C++14
C++14 is a version of the ISO/IEC 14882 standard for the programming language C++. It is intended to be a small extension over C++11, featuring mainly bug fixes and small improvements. Its approval was announced on August 18, 2014. C++14 was released on December 15, 2014.
Because earlier C++ standard revisions were noticeably late, the name "C++1y" was sometimes used instead until its approval, similarly to how the C++11 standard used to be termed "C++0x" with the expectation of its release before 2010.
New language features
These are the features added to the core language of C++14.Function [|return type deduction]
C++11 allowed lambda functions to deduce the return type based on the type of the expression given to the return statement. C++14 provides this ability to all functions. It also extends these facilities to lambda functions, allowing return type deduction for functions that are not of the formreturn expression;.In order to induce return type deduction, the function must be declared with
auto as the return type, but without the trailing return type specifier in C++11:auto DeduceReturnType; // Return type to be determined.
If multiple return expressions are used in the function's implementation, then they must all deduce the same type.
Functions that deduce their return types can be forward declared, but they cannot be used until they have been defined. Their definitions must be available to the translation unit that uses them.
Recursion can be used with a function of this type, but the recursive call must happen after at least one return statement in the definition of the function:
auto Correct
auto Wrong
Alternate type deduction on declarationhttp://thbecker.net/articles/auto_and_decltype/section_10.html
In C++11, two methods of type deduction were added.auto was a way to create a variable of the appropriate type, based on a given expression. decltype was a way to compute the type of a given expression. However, decltype and auto deduce types in different ways. In particular, auto always deduces a non-reference type, as though by using std::decay, while auto&& always deduces a reference type. However, decltype can be prodded into deducing a reference or non-reference type, based on the value category of the expression and the nature of the expression it is deducing:int i;
int&& f;
auto x3a = i; // decltype is int
decltype x3d = i; // decltype is int
auto x4a = ; // decltype is int
decltype) x4d = ; // decltype is int&
auto x5a = f; // decltype is int
decltype) x5d = f; // decltype is int&&
C++14 adds the
decltype syntax. This allows auto declarations to use the decltype rules on the given expression.The
decltype syntax can also be used with return type deduction, by using decltype syntax instead of auto for the function's return type deduction.Relaxed constexpr restrictions
introduced the concept of a constexpr-declared function; a function which could be executed at compile time. Their return values could be consumed by operations that require constant expressions, such as an integer template argument. However, C++11 constexpr functions could only contain a single expression that is returned.C++14 relaxes these restrictions. Constexpr-declared functions may now contain the following:
- Any declarations except:
- *
staticorthread_localvariables. - * Variable declarations without initializers.
- The conditional branching statements
ifandswitch. - Any looping statement, including range-based
for. - Expressions which change the value of an object if the lifetime of that object began within the constant expression function. This includes calls to any non-
constconstexpr-declared non-static member functions.
goto statements are forbidden in C++14 relaxed constexpr-declared functions.Also, C++11 stated that all non-static member functions that were declared
constexpr were also implicitly declared const, with respect to this. That has since been removed; non-static member functions may be non-const. However, per the restrictions above, a non-const constexpr member function can only modify a class member if that object's lifetime began within the constant expression evaluation.Variable templates
In prior versions of C++, only functions, classes or type aliases could be templated. C++14 now allows the creation of variables that are templated. An example given in the proposal is a variablepi that can be read to get the value of pi for various types.The usual rules of templates apply to such declarations and definitions, including specialization.
template
constexpr T pi = T;
// Usual specialization rules apply:
template<>
constexpr const char* pi
Aggregate member initialization
added member initializers, expressions to be applied to members at class scope if a constructor did not initialize the member itself. The definition of aggregates was changed to explicitly exclude any class with member initializers; therefore, they are not allowed to use aggregate initialization.C++14 relaxes this restriction, allowing aggregate initialization on such types. If the braced init list does not provide a value for that argument, the member initializer takes care of it.
Binary literals
Numeric literals in C++14 can be specified in binary form. The syntax uses the prefixes0b or 0B. The syntax is also used in other languages e.g. Java, C#, Swift, Go, Scala, Ruby, Python, OCaml, and as an unofficial extension in some C compilers since at least 2007.Digit separators
In C++14, the single-quote character may be used arbitrarily as a digit separator in numeric literals, both integer literals and floating point literals. This can make it easier for human readers to parse large numbers through subitizing.auto integer_literal = 1'000'000;
auto floating_point_literal = 0.000'015'3;
auto binary_literal = 0b0100'1100'0110;
auto silly_example = 1'0'0'000'00;
Generic lambdas
In C++11, lambda function parameters need to be declared with concrete types. C++14 relaxes this requirement, allowing lambda function parameters to be declared with theauto type specifier.auto lambda = ;
Concerning
auto type deduction, generic lambdas follow the rules of template argument deduction. The code above is equivalent to this:struct
lambda;
Generic lambdas are essentially templated functor lambdas.
Lambda capture expressions
C++11 lambda functions capture variables declared in their outer scope by value-copy or by reference. This means that value members of a lambda cannot be move-only types. C++14 allows captured members to be initialized with arbitrary expressions. This allows both capture by value-move and declaring arbitrary members of the lambda, without having a correspondingly named variable in an outer scope.This is done via the use of an initializer expression:
auto lambda = ;
The lambda function
lambda returns 1, which is what value was initialized with. The declared capture deduces the type from the initializer expression as if by auto.This can be used to capture by move, via the use of the standard
std::move function:std::unique_ptr
auto lambda = ;
The attribute [deprecated]
The deprecated attribute allows marking an entity deprecated, which makes it still legal to use but puts users on notice that use is discouraged and may cause a warning message to be printed during compilation. An optional string literal can appear as the argument of deprecated, to explain the rationale for deprecation and/or to suggest a replacement.deprecated int f;
deprecated is thread-unsafe. Use h instead")
void g;
void h;
void test
New standard library features
Shared mutexes and locking
C++14 adds a shared timed mutex and a companion shared lock type.Heterogeneous lookup in associative containers
The C++ Standard Library defines four associative container classes. These classes allow the user to look up a value based on a value of that type. The map containers allow the user to specify a key and a value, where lookup is done by key and returns a value. However, the lookup is always done by the specific key type, whether it is the key as in maps or the value itself as in sets.C++14 allows the lookup to be done via an arbitrary type, so long as the comparison operator can compare that type with the actual key type. This would allow a map from
std::string to some value to compare against a const char* or any other type for which an operator< overload is available. It is also useful for indexing composite objects in a std::set by the value of a single member without forcing the user of find to create a dummy object.To preserve backwards compatibility, heterogeneous lookup is only allowed when the comparator given to the associative container allows it. The standard library classes
std::less<> and std::greater<> are augmented to allow heterogeneous lookup.Standard user-defined literals
C++11 defined the syntax for user-defined literal suffixes, but the standard library did not use any of them. C++14 adds the following standard literals:- "s", for creating the various
std::basic_stringtypes. - "h", "min", "s", "ms", "us", "ns", for creating the corresponding
std::chrono::durationtime intervals. - "if", "i", "il", for creating the corresponding
std::complex,std::complexandstd::compleximaginary numbers.
auto str = "hello world"s; // auto deduces string
auto dur = 60s; // auto deduces chrono::seconds
auto z = 1i; // auto deduces complex
The two "s" literals do not interact, as the string one only operates on string literals, and the one for seconds operates only on numbers.
Tuple addressing via type
Thestd::tuple type introduced in C++11 allows an aggregate of typed values to be indexed by a compile-time constant integer. C++14 extends this to allow fetching from a tuple by type instead of by index. If the tuple has more than one element of the type, a compile-time error results:tuple
int i = get
int j = get<2>; // Same as before: j 7
string s = get
Smaller library features
std::make_unique can be used like std::make_shared for std::unique_ptr objects.std::integral_constant gained an operator overload to return the constant value.The class template
std::integer_sequence and related alias templates were added for representing compile-time integer sequences, such as the indices of elements in a parameter pack.The global
std::begin/std::end functions were augmented with std::cbegin/std::cend functions, which return constant iterators, and std::rbegin/std::rend and std::crbegin/std::crend which return reverse iterators.The
std::exchange function template assigns a new value to a variable and returns the old value.New overloads of
std::equal, std::mismatch, and std::is_permutation take a pair of iterators for the second range, so that the caller does not need to separately check that the two ranges are of the same length.The
std::is_final type trait detects if a class is marked final.The
std::quoted stream I/O manipulator allows inserting and extracting strings with embedded spaces, by placing delimiters on output and stripping them on input, and escaping any embedded delimiters.