Book Image

Modern C++ Programming Cookbook

By : Marius Bancila
Book Image

Modern C++ Programming Cookbook

By: Marius Bancila

Overview of this book

C++ is one of the most widely used programming languages. Fast, efficient, and flexible, it is used to solve many problems. The latest versions of C++ have seen programmers change the way they code, giving up on the old-fashioned C-style programming and adopting modern C++ instead. Beginning with the modern language features, each recipe addresses a specific problem, with a discussion that explains the solution and offers insight into how it works. You will learn major concepts about the core programming language as well as common tasks faced while building a wide variety of software. You will learn about concepts such as concurrency, performance, meta-programming, lambda expressions, regular expressions, testing, and many more in the form of recipes. These recipes will ensure you can make your applications robust and fast. By the end of the book, you will understand the newer aspects of C++11/14/17 and will be able to overcome tasks that are time-consuming or would break your stride while developing.

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Table of Contents (19 chapters)
Title Page
Title Page
Credits
Credits
About the Author
About the Author
About the Reviewer
About the Reviewer
www.PacktPub.com
www.PacktPub.com
Customer Feedback
Customer Feedback
Preface
Preface
Free Chapter
1
Learning Modern Core Language Features
Learning Modern Core Language Features
Introduction
Using auto whenever possible
Creating type aliases and alias templates
Understanding uniform initialization
Understanding the various forms of non-static member initialization
Controlling and querying object alignment
Using scoped enumerations
Using override and final for virtual methods
Using range-based for loops to iterate on a range
Enabling range-based for loops for custom types
Using explicit constructors and conversion operators to avoid implicit conversion
Using unnamed namespaces instead of static globals
Using inline namespaces for symbol versioning
Using structured bindings to handle multi-return values
2
Working with Numbers and Strings
Working with Numbers and Strings
Introduction
Converting between numeric and string types
Limits and other properties of numeric types
Generating pseudo-random numbers
Initializing all bits of internal state of a pseudo-random number generator
Creating cooked user-defined literals
Creating raw user-defined literals
Using raw string literals to avoid escaping characters
Creating a library of string helpers
Verifying the format of a string using regular expressions
Parsing the content of a string using regular expressions
Replacing the content of a string using regular expressions
Using string_view instead of constant string references
3
Exploring Functions
Exploring Functions
Introduction
Defaulted and deleted functions
Using lambdas with standard algorithms
Using generic lambdas
Writing a recursive lambda
Writing a function template with a variable number of arguments
Using fold expressions to simplify variadic function templates
Implementing higher-order functions map and fold
Composing functions into a higher-order function
Uniformly invoking anything callable
4
Preprocessor and Compilation
Preprocessor and Compilation
Introduction
Conditionally compiling your source code
Using the indirection pattern for preprocessor stringification and concatenation
Performing compile-time assertion checks with static_assert
Conditionally compiling classes and functions with enable_if
Selecting branches at compile time with constexpr if
Providing metadata to the compiler with attributes
5
Standard Library Containers, Algorithms, and Iterators
Standard Library Containers, Algorithms, and Iterators
Introduction
Using vector as a default container
Using bitset for fixed-size sequences of bits
Using vector<bool> for variable-size sequences of bits
Finding elements in a range
Sorting a range
Initializing a range
Using set operations on a range
Using iterators to insert new elements in a container
Writing your own random access iterator
Container access with non-member functions
6
General Purpose Utilities
General Purpose Utilities
Introduction
Expressing time intervals with chrono::duration
Measuring function execution time with a standard clock
Generating hash values for custom types
Using std::any to store any value
Using std::optional to store optional values
Using std::variant as a type-safe union
Visiting a std::variant
Registering a function to be called when a program exits normally
Using type traits to query properties of types
Writing your own type traits
Using std::conditional to choose between types
7
Working with Files and Streams
Working with Files and Streams
Introduction
Reading and writing raw data from/to binary files
Reading and writing objects from/to binary files
Using localized settings for streams
Using I/O manipulators to control the output of a stream
Using monetary I/O manipulators
Using time I/O manipulators
Working with filesystem paths
Creating, copying, and deleting files and directories
Removing content from a file
Checking the properties of an existing file or directory
Enumerating the content of a directory
Finding a file
8
Leveraging Threading and Concurrency
Leveraging Threading and Concurrency
Introduction
Working with threads
Handling exceptions from thread functions
Synchronizing access to shared data with mutexes and locks
Avoiding using recursive mutexes
Sending notifications between threads
Using promises and futures to return values from threads
Executing functions asynchronously
Using atomic types
Implementing parallel map and fold with threads
Implementing parallel map and fold with tasks
9
Robustness and Performance
Robustness and Performance
Introduction
Using exceptions for error handling
Using noexcept for functions that do not throw
Ensuring constant correctness for a program
Creating compile-time constant expressions
Performing correct type casts
Using unique_ptr to uniquely own a memory resource
Using shared_ptr to share a memory resource
Implementing move semantics
10
Implementing Patterns and Idioms
Implementing Patterns and Idioms
Introduction
Avoiding repetitive if...else statements in factory patterns
Implementing the pimpl idiom
Implementing the named parameter idiom
Separating interfaces and implementations with the non-virtual interface idiom
Handling friendship with the attorney-client idiom
Static polymorphism with the curiously recurring template pattern
Implementing a thread-safe singleton
11
Exploring Testing Frameworks
Exploring Testing Frameworks
Introduction
Getting started with Boost.Test
Writing and invoking tests with Boost.Test
Asserting with Boost.Test
Using fixtures in Boost.Test
Controlling outputs with Boost.Test
Getting started with Google Test
Writing and invoking tests with Google Test
Asserting with Google Test
Using text fixtures with Google Test
Controlling output with Google Test
Getting started with Catch
Writing and invoking tests with Catch
Asserting with Catch
Controlling output with Catch
Bibliography
Bibliography
Websites
Articles and books

Using exceptions for error handling

Exceptions are responses to exceptional circumstances that can appear when a program is running. They enable the transfer of the control flow to another part of the program. Exceptions are a mechanism for simpler and more robust error handling, as opposed to returning error codes that could greatly complicate and clutter the code. In this recipe, we will look at some key aspects related to throwing and handling exceptions.

Getting ready

I assume you have basic knowledge of the mechanism of throwing and catching exceptions.

How to do it...

Use the following practices to deal with exceptions:

  • Throw exceptions by value:
        void throwing_func()
        {
          throw std::system_error(
            std::make_error_code(std::errc::timed_out));
        }
  • Catch exceptions by reference, or in most cases, by constant reference:
        try
        {
          throwing_func();
        }
        catch (std::exception const & e)
        {
          std::cout &lt...
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