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I was looking at this video. Bjarne Stroustrup says that unsigned ints are error prone and lead to bugs. So, you should only use them when you really need them. I've also read in one of the question on Stack Overflow (but I don't remember which one) that using unsigned ints can lead to security bugs.

How do they lead to security bugs? Can someone clearly explain it by giving an suitable example?

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    Who voted to close? Why? What's wrong in question? – Destructor May 22 '15 at 11:17
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    I'd argue strongly for using unsigned types. If you get loop conditions wrong, you're a bad developer. It's very simple math to make it work with unsigned integers and it feels much more natural to me that quantities are unsigned – stefan May 22 '15 at 12:15
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    Problem is most developers are bad... – Joe May 22 '15 at 12:20
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    They can certainly magnify off-by-one errors. Consider the VLT that awarded a man $2^32-1$ cents. thestar.com/news/ontario/2009/03/18/… Of course there is the a similar problem with signed numbers where the smallest is only one off from the largest, but since we often play near 0, the cliff edge is closer with unsigned numbers. – Theodore Norvell May 22 '15 at 13:28
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    Signed ints are also error prone. I spend an hour debugging a problem in Java when shifting a "byte" value produced weird results. It was due to promotion and sign extension. I'd rather have both and choose the right type for the job. – Matti Virkkunen May 22 '15 at 15:30
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One possible aspect is that unsigned integers can lead to somewhat hard-to-spot problems in loops, because the underflow leads to large numbers. I cannot count (even with an unsigned integer!) how many times I made a variant of this bug

for(size_t i = foo.size(); i >= 0; --i)
    ...

Note that, by definition, i >= 0 is always true. (What causes this in the first place is that if i is signed, the compiler will warn about a possible overflow with the size_t of size()).

There are other reasons mentioned Danger – unsigned types used here!, the strongest of which, in my opinion, is the implicit type conversion between signed and unsigned.

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    I would accept this answer bc it's the only one that a compiler wouldn't warn about – Andriy Tylychko May 22 '15 at 11:58
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    @AndyT Get a better compiler. coliru.stacked-crooked.com/a/c79fc9148dfb5f3f – Baum mit Augen May 22 '15 at 12:01
  • @AndyT And btw, my example actually does not get a warning, unlike the above. :) – Baum mit Augen May 22 '15 at 12:04
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    Time to use operator--> ( go down to ): for (size_t i = sz; i --> 0;) ... iterates from sz-1 to 0 – jingyu9575 May 22 '15 at 13:41
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    This doesn't demonstrate a problem with unsigned integers. This demonstrates a problem with the code itself. Advocating avoiding the appropriate tools for a job because they can be used poorly is not doing anyone any favors. Just don't use them poorly. – fyngyrz May 22 '15 at 19:19
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One big factor is that it makes loop logic harder: Imagine you want to iterate over all but the last element of an array (which does happen in the real world). So you write your function:

void fun (const std::vector<int> &vec) {
    for (std::size_t i = 0; i < vec.size() - 1; ++i)
        do_something(vec[i]);
}

Looks good, doesn't it? It even compiles cleanly with very high warning levels! (Live) So you put this in your code, all tests run smoothly and you forget about it.

Now, later on, somebody comes along an passes an empty vector to your function. Now with a signed integer, you hopefully would have noticed the sign-compare compiler warning, introduced the appropriate cast and not have published the buggy code in the first place.

But in your implementation with the unsigned integer, you wrap and the loop condition becomes i < SIZE_T_MAX. Disaster, UB and most likely crash!

I want to know how they lead to security bugs?

This is also a security problem, in particular it is a buffer overflow. One way to possibly exploit this would be if do_something would do something that can be observed by the attacker. They might be able to find what input went into do_something, and that way data the attacker should not be able to access would be leaked from your memory. This would be a scenario similar to the Heartbleed bug. (Thanks to ratchet freak for pointing that out in a comment.)

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    I've always felt uneasy about this alleged counter-example. It's true that just by looking myopically a the code you would think that signed integers are better here. However, this ignores the larger algorithmic issue: The algorithm clearly wants to treat the last element of the range specially. Therefore, this algorithm should have some kind of precondition or branching that actually ensures that the range has a last element! And with such branching in place, unsigned integers would work just fine. – Kerrek SB May 22 '15 at 11:26
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    Why does everybody have to use subtraction here? Why not for (std::size_t i = 0; i + 1 < vec.size(); ++i)? – Siyuan Ren May 22 '15 at 14:21
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    @SiyuanRen I used subtraction because it is wrong. The whole point of this question and answer is highlighting potential bugs. No one is trying to argue that those bugs are not fixable or avoidable. I just argue that something like this could happen, and it would be bad. So yes, you can use your code, and then have correct code. The point is that one can (kind of easily) get it wrong (like I intentionally did in my answer). – Baum mit Augen May 22 '15 at 14:27
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    Again, it's bad code. Not a bad variable type. Doesn't make the case. Integers aren't error-prone. programming is error-prone. – fyngyrz May 22 '15 at 19:20
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    @fyngyrz: IMHO, unsigned int is a perfectly fine variable type in cases where one wants to perform modular arithmetic, but it is a semantically inappropriate [not "bad"] type in cases where one is representing quantities. – supercat May 22 '15 at 19:56
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I'm not going to watch a video just to answer a question, but one issue is the confusing conversions which can happen if you mix signed and unsigned values. For example:

#include <iostream>

int main() {
    unsigned n = 42;
    int i = -42;
    if (i < n) {
        std::cout << "All is well\n";
    } else {
        std::cout << "ARITHMETIC IS BROKEN!\n";
    }
}

The promotion rules mean that i is converted to unsigned for the comparison, giving a large positive number and a surprising result.

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    Any reason for the downvote? I'd like to correct the answer if it's wrong. – Mike Seymour May 22 '15 at 12:22
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    Did not downvote, but just a guess: If your compiler lets you do this, then you are compiling with too few warning flags – example May 22 '15 at 14:34
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    @example - your compiler must let you do this; the code is well formed and its meaning is well defined. Granted, a warning may help spot the logic error, but that's not the compiler's primary responsibility. – Pete Becker May 22 '15 at 21:03
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    The result could be made more interesting by performing comparisons among unsigned n=2; int i=-1, j=1; One will then observe that n < i, i < j, and j < n are all true. – supercat May 22 '15 at 22:15
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    The text should read "C++ IS BROKEN". @PeteBecker says “its meaning is well defined”; formally that is true, but the definition is mathematically ludicrous. Casting i to unsigned is harder to avoid if you are producing an integer result, but for a comparison it is trivial to define the language correctly. Even COBOL had has On size error, but C(++) just gives you enough rope to hang yourself! On VMS, DEC C (don’t know about ++) warns about signed/unsigned comparison/assignment, quite right too (given the broken language), – PJTraill May 23 '15 at 0:17
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Although it may only be considered as a variant of the existing answers: Referring to "Signed and unsigned types in interfaces," C++ Report, September 1995 by Scott Meyers, it's particularly important to avoid unsigned types in interfaces.

The problem is that it becomes impossible to detect certain errors that clients of the interface could make (and if they could make them, they will make them).

The example given there is:

template <class T>
  class Array {
  public:
      Array(unsigned int size);
  ...

and a possible instantiation of this class

int f(); // f and g are functions that return
int g(); // ints; what they do is unimportant
Array<double> a(f()-g()); // array size is f()-g()

The difference of the values returned by f() and g() might be negative, for an awful number of reasons. The constructor of the Array class will receive this difference as a value that is implicitly converted to be unsigned. Thus, as the implementor of the Array class, one can not distinguish between an erreonously passed value of -1, and a very large array allocation.

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  • Wouldn't the same argument hold true for references or values? Clearly someone could wrongly pass a nullpointer to Array<double>(*ptrToSize). – josefx May 25 '15 at 8:23
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    @josefx : You could check this. An assert(ptr != nullptr) could be sufficient there. Something like assert(size < theSizeThatIsLikelyToBeAllocated) doesn't work. Of course, one could still misuse the API with signed types. It's just harder, and the likeliest errors (that are caused by things like implicit conversions) can be covered. – Marco13 May 25 '15 at 13:15
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The big problem with unsigned int is that if you subtract 1 from an unsigned int 0, the result isn't a negative number, the result isn't less than the number you started with, but the result is the largest possible unsigned int value.

unsigned int x = 0;
unsigned int y = x - 1;

if (y > x) printf ("What a surprise! \n");

And this is what makes unsigned int error prone. Of course unsigned int works exactly as it is designed to work. It's absolutely safe if you know what you are doing and make no mistakes. But most people make mistakes.

If you are using a good compiler, you turn on all the warnings that the compiler produces, and it will tell you when you do dangerous things that are likely to be mistakes.

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    A nastier gotcha is that given uint32_t x,y,z; expressions like x-y > z will have very different meanings on 32-bit and 64-bit systems. – supercat May 22 '15 at 22:11
  • @supercat afaict it will have the same result on LP32, LP64 and LLP64 systems. Only ILP64 systems will differ. – plugwash Mar 1 '18 at 5:43
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    @plugwash: I should have clarified--on systems where int is 64 bits. IMHO the Standard would have benefited from defining non-promoting types whose behavior would be consistent on all compilers that accepted code using them. Operations that use wrap32_t should either yield a result of that type when possible, or refuse compilation altogether (e.g. because the compiler doesn't support the required semantics, or because e.g. code is trying to add a wrap16_t and wrap32_t together--an action that cannot possibly yield a result satisfying both constraints). – supercat Mar 1 '18 at 15:34
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The problem with unsigned integer types is that depending upon their size they may represent one of two different things:

  1. Unsigned types smaller than int (e.g. uint8) hold numbers in the range 0..2ⁿ-1, and calculations with them will behave according to the rules of integer arithmetic provided they don't exceed the range of the int type. Under present rules, if such a calculation exceeds the range of an int, a compiler is allowed to do anything it likes with the code, even going so far as to negate the laws of time and causality (some compilers will do precisely that!), and even if the result of the calculation would be assigned back to an unsigned type smaller than int.
  2. Unsigned types unsigned int and larger hold members of the abstract wrapping algebraic ring of integers congruent mod 2ⁿ; this effectively means that if a calculation goes outside the range 0..2ⁿ-1, the system will add or subtract whatever multiple of 2ⁿ would be required to get the value back in range.

Consequently, given uint32_t x=1, y=2; the expression x-y may have one of two meanings depending upon whether int is larger than 32 bits.

  1. If int is larger than 32 bits, the expression will subtract the number 2 from the number 1, yielding the number -1. Note that while a variable of type uint32_t can't hold the value -1 regardless of the size of int, and storing either -1 would cause such a variable to hold 0xFFFFFFFF, but unless or until the value is coerced to an unsigned type it will behave like the signed quantity -1.
  2. If int is 32 bits or smaller, the expression will yield a uint32_t value which, when added to the uint32_t value 2, will yield the uint32_t value 1 (i.e. the uint32_t value 0xFFFFFFFF).

IMHO, this problem could be solved cleanly if C and C++ were to define new unsigned types [e.g. unum32_t and uwrap32_t] such that a unum32_t would always behave as a number, regardless of the size of int (possibly requiring the right-hand operation of a subtraction or unary minus to be promoted to the next larger signed type if int is 32 bits or smaller), while a wrap32_t would always behave as a member of an algebraic ring (blocking promotions even if int were larger than 32 bits). In the absence of such types, however, it's often impossible to write code which is both portable and clean, since portable code will often require type coercions all over the place.

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    A thoroughly confusing answer. Are you saying that the wrapping and promotion rules for unsigned integers depend on their size as well as the size of "base" int? – Martin Ba May 22 '15 at 18:50
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    @MartinBa: yes, that's what he's saying. Since you understood it I guess it wasn't confusing, but it might be surprising to some :-) Integer types smaller than int are a complete PITA, unsigned ones especially so. – Steve Jessop May 22 '15 at 19:01
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    @MartinBa: The answer is confusing because the underlying rules are. I've added a little more to the first couple points; does that help. – supercat May 22 '15 at 19:16
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    @MartinBa: Unsigned types smaller than int will get promoted to signed int whenever any calculations are performed on them. On common 32-bit machines, this is most widely observable with types uint8_t and uint16_t. Promotion to int is often useful when the unsigned values represent quantities, but can be disastrous in cases where they represent things that are supposed to wrap. Note that given uint16_t x=65533; x*=x; a compiler for a system where unsigned int is 16 bits, or where it is larger than 32 bits, must set x=9, but on a system where unsigned is 17 to 32 bits... – supercat May 22 '15 at 21:48
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    @MartinBa: While you are correct that nearly all implementations in practice offer a "wrapping signed int" option, there are a couple of weaknesses: (1) There is no standard means by which a C program can request such semantics, or refuse compilation if the compiler cannot provide them; (2) Requiring that integer values (whether signed or unsigned) wrap precludes many optimizations which are often useful (though sometimes disastrous). I would really like to see C offer a variety of different kinds of integers with different semantics chosen to offer many good optimization opportunities... – supercat May 23 '15 at 17:09
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Numeric conversion rules in C and C++ are a byzantine mess. Using unsigned types exposes yourself to that mess to a much greater extent than using purely signed types.

Take for example the simple case of a comparison between two variables, one signed and the other unsigned.

  • If both operands are smaller than int then they will both be converted to int and the comparison will give numerically correct results.
  • If the unsigned operand is smaller than the signed operand then both will be converted to the type of the signed operand and the comparison will give numerically correct results.
  • If the unsigned operand is greater than or equal in size to the signed operand and also greater than or equal in size to int then both will be converted to the type of the unsigned operand. If the value of the signed operand is less than zero this will lead to numerically incorrect results.

To take another example consider multiplying two unsigned integers of the same size.

  • If the operand size is greater than or equal to the size of int then the multiplication will have defined wraparound semantics.
  • If the operand size is smaller than int but greater than or equal to half the size of int then there is the potential for undefined behaviour.
  • If the operand size is less than half the size of int then the multiplication will produce numerically correct results. Assigning this result back to a variable of the original unsigned type will produce defined wraparound semantics.
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In addition to range/warp issue with unsigned types. Using mix of unsigned and signed integer types impact significant performance issue for processor. Less then floating point cast, but quite a lot to ignore that. Additionally compiler may place range check for the value and change the behavior of further checks.

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    Could you elaborate what significant performance issues, and give example code? – user694733 May 22 '15 at 14:30
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    If you cast a unsigned to int or vice versa the binary representations identify exactly. So there is no overhead for the CPU when you cast the one to the other. – example May 22 '15 at 14:40
  • (provided the C++ implementation uses two's complement representation for negative integers) – Ruslan May 22 '15 at 14:59
  • @example binary layout not the same. Unsigned value occupy all the bit space (8,16,32,64), but signed has the most significant bit for sign which reduce value space by 1 bit. In case of SIMD instructions there is no one that perform calculation on both type in one instruction. Conversion with saturation take place, that is the performance fall. – PRu May 22 '15 at 17:56

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