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  • Book Overview & Buying Mastering Linux Kernel Development
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Mastering Linux Kernel Development

Mastering Linux Kernel Development

By : CH Raghav Maruthi
2.9 (10)
Buy this Book
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Mastering Linux Kernel Development

Mastering Linux Kernel Development

2.9 (10)
By: CH Raghav Maruthi
Buy this Book

Overview of this book

Mastering Linux Kernel Development looks at the Linux kernel, its internal arrangement and design, and various core subsystems, helping you to gain significant understanding of this open source marvel. You will look at how the Linux kernel, which possesses a kind of collective intelligence thanks to its scores of contributors, remains so elegant owing to its great design. This book also looks at all the key kernel code, core data structures, functions, and macros, giving you a comprehensive foundation of the implementation details of the kernel’s core services and mechanisms. You will also look at the Linux kernel as well-designed software, which gives us insights into software design in general that are easily scalable yet fundamentally strong and safe. By the end of this book, you will have considerable understanding of and appreciation for the Linux kernel.
Table of Contents (12 chapters)
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Preface
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Preface
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What this book covers
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What you need for this book
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Who this book is for
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Conventions
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Reader feedback
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Customer support
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1
Comprehending Processes, Address Space, and Threads
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Comprehending Processes, Address Space, and Threads
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Processes
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Process descriptors
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Kernel stack
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The issue of stack overflow
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Process creation
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Kernel threads
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Process status and termination
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Namespaces and cgroups
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Summary
2
Deciphering the Process Scheduler
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Deciphering the Process Scheduler
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Process schedulers
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Linux process scheduler design
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Runqueue
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The scheduler's entry point
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Process priorities
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Scheduler classes
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Completely Fair Scheduling class (CFS)
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Real-time scheduling class
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Scheduler related system calls
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Process preemption
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Summary
3
Signal Management
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Signal Management
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Signals
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Signal-management APIs
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Signal data structures
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Signal generation and delivery
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Restarting interrupted system calls
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Summary
4
Memory Management and Allocators
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Memory Management and Allocators
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Initialization operations
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Zones and nodes
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Memory allocators
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Summary
5
Filesystems and File I/O
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Filesystems and File I/O
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Filesystem - high-level view
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Filesystems in the Linux kernel
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Common filesystem interface
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Special filesystems
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Summary
6
Interprocess Communication
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Interprocess Communication
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Pipes and FIFOs
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Message queues
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Shared memory
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Semaphores
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Summary
7
Virtual Memory Management
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Virtual Memory Management
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Process address space
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Summary
8
Kernel Synchronization and Locking
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Kernel Synchronization and Locking
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Atomic operations
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Introducing exclusion locks
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Summary
9
Interrupts and Deferred Work
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Interrupts and Deferred Work
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Interrupt signals and vectors
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Programmable interrupt controller
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High-level interrupt-management interfaces
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Deferred work
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Summary
10
Clock and Time Management
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Clock and Time Management
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Time representation
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Hardware abstraction
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Linux timekeeping data structures, macros, and helper routines
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Software timers and delay functions
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POSIX clocks
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Summary
11
Module Management
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Module Management
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Kernel modules
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Summary

Process address space

The following diagram depicts the layout of a typical process address space in Linux systems, which is composed of a set of virtual memory segments:

Each segment is physically mapped to one or more linear memory blocks (made out of one or more pages), and appropriate address translation records are placed in a process page table. Before we get into the complete details of how the kernel manages memory maps and constructs page tables, let's understand in brief each segment of the address space:

  • Stack is the topmost segment, which expands downward. It contains stack frames that hold local variables and function parameters; a new frame is created on top of the stack upon entry into a called function, and is destroyed when the current function returns. Depending on the level of nesting of the function calls, there is always a need for the stack segment to dynamically expand to accommodate new frames. Such expansion is handled by the virtual memory manager through page faults...
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Tech Concepts
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Programming languages
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Mastering Linux Kernel Development
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