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Bjarne Stroustrup wrote in The C++ Programming Language:

The unsigned integer types are ideal for uses that treat storage as a bit array. Using an unsigned instead of an int to gain one more bit to represent positive integers is almost never a good idea. Attempts to ensure that some values are positive by declaring variables unsigned will typically be defeated by the implicit conversion rules.

size_t seems to be unsigned "to gain one more bit to represent positive integers". So was this a mistake (or trade-off), and if so, should we minimize use of it in our own code?

Another relevant article by Scott Meyers is here. To summarize, he recommends not using unsigned in interfaces, regardless of whether the value is always positive or not. In other words, even if negative values make no sense, you shouldn't necessarily use unsigned.

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Why would it be a "mistake" to make it unsigned? – Nicol Bolas Apr 16 '12 at 2:33
Similar: – Travis J Apr 16 '12 at 2:36
@Nicol: Because it's an unsigned that's used in interfaces, which Meyers recommends against, and Stroustrup seems to be saying it's not a good idea in the quote above. – Jon Apr 16 '12 at 2:55
Do note that Stroustrup didn't create C. And at the early days space/performance optimizations were very important, or most people would never stop coding in assembly. – dbrank0 Apr 16 '12 at 7:42
A relevant quote from Herb Sutter : "Use int unless you need something different, then still use something signed until you really need something different, then resort to unsigned. And yes, it's unfortunately a mistake in the STL and the standard library that we use unsigned indices." – Jon Jul 23 '15 at 9:58
up vote 42 down vote accepted

size_t is unsigned for historical reasons.

On an architecture with 16 bit pointers, such as the "small" model DOS programming, it would be impractical to limit strings to 32 KB.

For this reason, the C standard requires (via required ranges) ptrdiff_t, the signed counterpart to size_t and the result type of pointer difference, to be effectively 17 bits.

Those reasons can still apply in parts of the embedded programming world.

However, they do not apply to modern 32-bit or 64-bit programming, where a much more important consideration is that the unfortunate implicit conversion rules of C and C++ make unsigned types into bug attractors, when they're used for numbers (and hence, arithmetical operations and magnitude comparisions). With 20-20 hindsight we can now see that the decision to adopt those particular conversion rules, where e.g. string( "Hi" ).length() < -3 is practically guaranteed, was rather silly and impractical. However, that decision means that in modern programming, adopting unsigned types for numbers has severe disadvantages and no advantages – except for satisfying the feelings of those who find unsigned to be a self-descriptive type name, and fail to think of typedef int MyType.

Summing up, it was not a mistake. It was a decision for then very rational, practical programming reasons. It had nothing to do with transferring expectations from bounds-checked languages like Pascal to C++ (which is a fallacy, but a very very common one, even if some of those who do it have never heard of Pascal).

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I don't agree with the "bug attractors" part. C(++) is not the kind of language one should write in carelessly, making assumptions before reading and understanding a good detailed book on the language or the language standard itself. I don't think ignorance is a valid excuse for blaming a language feature. It's there, one must deal with it whether they want or not if they use it. There are more things about C(++) and other programming languages that are broken. Take floating point for example. Many start using it with all kinds of assumptions that are only valid in normal math. FP's a mistake? – Alexey Frunze Apr 17 '12 at 8:41
@Alex: I understand your feelings. Yet, the reason that we have strong type checking in C++, to the degree possible while keeping C compatibility, is that humans are fallible. There is even a very well known name for things going wrong when you just make it possible. – Cheers and hth. - Alf Apr 17 '12 at 11:24
All good compilers gives warning for string( "Hi" ).length() < -3 but not for comparisons between two signed int; your life won't become easier had size_t been defined as signed, you will just make different kinds of errors. – Lie Ryan Oct 6 '12 at 15:47
I saw Java made a mistake not including unsigned type and make things like parsing 0xffffffff or 0xffffffffffffffff harder/slower or working with unsigned values on the net. Now they must introduce some functions to support unsigned operations to Java 8. – Lưu Vĩnh Phúc Aug 6 '15 at 5:30

size_t is unsigned because negative sizes make no sense.

(From the comments:)

It's not so much ensuring, as stating what is. When is the last time you saw a list of size -1? Follow that logic too far and you find that unsigned should not exist at all and bit operations shouldn't be permitted either. – geekosaur

More to the point: addresses, for reasons you should think about, are not signed. Sizes are generated by comparing addresses; treating an address as signed will do very much the wrong thing, and using a signed value for the result will lose data in a way that your reading of the Stroustrup quote evidently thinks is acceptable, but in fact is not. Perhaps you can explain what a negative address should do instead. – geekosaur

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Isn't that exactly what Stroustrup was addressing when writing "Attempts to ensure that some values are positive by declaring variables unsigned..."? – Jon Apr 16 '12 at 2:44
Stroustrup's (and Meyer's) point is that just because a value can never be negative, doesn't mean you should make it unsigned. For one, you can no longer detect erroneous negative values passed in interfaces (which are implicitly converted). – Jon Apr 16 '12 at 2:58
Shouldn't that be your answer (size_t exists to compare addresses), rather than "negative sizes make no sense"? The latter seems to be in contradiction to what Stroustrup and Meyers stated. – Jon Apr 16 '12 at 3:15
@Jon: The warning lets you know that the possibility of a runtime error exists and should be fixed. Again, if you fix it (by either making the function take a signed int, or by making sure that negative values cannot be passed in), there's no problem. And if you don't fix it, if you just do a cast to shut the compiler up, then you deserve what you get. – Nicol Bolas Apr 16 '12 at 3:31
@NicolBolas: My compiler gives no warning here: size_t x = 0; for(size_t i=10; i>=x; --i) {} -- Does yours? – Benjamin Lindley Apr 16 '12 at 3:37

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