Types
Grammar
D is statically typed. Every expression has a type. Types constrain the values an expression can hold, and determine the semantics of operations on those values.
Type: TypeCtorsopt BasicType TypeSuffixesopt TypeCtors: TypeCtor TypeCtor TypeCtors TypeCtor: const immutable inout shared BasicType: FundamentalType . QualifiedIdentifier QualifiedIdentifier Typeof Typeof . QualifiedIdentifier TypeCtor ( Type ) Vector TraitsExpression MixinType Vector: __vector ( VectorBaseType ) VectorBaseType: Type FundamentalType: bool byte ubyte short ushort int uint long ulong cent ucent char wchar dchar float double real ifloat idouble ireal cfloat cdouble creal void TypeSuffixes: TypeSuffix TypeSuffixesopt TypeSuffix: * [ ] [ AssignExpression ] [ AssignExpression .. AssignExpression ] [ Type ] delegate Parameters MemberFunctionAttributesopt function Parameters FunctionAttributesopt QualifiedIdentifier: Identifier Identifier . QualifiedIdentifier TemplateInstance TemplateInstance . QualifiedIdentifier Identifier [ AssignExpression ] Identifier [ AssignExpression ] . QualifiedIdentifier
- Basic Data Types are leaf types.
- Derived Data Types build on leaf types.
- User-Defined Types are aggregates of basic and derived types.
Basic Data Types
Keyword | Default Initializer (.init) | Description |
---|---|---|
void | no default initializer | void has no value |
bool | false | boolean value |
byte | 0 | signed 8 bits |
ubyte | 0u | unsigned 8 bits |
short | 0 | signed 16 bits |
ushort | 0u | unsigned 16 bits |
int | 0 | signed 32 bits |
uint | 0u | unsigned 32 bits |
long | 0L | signed 64 bits |
ulong | 0uL | unsigned 64 bits |
cent | 0 | signed 128 bits |
ucent | 0u | unsigned 128 bits |
float | float.nan | 32 bit floating point |
double | double.nan | 64 bit floating point |
real | real.nan | largest floating point size available |
ifloat | float.nan*1.0i | imaginary float |
idouble | double.nan*1.0i | imaginary double |
ireal | real.nan*1.0i | imaginary real |
cfloat | float.nan+float.nan*1.0i | a complex number of two float values |
cdouble | double.nan+double.nan*1.0i | complex double |
creal | real.nan+real.nan*1.0i | complex real |
char | '\xFF' | unsigned 8 bit (UTF-8 code unit) |
wchar | '\uFFFF' | unsigned 16 bit (UTF-16 code unit) |
dchar | '\U0000FFFF' | unsigned 32 bit (UTF-32 code unit) |
Endianness of basic types is part of the ABI
NOTE: Complex and imaginary types ifloat, idouble, ireal, cfloat, cdouble, and creal have been deprecated in favor of std.complex.Complex.
Derived Data Types
Pointers
A pointer to type T has a value which is a reference (address) to another object of type T. It is commonly called a pointer to T and its type is T*. To access the object value, use the * dereference operator:
int* p; assert(p == null); p = new int(5); assert(p != null); assert(*p == 5); (*p)++; assert(*p == 6);
If a pointer contains a null value, it is not pointing to a valid object.
When a pointer to T is dereferenced, it must either contain a null value, or point to a valid object of type T.
- The behavior when a null pointer is dereferenced. Typically the program will be aborted.
To set a pointer to point at an existing object, use the & address of operator:
int i = 2; int* p = &i; assert(p == &i); assert(*p == 2); *p = 4; assert(i == 4);
See also Pointer Arithmetic.
User-Defined Types
Type Conversions
See also: CastExpression.Pointer Conversions
Pointers implicitly convert to void*.
Casting between pointers and non-pointers is allowed. Some pointer casts are disallowed in @safe code.
Implicit Conversions
Implicit conversions are used to automatically convert types as required. The rules for integers are detailed in the next sections.
An enum can be implicitly converted to its base type, but going the other way requires an explicit conversion. For example:
int i; enum Foo { E } Foo f; i = f; // OK f = i; // error f = cast(Foo)i; // OK f = 0; // error f = Foo.E; // OK
- All types implicitly convert to noreturn.
- Static and dynamic arrays implicitly convert to void[].
- Function pointers and delegates can convert to covariant types.
Class Conversions
A derived class can be implicitly converted to its base class, but going the other way requires an explicit cast. For example:
class Base {} class Derived : Base {} Base bd = new Derived(); // implicit conversion Derived db = cast(Derived)new Base(); // explicit conversion
A dynamic array, say x, of a derived class can be implicitly converted to a dynamic array, say y, of a base class iff elements of x and y are qualified as being either both const or both immutable.
class Base {} class Derived : Base {} const(Base)[] ca = (const(Derived)[]).init; // `const` elements immutable(Base)[] ia = (immutable(Derived)[]).init; // `immutable` elements
A static array, say x, of a derived class can be implicitly converted to a static array, say y, of a base class iff elements of x and y are qualified as being either both const or both immutable or both mutable (neither const nor immutable).
class Base {} class Derived : Base {} Base[3] ma = (Derived[3]).init; // mutable elements const(Base)[3] ca = (const(Derived)[3]).init; // `const` elements immutable(Base)[3] ia = (immutable(Derived)[3]).init; // `immutable` elements
Integer Promotions
Integer Promotions are conversions of the following types:
from | to |
---|---|
bool | int |
byte | int |
ubyte | int |
short | int |
ushort | int |
char | int |
wchar | int |
dchar | uint |
If an enum has as a base type one of the types in the left column, it is converted to the type in the right column.
Integer promotion applies to each operand of a binary expression:
void fun() { byte a; auto b = a + a; static assert(is(typeof(b) == int)); // error: can't implicitly convert expression of type int to byte: //byte c = a + a; ushort d; // error: can't implicitly convert expression of type int to ushort: //d = d * d; int e = d * d; // OK static assert(is(typeof(int() * d) == int)); dchar f; static assert(is(typeof(f - f) == uint)); }
- 32-bit integer operations are often faster than smaller integer types for single variables on modern architectures.
- Promotion helps avoid accidental overflow which is more common with small integer types.
Usual Arithmetic Conversions
The usual arithmetic conversions convert operands of binary operators to a common type. The operands must already be of arithmetic types. The following rules are applied in order, looking at the base type:
- If either operand is real, the other operand is converted to real.
- Else if either operand is double, the other operand is converted to double.
- Else if either operand is float, the other operand is converted to float.
- Else the integer promotions above are done on each operand,
followed by:
- If both are the same type, no more conversions are done.
- If both are signed or both are unsigned, the smaller type is converted to the larger.
- If the signed type is larger than the unsigned type, the unsigned type is converted to the signed type.
- The signed type is converted to the unsigned type.
Example: Signed and unsigned conversions:
int i; uint u; static assert(is(typeof(i + u) == uint)); static assert(is(typeof(short() + u) == uint)); static assert(is(typeof(ulong() + i) == ulong)); static assert(is(typeof(long() - u) == long)); static assert(is(typeof(long() * ulong()) == ulong));
Example: Floating point:
float f; static assert(is(typeof(f + ulong()) == float)); double d; static assert(is(typeof(f * d) == double)); static assert(is(typeof(real() / d) == real));
If one or both of the operand types is an enum after undergoing the above conversions, the result type is:
- If the operands are the same type, the result will be of that type.
- If one operand is an enum and the other is the base type of that enum, the result is the base type.
- If the two operands are different enums, the result is the closest base type common to both. A base type being closer means there is a shorter sequence of conversions to base type to get there from the original type.
Integer values cannot be implicitly converted to another type that cannot represent the integer bit pattern after integral promotion. For example:
ubyte u1 = -1; // error, -1 cannot be represented in a ubyte ushort u2 = -1; // error, -1 cannot be represented in a ushort uint u3 = int(-1); // ok, -1 can be represented in an int, which can be converted to a uint ulong u4 = long(-1); // ok, -1 can be represented in a long, which can be converted to a ulong
Floating point types cannot be implicitly converted to integral types. Complex or imaginary floating point types cannot be implicitly converted to non-complex floating point types. Non-complex floating point types cannot be implicitly converted to imaginary floating point types.
Value Range Propagation
Besides type-based implicit conversions, D allows certain integer expressions to implicitly convert to a narrower type after integer promotion. This works by analysing the minimum and maximum possible range of values for each expression. If that range of values matches or is a subset of a narrower target type's value range, implicit conversion is allowed. If a subexpression is known at compile-time, that can further narrow the range of values.
void fun(char c, int i, ubyte b) { // min is c.min + 100 > short.min // max is c.max + 100 < short.max short s = c + 100; // OK ubyte j = i & 0x3F; // OK, 0 ... 0x3F //ubyte k = i & 0x14A; // error, 0x14A > ubyte.max ushort k = i & 0x14A; // OK k = i & b; // OK, 0 ... b.max //b = b + b; // error, b.max + b.max > b.max s = b + b; // OK, 0 ... b.max + b.max }
Note the implementation does not track the range of possible values for mutable variables:
void fun(int i) { ushort s = i & 0xff; // OK // s is now assumed to be s.min ... s.max, not 0 ... 0xff //ubyte b = s; // error ubyte b = s & 0xff; // OK const int c = i & 0xff; // c's range is fixed and known b = c; // OK }
- For more information, see the dmc article.
- See also: https://en.wikipedia.org/wiki/Value_range_analysis.
bool
The bool type is a byte-size type that can only hold the value true or false.
The only operators that can accept operands of type bool are: & |, ^, &=, |=, ^=, !, &&, ||, and ?:.
A bool value can be implicitly converted to any integral type, with false becoming 0 and true becoming 1.
The numeric literals 0 and 1 can be implicitly converted to the bool values false and true, respectively. Casting an expression to bool means testing for 0 or !=0 for arithmetic types, and null or !=null for pointers or references.
Delegates
Delegates are an aggregate of two pieces of data: an object reference and a pointer to a non-static member function, or a pointer to a closure and a pointer to a nested function. The object reference forms the this pointer when the function is called.
Delegates are declared similarly to function pointers:
int function(int) fp; // fp is pointer to a function int delegate(int) dg; // dg is a delegate to a function
A delegate is initialized analogously to function pointers:
int func(int); fp = &func; // fp points to func class OB { int member(int); } OB o; dg = &o.member; // dg is a delegate to object o and // member function member
Delegates cannot be initialized with static member functions or non-member functions.
Delegates are called analogously to function pointers:
fp(3); // call func(3) dg(3); // call o.member(3)
The equivalent of member function pointers can be constructed using anonymous lambda functions:
class C { int a; int foo(int i) { return i + a; } } // mfp is the member function pointer auto mfp = function(C self, int i) { return self.foo(i); }; auto c = new C(); // create an instance of C mfp(c, 1); // and call c.foo(1)
The C style syntax for declaring pointers to functions is deprecated:
int (*fp)(int); // fp is pointer to a function
typeof
Typeof: typeof ( Expression ) typeof ( return )
typeof is a way to specify a type based on the type of an expression. For example:
void func(int i) { typeof(i) j; // j is of type int typeof(3 + 6.0) x; // x is of type double typeof(1)* p; // p is of type pointer to int int[typeof(p)] a; // a is of type int[int*] writeln(typeof('c').sizeof); // prints 1 double c = cast(typeof(1.0))j; // cast j to double }
Expression is not evaluated, it is used purely to generate the type:
void func() { int i = 1; typeof(++i) j; // j is declared to be an int, i is not incremented writeln(i); // prints 1 }
If Expression is a ValueSeq it will produce a TypeSeq containing the types of each element.
Special cases:
- typeof(return) will, when inside a function scope, give the return type of that function.
- typeof(this) will generate the type of what this would be in a non-static member function, even if not in a member function.
- Analogously, typeof(super) will generate the type of what super would be in a non-static member function.
class A { } class B : A { typeof(this) x; // x is declared to be a B typeof(super) y; // y is declared to be an A } struct C { static typeof(this) z; // z is declared to be a C typeof(super) q; // error, no super struct for C } typeof(this) r; // error, no enclosing struct or class
If the expression is a Property Function, typeof gives its return type.
struct S { @property int foo() { return 1; } } typeof(S.foo) n; // n is declared to be an int
If the expression is a Template, typeof gives the type void.
template t {} static assert(is(typeof(t) == void));
- Typeof is most useful in writing generic template code.
Mixin Types
MixinType: mixin ( ArgumentList )
Each AssignExpression in the ArgumentList is evaluated at compile time, and the result must be representable as a string. The resulting strings are concatenated to form a string. The text contents of the string must be compilable as a valid Type, and is compiled as such.
void test(mixin("int")* p) // int* p { mixin("int")[] a; // int[] a; mixin("int[]") b; // int[] b; }
Aliased Types
size_t
size_t is an alias to one of the unsigned integral basic types, and represents a type that is large enough to represent an offset into all addressable memory.
ptrdiff_t
ptrdiff_t is an alias to the signed integral basic type the same size as size_t.
string
A string is a special case of an array.
noreturn
noreturn is the bottom type which can implicitly convert to any type, including void. A value of type noreturn will never be produced and the compiler can optimize such code accordingly.
A function that never returns has the return type noreturn. This can occur due to an infinite loop or always throwing an exception.
noreturn abort(const(char)[] message); int example(int i) { if (i < 0) { // abort does not return, so it doesn't need to produce an int int val = abort("less than zero"); } // ternary expression's common type is still int return i != 0 ? 1024 / i : abort("calculation went awry."); }
noreturn is defined as typeof(*null). This is because dereferencing a null literal halts execution.