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I'd like to understand better why choose int over unsigned?

Personally, I've never liked signed values unless there is a valid reason for them. e.g. count of items in an array, or length of a string, or size of memory block, etc., so often these things cannot possibly be negative. Such a value has no possible meaning. Why prefer int when it is misleading in all such cases?

I ask this because both Bjarne Stroustrup and Chandler Carruth gave the advice to prefer int over unsigned here (approx 12:30').

I can see the argument for using int over short or long - int is the "most natural" data width for the target machine architecture.

But signed over unsigned has always annoyed me. Are signed values genuinely faster on typical modern CPU architectures? What makes them better?

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closed as primarily opinion-based by Adi Lester, Sebastian, Eric Brown, Roman C, Andrew Barber Sep 23 '13 at 20:46

Many good questions generate some degree of opinion based on expert experience, but answers to this question will tend to be almost entirely based on opinions, rather than facts, references, or specific expertise.If this question can be reworded to fit the rules in the help center, please edit the question.

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For the benefit of the readers who can't watch the 1 hour video now: What do Stroustrup and Carruth say about why they prefer signed? – us2012 Sep 13 '13 at 21:22
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I prefer int instead of unsigned because: 1. it's shorter (I'm serious!), 2. it's more generic and more intuitive (i. e. I like to be able to assume that 1 - 2 is -1 and not some obscure huge number), 3. what if I want to signal an error by returning an out-of-range value? – user529758 Sep 13 '13 at 21:27
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At 11:08: "there's no simple guidance that can be given" – Robᵩ Sep 13 '13 at 21:29
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@john Ok, but then they at least need to make int overflow defined behaviour and make twos-complement mandatory. Otherwise int would be plain unusable for many reasonable tasks for which there's no way around unsigned ints, as it is now. – Christian Rau Sep 13 '13 at 21:32
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@john: Preferring int to unsigned for most purposes is one thing; removing unsigned from the language is far more drastic. – Keith Thompson Sep 13 '13 at 21:49

13 Answers 13

up vote 27 down vote accepted

Let me paraphrase the video, as the experts said it succinctly.

Andrei Alexandrescu:

  • No simple guideline.
  • In systems programming, we need integers of different sizes and signedness.
  • Many conversions and arcane rules govern arithmetic (like for auto), so we need to be careful.

Chandler Carruth:

  • Here's some simple guidelines:
    1. Use signed integers unless you need two's complement arithmetic or a bit pattern
    2. Use the smallest integer that will suffice.
    3. Otherwise, use int if you think you could count the items, and a 64-bit integer if it's even more than you would want to count.
  • Stop worrying and use tools to tell you when you need a different type or size.

Bjarne Stroustrup:

  • Use int until you have a reason not to.
  • Use unsigned only for bit patterns.
  • Never mix signed and unsigned

Wariness about signedness rules aside, my one-sentence take away from the experts:

Use the appropriate type, and when you don't know, use an int until you do know.

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I find this answer interesting; however, could you elaborate a bit on "use int if you think you could count the items"? In particular, doesn't this clash with the rule of "never mix signed with unsigned" when we have to compare with size_t variables? – Alberto Moriconi Sep 16 '13 at 19:23
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He's just quoting the answers given by the speakers in the video in my OP. They do come back and touch on this topic a second time, including Herb Sutter saying that in the case of size_t, the standards library "got it wrong... sorry for that." – Mordachai Sep 16 '13 at 20:48
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@Alberto About the "use int if you think you could count the items", we are actually contrasting it against the use of a type like (signed) long, which wouldn't challenge the "never mix signed with unsigned" rule. – Prashant Kumar Sep 16 '13 at 21:04

As per requests in comments: I prefer int instead of unsigned because...

  1. it's shorter (I'm serious!)

  2. it's more generic and more intuitive (i. e. I like to be able to assume that 1 - 2 is -1 and not some obscure huge number)

  3. what if I want to signal an error by returning an out-of-range value?

Of course there are counter-arguments, but these are the principal reasons I like to declare my integers as int instead of unsigned. Of course, this is not always true, in other cases, an unsigned is just a better tool for a task, I am just answering the "why would anyone prefer defaulting to signed" question specifically.

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I think it's sad that saying it's shorter needs the (I'm serious). – ChiefTwoPencils Sep 13 '13 at 21:31
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@BobbyDigital Indeed. Less worrying should be carried out about "efficiency" and more about correctness, readability and style in general. – user529758 Sep 13 '13 at 21:32
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@H2CO3: If the positive range of int is sufficient for your purposes, them UINT_MAX is a perfectly good out-of-range value for indicating error conditions. In fact -1 can be used in the code for that purpose, since it evaluates to UINT_MAX when converted to unsigned. – AnT Sep 13 '13 at 21:42
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typing 'unsigned' is not exactly carpal-tunnel inducing ;) – Mordachai Sep 13 '13 at 21:42
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@Mordachai It's not about writability, it's about readability. – user529758 Sep 13 '13 at 21:44

Several reasons:

  1. Arithmetic on unsigned always yields unsigned, which can be a problem when subtracting integer quantities that can reasonably result in a negative result — think subtracting money quantities to yield balance, or array indices to yield distance between elements. If the operands are unsigned, you get a perfectly defined, but almost certainly meaningless result, and a result < 0 comparison will always be false (of which modern compilers will fortunately warn you).

  2. unsigned has the nasty property of contaminating the arithmetic where it gets mixed with signed integers. So, if you add a signed and unsigned and ask whether the result is greater than zero, you can get bitten, especially when the unsigned integral type is hidden behind a typedef.

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#2 has bit me once. Aaaargh! – user529758 Sep 13 '13 at 21:31
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signed1 - signed2 isn't safe either, because if it overflows you get undefined behavior. – Ben Voigt Sep 13 '13 at 21:33
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I think these are the real reasons. – MirroredFate Sep 13 '13 at 21:36
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The signed case won't overflow unless signed1 and/or signed2 is "large" (more than half the maximum representable value). By contrast, subtracting anything from an unsigned value can cause it to wrap. – supercat Sep 13 '13 at 21:52
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@Mordachai: There are many reasons not to create this exception. It would prevent the compiler from making many useful optimizations. See blog.regehr.org/archives/213 for discussion. – Rob Napier Sep 13 '13 at 22:54

There are no reasons to prefer signed over unsigned, aside from purely sociological ones, i.e. some people believe that average programmers are not competent and/or attentive enough to write proper code in terms of unsigned types. This is often the main reasoning used by various "speakers", regardless of how respected those speakers might be.

In reality, competent programmers quickly develop and/or learn the basic set of programming idioms and skills that allow them to write proper code in terms of unsigned integral types.

Note also that the fundamental differences between signed and unsigned semantics are always present (in superficially different form) in other parts of C and C++ language, like pointer arithmetic and iterator arithmetic. Which means that in general case the programmer does not really have the option of avoiding dealing with issues specific to unsigned semantics and the "problems" it brings with it. I.e. whether you want it or not, you have to learn to work with ranges that terminate abruptly at their left end and terminate right here (not somewhere in the distance), even if you adamantly avoid unsigned integers.

Also, as you probably know, many parts of standard library already rely on unsigned integer types quite heavily. Forcing signed arithmetic into the mix, instead of learning to work with unsigned one, will only result in disastrously bad code.

The only real reason to prefer signed in some contexts that comes to mind is that in mixed integer/floating-point code signed integer formats are typically directly supported by FPU instruction set, while unsigned formats are not supported at all, making the compiler to generate extra code for conversions between floating-point values and unsigned values. In such code signed types might perform better.

But at the same time in purely integer code unsigned types might perform better than signed types. For example, integer division often requires additional corrective code in order to satisfy the requirements of the language spec. The correction is only necessary in case of negative operands, so it wastes CPU cycles in situations when negative operands are not really used.

In my practice I devotedly stick to unsigned wherever I can, and use signed only if I really have to.

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I disagree. It's not about competency, but about what is common. (like when to use class vs struct) There are loads of competent programmers out there that could perfectly tell you when they could use an unsigned or signed value, but use signed anyway for these "sociological" reasons. (I'd argue even indentation is used for this purpose - yes, the purpose is to make code easier to read, but that's the point of int as well). – Luchian Grigore Sep 13 '13 at 21:53
    
I tend to agree with the comment as I use unsigned whenever the values for the variable are going to be unsigned like in a loop that is only positive values for (unsigned int i=0; i < 5; ++i) I feel it gives it a bit of an extra type specifier but I also see your point that just having int is by itself makes the code more succinct . – bjackfly Sep 13 '13 at 23:02
    
Don't use unsigned even if you are confident that the variable will never be negative, even in the loops like the above. Imagine that someone would add something like this in the body of the loop: if(i-3<0){/*something for the middle of the range*/}. If i is unsigned the above code would never be executed. Yes, the above code assume that "someone" is incompetent in using unsigned, but that happens more often than one would like. – Michael Sep 16 '13 at 20:29
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@Michael: Not really. This is one of those fake wisdoms that just "sound right". Like the one that people use to justify the "Yoda comparison" syntax, for one example. E.g. they say that one should write 3 == x instead or x == 3 to avoid accidentally using assignment instead of ==. But in reality it is a fake problem that never happens. People who use normal syntax x == 3 simply don't make that mistake. The same thing with unsigned. A competent developer will never write code like i - 3 < 0, when the natural way to expresss it is i < 3 and it is "signedness-independent". – AnT Sep 16 '13 at 20:55

Speed is the same on modern architectures. The problem with unsigned int is that it can sometimes generate unexpected behavior. This can create bugs that wouldn't show up otherwise.

Normally when you subtract 1 from a value, the value gets smaller. Now, with both signed and unsigned int variables, there will be a time that subtracting 1 creates a value that is MUCH LARGER. The key difference between unsigned int and int is that with unsigned int the value that generates the paradoxical result is a commonly used value --- 0 --- whereas with signed the number is safely far away from normal operations.

As far as returning -1 for an error value --- modern thinking is that it's better to throw an exception than to test for return values.

It's true that if you properly defend your code you won't have this problem, and if you use unsigned religiously everywhere you will be okay (provided that you are only adding, and never subtracting, and that you never get near MAX_INT). I use unsigned int everywhere. But it takes a lot of discipline. For a lot of programs, you can get by with using int and spend your time on other bugs.

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"The problem with unsigned int is that it can sometimes (in cases of overflow) generate unexpected behavior." And the problem with signed int is that it can sometimes (in cases of overflow) generate undefined behavior. Given those choices, unsigned looks pretty nice ;) – Ben Voigt Sep 13 '13 at 21:35
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(Of course, overflow occurs for completely different values, so overflow is infrequently a problem for signed types) – Ben Voigt Sep 13 '13 at 21:35
    
@BenVoigt Also, the "unexpected" is only unexpected if one doesn't know the implicit conversion rules (that's what I called "counter-intuitive"). Fortunately, unsigned overflow is 100% precisely defined by the C and C++ standards (well, as far as my knowledge about this goes). – user529758 Sep 13 '13 at 21:40
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@H2CO3: Except for out-of-range shift operand, which is the only example of UB for unsigned types that I know of. – Ben Voigt Sep 13 '13 at 21:41
    
@BenVoigt Ah yes, good ol' shifts. – user529758 Sep 13 '13 at 21:43

To answer the actual question: For the vast number of things, it doesn't really matter. int can be a little easier to deal with things like subtraction with the second operand larger than the first and you still get a "expected" result.

There is absolutely no speed difference in 99.9% of cases, because the ONLY instructions that are different for signed and unsigned numbers are:

  1. Making the number longer (fill with the sign for signed or zero for unsigned) - it takes the same effort to do both.
  2. Comparisons - a signed number, the processor has to take into account if either number is negative or not. But again, it's the same speed to make a compare with signed or unsigned numbers - it's just using a different instruction code to say "numbers that have the highest bit set are smaller than numbers with the highest bit not set" (essentially). [Pedantically, it's nearly always the operation using the RESULT of a comparison that is different - the most common case being a conditional jump or branch instruction - but either way, it's the same effort, just that the inputs are taken to mean slightly different things].
  3. Multiply and divide. Obviously, sign conversion of the result needs to happen if it's a signed multiplication, where a unsigned should not change the sign of the result if the highest bit of one of the inputs is set. And again, the effort is (as near as we care for) identical.

(I think there are one or two other cases, but the result is the same - it really doesn't matter if it's signed or unsigned, the effort to perform the operation is the same for both).

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Correct, highly relevant.... and doesn't answer the question. Still useful so +1 – Ben Voigt Sep 13 '13 at 21:40
  1. Use int by default: it plays nicer with the rest of the language

    • most common domain usage is regular arithmetic, not modular arithmetic
    • int main() {} // see an unsigned?
    • auto i = 0; // i is of type int
  2. Only use unsigned for modulo arithmetic and bit-twiddling (in particular shifting)

    • has different semantics than regular arithmetic, make sure it is what you want
    • bit-shifting signed types is subtle (see comments by @ChristianRau)
    • if you need a > 2Gb vector on a 32-bit machine, upgrade your OS / hardware
  3. Never mix signed and unsigned arithmetic

    • the rules for that are complicated and surprising (either one can be converted to the other, depending on the relative type sizes)
    • turn on -Wconversion -Wsign-conversion -Wsign-promo (gcc is better than Clang here)
    • the Standard Library got it wrong with std::size_t (quote from the GN13 video)
    • use range-for if you can,
    • for(auto i = 0; i < static_cast<int>(v.size()); ++i) if you must
  4. Don't use short or large types unless you actually need them

    • current architectures data flow caters well to 32-bit non-pointer data (but note the comment by @BenVoigt about cache effects for smaller types)
    • char and short save space but suffer from integral promotions
    • are you really going to count to over all int64_t?
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Best time performance is often dependent on how much data you can fit in cache... and then small types beat 32-bit handily. – Ben Voigt Sep 14 '13 at 0:25
    
"bit-shifting signed types is undefined behavior" - No, it isn't, but it can be. – Christian Rau Sep 14 '13 at 11:05
    
@ChristianRau thanks for pointing that out, updated. I didn't want to quote 5.8/2 in its entirety, but that was too much of a shortcut. – TemplateRex Sep 14 '13 at 11:12
    
@TemplateRex Well, unfortunately it still isn't neccessarily undefined behaviour, it's undefined for left-shift and implementation-defined for right-shift. If you didn't want to quote the standard, the easiest would probably have been to just say that it can be undefined behaviour. Making exact statements unfortunately comes with the responsibility to be exactly right. :-) – Christian Rau Sep 14 '13 at 11:18
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You’ve given a set of guidelines but few explanations. Your convoluted for loop in particular needs some ’splainin’. (I’d go as far as saying it’s a bad guideline – use for (auto i = 0u; i < v.size(); ++i) instead! – or, even better, for (auto i : indices(x)).) – Konrad Rudolph Sep 14 '13 at 11:28

The integral types in C and many languages which derive from it have two general usage cases: to represent numbers, or represent members of an abstract algebraic ring. For those unfamiliar with abstract algebra, the primary notion behind a ring is that adding, subtracting, or multiplying two items of a ring should yield another item of that ring--it shouldn't crash or yield a value outside the ring. On a 32-bit machine, adding unsigned 0x12345678 to unsigned 0xFFFFFFFF doesn't "overflow"--it simply yields the result 0x12345677 which is defined for the ring of integers congruent mod 2^32 (because the arithmetic result of adding 0x12345678 to 0xFFFFFFFF, i.e. 0x112345677, is congruent to 0x12345677 mod 2^32).

Conceptually, both purposes (representing numbers, or representing members of the ring of integers congruent mod 2^n) may be served by both signed and unsigned types, and many operations are the same for both usage cases, but there are some differences. Among other things, an attempt to adding two numbers should not be expected to yield anything other than the correct arithmetic sum. While it's debatable whether a language should be required to generate the code necessary to guarantee that it won't (e.g. that an exception would be thrown instead), one could argue that for code which uses integral types to represent numbers such behavior would be preferable to yielding an arithmetically-incorrect value and compilers shouldn't be forbidden from behaving that way.

The implementers of the C standards decided to use signed integer types to represent numbers and unsigned types to represent members of the algebraic ring of integers congruent mod 2^n. By contrast, Java uses signed integers to represent members of such rings (though they're represented differently, and conversions among signed types behave differently from among unsigned ones) and has neither unsigned integers nor any integral types which behave as numbers.

If a language provided a choice of signed and unsigned representations for both numbers and algebraic-ring numbers, it might make sense to use unsigned numbers to represent quantities that will always be positive. If, however, the only unsigned types represent members of an algebraic ring, and the only types that represent numbers are the signed ones, then even if a value will always be positive it should be represented using a type designed to represent numbers.

Incidentally, the reason that (uint32_t)-1 is 0xFFFFFFFF stems from the fact that casting a signed value to unsigned is equivalent to adding unsigned zero, and adding an integer to an unsigned value is defined as adding or subtracting its magnitude to/from the unsigned value according to the rules of the algebraic ring which specify that if X=Y-Z, then X is the one and only member of that ring such X+Z=Y. In unsigned math, 0xFFFFFFFF is the only number which, when added to unsigned 1, yields unsigned zero.

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Nitpicking: Fields allow for division by anything except the additive identity. If all you have is +, -, and *, the algebraic structure is that of a ring. – Chris White Sep 13 '13 at 22:52
    
@ChrisWhite: Thanks. Corrected above. It's been ages since I've taken abstract algebra; I'd originally said "group", but groups don't support multiplication. – supercat Sep 13 '13 at 22:57
    
@Chris: But unsigned integral types DO have divison by anything except the additive identity -- it just is based on natural arithmetic with rounding, and not modular equivalence classes. – Ben Voigt Sep 14 '13 at 0:27
    
@BenVoigt Of course, of course. But that "division" is not the inverse of multiplication, and so doesn't make the set a field. But this is all semantics, and I think we all know what we're talking about :) – Chris White Sep 14 '13 at 4:10
    
@Chris: Can you imagine the confusion that would result if C++ actually had Galois Field division on one of its primitive types? – Ben Voigt Sep 14 '13 at 5:17

int is preferred because it's most commonly used. unsigned is usually associated with bit operations. Whenever I see an unsigned, I assume it's used for bit twiddling.

If you need a bigger range, use a 64-bit integer.

If you're iterating over stuff using indexes, types usually have size_type, and you shouldn't care whether it's signed or unsigned.

Speed is not an issue.

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@ott-- I don't follow. What do you mean by "set flag"? Are you saying you set one less bit for an unsigned? Like... you'd just write 31 bits? – Luchian Grigore Sep 13 '13 at 21:42
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@ott: There are a lot, probably a majority, of values that are never negative. So your flag, and setting it, is unneeded. – Ben Voigt Sep 13 '13 at 21:43
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@ott-- Do you have a reference? I still can't see how using an unsigned saves on what flags are set or where. – Luchian Grigore Sep 13 '13 at 22:07
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@ott--: Aren't on most modern processors the instruction for signed and unsigned addition be more or less the same? Besides the speed of CPU is not determined by how much things it needs to do but by latency (numer of cycles) and clock (so in effect length of critical path) [omitting such details like OOO execution or superscalar architecture]. So as long as it does not increase critical path it should not have any effect on speed and negligible for power consumption. – Maciej Piechotka Sep 13 '13 at 23:17
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@ott: If you're talking about CPU flags set by the ALU, you should know that on many architectures those are set for both signed and unsigned. The CPU doesn't have much notion of data types. – Ben Voigt Sep 14 '13 at 0:24

The int type more closely resembles the behavior of mathematical integers than the unsigned type.

It is naive to prefer the unsigned type simply because a situation does not require negative values to be represented.

The problem is that the unsigned type has a discontinuous behavior right next to zero. Any operation that tries to compute a small negative value, instead produces some large positive value. (Worse: one that is implementation-defined.)

Algebraic relationships such as that a < b implies that a - b < 0 are wrecked in the unsigned domain, even for small values like a = 3 and b = 4.

A descending loop like for (i = max - 1; i >= 0; i--) fails to terminate if i is made unsigned.

Unsigned quirks can cause a problem which will affect code regardless of whether that code expects to be representing only positive quantities.

The virtue of the unsigned types is that certain operations that are not portably defined at the bit level for the signed types are that way for the unsigned types. The unsigned types lack a sign bit, and so shifting and masking through the sign bit isn't a problem. The unsigned types are good for bitmasks, and for code that implements precise arithmetic in a platform-independent way. Unsigned opearations will simulate two's complement semantics even on a non two's complement machine. Writing a multi-precision (bignum) library practically requires arrays of unsigned types to be used for the representation, rather than signed types.

The unsigned types are also suitable in situations in which numbers behave like identifiers and not as arithmetic types. For instance, an IPv4 address can be represented in a 32 bit unsigned type. You wouldn't add together IPv4 addresses.

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You surely know that modular arithmetic is perfectly mathematical, right? – GManNickG Sep 13 '13 at 22:42
    
@GManNickG That is why I said "mathematical integers" not "mathematics". In many common situations, modular arithmetic is inappropriate. – Kaz Sep 13 '13 at 22:52
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While for (i = max - 1; i >= 0; i--) will not terminate, note that for (i = max - 1; i != -1; i--) will work as intended (and is independent from signedness of the type). – AnT Sep 13 '13 at 22:54
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@Kaz: You probably meant natural numbers. – Ben Voigt Sep 14 '13 at 5:22
    
@BenVoigt Why would I invoke the natural numbers {1, 2, 3, ...}; they are hardly relevant here and as a type, they have drawbacks, like not being closed under subtraction, in which regard they are worse than a modular congruence. – Kaz Sep 14 '13 at 7:51

For me, in addition to all the integers in the range of 0..+2,147,483,647 contained within the set of signed and unsigned integers on 32 bit architectures, there is a higher probability that I will need to use -1 (or smaller) than need to use +2,147,483,648 (or larger).

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One good reason that I can think of is in case of detecting overflow.

For the use cases such as the count of items in an array, length of a string, or size of memory block, you can overflow an unsigned int and you may not notice a difference even when you take a look at the variable. If it is an signed int, the variable will be less than zero and clearly wrong.

You can simply check to see if the variable is zero when you want to use it. This way, you do not have to check for overflow after every arithmetic operation as is the case for unsigned ints.

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+1 for "make it more obvious when things go wrong" – Cogwheel Sep 13 '13 at 21:44
    
I come from an assembler background - an overflow was always encoded in the CPU state flags. It would be nice to simply have access to this information, rather than needing to slice off a bit from your range in order to notice such information, no? – Mordachai Sep 13 '13 at 21:46
    
technically, c++ doesn't have to run on a cpu, let alone one with flags that provide this kind of info. overflows are undefined behavior so you're "supposed" to ensure they don't happen in the first place. But yes, it would be nice :P – Cogwheel Sep 13 '13 at 21:52

It gives unexpected result when doing simple arithmetic operation:

unsigned int i;
i = 1 - 2;
//i is now 4294967295 on a 64bit machine

It gives unexpected result when doing simple comparison:

unsigned int j = 1;
std::cout << (j>-1) << std::endl;
//output 0 as false but 1 is greater than -1

This is because when doing the operations above, the signed ints are converted to unsigned, and it overflows and goes to a really big number.

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Yet those aren't any more "malfunctions" than any other rule perfectly defined by the standard. I'd consider the undefined behaviour of signed overflow much more a "malfunction". It is true that unsigned behaviour might be a bit counter-intuitive, but "malfunction" is definitely the wrong word here. – Christian Rau Sep 14 '13 at 11:10
    
@ChristianRau reworded – texasbruce Sep 14 '13 at 19:09
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Interesting. I find your examples to be perfectly sensible, and expected. Unsigned (ring) arithmetic seems far more sensible to me, than integer when dealing with counts of things that cannot be negative. If this really is the scary part of using unsigned, then I'm satisfied that the advice is merely general purpose, and mostly based on convention rather than any serious concern (when the problem domain doesn't need negative values). – Mordachai Sep 16 '13 at 13:33

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