As python is open source that's why we can customize python as per our requirements. After customization, we can name that version as we want. That's why multiple flavours of python are available. Each flavour is a customized version of python to fulfill a special requirement. It is similar to the fact that there are multiple flavours of UNIX like, Ubuntu, Linux, RedHat Linux etc. Below are some of the flavours of python :
Default implementation of python programming language which we download from python.org, provided by python software foundation. It is written in C and python. It does not allow us to write any C code, only python code are allowed. CPython can be called as both an interpreter and a compiler as here our python code first gets compiled to python bytecode then the bytecode gets interpreted into platform-specific operations by PVM or Python Virtual Machine. Keep in mind interpreters have language syntaxes predefined that's why it does not need to translate into low level machine code. Here Interpreter just executes bytecode on the fly during runtime and results in platform-specific operations.
Cython is a programming language which is a superset of python and C. It is written in C and python. It is designed to give C-like performance with python syntax and optional C-syntax. Cython is a compiled language as it generates C code and gets compiled by C compiler. We can write similar code in Cython as in default python or CPython, the differences are :
- Cython allows us to write optional additional C code and,
- In Cython, our python code gets translated into C code internally so that it can get compiled by C compiler. Although Cython results in considerably faster execution, but falls short of original C language execution. This is because Cython has to make calls to the CPython interpreter and CPython standard libraries to understand the written CPython code
JPython / Jython
Java implementation of python programming language. It is written in Java and python. Here our python code first gets compiled to Java bytecode and then that bytecode gets interpreted to platform-specific operations by JVM or Java Virtual Machine. This is similar to how Java code gets executed : Java code first gets compiled to intermediate bytecode then that bytecode gets interpreted to platform-specific operations by JVM
RPython implementation of python programming language. It is written in a restricted subset of python called Restricted Python (RPython). PyPy runs faster than CPython because to interpret bytecode, PyPy has a Just-in-time Compiler (Interpreter + Compiler) while CPython has an Interpreter. So JIT Compiler in PyPy can execute Python bytecode line-by-line like an Interpreter to reduce start up time, but if encounters with a hot section with repeatedly executed line of code then optimizes that code using
Baseline or Optimizing Compiler.
JIT Compiler in a Nutshell: Compiler in Python translates our high level source code into bytecode and to execute bytecode, some implementations have normal Interpreter, some have Just-in-time Compiler. To execute a loop which runs say, million times i.e. a very hot code, initially Interpreter will run it for some time and
Monitor of JIT Compiler will watch that code. Then when it gets repeated some times i.e. the code becomes warm* then JIT compiler will send that code to
Baseline Compiler which will make some assumptions on variable types etc. based on data gathered by
Monitor while watching the code. From next iterations if assumptions turn out to be valid, then no need to retranslate bytecode into machine code, i.e. steps can be skipped for faster execution. If the code repeats a lot of times i.e. code becomes very hot then JIT compiler will send that code to
Optimizing Compiler which will make more assumptions and will skip more steps for very fast execution.
JIT Compiler Drawbacks: initial slower execution when the code gets analysed, and if assumptions turn out to be false then optimized compiled code gets thrown out i.e.
Bailing out happens which can make code execution slower, although JIT compilers has limit for optimization/deoptimization cycle. After certain number of deoptimization happens, JIT Compiler just does not try to optimize anymore. Whereas normal Interpreter, in each iteration, repeatedly translates bytecode into machine code thereby taking more time to complete a loop which runs say, million times
C# implementation of python, targeting the .NET framework
works with Ruby platform
Distribution of python and R programming languages for scientific computing like, data science, machine learning, artificial intelligence, deep learning, handling large volume of data etc. Numerous number of libraries like, scikit-learn, tensorflow, pytorch, numba, pandas, jupyter, numpy, matplotlib etc. are available with this package
Python for Concurrency
To test speed of each implementation, we write a program to call integrate_f 500 times using an N value of 50,000, and record the execution time over several runs. Below table shows the benchmark results :
||Execution Time (seconds)
|CPython + Cython