Book Image

Clean Code in Python

By : Mariano Anaya

2 (1)

Book Image

Clean Code in Python

2 (1)

By: Mariano Anaya

Overview of this book

Python is currently used in many different areas such as software construction, systems administration, and data processing. In all of these areas, experienced professionals can find examples of inefficiency, problems, and other perils, as a result of bad code. After reading this book, readers will understand these problems, and more importantly, how to correct them. The book begins by describing the basic elements of writing clean code and how it plays an important role in Python programming. You will learn about writing efficient and readable code using the Python standard library and best practices for software design. You will learn to implement the SOLID principles in Python and use decorators to improve your code. The book delves more deeply into object oriented programming in Python and shows you how to use objects with descriptors and generators. It will also show you the design principles of software testing and how to resolve software problems by implementing design patterns in your code. In the final chapter we break down a monolithic application to a microservice one, starting from the code as the basis for a solid platform. By the end of the book, you will be proficient in applying industry approved coding practices to design clean, sustainable and readable Python code.

Preface

Who this book is for

What this book covers

To get the most out of this book

Free Chapter

Introduction, Code Formatting, and Tools

Introduction, Code Formatting, and Tools

The meaning of clean code

The importance of having clean code

Docstrings and annotations

Pythonic Code

Indexes and slices

Context managers

Properties, attributes, and different types of methods for objects

Iterable objects

Container objects

Dynamic attributes for objects

Callable objects

Summary of magic methods

Caveats in Python

General Traits of Good Code

General Traits of Good Code

Design by contract

Defensive programming

Separation of concerns

Acronyms to live by

Composition and inheritance

Arguments in functions and methods

Final remarks on good practices for software design

The SOLID Principles

The SOLID Principles

Single responsibility principle

The open/closed principle

Liskov's substitution principle

Interface segregation

Dependency inversion

Using Decorators to Improve Our Code

Using Decorators to Improve Our Code

What are decorators in Python?

Effective decorators – avoiding common mistakes

The DRY principle with decorators

Decorators and separation of concerns

Analyzing good decorators

Getting More Out of Our Objects with Descriptors

Getting More Out of Our Objects with Descriptors

A first look at descriptors

Types of descriptors

Descriptors in action

Analysis of descriptors

Using Generators

Using Generators

Technical requirements

Creating generators

Iterating idiomatically

Asynchronous programming

Unit Testing and Refactoring

Unit Testing and Refactoring

Design principles and unit testing

Frameworks and tools for testing

More about unit testing

A brief introduction to test-driven development

Common Design Patterns

Common Design Patterns

Considerations for design patterns in Python

Design patterns in action

The null object pattern

Final thoughts about design patterns

Clean Architecture

Clean Architecture

From clean code to clean architecture

Software components

Summing it all up

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Types of descriptors

Based on the methods we have just explored, we can make an important distinction among descriptors in terms of how they work. Understanding this distinction plays an important role in working effectively with descriptors, and will also help to avoid caveats or common errors at runtime.

If a descriptor implements the __set__ or __delete__ methods, it is called a data descriptor. Otherwise, a descriptor that solely implements __get__ is a non-data descriptor. Notice that __set_name__ does not affect this classification at all.

When trying to resolve an attribute of an object, a data descriptor will always take precedence over the dictionary of the object, whereas a non-data descriptor will not. This means that in a non-data descriptor if the object has a key on its dictionary with the same name as the descriptor, this one will always be called, and the descriptor...