script-blender-automation

pjt222

Aktualisiert 2 days ago

8 Ansichten

Metaapiautomationdesigndata

Über

Diese Fähigkeit ermöglicht es Entwicklern, Blender-Workflows mit Python und der bpy-API zu automatisieren. Sie ist für prozedurale Modellierung, Batch-Operationen, Add-on-Entwicklung und die Integration von Blender mit externen Daten oder Pipelines konzipiert. Nutzen Sie sie, um Geometrie aus Algorithmen zu generieren, repetitive Aufgaben zu automatisieren oder benutzerdefinierte Werkzeuge und Operatoren zu erstellen.

Schnellinstallation

Claude Code

Dokumentation

Script Blender Automation

Advanced Blender Python → procedural modeling, keyframe anim, batch ops, operator reg, add-on dev. Complex geom gen, automated workflows, external data integ.

Use When

Automate repetitive modeling|animation
Gen procedural geom from algos|data
Batch render w/ param variations
Build custom ops|add-ons for workflow
Integrate Blender w/ external pipelines|APIs
Script complex anims w/ math precision
Reusable team tools

In

Input	Type	Description	Example
Automation requirements	Specification	Task description, parameters, constraints	Render 100 variations, animate path from data
Data sources	Files/APIs	External data for procedural generation	CSV coordinates, JSON parameters, API responses
Algorithm definitions	Code/Math	Procedural generation logic	Fractal patterns, parametric curves, L-systems
Operator specifications	Requirements	Custom tool behavior and UI	Tool name, properties, modal interaction
Animation parameters	Keyframes/Data	Timing, easing, constraints	Frame ranges, interpolation curves

Do

1. Procedural Geom Gen

BMesh:

import bpy
import bmesh
import math

def create_parametric_surface(name, u_res=32, v_res=32):
    """Generate parametric surface using mathematical function."""
    mesh = bpy.data.meshes.new(name)
    obj = bpy.data.objects.new(name, mesh)
    bpy.context.collection.objects.link(obj)

    bm = bmesh.new()

    # Create vertices using parametric equations
    verts = []
    for i in range(u_res):
        for j in range(v_res):
            u = (i / (u_res - 1)) * 2 * math.pi
            v = (j / (v_res - 1)) * math.pi

            # Sphere parametric equations
            x = math.sin(v) * math.cos(u)
            y = math.sin(v) * math.sin(u)
            z = math.cos(v)

            vert = bm.verts.new((x, y, z))
            verts.append(vert)

    # Create faces
    bm.verts.ensure_lookup_table()
    for i in range(u_res - 1):
        for j in range(v_res - 1):
            v1 = verts[i * v_res + j]
            v2 = verts[(i + 1) * v_res + j]
            v3 = verts[(i + 1) * v_res + (j + 1)]
            v4 = verts[i * v_res + (j + 1)]
            bm.faces.new([v1, v2, v3, v4])

    # Write to mesh
    bm.to_mesh(mesh)
    bm.free()

    return obj

→ Complex geom from math fns.

If err: check BMesh API, vertex indexing, faces manifold.

2. Keyframe Anim Automation

def animate_rotation(obj, start_frame=1, end_frame=250, axis='Z', rotations=2):
    """Animate object rotation over time."""
    # Set initial keyframe
    obj.rotation_euler[2] = 0  # Z axis
    obj.keyframe_insert(data_path="rotation_euler", index=2, frame=start_frame)

    # Set end keyframe
    obj.rotation_euler[2] = rotations * 2 * math.pi
    obj.keyframe_insert(data_path="rotation_euler", index=2, frame=end_frame)

    # Set interpolation
    if obj.animation_data and obj.animation_data.action:
        for fcurve in obj.animation_data.action.fcurves:
            if 'rotation_euler' in fcurve.data_path:
                for keyframe in fcurve.keyframe_points:
                    keyframe.interpolation = 'LINEAR'

def animate_material_property(mat, property_path, values, frames):
    """Animate material node values."""
    if not mat.node_tree:
        return

    # Example: animate emission strength
    nodes = mat.node_tree.nodes
    emission = nodes.get('Emission')
    if emission:
        for frame, value in zip(frames, values):
            emission.inputs['Strength'].default_value = value
            emission.inputs['Strength'].keyframe_insert(
                data_path="default_value",
                frame=frame
            )

def create_driver(obj, property_path, expression):
    """Create driver for automated animation."""
    driver = obj.driver_add(property_path)
    driver.driver.type = 'SCRIPTED'
    driver.driver.expression = expression

    # Example: link rotation to frame number
    # expression = "frame / 10"

→ Keyframes inserted, anim plays back.

If err: check property paths, data_path syntax, objects keyable.

3. Batch Processing

import os
from pathlib import Path

def batch_import_and_render(input_dir, output_dir, file_pattern="*.obj"):
    """Import multiple files and render each."""
    input_path = Path(input_dir)
    output_path = Path(output_dir)
    output_path.mkdir(exist_ok=True)

    scene = bpy.context.scene

    for obj_file in input_path.glob(file_pattern):
        # Clear existing objects
        bpy.ops.object.select_all(action='SELECT')
        bpy.ops.object.delete()

        # Import model
        bpy.ops.import_scene.obj(filepath=str(obj_file))

        # Setup camera and lighting (reuse setup functions)
        setup_camera()
        setup_lighting()

        # Render
        output_file = output_path / f"{obj_file.stem}.png"
        scene.render.filepath = str(output_file)
        bpy.ops.render.render(write_still=True)

        print(f"Rendered: {output_file}")

def batch_material_variation(base_object, colors, output_prefix):
    """Render object with multiple material colors."""
    mat = base_object.data.materials[0]
    bsdf = mat.node_tree.nodes.get('Principled BSDF')

    if not bsdf:
        return

    for i, color in enumerate(colors):
        # Update material color
        bsdf.inputs['Base Color'].default_value = color + (1.0,)

        # Render
        bpy.context.scene.render.filepath = f"{output_prefix}_{i:03d}.png"
        bpy.ops.render.render(write_still=True)

→ Multi files processed, renders per variant.

If err: check paths exist, import operators, handle missing materials.

4. Custom Operator Dev

import bpy
from bpy.props import FloatProperty, IntProperty

class OBJECT_OT_generate_spiral(bpy.types.Operator):
    """Generate a spiral curve"""
    bl_idname = "object.generate_spiral"
    bl_label = "Generate Spiral"
    bl_options = {'REGISTER', 'UNDO'}

    # Operator properties
    radius: FloatProperty(
        name="Radius",
        description="Spiral radius",
        default=2.0,
        min=0.1,
        max=10.0
    )

    turns: IntProperty(
        name="Turns",
        description="Number of spiral turns",
        default=5,
        min=1,
        max=20
    )

    resolution: IntProperty(
        name="Resolution",
        description="Points per turn",
        default=32,
        min=8,
        max=128
    )

    def execute(self, context):
        # Create curve
        curve = bpy.data.curves.new('Spiral', 'CURVE')
        curve.dimensions = '3D'

        spline = curve.splines.new('NURBS')
        num_points = self.turns * self.resolution

        spline.points.add(num_points - 1)  # -1 because one point exists

        for i in range(num_points):
            t = i / self.resolution
            angle = t * 2 * math.pi

            x = self.radius * math.cos(angle)
            y = self.radius * math.sin(angle)
            z = t * 0.5

            spline.points[i].co = (x, y, z, 1.0)

        # Create object
        obj = bpy.data.objects.new('Spiral', curve)
        context.collection.objects.link(obj)
        obj.select_set(True)
        context.view_layer.objects.active = obj

        self.report({'INFO'}, f"Generated spiral with {num_points} points")
        return {'FINISHED'}

def register():
    bpy.utils.register_class(OBJECT_OT_generate_spiral)

def unregister():
    bpy.utils.unregister_class(OBJECT_OT_generate_spiral)

if __name__ == "__main__":
    register()

→ Operator in search, executes w/ undo.

If err: bl_idname format (lowercase + underscores), property types.

5. Modal Operator Interactive

class OBJECT_OT_modal_scale(bpy.types.Operator):
    """Interactive scaling with mouse"""
    bl_idname = "object.modal_scale"
    bl_label = "Modal Scale"
    bl_options = {'REGISTER', 'UNDO'}

    def __init__(self):
        self.initial_mouse_x = 0
        self.initial_scale = 1.0

    def modal(self, context, event):
        if event.type == 'MOUSEMOVE':
            # Calculate scale based on mouse movement
            delta = event.mouse_x - self.initial_mouse_x
            scale = self.initial_scale + (delta / 100.0)
            scale = max(0.1, scale)  # Minimum scale

            # Apply to active object
            context.active_object.scale = (scale, scale, scale)

        elif event.type == 'LEFTMOUSE':
            return {'FINISHED'}

        elif event.type in {'RIGHTMOUSE', 'ESC'}:
            # Cancel - restore initial scale
            context.active_object.scale = (
                self.initial_scale,
                self.initial_scale,
                self.initial_scale
            )
            return {'CANCELLED'}

        return {'RUNNING_MODAL'}

    def invoke(self, context, event):
        if context.active_object:
            self.initial_mouse_x = event.mouse_x
            self.initial_scale = context.active_object.scale[0]

            context.window_manager.modal_handler_add(self)
            return {'RUNNING_MODAL'}
        else:
            self.report({'WARNING'}, "No active object")
            return {'CANCELLED'}

→ Interactive, mouse-responsive, left-click confirms, ESC cancels.

If err: event types, modal handler added, handle no active obj.

6. Add-on Packaging

bl_info = {
    "name": "Custom Tools",
    "author": "Your Name",
    "version": (1, 0, 0),
    "blender": (3, 0, 0),
    "location": "View3D > Add > Mesh",
    "description": "Collection of custom modeling tools",
    "category": "Add Mesh",
}

import bpy

# Import operator classes
from .operators import OBJECT_OT_generate_spiral

classes = (
    OBJECT_OT_generate_spiral,
    # Add other classes
)

def menu_func(self, context):
    """Add to menu."""
    self.layout.operator(OBJECT_OT_generate_spiral.bl_idname)

def register():
    for cls in classes:
        bpy.utils.register_class(cls)

    bpy.types.VIEW3D_MT_mesh_add.append(menu_func)

def unregister():
    bpy.types.VIEW3D_MT_mesh_add.remove(menu_func)

    for cls in reversed(classes):
        bpy.utils.unregister_class(cls)

if __name__ == "__main__":
    register()

→ Add-on installs via Preferences, ops in menus.

If err: bl_info format, Blender ver req, all classes listed.

7. Data-Driven Procedural Gen

import csv
import json

def create_from_csv(filepath):
    """Generate objects from CSV data."""
    with open(filepath, 'r') as f:
        reader = csv.DictReader(f)

        for row in reader:
            # Parse data
            name = row['name']
            x, y, z = float(row['x']), float(row['y']), float(row['z'])
            scale = float(row.get('scale', 1.0))

            # Create object
            bpy.ops.mesh.primitive_uv_sphere_add(location=(x, y, z))
            obj = bpy.context.active_object
            obj.name = name
            obj.scale = (scale, scale, scale)

def create_from_json(filepath):
    """Generate scene from JSON configuration."""
    with open(filepath, 'r') as f:
        config = json.load(f)

    # Process objects
    for obj_config in config.get('objects', []):
        obj_type = obj_config['type']
        location = obj_config['location']

        if obj_type == 'cube':
            bpy.ops.mesh.primitive_cube_add(location=location)
        elif obj_type == 'sphere':
            bpy.ops.mesh.primitive_uv_sphere_add(location=location)

        obj = bpy.context.active_object
        obj.name = obj_config.get('name', 'Object')

        # Apply material if specified
        if 'material' in obj_config:
            mat_name = obj_config['material']
            mat = bpy.data.materials.get(mat_name)
            if mat:
                obj.data.materials.append(mat)

→ Objects created from external data files.

If err: validate format, missing fields, defaults.

Check

Traps

Circular imports in add-ons: Relative imports, structure modules carefully
Operator naming: bl_idname lowercase + single underscore (category.name)
Property types: Right bpy.props (FloatProperty, IntProperty, etc.)
Context access: Not all ops in all contexts (viewport vs render)
BMesh cleanup: Always bm.free() after bm.to_mesh() → no mem leaks
Anim keyframe timing: Frames start 1, not 0
Driver expr errs: Validate, safe namespace
Modal blocking: Don't block in modal(), use non-blocking
Add-on install paths: Place in Blender's scripts/addons
Ver compat: API changes between Blender vers, document reqs

→

create-3d-scene: Basic scene + obj creation
render-blender-output: Render workflows for automated output
create-r-package: Similar packaging for code distribution

GitHub Repository

pjt222/agent-almanac

Pfad: i18n/caveman-ultra/skills/script-blender-automation

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