深入理解Linux核心(2019年東南大學出版社出版的圖書)

　　為了透徹理解Linux的工作機理，以及為何它在各種系統上能順暢運行，你需要深入到核心的心臟。cPu與外部世界的所有互動活動都是由核心處理的，哪些程式會分享處理器的時間，以什麼樣的順序來分享。核心不遺餘力地管理有限的記憶體，以使數以千計的進程有效地共享系統資源。核心還精心組織數據傳送，使得cPu不再受限於慢速硬碟。《深入理解LINUX核心（影印版 第3版 涵蓋2.6版 英文版）》將領你暢遊核心中用到的主要數據結構、算法和編程技巧。如果你的確想了解計算機內部的實現機理，那么作者透過現象探尋本質，提供了頗有價值的深入分析。《深入理解LINUX核心（影印版 第3版 涵蓋2.6版 英文版）》針對具體的Intel平台，討論了其重要特徵，逐行剖析了相關的代碼片段。但是，《深入理解LINUX核心（影印版 第3版 涵蓋2.6版 英文版）》涵蓋的內容不僅僅局限於代碼的機理，還解釋了Linux運作方式的理論支撐。

Preface

1． Introduction

Linux Versus Other Unix-Like Kernels

Hardware Dependency

Linux Versions

Basic Operating System Concepts

An Overview of the Unix Filesystem

An Overview of Unix Kernels

2． Memory Addressing

Memory Addresses

Segmentation in Hardware

Segmentation in Linux

Paging in Hardware

Paging in Linux

3． Processes

Processes， Lightweight Processes， and Threads

Process Descriptor

Process Switch

Creating Processes

Destroying Processes

4． Interrupts and Exceptions

The Role of Interrupt Signals

Interrupts and Exceptions

Nested Execution of Exception and Interrupt Handlers

Initializing the Interrupt Descriptor Table

Exception Handling

Interrupt Handling

Softirqs and Tasklets

Work Queues

Returning from Interrupts and Exceptions

5． Kernel Synchronization

How the Kernel Services Requests

Synchronization Primitives

Synchronizing Accesses to Kernel Data Structures

Examples of Race Condition Prevention

6． Timing Measurements

Clock and Timer Circuits

The Linux Timekeeping Architecture

Updating the Time and Date

Updating System Statistics

Software Timers and Delay Functions

System Calls Related to Timing Measurements

7． Process Scheduling

Scheduling Policy

The Scheduling Algorithm

Data Structures Used by the Scheduler

Functions Used by the Scheduler

Runqueue Balancing in Muhiprocessor Systems

System Calls Related to Scheduling

8． Memory Management

Page Frame Management

Memory Area Management

Noncontiguous Memory Area Management

9． Process Address Space

The Process's Address Space

The Memory Descriptor

Memory Regions

Page Fault Exception Handler

Creating and Deleting a Process Address Space

Managing the Heap

10． System Calls

POSIX APls and System Calls

System Call Handler and Service Routines

Entering and Exiting a System Call

Parameter Passing

Kernel Wrapper Routines

11． Signals

The Role of Signals

Generating a Signal

Delivering a Signal

System Calls Related to Signal Handling

12． The Virtual Filesystem

The Role of the Virtual Filesystem （VFS）

VFS Data Structures

Filesystem Types

Filesystem Handling

Pathname Lookup

Implementations of VFS System Calls

File Locking

13． I/0 Architecture and Device Drivers

I/0 Architecture

The Device Driver Model

Device Files

Device Drivers

Character Device Drivers

14． Block Device Drivers

Block Devices Handling

The Generic Block Layer

The I/0 Scheduler

Block Device Drivers

Opening a Block Device File

15． The Page Cache

The Page Cache

Storing Blocks in the Page Cache

Writing Dirty Pages to Disk

The sync， fsync， and fdatasync System Calls

16． Accessing Files

Reading and Writing a File

Memory Mapping

Direct I/O Transfers

Asynchronous I/O

17． Page Frame Reclaiming

The Page Frame Reclaiming Algorithm

Reverse Mapping

Implementing the PFRA

Swapping

18． The Ext2 and Ext3 Filesystems

General Characteristics of Ext2

Ext2 Disk Data Structures

Ext2 Memory Data Structures

Creating the Ext2 Filesystem

Ext2 Methods

Managing Ext2 Disk Space

The Ext3 Filesystem

19． Process Communication

Pipes

FIFOs

System V IPC

POSIX Message Queues

20． Program Execution

Executable Files

Executable Formats

Execution Domains

The exec Functions

A． System Startup

B． Modules

Bibliography

Source Code Index

Index