Python High Performance, Second Edition

By : Dr. Gabriele Lanaro

4 (2)

Buy this Book

Python High Performance, Second Edition

4 (2)

By: Dr. Gabriele Lanaro

Buy this Book

Overview of this book

Python is a versatile language that has found applications in many industries. The clean syntax, rich standard library, and vast selection of third-party libraries make Python a wildly popular language. Python High Performance is a practical guide that shows how to leverage the power of both native and third-party Python libraries to build robust applications. The book explains how to use various profilers to find performance bottlenecks and apply the correct algorithm to fix them. The reader will learn how to effectively use NumPy and Cython to speed up numerical code. The book explains concepts of concurrent programming and how to implement robust and responsive applications using Reactive programming. Readers will learn how to write code for parallel architectures using Tensorflow and Theano, and use a cluster of computers for large-scale computations using technologies such as Dask and PySpark. By the end of the book, readers will have learned to achieve performance and scale from their Python applications.

Preface

What this book covers

What you need for this book

Who this book is for

Conventions

Reader feedback

Customer support

Free Chapter

Benchmarking and Profiling

Designing your application

Writing tests and benchmarks

Better tests and benchmarks with pytest-benchmark

Finding bottlenecks with cProfile

Profile line by line with line_profiler

Optimizing our code

The dis module

Profiling memory usage with memory_profiler

Summary

Pure Python Optimizations

Useful algorithms and data structures

Caching and memoization

Comprehensions and generators

Summary

Fast Array Operations with NumPy and Pandas

Getting started with NumPy

Rewriting the particle simulator in NumPy

Reaching optimal performance with numexpr

Pandas

Summary

C Performance with Cython

Compiling Cython extensions

Adding static types

Sharing declarations

Working with arrays

Particle simulator in Cython

Profiling Cython

Using Cython with Jupyter

Summary

Exploring Compilers

Numba

The PyPy project

Other interesting projects

Summary

Implementing Concurrency

Asynchronous programming

The asyncio framework

Reactive programming

Summary

Parallel Processing

Introduction to parallel programming

Using multiple processes

Parallel Cython with OpenMP

Automatic parallelism

Summary

Distributed Processing

Introduction to distributed computing

Dask

Using PySpark

Scientific computing with mpi4py

Summary

Designing for High Performance

Choosing a suitable strategy

Organizing your source code

Isolation, virtual environments, and containers

Continuous integration

Summary

Customer Reviews

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Rewriting the particle simulator in NumPy

In this section, we will optimize our particle simulator by rewriting some parts of it in NumPy. We found, from the profiling we did in Chapter 1, Benchmarking and Profiling, that the slowest part of our program is the following loop contained in the ParticleSimulator.evolve method:

    for i in range(nsteps): 
      for p in self.particles: 

        norm = (p.x**2 + p.y**2)**0.5 
        v_x = (-p.y)/norm 
        v_y = p.x/norm 

        d_x = timestep * p.ang_vel * v_x 
        d_y = timestep * p.ang_vel * v_y 

        p.x += d_x 
        p.y += d_y

You may have noticed that the body of the loop acts solely on the current particle. If we had an array containing the particle positions and angular speed, we could rewrite the loop using a broadcasted operation. In contrast, the loop's steps depend on the previous step and cannot be parallelized in this way.

It is natural then...