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When using integer values in my own code, I always try to consider the signedness, asking myself if the integer should be signed or unsigned.

When I'm sure the value will never need to be negative, I then use an unsigned integer.
And I have to say this happen most of the time.

When reading other peoples' code, I rarely see unsigned integers, even if the represented value can't be negative.

So I asked myself: «is there a good reason for this, or do people just use signed integers because the don't care»?

I've search on the subject, here and in other places, and I have to say I can't find a good reason not to use unsigned integers, when it applies.

I came across those questions: «Default int type: Signed or Unsigned?», and «Should you always use 'int' for numbers in C, even if they are non-negative?» which both present the following example:

for( unsigned int i = foo.Length() - 1; i >= 0; --i ) {}

To me, this is just bad design. Of course, it may result in an infinite loop, with unsigned integers.
But is it so hard to check if foo.Length() is 0, before the loop?

So I personally don't think this is a good reason for using signed integers all the way.

Some people may also say that signed integers may be useful, even for non-negative values, to provide an error flag, usually -1.

Ok, that's good to have a specific value that means «error».
But then, what's wrong with something like UINT_MAX, for that specific value?

I'm actually asking this question because it may lead to some huge problems, usually when using third-party libraries.

In such a case, you often have to deal with signed and unsigned values.

Most of the time, people just don't care about the signedness, and just assign a, for instance, an unsigned int to a signed int, without checking the range.

I have to say I'm a bit paranoid with the compiler warning flags, so with my setup, such an implicit cast will result in a compiler error.

For that kind of stuff, I usually use a function or macro to check the range, and then assign using an explicit cast, raising an error if needed.

This just seems logical to me.

As a last example, as I'm also an Objective-C developer (note that this question is not related to Objective-C only):

- ( NSInteger )tableView: ( UITableView * )tableView numberOfRowsInSection: ( NSInteger )section;

For those not fluent with Objective-C, NSInteger is a signed integer.
This method actually retrieves the number of rows in a table view, for a specific section.

The result will never be a negative value (as the section number, by the way).

So why use a signed integer for this?
I really don't understand.

This is just an example, but I just always see that kind of stuff, with C, C++ or Objective-C.

So again, I'm just wondering if people just don't care about that kind of problems, or if there is finally a good and valid reason not to use unsigned integers for such cases.

Looking forward to hear your answers : )

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7  
Maybe programmers are generally lazy and don't want to write "unsigned" for things where it really doesn't matter? –  Joachim Pileborg Dec 8 '11 at 8:02
    
I usually use signed types. The only time i consider whether to use unsigned types is when I am working with microcontrollers and other embedded systems. It is nice to another fellow developer what is "warning paranoid" ;-) –  bvd Dec 8 '11 at 8:06
    
@Joachim Pileborg I'm afraid you're right, but I asked the question to be sure. If that's really the case, I personally think this is just bad coding, especially for people who write libraries. –  Macmade Dec 8 '11 at 8:07
    
1  
This has been discussed several times (and SO is not really the place for discussion but for answers), so I voted to close this. Discussions on this tend to be quite ideological and not very fruitful. This doesn't mean at all that I don't agree with you, though, the type that I personally use most is size_t. –  Jens Gustedt Dec 8 '11 at 8:12

4 Answers 4

  • a signed return value might yield more information (think error-numbers, 0 is sometimes a valid answer, -1 indicates error, see man read) ... which might be relevant especially for developers of libraries.

  • if you are worrying about the one extra bit you gain when using unsigned instead of signed then you are probably using the wrong type anyway. (also kind of "premature optimization" argument)

  • languages like python, ruby, jscript etc are doing just fine without signed vs unsigned. that might be an indicator ...

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Thanks for the answer. As I said in the question, why should we use -1 for an error flag, when we could use UINT_MAX? –  Macmade Dec 8 '11 at 8:11
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Because the distinction between positive-negative conveys more information than the implicit small_value-big_value distinction. –  Michael Foukarakis Dec 8 '11 at 8:15
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Actually, I have seen code that used ~0 instead of -1 to represent an error value. –  mouviciel Dec 8 '11 at 8:22
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@Macmade: a) with UINT_MAX you have only one error-code. with -2 i have another one, just like that. b) UINT_MAX might be defined differently on the machine that is using the "library" than it was defined when compiling the "library"; -1 is always -1 (except for implicit cast to unsigned :)) –  akira Dec 8 '11 at 8:35

There is one heavy-weight argument against widely unsigned integers:

Premature optimization is the root of all evil.

We all have at least on one occasion been bitten by unsigned integers. Sometimes like in your loop, sometimes in other contexts. Unsigned integers add a hazard, even though a small one, to your program. And you are introducing this hazard to change the meaning of one bit. One little, tiny, insignificant-but-for-its-sign-meaning bit. On the other hand, the integers we work with in bread and butter applications are often far below the range of integers, more in the order of 10^1 than 10^7. Thus, the different range of unsigned integers is in the vast majority of cases not needed. And when it's needed, it is quite likely that this extra bit won't cut it (when 31 is too little, 32 is rarely enough) and you'll need a wider or an arbitrary-wide integer anyway. The pragmatic approach in these cases is to just use the signed integer and spare yourself the occasional underflow bug. Your time as a programmer can be put to much better use.

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I totally agree with the quote. But do you really think that using unsigned values is a premature optimization? –  Macmade Dec 8 '11 at 8:10
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@Macmade: If it is unproven that a plain int, which is less error-prone, will suffice: Yes, then I think using unsigned is premature. –  thiton Dec 8 '11 at 8:15
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@thiton Why do you consider that unsigned is an optimization over int? Is it only because the default is int? I have been bitten by signed ints when array indexes went below 0. With unsigned the error would have been immediate with a segmentation fault. –  mouviciel Dec 8 '11 at 8:27
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In my book, signed types are for things that can be negative, unsigned for things that can't. Plain simple. And most of the things in my practice are never negative. There are certain dangers involved with using each of them and especially all of them together, but guess what? Thou shalt know thy tools. And that applies to everyone, those who'd rather use signed, those who'd rather use unsigned and those who use both. There's no hazard if you're informed and aren't guessing what the compiler can and will do. –  Alexey Frunze Dec 8 '11 at 8:48
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I don't see at all what this has to do with premature optimization. unsigned integers are part of the language just as signed ones. Just use the correct type at the right time. –  Jens Gustedt Dec 8 '11 at 8:59

Unsigned intgers are an artifact from the past. This is from the time, where processors could do unsigned arithmetic a little bit faster.

This is a case of premature optimization which is considered evil.

Actually, in 2005 when AMD introduced x86_64 (or AMD64, how it was then called), the 64 bit architecture for x86, they brought the ghosts of the past back: If a signed integer is used as an index and the compiler can not prove that it is never negative, is has to insert a 32 to 64 bit sign extension instruction - because the default 32 to 64 bit extension is unsigned (the upper half of a 64 bit register gets cleard if you move a 32 bit value into it).

But I would recommend against using unsigned in any arithmetic at all, being it pointer arithmetic or just simple numbers.

for( unsigned int i = foo.Length() - 1; i >= 0; --i ) {}

Any recent compiler will warn about such an construct, with condition ist always true or similar. With using a signed variable you avoid such pitfalls at all. Instead use ptrdiff_t.

A problem might be the c++ library, it often uses an unsigned type for size_t, which is required because of some rare corner cases with very large sizes (between 2^31 and 2^32) on 32 bit systems with certain boot switches ( /3GB windows).

There are many more, comparisons between signed and unsigned come to my mind, where the signed value automagically gets promoted to a unsigned and thus becomes a huge positive number, when it has been a small negative before.

One exception for using unsigned exists: For bit fields, flags, masks it is quite common. Usually it doesn't make sense at all to interpret the value of these variables as a magnitude, and the reader may deduce from the type that this variable is to be interpreted in bits.

The result will never be a negative value (as the section number, by the way). So why use a signed integer for this?

Because you might want to compare the return value to a signed value, which is actually negative. The comparison should return true in that case, but the C standard specifies that the signed get promoted to an unsigned in that case and you will get a false instead. I don't know about ObjectiveC though.

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Ok for the performance note. But what about the range then? –  Macmade Dec 8 '11 at 8:22
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Unsigned integers are awesome for bit-masking and well-defined overflow behavior, not so good for arithmetic. Different tools for different jobs... –  sarnold Dec 8 '11 at 8:28
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When your program relies on the extra bit of precision but can't afford the extra 32 bits of the next larger type, you are in a very dangerous area anyway. In this case you can safely assume you are knowing what you a doing (because you would never run into trouble open-eyed, wouldn't you), and if you know what you do you can surely use unsigned :-) –  hirschhornsalz Dec 8 '11 at 8:44
    
@Macmade: Is the example where a comparison might give you a wrong result when you don't expect it not a valid reason in your book? –  hirschhornsalz Dec 8 '11 at 8:51
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"Unsigned intgers are an artifact from the past" historically this simply incorrect. At the beginning just had signed integer types. –  Jens Gustedt Dec 8 '11 at 9:03

From the C FAQ:

The first question in the C FAQ is which integer type should we decide to use?

If you might need large values (above 32,767 or below -32,767), use long. Otherwise, if space is very important (i.e. if there are large arrays or many structures), use short. Otherwise, use int. If well-defined overflow characteristics are important and negative values are not, or if you want to steer clear of sign-extension problems when manipulating bits or bytes, use one of the corresponding unsigned types.

Another question concerns types conversions:

If an operation involves both signed and unsigned integers, the situation is a bit more complicated. If the unsigned operand is smaller (perhaps we're operating on unsigned int and long int), such that the larger, signed type could represent all values of the smaller, unsigned type, then the unsigned value is converted to the larger, signed type, and the result has the larger, signed type. Otherwise (that is, if the signed type can not represent all values of the unsigned type), both values are converted to a common unsigned type, and the result has that unsigned type.

You can find it here. So basically using unisgned integers will complicate the situation since you'll have to either make all your integers unsigned, or be at the risk of confusing the compiler and yourself.

And when it is a good to use unsigned integers? one situation is when using bitwise operations:

The << operator shifts its first operand left by a number of bits given by its second operand, filling in new 0 bits at the right. Similarly, the >> operator shifts its first operand right. If the first operand is unsigned, >> fills in 0 bits from the left, but if the first operand is signed, >> might fill in 1 bits if the high-order bit was already 1. (Uncertainty like this is one reason why it's usually a good idea to use all unsigned operands when working with the bitwise operators.)

taken from here And I've seen this somewhere:

If it was best to use unsigned integers for values that are never negative, we would have started by using unsigned int in the main function int main(int argc, char* argv[]). One thing is sure, argc is never negative.

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This is isn't much of a good point to it. If you (almost) always use unsigned values for integer arithmetic this disappears. –  Jens Gustedt Dec 8 '11 at 9:09
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Your quote on main doesn't make much sense to me. The signature of main is there for historical reasons only. It predates even the existence oof the unsigned keyword in the C language. The C standards committee is very conservative in not breaking existing code. –  Jens Gustedt Dec 8 '11 at 11:22

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