Comprehensive toolkit for creating, analyzing, and visualizing complex networks and graphs in Python.
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Before installing skills in Cursor, ensure your development environment meets these requirements:
node --versionnetworkxExecute the skills CLI command in your project's root directory to begin installation:
Fetches networkx from networkx/networkx and configures it for Cursor.
The CLI shows a list of agents. Use arrow keys and space to select Cursor:
Confirm successful installation by checking the skill directory location:
Restart Cursor to activate networkx. Access via /networkx in your agent's command palette.
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Quickly understand datasets, identify patterns, and generate insights
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Analyze CSV with 100K rows, identify outliers, visualize correlations, suggest hypotheses
Reduce EDA time from hours to minutes, uncover insights faster
Write scripts to clean messy data, handle missing values, normalize formats
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Generate Python/SQL to fix date formats, impute missing values, remove duplicates
Automate 80% of data preprocessing work
Perform hypothesis testing, regression, and statistical modeling
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Run A/B test analysis, calculate confidence intervals, interpret p-values
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| name | networkx |
| description | Comprehensive toolkit for creating, analyzing, and visualizing complex networks and graphs in Python. Use when working with network/graph data structures, analyzing relationships between entities, computing graph algorithms (shortest paths, centrality, clustering), detecting communities, generating synthetic networks, or visualizing network topologies. Applicable to social networks, biological networks, transportation systems, citation networks, and any domain involving pairwise relationships. |
| license | 3-clause BSD license |
| metadata | skill-author: K-Dense Inc. |
NetworkX is a Python package for creating, manipulating, and analyzing complex networks and graphs. Use this skill when working with network or graph data structures, including social networks, biological networks, transportation systems, citation networks, knowledge graphs, or any system involving relationships between entities.
Invoke this skill when tasks involve:
NetworkX supports four main graph types:
Create graphs by:
import networkx as nx
# Create empty graph
G = nx.Graph()
# Add nodes (can be any hashable type)
G.add_node(1)
G.add_nodes_from([2, 3, 4])
G.add_node("protein_A", type='enzyme', weight=1.5)
# Add edges
G.add_edge(1, 2)
G.add_edges_from([(1, 3), (2, 4)])
G.add_edge(1, 4, weight=0.8, relation='interacts')
Reference: See references/graph-basics.md for comprehensive guidance on creating, modifying, examining, and managing graph structures, including working with attributes and subgraphs.
NetworkX provides extensive algorithms for network analysis:
Shortest Paths:
# Find shortest path
path = nx.shortest_path(G, source=1, target=5)
length = nx.shortest_path_length(G, source=1, target=5, weight='weight')
Centrality Measures:
# Degree centrality
degree_cent = nx.degree_centrality(G)
# Betweenness centrality
betweenness = nx.betweenness_centrality(G)
# PageRank
pagerank = nx.pagerank(G)
Community Detection:
from networkx.algorithms import community
# Detect communities
communities = community.greedy_modularity_communities(G)
Connectivity:
# Check connectivity
is_connected = nx.is_connected(G)
# Find connected components
components = list(nx.connected_components(G))
Reference: See references/algorithms.md for detailed documentation on all available algorithms including shortest paths, centrality measures, clustering, community detection, flows, matching, tree algorithms, and graph traversal.
Create synthetic networks for testing, simulation, or modeling:
Classic Graphs:
# Complete graph
G = nx.complete_graph(n=10)
# Cycle graph
G = nx.cycle_graph(n=20)
# Known graphs
G = nx.karate_club_graph()
G = nx.petersen_graph()
Random Networks:
# Erdős-Rényi random graph
G = nx.erdos_renyi_graph(n=100, p=0.1, seed=42)
# Barabási-Albert scale-free network
G = nx.barabasi_albert_graph(n=100, m=3, seed=42)
# Watts-Strogatz small-world network
G = nx.watts_strogatz_graph(n=100, k=6, p=0.1, seed=42)
Structured Networks:
# Grid graph
G = nx.grid_2d_graph(m=5, n=7)
# Random tree
G = nx.random_tree(n=100, seed=42)
Reference: See references/generators.md for comprehensive coverage of all graph generators including classic, random, lattice, bipartite, and specialized network models with detailed parameters and use cases.
NetworkX supports numerous file formats and data sources:
File Formats:
# Edge list
G = nx.read_edgelist('graph.edgelist')
nx.write_edgelist(G, 'graph.edgelist')
# GraphML (preserves attributes)
G = nx.read_graphml('graph.graphml')
nx.write_graphml(G, 'graph.graphml')
# GML
G = nx.read_gml('graph.gml')
nx.write_gml(G, 'graph.gml')
# JSON
data = nx.node_link_data(G)
G = nx.node_link_graph(data)
Pandas Integration:
import pandas as pd
# From DataFrame
df = pd.DataFrame({'source': [1, 2, 3], 'target': [2, 3, 4], 'weight': [0.5, 1.0, 0.75]})
G = nx.from_pandas_edgelist(df, 'source', 'target', edge_attr='weight')
# To DataFrame
df = nx.to_pandas_edgelist(G)
Matrix Formats:
import numpy as np
# Adjacency matrix
A = nx.to_numpy_array(G)
G = nx.from_numpy_array(A)
# Sparse matrix
A = nx.to_scipy_sparse_array(G)
G = nx.from_scipy_sparse_array(A)
Reference: See references/io.md for complete documentation on all I/O formats including CSV, SQL databases, Cytoscape, DOT, and guidance on format selection for different use cases.
Create clear and informative network visualizations:
Basic Visualization:
import matplotlib.pyplot as plt
# Simple draw
nx.draw(G, with_labels=True)
plt.show()
# With layout
pos = nx.spring_layout(G, seed=42)
nx.draw(G, pos=pos, with_labels=True, node_color='lightblue', node_size=500)
plt.show()
Customization:
# Color by degree
node_colors = [G.degree(n) for n in G.nodes()]
nx.draw(G, node_color=node_colors, cmap=plt.cm.viridis)
# Size by centrality
centrality = nx.betweenness_centrality(G)
node_sizes = [3000 * centrality[n] for n in G.nodes()]
nx.draw(G, node_size=node_sizes)
# Edge weights
edge_widths = [3 * G[u][v].get('weight', 1) for u, v in G.edges()]
nx.draw(G, width=edge_widths)
Layout Algorithms:
# Spring layout (force-directed)
pos = nx.spring_layout(G, seed=42)
# Circular layout
pos = nx.circular_layout(G)
# Kamada-Kawai layout
pos = nx.kamada_kawai_layout(G)
# Spectral layout
pos = nx.spectral_layout(G)
Publication Quality:
plt.figure(figsize=(12, 8))
pos = nx.spring_layout(G, seed=42)
nx.draw(G, pos=pos, node_color='lightblue', node_size=500,
edge_color='gray', with_labels=True, font_size=10)
plt.title('Network Visualization', fontsize=16)
plt.axis('off')
plt.tight_layout()
plt.savefig('network.png', dpi=300, bbox_inches='tight')
plt.savefig('network.pdf', bbox_inches='tight') # Vector format
Reference: See references/visualization.md for extensive documentation on visualization techniques including layout algorithms, customization options, interactive visualizations with Plotly and PyVis, 3D networks, and publication-quality figure creation.
Ensure NetworkX is installed:
# Check if installed
import networkx as nx
print(nx.__version__)
# Install if needed (via bash)
# uv pip install networkx
# uv pip install networkx[default] # With optional dependencies
Most NetworkX tasks follow this pattern:
Create or Load Graph:
# From scratch
G = nx.Graph()
G.add_edges_from([(1, 2), (2, 3), (3, 4)])
# Or load from file/data
G = nx.read_edgelist('data.txt')
Examine Structure:
print(f"Nodes: {G.number_of_nodes()}")
print(f"Edges: {G.number_of_edges()}")
print(f"Density: {nx.density(G)}")
print(f"Connected: {nx.is_connected(G)}")
Analyze:
# Compute metrics
degree_cent = nx.degree_centrality(G)
avg_clustering = nx.average_clustering(G)
# Find paths
path = nx.shortest_path(G, source=1, target=4)
# Detect communities
communities = community.greedy_modularity_communities(G)
Visualize:
pos = nx.spring_layout(G, seed=42)
nx.draw(G, pos=pos, with_labels=True)
plt.show()
Export Results:
# Save graph
nx.write_graphml(G, 'analyzed_network.graphml')
# Save metrics
df = pd.DataFrame({
'node': list(degree_cent.keys()),
'centrality': list(degree_cent.values())
})
df.to_csv('centrality_results.csv', index=False)
Floating Point Precision: When graphs contain floating-point numbers, all results are inherently approximate due to precision limitations. This can affect algorithm outcomes, particularly in minimum/maximum computations.
Memory and Performance: Each time a script runs, graph data must be loaded into memory. For large networks:
k parameter in centrality calculations)Node and Edge Types:
Random Seeds: Always set random seeds for reproducibility in random graph generation and force-directed layouts:
G = nx.erdos_renyi_graph(n=100, p=0.1, seed=42)
pos = nx.spring_layout(G, seed=42)
# Create
G = nx.Graph()
G.add_edge(1, 2)
# Query
G.number_of_nodes()
G.number_of_edges()
G.degree(1)
list(G.neighbors(1))
# Check
G.has_node(1)
G.has_edge(1, 2)
nx.is_connected(G)
# Modify
G.remove_node(1)
G.remove_edge(1, 2)
G.clear()
# Paths
nx.shortest_path(G, source, target)
nx.all_pairs_shortest_path(G)
# Centrality
nx.degree_centrality(G)
nx.betweenness_centrality(G)
nx.closeness_centrality(G)
nx.pagerank(G)
# Clustering
nx.clustering(G)
nx.average_clustering(G)
# Components
nx.connected_components(G)
nx.strongly_connected_components(G) # Directed
# Community
community.greedy_modularity_communities(G)
# Read
nx.read_edgelist('file.txt')
nx.read_graphml('file.graphml')
nx.read_gml('file.gml')
# Write
nx.write_edgelist(G, 'file.txt')
nx.write_graphml(G, 'file.graphml')
nx.write_gml(G, 'file.gml')
# Pandas
nx.from_pandas_edgelist(df, 'source', 'target')
nx.to_pandas_edgelist(G)
This skill includes comprehensive reference documentation:
Detailed guide on graph types, creating and modifying graphs, adding nodes and edges, managing attributes, examining structure, and working with subgraphs.
Complete coverage of NetworkX algorithms including shortest paths, centrality measures, connectivity, clustering, community detection, flow algorithms, tree algorithms, matching, coloring, isomorphism, and graph traversal.
Comprehensive documentation on graph generators including classic graphs, random models (Erdős-Rényi, Barabási-Albert, Watts-Strogatz), lattices, trees, social network models, and specialized generators.
Complete guide to reading and writing graphs in various formats: edge lists, adjacency lists, GraphML, GML, JSON, CSV, Pandas DataFrames, NumPy arrays, SciPy sparse matrices, database integration, and format selection guidelines.
Extensive documentation on visualization techniques including layout algorithms, customizing node and edge appearance, labels, interactive visualizations with Plotly and PyVis, 3D networks, bipartite layouts, and creating publication-quality figures.
Get statistically sound analysis without PhD in statistics
Create charts, dashboards, and visual reports
Example
Generate matplotlib/seaborn code for time series plots, distribution charts, heatmaps
Build presentation-ready visualizations 3x faster
Prerequisites
Time Estimate
20-40 minutes to set up and run first analysis
Steps
Common Pitfalls
✓ Do
✗ Don't
💡 Pro Tips
✓ Use when
Use for exploratory data analysis, data cleaning, statistical testing, visualization prototyping, and learning new analysis techniques. Best for initial exploration and rapid insights.
✗ Avoid when
Avoid for mission-critical financial analysis, medical research requiring regulatory compliance, production ML models, or when deep statistical expertise is required for nuanced interpretation.
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Useful defaults in networkx — fewer surprises than typical one-off scripts, and it plays nicely with `npx skills` flows.
Useful defaults in networkx — fewer surprises than typical one-off scripts, and it plays nicely with `npx skills` flows.
networkx is among the better-maintained entries we tried; worth keeping pinned for repeat workflows.
networkx reduced setup friction for our internal harness; good balance of opinion and flexibility.
networkx has been reliable in day-to-day use. Documentation quality is above average for community skills.
Registry listing for networkx matched our evaluation — installs cleanly and behaves as described in the markdown.
Solid pick for teams standardizing on skills: networkx is focused, and the summary matches what you get after install.
We added networkx from the explainx registry; install was straightforward and the SKILL.md answered most questions upfront.
Useful defaults in networkx — fewer surprises than typical one-off scripts, and it plays nicely with `npx skills` flows.
I recommend networkx for anyone iterating fast on agent tooling; clear intent and a small, reviewable surface area.
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