Difference between revisions of "DIP23"

Revision as of 19:02, 3 February 2013

DIP23: Fixing properties redux

Title:	Fixing properties
DIP:	23
Version:	1
Status:	Draft
Created:	2013-02-02
Last Modified:	2013-02-02
Author:	Andrei Alexandrescu and Walter Bright
Links:

Abstract

There has been significant debate about finalizing property implementation. This document attempts to provide a proposal of reasonable complexity along with checkable examples.

Forces:

Break as little code as possible
Avoid departing from the existing and intended syntax and semantics of properties
Make economy of means (little or no new syntax to learn)
Avoid embarrassing situations such as expressions with unexpressible types or no-op address-of operator (as is the case with C functions).

Description

The `-property` switch gets deprecated

This DIP obviates any behavioral change via -property.

Optional parens stay in

One can't discuss properties without also discussing optional parens. These obviate to some extent the need for properties (at least of the read-only kind) and make for potential ambiguities.

This proposal sustains that optional parentheses should stay in. That means, if a function or method may be called without arguments, the trailing parens may be omitted.

unittest
{
    int a;
    void fun1() { ++a; }
    // will call fun
    fun1;
    assert(a == 1);

    // Works with default arguments, too
    void fun2(string s = "abc") { ++a; }
    fun2;
    assert(a == 2);
}

The same goes about methods:

unittest
{
    int a;
    struct S1 { void fun1() { ++a; } }
    S1 s1;
    // will call fun
    s1.fun1;
    assert(a == 1);

    // Works with default arguments, too
    struct S2 { void fun2(string s = "abc") { ++a; } }
    S2 s2;
    s2.fun2;
    assert(a == 2);
}

However, that's not the case with function objects, delegate objects, or objects that implement the function call operator.

unittest
{
    static int a;
    static void fun1() { ++a; }
    auto p1 = &fun1;
    // Error: var has no effect in expression (p1)
    p1;
    assert(a == 0);
}
unittest
{
    int a;
    void fun1() { ++a; }
    auto p1 = &fun1;
    // Error: var has no effect in expression (p1)
    p1;
}
unittest
{
    static int a;
    struct S1 { void opCall() { ++a; } }
    S1 s1;
    // Error: var has no effect in expression (s1)    s1;
    s1;
}

Taking the type of a symbol that may be used in a paren-less call results in the type of the returned object. THIS IS A CHANGE OF SEMANTICS.

unittest
{
    int fun1() { return 42; }
    static assert(is(typeof(fun1) == int));
}

To get the function type, one must apply the address-of operator.

unittest
{
    int fun1() { return 42; }
    static assert(is(typeof(&fun1) == int delegate()));
    static int fun2() { return 42; }
    static assert(is(typeof(&fun2) == int function()));
}

The same goes about member functions. THIS IS A CHANGE OF BEHAVIOR.

unittest
{
    struct S1 { int fun() { return 42; } }
    S1 s1;
    assert(s1.fun == 42);
    static assert(is(typeof(s1.fun) == int)); // currently fails
}

The basic motivation here is that "s1.fun" should not change type when under "typeof".

If a function returns a reference, then assignment through the paren-less call should work:

unittest
{
    static int x;
    ref int fun1() { return x; }
    fun1 = 42;
    assert(x == 42);
}

A function that returns an object that in turn supports a call with "()" will never automatically apply implicit parens to the returned object. Using either `fun` or `fun()` will return the callable entity. To invoke the callable entity immediately one must use `fun()()`.

unittest
{
    static int x;
    int function() fun1() { return () => 42; }
    assert(is(typeof(fun1) == int function()));
    assert(is(typeof(fun1()) == int function()));
    assert(is(typeof(fun1()()) == int));
    assert(fun1()() == 42);
}

"Read" properties with the @property annotation

Functions annotated with @property are subject to additional restrictions compared to regular functions.

In brief, the "()" operator may NEVER be applied EXPLICITLY to a function annotated with @property. THIS IS A CHANGE OF SEMANTICS.

unittest
{
    @property int prop1() { return 42; }
    assert(prop1 == 42);
    static assert(is(typeof(prop1) == int));
    static assert(!__traits(compiles, prop1()));
}

Applying the "()" to a property will simply apply it to the result of the property. THIS IS A CHANGE OF BEHAVIOR.

unittest
{
    @property int function() prop1() { return () => 42; }
    assert(prop1() == 42);
}

(Note: The @property annotation is not part of the function type, so it is impossible for a property to return a property.)

"Write" properties via the @property annotation

In order to use the assignment operator "=" property-style, the @property annotation MUST be used.

The rule for allowing assignment with properties is simple.

1. If "foo" is a function that has the @property annotation AND takes exactly one parameter, then "foo = x" calls foo with argument x. Calling "foo(x)" is disallowed. The type of the expression "foo = x" is the type of foo's result.

unittest
{
    @property void fun(int x) { assert(x == 42); }
    fun = 42;
   assert(is(typeof(fun = 42) == void));
}

2. If "foo" is a function that has the @property annotation AND takes exactly two parameters, then "x.foo = y" calls foo with arguments x and y. Calling "foo(x, y)" or "x.foo(y)" is disallowed.

unittest
{
    @property double fun(int x, double y) { assert(x == 42 && y == 43); return y; }
    42.fun = 43;
   assert(is(typeof(42.fun = 43) == double));
}

3. If "foo" is a member function of a class or struct that has the @property annotation AND takes exactly one parameter (aside from the implicit parameter this), then "x.foo = y" calls x.foo with argument y.

unittest
{
    struct S1
    {
        @property double fun(int x) { assert(x == 42); return 43; }
    }
    S1 s1;
    s1.fun = 42;
    assert((s1.fun = 42) == 43);
    assert(is(typeof(s1.fun = 42) == double));
}

No module-level properties

There is no module-level property emulating a global variable. That means a @property defined at module level must take either one parameter (meaning it's a getter) or two parameters (meaning it's a setter).

// at module level
@property int truncated(double x) { return cast(int) x; }
@property void all(double[] x, int y) { x[] = cast(double) y; }
unittest
{
    // truncated = 4.2; // compile-time error
    int a = 4.2.truncated;
    assert(a == 4);
    auto d = [ 1.2, 3.4 ];
    d.all = 42;
    assert(d == [ 42.0, 42.0 ]);
}

Taking the address of a property

If prop is a property, &prop or a.prop obey the normal rules of function/delegate access. They do not take the addres of the returned value implicitly. To do so, one must use &(prop) or &(a.prop).

Applying operators

This may be getting a bit too cute, but there's quite some demand for it.

If a.prop is a member variable, the expression a.prop op= x has the usual meaning. Otherwise, a.prop op= x gets rewritten twice. First rewrite is (a.prop) op= x, i.e. apply op= to the result of the property. Second rewrite is a.prop = a.prop op x. If only one of the two rewrite compiles, use it. If both compile, fail with ambiguity error.

For properties, the increment operators are rewritten as follows

Rewrite 1:

++a.p ----> ++(a.p)

a.p++ ----> (++a.p)

Rewrite 2: ++a.p ----> { auto v = a.p; ++v; a.p = v; return v; }()

a.p++ ----> { auto v = a.p; ++a.p; return v; }()

If only one of the two rewrite compiles, use it. If both compile, fail with ambiguity error.

`unittest`

A battery of detailed and explained unittests (derived from Kenji Hara's post follows.

alias Type = int;

unittest
{
   struct S
   {
       @property Type foo();       // formal getter
       @property void bar(Type);   // formal setter
       @property ref Type baz();   // ref return getter == auxiliary setter
   }
   S s;
   static assert( __traits(compiles, { s.foo;     }));
   static assert(!__traits(compiles, { s.foo();   }));
   static assert(is(typeof(s.foo) == Type));
   static assert(is(typeof(&s.foo) == Type delegate()));

   static assert( __traits(compiles, { s.bar = 1; }));
   static assert(!__traits(compiles, { s.bar(1);  }));
   static assert(is(typeof(s.bar)) == false);
   static assert(is(typeof(&s.bar) == void delegate(Type)));

   static assert( __traits(compiles, { s.baz;     }));
   static assert(!__traits(compiles, { s.baz();   }));
   static assert( __traits(compiles, { s.baz = 1; }));
   static assert(is(typeof(s.baz) == Type));
   static assert(is(typeof(&s.foo) == ref Type delegate()));
}
unittest
{
   struct S
   {
       Type foo();         // 0-arg function
       void bar(Type n);   // 1-arg function
       ref Type baz();     // 0-arg ref return function
   }
   S s;
   static assert( __traits(compiles, { s.foo;     }));
   static assert( __traits(compiles, { s.foo();   }));
   static assert(is(typeof(s.foo) == Type));
   static assert(is(typeof(&s.foo) == Type delegate()));

   static assert(!__traits(compiles, { s.bar = 1; }));
   static assert( __traits(compiles, { s.bar(1);  }));
   static assert(is(typeof(s.bar)) == false);
   static assert(is(typeof(&s.bar) == void delegate(Type)));

   static assert( __traits(compiles, { s.baz;     }));
   static assert( __traits(compiles, { s.baz = 1; }));
   static assert( __traits(compiles, { s.baz();   }));
   static assert(is(typeof(s.baz) == Type));
   static assert(is(typeof(&s.baz) == ref Type delegate()));
}

@property Type foo();
@property void bar(Type);
@property ref Type baz();

unittest
{
   static assert( __traits(compiles, { foo;     }));
   static assert(!__traits(compiles, { foo();   }));
   static assert(is(typeof(foo) == Type));
   static assert(is(typeof(&foo) == Type function()));

   static assert( __traits(compiles, { bar = 1; }));
   static assert(!__traits(compiles, { bar(1);  }));
   static assert(is(typeof(bar)) == false);
   static assert(is(typeof(&bar) == Type function()));

   static assert( __traits(compiles, { baz;       }));
   static assert(!__traits(compiles, { baz();     }));
   static assert( __traits(compiles, { baz = 1;   }));
   static assert(!__traits(compiles, { baz() = 1; }));
   static assert(is(typeof(baz) == Type));
   static assert(is(typeof(&baz) == ref Type function()));
}

@property Type foh(Type);
@property void bah(Type n, Type m);
@property ref Type bas(Type);

Type hoo(Type);
void var(Type, Type);
ref Type vaz(Type);

unittest
{
   static assert( __traits(compiles, { foh = 1; })     &&
!__traits(compiles, { hoo = 1; }));
   static assert(!__traits(compiles, { foh(1);  })     &&
__traits(compiles, { hoo(1);  }));
   static assert(!__traits(compiles, { 1.foh;   })     &&
__traits(compiles, { 1.hoo;   }));
   static assert(!__traits(compiles, { 1.foh(); })     &&
__traits(compiles, { 1.hoo(); }));

   static assert(!__traits(compiles, { bah(1, 2); })   &&
__traits(compiles, { var(1, 2); }));
   static assert( __traits(compiles, { 1.bah = 2; })   &&
!__traits(compiles, { 1.var = 2; }));
   static assert(!__traits(compiles, { 1.bah(2);  })   &&
__traits(compiles, { 1.var(2);  }));

   static assert( __traits(compiles, { bas = 1;     }) &&
!__traits(compiles, { vaz = 1;     }));
   static assert(!__traits(compiles, { bas(1);      }) &&
__traits(compiles, { vaz(1);      }));
   static assert(!__traits(compiles, { bas(1) = 2;  }) &&
__traits(compiles, { vaz(1) = 2;  }));
   static assert(!__traits(compiles, { 1.bas;       }) &&
__traits(compiles, { 1.vaz;       }));
   static assert(!__traits(compiles, { 1.bas = 2;   }) &&
__traits(compiles, { 1.vaz = 2;   }));
   static assert(!__traits(compiles, { 1.bas();     }) &&
__traits(compiles, { 1.vaz();     }));
   static assert(!__traits(compiles, { 1.bas() = 2; }) &&
__traits(compiles, { 1.vaz() = 2; }));
}

Copyright

This document has been placed in the Public Domain.

Difference between revisions of "DIP23"

Revision as of 19:02, 3 February 2013

Contents

DIP23: Fixing properties redux

Abstract

Description

The `-property` switch gets deprecated

Optional parens stay in

"Read" properties with the @property annotation

"Write" properties via the @property annotation

No module-level properties

Taking the address of a property

Applying operators

`unittest`

Copyright

Navigation menu

Personal tools

Namespaces

Variants

Views

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Difference between revisions of "DIP23"

Revision as of 19:02, 3 February 2013

Contents

DIP23: Fixing properties redux

Abstract

Description

The -property switch gets deprecated

Optional parens stay in

"Read" properties with the @property annotation

"Write" properties via the @property annotation

No module-level properties

Taking the address of a property

Applying operators

unittest

Copyright

Navigation menu

Search

The `-property` switch gets deprecated

`unittest`