Many of these descriptions and examples are taken from various resources (see Acknowledgements section) and summarized in my own words.
C++20 includes the following new language features:
- coroutines
- concepts
- designated initializers
- template syntax for lambdas
- range-based for loop with initializer
- likely and unlikely attributes
- deprecate implicit capture of this
- class types in non-type template parameters
- constexpr virtual functions
- explicit(bool)
- immediate functions
- using enum
- lambda capture of parameter pack
- char8_t
C++20 includes the following new library features:
- concepts library
- synchronized buffered outputstream
- std::span
- bit operations
- math constants
- std::is_constant_evaluated
- std::make_shared supports arrays
- starts_with and ends_with on strings
- check if associative container has element
- std::bit_cast
- std::midpoint
- std::to_array
C++17 includes the following new language features:
- template argument deduction for class templates
- declaring non-type template parameters with auto
- folding expressions
- new rules for auto deduction from braced-init-list
- constexpr lambda
- lambda capture this by value
- inline variables
- nested namespaces
- structured bindings
- selection statements with initializer
- constexpr if
- utf-8 character literals
- direct-list-initialization of enums
- fallthrough, nodiscard, maybe_unused attributes
C++17 includes the following new library features:
- std::variant
- std::optional
- std::any
- std::string_view
- std::invoke
- std::apply
- std::filesystem
- std::byte
- splicing for maps and sets
- parallel algorithms
C++14 includes the following new language features:
- binary literals
- generic lambda expressions
- lambda capture initializers
- return type deduction
- decltype(auto)
- relaxing constraints on constexpr functions
- variable templates
- [[deprecated]] attribute
C++14 includes the following new library features:
C++11 includes the following new language features:
- move semantics
- variadic templates
- rvalue references
- forwarding references
- initializer lists
- static assertions
- auto
- lambda expressions
- decltype
- type aliases
- nullptr
- strongly-typed enums
- attributes
- constexpr
- delegating constructors
- user-defined literals
- explicit virtual overrides
- final specifier
- default functions
- deleted functions
- range-based for loops
- special member functions for move semantics
- converting constructors
- explicit conversion functions
- inline-namespaces
- non-static data member initializers
- right angle brackets
- ref-qualified member functions
- trailing return types
- noexcept specifier
- char32_t and char16_t
- raw string literals
C++11 includes the following new library features:
- std::move
- std::forward
- std::thread
- std::to_string
- type traits
- smart pointers
- std::chrono
- tuples
- std::tie
- std::array
- unordered containers
- std::make_shared
- std::ref
- memory model
- std::async
- std::begin/end
Coroutines are special functions that can have their execution suspended and resumed. To define a coroutine, the co_return
, co_await
, or co_yield
keywords must be present in the function's body. C++20's coroutines are stackless; unless optimized out by the compiler, their state is allocated on the heap.
An example of a coroutine is a generator function, which yields (i.e. generates) a value at each invocation:
generator<int> range(int start, int end) {
while (start < end) {
co_yield start;
start++;
}
// Implicit co_return at the end of this function:
// co_return;
}
for (int n : range(0, 10)) {
std::cout << n << std::endl;
}
The above range
generator function generates values starting at start
until end
(exclusive), with each iteration step yielding the current value stored in start
. The generator maintains its state across each invocation of range
(in this case, the invocation is for each iteration in the for loop). co_yield
takes the given expression, yields (i.e. returns) its value, and suspends the coroutine at that point. Upon resuming, execution continues after the co_yield
.
Another example of a coroutine is a task, which is an asynchronous computation that is executed when the task is awaited:
task<void> echo(socket s) {
for (;;) {
auto data = co_await s.async_read();
co_await async_write(s, data);
}
// Implicit co_return at the end of this function:
// co_return;
}
In this example, the co_await
keyword is introduced. This keyword takes an expression and suspends execution if the thing you're awaiting on (in this case, the read or write) is not ready, otherwise you continue execution. (Note that under the hood, co_yield
uses co_await
.)
Using a task to lazily evaluate a value:
task<int> calculate_meaning_of_life() {
co_return 42;
}
auto meaning_of_life = calculate_meaning_of_life();
// ...
co_await meaning_of_life; // == 42
Note: While these examples illustrate how to use coroutines at a basic level, there is lots more going on when the code is compiled. These examples are not meant to be complete coverage of C++20's coroutines. Since the generator
and task
classes are not provided by the standard library yet, I used the cppcoro library to compile these examples.
Concepts are named compile-time predicates which constrain types. They take the following form:
template < template-parameter-list >
concept concept-name = constraint-expression;
where constraint-expression
evaluates to a constexpr Boolean. Constraints should model semantic requirements, such as whether a type is a numeric or hashable. A compiler error results if a given type does not satisfy the concept it's bound by (i.e. constraint-expression
returns false
). Because constraints are evaluated at compile-time, they can provide more meaningful error messages and runtime safety.
// `T` is not limited by any constraints.
template <typename T>
concept always_satisfied = true;
// Limit `T` to integrals.
template <typename T>
concept integral = std::is_integral_v<T>;
// Limit `T` to both the `integral` constraint and signedness.
template <typename T>
concept signed_integral = integral<T> && std::is_signed_v<T>;
// Limit `T` to both the `integral` constraint and the negation of the `signed_integral` constraint.
template <typename T>
concept unsigned_integral = integral<T> && !signed_integral<T>;
There are a variety of syntactic forms for enforcing concepts:
// Forms for function parameters:
// `T` is a constrained type template parameter.
template <my_concept T>
void f(T v);
// `T` is a constrained type template parameter.
template <typename T>
requires my_concept<T>
void f(T v);
// `T` is a constrained type template parameter.
template <typename T>
void f(T v) requires my_concept<T>;
// `v` is a constrained deduced parameter.
void f(my_concept auto v);
// `v` is a constrained non-type template parameter.
template <my_concept auto v>
void g();
// Forms for auto-deduced variables:
// `foo` is a constrained auto-deduced value.
my_concept auto foo = ...;
// Forms for lambdas:
// `T` is a constrained type template parameter.
auto f = []<my_concept T> (T v) {
// ...
};
// `T` is a constrained type template parameter.
auto f = []<typename T> requires my_concept<T> (T v) {
// ...
};
// `T` is a constrained type template parameter.
auto f = []<typename T> (T v) requires my_concept<T> {
// ...
};
// `v` is a constrained deduced parameter.
auto f = [](my_concept auto v) {
// ...
};
// `v` is a constrained non-type template parameter.
auto g = []<my_concept auto v> () {
// ...
};
The requires
keyword is used either to start a requires
clause or a requires
expression:
template <typename T>
requires my_concept<T> // `requires` clause.
void f(T);
template <typename T>
concept callable = requires (T f) { f(); }; // `requires` expression.
template <typename T>
requires requires (T x) { x + x; } // `requires` clause and expression on same line.
T add(T a, T b) {
return a + b;
}
Note that the parameter list in a requires
expression is optional. Each requirement in a requires
expression are one of the following:
- Simple requirements - asserts that the given expression is valid.
template <typename T>
concept callable = requires (T f) { f(); };
- Type requirements - denoted by the
typename
keyword followed by a type name, asserts that the given type name is valid.
struct foo {
int foo;
};
struct bar {
using value = int;
value data;
};
struct baz {
using value = int;
value data;
};
// Using SFINAE, enable if `T` is a `baz`.
template <typename T, typename = std::enable_if_t<std::is_same_v<T, baz>>>
struct S {};
template <typename T>
using Ref = T&;
template <typename T>
concept C = requires {
// Requirements on type `T`:
typename T::value; // A) has an inner member named `value`
typename S<T>; // B) must have a valid class template specialization for `S`
typename Ref<T>; // C) must be a valid alias template substitution
};
template <C T>
void g(T a);
g(foo{}); // ERROR: Fails requirement A.
g(bar{}); // ERROR: Fails requirement B.
g(baz{}); // PASS.
- Compound requirements - an expression in braces followed by a trailing return type or type constraint.
template <typename T>
concept C = requires(T x) {
{*x} -> typename T::inner; // the type of the expression `*x` is convertible to `T::inner`
{x + 1} -> std::same_as<int>; // the expression `x + 1` satisfies `std::same_as<decltype((x + 1))>`
{x * 1} -> T; // the type of the expression `x * 1` is convertible to `T`
};
- Nested requirements - denoted by the
requires
keyword, specify additional constraints (such as those on local parameter arguments).
template <typename T>
concept C = requires(T x) {
requires std::same_as<sizeof(x), size_t>;
};
See also: concepts library.
C-style designated initializer syntax. Any member fields that are not explicitly listed in the designated initializer list are default-initialized.
struct A {
int x;
int y;
int z = 123;
};
A a {.x = 1, .z = 2}; // a.x == 1, a.y == 0, a.z == 2
Use familiar template syntax in lambda expressions.
auto f = []<typename T>(std::vector<T> v) {
// ...
};
This feature simplifies common code patterns, helps keep scopes tight, and offers an elegant solution to a common lifetime problem.
for (std::vector v{1, 2, 3}; auto& e : v) {
std::cout << e;
}
// prints "123"
Provides a hint to the optimizer that the labelled statement has a high probability of being executed.
switch (n) {
case 1:
// ...
break;
[[likely]] case 2: // n == 2 is considered to be arbitrarily more
// ... // likely than any other value of n
break;
}
If one of the likely/unlikely attributes appears after the right parenthesis of an if-statement, it indicates that the branch is likely/unlikely to have its substatement (body) executed.
int random = get_random_number_between_x_and_y(0, 3);
if (random > 0) [[likely]] {
// body of if statement
// ...
}
It can also be applied to the substatement (body) of an iteration statement.
while (unlikely_truthy_condition) [[unlikely]] {
// body of while statement
// ...
}
Implicitly capturing this
in a lambda capture using [=]
is now deprecated; prefer capturing explicitly using [=, this]
or [=, *this]
.
struct int_value {
int n = 0;
auto getter_fn() {
// BAD:
// return [=]() { return n; };
// GOOD:
return [=, *this]() { return n; };
}
};
Classes can now be used in non-type template parameters. Objects passed in as template arguments have the type const T
, where T
is the type of the object, and has static storage duration.
struct foo {
foo() = default;
constexpr foo(int) {}
};
template <foo f>
auto get_foo() {
return f;
}
get_foo(); // uses implicit constructor
get_foo<foo{123}>();
Virtual functions can now be constexpr
and evaluated at compile-time. constexpr
virtual functions can override non-constexpr
virtual functions and vice-versa.
struct X1 {
virtual int f() const = 0;
};
struct X2: public X1 {
constexpr virtual int f() const { return 2; }
};
struct X3: public X2 {
virtual int f() const { return 3; }
};
struct X4: public X3 {
constexpr virtual int f() const { return 4; }
};
constexpr X4 x4;
x4.f(); // == 4
Conditionally select at compile-time whether a constructor is made explicit or not. explicit(true)
is the same as specifying explicit
.
struct foo {
// Specify non-integral types (strings, floats, etc.) require explicit construction.
template <typename T>
explicit(!std::is_integral_v<T>) foo(T) {}
};
foo a = 123; // OK
foo b = "123"; // ERROR: explicit constructor is not a candidate (explicit specifier evaluates to true)
foo c {"123"}; // OK
Similar to constexpr
functions, but functions with a consteval
specifier must produce a constant. These are called immediate functions
.
consteval int sqr(int n) {
return n * n;
}
constexpr int r = sqr(100); // OK
int x = 100;
int r2 = sqr(x); // ERROR: the value of 'x' is not usable in a constant expression
// OK if `sqr` were a `constexpr` function
Bring an enum's members into scope to improve readability. Before:
enum class rgba_color_channel { red, green, blue, alpha };
std::string_view to_string(rgba_color_channel channel) {
switch (channel) {
case rgba_color_channel::red: return "red";
case rgba_color_channel::green: return "green";
case rgba_color_channel::blue: return "blue";
case rgba_color_channel::alpha: return "alpha";
}
}
After:
enum class rgba_color_channel { red, green, blue, alpha };
std::string_view to_string(rgba_color_channel my_channel) {
switch (my_channel) {
using enum rgba_color_channel;
case red: return "red";
case green: return "green";
case blue: return "blue";
case alpha: return "alpha";
}
}
Capture parameter packs by value:
template <typename... Args>
auto f(Args&&... args){
// BY VALUE:
return [...args = std::forward<Args>(args)] {
// ...
};
}
Capture parameter packs by reference:
template <typename... Args>
auto f(Args&&... args){
// BY REFERENCE:
return [&...args = std::forward<Args>(args)] {
// ...
};
}
Provides a standard type for representing UTF-8 strings.
char8_t utf8_str[] = u8"\u0123";
Concepts are also provided by the standard library for building more complicated concepts. Some of these include:
Core language concepts:
same_as
- specifies two types are the same.derived_from
- specifies that a type is derived from another type.convertible_to
- specifies that a type is implicitly convertible to another type.common_with
- specifies that two types share a common type.integral
- specifies that a type is an integral type.default_constructible
- specifies that an object of a type can be default-constructed.
Comparison concepts:
boolean
- specifies that a type can be used in Boolean contexts.equality_comparable
- specifies thatoperator==
is an equivalence relation.
Object concepts:
movable
- specifies that an object of a type can be moved and swapped.copyable
- specifies that an object of a type can be copied, moved, and swapped.semiregular
- specifies that an object of a type can be copied, moved, swapped, and default constructed.regular
- specifies that a type is regular, that is, it is bothsemiregular
andequality_comparable
.
Callable concepts:
invocable
- specifies that a callable type can be invoked with a given set of argument types.predicate
- specifies that a callable type is a Boolean predicate.
See also: concepts.
Buffers output operations for the wrapped output stream ensuring synchronization (i.e. no interleaving of output).
std::osyncstream{std::cout} << "The value of x is:" << x << std::endl;
A span is a view (i.e. non-owning) of a container providing bounds-checked access to a contiguous group of elements. Since views do not own their elements they are cheap to construct and copy -- a simplified way to think about views is they are holding references to their data. Spans can be dynamically-sized or fixed-sized.
void f(std::span<int> ints) {
std::for_each(ints.begin(), ints.end(), [](auto i) {
// ...
});
}
std::vector<int> v = {1, 2, 3};
f(v);
std::array<int, 3> a = {1, 2, 3};
f(a);
// etc.
Example: as opposed to maintaining a pointer and length field, a span wraps both of those up in a single container.
constexpr size_t LENGTH_ELEMENTS = 3;
int* arr = new int[LENGTH_ELEMENTS]; // arr = {0, 0, 0}
// Fixed-sized span which provides a view of `arr`.
std::span<int, LENGTH_ELEMENTS> span = arr;
span[1] = 1; // arr = {0, 1, 0}
// Dynamic-sized span which provides a view of `arr`.
std::span<int> d_span = arr;
span[0] = 1; // arr = {1, 1, 0}
constexpr size_t LENGTH_ELEMENTS = 3;
int* arr = new int[LENGTH_ELEMENTS];
std::span<int, LENGTH_ELEMENTS> span = arr; // OK
std::span<double, LENGTH_ELEMENTS> span2 = arr; // ERROR
std::span<int, 1> span3 = arr; // ERROR
C++20 provides a new <bit>
header which provides some bit operations including popcount.
std::popcount(0u); // 0
std::popcount(1u); // 1
std::popcount(0b1111'0000u); // 4
Mathematical constants including PI, Euler's number, etc. defined in the <numbers>
header.
std::numbers::pi; // 3.14159...
std::numbers::e; // 2.71828...
Predicate function which is truthy when it is called in a compile-time context.
constexpr bool is_compile_time() {
return std::is_constant_evaluated();
}
constexpr bool a = is_compile_time(); // true
bool b = is_compile_time(); // false
auto p = std::make_shared<int[]>(5); // pointer to `int[5]`
// OR
auto p = std::make_shared<int[5]>(); // pointer to `int[5]`
Strings (and string views) now have the starts_with
and ends_with
member functions to check if a string starts or ends with the given string.
std::string str = "foobar";
str.starts_with("foo"); // true
str.ends_with("baz"); // false
Associative containers such as sets and maps have a contains
member function, which can be used instead of the "find and check end of iterator" idiom.
std::map<int, char> map {{1, 'a'}, {2, 'b'}};
map.contains(2); // true
map.contains(123); // false
std::set<int> set {1, 2, 3};
set.contains(2); // true
A safer way to reinterpret an object from one type to another.
float f = 123.0;
int i = std::bit_cast<int>(f);
Calculate the midpoint of two integers safely (without overflow).
std::midpoint(1, 3); // == 2
Converts the given array/"array-like" object to a std::array
.
std::to_array("foo"); // returns `std::array<char, 4>`
std::to_array<int>({1, 2, 3}); // returns `std::array<int, 3>`
int a[] = {1, 2, 3};
std::to_array(a); // returns `std::array<int, 3>`
Automatic template argument deduction much like how it's done for functions, but now including class constructors.
template <typename T = float>
struct MyContainer {
T val;
MyContainer() : val{} {}
MyContainer(T val) : val{val} {}
// ...
};
MyContainer c1 {1}; // OK MyContainer<int>
MyContainer c2; // OK MyContainer<float>
Following the deduction rules of auto
, while respecting the non-type template parameter list of allowable types[*], template arguments can be deduced from the types of its arguments:
template <auto... seq>
struct my_integer_sequence {
// Implementation here ...
};
// Explicitly pass type `int` as template argument.
auto seq = std::integer_sequence<int, 0, 1, 2>();
// Type is deduced to be `int`.
auto seq2 = my_integer_sequence<0, 1, 2>();
* - For example, you cannot use a double
as a template parameter type, which also makes this an invalid deduction using auto
.
A fold expression performs a fold of a template parameter pack over a binary operator.
- An expression of the form
(... op e)
or(e op ...)
, whereop
is a fold-operator ande
is an unexpanded parameter pack, are called unary folds. - An expression of the form
(e1 op ... op e2)
, whereop
are fold-operators, is called a binary fold. Eithere1
ore2
is an unexpanded parameter pack, but not both.
template <typename... Args>
bool logicalAnd(Args... args) {
// Binary folding.
return (true && ... && args);
}
bool b = true;
bool& b2 = b;
logicalAnd(b, b2, true); // == true
template <typename... Args>
auto sum(Args... args) {
// Unary folding.
return (... + args);
}
sum(1.0, 2.0f, 3); // == 6.0
Changes to auto
deduction when used with the uniform initialization syntax. Previously, auto x {3};
deduces a std::initializer_list<int>
, which now deduces to int
.
auto x1 {1, 2, 3}; // error: not a single element
auto x2 = {1, 2, 3}; // x2 is std::initializer_list<int>
auto x3 {3}; // x3 is int
auto x4 {3.0}; // x4 is double
Compile-time lambdas using constexpr
.
auto identity = [](int n) constexpr { return n; };
static_assert(identity(123) == 123);
constexpr auto add = [](int x, int y) {
auto L = [=] { return x; };
auto R = [=] { return y; };
return [=] { return L() + R(); };
};
static_assert(add(1, 2)() == 3);
constexpr int addOne(int n) {
return [n] { return n + 1; }();
}
static_assert(addOne(1) == 2);
Capturing this
in a lambda's environment was previously reference-only. An example of where this is problematic is asynchronous code using callbacks that require an object to be available, potentially past its lifetime. *this
(C++17) will now make a copy of the current object, while this
(C++11) continues to capture by reference.
struct MyObj {
int value {123};
auto getValueCopy() {
return [*this] { return value; };
}
auto getValueRef() {
return [this] { return value; };
}
};
MyObj mo;
auto valueCopy = mo.getValueCopy();
auto valueRef = mo.getValueRef();
mo.value = 321;
valueCopy(); // 123
valueRef(); // 321
The inline specifier can be applied to variables as well as to functions. A variable declared inline has the same semantics as a function declared inline.
// Disassembly example using compiler explorer.
struct S { int x; };
inline S x1 = S{321}; // mov esi, dword ptr [x1]
// x1: .long 321
S x2 = S{123}; // mov eax, dword ptr [.L_ZZ4mainE2x2]
// mov dword ptr [rbp - 8], eax
// .L_ZZ4mainE2x2: .long 123
It can also be used to declare and define a static member variable, such that it does not need to be initialized in the source file.
struct S {
S() : id{count++} {}
~S() { count--; }
int id;
static inline int count{0}; // declare and initialize count to 0 within the class
};
Using the namespace resolution operator to create nested namespace definitions.
namespace A {
namespace B {
namespace C {
int i;
}
}
}
The code above can be written like this:
namespace A::B::C {
int i;
}
A proposal for de-structuring initialization, that would allow writing auto [ x, y, z ] = expr;
where the type of expr
was a tuple-like object, whose elements would be bound to the variables x
, y
, and z
(which this construct declares). Tuple-like objects include std::tuple
, std::pair
, std::array
, and aggregate structures.
using Coordinate = std::pair<int, int>;
Coordinate origin() {
return Coordinate{0, 0};
}
const auto [ x, y ] = origin();
x; // == 0
y; // == 0
std::unordered_map<std::string, int> mapping {
{"a", 1},
{"b", 2},
{"c", 3}
};
// Destructure by reference.
for (const auto& [key, value] : mapping) {
// Do something with key and value
}
New versions of the if
and switch
statements which simplify common code patterns and help users keep scopes tight.
{
std::lock_guard<std::mutex> lk(mx);
if (v.empty()) v.push_back(val);
}
// vs.
if (std::lock_guard<std::mutex> lk(mx); v.empty()) {
v.push_back(val);
}
Foo gadget(args);
switch (auto s = gadget.status()) {
case OK: gadget.zip(); break;
case Bad: throw BadFoo(s.message());
}
// vs.
switch (Foo gadget(args); auto s = gadget.status()) {
case OK: gadget.zip(); break;
case Bad: throw BadFoo(s.message());
}
Write code that is instantiated depending on a compile-time condition.
template <typename T>
constexpr bool isIntegral() {
if constexpr (std::is_integral<T>::value) {
return true;
} else {
return false;
}
}
static_assert(isIntegral<int>() == true);
static_assert(isIntegral<char>() == true);
static_assert(isIntegral<double>() == false);
struct S {};
static_assert(isIntegral<S>() == false);
A character literal that begins with u8
is a character literal of type char
. The value of a UTF-8 character literal is equal to its ISO 10646 code point value.
char x = u8'x';
Enums can now be initialized using braced syntax.
enum byte : unsigned char {};
byte b {0}; // OK
byte c {-1}; // ERROR
byte d = byte{1}; // OK
byte e = byte{256}; // ERROR
C++17 introduces three new attributes: [[fallthrough]]
, [[nodiscard]]
and [[maybe_unused]]
.
[[fallthrough]]
indicates to the compiler that falling through in a switch statement is intended behavior.
switch (n) {
case 1: [[fallthrough]]
// ...
case 2:
// ...
break;
}
[[nodiscard]]
issues a warning when either a function or class has this attribute and its return value is discarded.
[[nodiscard]] bool do_something() {
return is_success; // true for success, false for failure
}
do_something(); // warning: ignoring return value of 'bool do_something()',
// declared with attribute 'nodiscard'
// Only issues a warning when `error_info` is returned by value.
struct [[nodiscard]] error_info {
// ...
};
error_info do_something() {
error_info ei;
// ...
return ei;
}
do_something(); // warning: ignoring returned value of type 'error_info',
// declared with attribute 'nodiscard'
[[maybe_unused]]
indicates to the compiler that a variable or parameter might be unused and is intended.
void my_callback(std::string msg, [[maybe_unused]] bool error) {
// Don't care if `msg` is an error message, just log it.
log(msg);
}
The class template std::variant
represents a type-safe union
. An instance of std::variant
at any given time holds a value of one of its alternative types (it's also possible for it to be valueless).
std::variant<int, double> v {12};
std::get<int>(v); // == 12
std::get<0>(v); // == 12
v = 12.0;
std::get<double>(v); // == 12.0
std::get<1>(v); // == 12.0
The class template std::optional
manages an optional contained value, i.e. a value that may or may not be present. A common use case for optional is the return value of a function that may fail.
std::optional<std::string> create(bool b) {
if (b) {
return "Godzilla";
} else {
return {};
}
}
create(false).value_or("empty"); // == "empty"
create(true).value(); // == "Godzilla"
// optional-returning factory functions are usable as conditions of while and if
if (auto str = create(true)) {
// ...
}
A type-safe container for single values of any type.
std::any x {5};
x.has_value() // == true
std::any_cast<int>(x) // == 5
std::any_cast<int&>(x) = 10;
std::any_cast<int>(x) // == 10
A non-owning reference to a string. Useful for providing an abstraction on top of strings (e.g. for parsing).
// Regular strings.
std::string_view cppstr {"foo"};
// Wide strings.
std::wstring_view wcstr_v {L"baz"};
// Character arrays.
char array[3] = {'b', 'a', 'r'};
std::string_view array_v(array, std::size(array));
std::string str {" trim me"};
std::string_view v {str};
v.remove_prefix(std::min(v.find_first_not_of(" "), v.size()));
str; // == " trim me"
v; // == "trim me"
Invoke a Callable
object with parameters. Examples of Callable
objects are std::function
or std::bind
where an object can be called similarly to a regular function.
template <typename Callable>
class Proxy {
Callable c;
public:
Proxy(Callable c): c(c) {}
template <class... Args>
decltype(auto) operator()(Args&&... args) {
// ...
return std::invoke(c, std::forward<Args>(args)...);
}
};
auto add = [](int x, int y) {
return x + y;
};
Proxy<decltype(add)> p {add};
p(1, 2); // == 3
Invoke a Callable
object with a tuple of arguments.
auto add = [](int x, int y) {
return x + y;
};
std::apply(add, std::make_tuple(1, 2)); // == 3
The new std::filesystem
library provides a standard way to manipulate files, directories, and paths in a filesystem.
Here, a big file is copied to a temporary path if there is available space:
const auto bigFilePath {"bigFileToCopy"};
if (std::filesystem::exists(bigFilePath)) {
const auto bigFileSize {std::filesystem::file_size(bigFilePath)};
std::filesystem::path tmpPath {"/tmp"};
if (std::filesystem::space(tmpPath).available > bigFileSize) {
std::filesystem::create_directory(tmpPath.append("example"));
std::filesystem::copy_file(bigFilePath, tmpPath.append("newFile"));
}
}
The new std::byte
type provides a standard way of representing data as a byte. Benefits of using std::byte
over char
or unsigned char
is that it is not a character type, and is also not an arithmetic type; while the only operator overloads available are bitwise operations.
std::byte a {0};
std::byte b {0xFF};
int i = std::to_integer<int>(b); // 0xFF
std::byte c = a & b;
int j = std::to_integer<int>(c); // 0
Note that std::byte
is simply an enum, and braced initialization of enums become possible thanks to direct-list-initialization of enums.
Moving nodes and merging containers without the overhead of expensive copies, moves, or heap allocations/deallocations.
Moving elements from one map to another:
std::map<int, string> src {{1, "one"}, {2, "two"}, {3, "buckle my shoe"}};
std::map<int, string> dst {{3, "three"}};
dst.insert(src.extract(src.find(1))); // Cheap remove and insert of { 1, "one" } from `src` to `dst`.
dst.insert(src.extract(2)); // Cheap remove and insert of { 2, "two" } from `src` to `dst`.
// dst == { { 1, "one" }, { 2, "two" }, { 3, "three" } };
Inserting an entire set:
std::set<int> src {1, 3, 5};
std::set<int> dst {2, 4, 5};
dst.merge(src);
// src == { 5 }
// dst == { 1, 2, 3, 4, 5 }
Inserting elements which outlive the container:
auto elementFactory() {
std::set<...> s;
s.emplace(...);
return s.extract(s.begin());
}
s2.insert(elementFactory());
Changing the key of a map element:
std::map<int, string> m {{1, "one"}, {2, "two"}, {3, "three"}};
auto e = m.extract(2);
e.key() = 4;
m.insert(std::move(e));
// m == { { 1, "one" }, { 3, "three" }, { 4, "two" } }
Many of the STL algorithms, such as the copy
, find
and sort
methods, started to support the parallel execution policies: seq
, par
and par_unseq
which translate to "sequentially", "parallel" and "parallel unsequenced".
std::vector<int> longVector;
// Find element using parallel execution policy
auto result1 = std::find(std::execution::par, std::begin(longVector), std::end(longVector), 2);
// Sort elements using sequential execution policy
auto result2 = std::sort(std::execution::seq, std::begin(longVector), std::end(longVector));
Binary literals provide a convenient way to represent a base-2 number.
It is possible to separate digits with '
.
0b110 // == 6
0b1111'1111 // == 255
C++14 now allows the auto
type-specifier in the parameter list, enabling polymorphic lambdas.
auto identity = [](auto x) { return x; };
int three = identity(3); // == 3
std::string foo = identity("foo"); // == "foo"
This allows creating lambda captures initialized with arbitrary expressions. The name given to the captured value does not need to be related to any variables in the enclosing scopes and introduces a new name inside the lambda body. The initializing expression is evaluated when the lambda is created (not when it is invoked).
int factory(int i) { return i * 10; }
auto f = [x = factory(2)] { return x; }; // returns 20
auto generator = [x = 0] () mutable {
// this would not compile without 'mutable' as we are modifying x on each call
return x++;
};
auto a = generator(); // == 0
auto b = generator(); // == 1
auto c = generator(); // == 2
Because it is now possible to move (or forward) values into a lambda that could previously be only captured by copy or reference we can now capture move-only types in a lambda by value. Note that in the below example the p
in the capture-list of task2
on the left-hand-side of =
is a new variable private to the lambda body and does not refer to the original p
.
auto p = std::make_unique<int>(1);
auto task1 = [=] { *p = 5; }; // ERROR: std::unique_ptr cannot be copied
// vs.
auto task2 = [p = std::move(p)] { *p = 5; }; // OK: p is move-constructed into the closure object
// the original p is empty after task2 is created
Using this reference-captures can have different names than the referenced variable.
auto x = 1;
auto f = [&r = x, x = x * 10] {
++r;
return r + x;
};
f(); // sets x to 2 and returns 12
Using an auto
return type in C++14, the compiler will attempt to deduce the type for you. With lambdas, you can now deduce its return type using auto
, which makes returning a deduced reference or rvalue reference possible.
// Deduce return type as `int`.
auto f(int i) {
return i;
}
template <typename T>
auto& f(T& t) {
return t;
}
// Returns a reference to a deduced type.
auto g = [](auto& x) -> auto& { return f(x); };
int y = 123;
int& z = g(y); // reference to `y`
The decltype(auto)
type-specifier also deduces a type like auto
does. However, it deduces return types while keeping their references and cv-qualifiers, while auto
will not.
const int x = 0;
auto x1 = x; // int
decltype(auto) x2 = x; // const int
int y = 0;
int& y1 = y;
auto y2 = y1; // int
decltype(auto) y3 = y1; // int&
int&& z = 0;
auto z1 = std::move(z); // int
decltype(auto) z2 = std::move(z); // int&&
// Note: Especially useful for generic code!
// Return type is `int`.
auto f(const int& i) {
return i;
}
// Return type is `const int&`.
decltype(auto) g(const int& i) {
return i;
}
int x = 123;
static_assert(std::is_same<const int&, decltype(f(x))>::value == 0);
static_assert(std::is_same<int, decltype(f(x))>::value == 1);
static_assert(std::is_same<const int&, decltype(g(x))>::value == 1);
See also: decltype
.
In C++11, constexpr
function bodies could only contain a very limited set of syntaxes, including (but not limited to): typedef
s, using
s, and a single return
statement. In C++14, the set of allowable syntaxes expands greatly to include the most common syntax such as if
statements, multiple return
s, loops, etc.
constexpr int factorial(int n) {
if (n <= 1) {
return 1;
} else {
return n * factorial(n - 1);
}
}
factorial(5); // == 120
C++14 allows variables to be templated:
template<class T>
constexpr T pi = T(3.1415926535897932385);
template<class T>
constexpr T e = T(2.7182818284590452353);
C++14 introduces the [[deprecated]]
attribute to indicate that a unit (function, class, etc.) is discouraged and likely yield compilation warnings. If a reason is provided, it will be included in the warnings.
[[deprecated]]
void old_method();
[[deprecated("Use new_method instead")]]
void legacy_method();
New user-defined literals for standard library types, including new built-in literals for chrono
and basic_string
. These can be constexpr
meaning they can be used at compile-time. Some uses for these literals include compile-time integer parsing, binary literals, and imaginary number literals.
using namespace std::chrono_literals;
auto day = 24h;
day.count(); // == 24
std::chrono::duration_cast<std::chrono::minutes>(day).count(); // == 1440
The class template std::integer_sequence
represents a compile-time sequence of integers. There are a few helpers built on top:
std::make_integer_sequence<T, N>
- creates a sequence of0, ..., N - 1
with typeT
.std::index_sequence_for<T...>
- converts a template parameter pack into an integer sequence.
Convert an array into a tuple:
template<typename Array, std::size_t... I>
decltype(auto) a2t_impl(const Array& a, std::integer_sequence<std::size_t, I...>) {
return std::make_tuple(a[I]...);
}
template<typename T, std::size_t N, typename Indices = std::make_index_sequence<N>>
decltype(auto) a2t(const std::array<T, N>& a) {
return a2t_impl(a, Indices());
}
std::make_unique
is the recommended way to create instances of std::unique_ptr
s due to the following reasons:
- Avoid having to use the
new
operator. - Prevents code repetition when specifying the underlying type the pointer shall hold.
- Most importantly, it provides exception-safety. Suppose we were calling a function
foo
like so:
foo(std::unique_ptr<T>{new T{}}, function_that_throws(), std::unique_ptr<T>{new T{}});
The compiler is free to call new T{}
, then function_that_throws()
, and so on... Since we have allocated data on the heap in the first construction of a T
, we have introduced a leak here. With std::make_unique
, we are given exception-safety:
foo(std::make_unique<T>(), function_that_throws(), std::make_unique<T>());
See the section on smart pointers for more information on std::unique_ptr
and std::shared_ptr
.
Moving an object means to transfer ownership of some resource it manages to another object.
The first benefit of move semantics is performance optimization. When an object is about to reach the end of its lifetime, either because it's a temporary or by explicitly calling std::move
, a move is often a cheaper way to transfer resources. For example, moving a std::vector
is just copying some pointers and internal state over to the new vector -- copying would involve having to copy every single contained element in the vector, which is expensive and unnecessary if the old vector will soon be destroyed.
Moves also make it possible for non-copyable types such as std::unique_ptr
s (smart pointers) to guarantee at the language level that there is only ever one instance of a resource being managed at a time, while being able to transfer an instance between scopes.
See the sections on: rvalue references, special member functions for move semantics, std::move
, std::forward
, forwarding references
.
C++11 introduces a new reference termed the rvalue reference. An rvalue reference to T
, which is a non-template type parameter (such as int
, or a user-defined type), is created with the syntax T&&
. Rvalue references only bind to rvalues.
Type deduction with lvalues and rvalues:
int x = 0; // `x` is an lvalue of type `int`
int& xl = x; // `xl` is an lvalue of type `int&`
int&& xr = x; // compiler error -- `x` is an lvalue
int&& xr2 = 0; // `xr2` is an lvalue of type `int&&` -- binds to the rvalue temporary, `0`
void f(int& x) {}
void f(int&& x) {}
f(x); // calls f(int&)
f(xl); // calls f(int&)
f(3); // calls f(int&&)
f(std::move(x)) // calls f(int&&)
f(xr2); // calls f(int&)
f(std::move(xr2)) // calls f(int&& x)
See also: std::move
, std::forward
, forwarding references
.
Also known (unofficially) as universal references. A forwarding reference is created with the syntax T&&
where T
is a template type parameter, or using auto&&
. This enables perfect forwarding: the ability to pass arguments while maintaining their value category (e.g. lvalues stay as lvalues, temporaries are forwarded as rvalues).
Forwarding references allow a reference to bind to either an lvalue or rvalue depending on the type. Forwarding references follow the rules of reference collapsing:
T& &
becomesT&
T& &&
becomesT&
T&& &
becomesT&
T&& &&
becomesT&&
auto
type deduction with lvalues and rvalues:
int x = 0; // `x` is an lvalue of type `int`
auto&& al = x; // `al` is an lvalue of type `int&` -- binds to the lvalue, `x`
auto&& ar = 0; // `ar` is an lvalue of type `int&&` -- binds to the rvalue temporary, `0`
Template type parameter deduction with lvalues and rvalues:
// Since C++14 or later:
void f(auto&& t) {
// ...
}
// Since C++11 or later:
template <typename T>
void f(T&& t) {
// ...
}
int x = 0;
f(0); // T is int, deduces as f(int &&) => f(int&&)
f(x); // T is int&, deduces as f(int& &&) => f(int&)
int& y = x;
f(y); // T is int&, deduces as f(int& &&) => f(int&)
int&& z = 0; // NOTE: `z` is an lvalue with type `int&&`.
f(z); // T is int&, deduces as f(int& &&) => f(int&)
f(std::move(z)); // T is int, deduces as f(int &&) => f(int&&)
See also: std::move
, std::forward
, rvalue references
.
The ...
syntax creates a parameter pack or expands one. A template parameter pack is a template parameter that accepts zero or more template arguments (non-types, types, or templates). A template with at least one parameter pack is called a variadic template.
template <typename... T>
struct arity {
constexpr static int value = sizeof...(T);
};
static_assert(arity<>::value == 0);
static_assert(arity<char, short, int>::value == 3);
An interesting use for this is creating an initializer list from a parameter pack in order to iterate over variadic function arguments.
template <typename First, typename... Args>
auto sum(const First first, const Args... args) -> decltype(first) {
const auto values = {first, args...};
return std::accumulate(values.begin(), values.end(), First{0});
}
sum(1, 2, 3, 4, 5); // 15
sum(1, 2, 3); // 6
sum(1.5, 2.0, 3.7); // 7.2
A lightweight array-like container of elements created using a "braced list" syntax. For example, { 1, 2, 3 }
creates a sequences of integers, that has type std::initializer_list<int>
. Useful as a replacement to passing a vector of objects to a function.
int sum(const std::initializer_list<int>& list) {
int total = 0;
for (auto& e : list) {
total += e;
}
return total;
}
auto list = {1, 2, 3};
sum(list); // == 6
sum({1, 2, 3}); // == 6
sum({}); // == 0
Assertions that are evaluated at compile-time.
constexpr int x = 0;
constexpr int y = 1;
static_assert(x == y, "x != y");
auto
-typed variables are deduced by the compiler according to the type of their initializer.
auto a = 3.14; // double
auto b = 1; // int
auto& c = b; // int&
auto d = { 0 }; // std::initializer_list<int>
auto&& e = 1; // int&&
auto&& f = b; // int&
auto g = new auto(123); // int*
const auto h = 1; // const int
auto i = 1, j = 2, k = 3; // int, int, int
auto l = 1, m = true, n = 1.61; // error -- `l` deduced to be int, `m` is bool
auto o; // error -- `o` requires initializer
Extremely useful for readability, especially for complicated types:
std::vector<int> v = ...;
std::vector<int>::const_iterator cit = v.cbegin();
// vs.
auto cit = v.cbegin();
Functions can also deduce the return type using auto
. In C++11, a return type must be specified either explicitly, or using decltype
like so:
template <typename X, typename Y>
auto add(X x, Y y) -> decltype(x + y) {
return x + y;
}
add(1, 2); // == 3
add(1, 2.0); // == 3.0
add(1.5, 1.5); // == 3.0
The trailing return type in the above example is the declared type (see section on decltype
) of the expression x + y
. For example, if x
is an integer and y
is a double, decltype(x + y)
is a double. Therefore, the above function will deduce the type depending on what type the expression x + y
yields. Notice that the trailing return type has access to its parameters, and this
when appropriate.
A lambda
is an unnamed function object capable of capturing variables in scope. It features: a capture list; an optional set of parameters with an optional trailing return type; and a body. Examples of capture lists:
[]
- captures nothing.[=]
- capture local objects (local variables, parameters) in scope by value.[&]
- capture local objects (local variables, parameters) in scope by reference.[this]
- capturethis
by reference.[a, &b]
- capture objectsa
by value,b
by reference.
int x = 1;
auto getX = [=] { return x; };
getX(); // == 1
auto addX = [=](int y) { return x + y; };
addX(1); // == 2
auto getXRef = [&]() -> int& { return x; };
getXRef(); // int& to `x`
By default, value-captures cannot be modified inside the lambda because the compiler-generated method is marked as const
. The mutable
keyword allows modifying captured variables. The keyword is placed after the parameter-list (which must be present even if it is empty).
int x = 1;
auto f1 = [&x] { x = 2; }; // OK: x is a reference and modifies the original
auto f2 = [x] { x = 2; }; // ERROR: the lambda can only perform const-operations on the captured value
// vs.
auto f3 = [x]() mutable { x = 2; }; // OK: the lambda can perform any operations on the captured value
decltype
is an operator which returns the declared type of an expression passed to it. cv-qualifiers and references are maintained if they are part of the expression. Examples of decltype
:
int a = 1; // `a` is declared as type `int`
decltype(a) b = a; // `decltype(a)` is `int`
const int& c = a; // `c` is declared as type `const int&`
decltype(c) d = a; // `decltype(c)` is `const int&`
decltype(123) e = 123; // `decltype(123)` is `int`
int&& f = 1; // `f` is declared as type `int&&`
decltype(f) g = 1; // `decltype(f) is `int&&`
decltype((a)) h = g; // `decltype((a))` is int&
template <typename X, typename Y>
auto add(X x, Y y) -> decltype(x + y) {
return x + y;
}
add(1, 2.0); // `decltype(x + y)` => `decltype(3.0)` => `double`
See also: decltype(auto)
.
Semantically similar to using a typedef
however, type aliases with using
are easier to read and are compatible with templates.
template <typename T>
using Vec = std::vector<T>;
Vec<int> v; // std::vector<int>
using String = std::string;
String s {"foo"};
C++11 introduces a new null pointer type designed to replace C's NULL
macro. nullptr
itself is of type std::nullptr_t
and can be implicitly converted into pointer types, and unlike NULL
, not convertible to integral types except bool
.
void foo(int);
void foo(char*);
foo(NULL); // error -- ambiguous
foo(nullptr); // calls foo(char*)
Type-safe enums that solve a variety of problems with C-style enums including: implicit conversions, inability to specify the underlying type, scope pollution.
// Specifying underlying type as `unsigned int`
enum class Color : unsigned int { Red = 0xff0000, Green = 0xff00, Blue = 0xff };
// `Red`/`Green` in `Alert` don't conflict with `Color`
enum class Alert : bool { Red, Green };
Color c = Color::Red;
Attributes provide a universal syntax over __attribute__(...)
, __declspec
, etc.
// `noreturn` attribute indicates `f` doesn't return.
[[ noreturn ]] void f() {
throw "error";
}
Constant expressions are expressions evaluated by the compiler at compile-time. Only non-complex computations can be carried out in a constant expression. Use the constexpr
specifier to indicate the variable, function, etc. is a constant expression.
constexpr int square(int x) {
return x * x;
}
int square2(int x) {
return x * x;
}
int a = square(2); // mov DWORD PTR [rbp-4], 4
int b = square2(2); // mov edi, 2
// call square2(int)
// mov DWORD PTR [rbp-8], eax
constexpr
values are those that the compiler can evaluate at compile-time:
const int x = 123;
constexpr const int& y = x; // error -- constexpr variable `y` must be initialized by a constant expression
Constant expressions with classes:
struct Complex {
constexpr Complex(double r, double i) : re{r}, im{i} { }
constexpr double real() { return re; }
constexpr double imag() { return im; }
private:
double re;
double im;
};
constexpr Complex I(0, 1);
Constructors can now call other constructors in the same class using an initializer list.
struct Foo {
int foo;
Foo(int foo) : foo{foo} {}
Foo() : Foo(0) {}
};
Foo foo;
foo.foo; // == 0
User-defined literals allow you to extend the language and add your own syntax. To create a literal, define a T operator "" X(...) { ... }
function that returns a type T
, with a name X
. Note that the name of this function defines the name of the literal. Any literal names not starting with an underscore are reserved and won't be invoked. There are rules on what parameters a user-defined literal function should accept, according to what type the literal is called on.
Converting Celsius to Fahrenheit:
// `unsigned long long` parameter required for integer literal.
long long operator "" _celsius(unsigned long long tempCelsius) {
return std::llround(tempCelsius * 1.8 + 32);
}
24_celsius; // == 75
String to integer conversion:
// `const char*` and `std::size_t` required as parameters.
int operator "" _int(const char* str, std::size_t) {
return std::stoi(str);
}
"123"_int; // == 123, with type `int`
Specifies that a virtual function overrides another virtual function. If the virtual function does not override a parent's virtual function, throws a compiler error.
struct A {
virtual void foo();
void bar();
};
struct B : A {
void foo() override; // correct -- B::foo overrides A::foo
void bar() override; // error -- A::bar is not virtual
void baz() override; // error -- B::baz does not override A::baz
};
Specifies that a virtual function cannot be overridden in a derived class or that a class cannot be inherited from.
struct A {
virtual void foo();
};
struct B : A {
virtual void foo() final;
};
struct C : B {
virtual void foo(); // error -- declaration of 'foo' overrides a 'final' function
};
Class cannot be inherited from.
struct A final {};
struct B : A {}; // error -- base 'A' is marked 'final'
A more elegant, efficient way to provide a default implementation of a function, such as a constructor.
struct A {
A() = default;
A(int x) : x{x} {}
int x {1};
};
A a; // a.x == 1
A a2 {123}; // a.x == 123
With inheritance:
struct B {
B() : x{1} {}
int x;
};
struct C : B {
// Calls B::B
C() = default;
};
C c; // c.x == 1
A more elegant, efficient way to provide a deleted implementation of a function. Useful for preventing copies on objects.
class A {
int x;
public:
A(int x) : x{x} {};
A(const A&) = delete;
A& operator=(const A&) = delete;
};
A x {123};
A y = x; // error -- call to deleted copy constructor
y = x; // error -- operator= deleted
Syntactic sugar for iterating over a container's elements.
std::array<int, 5> a {1, 2, 3, 4, 5};
for (int& x : a) x *= 2;
// a == { 2, 4, 6, 8, 10 }
Note the difference when using int
as opposed to int&
:
std::array<int, 5> a {1, 2, 3, 4, 5};
for (int x : a) x *= 2;
// a == { 1, 2, 3, 4, 5 }
The copy constructor and copy assignment operator are called when copies are made, and with C++11's introduction of move semantics, there is now a move constructor and move assignment operator for moves.
struct A {
std::string s;
A() : s{"test"} {}
A(const A& o) : s{o.s} {}
A(A&& o) : s{std::move(o.s)} {}
A& operator=(A&& o) {
s = std::move(o.s);
return *this;
}
};
A f(A a) {
return a;
}
A a1 = f(A{}); // move-constructed from rvalue temporary
A a2 = std::move(a1); // move-constructed using std::move
A a3 = A{};
a2 = std::move(a3); // move-assignment using std::move
a1 = f(A{}); // move-assignment from rvalue temporary
Converting constructors will convert values of braced list syntax into constructor arguments.
struct A {
A(int) {}
A(int, int) {}
A(int, int, int) {}
};
A a {0, 0}; // calls A::A(int, int)
A b(0, 0); // calls A::A(int, int)
A c = {0, 0}; // calls A::A(int, int)
A d {0, 0, 0}; // calls A::A(int, int, int)
Note that the braced list syntax does not allow narrowing:
struct A {
A(int) {}
};
A a(1.1); // OK
A b {1.1}; // Error narrowing conversion from double to int
Note that if a constructor accepts a std::initializer_list
, it will be called instead:
struct A {
A(int) {}
A(int, int) {}
A(int, int, int) {}
A(std::initializer_list<int>) {}
};
A a {0, 0}; // calls A::A(std::initializer_list<int>)
A b(0, 0); // calls A::A(int, int)
A c = {0, 0}; // calls A::A(std::initializer_list<int>)
A d {0, 0, 0}; // calls A::A(std::initializer_list<int>)
Conversion functions can now be made explicit using the explicit
specifier.
struct A {
operator bool() const { return true; }
};
struct B {
explicit operator bool() const { return true; }
};
A a;
if (a); // OK calls A::operator bool()
bool ba = a; // OK copy-initialization selects A::operator bool()
B b;
if (b); // OK calls B::operator bool()
bool bb = b; // error copy-initialization does not consider B::operator bool()
All members of an inline namespace are treated as if they were part of its parent namespace, allowing specialization of functions and easing the process of versioning. This is a transitive property, if A contains B, which in turn contains C and both B and C are inline namespaces, C's members can be used as if they were on A.
namespace Program {
namespace Version1 {
int getVersion() { return 1; }
bool isFirstVersion() { return true; }
}
inline namespace Version2 {
int getVersion() { return 2; }
}
}
int version {Program::getVersion()}; // Uses getVersion() from Version2
int oldVersion {Program::Version1::getVersion()}; // Uses getVersion() from Version1
bool firstVersion {Program::isFirstVersion()}; // Does not compile when Version2 is added
Allows non-static data members to be initialized where they are declared, potentially cleaning up constructors of default initializations.
// Default initialization prior to C++11
class Human {
Human() : age{0} {}
private:
unsigned age;
};
// Default initialization on C++11
class Human {
private:
unsigned age {0};
};
C++11 is now able to infer when a series of right angle brackets is used as an operator or as a closing statement of typedef, without having to add whitespace.
typedef std::map<int, std::map <int, std::map <int, int> > > cpp98LongTypedef;
typedef std::map<int, std::map <int, std::map <int, int>>> cpp11LongTypedef;
Member functions can now be qualified depending on whether *this
is an lvalue or rvalue reference.
struct Bar {
// ...
};
struct Foo {
Bar getBar() & { return bar; }
Bar getBar() const& { return bar; }
Bar getBar() && { return std::move(bar); }
Bar getBar() const&& { return std::move(bar); }
private:
Bar bar;
};
Foo foo{};
Bar bar = foo.getBar(); // calls `Bar getBar() &`
const Foo foo2{};
Bar bar2 = foo2.getBar(); // calls `Bar Foo::getBar() const&`
Foo{}.getBar(); // calls `Bar Foo::getBar() &&`
std::move(foo).getBar(); // calls `Bar Foo::getBar() &&`
std::move(foo2).getBar(); // calls `Bar Foo::getBar() const&&`
C++11 allows functions and lambdas an alternative syntax for specifying their return types.
int f() {
return 123;
}
// vs.
auto f() -> int {
return 123;
}
auto g = []() -> int {
return 123;
};
This feature is especially useful when certain return types cannot be resolved:
// NOTE: This does not compile!
template <typename T, typename U>
decltype(a + b) add(T a, U b) {
return a + b;
}
// Trailing return types allows this:
template <typename T, typename U>
auto add(T a, U b) -> decltype(a + b) {
return a + b;
}
In C++14, decltype(auto) can be used instead.
The noexcept
specifier specifies whether a function could throw exceptions. It is an improved version of throw()
.
void func1() noexcept; // does not throw
void func2() noexcept(true); // does not throw
void func3() throw(); // does not throw
void func4() noexcept(false); // may throw
Non-throwing functions are permitted to call potentially-throwing functions. Whenever an exception is thrown and the search for a handler encounters the outermost block of a non-throwing function, the function std::terminate is called.
extern void f(); // potentially-throwing
void g() noexcept {
f(); // valid, even if f throws
throw 42; // valid, effectively a call to std::terminate
}
Provides standard types for representing UTF-8 strings.
char32_t utf8_str[] = U"\u0123";
char16_t utf8_str[] = u"\u0123";
C++11 introduces a new way to declare string literals as "raw string literals". Characters issued from an escape sequence (tabs, line feeds, single backslashes, etc.) can be inputted raw while preserving formatting. This is useful, for example, to write literary text, which might contain a lot of quotes or special formatting. This can make your string literals easier to read and maintain.
A raw string literal is declared using the following syntax:
R"delimiter(raw_characters)delimiter"
where:
delimiter
is an optional sequence of characters made of any source character except parentheses, backslashes and spaces.raw_characters
is any raw character sequence; must not contain the closing sequence")delimiter"
.
Example:
// msg1 and msg2 are equivalent.
const char* msg1 = "\nHello,\n\tworld!\n";
const char* msg2 = R"(
Hello,
world!
)";
std::move
indicates that the object passed to it may have its resources transferred. Using objects that have been moved from should be used with care, as they can be left in an unspecified state (see: What can I do with a moved-from object?).
A definition of std::move
(performing a move is nothing more than casting to an rvalue reference):
template <typename T>
typename remove_reference<T>::type&& move(T&& arg) {
return static_cast<typename remove_reference<T>::type&&>(arg);
}
Transferring std::unique_ptr
s:
std::unique_ptr<int> p1 {new int{0}}; // in practice, use std::make_unique
std::unique_ptr<int> p2 = p1; // error -- cannot copy unique pointers
std::unique_ptr<int> p3 = std::move(p1); // move `p1` into `p3`
// now unsafe to dereference object held by `p1`
Returns the arguments passed to it while maintaining their value category and cv-qualifiers. Useful for generic code and factories. Used in conjunction with forwarding references
.
A definition of std::forward
:
template <typename T>
T&& forward(typename remove_reference<T>::type& arg) {
return static_cast<T&&>(arg);
}
An example of a function wrapper
which just forwards other A
objects to a new A
object's copy or move constructor:
struct A {
A() = default;
A(const A& o) { std::cout << "copied" << std::endl; }
A(A&& o) { std::cout << "moved" << std::endl; }
};
template <typename T>
A wrapper(T&& arg) {
return A{std::forward<T>(arg)};
}
wrapper(A{}); // moved
A a;
wrapper(a); // copied
wrapper(std::move(a)); // moved
See also: forwarding references
, rvalue references
.
The std::thread
library provides a standard way to control threads, such as spawning and killing them. In the example below, multiple threads are spawned to do different calculations and then the program waits for all of them to finish.
void foo(bool clause) { /* do something... */ }
std::vector<std::thread> threadsVector;
threadsVector.emplace_back([]() {
// Lambda function that will be invoked
});
threadsVector.emplace_back(foo, true); // thread will run foo(true)
for (auto& thread : threadsVector) {
thread.join(); // Wait for threads to finish
}
Converts a numeric argument to a std::string
.
std::to_string(1.2); // == "1.2"
std::to_string(123); // == "123"
Type traits defines a compile-time template-based interface to query or modify the properties of types.
static_assert(std::is_integral<int>::value);
static_assert(std::is_same<int, int>::value);
static_assert(std::is_same<std::conditional<true, int, double>::type, int>::value);
C++11 introduces new smart pointers: std::unique_ptr
, std::shared_ptr
, std::weak_ptr
. std::auto_ptr
now becomes deprecated and then eventually removed in C++17.
std::unique_ptr
is a non-copyable, movable pointer that manages its own heap-allocated memory. Note: Prefer using the std::make_X
helper functions as opposed to using constructors. See the sections for std::make_unique and std::make_shared.
std::unique_ptr<Foo> p1 {new Foo{}}; // `p1` owns `Foo`
if (p1) {
p1->bar();
}
{
std::unique_ptr<Foo> p2 {std::move(p1)}; // Now `p2` owns `Foo`
f(*p2);
p1 = std::move(p2); // Ownership returns to `p1` -- `p2` gets destroyed
}
if (p1) {
p1->bar();
}
// `Foo` instance is destroyed when `p1` goes out of scope
A std::shared_ptr
is a smart pointer that manages a resource that is shared across multiple owners. A shared pointer holds a control block which has a few components such as the managed object and a reference counter. All control block access is thread-safe, however, manipulating the managed object itself is not thread-safe.
void foo(std::shared_ptr<T> t) {
// Do something with `t`...
}
void bar(std::shared_ptr<T> t) {
// Do something with `t`...
}
void baz(std::shared_ptr<T> t) {
// Do something with `t`...
}
std::shared_ptr<T> p1 {new T{}};
// Perhaps these take place in another threads?
foo(p1);
bar(p1);
baz(p1);
The chrono library contains a set of utility functions and types that deal with durations, clocks, and time points. One use case of this library is benchmarking code:
std::chrono::time_point<std::chrono::steady_clock> start, end;
start = std::chrono::steady_clock::now();
// Some computations...
end = std::chrono::steady_clock::now();
std::chrono::duration<double> elapsed_seconds = end - start;
double t = elapsed_seconds.count(); // t number of seconds, represented as a `double`
Tuples are a fixed-size collection of heterogeneous values. Access the elements of a std::tuple
by unpacking using std::tie
, or using std::get
.
// `playerProfile` has type `std::tuple<int, const char*, const char*>`.
auto playerProfile = std::make_tuple(51, "Frans Nielsen", "NYI");
std::get<0>(playerProfile); // 51
std::get<1>(playerProfile); // "Frans Nielsen"
std::get<2>(playerProfile); // "NYI"
Creates a tuple of lvalue references. Useful for unpacking std::pair
and std::tuple
objects. Use std::ignore
as a placeholder for ignored values. In C++17, structured bindings should be used instead.
// With tuples...
std::string playerName;
std::tie(std::ignore, playerName, std::ignore) = std::make_tuple(91, "John Tavares", "NYI");
// With pairs...
std::string yes, no;
std::tie(yes, no) = std::make_pair("yes", "no");
std::array
is a container built on top of a C-style array. Supports common container operations such as sorting.
std::array<int, 3> a = {2, 1, 3};
std::sort(a.begin(), a.end()); // a == { 1, 2, 3 }
for (int& x : a) x *= 2; // a == { 2, 4, 6 }
These containers maintain average constant-time complexity for search, insert, and remove operations. In order to achieve constant-time complexity, sacrifices order for speed by hashing elements into buckets. There are four unordered containers:
unordered_set
unordered_multiset
unordered_map
unordered_multimap
std::make_shared
is the recommended way to create instances of std::shared_ptr
s due to the following reasons:
- Avoid having to use the
new
operator. - Prevents code repetition when specifying the underlying type the pointer shall hold.
- It provides exception-safety. Suppose we were calling a function
foo
like so:
foo(std::shared_ptr<T>{new T{}}, function_that_throws(), std::shared_ptr<T>{new T{}});
The compiler is free to call new T{}
, then function_that_throws()
, and so on... Since we have allocated data on the heap in the first construction of a T
, we have introduced a leak here. With std::make_shared
, we are given exception-safety:
foo(std::make_shared<T>(), function_that_throws(), std::make_shared<T>());
- Prevents having to do two allocations. When calling
std::shared_ptr{ new T{} }
, we have to allocate memory forT
, then in the shared pointer we have to allocate memory for the control block within the pointer.
See the section on smart pointers for more information on std::unique_ptr
and std::shared_ptr
.
std::ref(val)
is used to create object of type std::reference_wrapper
that holds reference of val. Used in cases when usual reference passing using &
does not compile or &
is dropped due to type deduction. std::cref
is similar but created reference wrapper holds a const reference to val.
// create a container to store reference of objects.
auto val = 99;
auto _ref = std::ref(val);
_ref++;
auto _cref = std::cref(val);
//_cref++; does not compile
std::vector<std::reference_wrapper<int>>vec; // vector<int&>vec does not compile
vec.push_back(_ref); // vec.push_back(&i) does not compile
cout << val << endl; // prints 100
cout << vec[0] << endl; // prints 100
cout << _cref; // prints 100
C++11 introduces a memory model for C++, which means library support for threading and atomic operations. Some of these operations include (but aren't limited to) atomic loads/stores, compare-and-swap, atomic flags, promises, futures, locks, and condition variables.
See the sections on: std::thread
std::async
runs the given function either asynchronously or lazily-evaluated, then returns a std::future
which holds the result of that function call.
The first parameter is the policy which can be:
std::launch::async | std::launch::deferred
It is up to the implementation whether to perform asynchronous execution or lazy evaluation.std::launch::async
Run the callable object on a new thread.std::launch::deferred
Perform lazy evaluation on the current thread.
int foo() {
/* Do something here, then return the result. */
return 1000;
}
auto handle = std::async(std::launch::async, foo); // create an async task
auto result = handle.get(); // wait for the result
std::begin
and std::end
free functions were added to return begin and end iterators of a container generically. These functions also work with raw arrays which do not have begin
and end
member functions.
template <typename T>
int CountTwos(const T& container) {
return std::count_if(std::begin(container), std::end(container), [](int item) {
return item == 2;
});
}
std::vector<int> vec = {2, 2, 43, 435, 4543, 534};
int arr[8] = {2, 43, 45, 435, 32, 32, 32, 32};
auto a = CountTwos(vec); // 2
auto b = CountTwos(arr); // 1
- cppreference - especially useful for finding examples and documentation of new library features.
- C++ Rvalue References Explained - a great introduction I used to understand rvalue references, perfect forwarding, and move semantics.
- clang and gcc's standards support pages. Also included here are the proposals for language/library features that I used to help find a description of, what it's meant to fix, and some examples.
- Compiler explorer
- Scott Meyers' Effective Modern C++ - highly recommended book!
- Jason Turner's C++ Weekly - nice collection of C++-related videos.
- What can I do with a moved-from object?
- What are some uses of decltype(auto)?
- And many more SO posts I'm forgetting...
Anthony Calandra
See: https://github.com/AnthonyCalandra/modern-cpp-features/graphs/contributors
MIT