Jupyter (iPython) notebook is deservedly known as a good tool for prototyping the code and doing all kinds of machine learning stuff interactively. But when I use it, I inevitably run into the following:

  • the notebook quickly becomes too complex and messy to be maintained and improved further as notebook, and I have to make python scripts out of it;
  • when it comes to production code (e.g. one that needs to be re-run every day), the notebook again is not the best format.

Suppose I've developed a whole machine learning pipeline in jupyter that includes fetching raw data from various sources, cleaning the data, feature engineering, and training models after all. Now what's the best logic to make scripts from it with efficient and readable code? I used to tackle it several ways so far:

  1. Simply convert .ipynb to .py and, with only slight changes, hard-code all the pipeline from the notebook into one python script.

    • '+': quick
    • '-': dirty, non-flexible, not convenient to maintain
  2. Make a single script with many functions (approximately, 1 function for each one or two cell), trying to comprise the stages of the pipeline with separate functions, and name them accordingly. Then specify all parameters and global constants via argparse.

    • '+': more flexible usage; more readable code (if you properly transformed the pipeline logic to functions)
    • '-': oftentimes, the pipeline is NOT splittable into logically completed pieces that could become functions without any quirks in the code. All these functions are typically needed to be only called once in the script rather than to be called many times inside loops, maps etc. Furthermore, each function typically takes the output of all functions called before, so one has to pass many arguments to each function.
  3. The same thing as point (2), but now wrap all the functions inside the class. Now all the global constants, as well as outputs of each method can be stored as class attributes.

    • '+': you needn't to pass many arguments to each method -- all the previous outputs already stored as attributes
    • '-': the overall logic of a task is still not captured -- it is data and machine learning pipeline, not just class. The only goal for the class is to be created, call all the methods sequentially one-by-one and then be removed. On top of this, classes are quite long to implement.
  4. Convert a notebook into python module with several scripts. I didn't try this out, but I suspect this is the longest way to deal with the problem.

I suppose, this overall setting is very common among data scientists, but surprisingly I cannot find any useful advice around.

Folks, please, share your ideas and experience. Have you ever encountered this issue? How have you tackled it?

  • Do you just want to extract the python code from Notebook file? Aug 26 '15 at 3:23
  • I did it a couple of times -- it's just the way I mention in point (1). It has some drawbacks. First, non-flexible hard code. Second, typically you don't want to execute every cell in the notebook one-by-one (there may be a plenty of purely visualization or just excessive cells), so you still need to a clean up the code after exporting -- the same work volume as if you just copy-pasted cells manually.
    – kurtosis
    Aug 26 '15 at 9:38
  • You could write a script to extract all the Python code instead of manually. Is this what you want? Aug 26 '15 at 9:41
  • 1
    The simply exporting notebook to .py file does just this -- it extracts all the Python code. But it's not exactly what I want. I'd like to make it a good script as a whole: with transparent code, with classes and functions when it's needed, with flexible api (things like argparse) etc. What is the best practice to wrap a 'data pipeline' into code logic?
    – kurtosis
    Aug 26 '15 at 10:01
  • @kutosis See... That might depend on the usage, if it will only run once, left it as a script is fine. If flexibility is needed, you could wrap it in to module or executable as you like, in class or function does not matters. Aug 26 '15 at 10:23

Life saver: as you're writing your notebooks, incrementally refactor your code into functions, writing some minimal assert tests and docstrings.

After that, refactoring from notebook to script is natural. Not only that, but it makes your life easier when writing long notebooks, even if you have no plans to turn them into anything else.

Basic example of a cell's content with "minimal" tests and docstrings:

def zip_count(f):
    """Given zip filename, returns number of files inside.

    str -> int"""
    from contextlib import closing
    with closing(zipfile.ZipFile(f)) as archive:
        num_files = len(archive.infolist())
    return num_files

zip_filename = 'data/myfile.zip'

# Make sure `myfile` always has three files
assert zip_count(zip_filename) == 3
# And total zip size is under 2 MB
assert os.path.getsize(zip_filename) / 1024**2 < 2


Once you've exported it to bare .py files, your code will probably not be structured into classes yet. But it is worth the effort to have refactored your notebook to the point where it has a set of documented functions, each with a set of simple assert statements that can easily be moved into tests.py for testing with pytest, unittest, or what have you. If it makes sense, bundling these functions into methods for your classes is dead-easy after that.

If all goes well, all you need to do after that is to write your if __name__ == '__main__': and its "hooks": if you're writing script to be called by the terminal you'll want to handle command-line arguments, if you're writing a module you'll want to think about its API with the __init__.py file, etc.

It all depends on what the intended use case is, of course: there's quite a difference between converting a notebook to a small script vs. turning it into a full-fledged module or package.

Here's a few ideas for a notebook-to-script workflow:

  1. Export the Jupyter Notebook to Python file (.py) through the GUI.
  2. Remove the "helper" lines that don't do the actual work: print statements, plots, etc.
  3. If need be, bundle your logic into classes. The only extra refactoring work required should be to write your class docstrings and attributes.
  4. Write your script's entryways with if __name__ == '__main__'.
  5. Separate your assert statements for each of your functions/methods, and flesh out a minimal test suite in tests.py.

We are having the similar issue. However we are using several notebooks for prototyping the outcomes which should become also several python scripts after all.

Our approach is that we put aside the code, which seams to repeat across those notebooks. We put it into the python module, which is imported by each notebook and also used in the production. We iteratively improve this module continuously and add tests of what we find during prototyping.

Notebooks then become rather like the configuration scripts (which we just plainly copy into the end resulting python files) and several prototyping checks and validations, which we do not need in the production.

Most of all we are not afraid of the refactoring :)

  • This sounds like a good approach: it seems to be impossible to do refactoring directly within a notebook - be it ipython/jupyter, zeppelin, spark-notebook .. whatever. That is a showstopper. So your characterization of a notebook as "configuration" is an additional facet to my consideration that it were a presentation tool - but not a development one. Jul 4 '17 at 18:31
  • 1
    @javadba To do so, we would need language integrated IDE both geared towards production usage and exploration. Apr 11 '18 at 5:16

I made a module recently (NotebookScripter) to help address this issue. It allows you to invoke a jupyter notebook via a function call. Its as simple to use as

from NotebookScripter import run_notebook
run_notebook("./path/to/Notebook.ipynb", some_param="Provided Exteranlly")

Keyword parameters can be passed to the function call. Its easy to adapt a notebook to be parameterizable externally.

Within a .ipynb cell

from NotebookScripter import receive_parameter

some_param = receive_parameter(some_param="Return's this value by default when matching keyword not provided by external caller")

print("some_param={0} within the invocation".format(some_param))

run_notebook() supports .ipynb files or .py files -- allowing one to easily use .py files as might be generated by nbconvert of vscode's ipython. You can keep your code organized in a way that makes sense for interactive use, and also reuse/customize it externally when needed.


You should breakdown the logic in small steps, that way your pipeline will be easier to maintain. Since you already have a working codebase, you want to keep your code running, so make small changes, test and repeat.

I'd go this way:

  1. Add some tests to your pipeline, for ML pipelines this is a bit hard, but if your notebook trains a model, you can use performance metrics to test if your pipeline still works (your test can be accuracy = 0.8, but make sure you define a tolerable range since the number hardly be the exact same for each run)
  2. Break apart your single notebook into smaller ones, the output from one should the input for the other. As soon as you create a split, make sure you add a few tests for each notebook individually. To manage this sequential execution, you can use papermill to execute your notebooks or a workflow management tool such as ploomber which integrates with papermill, is able to resolve complex dependencies and has a hook to run tests upon notebook execution (Disclaimer: I'm ploomber's author)
  3. Once you have a pipeline composed of several notebooks that passes all your tests you can decide whether you want to keep using the ipynb format or not. My recommendation would be to only keep as notebooks the tasks that have rich output (such as tables or plots), the rest can be refactored into Python functions, which are more maintainable

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