Book Image

Linux Kernel Programming

By : Kaiwan N. Billimoria
Book Image

Linux Kernel Programming

By: Kaiwan N. Billimoria

Overview of this book

Linux Kernel Programming is a comprehensive introduction for those new to Linux kernel and module development. This easy-to-follow guide will have you up and running with writing kernel code in next-to-no time. This book uses the latest 5.4 Long-Term Support (LTS) Linux kernel, which will be maintained from November 2019 through to December 2025. By working with the 5.4 LTS kernel throughout the book, you can be confident that your knowledge will continue to be valid for years to come. You’ll start the journey by learning how to build the kernel from the source. Next, you’ll write your first kernel module using the powerful Loadable Kernel Module (LKM) framework. The following chapters will cover key kernel internals topics including Linux kernel architecture, memory management, and CPU scheduling. During the course of this book, you’ll delve into the fairly complex topic of concurrency within the kernel, understand the issues it can cause, and learn how they can be addressed with various locking technologies (mutexes, spinlocks, atomic, and refcount operators). You’ll also benefit from more advanced material on cache effects, a primer on lock-free techniques within the kernel, deadlock avoidance (with lockdep), and kernel lock debugging techniques. By the end of this kernel book, you’ll have a detailed understanding of the fundamentals of writing Linux kernel module code for real-world projects and products.
Table of Contents (19 chapters)
1
Section 1: The Basics
6
Writing Your First Kernel Module - LKMs Part 2
7
Section 2: Understanding and Working with the Kernel
10
Kernel Memory Allocation for Module Authors - Part 1
11
Kernel Memory Allocation for Module Authors - Part 2
14
Section 3: Delving Deeper
17
About Packt

Test sleep in an atomic context

You have already learned that the one thing we should not do is sleep (block) in any kind of atomic or interrupt context. Let's put this to the test. As always, the empirical approach where you test things for yourself rather than relying on other's experiences is key!

How exactly can we test this? Easy: we shall use a simple integer module parameter, buggy, that, when set to 1 (the default value being 0), executes a code path within our spinlock's critical section that violates this rule. We shall invoke the schedule_timeout() API (which, as you learned in Chapter 15, Timers, Kernel Threads, and More, in the Understanding how to use the *sleep() blocking APIs section) internally invokes schedule(); it's how we go to sleep in the kernel space). Here's the relevant code:

// ch12/2_miscdrv_rdwr_spinlock/2_miscdrv_rdwr_spinlock.c
[ ... ]
static int buggy;
module_param(buggy...