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std.experimental.allocator.typed

This module defines TypedAllocator, a statically-typed allocator that aggregates multiple untyped allocators and uses them depending on the static properties of the types allocated. For example, distinct allocators may be used for thread-local vs. thread-shared data, or for fixed-size data (struct, class objects) vs. resizable data (arrays).
enum AllocFlag: uint;
Allocation-related flags dictated by type characteristics. TypedAllocator deduces these flags from the type being allocated and uses the appropriate allocator accordingly.
fixedSize
Fixed-size allocation (unlikely to get reallocated later). Examples: int, double, any struct or class type. By default it is assumed that the allocation is variable-size, i.e. susceptible to later reallocation (for example all array types). This flag is advisory, i.e. in-place resizing may be attempted for fixedSize allocations and may succeed. The flag is just a hint to the compiler it may use allocation strategies that work well with objects of fixed size.
hasNoIndirections
The type being allocated embeds no pointers. Examples: int, int[], Tuple!(int, float). The implicit conservative assumption is that the type has members with indirections so it needs to be scanned if garbage collected. Example of types with pointers: int*[], Tuple!(int, string).
immutableShared
threadLocal
By default it is conservatively assumed that allocated memory may be cast to shared, passed across threads, and deallocated in a different thread than the one that allocated it. If that's not the case, there are two options. First, immutableShared means the memory is allocated for immutable data and will be deallocated in the same thread it was allocated in. Second, threadLocal means the memory is not to be shared across threads at all. The two flags cannot be simultaneously present.
struct TypedAllocator(PrimaryAllocator, Policies...);
TypedAllocator acts like a chassis on which several specialized allocators can be assembled. To let the system make a choice about a particular kind of allocation, use Default for the respective parameters.
There is a hierarchy of allocation kinds. When an allocator is implemented for a given combination of flags, it is used. Otherwise, the next down the list is chosen.

AllocFlag combination Description
AllocFlag.threadLocal | AllocFlag.hasNoIndirections | AllocFlag.fixedSize This is the most specific allocation policy: the memory being allocated is thread local, has no indirections at all, and will not be reallocated. Examples of types fitting this description: int, double, Tuple!(int, long), but not Tuple!(int, string), which contains an indirection.
AllocFlag.threadLocal | AllocFlag.hasNoIndirections As above, but may be reallocated later. Examples of types fitting this description are int[], double[], Tuple!(int, long)[], but not Tuple!(int, string)[], which contains an indirection.
AllocFlag.threadLocal As above, but may embed indirections. Examples of types fitting this description are int*[], Object[], Tuple!(int, string)[].
AllocFlag.immutableShared | AllocFlag.hasNoIndirections | AllocFlag.fixedSize The type being allocated is immutable and has no pointers. The thread that allocated it must also deallocate it. Example: immutable(int).
AllocFlag.immutableShared | AllocFlag.hasNoIndirections As above, but the type may be appended to in the future. Example: string.
AllocFlag.immutableShared As above, but the type may embed references. Example: immutable(Object)[].
AllocFlag.hasNoIndirections | AllocFlag.fixedSize The type being allocated may be shared across threads, embeds no indirections, and has fixed size.
AllocFlag.hasNoIndirections The type being allocated may be shared across threads, may embed indirections, and has variable size.
AllocFlag.fixedSize The type being allocated may be shared across threads, may embed indirections, and has fixed size.
0 The most conservative/general allocation: memory may be shared, deallocated in a different thread, may or may not be resized, and may embed references.
Parameters:
PrimaryAllocator The default allocator.
Policies Zero or more pairs consisting of an AllocFlag and an allocator type.
Examples:
import std.experimental.allocator.gc_allocator : GCAllocator;
import std.experimental.allocator.mallocator : Mallocator;
import std.experimental.allocator.mmap_allocator : MmapAllocator;
alias MyAllocator = TypedAllocator!(GCAllocator,
    AllocFlag.fixedSize | AllocFlag.threadLocal, Mallocator,
    AllocFlag.fixedSize | AllocFlag.threadLocal
            | AllocFlag.hasNoIndirections,
        MmapAllocator,
);
MyAllocator a;
auto b = &a.allocatorFor!0();
static assert(is(typeof(*b) == shared GCAllocator));
enum f1 = AllocFlag.fixedSize | AllocFlag.threadLocal;
auto c = &a.allocatorFor!f1();
static assert(is(typeof(*c) == Mallocator));
enum f2 = AllocFlag.fixedSize | AllocFlag.threadLocal;
static assert(is(typeof(a.allocatorFor!f2()) == Mallocator));
// Partial match
enum f3 = AllocFlag.threadLocal;
static assert(is(typeof(a.allocatorFor!f3()) == Mallocator));

int* p = a.make!int;
scope(exit) a.dispose(p);
int[] arr = a.makeArray!int(42);
scope(exit) a.dispose(arr);
assert(a.expandArray(arr, 3));
assert(a.shrinkArray(arr, 4));
ref auto allocatorFor(uint flags)();
ref auto allocatorFor(T)();
Given flags as a combination of AllocFlag values, or a type T, returns the allocator that's a closest fit in capabilities.
uint type2flags(T)();
Given a type T, returns its allocation-related flags as a combination of AllocFlag values.
auto make(T, A...)(auto ref A args);
Dynamically allocates (using the appropriate allocator chosen with allocatorFor!T) and then creates in the memory allocated an object of type T, using args (if any) for its initialization. Initialization occurs in the memory allocated and is otherwise semantically the same as T(args). (Note that using make!(T[]) creates a pointer to an (empty) array of Ts, not an array. To allocate and initialize an array, use makeArray!T described below.)
Parameters:
T Type of the object being created.
A args Optional arguments used for initializing the created object. If not present, the object is default constructed.
Returns:
If T is a class type, returns a reference to the created T object. Otherwise, returns a T* pointing to the created object. In all cases, returns null if allocation failed.
Throws:
If T's constructor throws, deallocates the allocated memory and propagates the exception.
T[] makeArray(T)(size_t length);
T[] makeArray(T)(size_t length, auto ref T init);
T[] makeArray(T, R)(R range) if (isInputRange!R);
Create an array of T with length elements. The array is either default-initialized, filled with copies of init, or initialized with values fetched from range.
Parameters:
T element type of the array being created
size_t length length of the newly created array
T init element used for filling the array
R range range used for initializing the array elements
Returns:
The newly-created array, or null if either length was 0 or allocation failed.
Throws:
The first two overloads throw only if the used allocator's primitives do. The overloads that involve copy initialization deallocate memory and propagate the exception if the copy operation throws.
bool expandArray(T)(ref T[] array, size_t delta);
bool expandArray(T)(T[] array, size_t delta, auto ref T init);
bool expandArray(T, R)(ref T[] array, R range) if (isInputRange!R);
Grows array by appending delta more elements. The needed memory is allocated using the same allocator that was used for the array type. The extra elements added are either default-initialized, filled with copies of init, or initialized with values fetched from range.
Parameters:
T element type of the array being created
T[] array a reference to the array being grown
size_t delta number of elements to add (upon success the new length of array is array.length + delta)
T init element used for filling the array
R range range used for initializing the array elements
Returns:
true upon success, false if memory could not be allocated. In the latter case array is left unaffected.
Throws:
The first two overloads throw only if the used allocator's primitives do. The overloads that involve copy initialization deallocate memory and propagate the exception if the copy operation throws.
bool shrinkArray(T)(ref T[] arr, size_t delta);
Shrinks an array by delta elements using allocatorFor!(T[]).
If arr.length < delta, does nothing and returns false. Otherwise, destroys the last arr.length - delta elements in the array and then reallocates the array's buffer. If reallocation fails, fills the array with default-initialized data.
Parameters:
T element type of the array being created
T[] arr a reference to the array being shrunk
size_t delta number of elements to remove (upon success the new length of arr is arr.length - delta)
Returns:
true upon success, false if memory could not be reallocated. In the latter case arr[$ - delta .. $] is left with default-initialized elements.
Throws:
The first two overloads throw only if the used allocator's primitives do. The overloads that involve copy initialization deallocate memory and propagate the exception if the copy operation throws.
void dispose(T)(T* p);
void dispose(T)(T p) if (is(T == class) || is(T == interface));
void dispose(T)(T[] array);
Destroys and then deallocates (using allocatorFor!T) the object pointed to by a pointer, the class object referred to by a class or interface reference, or an entire array. It is assumed the respective entities had been allocated with the same allocator.