You're reading from Hands-On Design Patterns with C++ Solve common C++ problems with modern design patterns and build robust applications

Product type Paperback

Published in Jul 2023

Publisher Packt

ISBN-13 9781804611555

Length 626 pages

Edition 2nd Edition

Languages

C++

Concepts

Design Patterns

Author (1):

Fedor G. Pikus

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Table of Contents (26) Chapters

Preface

1. Part 1: Getting Started with C++ Features and Concepts

2. Chapter 1: An Introduction to Inheritance and Polymorphism FREE CHAPTER

3. Chapter 2: Class and Function Templates

4. Chapter 3: Memory and Ownership

5. Part 2: Common C++ Idioms

6. Chapter 4: Swap – from Simple to Subtle

7. Chapter 5: A Comprehensive Look at RAII

8. Chapter 6: Understanding Type Erasure

9. Chapter 7: SFINAE, Concepts, and Overload Resolution Management

10. Part 3: C++ Design Patterns

11. Chapter 8: The Curiously Recurring Template Pattern

12. Chapter 9: Named Arguments, Method Chaining, and the Builder Pattern

13. Chapter 10: Local Buffer Optimization

14. Chapter 11: ScopeGuard

15. Chapter 12: Friend Factory

16. Chapter 13: Virtual Constructors and Factories

17. Chapter 14: The Template Method Pattern and the Non-Virtual Idiom

18. Part 4: Advanced C++ Design Patterns

19. Chapter 15: Policy-Based Design

20. Chapter 16: Adapters and Decorators

21. Chapter 17: The Visitor Pattern and Multiple Dispatch

22. Chapter 18: Patterns for Concurrency

23. Assessments

24. Index

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Variadic templates

Probably the greatest difference between generic programming in C and C++ is type safety. It is possible to write generic code in C—the standard function qsort() is a perfect example—it can sort values of any type and they are passed in using a void* pointer, which can really be a pointer to any type. Of course, the programmer has to know what the real type is and cast the pointer to the right type. In a generic C++ program, the types are either explicitly specified or deduced at the time of the instantiation, and the type system for generic types is as strong as it is for regular types. Unless we want a function with an unknown number of arguments, that is, prior to C++11, the only way was the old C-style variadic functions where the compiler had no idea what the argument types were; the programmer just had to know and unpack the variable arguments correctly.

C++11 introduced the modern equivalent to a variadic function—a variadic template...