shap
FreeNo executable scriptsNot checkedModel interpretability and explainability using SHAP (SHapley Additive exPlanations). Use this skill when explaining machine learning model predictions, computi
About this skill
SHAP (SHapley Additive exPlanations)
Overview
SHAP is a unified approach to explain machine learning model outputs using Shapley values from cooperative game theory. This skill provides comprehensive guidance for:
- Computing SHAP values for any model type
- Creating visualizations to understand feature importance
- Debugging and validating model behavior
- Analyzing fairness and bias
- Implementing explainable AI in production
SHAP works with all model types: tree-based models (XGBoost, LightGBM, CatBoost, Random Forest), deep learning models (TensorFlow, PyTorch, Keras), linear models, and black-box models.
When to Use This Skill
Trigger this skill when users ask about:
- "Explain which features are most important in my model"
- "Generate SHAP plots" (waterfall, beeswarm, bar, scatter, force, heatmap, etc.)
- "Why did my model make this prediction?"
- "Calculate SHAP values for my model"
- "Visualize feature importance using SHAP"
- "Debug my model's behavior" or "validate my model"
- "Check my model for bias" or "analyze fairness"
- "Compare feature importance across models"
- "Implement explainable AI" or "add explanations to my model"
- "Understand feature interactions"
- "Create model interpretation dashboard"
Quick Start Guide
Step 1: Select the Right Explainer
Decision Tree:
Tree-based model? (XGBoost, LightGBM, CatBoost, Random Forest, Gradient Boosting)
- Use
shap.TreeExplainer(fast, exact)
- Use
Deep neural network? (TensorFlow, PyTorch, Keras, CNNs, RNNs, Transformers)
- Use
shap.DeepExplainerorshap.GradientExplainer
- Use
Linear model? (Linear/Logistic Regression, GLMs)
- Use
shap.LinearExplainer(extremely fast)
- Use
Any other model? (SVMs, custom functions, black-box models)
- Use
shap.KernelExplainer(model-agnostic but slower)
- Use
Unsure?
- Use
shap.Explainer(automatically selects best algorithm)
- Use
See references/explainers.md for detailed information on all explainer types.
Step 2: Compute SHAP Values
import shap
# Example with tree-based model (XGBoost)
import xgboost as xgb
# Train model
model = xgb.XGBClassifier().fit(X_train, y_train)
# Create explainer
explainer = shap.TreeExplainer(model)
# Compute SHAP values
shap_values = explainer(X_test)
# The shap_values object contains:
# - values: SHAP values (feature attributions)
# - base_values: Expected model output (baseline)
# - data: Original feature values
Step 3: Visualize Results
For Global Understanding (entire dataset):
# Beeswarm plot - shows feature importance with value distributions
shap.plots.beeswarm(shap_values, max_display=15)
# Bar plot - clean summary of feature importance
shap.plots.bar(shap_values)
For Individual Predictions:
# Waterfall plot - detailed breakdown of single prediction
shap.plots.waterfall(shap_values[0])
# Force plot - additive force visualization
shap.plots.force(shap_values[0])
For Feature Relationships:
# Scatter plot - feature-prediction relationship
shap.plots.scatter(shap_values[:, "Feature_Name"])
# Colored by another feature to show interactions
shap.plots.scatter(shap_values[:, "Age"], color=shap_values[:, "Education"])
See references/plots.md for comprehensive guide on all plot types.
Core Workflows
This skill supports several common workflows. Choose the workflow that matches the current task.
Workflow 1: Basic Model Explanation
Goal: Understand what drives model predictions
Steps:
- Train model and create appropriate explainer
- Compute SHAP values for test set
- Generate global importance plots (beeswarm or bar)
- Examine top feature relationships (scatter plots)
- Explain specific predictions (waterfall plots)
Example:
# Step 1-2: Setup
explainer = shap.TreeExplainer(model)
shap_values = explainer(X_test)
# Step 3: Global importance
shap.plots.beeswarm(shap_values)
# Step 4: Feature relationships
shap.plots.scatter(shap_values[:, "Most_Important_Feature"])
# Step 5: Individual explanation
shap.plots.waterfall(shap_values[0])
Workflow 2: Model Debugging
Goal: Identify and fix model issues
Steps:
- Compute SHAP values
- Identify prediction errors
- Explain misclassified samples
- Check for unexpected feature importance (data leakage)
- Validate feature relationships make sense
- Check feature interactions
See references/workflows.md for detailed debugging workflow.
Workflow 3: Feature Engineering
Goal: Use SHAP insights to improve features
Steps:
- Compute SHAP values for baseline model
- Identify nonlinear relationships (candidates for transformation)
- Identify feature interactions (candidates for interaction terms)
- Engineer new features
- Retrain and compare SHAP values
- Validate improvements
See references/workflows.md for detailed feature engineering workflow.
Workflow 4: Model Comparison
Goal: Compare multiple models to select best interpretable option
Steps:
- Train multiple models
- Compute SHAP values for each
- Compare global feature importance
- Check consistency of feature rankings
- Analyze specific predictions across models
- Select based on accuracy, interpretability, and consistency
See references/workflows.md for detailed model comparison workflow.
Workflow 5: Fairness and Bias Analysis
Goal: Detect and analyze model bias across demographic groups
Steps:
- Identify protected attributes (gender, race, age, etc.)
- Compute SHAP values
- Compare feature importance across groups
- Check protected attribute SHAP importance
- Identify proxy features
- Implement mitigation strategies if bias found
See references/workflows.md for detailed fairness analysis workflow.
Workflow 6: Production Deployment
Goal: Integrate SHAP explanations into production systems
Steps:
- Train and save model
- Create and save explainer
- Build explanation service
- Create API endpoints for predictions with explanations
- Implement caching and optimization
- Monitor explanation quality
See references/workflows.md for detailed production deployment workflow.
Key Concepts
SHAP Values
Definition: SHAP values quantify each feature's contribution to a prediction, measured as the deviation from the expected model output (baseline).
Properties:
- Additivity: SHAP values sum to difference between prediction and baseline
- Fairness: Based on Shapley values from game theory
- Consistency: If a feature becomes more important, its SHAP value increases
Interpretation:
- Positive SHAP value → Feature pushes prediction higher
- Negative SHAP value → Feature pushes prediction lower
- Magnitude → Strength of feature's impact
- Sum of SHAP values → Total prediction change from baseline
Example:
Baseline (expected value): 0.30
Feature contributions (SHAP values):
Age: +0.15
Income: +0.10
Education: -0.05
Final prediction: 0.30 + 0.15 + 0.10 - 0.05 = 0.50
Background Data / Baseline
Purpose: Represents "typical" input to establish baseline expectations
Selection:
- Random sample from training data (50-1000 samples)
- Or use kmeans to select representative samples
- For DeepExplainer/KernelExplainer: 100-1000 samples balances accuracy and speed
Impact: Baseline affects SHAP value magnitudes but not relative importance
Model Output Types
Critical Consideration: Understand what your model outputs
- Raw output: For regression or tree margins
- Probability: For classification probability
- Log-odds: For logistic regression (before sigmoid)
Example: XGBoost classifiers explain margin output (log-odds) by default. To explain probabilities, use model_output="probability" in TreeExplainer.
Common Patterns
Pattern 1: Complete Model Analysis
# 1. Setup
explainer = shap.TreeExplainer(model)
Install shap in Claude Code & Claude Desktop
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- Reveal the one-line install command
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Allowed tools
Tools this skill is permitted to call.
No restriction — this skill can use any tool.
Bundled files
FAQ
What does the shap skill do?
Model interpretability and explainability using SHAP (SHapley Additive exPlanations). Use this skill when explaining machine learning model predictions, computing feature importance, generating SHAP plots (waterfall, beeswarm, bar, scatter, force, heatmap), debugging models, analyzing model bias or fairness, comparing models, or implementing explainable AI. Works with tree-based models (XGBoost, LightGBM, Random Forest), deep learning (TensorFlow, PyTorch), linear models, and any black-box model.
How do I install the shap skill?
Copy the skill folder into ~/.claude/skills (the Claude Code tab above does this in one command), or install it as a plugin.
Does the shap skill run scripts?
No, this skill is instructions only (SKILL.md) with no executable scripts.
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