/**
* Contains traits for runtime internal usage.
*
* Copyright: Copyright Digital Mars 2014 -.
* License: $(HTTP www.boost.org/LICENSE_1_0.txt, Boost License 1.0).
* Authors: Martin Nowak
* Source: $(DRUNTIMESRC core/internal/_traits.d)
*/
module core.internal.traits;
alias AliasSeq(TList...) = TList;
template Fields(T)
{
static if (is(T == struct) || is(T == union))
alias Fields = typeof(T.tupleof[0 .. $ - __traits(isNested, T)]);
else static if (is(T == class) || is(T == interface))
alias Fields = typeof(T.tupleof);
else
alias Fields = AliasSeq!T;
}
T trustedCast(T, U)(auto ref U u) @trusted pure nothrow
{
return cast(T)u;
}
alias Unconst(T : const U, U) = U;
/// taken from std.traits.Unqual
template Unqual(T : const U, U)
{
static if (is(U == shared V, V))
alias Unqual = V;
else
alias Unqual = U;
}
template BaseElemOf(T)
{
static if (is(T == E[N], E, size_t N))
alias BaseElemOf = BaseElemOf!E;
else
alias BaseElemOf = T;
}
unittest
{
static assert(is(BaseElemOf!(int) == int));
static assert(is(BaseElemOf!(int[1]) == int));
static assert(is(BaseElemOf!(int[1][2]) == int));
static assert(is(BaseElemOf!(int[1][]) == int[1][]));
static assert(is(BaseElemOf!(int[][1]) == int[]));
}
// [For internal use]
template ModifyTypePreservingTQ(alias Modifier, T)
{
static if (is(T U == immutable U)) alias ModifyTypePreservingTQ = immutable Modifier!U;
else static if (is(T U == shared inout const U)) alias ModifyTypePreservingTQ = shared inout const Modifier!U;
else static if (is(T U == shared inout U)) alias ModifyTypePreservingTQ = shared inout Modifier!U;
else static if (is(T U == shared const U)) alias ModifyTypePreservingTQ = shared const Modifier!U;
else static if (is(T U == shared U)) alias ModifyTypePreservingTQ = shared Modifier!U;
else static if (is(T U == inout const U)) alias ModifyTypePreservingTQ = inout const Modifier!U;
else static if (is(T U == inout U)) alias ModifyTypePreservingTQ = inout Modifier!U;
else static if (is(T U == const U)) alias ModifyTypePreservingTQ = const Modifier!U;
else alias ModifyTypePreservingTQ = Modifier!T;
}
@safe unittest
{
alias Intify(T) = int;
static assert(is(ModifyTypePreservingTQ!(Intify, real) == int));
static assert(is(ModifyTypePreservingTQ!(Intify, const real) == const int));
static assert(is(ModifyTypePreservingTQ!(Intify, inout real) == inout int));
static assert(is(ModifyTypePreservingTQ!(Intify, inout const real) == inout const int));
static assert(is(ModifyTypePreservingTQ!(Intify, shared real) == shared int));
static assert(is(ModifyTypePreservingTQ!(Intify, shared const real) == shared const int));
static assert(is(ModifyTypePreservingTQ!(Intify, shared inout real) == shared inout int));
static assert(is(ModifyTypePreservingTQ!(Intify, shared inout const real) == shared inout const int));
static assert(is(ModifyTypePreservingTQ!(Intify, immutable real) == immutable int));
}
// Substitute all `inout` qualifiers that appears in T to `const`
template substInout(T)
{
static if (is(T == immutable))
{
alias substInout = T;
}
else static if (is(T : shared const U, U) || is(T : const U, U))
{
// U is top-unqualified
mixin("alias substInout = "
~ (is(T == shared) ? "shared " : "")
~ (is(T == const) || is(T == inout) ? "const " : "") // substitute inout to const
~ "substInoutForm!U;");
}
else
static assert(0);
}
private template substInoutForm(T)
{
static if (is(T == struct) || is(T == class) || is(T == union) || is(T == interface))
{
alias substInoutForm = T; // prevent matching to the form of alias-this-ed type
}
else static if (is(T : V[K], K, V)) alias substInoutForm = substInout!V[substInout!K];
else static if (is(T : U[n], U, size_t n)) alias substInoutForm = substInout!U[n];
else static if (is(T : U[], U)) alias substInoutForm = substInout!U[];
else static if (is(T : U*, U)) alias substInoutForm = substInout!U*;
else alias substInoutForm = T;
}
/// used to declare an extern(D) function that is defined in a different module
template externDFunc(string fqn, T:FT*, FT) if (is(FT == function))
{
static if (is(FT RT == return) && is(FT Args == function))
{
import core.demangle : mangleFunc;
enum decl = {
string s = "extern(D) RT externDFunc(Args)";
foreach (attr; __traits(getFunctionAttributes, FT))
s ~= " " ~ attr;
return s ~ ";";
}();
pragma(mangle, mangleFunc!T(fqn)) mixin(decl);
}
else
static assert(0);
}
template staticIota(int beg, int end)
{
static if (beg + 1 >= end)
{
static if (beg >= end)
{
alias staticIota = AliasSeq!();
}
else
{
alias staticIota = AliasSeq!(+beg);
}
}
else
{
enum mid = beg + (end - beg) / 2;
alias staticIota = AliasSeq!(staticIota!(beg, mid), staticIota!(mid, end));
}
}
private struct __InoutWorkaroundStruct {}
@property T rvalueOf(T)(T val) { return val; }
@property T rvalueOf(T)(inout __InoutWorkaroundStruct = __InoutWorkaroundStruct.init);
@property ref T lvalueOf(T)(inout __InoutWorkaroundStruct = __InoutWorkaroundStruct.init);
// taken from std.traits.isAssignable
template isAssignable(Lhs, Rhs = Lhs)
{
enum isAssignable = __traits(compiles, lvalueOf!Lhs = rvalueOf!Rhs) && __traits(compiles, lvalueOf!Lhs = lvalueOf!Rhs);
}
// taken from std.traits.isInnerClass
template isInnerClass(T) if (is(T == class))
{
static if (is(typeof(T.outer)))
{
template hasOuterMember(T...)
{
static if (T.length == 0)
enum hasOuterMember = false;
else
enum hasOuterMember = T[0] == "outer" || hasOuterMember!(T[1 .. $]);
}
enum isInnerClass = __traits(isSame, typeof(T.outer), __traits(parent, T)) && !hasOuterMember!(__traits(allMembers, T));
}
else
enum isInnerClass = false;
}
template dtorIsNothrow(T)
{
enum dtorIsNothrow = is(typeof(function{T t=void;}) : void function() nothrow);
}
// taken from std.meta.allSatisfy
template allSatisfy(alias F, T...)
{
static foreach (Ti; T)
{
static if (!is(typeof(allSatisfy) == bool) && // not yet defined
!F!(Ti))
{
enum allSatisfy = false;
}
}
static if (!is(typeof(allSatisfy) == bool)) // if not yet defined
{
enum allSatisfy = true;
}
}
// taken from std.meta.anySatisfy
template anySatisfy(alias F, Ts...)
{
static foreach (T; Ts)
{
static if (!is(typeof(anySatisfy) == bool) && // not yet defined
F!T)
{
enum anySatisfy = true;
}
}
static if (!is(typeof(anySatisfy) == bool)) // if not yet defined
{
enum anySatisfy = false;
}
}
// simplified from std.traits.maxAlignment
template maxAlignment(Ts...)
if (Ts.length > 0)
{
enum maxAlignment =
{
size_t result = 0;
static foreach (T; Ts)
if (T.alignof > result) result = T.alignof;
return result;
}();
}
template classInstanceAlignment(T)
if (is(T == class))
{
enum classInstanceAlignment = __traits(classInstanceAlignment, T);
}
/// See $(REF hasElaborateMove, std,traits)
template hasElaborateMove(S)
{
static if (__traits(isStaticArray, S))
{
enum bool hasElaborateMove = S.sizeof && hasElaborateMove!(BaseElemOf!S);
}
else static if (is(S == struct))
{
enum hasElaborateMove = (is(typeof(S.init.opPostMove(lvalueOf!S))) &&
!is(typeof(S.init.opPostMove(rvalueOf!S)))) ||
anySatisfy!(.hasElaborateMove, Fields!S);
}
else
{
enum bool hasElaborateMove = false;
}
}
// std.traits.hasElaborateDestructor
template hasElaborateDestructor(S)
{
static if (__traits(isStaticArray, S))
{
enum bool hasElaborateDestructor = S.sizeof && hasElaborateDestructor!(BaseElemOf!S);
}
else static if (is(S == struct))
{
enum hasElaborateDestructor = __traits(hasMember, S, "__dtor")
|| anySatisfy!(.hasElaborateDestructor, Fields!S);
}
else
{
enum bool hasElaborateDestructor = false;
}
}
// std.traits.hasElaborateCopyDestructor
template hasElaborateCopyConstructor(S)
{
static if (__traits(isStaticArray, S))
{
enum bool hasElaborateCopyConstructor = S.sizeof && hasElaborateCopyConstructor!(BaseElemOf!S);
}
else static if (is(S == struct))
{
enum hasElaborateCopyConstructor = __traits(hasCopyConstructor, S) || __traits(hasPostblit, S);
}
else
{
enum bool hasElaborateCopyConstructor = false;
}
}
@safe unittest
{
static struct S
{
int x;
this(return scope ref typeof(this) rhs) { }
this(int x, int y) {}
}
static assert(hasElaborateCopyConstructor!S);
static assert(!hasElaborateCopyConstructor!(S[0][1]));
static struct S2
{
int x;
this(int x, int y) {}
}
static assert(!hasElaborateCopyConstructor!S2);
static struct S3
{
int x;
this(return scope ref typeof(this) rhs, int x = 42) { }
this(int x, int y) {}
}
static assert(hasElaborateCopyConstructor!S3);
}
template hasElaborateAssign(S)
{
static if (__traits(isStaticArray, S))
{
enum bool hasElaborateAssign = S.sizeof && hasElaborateAssign!(BaseElemOf!S);
}
else static if (is(S == struct))
{
enum hasElaborateAssign = is(typeof(S.init.opAssign(rvalueOf!S))) ||
is(typeof(S.init.opAssign(lvalueOf!S))) ||
anySatisfy!(.hasElaborateAssign, Fields!S);
}
else
{
enum bool hasElaborateAssign = false;
}
}
template hasIndirections(T)
{
static if (is(T == struct) || is(T == union))
enum hasIndirections = anySatisfy!(.hasIndirections, typeof(T.tupleof));
else static if (is(T == E[N], E, size_t N))
enum hasIndirections = T.sizeof && is(E == void) ? true : hasIndirections!(BaseElemOf!E);
else static if (isFunctionPointer!T)
enum hasIndirections = false;
else
enum hasIndirections = isPointer!T || isDelegate!T || isDynamicArray!T ||
__traits(isAssociativeArray, T) || is (T == class) || is(T == interface);
}
template hasUnsharedIndirections(T)
{
static if (is(T == immutable))
enum hasUnsharedIndirections = false;
else static if (is(T == struct) || is(T == union))
enum hasUnsharedIndirections = anySatisfy!(.hasUnsharedIndirections, Fields!T);
else static if (is(T : E[N], E, size_t N))
enum hasUnsharedIndirections = is(E == void) ? false : hasUnsharedIndirections!E;
else static if (isFunctionPointer!T)
enum hasUnsharedIndirections = false;
else static if (isPointer!T)
enum hasUnsharedIndirections = !is(T : shared(U)*, U) && !is(T : immutable(U)*, U);
else static if (isDynamicArray!T)
enum hasUnsharedIndirections = !is(T : shared(V)[], V) && !is(T : immutable(V)[], V);
else static if (is(T == class) || is(T == interface))
enum hasUnsharedIndirections = !is(T : shared(W), W);
else
enum hasUnsharedIndirections = isDelegate!T || __traits(isAssociativeArray, T); // TODO: how to handle these?
}
unittest
{
static struct Foo { shared(int)* val; }
static assert(!hasUnsharedIndirections!(immutable(char)*));
static assert(!hasUnsharedIndirections!(string));
static assert(!hasUnsharedIndirections!(Foo));
static assert( hasUnsharedIndirections!(Foo*));
static assert(!hasUnsharedIndirections!(shared(Foo)*));
static assert(!hasUnsharedIndirections!(immutable(Foo)*));
int local;
struct HasContextPointer { int opCall() { return ++local; } }
static assert(hasIndirections!HasContextPointer);
}
enum bool isAggregateType(T) = is(T == struct) || is(T == union) ||
is(T == class) || is(T == interface);
enum bool isPointer(T) = is(T == U*, U) && !isAggregateType!T;
enum bool isDynamicArray(T) = is(DynamicArrayTypeOf!T) && !isAggregateType!T;
template OriginalType(T)
{
template Impl(T)
{
static if (is(T U == enum)) alias Impl = OriginalType!U;
else alias Impl = T;
}
alias OriginalType = ModifyTypePreservingTQ!(Impl, T);
}
template DynamicArrayTypeOf(T)
{
static if (is(AliasThisTypeOf!T AT) && !is(AT[] == AT))
alias X = DynamicArrayTypeOf!AT;
else
alias X = OriginalType!T;
static if (is(Unqual!X : E[], E) && !is(typeof({ enum n = X.length; })))
alias DynamicArrayTypeOf = X;
else
static assert(0, T.stringof ~ " is not a dynamic array");
}
private template AliasThisTypeOf(T)
if (isAggregateType!T)
{
alias members = __traits(getAliasThis, T);
static if (members.length == 1)
alias AliasThisTypeOf = typeof(__traits(getMember, T.init, members[0]));
else
static assert(0, T.stringof~" does not have alias this type");
}
template isFunctionPointer(T...)
if (T.length == 1)
{
static if (is(T[0] U) || is(typeof(T[0]) U))
{
static if (is(U F : F*) && is(F == function))
enum bool isFunctionPointer = true;
else
enum bool isFunctionPointer = false;
}
else
enum bool isFunctionPointer = false;
}
template isDelegate(T...)
if (T.length == 1)
{
static if (is(typeof(& T[0]) U : U*) && is(typeof(& T[0]) U == delegate))
{
// T is a (nested) function symbol.
enum bool isDelegate = true;
}
else static if (is(T[0] W) || is(typeof(T[0]) W))
{
// T is an expression or a type. Take the type of it and examine.
enum bool isDelegate = is(W == delegate);
}
else
enum bool isDelegate = false;
}
// std.meta.Filter
template Filter(alias pred, TList...)
{
static if (TList.length == 0)
{
alias Filter = AliasSeq!();
}
else static if (TList.length == 1)
{
static if (pred!(TList[0]))
alias Filter = AliasSeq!(TList[0]);
else
alias Filter = AliasSeq!();
}
/* The next case speeds up compilation by reducing
* the number of Filter instantiations
*/
else static if (TList.length == 2)
{
static if (pred!(TList[0]))
{
static if (pred!(TList[1]))
alias Filter = AliasSeq!(TList[0], TList[1]);
else
alias Filter = AliasSeq!(TList[0]);
}
else
{
static if (pred!(TList[1]))
alias Filter = AliasSeq!(TList[1]);
else
alias Filter = AliasSeq!();
}
}
else
{
alias Filter =
AliasSeq!(
Filter!(pred, TList[ 0 .. $/2]),
Filter!(pred, TList[$/2 .. $ ]));
}
}
// std.meta.staticMap
template staticMap(alias F, T...)
{
static if (T.length == 0)
{
alias staticMap = AliasSeq!();
}
else static if (T.length == 1)
{
alias staticMap = AliasSeq!(F!(T[0]));
}
/* Cases 2 to 8 improve compile performance by reducing
* the number of recursive instantiations of staticMap
*/
else static if (T.length == 2)
{
alias staticMap = AliasSeq!(F!(T[0]), F!(T[1]));
}
else static if (T.length == 3)
{
alias staticMap = AliasSeq!(F!(T[0]), F!(T[1]), F!(T[2]));
}
else static if (T.length == 4)
{
alias staticMap = AliasSeq!(F!(T[0]), F!(T[1]), F!(T[2]), F!(T[3]));
}
else static if (T.length == 5)
{
alias staticMap = AliasSeq!(F!(T[0]), F!(T[1]), F!(T[2]), F!(T[3]), F!(T[4]));
}
else static if (T.length == 6)
{
alias staticMap = AliasSeq!(F!(T[0]), F!(T[1]), F!(T[2]), F!(T[3]), F!(T[4]), F!(T[5]));
}
else static if (T.length == 7)
{
alias staticMap = AliasSeq!(F!(T[0]), F!(T[1]), F!(T[2]), F!(T[3]), F!(T[4]), F!(T[5]), F!(T[6]));
}
else static if (T.length == 8)
{
alias staticMap = AliasSeq!(F!(T[0]), F!(T[1]), F!(T[2]), F!(T[3]), F!(T[4]), F!(T[5]), F!(T[6]), F!(T[7]));
}
else
{
alias staticMap =
AliasSeq!(
staticMap!(F, T[ 0 .. $/2]),
staticMap!(F, T[$/2 .. $ ]));
}
}
// std.exception.assertCTFEable
version (CoreUnittest) package(core)
void assertCTFEable(alias dg)()
{
static assert({ cast(void) dg(); return true; }());
cast(void) dg();
}
// std.traits.FunctionTypeOf
/*
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.
Note:
Do not confuse function types with function pointer types; function types are
usually used for compile-time reflection purposes.
*/
template FunctionTypeOf(func...)
if (func.length == 1 /*&& isCallable!func*/)
{
static if (is(typeof(& func[0]) Fsym : Fsym*) && is(Fsym == function) || is(typeof(& func[0]) Fsym == delegate))
{
alias FunctionTypeOf = Fsym; // HIT: (nested) function symbol
}
else static if (is(typeof(& func[0].opCall) Fobj == delegate))
{
alias FunctionTypeOf = Fobj; // HIT: callable object
}
else static if (is(typeof(& func[0].opCall) Ftyp : Ftyp*) && is(Ftyp == function))
{
alias FunctionTypeOf = Ftyp; // HIT: callable type
}
else static if (is(func[0] T) || is(typeof(func[0]) T))
{
static if (is(T == function))
alias FunctionTypeOf = T; // HIT: function
else static if (is(T Fptr : Fptr*) && is(Fptr == function))
alias FunctionTypeOf = Fptr; // HIT: function pointer
else static if (is(T Fdlg == delegate))
alias FunctionTypeOf = Fdlg; // HIT: delegate
else
static assert(0);
}
else
static assert(0);
}
@safe unittest
{
class C
{
int value() @property { return 0; }
}
static assert(is( typeof(C.value) == int ));
static assert(is( FunctionTypeOf!(C.value) == function ));
}
@system unittest
{
int test(int a);
int propGet() @property;
int propSet(int a) @property;
int function(int) test_fp;
int delegate(int) test_dg;
static assert(is( typeof(test) == FunctionTypeOf!(typeof(test)) ));
static assert(is( typeof(test) == FunctionTypeOf!test ));
static assert(is( typeof(test) == FunctionTypeOf!test_fp ));
static assert(is( typeof(test) == FunctionTypeOf!test_dg ));
alias int GetterType() @property;
alias int SetterType(int) @property;
static assert(is( FunctionTypeOf!propGet == GetterType ));
static assert(is( FunctionTypeOf!propSet == SetterType ));
interface Prop { int prop() @property; }
Prop prop;
static assert(is( FunctionTypeOf!(Prop.prop) == GetterType ));
static assert(is( FunctionTypeOf!(prop.prop) == GetterType ));
class Callable { int opCall(int) { return 0; } }
auto call = new Callable;
static assert(is( FunctionTypeOf!call == typeof(test) ));
struct StaticCallable { static int opCall(int) { return 0; } }
StaticCallable stcall_val;
StaticCallable* stcall_ptr;
static assert(is( FunctionTypeOf!stcall_val == typeof(test) ));
static assert(is( FunctionTypeOf!stcall_ptr == typeof(test) ));
interface Overloads
{
void test(string);
real test(real);
int test(int);
int test() @property;
}
alias ov = __traits(getVirtualMethods, Overloads, "test");
alias F_ov0 = FunctionTypeOf!(ov[0]);
alias F_ov1 = FunctionTypeOf!(ov[1]);
alias F_ov2 = FunctionTypeOf!(ov[2]);
alias F_ov3 = FunctionTypeOf!(ov[3]);
static assert(is(F_ov0* == void function(string)));
static assert(is(F_ov1* == real function(real)));
static assert(is(F_ov2* == int function(int)));
static assert(is(F_ov3* == int function() @property));
alias F_dglit = FunctionTypeOf!((int a){ return a; });
static assert(is(F_dglit* : int function(int)));
}
// std.traits.ReturnType
/*
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 $(D_KEYWORD ref)
is not part of a type, but the attribute of the function
(see template $(LREF functionAttributes)).
*/
template ReturnType(func...)
if (func.length == 1 /*&& isCallable!func*/)
{
static if (is(FunctionTypeOf!func R == return))
alias ReturnType = R;
else
static assert(0, "argument has no return type");
}
//
@safe unittest
{
int foo();
ReturnType!foo x; // x is declared as int
}
@safe unittest
{
struct G
{
int opCall (int i) { return 1;}
}
alias ShouldBeInt = ReturnType!G;
static assert(is(ShouldBeInt == int));
G g;
static assert(is(ReturnType!g == int));
G* p;
alias pg = ReturnType!p;
static assert(is(pg == int));
class C
{
int opCall (int i) { return 1;}
}
static assert(is(ReturnType!C == int));
C c;
static assert(is(ReturnType!c == int));
class Test
{
int prop() @property { return 0; }
}
alias R_Test_prop = ReturnType!(Test.prop);
static assert(is(R_Test_prop == int));
alias R_dglit = ReturnType!((int a) { return a; });
static assert(is(R_dglit == int));
}
// std.traits.Parameters
/*
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`.
*/
template Parameters(func...)
if (func.length == 1 /*&& isCallable!func*/)
{
static if (is(FunctionTypeOf!func P == function))
alias Parameters = P;
else
static assert(0, "argument has no parameters");
}
//
@safe unittest
{
int foo(int, long);
void bar(Parameters!foo); // declares void bar(int, long);
void abc(Parameters!foo[1]); // declares void abc(long);
}
@safe unittest
{
int foo(int i, bool b) { return 0; }
static assert(is(Parameters!foo == AliasSeq!(int, bool)));
static assert(is(Parameters!(typeof(&foo)) == AliasSeq!(int, bool)));
struct S { real opCall(real r, int i) { return 0.0; } }
S s;
static assert(is(Parameters!S == AliasSeq!(real, int)));
static assert(is(Parameters!(S*) == AliasSeq!(real, int)));
static assert(is(Parameters!s == AliasSeq!(real, int)));
class Test
{
int prop() @property { return 0; }
}
alias P_Test_prop = Parameters!(Test.prop);
static assert(P_Test_prop.length == 0);
alias P_dglit = Parameters!((int a){});
static assert(P_dglit.length == 1);
static assert(is(P_dglit[0] == int));
}
// Return `true` if `Type` has `member` that evaluates to `true` in a static if condition
enum isTrue(Type, string member) = __traits(compiles, { static if (__traits(getMember, Type, member)) {} else static assert(0); });
unittest
{
static struct T
{
enum a = true;
enum b = false;
enum c = 1;
enum d = 45;
enum e = "true";
enum f = "";
enum g = null;
alias h = bool;
}
static assert( isTrue!(T, "a"));
static assert(!isTrue!(T, "b"));
static assert( isTrue!(T, "c"));
static assert( isTrue!(T, "d"));
static assert( isTrue!(T, "e"));
static assert( isTrue!(T, "f"));
static assert(!isTrue!(T, "g"));
static assert(!isTrue!(T, "h"));
}
template hasUDA(alias symbol, alias attribute)
{
alias attrs = __traits(getAttributes, symbol);
static foreach (a; attrs)
{
static if (is(a == attribute))
{
enum hasUDA = true;
}
}
static if (!__traits(compiles, (hasUDA == true)))
enum hasUDA = false;
}
unittest
{
struct SomeUDA{}
struct Test
{
int woUDA;
@SomeUDA int withUDA;
}
static assert(hasUDA!(Test.withUDA, SomeUDA));
static assert(!hasUDA!(Test.woUDA, SomeUDA));
}