You're reading from Linux Device Driver Development - Second Edition

Product type Book

Published in Apr 2022

Publisher Packt

ISBN-13 9781803240060

Pages 708 pages

Edition 2nd Edition

Languages

Concepts

Embedded Systems

Author (1):

John Madieu

Table of Contents (23) Chapters

Preface

1. Section 1 -Linux Kernel Development Basics

2. Chapter 1: Introduction to Kernel Development

3. Chapter 2: Understanding Linux Kernel Module Basic Concepts

4. Chapter 3: Dealing with Kernel Core Helpers

5. Chapter 4: Writing Character Device Drivers

6. Section 2 - Linux Kernel Platform Abstraction and Device Drivers

7. Chapter 5: Understanding and Leveraging the Device Tree

8. Chapter 6: Introduction to Devices, Drivers, and Platform Abstraction

9. Chapter 7: Understanding the Concept of Platform Devices and Drivers

10. Chapter 8: Writing I2C Device Drivers

11. Chapter 9: Writing SPI Device Drivers

12. Section 3 - Making the Most out of Your Hardware

13. Chapter 10: Understanding the Linux Kernel Memory Allocation

14. Chapter 11: Implementing Direct Memory Access (DMA) Support

15. Chapter 12: Abstracting Memory Access – Introduction to the Regmap API: a Register Map Abstraction

16. Chapter 13: Demystifying the Kernel IRQ Framework

17. Chapter 14: Introduction to the Linux Device Model

18. Section 4 - Misc Kernel Subsystems for the Embedded World

19. Chapter 15: Digging into the IIO Framework

20. Chapter 16: Getting the Most Out of the Pin Controller and GPIO Subsystems

21. Chapter 17: Leveraging the Linux Kernel Input Subsystem

22. Other Books You May Enjoy

Dealing with the SPI driver abstraction and architecture

This is where the driver logic takes place. It consists of filling struct spi_driver with a set of driving functions that allow probing and controlling the underlying device.

Probing the device

The SPI device is probed by the spi_driver.probe callback. The probe callback is responsible for making sure the driver recognizes the given device before they can be bound together. This callback has the following prototype:

int probe(struct spi_device *spi)

This method must return 0 on success, or a negative error number otherwise. The only argument is the SPI device to be probed, whose structure has been pre-initialized by the core according to its description in the device tree.

However, most (if not all) of the properties of the SPI device can be overridden, as we have seen while describing its data structure. SPI protocol drivers may need to update the transfer mode if the device doesn't work with its default...