GPU-Accelerated Computing with Python 3 and CUDA: From low-level kernels to real-world applications in scientific computing and machine learning - Softcover

Niels Cautaerts; Hossein Ghorbanfekr

 
9781803245423: GPU-Accelerated Computing with Python 3 and CUDA: From low-level kernels to real-world applications in scientific computing and machine learning
Softcover
ISBN 10: 1803245425 ISBN 13: 9781803245423
Publisher: Packt Publishing, 2026

Synopsis

Accelerate your Python code on the GPU using CUDA, Numba, and modern libraries to solve real-world problems faster and more efficiently.

Key Features

  • Build a solid foundation in CUDA with Python, from kernel design to execution and debugging
  • Optimize GPU performance with efficient memory access, CUDA streams, and multi-GPU scaling
  • Use JAX, CuPy, RAPIDS, and Numba to accelerate numerical computing and machine learning
  • Create practical GPU applications, from PDE solvers to image processing and transformers

Book Description

Writing high-performance Python code doesn’t have to mean switching to C++. This book shows you how to accelerate Python applications using NVIDIA’s CUDA platform and a modern ecosystem of Python tools and libraries. Aimed at researchers, engineers, and data scientists, it offers a practical yet deep understanding of GPU programming and how to fully exploit modern GPU hardware.

You’ll begin with the fundamentals of CUDA programming in Python using Numba-CUDA, learning how GPUs work and how to write, execute, and debug custom GPU kernels. Building on this foundation, the book explores memory access optimization, asynchronous execution with CUDA streams, and multi-GPU scaling using Dask-CUDA. Performance analysis and tuning are emphasized throughout, using NVIDIA Nsight profilers.

You’ll also learn to use high-level GPU libraries such as JAX, CuPy, and RAPIDS to accelerate numerical Python workflows with minimal code changes. These techniques are applied to real-world examples, including PDE solvers, image processing, physical simulations, and transformer models.

Written by experienced GPU practitioners, this hands-on guide emphasizes reproducible workflows using Python 3.10+, CUDA 12.3+, and tools like the Pixi package manager. By the end, you’ll have future-ready skills for building scalable GPU applications in Python.

What you will learn

  • Understand GPU execution, parallelism, and the CUDA programming model
  • Write, launch, and debug custom CUDA kernels in Python with CUDA
  • Profile GPU code with NVIDIA Nsight and optimize memory access
  • Use CUDA streams and async execution to overlap compute and transfers
  • Apply JAX, CuPy, and RAPIDS to numerical computing and machine learning
  • Scale GPU workloads across devices using Dask and multi-GPU strategies
  • Accelerate PDE solvers, simulations, and image processing on the GPU
  • Build, train, and run a transformer model from scratch on the GPU

Who this book is for

Python developers, (data) scientists, engineers, and researchers looking to accelerate numerical computations without switching to low-level languages. This book is ideal for those with experience in scientific Python (NumPy, Pandas, SciPy) and a basic understanding of computing fundamentals who want deeper control over performance in GPU environments.

Table of Contents

  1. Why GPU Programming with CUDA in Python 3?
  2. Setting Up a GPU Programming Environment Locally and in the Cloud
  3. Writing and Executing CUDA Kernels with Numba-CUDA
  4. Profiling and Debugging CUDA Code
  5. Optimizing the Performance of CUDA Code
  6. Enabling Concurrency Using CUDA Streams
  7. Scaling to Multiple GPUs
  8. Bringing NumPy and SciPy to the GPU with CuPy
  9. Bringing pandas and scikit-learn to the GPU with Rapids
  10. Solving Optimization Problems on the GPU with JAX
  11. Solving the Heat Equation on the GPU
  12. Image Processing and Computer Vision on the GPU
  13. Simulating Atomic Interactions on the GPU
  14. Implementing Your Own Transformer-Based Language Model
  15. Expanding and Deepening Your GPU Programming Knowledge

"synopsis" may belong to another edition of this title.

About the Author

Dr. Niels Cautaerts has 10 years of experience writing Python for scientific applications. Five years ago he became interested to leverage hardware acceleration in his code. Soon after, he began contributing CUDA kernels to open source projects in his field of research. He has since applied his expertise to build GPU accelerated code in various projects, including a low latency framework for object detection in continuous image streams. Niels maintains a small following on YouTube and Medium, where he shares educational content about tech. Currently Niels works as a research software developer and data scientist. He has also worked as a big-data engineer. Niels has a background in materials science and holds a Ph.D. in applied Physics.

Hossein Ghorbanfekr is a computational physicist with over a decade of expertise in scientific programming for material modeling, specializing in C/C++ and Python. During his Ph.D., he wrote various codes, utilizing parallel computing and GPU acceleration. Since 2020, he has been working as a data scientist, focusing on machine learning and high-performance computing in research projects. Hossein has contributed to the development of an object detection framework for waste stream analysis and created GEOBERTje, a domain-specific large language model in geology. His recent work includes Pantea, an open-source, GPU-accelerated machine learning framework for molecular simulations.

"About this title" may belong to another edition of this title.

Publisher
Packt Publishing
Publication date
2026
Language
English
ISBN 10 
1803245425
ISBN 13 
9781803245423
Binding
Paperback
Number of pages
534