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Applied Data Science with Python and Jupyter

You're reading from   Applied Data Science with Python and Jupyter Use powerful industry-standard tools to unlock new, actionable insights from your data

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Product type Paperback
Published in Oct 2018
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ISBN-13 9781789958171
Length 192 pages
Edition 1st Edition
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Alex Galea Alex Galea
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Alex Galea
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Basic Functionality and Features

In this section, we first demonstrate the usefulness of Jupyter Notebooks with examples and through discussion. Then, in order to cover the fundamentals of Jupyter Notebooks for beginners, we'll see the basic usage of them in terms of launching and interacting with the platform. For those who have used Jupyter Notebooks before, this will be mostly a review; however, you will certainly see new things in this topic as well.

What is a Jupyter Notebook and Why is it Useful?

Jupyter Notebooks are locally run web applications which contain live code, equations, figures, interactive apps, and Markdown text. The standard language is Python, and that's what we'll be using for this book; however, note that a variety of alternatives are supported. This includes the other dominant data science language, R:

Figure 1.1: Jupyter Notebook sample workbook
Figure 1.1: Jupyter Notebook sample workbook

Those familiar with R will know about R Markdown. Markdown documents allow for Markdown-formatted text to be combined with executable code. Markdown is a simple language used for styling text on the web. For example, most GitHub repositories have a README.md Markdown file. This format is useful for basic text formatting. It's comparable to HTML but allows for much less customization.

Commonly used symbols in Markdown include hashes (#) to make text into a heading, square and round brackets to insert hyperlinks, and stars to create italicized or bold text:

Figure 1.2: Sample Markdown document
Figure 1.2: Sample Markdown document

Having seen the basics of Markdown, let's come back to R Markdown, where Markdown text can be written alongside executable code. Jupyter Notebooks offer the equivalent functionality for Python, although, as we'll see, they function quite differently than R Markdown documents. For example, R Markdown assumes you are writing Markdown unless otherwise specified, whereas Jupyter Notebooks assume you are inputting code. This makes it more appealing to use Jupyter Notebooks for rapid development and testing.

From a data science perspective, there are two primary types for a Jupyter Notebook depending on how they are used: lab-style and deliverable.

Lab-style Notebooks are meant to serve as the programming analog of research journals. These should contain all the work you've done to load, process, analyze, and model the data. The idea here is to document everything you've done for future reference, so it's usually not advisable to delete or alter previous lab-style Notebooks. It's also a good idea to accumulate multiple date-stamped versions of the Notebook as you progress through the analysis, in case you want to look back at previous states.

Deliverable Notebooks are intended to be presentable and should contain only select parts of the lab-style Notebooks. For example, this could be an interesting discovery to share with your colleagues, an in-depth report of your analysis for a manager, or a summary of the key findings for stakeholders.

In either case, an important concept is reproducibility. If you've been diligent in documenting your software versions, anyone receiving the reports will be able to rerun the Notebook and compute the same results as you did. In the scientific community, where reproducibility is becoming increasingly difficult, this is a breath of fresh air.

Navigating the Platform

Now, we are going to open up a Jupyter Notebook and start to learn the interface. Here, we will assume you have no prior knowledge of the platform and go over the basic usage.

Exercise 1: Introducing Jupyter Notebooks

  1. Navigate to the companion material directory in the terminal

    Note

    Unix machines such as Mac or Linux, command-line navigation can be done using ls to display directory contents and cd to change directories. On Windows machines, use dir to display directory contents and use cd to change directories instead. If, for example, you want to change the drive from C: to D:, you should execute d: to change drives.

  2. Start a new local Notebook server here by typing the following into the terminal:
    jupyter notebook

    A new window or tab of your default browser will open the Notebook Dashboard to the working directory. Here, you will see a list of folders and files contained therein.

  3. Click on a folder to navigate to that particular path and open a file by clicking on it. Although its main use is editing IPYNB Notebook files, Jupyter functions as a standard text editor as well.
  4. Reopen the terminal window used to launch the app. We can see the NotebookApp being run on a local server. In particular, you should see a line like this:
    [I 20:03:01.045 NotebookApp] The Jupyter Notebook is running at: http://localhost:8888/?token=e915bb06866f19ce462d959a9193a94c7c088e81765f9d8a

    Going to that HTTP address will load the app in your browser window, as was done automatically when starting the app. Closing the window does not stop the app; this should be done from the terminal by typing Ctrl + C.

  5. Close the app by typing Ctrl + C in the terminal. You may also have to confirm by entering y. Close the web browser window as well.
  6. Load the list of available options by running the following code:
    jupyter notebook --help
  7. Open the NotebookApp at local port 9000 by running the following:
    jupyter notebook --port 9000
  8. Click New in the upper-right corner of the Jupyter Dashboard and select a kernel from the drop-down menu (that is, select something in the Notebooks section):
    Figure 1.3: Selecting a kernel from the drop down menu
    Figure 1.3: Selecting a kernel from the drop down menu

    This is the primary method of creating a new Jupyter Notebook.

    Kernels provide programming language support for the Notebook. If you have installed Python with Anaconda, that version should be the default kernel. Conda virtual environments will also be available here.

    Note

    Virtual environments are a great tool for managing multiple projects on the same machine. Each virtual environment may contain a different version of Python and external libraries. Python has built-in virtual environments; however, the Conda virtual environment integrates better with Jupyter Notebooks and boasts other nice features. The documentation is available at: https://conda.io/docs/user-guide/tasks/manage-environments.html.

  9. With the newly created blank Notebook, click the top cell and type print('hello world'), or any other code snippet that writes to the screen.
  10. Click the cell and press Shift + Enter or select Run Cell in the Cell menu.

    Any stdout or stderr output from the code will be displayed beneath as the cell runs. Furthermore, the string representation of the object written in the final line will be displayed as well. This is very handy, especially for displaying tables, but sometimes we don't want the final object to be displayed. In such cases, a semicolon (;) can be added to the end of the line to suppress the display. New cells expect and run code input by default; however, they can be changed to render Markdown instead.

  11. Click an empty cell and change it to accept the Markdown-formatted text. This can be done from the drop-down menu icon in the toolbar or by selecting Markdown from the Cell menu. Write some text in here (any text will do), making sure to utilize Markdown formatting symbols such as #.
  12. Scroll to the Play icon in the tool bar:
    Figure 1.4: Jupyter Notebook tool bar
    Figure 1.4: Jupyter Notebook tool bar

    This can be used to run cells. As we'll see later, however, it's handier to use the keyboard shortcut Shift + Enter to run cells.

    Right next to this is a Stop icon, which can be used to stop cells from running. This is useful, for example, if a cell is taking too long to run:

    Figure 1.5: Stop icon in Jupyter Notebooks
    Figure 1.5: Stop icon in Jupyter Notebooks

    New cells can be manually added from the Insert menu:

    Figure 1.6: Adding new cells from the Insert menu in Jupyter Notebooks
    Figure 1.6: Adding new cells from the Insert menu in Jupyter Notebooks

    Cells can be copied, pasted, and deleted using icons or by selecting options from the Edit menu:

    Figure 1.7: Edit Menu in the Jupyter Notebooks
    Figure 1.7: Edit Menu in the Jupyter Notebooks
    Figure 1.8: Cutting and copying cells in Jupyter Notebooks
    Figure 1.8: Cutting and copying cells in Jupyter Notebooks

    Cells can also be moved up and down this way:

    Figure 1.9: Moving cells up and down in Jupyter Notebooks
    Figure 1.9: Moving cells up and down in Jupyter Notebooks

    There are useful options under the Cell menu to run a group of cells or the entire Notebook:

    Figure 1.10: Running Cells in Jupyter Notebooks
    Figure 1.10: Running cells in Jupyter Notebooks

    Experiment with the toolbar options to move cells up and down, insert new cells, and delete cells. An important thing to understand about these Notebooks is the shared memory between cells. It's quite simple: every cell existing on the sheet has access to the global set of variables. So, for example, a function defined in one cell could be called from any other, and the same applies to variables. As one would expect, anything within the scope of a function will not be a global variable and can only be accessed from within that specific function.

  13. Open the Kernel menu to see the selections. The Kernel menu is useful for stopping script executions and restarting the Notebook if the kernel dies. Kernels can also be swapped here at any time, but it is unadvisable to use multiple kernels for a single Notebook due to reproducibility concerns.
  14. Open the File menu to see the selections. The File menu contains options for downloading the Notebook in various formats. In particular, it's recommended to save an HTML version of your Notebook, where the content is rendered statically and can be opened and viewed "as you would expect" in web browsers.

    The Notebook name will be displayed in the upper-left corner. New Notebooks will automatically be named Untitled.

  15. Change the name of your IPYNB Notebook file by clicking on the current name in the upper-left corner and typing the new name. Then, save the file.
  16. Close the current tab in your web browser (exiting the Notebook) and go to the Jupyter Dashboard tab, which should still be open. (If it's not open, then reload it by copy and pasting the HTTP link from the terminal.)

    Since we didn't shut down the Notebook, and we just saved and exited, it will have a green book symbol next to its name in the Files section of the Jupyter Dashboard and will be listed as Running on the right side next to the last modified date. Notebooks can be shut down from here.

  17. Quit the Notebook you have been working on by selecting it (checkbox to the left of the name), and then click the orange Shutdown button:

    Note

    Read through the basic keyboard shortcuts and test them.

Figure 1.11: Shutting down the Jupyter notebook
Figure 1.11: Shutting down the Jupyter notebook

Note

If you plan to spend a lot of time working with Jupyter Notebooks, it's worthwhile to learn the keyboard shortcuts. This will speed up your workflow considerably. Particularly useful commands to learn are the shortcuts for manually adding new cells and converting cells from code to Markdown formatting. Click on Keyboard Shortcuts from the Help menu to see how.

Jupyter Features

Jupyter has many appealing features that make for efficient Python programming. These include an assortment of things, from methods for viewing docstrings to executing Bash commands. We will explore some of these features in this section.

Note

The official IPython documentation can be found here: http://ipython.readthedocs.io/en/stable/. It has details on the features we will discuss here and others.

Exercise 2: Implementing Jupyter's Most Useful Features

  1. Navigate to the lesson-1 directory from the Jupyter Dashboard and open lesson-1-workbook.ipynb by selecting it.

    The standard file extension for Jupyter Notebooks is .ipynb, which was introduced back when they were called IPython Notebooks.

  2. Scroll down to Subtopic C: Jupyter Features in the Jupyter Notebook.

    We start by reviewing the basic keyboard shortcuts. These are especially helpful to avoid having to use the mouse so often, which will greatly speed up the workflow.

    You can get help by adding a question mark to the end of any object and running the cell. Jupyter finds the docstring for that object and returns it in a pop-out window at the bottom of the app.

  3. Run the Getting Help cell and check how Jupyter displays the docstrings at the bottom of the Notebook. Add a cell in this section and get help on the object of your choice:
    Figure 1.12: Getting help in Jupyter Notebooks
    Figure 1.12: Getting help in Jupyter Notebooks
  4. Click an empty code cell in the Tab Completion section. Type import (including the space after) and then press the Tab key:
    Figure 1.13: Tab completion in Jupyter Notebooks
    Figure 1.13: Tab completion in Jupyter Notebooks

    The above action listed all the available modules for import.

    Tab completion can be used for the following: list available modules when importing external libraries; list available modules of imported external libraries; function and variable completion. This can be especially useful when you need to know the available input arguments for a module, when exploring a new library, to discover new modules, or simply to speed up workflow. They will save time writing out variable names or functions and reduce bugs from typos. The tab completion works so well that you may have difficulty coding Python in other editors after today!

  5. Scroll to the Jupyter Magic Functions section and run the cells containing %lsmagic and %matplotlib inline:
    Figure 1.14: Jupyter Magic functions
    Figure 1.14: Jupyter Magic functions

    The percent signs, % and %%, are one of the basic features of Jupyter Notebook and are called magic commands. Magics starting with %% will apply to the entire cell, and magics starting with % will only apply to that line.

    %lsmagic lists the available options. We will discuss and show examples of some of the most useful ones. The most common magic command you will probably see is %matplotlib inline, which allows matplotlib figures to be displayed in the Notebook without having to explicitly use plt.show().

    The timing functions are very handy and come in two varieties: a standard timer (%time or %%time) and a timer that measures the average runtime of many iterations (%timeit and %%timeit).

    Note

    Notice how list comprehensions are quicker than loops in Python. This can be seen by comparing the wall time for the first and second cell, where the same calculation is done significantly faster with the list comprehension.

  6. Run the cells in the Timers section.

    Note the difference between using one and two percent signs. Even by using a Python kernel (as you are currently doing), other languages can be invoked using magic commands. The built-in options include JavaScript, R, Pearl, Ruby, and Bash. Bash is particularly useful, as you can use Unix commands to find out where you are currently (pwd), what's in the directory (ls), make new folders (mkdir), and write file contents (cat/head/tail).

  7. Run the first cell in the Using bash in the notebook section.

    This cell writes some text to a file in the working directory, prints the directory contents, prints an empty line, and then writes back the contents of the newly created file before removing it:

    Figure 1.15: Using Bash in Jupyter Notebooks
    Figure 1.15: Using Bash in Jupyter Notebooks
  8. Run the cells containing only ls and pwd.

    Note how we did not have to explicitly use the Bash magic command for these to work. There are plenty of external magic commands that can be installed. A popular one is ipython-sql, which allows for SQL code to be executed in cells.

  9. Open a new terminal window and execute the following code to install ipython-sql:
    pip install ipython-sql
    Figure 1.16: Installing ipython-sql using pip
    Figure 1.16: Installing ipython-sql using pip
  10. Run the %load_ext sql cell to load the external command into the Notebook:
    Figure 1.17: Loading sql in Jupyter Notebooks
    Figure 1.17: Loading sql in Jupyter Notebooks

    This allows for connections to remote databases so that queries can be executed (and thereby documented) right inside the Notebook.

  11. Run the cell containing the SQL sample query:
    Figure 1.18: Running a sample SQL query
    Figure 1.18: Running a sample SQL query

    Here, we first connect to the local sqlite source; however, this line could instead point to a specific database on a local or remote server. Then, we execute a simple SELECT to show how the cell has been converted to run SQL code instead of Python.

  12. Install the version documentation tool now from the terminal using pip. Open up a new window and run the following code:
    pip install version_information

    Once installed, it can then be imported into any Notebook using %load_ext version_information. Finally, once loaded, it can be used to display the versions of each piece of software in the Notebook.

    The %version_information commands helps with documentation, but it does not come as standard with Jupyter. Like the SQL example we just saw, it can be installed from the command line with pip.

  13. Run the cell that loads and calls the version_information command:
Figure 1.19: Version Information in Jupyter
Figure 1.19: Version Information in Jupyter

Converting a Jupyter Notebook to a Python Script

You can convert a Jupyter Notebook to a Python script. This is equivalent to copying and pasting the contents of each code cell into a single .py file. The Markdown sections are also included as comments.

The conversion can be done from the NotebookApp or in the command line as follows:

jupyter nbconvert --to=python lesson-1-notebook.ipynb
Figure 1.20: Converting a Jupyter Notebook into a Python Script
Figure 1.20: Converting a Jupyter Notebook into a Python Script

This is useful, for example, when you want to determine the library requirements for a Notebook using a tool such as pipreqs. This tool determines the libraries used in a project and exports them into a requirements.txt file (and it can be installed by running pip install pipreqs).

The command is called from outside the folder containing your .py files. For example, if the .py files are inside a folder called lesson-1, you could do the following:

pipreqs lesson-1/
Figure 1.21: Determining library requirements using pipreqs
Figure 1.21: Determining library requirements using pipreqs

The resulting requirements.txt file for lesson-1-workbook.ipynb looks like this:

cat lesson-1/requirements.txt 
matplotlib==2.0.2 numpy==1.13.1
pandas==0.20.3 
requests==2.18.4 
seaborn==0.8 
beautifulsoup4==4.6.0 
scikit_learn==0.19.0

Python Libraries

Having now seen all the basics of Jupyter Notebooks, and even some more advanced features, we'll shift our attention to the Python libraries we'll be using in this book. Libraries, in general, extend the default set of Python functions. Examples of commonly used standard libraries are datetime, time, and os. These are called standard libraries because they come standard with every installation of Python.

For data science with Python, the most important libraries are external, which means they do not come standard with Python.

The external data science libraries we'll be using in this book are NumPy, Pandas, Seaborn, matplotlib, scikit-learn, Requests, and Bokeh.

Note

A word of caution: It's a good idea to import libraries using industry standards, for example, import numpy as np; this way, your code is more readable. Try to avoid doing things such as from numpy import *, as you may unwittingly overwrite functions. Furthermore, it's often nice to have modules linked to the library via a dot (.) for code readability.

Let's briefly introduce each.

  • NumPy offers multi-dimensional data structures (arrays) on which operations can be performed far quicker than standard Python data structures (for example, lists). This is done in part by performing operations in the background using C. NumPy also offers various mathematical and data manipulation functions.
  • Pandas is Python's answer to the R DataFrame. It stores data in 2D tabular structures where columns represent different variables and rows correspond to samples. Pandas provides many handy tools for data wrangling such as filling in NaN entries and computing statistical descriptions of the data. Working with Pandas DataFrames will be a big focus of this book.
  • Matplotlib is a plotting tool inspired by the MATLAB platform. Those familiar with R can think of it as Python's version of ggplot. It's the most popular Python library for plotting figures and allows for a high level of customization.
  • Seaborn works as an extension to matplotlib, where various plotting tools useful for data science are included. Generally speaking, this allows for analysis to be done much faster than if you were to create the same things manually with libraries such as matplotlib and scikit-learn.
  • scikit-learn is the most commonly used machine learning library. It offers top-of-the-line algorithms and a very elegant API where models are instantiated and then fit with data. It also provides data processing modules and other tools useful for predictive analytics.
  • Requests is the go-to library for making HTTP requests. It makes it straightforward to get HTML from web pages and interface with APIs. For parsing the HTML, many choose BeautifulSoup4, which we will also cover in this book.
  • Bokeh is an interactive visualization library. It functions similar to matplotlib, but allows us to add hover, zoom, click, and use other interactive tools to our plots. It also allows us to render and play with the plots inside our Jupyter Notebook.

Having introduced these libraries, let's go back to our Notebook and load them, by running the import statements. This will lead us into our first analysis, where we finally start working with a dataset.

Exercise 3: Importing the External Libraries and Setting Up the Plotting Environment

  1. Open up the lesson 1 Jupyter Notebook and scroll to the Subtopic D: Python Libraries section.

    Just like for regular Python scripts, libraries can be imported into the Notebook at any time. It's best practice to put the majority of the packages you use at the top of the file. Sometimes it makes sense to load things midway through the Notebook and that is completely fine.

  2. Run the cells to import the external libraries and set the plotting options:
Figure 1.22: Importing Python libraries
Figure 1.22: Importing Python libraries

For a nice Notebook setup, it's often useful to set various options along with the imports at the top. For example, the following can be run to change the figure appearance to something more aesthetically pleasing than the matplotlib and Seaborn defaults:

import matplotlib.pyplot as plt
%matplotlib inline import 
seaborn as sns
# See here for more options: https://matplotlib.org/users/ customizing.html
%config InlineBackend.figure_format='retina' 
sns.set() # Revert to matplotlib defaults 
plt.rcParams['figure.figsize'] = (9, 6)
plt.rcParams['axes.labelpad'] = 10 sns.set_style("darkgrid")

So far in this book, we've gone over the basics of using Jupyter Notebooks for data science. We started by exploring the platform and finding our way around the interface. Then, we discussed the most useful features, which include tab completion and magic functions. Finally, we introduced the Python libraries we'll be using in this book.

The next section will be very interactive as we perform our first analysis together using the Jupyter Notebook.

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