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C++ Standard Library
Containers
C standard library

The C++ programming language has support for string handling, mostly implemented in its standard library. The language standard specifies several string types, some inherited from C, some designed to make use of the language's features, such as classes and RAII. The most-used of these is std::string.

Since the initial versions of C++ had only the "low-level" C string handling functionality and conventions, multiple incompatible designs for string handling classes have been designed over the years and are still used instead of std::string, and C++ programmers may need to handle multiple conventions in a single application.

History

The std::string type is the main string datatype in standard C++ since 1998, but it was not always part of C++. From C, C++ inherited the convention of using null-terminated strings that are handled by a pointer to their first element, and a library of functions that manipulate such strings. In modern standard C++, a string literal such as "hello" still denotes a NUL-terminated array of characters.

Using C++ classes to implement a string type offers several benefits of automated memory management and a reduced risk of out-of-bounds accesses, and more intuitive syntax for string comparison and concatenation. Therefore, it was strongly tempting to create such a class. Over the years, C++ application, library and framework developers produced their own, incompatible string representations, such as the one in AT&T's Standard Components library (the first such implementation, 1983) or the CString type in Microsoft's MFC. While std::string standardized strings, legacy applications still commonly contain such custom string types and libraries may expect C-style strings, making it "virtually impossible" to avoid using multiple string types in C++ programs and requiring programmers to decide on the desired string representation ahead of starting a project.

In a 1991 retrospective on the history of C++, its inventor Bjarne Stroustrup called the lack of a standard string type (and some other standard types) in C++ 1.0 the worst mistake he made in its development; "the absence of those led to everybody re-inventing the wheel and to an unnecessary diversity in the most fundamental classes".

Implementation issues

The various vendors' string types have different implementation strategies and performance characteristics. In particular, some string types use a copy-on-write strategy, where an operation such as

string a = "hello!";
string b = a; // Copy constructor

does not actually copy the content of a to b; instead, both strings share their contents and a reference count on the content is incremented. The actual copying is postponed until a mutating operation, such as appending a character to either string, makes the strings' contents differ. Copy-on-write can make major performance changes to code using strings (making some operations much faster and some much slower). Though std::string no longer uses it, many (perhaps most) alternative string libraries still implement copy-on-write strings.

Some string implementations store 16-bit or 32-bit code points instead of bytes, this was intended to facilitate processing of Unicode text. However, it means that conversion to these types from std::string or from arrays of bytes is dependent on the "locale" and can throw exceptions. Any processing advantages of 16-bit code units vanished when the variable-width UTF-16 encoding was introduced (though there are still advantages if you must communicate with a 16-bit API such as Windows). Qt's QString is an example.

Third-party string implementations also differed considerably in the syntax to extract or compare substrings, or to perform searches in the text.

Standard string types

The std::string class is the standard representation for a text string since C++98. The class provides some typical string operations like comparison, concatenation, find and replace, and a function for obtaining substrings. An std::string can be constructed from a C-style string, and a C-style string can also be obtained from one.

The individual units making up the string are of type char, at least (and almost always) 8 bits each. In modern usage these are often not "characters", but parts of a multibyte character encoding such as UTF-8.

The copy-on-write strategy was deliberately allowed by the initial C++ Standard for std::string because it was deemed a useful optimization, and used by nearly all implementations. However, there were mistakes, in particular the operator returned a non-const reference in order to make it easy to port C in-place string manipulations (such code often assumed one byte per character and thus this may not have been a good idea!) This allowed the following code that shows that it must make a copy even though it is almost always used only to examine the string and not modify it:

  std::string original("aaaaaaa");
  std::string string_copy = original; // make a copy
  char* pointer = &string_copy; // some tried to make operator return a "trick" class but this makes it complex
  arbitrary_code_here(); // no optimizations can fix this
  *pointer = 'b'; // if operator did not copy, this would change original unexpectedly

This caused some implementations to abandon copy-on-write. It was also discovered that the overhead in multi-threaded applications due to the locking needed to examine or change the reference count was greater than the overhead of copying small strings on modern processors (especially for strings smaller than the size of a pointer). The optimization was finally disallowed in C++11, with the result that even passing a std::string as an argument to a function, viz.

void print(std::string s) { std::cout << s; }

must be expected to perform a full copy of the string into newly allocated memory. The common idiom to avoid such copying is to pass as a const reference:

void print(const std::string& s) { std::cout << s; }

In C++17 added a new string_view class that is only a pointer and length to read-only data, makes passing arguments far faster than either of the above examples:

void print(std::string_view s) { std::cout << s; }
...
  std::string x = ...;
  print(x); // does not copy x.data()
  print("this is a literal string"); // also does not copy the characters!
...

Example usage

#include <iostream>
#include <iomanip>
#include <string>
int main() {
    std::string foo = "fighters";
    std::string bar = "stool";
    if (foo != bar) std::cout << "The strings are different!\n";
    std::cout << "foo = " << std::quoted(foo)
              << " while bar = " << std::quoted(bar);
}

Related classes

std::string is a typedef for a particular instantiation of the std::basic_string template class. Its definition is found in the <string> header:

using string = std::basic_string<char>;

Thus string provides basic_string functionality for strings having elements of type char. There is a similar class std::wstring, which consists of wchar t, and is most often used to store UTF-16 text on Windows and UTF-32 on most Unix-like platforms. The C++ standard, however, does not impose any interpretation as Unicode code points or code units on these types and does not even guarantee that a wchar_t holds more bits than a char. To resolve some of the incompatibilities resulting from wchar_t's properties, C++11 added two new classes: std::u16string and std::u32string (made up of the new types char16_t and char32_t), which are the given number of bits per code unit on all platforms. C++11 also added new string literals of 16-bit and 32-bit "characters" and syntax for putting Unicode code points into null-terminated (C-style) strings.

A basic_string is guaranteed to be specializable for any type with a char_traits struct to accompany it. As of C++11, only char, wchar_t, char16_t and char32_t specializations are required to be implemented.

A basic_string is also a Standard Library container, and thus the Standard Library algorithms can be applied to the code units in strings.

Critiques

The design of std::string has been held up as an example of monolithic design by Herb Sutter, who reckons that of the 103 member functions on the class in C++98, 71 could have been decoupled without loss of implementation efficiency.

References

  1. ^ Seacord, Robert C. (2013). Secure Coding in C and C++. Addison-Wesley. ISBN 9780132981972.
  2. Oualline, Steve (2003). Practical C++ Programming. O'Reilly.
  3. ^ Stroustrup, Bjarne (1993). A History of C++: 1979–1991 (PDF). Proc. ACM History of Programming Languages Conf.
  4. ^ Solter, Nicholas A.; Kleper, Scott J. (2005). Professional C++. John Wiley & Sons. p. 23. ISBN 9780764589492.
  5. ^ Blanchette, Jasmin; Summerfield, Mark (2008). C++ GUI Programming with Qt4. Pearson Education. ISBN 9780132703000.
  6. "wstring_convert Class". docs.microsoft.com. 3 August 2021. Retrieved 26 December 2021.
  7. ^ Meyers, Scott (2012), Effective STL, Addison-Wesley, pp. 64–65, ISBN 9780132979184
  8. ^ Meredith, Alisdair; Boehm, Hans; Crowl, Lawrence; Dimov, Peter (2008). "Concurrency Modifications to Basic String". ISO/IEC JTC 1/SC 22/WG 21. Retrieved 19 November 2015.
  9. "21334 – Lack of Posix compliant thread safety in STD::basic_string".
  10. Sutter, Herb (1999). "Optimizations That Aren't (In a Multithreaded World)". C/C++ Users Journal. 17 (6).
  11. "std::basic_string_view – cppreference.com". en.cppreference.com. Retrieved 23 June 2016.
  12. "C++ reference for basic_string". Cppreference.com. Retrieved 11 January 2011.
  13. Gillam, Richard (2003). Unicode Demystified: A Practical Programmer's Guide to the Encoding Standard. Addison-Wesley Professional. p. 714. ISBN 9780201700527.
  14. "C++11 Paper N3336". Open Standards. Programming Language C++, Library Working Group. 13 January 2012. Retrieved 2 November 2013.
  15. Stroustrup, Bjarne (2013). The C++ Programming Language. Addison Wesley. p. 179. Archived from the original on 25 November 2015. Retrieved 24 November 2015.
  16. "char_traits – C++ Reference". Retrieved 1 August 2015.
  17. Sutter, Herb. "Monoliths "Unstrung"". gotw.ca. Retrieved 23 November 2015.
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