Templates which extract information about types and symbols at compile time.
isExpressions
), Andrei Alexandrescu, Shin Fujishiro, Robert Clipsham, David Nadlinger, Kenji Hara, Shoichi Kato T | The type to qualify |
T
with the inout
qualifier added.static assert(is(InoutOf!(int) == inout int)); static assert(is(InoutOf!(inout int) == inout int)); static assert(is(InoutOf!(const int) == inout const int)); static assert(is(InoutOf!(shared int) == inout shared int));
T | The type to qualify |
T
with the const
qualifier added.static assert(is(ConstOf!(int) == const int)); static assert(is(ConstOf!(const int) == const int)); static assert(is(ConstOf!(inout int) == const inout int)); static assert(is(ConstOf!(shared int) == const shared int));
T | The type to qualify |
T
with the shared
qualifier added.static assert(is(SharedOf!(int) == shared int)); static assert(is(SharedOf!(shared int) == shared int)); static assert(is(SharedOf!(inout int) == shared inout int)); static assert(is(SharedOf!(immutable int) == shared immutable int));
T | The type to qualify |
T
with the inout
and shared
qualifiers added.static assert(is(SharedInoutOf!(int) == shared inout int)); static assert(is(SharedInoutOf!(int) == inout shared int)); static assert(is(SharedInoutOf!(const int) == shared inout const int)); static assert(is(SharedInoutOf!(immutable int) == shared inout immutable int));
T | The type to qualify |
T
with the const
and shared
qualifiers added.static assert(is(SharedConstOf!(int) == shared const int)); static assert(is(SharedConstOf!(int) == const shared int)); static assert(is(SharedConstOf!(inout int) == shared inout const int)); // immutable variables are implicitly shared and const static assert(is(SharedConstOf!(immutable int) == immutable int));
T | The type to qualify |
T
with the immutable
qualifier added.static assert(is(ImmutableOf!(int) == immutable int)); static assert(is(ImmutableOf!(const int) == immutable int)); static assert(is(ImmutableOf!(inout int) == immutable int)); static assert(is(ImmutableOf!(shared int) == immutable int));
Gives a template that can be used to apply the same attributes that are on the given type T
. E.g. passing inout shared int
will return SharedInoutOf
.
T | the type to check qualifiers from |
T
static assert(__traits(isSame, QualifierOf!(immutable int), ImmutableOf)); static assert(__traits(isSame, QualifierOf!(shared int), SharedOf)); static assert(__traits(isSame, QualifierOf!(shared inout int), SharedInoutOf));
Get the full package name for the given symbol.
static assert(packageName!packageName == "std");
static assert(packageName!moduleName == "std");
Get the module name (including package) for the given symbol.
static assert(moduleName!moduleName == "std.traits");
Get the fully qualified name of a type or a symbol. Can act as an intelligent type/symbol to string converter.
module myModule; struct MyStruct {} static assert(fullyQualifiedName!(const MyStruct[]) == "const(myModule.MyStruct[])");
static assert(fullyQualifiedName!fullyQualifiedName == "std.traits.fullyQualifiedName");
Get the type of the return value from a function, a pointer to function, a delegate, a struct with an opCall, a pointer to a struct with an opCall, or a class with an opCall
. Please note that ref is not part of a type, but the attribute of the function (see template functionAttributes
).
int foo(); ReturnType!foo x; // x is declared as int
Get, as a tuple, the types of the parameters to a function, a pointer to function, a delegate, a struct with an opCall
, a pointer to a struct with an opCall
, or a class with an opCall
.
int foo(int, long); void bar(Parameters!foo); // declares void bar(int, long); void abc(Parameters!foo[1]); // declares void abc(long);
Alternate name for Parameters
, kept for legacy compatibility.
Returns the number of arguments of function func
. arity is undefined for variadic functions.
void foo(){} static assert(arity!foo == 0); void bar(uint){} static assert(arity!bar == 1); void variadicFoo(uint...){} static assert(!__traits(compiles, arity!variadicFoo));
Get tuple, one per function parameter, of the storage classes of the parameters.
func | function symbol or type of function, delegate, or pointer to function |
alias STC = ParameterStorageClass; // shorten the enum name void func(ref int ctx, out real result, real param) { } alias pstc = ParameterStorageClassTuple!func; static assert(pstc.length == 3); // three parameters static assert(pstc[0] == STC.ref_); static assert(pstc[1] == STC.out_); static assert(pstc[2] == STC.none);
These flags can be bitwise OR-ed together to represent complex storage class.
Convert the result of __traits(getParameterStorageClasses)
to ParameterStorageClass
enum
s.
Attribs | The return value of __traits(getParameterStorageClasses)
|
ParameterStorageClass
enum
s.static void func(ref int ctx, out real result); enum param1 = extractParameterStorageClassFlags!( __traits(getParameterStorageClasses, func, 0) ); static assert(param1 == ParameterStorageClass.ref_); enum param2 = extractParameterStorageClassFlags!( __traits(getParameterStorageClasses, func, 1) ); static assert(param2 == ParameterStorageClass.out_); enum param3 = extractParameterStorageClassFlags!( __traits(getParameterStorageClasses, func, 0), __traits(getParameterStorageClasses, func, 1) ); static assert(param3 == (ParameterStorageClass.ref_ | ParameterStorageClass.out_));
Get, as a tuple, the identifiers of the parameters to a function symbol.
int foo(int num, string name, int); static assert([ParameterIdentifierTuple!foo] == ["num", "name", ""]);
Get, as a tuple, the default value of the parameters to a function symbol. If a parameter doesn't have the default value, void
is returned instead.
int foo(int num, string name = "hello", int[] = [1,2,3], lazy int x = 0); static assert(is(ParameterDefaults!foo[0] == void)); static assert( ParameterDefaults!foo[1] == "hello"); static assert( ParameterDefaults!foo[2] == [1,2,3]); static assert( ParameterDefaults!foo[3] == 0);
Alternate name for ParameterDefaults
, kept for legacy compatibility.
Returns the FunctionAttribute mask for function func
.
hasFunctionAttributes
alias FA = FunctionAttribute; // shorten the enum name real func(real x) pure nothrow @safe { return x; } static assert(functionAttributes!func & FA.pure_); static assert(functionAttributes!func & FA.safe); static assert(!(functionAttributes!func & FA.trusted)); // not @trusted
These flags can be bitwise OR-ed together to represent a complex attribute.
Checks whether a function has the given attributes attached.
args | Function to check, followed by a variadic number of function attributes as strings |
true
, if the function has the list of attributes attached and false
otherwise. functionAttributes
real func(real x) pure nothrow @safe; static assert(hasFunctionAttributes!(func, "@safe", "pure")); static assert(!hasFunctionAttributes!(func, "@trusted")); // for templates attributes are automatically inferred bool myFunc(T)(T b) { return !b; } static assert(hasFunctionAttributes!(myFunc!bool, "@safe", "pure", "@nogc", "nothrow")); static assert(!hasFunctionAttributes!(myFunc!bool, "shared"));
true
if func
is @safe
or @trusted
.
@safe int add(int a, int b) {return a+b;} @trusted int sub(int a, int b) {return a-b;} @system int mul(int a, int b) {return a*b;} static assert( isSafe!add); static assert( isSafe!sub); static assert(!isSafe!mul);
true
if func
is @system
.
@safe int add(int a, int b) {return a+b;} @trusted int sub(int a, int b) {return a-b;} @system int mul(int a, int b) {return a*b;} static assert(!isUnsafe!add); static assert(!isUnsafe!sub); static assert( isUnsafe!mul);
Determine the linkage attribute of the function.
func | the function symbol, or the type of a function, delegate, or pointer to function |
extern(D) void Dfunc() {} extern(C) void Cfunc() {} static assert(functionLinkage!Dfunc == "D"); static assert(functionLinkage!Cfunc == "C"); string a = functionLinkage!Dfunc; writeln(a); // "D" auto fp = &Cfunc; string b = functionLinkage!fp; writeln(b); // "C"
Determines what kind of variadic parameters function has.
func | function symbol or type of function, delegate, or pointer to function |
void func() {} static assert(variadicFunctionStyle!func == Variadic.no); extern(C) int printf(in char*, ...); static assert(variadicFunctionStyle!printf == Variadic.c);
Function is not variadic.
Function is a C-style variadic function, which uses core.stdc.stdarg
Function is a D-style variadic function, which uses __argptr
and __arguments
.
Function is a typesafe variadic function.
Get the function type from a callable object func
.
Using builtin typeof
on a property function yields the types of the property value, not of the property function itself. Still, FunctionTypeOf
is able to obtain function types of properties.
class C { int value() @property { return 0; } } static assert(is( typeof(C.value) == int )); static assert(is( FunctionTypeOf!(C.value) == function ));
Constructs a new function or delegate type with the same basic signature as the given one, but different attributes (including linkage).
This is especially useful for adding/removing attributes to/from types in generic code, where the actual type name cannot be spelt out.
T | The base type. |
linkage | The desired linkage of the result type. |
attrs | The desired FunctionAttribute s of the result type. |
alias ExternC(T) = SetFunctionAttributes!(T, "C", functionAttributes!T); auto assumePure(T)(T t) if (isFunctionPointer!T || isDelegate!T) { enum attrs = functionAttributes!T | FunctionAttribute.pure_; return cast(SetFunctionAttributes!(T, functionLinkage!T, attrs)) t; } int f() { import core.thread : getpid; return getpid(); } int g() pure @trusted { auto pureF = assumePure(&f); return pureF(); } assert(g() > 0);
Determines whether T
is a class nested inside another class and that T.outer
is the implicit reference to the outer class (i.e. outer
has not been used as a field or method name)
T | type to test |
true
if T
is a class nested inside another, with the conditions described above; false
otherwiseclass C { int outer; } static assert(!isInnerClass!C); class Outer1 { class Inner1 { } class Inner2 { int outer; } } static assert(isInnerClass!(Outer1.Inner1)); static assert(!isInnerClass!(Outer1.Inner2)); static class Outer2 { static class Inner { int outer; } } static assert(!isInnerClass!(Outer2.Inner));
Determines whether T
has its own context pointer. T
must be either class
, struct
, or union
.
static struct S { } static assert(!isNested!S); int i; struct NestedStruct { void f() { ++i; } } static assert(isNested!NestedStruct);
Determines whether T
or any of its representation types have a context pointer.
static struct S { } int i; struct NS { void f() { ++i; } } static assert(!hasNested!(S[2])); static assert(hasNested!(NS[2]));
Get as a tuple the types of the fields of a struct, class, or union. This consists of the fields that take up memory space, excluding the hidden fields like the virtual function table pointer or a context pointer for nested types. If T
isn't a struct, class, or union returns a tuple with one element T
.
import std.meta : AliasSeq; struct S { int x; float y; } static assert(is(Fields!S == AliasSeq!(int, float)));
Alternate name for Fields
, kept for legacy compatibility.
Get as an expression tuple the names of the fields of a struct, class, or union. This consists of the fields that take up memory space, excluding the hidden fields like the virtual function table pointer or a context pointer for nested types. Inherited fields (for classes) are not included. If T
isn't a struct, class, or union, an expression tuple with an empty string is returned.
import std.meta : AliasSeq; struct S { int x; float y; } static assert(FieldNameTuple!S == AliasSeq!("x", "y")); static assert(FieldNameTuple!int == AliasSeq!"");
Get the primitive types of the fields of a struct or class, in topological order.
struct S1 { int a; float b; } struct S2 { char[] a; union { S1 b; S1 * c; } } alias R = RepresentationTypeTuple!S2; assert(R.length == 4 && is(R[0] == char[]) && is(R[1] == int) && is(R[2] == float) && is(R[3] == S1*));
Returns true
if and only if T
's representation includes at least one of the following:
U*
and U
is not immutable;U[]
and U
is not immutable;C
and C
is not immutable.struct S1 { int a; Object b; } struct S2 { string a; } struct S3 { int a; immutable Object b; } struct S4 { float[3] vals; } static assert( hasAliasing!S1); static assert(!hasAliasing!S2); static assert(!hasAliasing!S3); static assert(!hasAliasing!S4);
Returns true
if and only if T
's representation includes at least one of the following:
U*
;U[]
;C
.static assert( hasIndirections!(int[string])); static assert( hasIndirections!(void delegate())); static assert( hasIndirections!(void delegate() immutable)); static assert( hasIndirections!(immutable(void delegate()))); static assert( hasIndirections!(immutable(void delegate() immutable))); static assert(!hasIndirections!(void function())); static assert( hasIndirections!(void*[1])); static assert(!hasIndirections!(byte[1]));
Returns true
if and only if T
's representation includes at least one of the following:
U*
and U
is not immutable or shared;U[]
and U
is not immutable or shared;C
and C
is not immutable or shared.struct S1 { int a; Object b; } struct S2 { string a; } struct S3 { int a; immutable Object b; } static assert( hasUnsharedAliasing!S1); static assert(!hasUnsharedAliasing!S2); static assert(!hasUnsharedAliasing!S3); struct S4 { int a; shared Object b; } struct S5 { char[] a; } struct S6 { shared char[] b; } struct S7 { float[3] vals; } static assert(!hasUnsharedAliasing!S4); static assert( hasUnsharedAliasing!S5); static assert(!hasUnsharedAliasing!S6); static assert(!hasUnsharedAliasing!S7);
True if S
or any type embedded directly in the representation of S
defines an elaborate copy constructor. Elaborate copy constructors are introduced by defining this(this)
for a struct
.
Classes and unions never have elaborate copy constructors.
static assert(!hasElaborateCopyConstructor!int); static struct S1 { } static struct S2 { this(this) {} } static struct S3 { S2 field; } static struct S4 { S3[1] field; } static struct S5 { S3[] field; } static struct S6 { S3[0] field; } static struct S7 { @disable this(); S3 field; } static assert(!hasElaborateCopyConstructor!S1); static assert( hasElaborateCopyConstructor!S2); static assert( hasElaborateCopyConstructor!(immutable S2)); static assert( hasElaborateCopyConstructor!S3); static assert( hasElaborateCopyConstructor!(S3[1])); static assert(!hasElaborateCopyConstructor!(S3[0])); static assert( hasElaborateCopyConstructor!S4); static assert(!hasElaborateCopyConstructor!S5); static assert(!hasElaborateCopyConstructor!S6); static assert( hasElaborateCopyConstructor!S7);
True if S
or any type directly embedded in the representation of S
defines an elaborate assignment. Elaborate assignments are introduced by defining opAssign(typeof(this))
or opAssign(ref typeof(this))
for a struct
or when there is a compiler-generated opAssign
.
A type S
gets compiler-generated opAssign
in case it has an elaborate copy constructor or elaborate destructor.
Classes and unions never have elaborate assignments.
static assert(!hasElaborateAssign!int); static struct S { void opAssign(S) {} } static assert( hasElaborateAssign!S); static assert(!hasElaborateAssign!(const(S))); static struct S1 { void opAssign(ref S1) {} } static struct S2 { void opAssign(int) {} } static struct S3 { S s; } static assert( hasElaborateAssign!S1); static assert(!hasElaborateAssign!S2); static assert( hasElaborateAssign!S3); static assert( hasElaborateAssign!(S3[1])); static assert(!hasElaborateAssign!(S3[0]));
True if S
or any type directly embedded in the representation of S
defines an elaborate destructor. Elaborate destructors are introduced by defining ~this()
for a struct
.
Classes and unions never have elaborate destructors, even though classes may define ~this()
.
static assert(!hasElaborateDestructor!int); static struct S1 { } static struct S2 { ~this() {} } static struct S3 { S2 field; } static struct S4 { S3[1] field; } static struct S5 { S3[] field; } static struct S6 { S3[0] field; } static struct S7 { @disable this(); S3 field; } static assert(!hasElaborateDestructor!S1); static assert( hasElaborateDestructor!S2); static assert( hasElaborateDestructor!(immutable S2)); static assert( hasElaborateDestructor!S3); static assert( hasElaborateDestructor!(S3[1])); static assert(!hasElaborateDestructor!(S3[0])); static assert( hasElaborateDestructor!S4); static assert(!hasElaborateDestructor!S5); static assert(!hasElaborateDestructor!S6); static assert( hasElaborateDestructor!S7);
True if S
or any type embedded directly in the representation of S
defines elaborate move semantics. Elaborate move semantics are introduced by defining opPostMove(ref typeof(this))
for a struct
.
Classes and unions never have elaborate move semantics.
static assert(!hasElaborateMove!int); static struct S1 { } static struct S2 { void opPostMove(ref S2) {} } static struct S3 { void opPostMove(inout ref S3) inout {} } static struct S4 { void opPostMove(const ref S4) {} } static struct S5 { void opPostMove(S5) {} } static struct S6 { void opPostMove(int) {} } static struct S7 { S3[1] field; } static struct S8 { S3[] field; } static struct S9 { S3[0] field; } static struct S10 { @disable this(); S3 field; } static assert(!hasElaborateMove!S1); static assert( hasElaborateMove!S2); static assert( hasElaborateMove!S3); static assert( hasElaborateMove!(immutable S3)); static assert( hasElaborateMove!S4); static assert(!hasElaborateMove!S5); static assert(!hasElaborateMove!S6); static assert( hasElaborateMove!S7); static assert(!hasElaborateMove!S8); static assert(!hasElaborateMove!S9); static assert( hasElaborateMove!S10);
Yields true
if and only if T
is an aggregate that defines a symbol called name
.
static assert(!hasMember!(int, "blah")); struct S1 { int blah; } struct S2 { int blah(){ return 0; } } class C1 { int blah; } class C2 { int blah(){ return 0; } } static assert(hasMember!(S1, "blah")); static assert(hasMember!(S2, "blah")); static assert(hasMember!(C1, "blah")); static assert(hasMember!(C2, "blah"));
Whether the symbol represented by the string, member, exists and is a static member of T.
T | Type containing symbol member . |
member | Name of symbol to test that resides in T . |
true
iff member
exists and is static.static struct S { static void sf() {} void f() {} static int si; int i; } static assert( hasStaticMember!(S, "sf")); static assert(!hasStaticMember!(S, "f")); static assert( hasStaticMember!(S, "si")); static assert(!hasStaticMember!(S, "i")); static assert(!hasStaticMember!(S, "hello"));
Retrieves the members of an enumerated type enum E
.
E | An enumerated type. E may have duplicated values. |
E
. The members are arranged in the same order as declared in E
. The name of the enum can be found by querying the compiler for the name of the identifier, i.e. __traits(identifier, EnumMembers!MyEnum[i])
. For enumerations with unique values, std.conv.to
can also be used. std.meta.NoDuplicates
template to avoid generating duplicate switch cases. E
. Thus, the following code does not work without the explicit cast: enum E : int { a, b, c } int[] abc = cast(int[]) [ EnumMembers!E ];Cast is not necessary if the type of the variable is inferred. See the example below.
enum Sqrts : real { one = 1, two = 1.41421, three = 1.73205 } auto sqrts = [EnumMembers!Sqrts]; writeln(sqrts); // [Sqrts.one, Sqrts.two, Sqrts.three]
rank(v)
in the following example uses this template for finding a member e
in an enumerated type E
. // Returns i if e is the i-th enumerator of E. static size_t rank(E)(E e) if (is(E == enum)) { static foreach (i, member; EnumMembers!E) { if (e == member) return i; } assert(0, "Not an enum member"); } enum Mode { read = 1, write = 2, map = 4 } writeln(rank(Mode.read)); // 0 writeln(rank(Mode.write)); // 1 writeln(rank(Mode.map)); // 2
import std.conv : to; class FooClass { string calledMethod; void foo() @safe { calledMethod = "foo"; } void bar() @safe { calledMethod = "bar"; } void baz() @safe { calledMethod = "baz"; } } enum FooEnum { foo, bar, baz } auto var = FooEnum.bar; auto fooObj = new FooClass(); s: final switch (var) { static foreach (member; EnumMembers!FooEnum) { case member: // Generate a case for each enum value. // Call fooObj.{name of enum value}(). __traits(getMember, fooObj, to!string(member))(); break s; } } // As we pass in FooEnum.bar, the bar() method gets called. writeln(fooObj.calledMethod); // "bar"
Get a AliasSeq of the base class and base interfaces of this class or interface. BaseTypeTuple!Object returns the empty type tuple.
import std.meta : AliasSeq; interface I1 { } interface I2 { } interface I12 : I1, I2 { } static assert(is(BaseTypeTuple!I12 == AliasSeq!(I1, I2))); interface I3 : I1 { } interface I123 : I1, I2, I3 { } static assert(is(BaseTypeTuple!I123 == AliasSeq!(I1, I2, I3)));
Get a AliasSeq of all base classes of this class, in decreasing order. Interfaces are not included. BaseClassesTuple!Object yields the empty type tuple.
import std.meta : AliasSeq; class C1 { } class C2 : C1 { } class C3 : C2 { } static assert(!BaseClassesTuple!Object.length); static assert(is(BaseClassesTuple!C1 == AliasSeq!(Object))); static assert(is(BaseClassesTuple!C2 == AliasSeq!(C1, Object))); static assert(is(BaseClassesTuple!C3 == AliasSeq!(C2, C1, Object)));
T | The class or interface to search. |
std.meta.AliasSeq
of all interfaces directly or indirectly inherited by this class or interface. Interfaces do not repeat if multiply implemented. InterfacesTuple!Object
yields an empty AliasSeq
.interface I1 {} interface I2 {} class A : I1, I2 {} class B : A, I1 {} class C : B {} alias TL = InterfacesTuple!C; static assert(is(TL[0] == I1) && is(TL[1] == I2));
Get a AliasSeq of all base classes of T, in decreasing order, followed by T's interfaces. TransitiveBaseTypeTuple!Object yields the empty type tuple.
interface J1 {} interface J2 {} class B1 {} class B2 : B1, J1, J2 {} class B3 : B2, J1 {} alias TL = TransitiveBaseTypeTuple!B3; writeln(TL.length); // 5 assert(is (TL[0] == B2)); assert(is (TL[1] == B1)); assert(is (TL[2] == Object)); assert(is (TL[3] == J1)); assert(is (TL[4] == J2)); writeln(TransitiveBaseTypeTuple!Object.length); // 0
Returns a tuple of non-static functions with the name name
declared in the class or interface C
. Covariant duplicates are shrunk into the most derived one.
interface I { I foo(); } class B { real foo(real v) { return v; } } class C : B, I { override C foo() { return this; } // covariant overriding of I.foo() } alias foos = MemberFunctionsTuple!(C, "foo"); static assert(foos.length == 2); static assert(__traits(isSame, foos[0], C.foo)); static assert(__traits(isSame, foos[1], B.foo));
Returns an alias to the template that T
is an instance of. It will return void
if a symbol without a template is given.
struct Foo(T, U) {} static assert(__traits(isSame, TemplateOf!(Foo!(int, real)), Foo));
Returns a AliasSeq
of the template arguments used to instantiate T
.
import std.meta : AliasSeq; struct Foo(T, U) {} static assert(is(TemplateArgsOf!(Foo!(int, real)) == AliasSeq!(int, real)));
Returns class instance alignment.
class A { byte b; } class B { long l; } // As class instance always has a hidden pointer static assert(classInstanceAlignment!A == (void*).alignof); static assert(classInstanceAlignment!B == long.alignof);
Get the type that all types can be implicitly converted to. Useful e.g. in figuring out an array type from a bunch of initializing values. Returns void if passed an empty list, or if the types have no common type.
alias X = CommonType!(int, long, short); assert(is(X == long)); alias Y = CommonType!(int, char[], short); assert(is(Y == void));
static assert(is(CommonType!(3) == int)); static assert(is(CommonType!(double, 4, float) == double)); static assert(is(CommonType!(string, char[]) == const(char)[])); static assert(is(CommonType!(3, 3U) == uint)); static assert(is(CommonType!(double, int) == double));
T | The type to check |
std.meta.AliasSeq
with all possible target types of an implicit conversion T
. If T
is a class derived from Object
, the the result of TransitiveBaseTypeTuple
is returned. If the type is not a built-in value type or a class derived from Object
, the an empty std.meta.AliasSeq
is returned. ImplicitConversionTargets!double
does not include float
. isImplicitlyConvertible
import std.meta : AliasSeq; static assert(is(ImplicitConversionTargets!(ulong) == AliasSeq!(float, double, real))); static assert(is(ImplicitConversionTargets!(int) == AliasSeq!(long, ulong, float, double, real))); static assert(is(ImplicitConversionTargets!(float) == AliasSeq!(double, real))); static assert(is(ImplicitConversionTargets!(double) == AliasSeq!(real))); static assert(is(ImplicitConversionTargets!(char) == AliasSeq!( wchar, dchar, byte, ubyte, short, ushort, int, uint, long, ulong, float, double, real ))); static assert(is(ImplicitConversionTargets!(wchar) == AliasSeq!( dchar, short, ushort, int, uint, long, ulong, float, double, real ))); static assert(is(ImplicitConversionTargets!(dchar) == AliasSeq!( int, uint, long, ulong, float, double, real ))); static assert(is(ImplicitConversionTargets!(string) == AliasSeq!(const(char)[]))); static assert(is(ImplicitConversionTargets!(void*) == AliasSeq!(void*))); interface A {} interface B {} class C : A, B {} static assert(is(ImplicitConversionTargets!(C) == AliasSeq!(Object, A, B)));
Is From
implicitly convertible to To
?
static assert( isImplicitlyConvertible!(immutable(char), char)); static assert( isImplicitlyConvertible!(const(char), char)); static assert( isImplicitlyConvertible!(char, wchar)); static assert(!isImplicitlyConvertible!(wchar, char)); static assert(!isImplicitlyConvertible!(const(ushort), ubyte)); static assert(!isImplicitlyConvertible!(const(uint), ubyte)); static assert(!isImplicitlyConvertible!(const(ulong), ubyte)); static assert(!isImplicitlyConvertible!(const(char)[], string)); static assert( isImplicitlyConvertible!(string, const(char)[]));
Returns true
iff a value of type Rhs
can be assigned to a variable of type Lhs
.
isAssignable
returns whether both an lvalue and rvalue can be assigned.
If you omit Rhs
, isAssignable
will check identity assignable of Lhs
.
static assert( isAssignable!(long, int)); static assert(!isAssignable!(int, long)); static assert( isAssignable!(const(char)[], string)); static assert(!isAssignable!(string, char[])); // int is assignable to int static assert( isAssignable!int); // immutable int is not assignable to immutable int static assert(!isAssignable!(immutable int));
Determines whether the function type F
is covariant with G
, i.e., functions of the type F
can override ones of the type G
.
interface I { I clone(); } interface J { J clone(); } class C : I { override C clone() // covariant overriding of I.clone() { return new C; } } // C.clone() can override I.clone(), indeed. static assert(isCovariantWith!(typeof(C.clone), typeof(I.clone))); // C.clone() can't override J.clone(); the return type C is not implicitly // convertible to J. static assert(!isCovariantWith!(typeof(C.clone), typeof(J.clone)));
Creates an lvalue or rvalue of type T
for typeof(...)
and __traits(compiles, ...)
purposes. No actual value is returned.
T | The type to transform |
static int f(int); static assert(is(typeof(f(rvalueOf!int)) == int));
static bool f(ref int); static assert(is(typeof(f(lvalueOf!int)) == bool));
Detect whether T
is a built-in boolean type.
static assert( isBoolean!bool); enum EB : bool { a = true } static assert( isBoolean!EB); static assert(!isBoolean!(SubTypeOf!bool));
Detect whether T
is a built-in integral type. Types bool
, char
, wchar
, and dchar
are not considered integral.
static assert( isIntegral!byte && isIntegral!short && isIntegral!int && isIntegral!long && isIntegral!(const(long)) && isIntegral!(immutable(long)) ); static assert( !isIntegral!bool && !isIntegral!char && !isIntegral!double ); // types which act as integral values do not pass struct S { int val; alias val this; } static assert(!isIntegral!S);
Detect whether T
is a built-in floating point type.
static assert( isFloatingPoint!float && isFloatingPoint!double && isFloatingPoint!real && isFloatingPoint!(const(real)) && isFloatingPoint!(immutable(real)) ); static assert(!isFloatingPoint!int); // complex and imaginary numbers do not pass static assert( !isFloatingPoint!cfloat && !isFloatingPoint!ifloat ); // types which act as floating point values do not pass struct S { float val; alias val this; } static assert(!isFloatingPoint!S);
Detect whether T
is a built-in numeric type (integral or floating point).
static assert( isNumeric!byte && isNumeric!short && isNumeric!int && isNumeric!long && isNumeric!float && isNumeric!double && isNumeric!real && isNumeric!(const(real)) && isNumeric!(immutable(real)) ); static assert( !isNumeric!void && !isNumeric!bool && !isNumeric!char && !isNumeric!wchar && !isNumeric!dchar ); // types which act as numeric values do not pass struct S { int val; alias val this; } static assert(!isIntegral!S);
Detect whether T
is a scalar type (a built-in numeric, character or boolean type).
static assert(!isScalarType!void); static assert( isScalarType!(immutable(byte))); static assert( isScalarType!(immutable(ushort))); static assert( isScalarType!(immutable(int))); static assert( isScalarType!(ulong)); static assert( isScalarType!(shared(float))); static assert( isScalarType!(shared(const bool))); static assert( isScalarType!(const(char))); static assert( isScalarType!(wchar)); static assert( isScalarType!(const(dchar))); static assert( isScalarType!(const(double))); static assert( isScalarType!(const(real)));
Detect whether T
is a basic type (scalar type or void).
static assert(isBasicType!void); static assert(isBasicType!(const(void))); static assert(isBasicType!(shared(void))); static assert(isBasicType!(immutable(void))); static assert(isBasicType!(shared const(void))); static assert(isBasicType!(shared inout(void))); static assert(isBasicType!(shared inout const(void))); static assert(isBasicType!(inout(void))); static assert(isBasicType!(inout const(void))); static assert(isBasicType!(immutable(int))); static assert(isBasicType!(shared(float))); static assert(isBasicType!(shared(const bool))); static assert(isBasicType!(const(dchar)));
Detect whether T
is a built-in unsigned numeric type.
static assert( isUnsigned!uint && isUnsigned!ulong ); static assert( !isUnsigned!char && !isUnsigned!int && !isUnsigned!long && !isUnsigned!char && !isUnsigned!wchar && !isUnsigned!dchar );
Detect whether T
is a built-in signed numeric type.
static assert( isSigned!int && isSigned!long ); static assert( !isSigned!uint && !isSigned!ulong );
Detect whether T
is one of the built-in character types.
The built-in char types are any of char
, wchar
or dchar
, with or without qualifiers.
//Char types static assert( isSomeChar!char); static assert( isSomeChar!wchar); static assert( isSomeChar!dchar); static assert( isSomeChar!(typeof('c'))); static assert( isSomeChar!(immutable char)); static assert( isSomeChar!(const dchar)); //Non char types static assert(!isSomeChar!int); static assert(!isSomeChar!byte); static assert(!isSomeChar!string); static assert(!isSomeChar!wstring); static assert(!isSomeChar!dstring); static assert(!isSomeChar!(char[4]));
Detect whether T
is one of the built-in string types.
The built-in string types are Char[]
, where Char
is any of char
, wchar
or dchar
, with or without qualifiers.
Static arrays of characters (like char[80]
) are not considered built-in string types.
//String types static assert( isSomeString!string); static assert( isSomeString!(wchar[])); static assert( isSomeString!(dchar[])); static assert( isSomeString!(typeof("aaa"))); static assert( isSomeString!(const(char)[])); //Non string types static assert(!isSomeString!int); static assert(!isSomeString!(int[])); static assert(!isSomeString!(byte[])); static assert(!isSomeString!(typeof(null))); static assert(!isSomeString!(char[4])); enum ES : string { a = "aaa", b = "bbb" } static assert(!isSomeString!ES); static struct Stringish { string str; alias str this; } static assert(!isSomeString!Stringish);
Detect whether type T
is a narrow string.
All arrays that use char, wchar, and their qualified versions are narrow strings. (Those include string and wstring).
static assert(isNarrowString!string); static assert(isNarrowString!wstring); static assert(isNarrowString!(char[])); static assert(isNarrowString!(wchar[])); static assert(!isNarrowString!dstring); static assert(!isNarrowString!(dchar[])); static assert(!isNarrowString!(typeof(null))); static assert(!isNarrowString!(char[4])); enum ES : string { a = "aaa", b = "bbb" } static assert(!isNarrowString!ES); static struct Stringish { string str; alias str this; } static assert(!isNarrowString!Stringish);
Detects whether T
is a comparable type. Basic types and structs and classes that implement opCmp are ordering comparable.
static assert(isOrderingComparable!int); static assert(isOrderingComparable!string); static assert(!isOrderingComparable!creal); static struct Foo {} static assert(!isOrderingComparable!Foo); static struct Bar { int a; auto opCmp(Bar b1) const { return a - b1.a; } } Bar b1 = Bar(5); Bar b2 = Bar(7); assert(isOrderingComparable!Bar && b2 > b1);
Warning: This trait will be deprecated as soon as it is no longer used in Phobos. For a function parameter to safely accept a type that implicitly converts to string as a string, the conversion needs to happen at the callsite; otherwise, the conversion is done inside the function, and in many cases, that means that local memory is sliced (e.g. if a static array is passed to the function, then it's copied, and the resulting dynamic array will be a slice of a local variable). So, if the resulting string escapes the function, the string refers to invalid memory, and accessing it would mean accessing invalid memory. As such, the only safe way for a function to accept types that implicitly convert to string is for the implicit conversion to be done at the callsite, and that can only occur if the parameter is explicitly typed as an array, whereas using isConvertibleToString in a template constraint would result in the conversion being done inside the function. As such, isConvertibleToString is inherently unsafe and is going to be deprecated.
Detect whether T
is a struct, static array, or enum that is implicitly convertible to a string.
static struct AliasedString { string s; alias s this; } enum StringEnum { a = "foo" } assert(!isConvertibleToString!string); assert(isConvertibleToString!AliasedString); assert(isConvertibleToString!StringEnum); assert(isConvertibleToString!(char[25])); assert(!isConvertibleToString!(char[]));
Detect whether type T
is a string that will be autodecoded.
Given a type S
that is one of:
const(char)[]
const(wchar)[]
T
can be one of: S
T
T
T
T
cannot be a static array. T | type to be tested |
isNarrowString
static struct Stringish { string s; alias s this; } static assert(isAutodecodableString!wstring); static assert(isAutodecodableString!Stringish); static assert(!isAutodecodableString!dstring); enum E : const(char)[3] { X = "abc" } enum F : const(char)[] { X = "abc" } enum G : F { X = F.init } static assert(isAutodecodableString!(char[])); static assert(!isAutodecodableString!(E)); static assert(isAutodecodableString!(F)); static assert(isAutodecodableString!(G)); struct Stringish2 { Stringish s; alias s this; } enum H : Stringish { X = Stringish() } enum I : Stringish2 { X = Stringish2() } static assert(isAutodecodableString!(H)); static assert(isAutodecodableString!(I));
Detect whether type T
is a static array.
static assert( isStaticArray!(int[3])); static assert( isStaticArray!(const(int)[5])); static assert( isStaticArray!(const(int)[][5])); static assert(!isStaticArray!(const(int)[])); static assert(!isStaticArray!(immutable(int)[])); static assert(!isStaticArray!(const(int)[4][])); static assert(!isStaticArray!(int[])); static assert(!isStaticArray!(int[char])); static assert(!isStaticArray!(int[1][])); static assert(!isStaticArray!(int[int])); static assert(!isStaticArray!int);
Detect whether type T
is a dynamic array.
static assert( isDynamicArray!(int[])); static assert( isDynamicArray!(string)); static assert( isDynamicArray!(long[3][])); static assert(!isDynamicArray!(int[5])); static assert(!isDynamicArray!(typeof(null)));
Detect whether type T
is an array (static or dynamic; for associative arrays see isAssociativeArray
).
static assert( isArray!(int[])); static assert( isArray!(int[5])); static assert( isArray!(string)); static assert(!isArray!uint); static assert(!isArray!(uint[uint])); static assert(!isArray!(typeof(null)));
Detect whether T
is an associative array type
Detect whether type T
is a builtin type.
class C; union U; struct S; interface I; static assert( isBuiltinType!void); static assert( isBuiltinType!string); static assert( isBuiltinType!(int[])); static assert( isBuiltinType!(C[string])); static assert(!isBuiltinType!C); static assert(!isBuiltinType!U); static assert(!isBuiltinType!S); static assert(!isBuiltinType!I); static assert(!isBuiltinType!(void delegate(int)));
Detect whether type T
is a SIMD vector type.
Detect whether type T
is a pointer.
Returns the target type of a pointer.
static assert(is(PointerTarget!(int*) == int)); static assert(is(PointerTarget!(void*) == void));
Detect whether type T
is an aggregate type.
class C; union U; struct S; interface I; static assert( isAggregateType!C); static assert( isAggregateType!U); static assert( isAggregateType!S); static assert( isAggregateType!I); static assert(!isAggregateType!void); static assert(!isAggregateType!string); static assert(!isAggregateType!(int[])); static assert(!isAggregateType!(C[string])); static assert(!isAggregateType!(void delegate(int)));
Returns true
if T can be iterated over using a foreach
loop with a single loop variable of automatically inferred type, regardless of how the foreach
loop is implemented. This includes ranges, structs/classes that define opApply
with a single loop variable, and builtin dynamic, static and associative arrays.
struct OpApply { int opApply(scope int delegate(ref uint) dg) { assert(0); } } struct Range { @property uint front() { assert(0); } void popFront() { assert(0); } enum bool empty = false; } static assert( isIterable!(uint[])); static assert( isIterable!OpApply); static assert( isIterable!(uint[string])); static assert( isIterable!Range); static assert(!isIterable!uint);
Returns true if T is not const or immutable. Note that isMutable is true for string, or immutable(char)[], because the 'head' is mutable.
static assert( isMutable!int); static assert( isMutable!string); static assert( isMutable!(shared int)); static assert( isMutable!(shared const(int)[])); static assert(!isMutable!(const int)); static assert(!isMutable!(inout int)); static assert(!isMutable!(shared(const int))); static assert(!isMutable!(shared(inout int))); static assert(!isMutable!(immutable string));
Returns true if T is an instance of the template S.
static struct Foo(T...) { } static struct Bar(T...) { } static struct Doo(T) { } static struct ABC(int x) { } static void fun(T)() { } template templ(T) { } static assert(isInstanceOf!(Foo, Foo!int)); static assert(!isInstanceOf!(Foo, Bar!int)); static assert(!isInstanceOf!(Foo, int)); static assert(isInstanceOf!(Doo, Doo!int)); static assert(isInstanceOf!(ABC, ABC!1)); static assert(!isInstanceOf!(Foo, Foo)); static assert(isInstanceOf!(fun, fun!int)); static assert(isInstanceOf!(templ, templ!int));
isInstanceOf
to check the identity of a template while inside of said template, use TemplateOf
. static struct A(T = void) { // doesn't work as expected, only accepts A when T = void void func(B)(B b) if (isInstanceOf!(A, B)) {} // correct behavior void method(B)(B b) if (isInstanceOf!(TemplateOf!(A), B)) {} } A!(void) a1; A!(void) a2; A!(int) a3; static assert(!__traits(compiles, a1.func(a3))); static assert( __traits(compiles, a1.method(a2))); static assert( __traits(compiles, a1.method(a3)));
Check whether the tuple T is an expression tuple. An expression tuple only contains expressions.
isTypeTuple
.static assert(isExpressions!(1, 2.0, "a")); static assert(!isExpressions!(int, double, string)); static assert(!isExpressions!(int, 2.0, "a"));
Alternate name for isExpressions
, kept for legacy compatibility.
Check whether the tuple T
is a type tuple. A type tuple only contains types.
isExpressions
.static assert(isTypeTuple!(int, float, string)); static assert(!isTypeTuple!(1, 2.0, "a")); static assert(!isTypeTuple!(1, double, string));
Detect whether symbol or type T
is a function pointer.
static void foo() {} void bar() {} auto fpfoo = &foo; static assert( isFunctionPointer!fpfoo); static assert( isFunctionPointer!(void function())); auto dgbar = &bar; static assert(!isFunctionPointer!dgbar); static assert(!isFunctionPointer!(void delegate())); static assert(!isFunctionPointer!foo); static assert(!isFunctionPointer!bar); static assert( isFunctionPointer!((int a) {}));
Detect whether symbol or type T
is a delegate.
static void sfunc() { } int x; void func() { x++; } int delegate() dg; assert(isDelegate!dg); assert(isDelegate!(int delegate())); assert(isDelegate!(typeof(&func))); int function() fp; assert(!isDelegate!fp); assert(!isDelegate!(int function())); assert(!isDelegate!(typeof(&sfunc)));
Detect whether symbol or type T
is a function, a function pointer or a delegate.
T | The type to check |
bool
static real func(ref int) { return 0; } static void prop() @property { } class C { real method(ref int) { return 0; } real prop() @property { return 0; } } auto c = new C; auto fp = &func; auto dg = &c.method; real val; static assert( isSomeFunction!func); static assert( isSomeFunction!prop); static assert( isSomeFunction!(C.method)); static assert( isSomeFunction!(C.prop)); static assert( isSomeFunction!(c.prop)); static assert( isSomeFunction!(c.prop)); static assert( isSomeFunction!fp); static assert( isSomeFunction!dg); static assert(!isSomeFunction!int); static assert(!isSomeFunction!val);
Detect whether T
is a callable object, which can be called with the function call operator (...)
.
interface I { real value() @property; } struct S { static int opCall(int) { return 0; } } class C { int opCall(int) { return 0; } } auto c = new C; static assert( isCallable!c); static assert( isCallable!S); static assert( isCallable!(c.opCall)); static assert( isCallable!(I.value)); static assert( isCallable!((int a) { return a; })); static assert(!isCallable!I);
Detect whether T
is an abstract function.
T | The type to check |
bool
struct S { void foo() { } } class C { void foo() { } } class AC { abstract void foo(); } static assert(!isAbstractFunction!(int)); static assert(!isAbstractFunction!(S.foo)); static assert(!isAbstractFunction!(C.foo)); static assert( isAbstractFunction!(AC.foo));
Detect whether T
is a final function.
struct S { void bar() { } } final class FC { void foo(); } class C { void bar() { } final void foo(); } static assert(!isFinalFunction!(int)); static assert(!isFinalFunction!(S.bar)); static assert( isFinalFunction!(FC.foo)); static assert(!isFinalFunction!(C.bar)); static assert( isFinalFunction!(C.foo));
Determines if f
is a function that requires a context pointer.
f | The type to check Returns A bool
|
static void f() {} static void fun() { int i; int f() { return i; } static assert(isNestedFunction!(f)); } static assert(!isNestedFunction!f);
Detect whether T
is an abstract class.
struct S { } class C { } abstract class AC { } static assert(!isAbstractClass!S); static assert(!isAbstractClass!C); static assert( isAbstractClass!AC); C c; static assert(!isAbstractClass!c); AC ac; static assert( isAbstractClass!ac);
Detect whether T
is a final class.
class C { } abstract class AC { } final class FC1 : C { } final class FC2 { } static assert(!isFinalClass!C); static assert(!isFinalClass!AC); static assert( isFinalClass!FC1); static assert( isFinalClass!FC2); C c; static assert(!isFinalClass!c); FC1 fc1; static assert( isFinalClass!fc1);
Removes all qualifiers, if any, from type T
.
static assert(is(Unqual!int == int)); static assert(is(Unqual!(const int) == int)); static assert(is(Unqual!(immutable int) == int)); static assert(is(Unqual!(shared int) == int)); static assert(is(Unqual!(shared(const int)) == int));
Copies type qualifiers from FromType
to ToType
.
Supported type qualifiers:
const
inout
immutable
shared
static assert(is(CopyTypeQualifiers!(inout const real, int) == inout const int));
Returns the type of Target
with the "constness" of Source
. A type's constness refers to whether it is const
, immutable
, or inout
. If source
has no constness, the returned type will be the same as Target
.
const(int) i; CopyConstness!(typeof(i), float) f; assert( is(typeof(f) == const float)); CopyConstness!(char, uint) u; assert( is(typeof(u) == uint)); //The 'shared' qualifier will not be copied assert(!is(CopyConstness!(shared bool, int) == shared int)); //But the constness will be assert( is(CopyConstness!(shared const real, double) == const double)); //Careful, const(int)[] is a mutable array of const(int) alias MutT = CopyConstness!(const(int)[], int); assert(!is(MutT == const(int))); //Okay, const(int[]) applies to array and contained ints alias CstT = CopyConstness!(const(int[]), int); assert( is(CstT == const(int)));
Returns the inferred type of the loop variable when a variable of type T is iterated over using a foreach
loop with a single loop variable and automatically inferred return type. Note that this may not be the same as std.range.ElementType!Range
in the case of narrow strings, or if T has both opApply and a range interface.
static assert(is(ForeachType!(uint[]) == uint)); static assert(is(ForeachType!string == immutable(char))); static assert(is(ForeachType!(string[string]) == string)); static assert(is(ForeachType!(inout(int)[]) == inout(int)));
Strips off all enum
s from type T
.
enum E : real { a = 0 } // NOTE: explicit initialization to 0 required during Enum init deprecation cycle enum F : E { a = E.a } alias G = const(F); static assert(is(OriginalType!E == real)); static assert(is(OriginalType!F == real)); static assert(is(OriginalType!G == const real));
Get the Key type of an Associative Array.
alias Hash = int[string]; static assert(is(KeyType!Hash == string)); static assert(is(ValueType!Hash == int)); KeyType!Hash str = "a"; // str is declared as string ValueType!Hash num = 1; // num is declared as int
Get the Value type of an Associative Array.
alias Hash = int[string]; static assert(is(KeyType!Hash == string)); static assert(is(ValueType!Hash == int)); KeyType!Hash str = "a"; // str is declared as string ValueType!Hash num = 1; // num is declared as int
T | A built in integral or vector type. |
T
with the same type qualifiers. If T
is not a integral or vector, a compile-time error is given.static assert(is(Unsigned!(int) == uint)); static assert(is(Unsigned!(long) == ulong)); static assert(is(Unsigned!(const short) == const ushort)); static assert(is(Unsigned!(immutable byte) == immutable ubyte)); static assert(is(Unsigned!(inout int) == inout uint));
static assert(is(Unsigned!(uint) == uint)); static assert(is(Unsigned!(const uint) == const uint)); static assert(is(Unsigned!(ubyte) == ubyte)); static assert(is(Unsigned!(immutable uint) == immutable uint));
Returns the largest type, i.e. T such that T.sizeof is the largest. If more than one type is of the same size, the leftmost argument of these in will be returned.
static assert(is(Largest!(uint, ubyte, ushort, real) == real)); static assert(is(Largest!(ulong, double) == ulong)); static assert(is(Largest!(double, ulong) == double)); static assert(is(Largest!(uint, byte, double, short) == double)); static if (is(ucent)) static assert(is(Largest!(uint, ubyte, ucent, ushort) == ucent));
Returns the corresponding signed type for T. T must be a numeric integral type, otherwise a compile-time error occurs.
alias S1 = Signed!uint; static assert(is(S1 == int)); alias S2 = Signed!(const(uint)); static assert(is(S2 == const(int))); alias S3 = Signed!(immutable(uint)); static assert(is(S3 == immutable(int))); static if (is(ucent)) { alias S4 = Signed!ucent; static assert(is(S4 == cent)); }
Returns the most negative value of the numeric type T.
static assert(mostNegative!float == -float.max); static assert(mostNegative!double == -double.max); static assert(mostNegative!real == -real.max); static assert(mostNegative!bool == false);
import std.meta : AliasSeq; static foreach (T; AliasSeq!(bool, byte, short, int, long)) static assert(mostNegative!T == T.min); static foreach (T; AliasSeq!(ubyte, ushort, uint, ulong, char, wchar, dchar)) static assert(mostNegative!T == 0);
Get the type that a scalar type T
will promote to in multi-term arithmetic expressions.
ubyte a = 3, b = 5; static assert(is(typeof(a * b) == Promoted!ubyte)); static assert(is(Promoted!ubyte == int)); static assert(is(Promoted!(shared(bool)) == shared(int))); static assert(is(Promoted!(const(int)) == const(int))); static assert(is(Promoted!double == double));
Returns the mangled name of symbol or type sth
.
mangledName
is the same as builtin .mangleof
property, but might be more convenient in generic code, e.g. as a template argument when invoking staticMap.
import std.meta : AliasSeq; alias TL = staticMap!(mangledName, int, const int, immutable int); static assert(TL == AliasSeq!("i", "xi", "yi"));
Aliases itself to T[0]
if the boolean condition
is true
and to T[1]
otherwise.
// can select types static assert(is(Select!(true, int, long) == int)); static assert(is(Select!(false, int, long) == long)); static struct Foo {} static assert(is(Select!(false, const(int), const(Foo)) == const(Foo))); // can select symbols int a = 1; int b = 2; alias selA = Select!(true, a, b); alias selB = Select!(false, a, b); writeln(selA); // 1 writeln(selB); // 2 // can select (compile-time) expressions enum val = Select!(false, -4, 9 - 6); static assert(val == 3);
Select one of two functions to run via template parameter.
cond | A bool which determines which function is run |
A a
| The first function |
B b
| The second function |
a
without evaluating b
if cond
is true
. Otherwise, returns b
without evaluating a
.real run() { return 0; } int fail() { assert(0); } auto a = select!true(run(), fail()); auto b = select!false(fail(), run()); static assert(is(typeof(a) == real)); static assert(is(typeof(b) == real));
Determine if a symbol has a given user-defined attribute.
getUDAs
enum E; struct S {} @("alpha") int a; static assert(hasUDA!(a, "alpha")); static assert(!hasUDA!(a, S)); static assert(!hasUDA!(a, E)); @(E) int b; static assert(!hasUDA!(b, "alpha")); static assert(!hasUDA!(b, S)); static assert(hasUDA!(b, E)); @E int c; static assert(!hasUDA!(c, "alpha")); static assert(!hasUDA!(c, S)); static assert(hasUDA!(c, E)); @(S, E) int d; static assert(!hasUDA!(d, "alpha")); static assert(hasUDA!(d, S)); static assert(hasUDA!(d, E)); @S int e; static assert(!hasUDA!(e, "alpha")); static assert(hasUDA!(e, S)); static assert(!hasUDA!(e, S())); static assert(!hasUDA!(e, E)); @S() int f; static assert(!hasUDA!(f, "alpha")); static assert(hasUDA!(f, S)); static assert(hasUDA!(f, S())); static assert(!hasUDA!(f, E)); @(S, E, "alpha") int g; static assert(hasUDA!(g, "alpha")); static assert(hasUDA!(g, S)); static assert(hasUDA!(g, E)); @(100) int h; static assert(hasUDA!(h, 100)); struct Named { string name; } @Named("abc") int i; static assert(hasUDA!(i, Named)); static assert(hasUDA!(i, Named("abc"))); static assert(!hasUDA!(i, Named("def"))); struct AttrT(T) { string name; T value; } @AttrT!int("answer", 42) int j; static assert(hasUDA!(j, AttrT)); static assert(hasUDA!(j, AttrT!int)); static assert(!hasUDA!(j, AttrT!string)); @AttrT!string("hello", "world") int k; static assert(hasUDA!(k, AttrT)); static assert(!hasUDA!(k, AttrT!int)); static assert(hasUDA!(k, AttrT!string)); struct FuncAttr(alias f) { alias func = f; } static int fourtyTwo() { return 42; } static size_t getLen(string s) { return s.length; } @FuncAttr!getLen int l; static assert(hasUDA!(l, FuncAttr)); static assert(!hasUDA!(l, FuncAttr!fourtyTwo)); static assert(hasUDA!(l, FuncAttr!getLen)); static assert(!hasUDA!(l, FuncAttr!fourtyTwo())); static assert(!hasUDA!(l, FuncAttr!getLen())); @FuncAttr!getLen() int m; static assert(hasUDA!(m, FuncAttr)); static assert(!hasUDA!(m, FuncAttr!fourtyTwo)); static assert(hasUDA!(m, FuncAttr!getLen)); static assert(!hasUDA!(m, FuncAttr!fourtyTwo())); static assert(hasUDA!(m, FuncAttr!getLen()));
Gets the matching user-defined attributes from the given symbol.
If the UDA is a type, then any UDAs of the same type on the symbol will match. If the UDA is a template for a type, then any UDA which is an instantiation of that template will match. And if the UDA is a value, then any UDAs on the symbol which are equal to that value will match.
hasUDA
struct Attr { string name; int value; } @Attr("Answer", 42) int a; static assert(getUDAs!(a, Attr).length == 1); static assert(getUDAs!(a, Attr)[0].name == "Answer"); static assert(getUDAs!(a, Attr)[0].value == 42); @(Attr("Answer", 42), "string", 9999) int b; static assert(getUDAs!(b, Attr).length == 1); static assert(getUDAs!(b, Attr)[0].name == "Answer"); static assert(getUDAs!(b, Attr)[0].value == 42); @Attr("Answer", 42) @Attr("Pi", 3) int c; static assert(getUDAs!(c, Attr).length == 2); static assert(getUDAs!(c, Attr)[0].name == "Answer"); static assert(getUDAs!(c, Attr)[0].value == 42); static assert(getUDAs!(c, Attr)[1].name == "Pi"); static assert(getUDAs!(c, Attr)[1].value == 3); static assert(getUDAs!(c, Attr("Answer", 42)).length == 1); static assert(getUDAs!(c, Attr("Answer", 42))[0].name == "Answer"); static assert(getUDAs!(c, Attr("Answer", 42))[0].value == 42); static assert(getUDAs!(c, Attr("Answer", 99)).length == 0); struct AttrT(T) { string name; T value; } @AttrT!uint("Answer", 42) @AttrT!int("Pi", 3) @AttrT int d; static assert(getUDAs!(d, AttrT).length == 2); static assert(getUDAs!(d, AttrT)[0].name == "Answer"); static assert(getUDAs!(d, AttrT)[0].value == 42); static assert(getUDAs!(d, AttrT)[1].name == "Pi"); static assert(getUDAs!(d, AttrT)[1].value == 3); static assert(getUDAs!(d, AttrT!uint).length == 1); static assert(getUDAs!(d, AttrT!uint)[0].name == "Answer"); static assert(getUDAs!(d, AttrT!uint)[0].value == 42); static assert(getUDAs!(d, AttrT!int).length == 1); static assert(getUDAs!(d, AttrT!int)[0].name == "Pi"); static assert(getUDAs!(d, AttrT!int)[0].value == 3); struct SimpleAttr {} @SimpleAttr int e; static assert(getUDAs!(e, SimpleAttr).length == 1); static assert(is(getUDAs!(e, SimpleAttr)[0] == SimpleAttr)); @SimpleAttr() int f; static assert(getUDAs!(f, SimpleAttr).length == 1); static assert(is(typeof(getUDAs!(f, SimpleAttr)[0]) == SimpleAttr)); struct FuncAttr(alias f) { alias func = f; } static int add42(int v) { return v + 42; } static string concat(string l, string r) { return l ~ r; } @FuncAttr!add42 int g; static assert(getUDAs!(g, FuncAttr).length == 1); static assert(getUDAs!(g, FuncAttr)[0].func(5) == 47); static assert(getUDAs!(g, FuncAttr!add42).length == 1); static assert(getUDAs!(g, FuncAttr!add42)[0].func(5) == 47); static assert(getUDAs!(g, FuncAttr!add42()).length == 0); static assert(getUDAs!(g, FuncAttr!concat).length == 0); static assert(getUDAs!(g, FuncAttr!concat()).length == 0); @FuncAttr!add42() int h; static assert(getUDAs!(h, FuncAttr).length == 1); static assert(getUDAs!(h, FuncAttr)[0].func(5) == 47); static assert(getUDAs!(h, FuncAttr!add42).length == 1); static assert(getUDAs!(h, FuncAttr!add42)[0].func(5) == 47); static assert(getUDAs!(h, FuncAttr!add42()).length == 1); static assert(getUDAs!(h, FuncAttr!add42())[0].func(5) == 47); static assert(getUDAs!(h, FuncAttr!concat).length == 0); static assert(getUDAs!(h, FuncAttr!concat()).length == 0); @("alpha") @(42) int i; static assert(getUDAs!(i, "alpha").length == 1); static assert(getUDAs!(i, "alpha")[0] == "alpha"); static assert(getUDAs!(i, 42).length == 1); static assert(getUDAs!(i, 42)[0] == 42); static assert(getUDAs!(i, 'c').length == 0);
symbol | The aggregate type to search |
attribute | The user-defined attribute to search for |
symbol
that have the given UDA attribute
. enum Attr; struct A { @Attr int a; int b; } static assert(getSymbolsByUDA!(A, Attr).length == 1); static assert(hasUDA!(getSymbolsByUDA!(A, Attr)[0], Attr));
enum Attr; static struct A { @Attr int a; int b; @Attr void doStuff() {} void doOtherStuff() {} static struct Inner { // Not found by getSymbolsByUDA @Attr int c; } } // Finds both variables and functions with the attribute, but // doesn't include the variables and functions without it. static assert(getSymbolsByUDA!(A, Attr).length == 2); // Can access attributes on the symbols returned by getSymbolsByUDA. static assert(hasUDA!(getSymbolsByUDA!(A, Attr)[0], Attr)); static assert(hasUDA!(getSymbolsByUDA!(A, Attr)[1], Attr));
static struct UDA { string name; } static struct B { @UDA("X") int x; @UDA("Y") int y; @(100) int z; } // Finds both UDA attributes. static assert(getSymbolsByUDA!(B, UDA).length == 2); // Finds one `100` attribute. static assert(getSymbolsByUDA!(B, 100).length == 1); // Can get the value of the UDA from the return value static assert(getUDAs!(getSymbolsByUDA!(B, UDA)[0], UDA)[0].name == "X");
static struct UDA { string name; } @UDA("A") static struct C { @UDA("B") int d; } static assert(getSymbolsByUDA!(C, UDA).length == 2); static assert(getSymbolsByUDA!(C, UDA)[0].stringof == "C"); static assert(getSymbolsByUDA!(C, UDA)[1].stringof == "d");
static struct UDA { string name; } static struct D { int x; } static assert(getSymbolsByUDA!(D, UDA).length == 0);
true
iff all types T
are the same.static assert(allSameType!(int, int)); static assert(allSameType!(int, int, int)); static assert(allSameType!(float, float, float)); static assert(!allSameType!(int, double)); static assert(!allSameType!(int, float, double)); static assert(!allSameType!(int, float, double, real)); static assert(!allSameType!(short, int, float, double, real));
true
iff the type T
can be tested in an if
-expression, that is if if (pred(T.init)) {}
is compilable.Detect whether X
is a type. Analogous to is(X)
. This is useful when used in conjunction with other templates, e.g. allSatisfy!(isType, X)
.
true
if X
is a type, false
otherwisestruct S { template Test() {} } class C {} interface I {} union U {} static assert(isType!int); static assert(isType!string); static assert(isType!(int[int])); static assert(isType!S); static assert(isType!C); static assert(isType!I); static assert(isType!U); int n; void func(){} static assert(!isType!n); static assert(!isType!func); static assert(!isType!(S.Test)); static assert(!isType!(S.Test!()));
Detect whether symbol or type X
is a function. This is different that finding if a symbol is callable or satisfying is(X == function)
, it finds specifically if the symbol represents a normal function declaration, i.e. not a delegate or a function pointer.
true
if X
is a function, false
otherwise isFunctionPointer
or isDelegate
for detecting those types respectively.static void func(){} static assert(isFunction!func); struct S { void func(){} } static assert(isFunction!(S.func));
Detect whether X
is a final method or class.
true
if X
is final, false
otherwiseclass C { void nf() {} static void sf() {} final void ff() {} } final class FC { } static assert(!isFinal!(C)); static assert( isFinal!(FC)); static assert(!isFinal!(C.nf)); static assert(!isFinal!(C.sf)); static assert( isFinal!(C.ff));
Determines whether the type S
can be copied. If a type cannot be copied, then code such as MyStruct x; auto y = x;
will fail to compile. Copying for structs can be disabled by using @disable this(this)
.
S | The type to check. |
true
if S
can be copied. false
otherwise.struct S1 {} // Fine. Can be copied struct S2 { this(this) {}} // Fine. Can be copied struct S3 {@disable this(this); } // Not fine. Copying is disabled. struct S4 {S3 s;} // Not fine. A field has copying disabled. class C1 {} static assert( isCopyable!S1); static assert( isCopyable!S2); static assert(!isCopyable!S3); static assert(!isCopyable!S4); static assert(isCopyable!C1); static assert(isCopyable!int); static assert(isCopyable!(int[]));
© 1999–2019 The D Language Foundation
Licensed under the Boost License 1.0.
https://dlang.org/phobos/std_traits.html