create-2d-composition
Über
Diese Fähigkeit ermöglicht die programmatische Erzeugung von 2D-Grafiken wie Diagrammen und Charts durch SVG-Erstellung, Layout-Algorithmen und Bildkomposition. Sie ist ideal zur Automatisierung von visuellen Assets, zum Erstellen individueller Visualisierungen oder zur Stapelproduktion von Grafiken mit Parameter-Variationen. Entwickler können sie für reproduzierbare Abbildungen, Flussdiagramme und Infografiken nutzen, wenn Standard-Diagrammbibliotheken nicht ausreichen.
Schnellinstallation
Claude Code
Empfohlennpx 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/create-2d-compositionKopieren Sie diesen Befehl und fügen Sie ihn in Claude Code ein, um diese Fähigkeit zu installieren
Dokumentation
Create 2D Composition
Generate 2D graphics programmatically using SVG construction, diagram layout algorithms, image compositing, and batch processing workflows. Covers vector graphics generation, raster image manipulation, typography, and automated production of charts, diagrams, and infographics.
When to Use
- Generating diagrams, flowcharts, or infographics programmatically
- Creating reproducible scientific figures or publication graphics
- Automating production of badges, icons, or visual assets
- Compositing multiple images or data visualizations
- Building custom chart types not available in standard libraries
- Batch generating graphics with parameter variations
- Creating SVG templates for web or print applications
Inputs
| Input | Type | Description | Example |
|---|---|---|---|
| Layout specification | Configuration | Dimensions, margins, grid layout | Canvas 800x600px, 20px margins |
| Visual elements | Data/Assets | Shapes, text, images, data points | Rectangle coordinates, labels, icons |
| Style parameters | CSS/Attributes | Colors, fonts, stroke widths, opacity | fill="#3366cc", stroke-width="2" |
| Data sources | Files/Arrays | Values to visualize or annotate | CSV data, JSON configuration |
| Output format | String | SVG, PNG, PDF, composite formats | output.svg, 300 DPI PNG |
Procedure
1. Set Up Python Environment
Install required libraries for 2D composition:
# Core libraries
pip install svgwrite pillow cairosvg
# Optional: advanced features
pip install drawsvg reportlab pycairo
# For data-driven graphics
pip install matplotlib numpy pandas
Got: Libraries installed successfully If fail: Check Python version (3.7+), use virtual environment to avoid conflicts
2. Create Basic SVG Graphics
Generate SVG using svgwrite:
import svgwrite
from svgwrite import cm, mm
def create_basic_svg(output_path):
"""Create a simple SVG graphic."""
# Initialize drawing (use mm for precise dimensions)
dwg = svgwrite.Drawing(output_path, size=('180mm', '120mm'), profile='full')
# Add background rectangle
dwg.add(dwg.rect(
insert=(0, 0),
size=('100%', '100%'),
fill='white'
))
# Add shapes
dwg.add(dwg.circle(
center=(90*mm, 60*mm),
r=30*mm,
fill='lightblue',
stroke='navy',
stroke_width=2
))
dwg.add(dwg.rect(
insert=(30*mm, 30*mm),
size=(60*mm, 40*mm),
fill='lightgreen',
stroke='darkgreen',
stroke_width=2,
rx=5, # Rounded corners
ry=5
))
# Add text
dwg.add(dwg.text(
'Example Graphic',
insert=(90*mm, 20*mm),
text_anchor='middle',
font_size='18pt',
font_family='Arial',
fill='black'
))
dwg.save()
print(f"Saved: {output_path}")
Got: SVG file generated with shapes and text If fail: Check svgwrite version, verify output directory writable
3. Build Diagrams with Layout Logic
Create structured diagrams with calculated positioning:
def create_flowchart(steps, output_path):
"""Generate a flowchart from list of steps."""
dwg = svgwrite.Drawing(output_path, size=('800px', '600px'))
# Layout parameters
box_width = 120
box_height = 60
spacing_y = 100
start_x = 340
start_y = 50
for i, step in enumerate(steps):
y_pos = start_y + i * spacing_y
# Draw box
box = dwg.add(dwg.g(id=f'step_{i}'))
box.add(dwg.rect(
insert=(start_x, y_pos),
size=(box_width, box_height),
fill='lightblue',
stroke='navy',
stroke_width=2,
rx=5,
ry=5
))
# Add text (wrapped if needed)
text_lines = wrap_text(step, max_width=16)
text_y = y_pos + box_height/2 - (len(text_lines)-1) * 7
for j, line in enumerate(text_lines):
box.add(dwg.text(
line,
insert=(start_x + box_width/2, text_y + j*14),
text_anchor='middle',
font_size='12pt',
font_family='Arial',
fill='black'
))
# Draw arrow to next step
if i < len(steps) - 1:
arrow_start_y = y_pos + box_height
arrow_end_y = y_pos + spacing_y
dwg.add(dwg.line(
start=(start_x + box_width/2, arrow_start_y),
end=(start_x + box_width/2, arrow_end_y),
stroke='black',
stroke_width=2,
marker_end=dwg.marker(
id='arrow',
viewBox='0 0 10 10',
refX=5,
refY=5,
markerWidth=6,
markerHeight=6,
orient='auto'
)
))
dwg.save()
def wrap_text(text, max_width=20):
"""Simple text wrapping."""
words = text.split()
lines = []
current_line = []
for word in words:
test_line = ' '.join(current_line + [word])
if len(test_line) <= max_width:
current_line.append(word)
else:
if current_line:
lines.append(' '.join(current_line))
current_line = [word]
if current_line:
lines.append(' '.join(current_line))
return lines
Got: Flowchart with connected boxes and arrows If fail: Adjust layout calculations, verify arrow marker definitions
4. Composite Raster Images
Combine multiple images using Pillow:
from PIL import Image, ImageDraw, ImageFont, ImageFilter
import os
def composite_images(image_paths, output_path, layout='grid'):
"""Composite multiple images into single output."""
# Load images
images = [Image.open(path) for path in image_paths]
if layout == 'grid':
# Calculate grid dimensions
n = len(images)
cols = int(n ** 0.5)
rows = (n + cols - 1) // cols
# Get max dimensions
max_width = max(img.width for img in images)
max_height = max(img.height for img in images)
# Create composite canvas
canvas_width = cols * max_width
canvas_height = rows * max_height
composite = Image.new('RGB', (canvas_width, canvas_height), 'white')
# Paste images
for i, img in enumerate(images):
row = i // cols
col = i % cols
x = col * max_width
y = row * max_height
composite.paste(img, (x, y))
elif layout == 'horizontal':
# Horizontal concatenation
total_width = sum(img.width for img in images)
max_height = max(img.height for img in images)
composite = Image.new('RGB', (total_width, max_height), 'white')
x_offset = 0
for img in images:
composite.paste(img, (x_offset, 0))
x_offset += img.width
elif layout == 'vertical':
# Vertical concatenation
max_width = max(img.width for img in images)
total_height = sum(img.height for img in images)
composite = Image.new('RGB', (max_width, total_height), 'white')
y_offset = 0
for img in images:
composite.paste(img, (0, y_offset))
y_offset += img.height
composite.save(output_path)
print(f"Saved composite: {output_path}")
def add_annotations(image_path, annotations, output_path):
"""Add text annotations to image."""
img = Image.open(image_path)
draw = ImageDraw.Draw(img)
# Load font
try:
font = ImageFont.truetype("Arial.ttf", 24)
except:
font = ImageFont.load_default()
for annotation in annotations:
text = annotation['text']
position = annotation['position']
color = annotation.get('color', 'black')
# Add text shadow for readability
shadow_offset = 2
draw.text(
(position[0] + shadow_offset, position[1] + shadow_offset),
text,
font=font,
fill='white'
)
draw.text(position, text, font=font, fill=color)
img.save(output_path)
Got: Composite image created with proper layout If fail: Check all input images exist, verify image modes compatible
5. Generate Data-Driven Graphics
Create visualizations from data:
import numpy as np
def create_bar_chart_svg(data, labels, output_path):
"""Generate SVG bar chart from data."""
dwg = svgwrite.Drawing(output_path, size=('600px', '400px'))
# Chart area
margin = 50
chart_width = 500
chart_height = 300
bar_spacing = 10
# Calculate bar dimensions
n_bars = len(data)
bar_width = (chart_width - (n_bars - 1) * bar_spacing) / n_bars
# Scale data to fit chart
max_value = max(data)
scale = chart_height / max_value
# Draw axes
dwg.add(dwg.line(
start=(margin, margin),
end=(margin, margin + chart_height),
stroke='black',
stroke_width=2
))
dwg.add(dwg.line(
start=(margin, margin + chart_height),
end=(margin + chart_width, margin + chart_height),
stroke='black',
stroke_width=2
))
# Draw bars
for i, (value, label) in enumerate(zip(data, labels)):
x = margin + i * (bar_width + bar_spacing)
bar_height = value * scale
y = margin + chart_height - bar_height
# Bar
dwg.add(dwg.rect(
insert=(x, y),
size=(bar_width, bar_height),
fill='steelblue',
stroke='navy',
stroke_width=1
))
# Value label
dwg.add(dwg.text(
f'{value:.1f}',
insert=(x + bar_width/2, y - 5),
text_anchor='middle',
font_size='10pt',
fill='black'
))
# X-axis label
dwg.add(dwg.text(
label,
insert=(x + bar_width/2, margin + chart_height + 20),
text_anchor='middle',
font_size='10pt',
fill='black'
))
dwg.save()
Got: SVG bar chart with scaled data If fail: Handle edge cases (empty data, negative values), add validation
6. Batch Generate Graphics
Automate creation of multiple graphics:
def batch_generate_badges(users, template_path, output_dir):
"""Generate badge for each user."""
os.makedirs(output_dir, exist_ok=True)
for user in users:
output_path = os.path.join(output_dir, f"{user['id']}_badge.svg")
dwg = svgwrite.Drawing(output_path, size=('300px', '100px'))
# Background
dwg.add(dwg.rect(
insert=(0, 0),
size=('100%', '100%'),
fill='#3366cc',
rx=10,
ry=10
))
# User name
dwg.add(dwg.text(
user['name'],
insert=(150, 40),
text_anchor='middle',
font_size='20pt',
font_weight='bold',
fill='white'
))
# User role
dwg.add(dwg.text(
user['role'],
insert=(150, 70),
text_anchor='middle',
font_size='14pt',
fill='lightblue'
))
dwg.save()
print(f"Generated badge: {output_path}")
Got: Individual graphic generated for each data item If fail: Check data structure, handle missing fields with defaults
7. Convert SVG to Raster
Export SVG to PNG/PDF for various uses:
import cairosvg
def svg_to_png(svg_path, png_path, dpi=300):
"""Convert SVG to PNG with specified DPI."""
# Calculate pixel dimensions from DPI
# Assuming A4 size as example
width_inches = 8.27
height_inches = 11.69
width_px = int(width_inches * dpi)
height_px = int(height_inches * dpi)
cairosvg.svg2png(
url=svg_path,
write_to=png_path,
output_width=width_px,
output_height=height_px
)
print(f"Converted to PNG: {png_path}")
def svg_to_pdf(svg_path, pdf_path):
"""Convert SVG to PDF."""
cairosvg.svg2pdf(url=svg_path, write_to=pdf_path)
print(f"Converted to PDF: {pdf_path}")
Got: Raster output generated at specified resolution If fail: Install cairo system library if missing, check SVG validity
Validation Checklist
- Graphics render correctly in target applications
- Text is readable and properly positioned
- Colors match specifications (check hex codes)
- Dimensions appropriate for use case
- SVG validates against standard (if required)
- Raster exports have correct DPI
- Layout adapts to data variations
- Batch processing completes without errors
- Output files organized logically
- Code includes error handling
Pitfalls
- Unit confusion: SVG units (px, mm, cm) vs screen pixels vs print DPI
- Text overflow: Text exceeding shape boundaries, implement wrapping
- Font availability: System fonts may differ, embed or use web-safe fonts
- Coordinate calculations: Off-by-one errors in grid layouts; color format — SVG uses hex strings (
#rrggbb), not tuples - SVG validity: Check XML structure, close all tags; handle special characters and spaces in file paths
- Memory usage: Large batch operations may require chunking; maintain aspect ratio when resizing
- Transparency: PNG supports alpha, JPEG does not
Related Skills
- render-publication-graphic: Publication-specific output requirements
- create-3d-scene: Similar programmatic approach for 3D
- generate-quarto-report: Integrating graphics into reports
GitHub Repository
Verwandte Skills
content-collections
MetaDiese Skill bietet eine produktionsgetestete Einrichtung für Content Collections – ein TypeScript-first-Tool, das Markdown/MDX-Dateien in typsichere Datensammlungen mit Zod-Validierung umwandelt. Verwenden Sie ihn beim Erstellen von Blogs, Dokumentationsseiten oder inhaltsstarken Vite + React-Anwendungen, um Typsicherheit und automatische Inhaltsvalidierung zu gewährleisten. Er behandelt alles von der Vite-Plugin-Konfiguration und MDX-Kompilierung bis hin zur Deployment-Optimierung und Schema-Validierung.
polymarket
MetaDiese Fähigkeit ermöglicht es Entwicklern, Anwendungen mit der Polymarket-Prognosemärkte-Plattform zu erstellen, einschließlich API-Integration für Handel und Marktdaten. Sie bietet außerdem Echtzeit-Datenstreaming über WebSocket, um Live-Trades und Marktaktivitäten zu überwachen. Nutzen Sie sie zur Implementierung von Handelsstrategien oder zur Erstellung von Tools, die Live-Marktaktualisierungen verarbeiten.
creating-opencode-plugins
MetaDiese Fähigkeit unterstützt Entwickler dabei, OpenCode-Plugins zu erstellen, die in über 25 Ereignistypen wie Befehle, Dateien und LSP-Operationen eingreifen. Sie bietet die Plugin-Struktur, Event-API-Spezifikationen und Implementierungsmuster für JavaScript/TypeScript-Module. Nutzen Sie sie, wenn Sie den Lebenszyklus des OpenCode KI-Assistenten mit benutzerdefinierter ereignisgesteuerter Logik abfangen, überwachen oder erweitern müssen.
sglang
MetaSGLang ist ein hochperformantes LLM-Serving-Framework, das sich auf schnelle, strukturierte Generierung für JSON, Regex und agentenbasierte Workflows unter Verwendung seines RadixAttention-Prefix-Cachings spezialisiert. Es bietet deutlich schnellere Inferenz, insbesondere für Aufgaben mit wiederholten Präfixen, was es ideal für komplexe, strukturierte Ausgaben und Mehrfachdialoge macht. Wählen Sie SGLang gegenüber Alternativen wie vLLM, wenn Sie constrained decoding benötigen oder Anwendungen mit umfangreicher Präfix-Weitergabe entwickeln.