render-blender-output

pjt222

Updated 2 days ago

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Metapowerpointapiautomation

About

This skill automates Blender rendering by configuring engines (Cycles/EEVEE), settings, and compositing nodes via Python or CLI. It's designed for batch processing, quality-performance tuning, and generating multiple output formats from a single render. Use it to build automated post-processing pipelines and produce final publication-ready assets.

Quick Install

Claude Code

Recommended

Primary

npx skills add pjt222/agent-almanac -a claude-code

Plugin CommandAlternative

/plugin add https://github.com/pjt222/agent-almanac

Git CloneAlternative

git clone https://github.com/pjt222/agent-almanac.git ~/.claude/skills/render-blender-output

Copy and paste this command in Claude Code to install this skill

Documentation

Render Blender Output

Configure render engines (Cycles, EEVEE), set output parameters, build compositing node graphs, execute renders via Python API or command-line interface. Covers render settings optimization, file format selection, post-processing workflows.

When Use

Automate render execution for batch processing
Configure render quality and performance trade-offs
Set up compositing pipelines for post-processing
Generate multiple output formats from single render
Optimize render settings for different hardware
Create command-line rendering workflows
Produce final output for publication or presentation

Inputs

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`

Steps

1. Configure Render Engine

Set render engine and basic parameters:

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'

Got: Render engine configured with appropriate quality settings If fail: Check engine name spelling, verify GPU availability for GPU rendering

2. Set Resolution and Output Format

Configure output dimensions and file 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

Got: Output format and resolution configured correctly If fail: Check format names valid, verify color depth compatible with format

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'])

Got: Compositing nodes configured with post-processing effects If fail: Check node type names, verify inputs exist, ensure link connections valid

4. Set Output File Paths

Configure output file naming with 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'

Got: Output directory created, filepath configured with frame numbering If fail: Check directory permissions, verify path syntax for OS

5. Configure View Layers and 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

Got: Render passes enabled for advanced compositing If fail: Check if passes available for current engine, verify view layer name

6. Execute Render

Render via Python API or command line:

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

Got: Render executes, output files written to specified location If fail: Check scene setup, verify camera exists, ensure output directory writable

7. Batch Render Multiple Cameras

Render from multiple 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

Got: Renders generated for each camera in scene If fail: Check cameras exist, verify each camera positioned correctly

8. Optimize Render Performance

Configure performance 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

Got: Render settings optimized for target hardware If fail: Test with lower quality first, monitor memory usage

Checks

Pitfalls

Missing camera: Scene must have active camera set for rendering
Output path not set: Always specify scene.render.filepath before rendering
Insufficient samples: Low sample counts cause noise in Cycles renders
Wrong color space: Check color management settings for correct display
File format incompatibility: Not all formats support all color depths
Memory overflow: Large resolutions or complex scenes may exceed RAM
GPU out of memory: Reduce tile size or switch to CPU for large scenes
Background mode output: In background mode, must use --render-output flag or set filepath
Frame number formatting: Use #### for automatic frame padding
Compositing disabled: Enable scene.use_nodes to use compositing

GitHub Repository

pjt222/agent-almanac

Path: i18n/caveman/skills/render-blender-output

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View skill

render-blender-output

About

Quick Install

Claude Code

Documentation

Render Blender Output

When Use

Inputs

Steps

1. Configure Render Engine

2. Set Resolution and Output Format

3. Configure Compositing

4. Set Output File Paths

5. Configure View Layers and Passes

6. Execute Render

7. Batch Render Multiple Cameras

8. Optimize Render Performance

Checks

Pitfalls

See Also

GitHub Repository

Related Skills

content-collections

polymarket

creating-opencode-plugins

sglang