I'm looking for a clear, concise and accurate answer.
Ideally as the actual answer, although links to good explanations welcome.
Thus, boxed values use more memory and take at minimum two memory lookups to access: once to get the pointer, and another to follow that pointer to the primitive. Obviously this isn't the kind of thing you want in your inner loops. On the other hand, boxed values typically play better with other types in the system. Since they are first-class data structures in the language, they have the expected metadata and structure that other data structures have.
In Java and Haskell generic collections can't contain unboxed values. Generic collections in .NET can hold unboxed values with no penalties. Where Java's generics are only used for compile-time type checking, .NET will generate specific classes for each generic type instantiated at run time.
Java and Haskell have unboxed arrays, but they're distinctly less convenient than the other collections. However, when peak performance is needed it's worth a little inconvenience to avoid the overhead of boxing and unboxing.
* For this discussion, a primitive value is any that can be stored on the call stack, rather than stored as a pointer to a value on the heap. Frequently that's just the machine types (ints, floats, etc), structs, and sometimes static sized arrays. .NET-land calls them value types (as opposed to reference types). Java folks call them primitive types. Haskellions just call them unboxed.
*** Caveat: A sufficiently advanced compiler / JIT can in some cases actually detect that a value which is semantically boxed when looking at the source, can safely be an unboxed value at runtime. In essence, thanks to brilliant language implementors your boxes are sometimes free.
Java + c# GURU explains ..
see here : Jon Skeet On Boxing/Unboxing
see also :
Boxing is the process of conversion of a value type into a reference type.
Unboxing is the conversion of a reference type into a value type.
Value Type are:
from C# 3.0 In a Nutshell:
Often you can't rely on what the type of variable a function will consume, so you need to use an object variable which extends from the lowest common denominator - in .Net this is
While both these hold the same information the second list is larger and slower. Each value in the second list is actually a reference to an
This is called boxed because the
For value types (i.e. all
For reference types (i.e. all
A further problem with a boxed value type is that it's not obvious that you're dealing with the box, rather than the value. When you compare two
This can be confusing when dealing with boxed value types:
It's easy to work around:
However it is another thing to be careful of when dealing with boxed values.
Like anything else, autoboxing can be problematic if not used carefully. The classic is to end up with a NullPointerException and not be able to track it down. Even with a debugger. Try this:
The .NET FCL generic collections:
were all designed to overcome the performance issues of boxing and unboxing in previous collection implementations.
For more, see chapter 16, CLR via C# (2nd Edition).
Boxing & unboxing is the process of converting a primitive value into an object oriented wrapper class (boxing), or converting a value from an object oriented wrapper class back to the primitive value (unboxing).
For example, in java, you may need to convert an
Boxing and unboxing is not inherently bad, but it is a tradeoff. Depending on the language implementation, it can be slower and more memory intensive than just using primitives. However, it may also allow you to use higher level data structures and achieve greater flexibility in your code.
These days, it is most commonly discussed in the context of Java's (and other language's) "autoboxing/autounboxing" feature. Here is a java centric explanation of autoboxing.