script-blender-automation
About
This skill generates Python scripts for Blender automation using the bpy API. It handles procedural modeling, animation, batch operations, and add-on development for tasks like automating repetitive work or creating rendering pipelines. Use it to integrate Blender with external data or build custom tools and operators.
Quick Install
Claude Code
Recommendednpx skills add pjt222/agent-almanac -a claude-code/plugin add https://github.com/pjt222/agent-almanacgit clone https://github.com/pjt222/agent-almanac.git ~/.claude/skills/script-blender-automationCopy and paste this command in Claude Code to install this skill
Documentation
寫 Blender 自動之本
於 Blender 寫 Python 之本:程序之模、關鍵幀之動畫、批處理、操作子之註、附加之發。涵繁形之生、自動之流、與外數源之集。
用時
- 自動重複之建模或動畫之務乃用
- 自算或數生程序之形乃用
- 立批渲染之管線附參之變乃用
- 建自定操作子或附加以增工作流乃用
- Blender 與外數管或 API 之集乃用
- 以數學精度寫繁動畫乃用
- 建可重用之器以共團之流乃用
入
| 入 | 類 | 述 | 例 |
|---|---|---|---|
| 自動之求 | 規 | 務述、參、限 | 渲百變、自數動路 |
| 數源 | 文件/API | 外數以為程序生 | CSV 坐標、JSON 參、API 應 |
| 算之定 | 碼/數 | 程序生之邏 | 分形、參曲線、L-系統 |
| 操作子之規 | 求 | 自定器之行與 UI | 器名、屬、模式之交互 |
| 動畫之參 | 關鍵幀/數 | 時、緩、限 | 幀範、插曲線 |
法
一、程序之形之生
以 BMesh 程序立網形:
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
得:自數函生繁形 敗則:察 BMesh API 之呼,驗頂索之引,確面為流形
二、關鍵幀動畫之自動
寫關鍵幀與驅動:
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"
得:關鍵幀已插,動畫播放正 敗則:察屬之徑,驗 data_path 之語法,確物可下關鍵幀
三、批處理之操
批處諸物或諸文件:
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)
得:諸文件皆處,每變皆生渲 敗則:察文徑存,驗導入之操作子,處缺材之事
四、自定操作子之發
立可重用之自定操作子:
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()
得:操作子現於搜,行而支撤 敗則:察 bl_idname 之式(小寫加底線),驗屬之類
五、模式之操作子為交互之器
立交互模式之操作子:
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'}
得:交互之操作子應鼠,左擊確,ESC 取消 敗則:察事件之類,確模式之手已加,處無活物之例
六、附加之裝包
碼結構為可裝之附加:
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()
得:附加由偏好設置裝,操作子現於菜 敗則:察 bl_info 之式,驗 Blender 之版求,確諸類皆列
七、依數而生形
自外數生形:
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)
得:物依外數文件生 敗則:驗文件之式,處缺域,供默值
驗
- 本於 Blender Python 之境行而無誤
- 程序之形如預期生
- 動畫關鍵幀於正幀插
- 批操處諸文件成
- 自定操作子現於搜而行正
- 模式之操作子應鼠/鍵之事件
- 附加裝/卸皆潔
- 外數文件解析正
- 誤處覆邊例
- 碼遵 PEP 8 之風
陷
- 附加之循環引:用相對引,慎結構模
- 操作子之名:bl_idname 必為小寫加單底線(category.name)
- 屬之類:用正之 bpy.props 類(FloatProperty、IntProperty 等)
- 境之訪:非諸操作子皆於諸境可行(視口 vs 渲)
- BMesh 之清:於
bm.to_mesh()後常呼bm.free()以防漏 - 動畫關鍵幀之時:幀始於 1,非 0
- 驅動表達之誤:驗表達,用安全命名空
- 模式操作子之阻:勿於 modal() 阻,用非阻之操
- 附加裝之徑:置於 Blender 之 scripts/addons 目
- 版兼容:API 於諸 Blender 版間變,書其求
參
- create-3d-scene:基景之設與物之立
- render-blender-output:自動出之渲流
- create-r-package:相似之碼散裝包模
GitHub Repository
Related Skills
content-collections
MetaThis skill provides a production-tested setup for Content Collections, a TypeScript-first tool that transforms Markdown/MDX files into type-safe data collections with Zod validation. Use it when building blogs, documentation sites, or content-heavy Vite + React applications to ensure type safety and automatic content validation. It covers everything from Vite plugin configuration and MDX compilation to deployment optimization and schema validation.
polymarket
MetaThis skill enables developers to build applications with the Polymarket prediction markets platform, including API integration for trading and market data. It also provides real-time data streaming via WebSocket to monitor live trades and market activity. Use it for implementing trading strategies or creating tools that process live market updates.
creating-opencode-plugins
MetaThis skill helps developers create OpenCode plugins that hook into 25+ event types like commands, files, and LSP operations. It provides the plugin structure, event API specifications, and implementation patterns for JavaScript/TypeScript modules. Use it when you need to intercept, monitor, or extend the OpenCode AI assistant's lifecycle with custom event-driven logic.
sglang
MetaSGLang is a high-performance LLM serving framework that specializes in fast, structured generation for JSON, regex, and agentic workflows using its RadixAttention prefix caching. It delivers significantly faster inference, especially for tasks with repeated prefixes, making it ideal for complex, structured outputs and multi-turn conversations. Choose SGLang over alternatives like vLLM when you need constrained decoding or are building applications with extensive prefix sharing.