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  • Book Overview & Buying Mastering Embedded Linux Programming
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Mastering Embedded Linux Programming

Mastering Embedded Linux Programming

By : Chris Simmonds
4.8 (20)
Buy this Book
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Mastering Embedded Linux Programming

Mastering Embedded Linux Programming

4.8 (20)
By: Chris Simmonds
Buy this Book

Overview of this book

Mastering Embedded Linux Programming takes you through the product cycle and gives you an in-depth description of the components and options that are available at each stage. You will begin by learning about toolchains, bootloaders, the Linux kernel, and how to configure a root filesystem to create a basic working device. You will then learn how to use the two most commonly used build systems, Buildroot and Yocto, to speed up and simplify the development process. Building on this solid base, the next section considers how to make best use of raw NAND/NOR flash memory and managed flash eMMC chips, including mechanisms for increasing the lifetime of the devices and to perform reliable in-field updates. Next, you need to consider what techniques are best suited to writing applications for your device. We will then see how functions are split between processes and the usage of POSIX threads, which have a big impact on the responsiveness and performance of the final device The closing sections look at the techniques available to developers for profiling and tracing applications and kernel code using perf and ftrace.
Table of Contents (16 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
1. Starting Out
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1. Starting Out
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Selecting the right operating system
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The players
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Project lifecycle
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Open source
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Hardware for embedded Linux
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Hardware used in this book
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Software used in this book
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Summary
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2. Learning About Toolchains
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2. Learning About Toolchains
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What is a toolchain?
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Types of toolchain - native versus cross toolchain
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Choosing the C library
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Finding a toolchain
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Anatomy of a toolchain
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Other tools in the toolchain
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Looking at the components of the C library
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Linking with libraries: static and dynamic linking
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The art of cross compiling
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Problems with cross compiling
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Summary
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3. All About Bootloaders
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3. All About Bootloaders
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What does a bootloader do?
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The boot sequence
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Booting with UEFI firmware
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Moving from bootloader to kernel
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Introducing device trees
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Choosing a bootloader
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U-Boot
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Barebox
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Summary
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4. Porting and Configuring the Kernel
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4. Porting and Configuring the Kernel
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What does the kernel do?
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Choosing a kernel
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Building the kernel
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Compiling
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Cleaning kernel sources
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Booting your kernel
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Porting Linux to a new board
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Additional reading
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Summary
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5. Building a Root Filesystem
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5. Building a Root Filesystem
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What should be in the root filesystem?
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Programs for the root filesystem
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Libraries for the root filesystem
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Device nodes
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The proc and sysfs filesystems
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Kernel modules
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Transfering the root filesystem to the target
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Creating a boot ramdisk
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The init program
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Configuring user accounts
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Starting a daemon process
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A better way of managing device nodes
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Configuring the network
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Creating filesystem images with device tables
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Mounting the root filesystem using NFS
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Using TFTP to load the kernel
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Additional reading
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Summary
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6. Selecting a Build System
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6. Selecting a Build System
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No more rolling your own embedded Linux
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Build systems
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Package formats and package managers
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Buildroot
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The Yocto Project
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Further reading
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Summary
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7. Creating a Storage Strategy
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7. Creating a Storage Strategy
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Storage options
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Accessing flash memory from the bootloader
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Accessing flash memory from Linux
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Filesystems for flash memory
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Filesystems for NOR and NAND flash memory
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Filesystems for managed flash
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Read-only compressed filesystems
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Temporary filesystems
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Making the root filesystem read-only
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Filesystem choices
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Updating in the field
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Further reading
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Summary
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8. Introducing Device Drivers
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8. Introducing Device Drivers
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The role of device drivers
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Character devices
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Block devices
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Network devices
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Finding out about drivers at runtime
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Finding the right device driver
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Device drivers in user-space
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Writing a kernel device driver
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Loading kernel modules
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Discovering hardware configuration
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Additional reading
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Summary
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9. Starting up - the init Program
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9. Starting up - the init Program
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After the kernel has booted
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Introducing the init programs
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BusyBox init
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System V init
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systemd
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Further reading
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Summary
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10. Learning About Processes and Threads
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10. Learning About Processes and Threads
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Process or thread?
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Processes
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Threads
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Scheduling
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Further reading
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Summary
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11. Managing Memory
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11. Managing Memory
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Virtual memory basics
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Kernel space memory layout
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User space memory layout
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Process memory map
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Swap
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Mapping memory with mmap
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How much memory does my application use?
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Per-process memory usage
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Identifying memory leaks
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Running out of memory
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Further reading
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Summary
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12. Debugging with GDB
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12. Debugging with GDB
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The GNU debugger
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Preparing to debug
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Debugging applications using GDB
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Remote debugging using gdbserver
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Starting to debug
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Debugging shared libraries
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Just-in-time debugging
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Debugging forks and threads
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Core files
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GDB user interfaces
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Debugging kernel code
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Additional reading
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Summary
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13. Profiling and Tracing
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13. Profiling and Tracing
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The observer effect
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Beginning to profile
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Profiling with top
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Introducing perf
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Other profilers: OProfile and gprof
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Tracing events
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Introducing Ftrace
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Using LTTng
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Using Valgrind for application profiling
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Callgrind
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Helgrind
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Using strace to show system calls
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Summary
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14. Real-time Programming
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14. Real-time Programming
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What is real-time?
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Identifying the sources of non-determinism
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Understanding scheduling latency
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Kernel preemption
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The real-time Linux kernel (PREEMPT_RT)
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Threaded interrupt handlers
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Preemptible kernel locks
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Getting the PREEMPT_RT patches
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High resolution timers
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Avoiding page faults in a real-time application
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Interrupt shielding
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Measuring scheduling latencies
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Further reading
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Summary
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Index
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Index

The role of device drivers

As mentioned in Chapter 4, Porting and Configuring the Kernel, one of the functions of the kernel is to encapsulate the many hardware interfaces of a computer system and present them in a consistent manner to user-space programs. There are frameworks designed to make it easy to write the interface logic for a device in the kernel and you can integrate it with the kernel: this is a device driver, the piece of code that mediates between the kernel above it and the hardware below. A device driver is a piece of software that controls physical devices such as a UART or an MMC controller, or virtual devices such as the null device (/dev/null) or a ramdisk. One driver may control multiple devices of the same kind.

Kernel device driver code runs at a high privilege level, as does the rest of the kernel. It has full access to the processor address space and hardware registers. It can handle interrupts and DMA transfers. It can make use of the sophisticated kernel infrastructure...

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