Is it possible for a class of exposing a type for function returns, without allowing users of that class to create variables of that type? A couple usage scenarios:
- A Fluent interface on a large class; a statement like "foo=bar.WithX(5).WithY(9).WithZ(19);" would be inefficient if it had to create three new instances of the class, but could be much more efficient if the WithX could create one instance, and the other statements could simply use it.
- A class may wish to support a statement like "foo.x = 9;" even when foo itself isn't an array, and does not hold the data in class instances that can be exposed to the public; one way to do that is to have foo return a struct which holds a reference to 'foo' and the value '19', and has a member property 'x' which could call "foo.SetXValue(19, 9);" Such a struct could have a conversion operator to convert itself to the "apparent" type of foo.
In both of these scenarios, storing the value returned by a method or property into a variable and then using it more than once would cause strange behavior. It would be desirable if the designer of the class exposing such methods or properties could ensure that callers wouldn't be able to use them more than once. Is there any practical way to accomplish that?
In formulating a question, it's difficult sometimes to draw the line between complicated usage cases, and simpler usage cases which aren't quite so important. Here's another usage case, and one closer to the one I'd be most interested in (though I'm also interested in Fluent chaining; being able to have something behave like a C++ reference to a value type would be nice, but probably too much work to bother with).
I have a type which is somewhat like the Windows registry, in that it is a hierarchical collection of items, each of which may have a string value, an integer value, and/or a nested collection of items. I wish to be able to support the following types of usage:
// Store "George" as string in MyCollection!Wow MyCollection["Wow"].st = "George" // Store "George" as string in MyCollection!This!That MyCollection["This"]["That"].i = 9 // Throws exception if ["Wow"] doesn't exist in collection someInteger = MyCollection["This"]["That"].i // Throws exception if ["This"]["That"] doesn't exist in collection someString = MyCollection["Wow"].st // Uses 9 as default value if it doesn't exist someInteger = MyCollection["Whatever"].ii(9) // Uses "George" as default if it doesn't exist someString = MyCollection["Multi"]["Level"]["Path"].sst("George")
Being able to index things directly is very nice (the actual code is in VB, so it's possible to use the "!" syntax, for better or for worse--that's another story). When evaluating a statement like:
MyCollection["This"]["that"].st = "George"or
someString = MyCollection["This"]["that"].sst("George")
it's necessary to return some type of object for MyCollection["This"] without knowing whether the object will ultimately be used for reading or writing. In the latter case, if MyCollection["This"] doesn't already exist, it will need to be created. My present code simply creates the node regardless, but then tries to keep track of whether it "really" exists, which ends up being a nuisance. Many of these objects get deep-cloned, so copy-on-write would be highly desirable, but when even reading a data structure can change it, copy-on-write ends up being highly impractical.
A somewhat cleaner solution would be to have the indexer return a data structure which indicates the collection being indexed and the key value, and then have whatever operation will ultimately be done on it (e.g. "st") do all of the necessary indexing. This would improve the abstraction offered by the nested collection, and would also facilitate things like copy-on-write. One caveat is that if someone were to do something like:
MyEvilVariable = MyCollection["This"]; MyEvilVariable["Nasty1"].st = "I'm evil" MyEvilVariable["Nasty2"].st = "Really evil"
the second usage of MyEvilVariable could break the collection.
As for the Fluent interface, my thought would be to have the WithXXX properties return a new instance of a derived class which shadows (not overrides!) the WithXXX properties with versions that simply modify the current instance. The return object from WithXXX would be known to be of the derived class, and would thus use the shadowed WithXXX methods, but once it was assigned to a variable, it would be regarded as an instance of the base class, so the next WithXXX would create a new instance.
C++ a stronger concept of value types than C# or vb.net, including the very useful concept of references to value types; it ensures that references to value types cannot be persisted outside the scope of the type in question. Unsafe code in C# can use pointers to value types, but they don't have the protections offered by C++ references.