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Template Comparison
C++ pioneered templates and template metaprogramming and has continued to improve on it. The D programming language is the first to comprehensively reengineer templates based on the C++ experience.
Feature | D | C++ |
---|---|---|
Argument list delineation | Uses !( ), as in Foo!(int). Can omit parens when the argument is a single lexical token: Foo!int |
Uses < > as in Foo<int> |
Class Templates | Yes:
class Foo(T)
{
T x;
}
|
Yes:
template<class T> class Foo { T x; }; |
Function Templates | Yes:
T foo(T)(T i) { ... } |
Yes:
template<class T> T foo(T i) { ... } |
Member Templates | Yes | Yes |
Constructor Templates | Yes | Yes |
Parameterize any Declaration | Yes, classes, functions, any
alias,
variables, any enum, etc. can be parameterized,
such as this variable:
template Foo(T) { static T* p; } |
C++98 No, only classes and functions C++11 Added using type aliases: template<class T> using ptr = T*; ptr<int> p;C++14 Added constexpr constant: template<class T> constexpr T pi = T(3.1415926535897932385L); |
Template Typedefs: Create an alias that binds to some but not all of the template parameters | Yes:
class Foo(T, U) { } template MyFoo(T) { alias MyFoo = Foo!(T, int); } MyFoo!(uint) f; |
C++98 No C++11 Yes: template<class T, class U> class Foo { }; template<class T> using MyFoo = Foo<T, int>; MyFoo<unsigned> f; |
Sequence Constructors | No, use a variadic parameter instead | C++98 No C++11 Yes: template <class T> class Foo { Foo(std::initializer_list<T>); }; Foo<double> f = { 1.2, 3.0, 6.8 }; |
Concepts | Yes: Constraints | C++98 No C++20 Yes: Constraints and Concepts |
Recursive Templates | Yes:
template factorial(int n) { const factorial = n * factorial!(n-1); } template factorial(int n : 1) { const factorial = 1; } |
Yes:
template<int n> class factorial { public: enum { result = n * factorial<n-1>::result }; }; template<> class factorial<1> { public: enum { result = 1 }; }; |
Conditional Compilation based on Template Arguments | Yes:
void foo(T)(T i) { static if (can_fast_foo!(T)) FastFoo f = fast_foo(i); else SlowFoo f = slow_foo(i); use_foo(f); } class HashTable(T, int maxLength) { static if (maxLength < 0xFFFE) alias CellIdx = ushort; else alias CellIdx = uint; CellIdx index; } |
C++98 No, but workarounds exist: template<class T> void foo(T i) { // Differentiate using a // Helper<bool> specialization Helper<can_fast_foo<T>>::use_foo(i); }; template<class T, int maxLength> class HashTable { typedef typename std::conditional< maxLength < 0xFFFE, uint16_t, uint32_t> ::type CellIdx; CellIdx index; }; C++17 Yes, but it's limited to block scope: template<class T> void foo(T i) { if constexpr (can_fast_foo<T>) FastFoo foo = fast_foo(i); else SlowFoo foo = slow_foo(i); use_foo(foo); // error foo is undeclared } template<class T, int maxLength> class HashTable { // error cannot use 'if' outside of a function if constexpr (maxLength < 0xFFFE) using CellIdx = ushort; else using CellIdx = uint; CellIdx index; }; |
Template Forward Declarations | Not necessary | Yes:
template<class T> class Foo; |
Grouping templates with the same parameters together | Yes:
template Foo(T, U) { class Bar { ... } T foo(T t, U u) { ... } } Foo!(int,long).Bar b; return Foo!(char,int).foo('c',3); |
Sort of, using a class' members:
template<class T, class U> class Foo { class Bar { ... }; static T foo(T t, U u) { ... } }; Foo<int, long>::bar b; return Foo<char, int>::foo('c', 3); |
Deducing this parameter type | Yes | C++23 Yes |
Compile time execution of functions | Yes:
int factorial(int i) { if (i == 0) return 1; else return i * factorial(i - 1); } pragma(msg, factorial(6)); |
C++98 No C++11 Yes, but only for constexpr functions. constexpr was highly restricted in C++11, but each subsequent standard has eased these restrictions. |
Parameters | D | C++ |
Type Parameters | Yes:
class Foo(T) { T x; } Foo!(int) f; |
Yes:
template<class T> class Foo { T x; }; Foo<int> f; |
Integral Parameters | Yes:
void foo(int i)() { int v = i; } |
Yes:
template<int i> void foo() { int v = i; } |
Pointer Parameters | Yes, a pointer to object or function | Yes, a pointer to object or function |
Reference Parameters | No, but an alias parameter can be used instead (see below). | Yes:
template<double& D> void foo() { double y = D; } |
Pointer to Member Parameters | No, D does not have pointers to members. It does have delegates however, which can be used as parameters | Yes |
Template Template Parameters | Yes:
class Foo(T, alias C) { C!(T) x; } |
Yes:
template<class T, template<class U> class C> class Foo { C<T> x; }; |
Alias Parameters | Yes, any symbol can be passed to a template as an alias:
void bar(int); void bar(double); void foo(T, alias S)(T t) { S(t); } // calls bar(double) foo!(double, bar)(1); |
No |
Floating Point Parameters | Yes:
class Foo(double D) { double x = D; } ... Foo!(1.6) F; |
C++98 No C++11 Yes: template<float f> void foo() { int v = f; } |
String Parameters | Yes:
void foo(string format)(int i) { writefln(format, i); } ... foo!("i = %s")(3); |
C++98 No C++17 Only indirectly: template <const char *str>
struct S {};
S<"Foo"> foo1; // error A string literal argument is still illegal
const char foo_str[] = "foo";
S<foo_str> foo2; // Literal types are allowed, including arrays.
|
Local Class Parameters | Yes | C++98 No C++17 Yes |
Local Variable Parameters | Yes | No |
Parameter Default Values | Yes:
class Foo(T = int) { T x; } |
Yes:
template<class T = int> class Foo { T x; }; |
Variadic Parameters | Yes, Variadic Templates:
void print(A...)(A a) { foreach(t; a) writeln(t); } |
C++98 No C++11 Yes: // Need a zero- or one-argument version // to handle the final argument. void print() {}; template <class Arg, class... Args> void print(const Arg& arg, Args&&... args) { writeln(arg); print(std::forward<Args>(args)...); }Note that the example above was improved somewhat in C++17 using Fold Expressions: template <class Args...> void print(Args...&& args) { (writeln(std::forward<Args.>(args)), ...); } |
Specializations | D | C++ |
Explicit Specialization | Yes:
class Foo(T : int) { T x; } |
Yes:
template<> class Foo<int> { int x; }; |
Partial Specialization | Yes:
class Foo(T : T*, U)
{
T x;
}
|
Yes:
template<class T, class U> class Foo<T*, U> { T x; }; |
Partial specialization derived from multiple parameters | Yes:
class Foo(T : Bar!(T, U), U)
{
...
}
|
Yes:
template<class T, class U> class Foo< Bar<T,U> > { ... }; |
Can specializations exist without a primary template? | Yes | No |
Other | D | C++ |
Exported Templates | Yes, it falls out as a natural consequence of modules | C++98 Yes, but was only support in compilers based on EDG's front end. C++11 Was removed from the language due to a lack of support. |
SFINAE (Substitution Failure Is Not An Error) | No | Yes |
Parse Template Definition Bodies before Instantiation | Yes | Not required by the Standard, but some implementations do |
Overloading Function Templates with Functions | Yes:
void foo(T)(T t) { } void foo(int i) { } |
Yes:
template<class T> void foo(T t) { } void foo(int i) { } |
Implicit Function Template Instantiation | Yes | Yes |
Templates can be evaluated in scope of instantiation rather than definition | Yes, Template Mixins | No, but can be faked using macros |
Can extract arguments of template instance | Yes:
struct Bar(T1, T2) { } alias BarInst = Bar!(int, float); static if (is(BarInst : Template!Args, alias Template, Args...)) { pragma(msg, Args); // (int, float) } |
No |
Parsing Idiosyncracies | D | C++ |
Context-Free Grammar | Yes:
class Foo(int i) { ... } Foo!(3 > 4) f; |
No:
template<int i> class Foo
{
...
};
Foo<3 > 4> f; // error
|
Distinguish template arguments from other operators | Yes:
class Foo(T) { ... } class Bar(int i) { ... } Foo!(Bar!(1)) x1; |
C++98 No: template<class T> class Foo
{
...
};
template<int i> class Bar
{
...
};
Foo<Bar<1>> x1; // error
Foo<Bar<1> > x2;
C++11 Partially fixed by Right Angle Brackets N1757 |
Redeclaration of Template Parameter | Yes:
class Foo(T) { int T; void foo() { int T; } } |
No:
template<class T> class Foo { int T; // error void foo() { int T; // error } }; |
Dependent Base Class Lookup | Yes:
class Foo(T) { alias A = int; } class Bar(T) : Foo(T) { A x; } |
No:
template<class T>
class Foo
{
public:
typedef int A;
};
template<class T>
class Bar : Foo<T>
{
public:
A x; // error
};
|
Forward Referencing | Yes:
int g(void *); class Foo(T) { int foo() { return g(1); } } int g(int i); |
No:
int g(void *);
template<class T>
class Foo
{
int foo()
{
return g(1); // error
}
};
int g(int i);
|
Member templates parseable without hints | Yes:
class Foo { Foo bar!(int I)(); } void abd(T)(T f) { T f1 = f.bar!(3)(); } |
No:
class Foo
{
public:
template<int> Foo *bar();
};
template<class T> void abc(T *f)
{
T *f1 = f->bar<3>(); // error
T *f2 = f->template bar<3>();
}
|
Dependent type members parseable without hints | Yes:
class Foo(T)
{
T.A* a1;
}
|
No:
template<class T> class Foo
{
public:
T::A *a1; // error
typename T::A *a2;
};
|
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