new expression
Creates and initializes objects with dynamic storage duration, that is, objects whose lifetime is not limited by the scope in which they were created.
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[edit] Syntax
:: (optional) new ( placement_params) (optional) ( type ) initializer(optional)
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(1) | ||||||||
:: (optional) new ( placement_params) (optional) type initializer(optional)
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(2) | ||||||||
type
, which may be array type, and may include the type specifier auto
(since C++11).type
cannot include parentheses:
new int(*[10])(); // parser error: parsed as (new int) (*[10]) () new (int (*[10])()); // OK: allocates an array of 10 pointers to functions
In addition, unparenthesized type is greedy: it will include every token that can be a part of a declarator:
new int + 1; // OK: parsed as (new int) + 1, increments a pointer returned by new int new int * 1; // Error: parsed as (new int*) (1)
Note: If auto
is used in type
, then initializer
is not optional: it is required to deduce the type to use in place of auto
:
auto p = new auto('c'); // creates a single object of type char. p is a char*
[edit] Explanation
The new
expression attempts to allocate storage and then attempts to construct and initialize either a single unnamed object, or an unnamed array of objects in the allocated storage. The new-expression returns a prvalue pointer to the constructed object or, if an array of objects was constructed, a pointer to the initial element of the array.
If type
is an array type, all dimensions other than the first must be specified as positive converted constant expression of type std::size_t, but the first dimension may be any expression convertible to std::size_t. This is the only way to directly create an array with size defined at runtime, such arrays are often referred to as dynamic arrays:
int n = 42; double a[n][5]; // Error auto p1 = new double[n][5]; // OK auto p2 = new double[5][n]; // Error
In the following cases the expression specifying the first dimension is erroneous:
- the expression is of non-class type and its value before conversion to std::size_t is negative
- the expression is of class type and its value after user-defined conversion function and before the second standard conversion is negative
- the value of the expression is larger than some implementation-defined limit
- the value is smaller than the number of array elements provided in the brace-enclosed initializer (including the terminating '\0' on a string literal)
If the value in the first dimension is erroneous for any of these reasons,
- if, after conversion to std::size_t, the first dimension is a core constant expression, the program is ill-formed.
- Otherwise, the new expression does not call the allocation function, and instead throws an excetion of type std::bad_array_new_length or derived from it (since C++11).
The first dimension of zero is acceptable, and the allocation function is called.
Note: std::vector offers similar functionality for one-dimensional dynamic arrays.
[edit] Allocation
The new-expression allocates storage by calling the appropriate allocation function. If type
is a non-array type, the name of the function is operator new()
. If type
is an array type, the name of the function is operator new[]()
.
As described in allocation function, the C++ program may provide global and class-specific replacements for these functions. If the new-expression begins with the optional :: operator, as in ::new T or ::new T[n], class-specific replacements will be ignored (the function is looked up in global scope). Otherwise, if T
is a class type, it is looked up in the scope of T
first.
When calling the allocation function, the new-expression passes the number of bytes requested as the first argument, of type size_t
, which is exactly sizeof(T) for non-array T
.
Array allocation may supply unspecified overhead, which may vary from one call to new to the next. The pointer returned by the new-expression will be offset by that value from the pointer returned by the allocation function. Many implementations use the array overhead to store the number of objects in the array which is used by operator delete[] to call the correct number of destructors. In addition, if the new-expression is used to allocate an array of char or an array unsigned char, it may request additional memory from the allocation function if necessary to guarantee correct alignment of objects of all types no larger than the requested array size, if one is later placed into the allocated array.
New expressions are allowed to combine allocations made through replaceable allocation functions: the allocation made by a new-expression E1 may be extended to provide additional storage for another new-expression E2 if all of the following is true:
1) The lifetime of the object allocated by E1 strictly contains the lifetime of the object allocated by E2,
2) E1 and E2 would invoke the same replaceable global allocation function
3) For a throwing allocation function, exceptions in E1 and E2 would be first caught in the same handler.
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(since C++14) |
If placement_params
are provided, they are passed to the allocation function as additional arguments:
new T; // calls operator new( sizeof(T) ) new T[5]; // calls operator new[]( sizeof(T)*5 + overhead) new(2,f) T; // calls operator new( sizeof(T), 2, f)
Such allocation functions are known as "placement new", after the standard allocation function void* operator new(std::size_t, void*), which simply returns its second argument unchanged. This is used to construct objects in allocated storage:
char* ptr = new char[sizeof(T)]; // allocate memory T* tptr = new(ptr) T; // construct in allocated storage ("place") tptr->~T(); // destruct delete[] ptr; // deallocate
Note: this functionality is encapsulated by the member functions of the Allocator
classes.
If the allocation function return a null pointer, which is possible if the non-throwing overload was selected, e.g. with new(std::nothrow) T;, then the new-expression returns immediately, it does not attempt to initialize an object or to call a deallocation function.
[edit] Construction
The object created by a new expression is initialized according to the following rules:
- For non-array
type
, the single object is constructed in the acquired memory area.
-
- If initializer is absent, the object is default-initialized.
- If initializer is a parenthesized list of arguments, the object is direct-initialized.
- If initializer is a brace-enclosed list of arguments(since C++11), the object is list-initialized.
- If type is an array type, an array of objects is initialized.
-
- If initializer is absent, each element is default-initialized
- If initializer is an empty pair of parentheses, each element is value-initialized.
- If initializer is a brace-enclosed list of arguments(since C++11), the elements of the array are aggregate-initialized.
If initialization terminates by throwing an exception (e.g. from the constructor), if new-expression allocated any storage, it calls the appropriate deallocation function: operator delete() for non-array type
, operator delete[]() for array type
. The deallocation function is looked up in global scope if the new expression used the ::new syntax, otherwise it is looked up in the scope of T
first, if T
is a class type. If no deallocation function is found, memory is not deallocated. The value obtained earlier from the allocation function is passed as the first argument to the deallocation function.
[edit] Memory leaks
The objects created by new expressions (objects with dynamic storage duration) persist until the pointer returned by the new expression is used in a matching delete-expression. If the original value of pointer is lost, the object becomes unreachable and cannot be deallocated: a memory leak occurs.
This may happen if the pointer is assigned to:
int* p = new int(7); // dynamically allocated int with value 7 p = NULL; // memory leak
or if the pointer goes out of scope:
void f() { int* p = new int(7); } // memory leak
or due to exception
void f() { int* p = new int(7); g(); // may throw delete p; // OK if no exception } // memory leak if g() throws
To simplify management of dynamically-allocated objects, the result of a new-expression is often stored in a smart pointer: std::unique_ptr, std::shared_ptr, or std::auto_ptr(deprecated). These pointers guarantee that the delete expression is executed in the situations shown above.