To avoid weird semantics, any struct which holds a field of a mutable reference type must do one of two things:
- It should make very clear that, from its perspective, the the content of the field serves not to "hold" an object, but merely to identify one. For example, a `KeyValuePair<String, Control>` would be a perfectly reasonable type, since although `Control` is mutable, the identity of a control referenced by such a type would be immutable.
- The mutable object must be one which is created by the value type, will never be exposed outside it. Further, any mutations that will ever be performed upon the immutable object must be performed before a reference to the object is stored into any field of the struct.
As others have noted, one way to allow a struct to simulate an array would be for it to hold an array, and make a new copy of that array any time an element is modified. Such a thing would, of course, be outrageously slow. An alternative approach would be to add some logic to store the indices and values of the last few mutations requests; any time an attempt is made to read the array, check whether the value is one of the recently-written ones and, if so, use the value stored in the struct instead of the one in the array. Once all of the 'slots' within the struct are filled up, make a copy of the array. This approach would at best "only" offer a constant speed up versus regenerating the array if updates hit many different elements, but could be helpful if the extremely vast majority of updates hit a small number of elements.
Another approach when updates are likely to have a high special concentration, but hit too many elements for them to fit entirely within a struct, would be to keep a reference to a "main" array, as well as an "updates" array along with an integer indicating what part of the main array the "updates" array represents. Updates would often require regeneration of the "updates" array, but that could be much smaller than the main array; if the
"updates" array gets too big, the main array can be regenerated with changes represented by the "updates" array incorporated within it.
The biggest problem with any of these approaches is that while the
struct could be engineered in such a way as to present consistent value-type semantics while allowing efficient copying, a glance at the struct's code would hardly make that obvious (as compared with plain-old-data structs, where the fact that the struct has a public field called
Foo makes it very clear how
Foo will behave).