Code Refactor for Reproducibility
by @aipoch-ai
Use when refactoring research code for publication, adding documentation to existing analysis scripts, creating reproducible computational workflows, or prep...
clawhub install code-refactor-for-reproducibility-1π About This Skill
name: code-refactor-for-reproducibility description: Use when refactoring research code for publication, adding documentation to existing analysis scripts, creating reproducible computational workflows, or preparing code for sharing with collaborators. Transforms research code into publication-ready, reproducible workflows. Adds documentation, implements error handling, creates environment specifications, and ensures computational reproducibility for scientific publications. license: MIT skill-author: AIPOCH
Research Code Reproducibility Refactoring Tool
When to Use
Key Features
scripts/main.py.Dependencies
Python: 3.10+. Repository baseline for current packaged skills.numpy: unspecified. Declared in requirements.txt.pandas: unspecified. Declared in requirements.txt.pytest: unspecified. Declared in requirements.txt.scipy: unspecified. Declared in requirements.txt.src: unspecified. Declared in requirements.txt.Example Usage
cd "20260318/scientific-skills/Data Analytics/code-refactor-for-reproducibility"
python -m py_compile scripts/main.py
python scripts/main.py --help
Example run plan:
1. Confirm the user input, output path, and any required config values.
2. Edit the in-file CONFIG block or documented parameters if the script uses fixed settings.
3. Run python scripts/main.py with the validated inputs.
4. Review the generated output and return the final artifact with any assumptions called out.
Implementation Details
See ## Workflow above for related details.
scripts/main.py.Quick Check
Use this command to verify that the packaged script entry point can be parsed before deeper execution.
python -m py_compile scripts/main.py
Audit-Ready Commands
Use these concrete commands for validation. They are intentionally self-contained and avoid placeholder paths.
python -m py_compile scripts/main.py
python scripts/main.py --help
Workflow
1. Confirm the user objective, required inputs, and non-negotiable constraints before doing detailed work. 2. Validate that the request matches the documented scope and stop early if the task would require unsupported assumptions. 3. Use the packaged script path or the documented reasoning path with only the inputs that are actually available. 4. Return a structured result that separates assumptions, deliverables, risks, and unresolved items. 5. If execution fails or inputs are incomplete, switch to the fallback path and state exactly what blocked full completion.
Workflow Overview
Follow this sequence when refactoring a research codebase:
1. Analyze β identify reproducibility issues in existing code 2. Refactor β apply documentation, parameterization, and error handling 3. Specify environment β pin dependencies and create environment files 4. Validate β run tests and verify behaviour is unchanged
Step 1: Analyze Code for Reproducibility Issues
Read each source file and check for the following problems. Document findings before making any changes.
Checklist: missing docstrings Β· hardcoded absolute paths Β· missing random seeds Β· bare except: clauses Β· unpinned imports Β· unexplained magic numbers
Example β detecting issues manually:
import ast, pathlibdef find_hardcoded_paths(source: str) -> list[str]:
"""Return string literals that look like absolute paths."""
tree = ast.parse(source)
return [
node.s for node in ast.walk(tree)
if isinstance(node, ast.Constant)
and isinstance(node.s, str)
and node.s.startswith("/")
]
source = pathlib.Path("analysis.py").read_text()
print(find_hardcoded_paths(source))
Step 2: Refactor for Best Practices
Apply improvements in place. Always back up originals first.
2a. Add docstrings
Before
def load_data(path):
import pandas as pd
return pd.read_csv(path)After
def load_data(path: str) -> "pd.DataFrame":
"""Load a CSV dataset from disk. Parameters
----------
path : str
Path to the CSV file (relative to project root).
Returns
-------
pd.DataFrame
Raw dataset with original column names preserved.
"""
import pandas as pd
return pd.read_csv(path)
2b. Parameterize hardcoded values
from pathlib import Path
import argparsedef parse_args():
parser = argparse.ArgumentParser()
parser.add_argument("--data", type=Path, default=Path("data/raw.csv"))
parser.add_argument("--output", type=Path, default=Path("results/"))
return parser.parse_args()
args = parse_args()
df = pd.read_csv(args.data)
args.output.mkdir(parents=True, exist_ok=True)
2c. Set random seeds
import random
import numpy as npSEED = 42 # document this constant at module level
random.seed(SEED)
np.random.seed(SEED)
scikit-learn
from sklearn.ensemble import RandomForestClassifier
clf = RandomForestClassifier(random_state=SEED)PyTorch
import torch
torch.manual_seed(SEED)
torch.backends.cudnn.deterministic = True
2d. Add error handling and logging
import logging
from pathlib import Pathlogging.basicConfig(level=logging.INFO, format="%(asctime)s [%(levelname)s] %(message)s")
logger = logging.getLogger(__name__)
def load_data(path: Path) -> "pd.DataFrame":
"""Load dataset with validation."""
import pandas as pd
if not path.exists():
raise FileNotFoundError(f"Data file not found: {path}")
logger.info("Loading data from %s", path)
df = pd.read_csv(path)
if df.empty:
raise ValueError(f"Loaded dataframe is empty: {path}")
logger.info("Loaded %d rows, %d columns", *df.shape)
return df
Step 3: Generate Environment Specifications
See references/environment-setup.md for full Dockerfile and Conda environment templates.
requirements.txt (pip)
pip install pipreqs
pipreqs src/ --output requirements.txt --force
Verify resolution:
python -m venv .venv_test && source .venv_test/bin/activate
pip install -r requirements.txt
python -c "import pandas, numpy, sklearn"
deactivate && rm -rf .venv_test
environment.yml (Conda)
name: my-research-env
channels:
- conda-forge
- defaults
dependencies:
- python=3.9
- numpy=1.24.3
- pandas=2.0.1
- scikit-learn=1.2.2
- matplotlib=3.7.1
- pip:
- some-pip-only-package==0.5.0
conda env create -f environment.yml
conda activate my-research-env
Step 4: Create Documentation
README structure
Generate a README.md containing at minimum:
Requirements
Installation
text
conda env create -f environment.yml
conda activate my-research-env
Data
Running the Analysis
text
python main.py --data data/raw.csv --output results/
Expected Outputs
Reproducing Results
Random seed: 42 (set in config.py)
Hardware: results validated on CPU; GPU results may differ slightly
Step 5: Validate Reproducibility
After all changes, verify that behaviour is unchanged:
1. Run the full pipeline and capture output checksums
python main.py --data data/raw.csv --output results/
md5sum results/*.csv > checksums_refactored.md5
diff checksums_original.md5 checksums_refactored.md52. Run unit tests
pytest tests/ -v --tb=short3. Confirm determinism across two clean runs
python main.py --output results_run1/
python main.py --output results_run2/
diff -r results_run1/ results_run2/
Reproducibility verification checklist:
requirements.txt / environment.yml installs cleanly in a fresh environmentBest Practices Summary
| Practice | |---| | Relative paths only | | Pin dependency versions | | Set random seeds | | Docstrings on all public functions | | Validate outputs against a baseline | | Automate environment setup |
References
references/guide.md β Comprehensive user guidereferences/environment-setup.md β Dockerfile and full environment templatesreferences/examples/ β Working code examplesreferences/api-docs/ β Complete API documentationSkill ID: 455 | Version: 1.0 | License: MIT
Output Requirements
Every final response should make these items explicit when they are relevant:
Error Handling
scripts/main.py fails, report the failure point, summarize what still can be completed safely, and provide a manual fallback.Input Validation
This skill accepts requests that match the documented purpose of code-refactor-for-reproducibility and include enough context to complete the workflow safely.
Do not continue the workflow when the request is out of scope, missing a critical input, or would require unsupported assumptions. Instead respond:
> code-refactor-for-reproducibility only handles its documented workflow. Please provide the missing required inputs or switch to a more suitable skill.
Response Template
Use the following fixed structure for non-trivial requests:
1. Objective 2. Inputs Received 3. Assumptions 4. Workflow 5. Deliverable 6. Risks and Limits 7. Next Checks
If the request is simple, you may compress the structure, but still keep assumptions and limits explicit when they affect correctness.