--- name: python-performance-optimization description: Profile and optimize Python code using cProfile, memory profilers, and performance best practices. Use when debugging slow Python code, optimizing bottlenecks, or improving application performance. --- # Python Performance Optimization Comprehensive guide to profiling, analyzing, and optimizing Python code for better performance, including CPU profiling, memory optimization, and implementation best practices. ## When to Use This Skill - Identifying performance bottlenecks in Python applications - Reducing application latency and response times - Optimizing CPU-intensive operations - Reducing memory consumption and memory leaks - Improving database query performance - Optimizing I/O operations - Speeding up data processing pipelines - Implementing high-performance algorithms - Profiling production applications ## Core Concepts ### 1. Profiling Types - **CPU Profiling**: Identify time-consuming functions - **Memory Profiling**: Track memory allocation and leaks - **Line Profiling**: Profile at line-by-line granularity - **Call Graph**: Visualize function call relationships ### 2. Performance Metrics - **Execution Time**: How long operations take - **Memory Usage**: Peak and average memory consumption - **CPU Utilization**: Processor usage patterns - **I/O Wait**: Time spent on I/O operations ### 3. Optimization Strategies - **Algorithmic**: Better algorithms and data structures - **Implementation**: More efficient code patterns - **Parallelization**: Multi-threading/processing - **Caching**: Avoid redundant computation - **Native Extensions**: C/Rust for critical paths ## Quick Start ### Basic Timing ```python import time def measure_time(): """Simple timing measurement.""" start = time.time() # Your code here result = sum(range(1000000)) elapsed = time.time() - start print(f"Execution time: {elapsed:.4f} seconds") return result # Better: use timeit for accurate measurements import timeit execution_time = timeit.timeit( "sum(range(1000000))", number=100 ) print(f"Average time: {execution_time/100:.6f} seconds") ``` ## Detailed patterns and worked examples Detailed pattern documentation lives in `references/details.md`. Read that file when the navigation tier above is insufficient. ## Best Practices 1. **Profile before optimizing** - Measure to find real bottlenecks 2. **Focus on hot paths** - Optimize code that runs most frequently 3. **Use appropriate data structures** - Dict for lookups, set for membership 4. **Avoid premature optimization** - Clarity first, then optimize 5. **Use built-in functions** - They're implemented in C 6. **Cache expensive computations** - Use lru_cache 7. **Batch I/O operations** - Reduce system calls 8. **Use generators** for large datasets 9. **Consider NumPy** for numerical operations 10. **Profile production code** - Use py-spy for live systems ## Common Pitfalls - Optimizing without profiling - Using global variables unnecessarily - Not using appropriate data structures - Creating unnecessary copies of data - Not using connection pooling for databases - Ignoring algorithmic complexity - Over-optimizing rare code paths - Not considering memory usage