I'm getting warning for signed vs. unsigned comparison when I'm comparing a std::abs(int) against an unsigned. And indeed, std::abs returns signed values. Why was that choice made? It would have solved the problem of negative values whose absolute value cannot be represented in the signed type.

And then, is there something cleaner (i.e., without cast) than this to avoid warnings?

#include <cassert>
#include <cstdlib>

// max(1, lhs + rhs). (lhs must be > 0)
unsigned add(unsigned lhs, int rhs)
    (0 < rhs || static_cast<unsigned>(-rhs) < lhs
     ? rhs + lhs
     : 1);

int main()
  assert(add(42, -41) == 1);
  assert(add(42, 0) == 43);
  assert(add(42, 1) == 43);
  assert(add(42, -51) == 1);
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    I doubt that this had much influence on the standard rationale, but it isn't actually guaranteed that unsigned can represent every absolute value of int. In theory you could have a conforming implementation in which int is 33 bits 2's complement, and unsigned is 32 bits. On that implementation, neither int nor unsigned can represent the absolute value of INT_MIN. Not sure why you'd want such an implementation, of course, but it's legal and so your proposal doesn't strictly solve the problem. The standard would still permit implementations where you can't do abs(INT_MIN)! – Steve Jessop Apr 19 '13 at 9:43
  • And in practice, the fact that there's one value of int on which you can't do abs isn't really any more hassle than the fact that there's one value of int on which you can't do --. And likewise a value on which you can't do ++. The authors of C and C++ don't hate undefined overflow behavior enough to remove it. – Steve Jessop Apr 19 '13 at 9:44
  • @SteveJessop How's that possible given §3.9.1-3 (same amount of storage and same object representation for unsigned int and int)? – Christian Rau Apr 19 '13 at 10:45
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    @ChristianRau: different numbers of padding bits. Whether a bit participates in the value or not isn't part of the object representation, it's part of the value representation. It's pretty academic, but C and C++ are determined to allow for funny architectures. I say funny: verging on hilarious. 32 and 31 would be more plausible than 33 and 32, though, with an 8 bit byte. I'm not sure, but I think there may have been machines where the sign bit was unused in unsigned types (although unsigned char would have to use it). Whether they had standard-conforming C++ compilers is another matter. – Steve Jessop Apr 19 '13 at 10:48
  • Didn't Cray have an int type like that? IIRC it used the float layout, but with exponent bits set to zero. And for unsigned int, probably the sign bit was set to zero as well. – MSalters Apr 19 '13 at 12:59

The short answer is that this is done so that the return type of abs is the same as its input type. This is exactly what you want, most of the time.

Mostly, when calling abs, you're dealing with an equation where all elements are of the same type (or you'd get warnings) and you want to use the magnitude of some variable in that equation. That doesn't mean you want to change the type of one of the variables in your equation. That would give the kind of issues/warnings you're mentioning.

So, in short, it is more common and more natural to want the same input and output type when asking for the absolute value of a signed variable. The magnitude of value isn't commonly used as an index.

  • +1 Absolutely. In the end it's a mathematical function and not supposed to mess my types around. You don't want std::abs(1.0) to return an unsigned double either. In the same way std::floor doesn't return an int (ok, this one might also be concerned about representable ranges in addition to mere conceptual type conservation). – Christian Rau Apr 19 '13 at 10:35
  • @ChristianRau: I don't know what an unsigned double is, but I certainly don't want one ever ;-) And some people would say much the same about unsigned integer types. – Steve Jessop Apr 19 '13 at 10:36
  • @ChristianRau Exactly my point! Also, I agree with @SteveJessop that an unsigned double sounds very unmotivated and I certainly don't miss it in the standard. – Agentlien Apr 19 '13 at 10:57
  • @SteveJessop & Argentlien Well, you never know when you need that extra bit of precision in a context where numbers cannot be negative. But Ok, this would probably make the actual computing machinery unneccessarily more complex, I guess (since a floating point type not backed by an IEEE standardization and a hardware implementation is pretty useless anyway). But I'm wandering anyway ;) – Christian Rau Apr 19 '13 at 11:00
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    @SteveJessop: "And some people would say much the same about unsigned integer types". Well, I do know people who work in Java and rage against it about every day for its lack of unsigned integers. – akim Apr 19 '13 at 13:16

In c++11 you could write your own to make to cast automatic:

#include <utility>

template< typename T >
typename std::make_unsigned<T>::type  abs( T x )
    //We need to cast before negating x to avoid the overflow.
    return x < 0? -static_cast<std::make_unsigned<T>::type>(x) : x;

I tried it with -Wall options, got no warnings.

  • 2
    Btw this code still has UB when passed INT_MIN, it doesn't "solve the problem of negative values whose absolute value cannot be represented". But it does save typing out the static_cast every time you use it. – Steve Jessop Apr 19 '13 at 9:49
  • I thought so too, but then I tried: int x = std::numeric_limits<int>::min(); unsigned y = my_abs(x); cout << x << endl; cout << y << endl; – fstamour Apr 19 '13 at 9:51
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    The problem is that -x has type T, and overflows with the 2's complement min value before you have a chance to convert to the unsigned type. On your implementation, when you tested it, that overflow was harmless, but it isn't guaranteed to be harmless. A safe alternative would be return (x < 0) ? static_cast<std::make_unsigned<T>>(-(x+1))+1 : x;, and you can hope that maybe the optimizer will sort it out. – Steve Jessop Apr 19 '13 at 10:05
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    I see, -static_cast<std::make_unsigned<T>>(x) would be sufficient no? Instead of forcing it to overflow. ? – fstamour Apr 19 '13 at 10:12
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    Yes, I think that works. You could even make it a bit shorter with -static_cast<decltype(my_abs(x))>(x) rather than repeating the return type definition :-) – Steve Jessop Apr 19 '13 at 10:33

That is no choice, that is definition. abs is implemented via a template, which returns the type in which the original value was stored. The result will always be valid, as the absolute value of an signed integer will always fit in its original data type. An explicit cast to your target data type should be enough to get rid of any warnings...

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    "the absolute value of an signed integer will always fit in his original data type" -- that's not true. On almost all implementations, the absolute value of INT_MIN doesn't fit in int, and abs(INT_MIN) causes overflow. – Steve Jessop Apr 19 '13 at 9:23
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    abs is implemented via a template. The abs I know is not a template. – Jesse Good Apr 19 '13 at 9:26
  • These are the variants of abs that exist according to the standard: en.cppreference.com/w/cpp/numeric/math/abs The only ones of these that are templated are those that take template types as input. (valarray and complex). – Agentlien Apr 19 '13 at 9:31
  • I don't understand what "That is no choice, that is definition... implemented via a template". It seems that you claim that the interface of the function was dictated by its implementation (which is based on overloading as already reported). Of course it must be the opposite. – akim Apr 19 '13 at 9:33
  • It is a template for complex values: template<class T> T abs (const complex<T>& x); but I confused that with the standard implementation. You are both right. – Lord Wolfchild Apr 19 '13 at 9:34

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