render-blender-output
About
This skill automates Blender rendering by configuring settings, compositing nodes, and output formats via Python API or CLI. Use it to execute batch renders, manage quality/performance trade-offs, and generate multiple outputs from a single render. It's ideal for setting up compositing pipelines and producing final publication-ready assets.
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/render-blender-outputCopy and paste this command in Claude Code to install this skill
Documentation
Render Blender Output
Configure render engines (Cycles, EEVEE), set output params, build compositing node graphs, execute via Python API or CLI. Render settings opt, file format select, post-processing.
Use When
- Automate batch render
- Config render quality + perf trade-offs
- Set up compositing pipelines → post-process
- Generate multi output formats from single render
- Optimize render settings → diff hardware
- Create CLI rendering workflows
- Produce final output → publication/presentation
In
| Input | Type | Description | Example |
|---|---|---|---|
| Scene file | .blend file | Blender scene to render | scene.blend |
| Render engine | String | Cycles, EEVEE, or Workbench | CYCLES |
| Quality settings | Parameters | Samples, resolution, denoising | 128 samples, 1920x1080, OptiX denoiser |
| Output format | String | PNG, EXR, JPEG, TIFF | OPEN_EXR, 16-bit, ZIP compression |
| Compositing setup | Node graph | Post-processing effects | Color grading, glare, vignette |
| Output path | File path | Render destination | /renders/output_####.png |
Do
1. Configure Render Engine
Set engine + basic params:
import bpy
def setup_cycles_engine():
"""Configure Cycles render engine."""
scene = bpy.context.scene
scene.render.engine = 'CYCLES'
# Device settings
scene.cycles.device = 'GPU' # or 'CPU'
# Sampling
scene.cycles.samples = 128 # Viewport: fewer samples
scene.cycles.use_adaptive_sampling = True
scene.cycles.adaptive_threshold = 0.01
# Denoising
scene.cycles.use_denoising = True
scene.cycles.denoiser = 'OPTIX' # or 'OPENIMAGEDENOISE', 'NLM'
# Light paths
scene.cycles.max_bounces = 12
scene.cycles.diffuse_bounces = 4
scene.cycles.glossy_bounces = 4
scene.cycles.transmission_bounces = 12
scene.cycles.volume_bounces = 0
def setup_eevee_engine():
"""Configure EEVEE render engine."""
scene = bpy.context.scene
scene.render.engine = 'BLENDER_EEVEE'
# Sampling
scene.eevee.taa_render_samples = 64
# Effects
scene.eevee.use_bloom = True
scene.eevee.bloom_threshold = 0.8
scene.eevee.bloom_intensity = 0.1
scene.eevee.use_gtao = True # Ambient occlusion
scene.eevee.gtao_distance = 0.2
scene.eevee.use_ssr = True # Screen space reflections
scene.eevee.ssr_quality = 0.5
# Shadows
scene.eevee.shadow_cube_size = '1024'
scene.eevee.shadow_cascade_size = '1024'
→ Engine configured w/ appropriate quality settings If err: check engine name spelling, verify GPU available for GPU rendering
2. Resolution + Output Format
Configure output dimensions + format:
def configure_output(width=1920, height=1080, file_format='PNG', color_depth='16'):
"""Set output resolution and format."""
scene = bpy.context.scene
# Resolution
scene.render.resolution_x = width
scene.render.resolution_y = height
scene.render.resolution_percentage = 100
# Aspect ratio
scene.render.pixel_aspect_x = 1.0
scene.render.pixel_aspect_y = 1.0
# File format
scene.render.image_settings.file_format = file_format
if file_format == 'PNG':
scene.render.image_settings.color_mode = 'RGBA'
scene.render.image_settings.color_depth = color_depth # '8' or '16'
scene.render.image_settings.compression = 15 # 0-100
elif file_format == 'OPEN_EXR':
scene.render.image_settings.color_mode = 'RGBA'
scene.render.image_settings.color_depth = '32' # or '16'
scene.render.image_settings.exr_codec = 'ZIP' # or 'DWAA', 'PIZ'
elif file_format == 'JPEG':
scene.render.image_settings.color_mode = 'RGB'
scene.render.image_settings.quality = 90 # 0-100
elif file_format == 'TIFF':
scene.render.image_settings.color_mode = 'RGBA'
scene.render.image_settings.color_depth = color_depth
scene.render.image_settings.tiff_codec = 'DEFLATE'
# Frame range (for animations)
scene.frame_start = 1
scene.frame_end = 250
scene.frame_step = 1
→ Output format + resolution configured correctly If err: check format names valid, verify color depth compatible
3. Configure Compositing
Set up compositing node graph:
def setup_compositing():
"""Create compositing node setup."""
scene = bpy.context.scene
scene.use_nodes = True
tree = scene.node_tree
nodes = tree.nodes
links = tree.links
# Clear default nodes
nodes.clear()
# Render Layers input
render_layers = nodes.new(type='CompositorNodeRLayers')
render_layers.location = (-400, 300)
# Denoise (if not using Cycles denoiser)
# denoise = nodes.new(type='CompositorNodeDenoise')
# denoise.location = (-200, 300)
# Color correction
color_correct = nodes.new(type='CompositorNodeColorCorrection')
color_correct.location = (0, 300)
color_correct.master_saturation = 1.1
color_correct.master_gain = 1.05
# Glare effect
glare = nodes.new(type='CompositorNodeGlare')
glare.location = (200, 200)
glare.glare_type = 'FOG_GLOW'
glare.threshold = 0.9
glare.size = 8
# Vignette
lens_distortion = nodes.new(type='CompositorNodeLensdist')
lens_distortion.location = (200, 0)
lens_distortion.inputs['Dispersion'].default_value = 0.0
lens_distortion.inputs['Distortion'].default_value = -0.02
# Mix nodes
mix1 = nodes.new(type='CompositorNodeMixRGB')
mix1.location = (400, 250)
mix1.blend_type = 'ADD'
mix1.inputs['Fac'].default_value = 0.3
# Composite output
composite = nodes.new(type='CompositorNodeComposite')
composite.location = (600, 300)
# Viewer output (for preview)
viewer = nodes.new(type='CompositorNodeViewer')
viewer.location = (600, 100)
# Link nodes
links.new(render_layers.outputs['Image'], color_correct.inputs['Image'])
links.new(color_correct.outputs['Image'], mix1.inputs[1])
links.new(color_correct.outputs['Image'], glare.inputs['Image'])
links.new(glare.outputs['Image'], mix1.inputs[2])
links.new(mix1.outputs['Image'], composite.inputs['Image'])
links.new(mix1.outputs['Image'], viewer.inputs['Image'])
→ Compositing nodes configured w/ post-processing effects If err: check node type names, verify inputs exist, ensure link connections valid
4. Output File Paths
Configure output naming w/ frame numbers:
import os
from pathlib import Path
def set_output_path(base_dir, project_name, use_frame_number=True):
"""Configure output file path."""
scene = bpy.context.scene
# Create output directory
output_dir = Path(base_dir) / project_name / "renders"
output_dir.mkdir(parents=True, exist_ok=True)
# Set filepath
if use_frame_number:
# #### is replaced with frame number (0001, 0002, etc.)
filename = f"{project_name}_####"
else:
filename = project_name
scene.render.filepath = str(output_dir / filename)
# Optional: Set file extension explicitly
# Extension added automatically based on file_format
# But can override: scene.render.file_extension = '.png'
→ Output dir created, filepath configured w/ frame numbering If err: check dir perms, verify path syntax for OS
5. View Layers + Passes
Set up render passes for compositing:
def configure_view_layers():
"""Enable render passes."""
scene = bpy.context.scene
view_layer = scene.view_layers['ViewLayer']
# Enable passes
view_layer.use_pass_combined = True
view_layer.use_pass_z = True # Depth
view_layer.use_pass_mist = False
view_layer.use_pass_normal = True
view_layer.use_pass_vector = True # Motion vectors
view_layer.use_pass_ambient_occlusion = True
# Cycles-specific passes
cycles = view_layer.cycles
cycles.use_pass_diffuse_direct = True
cycles.use_pass_diffuse_indirect = True
cycles.use_pass_glossy_direct = True
cycles.use_pass_glossy_indirect = True
cycles.use_pass_emission = True
cycles.use_pass_environment = True
# Cryptomatte passes (for post-production)
cycles.use_pass_crypto_object = True
cycles.use_pass_crypto_material = True
cycles.use_pass_crypto_asset = True
→ Render passes enabled for advanced compositing If err: check passes available for engine, verify view layer name
6. Execute Render
Render via Python API or CLI:
def render_still():
"""Render current frame."""
bpy.ops.render.render(write_still=True)
def render_animation():
"""Render animation frame range."""
bpy.ops.render.render(animation=True)
def render_frame(frame_number):
"""Render specific frame."""
scene = bpy.context.scene
scene.frame_set(frame_number)
bpy.ops.render.render(write_still=True)
# Command-line rendering (run from terminal)
# Single frame:
# blender scene.blend --background --render-frame 1
# Animation:
# blender scene.blend --background --render-anim
# Specific frame range:
# blender scene.blend --background --frame-start 10 --frame-end 20 --render-anim
# Override output path:
# blender scene.blend --background --render-output /tmp/render_#### --render-anim
# Use Python script:
# blender scene.blend --background --python render_script.py
→ Render executes, output files written to specified location If err: check scene setup, verify camera exists, ensure output dir writable
7. Batch Render Multi Cameras
Render from multi camera angles:
def render_all_cameras(output_dir):
"""Render scene from all cameras."""
scene = bpy.context.scene
original_camera = scene.camera
cameras = [obj for obj in bpy.data.objects if obj.type == 'CAMERA']
for camera in cameras:
# Set active camera
scene.camera = camera
# Update output path
camera_name = camera.name.replace(' ', '_')
scene.render.filepath = os.path.join(output_dir, f"{camera_name}_####")
# Render
bpy.ops.render.render(write_still=True)
print(f"Rendered from camera: {camera.name}")
# Restore original camera
scene.camera = original_camera
→ Renders generated for each camera in scene If err: check cameras exist, verify each positioned correctly
8. Optimize Perf
Configure perf settings:
def optimize_performance():
"""Optimize render settings for speed."""
scene = bpy.context.scene
if scene.render.engine == 'CYCLES':
# Tile size (GPU: larger tiles, CPU: smaller tiles)
if scene.cycles.device == 'GPU':
scene.render.tile_x = 256
scene.render.tile_y = 256
else:
scene.render.tile_x = 32
scene.render.tile_y = 32
# Performance settings
scene.cycles.use_adaptive_sampling = True
scene.render.use_persistent_data = True # Keep scene in memory
# Reduce light path complexity for preview
scene.cycles.max_bounces = 4
scene.cycles.diffuse_bounces = 2
scene.cycles.glossy_bounces = 2
# Progressive refine (for viewport)
scene.cycles.use_progressive_refine = True
elif scene.render.engine == 'BLENDER_EEVEE':
# Simplify settings for preview
scene.render.use_simplify = True
scene.render.simplify_subdivision = 2
# Reduce sampling
scene.eevee.taa_render_samples = 32
→ Render settings optimized for target hardware If err: test w/ lower quality first, monitor mem usage
Check
- Engine configured (Cycles/EEVEE)
- Resolution + aspect ratio match req
- Output format appropriate
- Color depth + compression verified
- Compositing nodes connected properly
- Output dir exists + writable
- Filename has frame numbering if needed
- Passes enabled as required
- Camera positioned correctly
- Test render completes w/o errors
- Output files have correct format + quality
Traps
- Missing camera: Scene must have active camera set for rendering
- Output path not set: Always specify
scene.render.filepathbefore render - Insufficient samples: Low sample counts → noise in Cycles renders
- Wrong color space: Check color mgmt for correct display
- File format incompat: Not all formats support all color depths
- Mem overflow: Large resolutions or complex scenes exceed RAM
- GPU OOM: Reduce tile size or switch to CPU for large scenes
- Background mode output: Must use --render-output flag or set filepath
- Frame number formatting: Use #### for auto frame padding
- Compositing disabled: Enable
scene.use_nodesto use compositing
→
- create-3d-scene: Scene setup required before render
- script-blender-automation: Batch render automation patterns
- render-publication-graphic: Publication output requirements
GitHub Repository
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