:
    from . import Dekogon
    from . import CubeProjection
    from . import Helper
    from . import PrepareLods
    from . import AutoColorPalette
    from . import MaterialToMask
 import bpy
 from . Dekogon              import MESH_OT_group_objects_in_collections, MESH_OT_assign_textures
 from . CubeProjection       import MESH_OT_add_auto_cube_projection, MESH_OT_add_modifier_to_mesh
 from . Helper               import MESH_OT_fix_material_names, MESH_OT_fix_naming_conventions, MESH_OT_generate_empty_for_mesh, MESH_OT_select_face_id
 from . PrepareLods          import MESH_OT_prepare_lods_decimate
 from . AutoColorPalette     import MESH_OT_set_up_mlod, EnumColorPalettes # MESH_OT_bake_basic_mlod,
 from . MaterialToMask       import UVEnumProperties, MESH_OT_merge_materials_to_mask
 class L1960_PT_dekogon(bpy.types.Panel):
    #where to add the panel
    bl_space_type = "VIEW_3D"
    bl_region_type = "UI"
    #add labels
    bl_label = "1960-Life Import"
    bl_category = "1960-Life"
    bl_options = {'DEFAULT_CLOSED'}
    def draw(self, context):
        box = self.layout.box()
        # Dekogon-Import
        box.label(text="Dekogon-Import")
        row = box.row()
        row.operator("mesh.group_objects_in_collections", text="Group to Collections")
        row = box.row()
        split = row.split(factor=0.5)
        split.operator("mesh.assign_textures", text="Assign Textures")
        split.prop(context.scene, "dekogon_file_path", text="")
        row = box.row()
        row.prop(context.scene, "section1",
                 text="Settings",
                 icon="TRIA_DOWN" if context.scene.section1 else "TRIA_RIGHT",
                 emboss=False)
        if context.scene.section1:
            box.prop(context.scene, "dekogon_settings_prefix", text="Prefix")
            box.prop(context.scene, "dekogon_settings_suffix", text="Suffix")
            box.prop(context.scene, "dekogon_settings_filetype", text="File Type")
        self.layout.separator() 
        box = self.layout.box()
        # Americano-Import
        box.label(text="Materials-to-Multi")
        row = box.row()
        row.operator("mesh.merge_materials_to_mask", text="Merge Materials to Mask")
        row = box.row()
        row.prop(context.scene, "section2",
                 text="Settings",
                 icon="TRIA_DOWN" if context.scene.section2 else "TRIA_RIGHT",
                 emboss=False)
        if context.scene.section2:
            row = box.row()
            props = context.scene.uv_enum_props
            row.prop(props, "uv_enum", text="Use UV")
            box.prop(context.scene, "settings_multi_ignor", text="Ignore")
            box.prop(context.scene, "uv_island_margin_slider", text="Island Margin")
 class L1960_PT_tools(bpy.types.Panel):
    #where to add the panel
    bl_space_type = "VIEW_3D"
    bl_region_type = "UI"
    #add labels
    bl_label = "1960-Life Tools" 
    bl_category = "1960-Life"
    def draw(self, context):
        """define the layout of the panel"""
        box = self.layout.box()
        # UV-Project helper
        box.label(text="UV-Projection")
        row = box.row()
        row.operator("mesh.add_auto_cube_projection", text="Set up Projectors")
        row = box.row()
        row.operator("mesh.add_modifier_to_mesh", text="Add Modifier to Mesh")
        self.layout.separator()
        # Helpers
        box = self.layout.box()
        box.label(text="Various Helper")
        row = box.row()
        row.operator("mesh.fix_material_names", text="Fix Material Name´s")
        row = box.row()
        row.operator("mesh.fix_naming_convention", text="Fix Naming Convention")
        row = box.row()
        row.operator("mesh.generate_empty_for_mesh", text="Generate Empty")
        row = box.row()
        split = row.split(factor=0.7)
        split.operator("mesh.select_face_id", text="Show Face Index")
        split.prop(context.scene, "face_id_field", text="")
        self.layout.separator()
        # Generate LODs
        box = self.layout.box()
        box.label(text="LOD´s")
        row = box.row()
        row.operator("mesh.prepare_lods_decimate", text="Create LOD´s")
        box.prop(context.scene, "lod_slider", text="Amount")
        box = self.layout.box()
        box.prop(context.scene.color_palettes, "mlod_enum_selection", expand=True)
        # row = box.row()
        # row.operator("mesh.set_up_mlod", text="Set up MLOD")
        row = box.row()
        row.operator("mesh.set_up_mlod", text="Generate MLOD (Palette)")
        self.layout.separator()
        ###############################
        # Enfusion Blender Tools Linked
        box = self.layout.box()
        box.label(text="EBT Linked")
        row = box.row()
        row.operator("view3d.ebt_sort", text="Sort Objects")
        # colliders setup is allowed in both OBJECT and EDIT mode
        row = box.row()
        row.operator("view3d.ebt_colliders_setup", text=" Colliders Setup")
        row = box.row()
        # Light Setup
        row.operator("view3d.ebt_setup_light", text=" Light Setup")
        row = box.row()
        col = row.column(align=True)
        # Update Materials
        col.operator("scene.ebt_update_enf_materials",)
        row = box.row()
        col = row.column(align=True)
 #register the panel with blender
 modules = [ L1960_PT_dekogon,
            L1960_PT_tools,
            MESH_OT_add_auto_cube_projection,
            MESH_OT_add_modifier_to_mesh,
            MESH_OT_merge_materials_to_mask,
            MESH_OT_fix_material_names,
            MESH_OT_group_objects_in_collections,
            MESH_OT_assign_textures,
            MESH_OT_fix_naming_conventions,
            MESH_OT_generate_empty_for_mesh,
            MESH_OT_prepare_lods_decimate,
            # MESH_OT_bake_basic_mlod,
            MESH_OT_set_up_mlod,
            EnumColorPalettes,
            MESH_OT_select_face_id,
            UVEnumProperties
 ]
 def register():
    for mod in modules:
        bpy.utils.register_class(mod)
    bpy.types.Scene.lod_slider = bpy.props.IntProperty(name="LOD Number", default=3, min=0, max=10)
    bpy.types.Scene.color_palettes = bpy.props.PointerProperty(type=EnumColorPalettes)
    bpy.types.Scene.face_id_field = bpy.props.IntProperty(name="Face ID", default=0, min=0)
    bpy.types.Scene.section1 = bpy.props.BoolProperty(name="Expand Section", default=False)
    bpy.types.Scene.section2 = bpy.props.BoolProperty(name="Expand Section", default=False)
    bpy.types.Scene.dekogon_file_path = bpy.props.StringProperty(name="Textures", description="Path to the texture folder, textures to be applied from", subtype="DIR_PATH", default="")
    bpy.types.Scene.dekogon_settings_prefix = bpy.props.StringProperty(name="Prefix", default="TX")
    bpy.types.Scene.dekogon_settings_suffix = bpy.props.StringProperty(name="Suffix", default="ALB")
    bpy.types.Scene.dekogon_settings_filetype = bpy.props.StringProperty(name="File Type", default="tga")
    bpy.types.Scene.settings_multi_ignor = bpy.props.StringProperty(name="Ignore", default="", description="Ignore material when string is in name (split by comma)")
    bpy.types.Scene.uv_enum_props = bpy.props.PointerProperty(type=UVEnumProperties)
    bpy.types.Scene.uv_island_margin_slider = bpy.props.FloatProperty(name="Island Margin", default=0.02, min=0.01, max=0.1)
 def unregister():
    for mod in modules:
        bpy.utils.unregister_class(mod)
    del bpy.types.Scene.lod_slider
    del bpy.types.Scene.color_palettes
    del bpy.types.Scene.face_id_field
    del bpy.types.Scene.section1
    del bpy.types.Scene.section2
    del bpy.types.Scene.dekogon_file_path
    del bpy.types.Scene.dekogon_settings_prefix
    del bpy.types.Scene.dekogon_settings_suffix
    del bpy.types.Scene.dekogon_settings_filetype
    del bpy.types.Scene.settings_multi_ignor
    del bpy.types.Scene.uv_enum_props
    del bpy.types.Scene.uv_island_margin_slider
 if __name__== "__main__":
    register()