I usually program in C++, but for school i have to do a project in C#.

So i went ahead and coded like i was used to in C++, but was surprised when the compiler complained about code like the following:

        const uint size = 10;
        ArrayList myarray = new ArrayList(size); //Arg 1: cannot convert from 'uint' to 'int

Ok they expect int as argument type, but why ? I would feel much more comfortable with uint as argument type, because uint fits much better in this case.

Why do they use int as argument type pretty much everywhere in the .NET library even if though for many cases negative numbers dont make any sense (since no container nor gui element can have a negative size).

If the reason that they used int is, that they didnt expect that the average user cares about signedness, why didnt they add overloads for uint additonally ?

Is this just MS not caring about sign correctness or are there cases where negative values make some sense/ carry some information (error code ????) for container/gui widget/... sizes ?

  • I already wondered about the same fact and didn't find an answer. – chrmue Apr 24 '10 at 17:49

I would imagine that Microsoft chose Int32 because UInt32 is not CLS-compliant (in other words not all languages that use the .NET framework support unsigned integers).

  • still they should've added some meta-attribute to support implicit conversion of uint to int in these cases (only), the lack of something like this renders uint pretty much worthless when working with .NET – smerlin Apr 24 '10 at 19:33

Because unsigned integers are not CLS compliant. There are languages that are missing support for them, Java would be an example.


In addition to the answers talking about CLS compliance, consider that integer math (e.g. 10 + 2) results in integer (as in signed) data, which only makes sense; now consider the bother of having to cast every mathematical expression to uint to pass it to one of the methods you refer to.

As for overloads that take uint -- in many cases method arguments are stored as (or used to calculate) property values, which are usually of type int (again for CLS compliance, and possibly for integer math convenience); the discrepancy in sign would be confusing, not to mention vulnerable to overflow.

  • 1
    If you perform arithmetic with uints, the result is a uint too. See section 7.7 of the C# 3 spec for details. It's true that integer literals effectively default to being int, but that decision could have been made differently too. – Jon Skeet Apr 24 '10 at 18:27
  • @Jon Skeet: You're right, I was referring to literals. I may misunderstand, but you seem to suggest that uint literals would be a viable alternative. I take it you mean in theory, not practise -- since we'd end up with a lot of confused new C# developers, not to mention reams of casting. – Ben M Apr 24 '10 at 20:34
  • I mean that C# could have been designed such that positive literals "defaulted" to uint instead of int. It's obviously far too late to change it now. – Jon Skeet Apr 24 '10 at 20:39
  • @Jon: No, of course! -- I meant that I think it would not have been viable (meaning practical) from the first. – Ben M Apr 24 '10 at 20:54
  • I'm not sure about that. It would definitely have felt a little strange to developers from other languages, but there are many many values which we often just use "int" for but which can never sensibly be negative. I suspect a more unsigned-oriented view of the world could work well. – Jon Skeet Apr 24 '10 at 21:10

Stroustrup prefers int over "uint" in The C++ Programming Language, and I think his reasons apply to C# too:

It's about underflow with no warning:

// Unintended very large uint
uint oops = (uint)5 - (uint)10;


// Unintended infinite loop
for( uint counter = 10; counter >= 0; counter-- )
    ;  // Do something

The extra bit of info is rarely worth having to watch for these kinds of bugs.

  • C# can throw exception on underflows/overflows (if enabled via project-settings), so this doesnt seem to be a valid argument. – smerlin Apr 25 '10 at 18:35

This possibly come a "little" late, but just found the question and want to add a missing bit.

A prime example where negative values make perfect sense is in graphical frameworks. For sizes, as stated in the question, negatives are out of question, but for position values it's perfectly acceptable to have negative values. Such values make objects to appear off-screen or at least partially cropped: Control with negative location value

It follows the very same principle as in mathematics, negative coordinates just make points to go to the opposing from where the axis grows values. Assuming that (0,0) is at the upper-left corner of the screen, negative values displace things to the left and top of that point, making them half-visible.

This is useful for example if you want to implement a scrolling region, where the contents are larger than the available space. Simply all objects positions become negative to begin disappear from the top or larger that the height for disappear from bottom.

Such things aren't limited to C#. Winforms and WPF use that, as per in the question, but most other graphical environments have the same behavior. HTML+CSS can place elements in the same way, or the C/C++ library SDL also can make use of this effect.

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