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Hands-On Embedded Programming with C++17

By : Maya Posch

2.5 (6)

Hands-On Embedded Programming with C++17

2.5 (6)

By: Maya Posch

Overview of this book

C++ is a great choice for embedded development, most notably, because it does not add any bloat, extends maintainability, and offers many advantages over different programming languages. Hands-On Embedded Programming with C++17 will show you how C++ can be used to build robust and concurrent systems that leverage the available hardware resources. Starting with a primer on embedded programming and the latest features of C++17, the book takes you through various facets of good programming. You’ll learn how to use the concurrency, memory management, and functional programming features of C++ to build embedded systems. You will understand how to integrate your systems with external peripherals and efficient ways of working with drivers. This book will also guide you in testing and optimizing code for better performance and implementing useful design patterns. As an additional benefit, you will see how to work with Qt, the popular GUI library used for building embedded systems. By the end of the book, you will have gained the confidence to use C++ for embedded programming.

Preface

Preface

Who this book is for

What this book covers

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Section 1: The Fundamentals - Embedded programming and the role of C++

Section 1: The Fundamentals - Embedded programming and the role of C++

What Are Embedded Systems?

What Are Embedded Systems?

The many faces of embedded systems

Microcontrollers

System-on-Chip/Single Board Computer

Summary

C++ as an Embedded Language

C++ as an Embedded Language

C++ relative to C

C++ as an embedded language

C++ language features

The standard template library

Maintainability

Summary

Developing for Embedded Linux and Similar Systems

Developing for Embedded Linux and Similar Systems

Embedded operating systems

Real-time OSes

Custom peripherals and drivers

Resource limitations

Example – club room monitoring

Example – basic media player

Summary

Resource-Restricted Embedded Systems

Resource-Restricted Embedded Systems

The big picture for small systems

Embedded IDEs and frameworks

Programming MCUs

Memory management

Concurrency

AVR development with Nodate

ESP8266 development with Sming

ARM MCU development

RTOS usage

Summary

Example - Soil Humidity Monitor with Wi-Fi

Example - Soil Humidity Monitor with Wi-Fi

Keeping plants happy

Our solution

The hardware

The firmware

Taking it further

Complications

Summary

Section 2: Testing, Monitoring

Section 2: Testing, Monitoring

Testing OS-Based Applications

Testing OS-Based Applications

Avoiding real hardware

Cross-compiling for SBCs

Integration test for club status service

Testing with Valgrind

Multi-target build system

Remote testing on real hardware

Summary

Testing Resource-Restricted Platforms

Testing Resource-Restricted Platforms

Reducing wear

Planning out a design

Platform-independent build systems

Using cross-compilers

Local and on-chip debugging

Example – ESP8266 integration test

Summary

Example - Linux-Based Infotainment System

Example - Linux-Based Infotainment System

One box that does everything

Hardware needed

Software requirements

Bluetooth audio sources and sinks

Online streaming

Voice-driven user interface

Usage scenarios

Source code

Building the project

Extending the system

Summary

Example - Building Monitoring and Control

Example - Building Monitoring and Control

Plants, rooms, and beyond

Developmental history

Functional modules

Firmware source

Command and control server

Administration tool

Air-conditioning service

InfluxDB for recording sensor readings

Security aspects

Future developments

Summary

Section 3: Integration with other tools and frameworks

Section 3: Integration with other tools and frameworks

Developing Embedded Systems with Qt

Developing Embedded Systems with Qt

The power of the right framework

Qt for command-line use

GUI-based Qt applications

Embedded Qt

Custom GUIs with stylesheets

QML

3D designer

An example of adding a GUI to the infotainment system

Summary

Developing for Hybrid SoC/FPGA Systems

Developing for Hybrid SoC/FPGA Systems

Going extremely parallel

Hardware description languages

FPGA architecture

Hybrid FPGA/SoC chips

Example – basic oscilloscope

Building the project

Summary

Best Practices

Best Practices

All the best-laid plans

Working with the hardware

The confusing world of peripherals

Knowing your tools

Choosing asynchronous methods

Reading the datasheet

Keeping interrupt handlers short

8-bit means 8 bits

Don't reinvent the wheel

Think before you optimize

Requirements are not optional

Documentation saves lives

Testing code means trying to destroy it

Summary

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Custom peripherals and drivers

A peripheral is defined as an ancillary device that adds I/O or other functionality to a computer system. This can be anything from an I2C, SPI, or SD card controller to an audio or graphics device. Most of those are part of the physical SoC, with others added via interfaces that the SoC exposes to the outside world. Examples of external peripherals would be RAM (via the RAM controller) and a real-time clock (RTC).

One issue that one will likely encounter when using cheaper SBCs such as the Raspberry Pi, Orange Pi, and countless similar systems is that they usually lack an RTC, meaning that when they are powered off, they no longer keep track of the time. The thought behind this is usually that those boards will be connected to the internet anyway, so the OS can use an online time service (Network Time Protocol, or NTP) to synchronize the system...

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