mirror of https://github.com/MLSysBook/TinyTorch.git synced 2026-05-29 20:11:59 -05:00

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Vijay Janapa Reddi a16bfc8a32 feat: Complete educational module-developer framework with progressive disclosure

- Enhanced module-developer agent with Dr. Sarah Rodriguez persona
- Added comprehensive educational frameworks and Golden Rules
- Implemented Progressive Disclosure Principle (no forward references)
- Added Immediate Testing Pattern (test after each implementation)
- Integrated package structure template (📦 where code exports to)
- Applied clean NBGrader structure with proper scaffolding
- Fixed tensor module formatting and scope boundaries
- Removed confusing transparent analysis patterns
- Added visual impact icons system for consistent motivation

🎯 Ready to apply these proven educational principles to all modules

2025-09-28 05:33:38 -04:00

15_profiling.yml

refactor: Migrate module configuration files from .yaml to .yml

2025-09-27 01:36:27 -04:00

module.yaml

feat: Complete educational module-developer framework with progressive disclosure

2025-09-28 05:33:38 -04:00

profiling_dev.ipynb

FOUNDATION: Establish AI Engineering as a discipline through TinyTorch

2025-09-25 11:16:28 -04:00

profiling_dev.py

feat: Complete comprehensive TinyTorch educational enhancement (modules 02-20)

2025-09-27 16:14:27 -04:00

README.md

FEAT: Complete optimization modules 15-20 with ML Systems focus

2025-09-24 22:34:20 -04:00

README.md

Module 15: Profiling - Performance Detective Work

Overview

Become a performance detective! You just built MLPs, CNNs, and Transformers - but why is your transformer 100x slower than PyTorch? Build professional profiling infrastructure to reveal bottlenecks and guide optimization decisions.

What You'll Build

Timer Class: Statistical timing with warmup runs and percentile reporting
Memory Profiler: Track allocations, peak usage, and memory patterns
FLOP Counter: Count operations and analyze computational complexity
Profiler Context: Comprehensive profiling manager combining all tools
Performance Analysis: Complete bottleneck detection and optimization guidance

Learning Objectives

Statistical Timing: Build robust timing infrastructure with confidence intervals
Memory Analysis: Track allocations and identify memory bottlenecks
Computational Complexity: Count FLOPs and understand scaling behavior
Bottleneck Detection: Use Amdahl's Law to identify optimization targets
Systems Thinking: Connect profiling insights to production decisions

Prerequisites

Module 14: Transformers (need models to profile)
Understanding of basic complexity analysis (O(n), O(n²))

Key Concepts

Professional Timing Infrastructure

timer = Timer()
stats = timer.measure(model.forward, warmup=3, runs=100)
# Returns: mean, std, p50, p95, p99 with confidence intervals

Memory Profiling with tracemalloc

profiler = MemoryProfiler()
stats = profiler.profile(expensive_operation)
# Tracks: baseline, peak, allocated, memory patterns

FLOP Analysis for Architecture Comparison

counter = FLOPCounter()
flops = counter.count_attention(seq_len=128, d_model=512)
# Reveals: O(n²) scaling, computational bottlenecks

Comprehensive Profiling Context

with ProfilerContext("MyModel") as profiler:
    result = profiler.profile_function(model.forward, args=(input,))
# Automatic report: timing + memory + FLOPs + insights

Performance Insights

MLPs: Linear scaling, memory efficient, excellent for classification
CNNs: Moderate speed, vectorizable, great for spatial data
Transformers: O(n²) attention scaling, memory hungry, powerful but expensive

Real-World Applications

Bottleneck Identification: Find the 20% of code using 80% of time
Hardware Selection: Use profiling data to choose CPU vs GPU
Cost Prediction: Estimate infrastructure costs from FLOP counts
Optimization ROI: Amdahl's Law guides where to optimize first

Module Structure

Timer Class: Statistical timing with warmup and confidence intervals
Memory Profiler: Allocation tracking and peak usage analysis
FLOP Counter: Operation counting for different layer types
Profiler Context: Integrated profiling with automatic reporting
Architecture Comparison: MLP vs CNN vs Transformer analysis
Bottleneck Detection: Complete model profiling and optimization guidance
Systems Analysis: Connect profiling insights to production decisions

Hands-On Detective Work

# Reveal the transformer bottleneck
with ProfilerContext("Transformer Analysis") as profiler:
    output = profiler.profile_function(transformer.forward, args=(tokens,))
    
# Result: Attention consumes 73% of compute time!
# Next: Optimize attention in Module 16 (Acceleration)

Success Criteria

✅ Build timer with statistical rigor (warmup, percentiles, confidence intervals)
✅ Implement memory profiler tracking allocations and peak usage
✅ Create FLOP counter analyzing computational complexity
✅ Develop integrated profiling context for comprehensive analysis
✅ Identify bottlenecks using data-driven analysis

Systems Insights

Attention is O(n²): 2x sequence length = 4x computation
Memory bandwidth matters: Large models are memory-bound, not compute-bound
Amdahl's Law rules: Optimize the bottleneck first for maximum impact
Profiling drives decisions: Every major ML optimization started with profiling

ML Systems Focus

This module teaches performance analysis as the foundation of all optimization work. You'll build the same profiling tools used to optimize GPT, BERT, and every production ML system. Understanding performance through measurement is the first step toward building efficient ML systems.

The detective work you do here reveals the bottlenecks that Module 16 (Acceleration) will fix!