Python programming language: A cheat sheet
Python programming language: A cheat sheet
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This comprehensive guide explores what Python is used for, how it compares to other programming languages, and resources for building skills in Python.

With over 8.2 million developers using Python, the popularity of the Python programming language can’t be denied. Since the first release in1990, Python has gained public support in academia and business, being used extensively in artificial intelligence and machine learning, serving as the underpinning of OpenStack, as well as powering the cloud file storage service Dropbox.

This extensibility makes Python an excellent programming language for junior developers to get started with, but also one that remains applicable at scale, as Python is used extensively for real-world applications. This cheat sheet explores what Python is used for and how it compares to other programming languages, and provides resources for learning the language. 

SEE: All of TechRepublic’s cheat sheets and smart person’s guides

What is the Python programming language?

Python is an interpreted programming language created in 1990 by Dutch programmer Guido van Rossum, following his experience working on the education-focused ABC language at CWI. Python differs from other programming languages, as it prioritizes code readability and use of whitespace over compact, tiny source files.

Python is dynamically typed and garbage-collected (through reference counting and cycle detection), supports object-oriented and structured programming fully, and largely supports functional and aspect-oriented programming, making it particularly versatile and applicable for a wide variety of use cases.

SEE: Python is eating the world: How one developer’s side project became the hottest programming language on the planet (TechRepublic cover story PDF)

The standard library is commonly considered one of the greatest strengths of Python; this feature enables programmers to quickly develop projects without needing to rely heavily on third-party packages for the basic plumbing of a given application. To complement the standard library, the Python Package Index (PyPI) catalogues over 200,000 packages that provide various functions.

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What makes Python a good choice for my project?

Python’s design as a language makes it a good choice for projects with multiple authors, as the inherent readability of the language aides in the ability to pick up code and clearly understand how it operates. Python is a powerful programming language, enabling even junior developers to accomplish quite a lot—as is the case for practically everything in computer science, there is an xkcd for that

SEE: Hiring kit: Python developer (TechRepublic Premium)

Python is used extensively in artificial intelligence; Google’s TensorFlow framework includes Python modules, as does Keras and Scikit-learn. The Anaconda project is a distribution of Python and R for scientific computing. IBM’s Qiskit and D-Wave’s Ocean learning platforms also use Python for programming quantum computers. Python is used in scientific computer libraries, including NumPy, SciPy, and Matplotlib, and in web frameworks including Django, CherryPy, Pyramid, Flash, web2py, and webapp2.

Graphics editing programs also use inline Python scripting, including the 3D animation software Autodesk 3ds Max, Maya, and MotionBuilder, as well as Cinema 4D, Lightwave, Houdini, and modo, the Nuke compositor, and the open source Blender toolset. Of 2D graphics software, PaintShop Pro, as well as the open-source software GIMP, Inkscape, and Scribus.

Additionally, LibreOffice uses Python for inline scripting, much in the same way Visual Basic is used to extend features of Microsoft Office. 

In 1999, software developer Tim Peters, a major contributor to Python and creator of the original CPython implementation, wrote the “Zen of Python,” an explanation of Python’s design philosophy, and the philosophy that programmers should incorporate into their programming approach. The document was later incorporated into official Python documentation.

Beautiful is better than ugly.
Explicit is better than implicit.
Simple is better than complex.
Complex is better than complicated.
Flat is better than nested.
Sparse is better than dense.
Readability counts.
Special cases aren’t special enough to break the rules.
Although practicality beats purity.
Errors should never pass silently.
Unless explicitly silenced.
In the face of ambiguity, refuse the temptation to guess.
There should be one—and preferably only one—obvious way to do it.
Although that way may not be obvious at first unless you’re Dutch.
Now is better than never.
Although never is often better than right now.
If the implementation is hard to explain, it’s a bad idea.
If the implementation is easy to explain, it may be a good idea.
Namespaces are one honking great idea—let’s do more of those!

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How does Python compare to other programming languages?

Python can be used for practically any use case that any other high-level language (C/C++, JavaScript, PHP, etc.) can be used for. Implementations for modern microcontrollers exist, though older CPUs (m68k, z80, 6502) cannot use Python.

While the CPython reference implementation is broadly useful for most use cases, other implementations of Python do exist to address specific needs and deployment scenarios. MicroPython is a microcontroller-focused implementation supporting Arm architectures, in addition to Arduino, ESP8266, ESP32, and RISC-V (32- and 64-bit) architectures. CircuitPython is an education-focused fork of MicroPython.

PyPy is the most popular general-purpose alternative implementation of Python. It differs from CPython in that PyPy is a (faster) just-in-time compiler, while CPython is an interpreter.

Language-target implementations also exist, including CLPython for Common Lisp, IronPython for .NET/Mono, and Jython for Java. Likewise, the Nuitka project is a source-to-source compiler from Python to C/C++ source code.

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What is the difference between Python 2 and Python 3?

The Python 3.x series was introduced in December 2008, addressing and rectifying fundamental design flaws, as well as generally modernizing the language. Python 3 was developed with the guiding principle of “[reducing] feature duplication by removing old ways of doing things.” Due to this, Python 3 is not fully backward-compatible with Python 2, requiring developers to modernize their code to run on the new version.

Support for Python 2.7 is ending on January 1, 2020, making the transition to Python 3 all the more urgent. 

For programmers, tool-assisted porting using futurize or modernize can aid in the transition, while the caniusepython3 project shows what legacy dependencies may be blocking you from using Python 3.

Additional resources

How do I get started programming in Python?

Learning Python doesn’t require getting a degree in computer science—there’s a wealth of resources available online to help users get started with the programming language.

SEE: Getting started with Python: A list of free resources (free PDF) (TechRepublic)

TechRepublic Academy, a joint venture between TechRepublic, ZDNet, and StackCommerce, also offers a wide variety of in-depth Python training courses.
 
If you’re already familiar with programming, chances are your IDE of choice either natively supports Python or support can be added using a plugin. For new programmers, using a free IDE that supports Python is a quick way to get started—these include Atom, PyCharm, Geany, Sublime Text, and Visual Studio Code. 

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