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I could use a little help clarifying this strange comparison when dealing with vector.size() aka size_type

vector<cv::Mat> rebuiltFaces;
int rebuildIndex = 1;
cout << "rebuiltFaces size is " << rebuiltFaces.size() << endl;

while( rebuildIndex >= rebuiltFaces.size() ) {
    cout << (rebuildIndex >= rebuiltFaces.size()) << " , " << rebuildIndex << " >= " << rebuiltFaces.size() << endl;

And what I get out of the console is

rebuiltFaces size is 0
1 , 1 >= 0
1 , 0 >= 0
1 , -1 >= 0
1 , -2 >= 0
1 , -3 >= 0

If I had to guess I would say the compiler is blindly casting rebuildIndex to unsigned and the +- but is causing things to behave oddly, but I'm really not sure. Does anyone know?

share|improve this question
Well yes, when you compare a signed and an unsigned integer of equal size, the signed integer is cast to unsigned. It's defined by the standard. – Mysticial Aug 28 '12 at 4:06
You'll often get a compiler warning for doing this ... What is the question exactly? – twsaef Aug 28 '12 at 4:07
Here's a solution for decrementing unsigned index loops: Unsigned integers in C++ for loops – Mysticial Aug 28 '12 at 4:08
And another falls afoul of the integral promotion rules. – Matthieu M. Aug 28 '12 at 7:30
Thanks for the insight everyone. My post was less of a question and more to gain an understanding regarding what was taking place. Without having read the standard (I confess), I would have assumed everything is casted to a signed value as this makes sense to me logically. Looking at it from a computer architecture perspective it makes sense to cast to unsigned to preserve number range. – lvicks Sep 4 '12 at 20:28
up vote 3 down vote accepted

As others have pointed out, this is due to the somewhat counter-intuitive rules C++ applies when comparing values with different signedness; the standard requires the compiler to convert both values to unsigned. For this reason, it's generally considered best practice to avoid unsigned unless you're doing bit manipulations (where the actual numeric value is irrelevant). Regretfully, the standard containers don't follow this best practice.

If you somehow know that the size of the vector can never overflow int, then you can just cast the results of std::vector<>::size() to int and be done with it. This is not without danger, however; as Mark Twain said: "It's not what you don't know that kills you, it's what you know for sure that ain't true." If there are no validations when inserting into the vector, then a safer test would be:

while ( rebuildFaces.size() <= INT_MAX
        && rebuildIndex >= (int)rebuildFaces.size() )

Or if you really don't expect the case, and are prepared to abort if it occurs, design (or find) a checked_cast function, and use it.

share|improve this answer
Or, an even better programming practice would be to do exactly the opposite: use signed types only when you really really really have to and stick to unsigned ones at all other times. – AnT Aug 28 '12 at 15:19
@AndreyT Except that given the way unsigned arithmetic works in C++, you almost always really, really have to use signed. The default type for integral values in C++ is int. That's the way the language was designed, and that's the way pretty much all experienced programmers use it. Any time you use a type other than int for an integral numeric value, you're screaming that some very unusual constraints are involved. – James Kanze Aug 28 '12 at 15:28
In my experience, it is not true. Any sort of combinatorial programming is done very naturally in unsigned types only. That's how I do it every day. In my field signed types exist primarily as geometric coordinates and that's it. – AnT Aug 28 '12 at 16:09
Calling the dominance of int it "language design" would be a stretch. It is simply a legacy feature inherited from the ancient versions of the language (like CRM), which simply had no unsigned types at all. And absence of unsigned types at that time was more of a design oversight, than a conscious design decision. (If we assume that there was any "design" involved at all.) – AnT Aug 28 '12 at 16:10
The feature that really defined the design of C and C++ languages, in my opinion, is how these languages treat iterator ranges. In C that would be pointer arithmetic in an array. The general principles of pointer arithmetic is aligned with unsigned arithmetic, which is why unsigned types should dominate C and C++ programs. – AnT Aug 28 '12 at 16:14

On any modern computer that I can think of, signed integers are represented as two's complement. 32-bit int max is 0x7fffffff, and int min is 0x80000000, this makes adding easy when the value is negative. The system works so that 0xffffffff is -1, and adding one to that causes the bits to all roll over and equal zero. It's a very efficient thing to implement in hardware.

When the number is cast from a signed value to an unsigned value the bits stored in the register don't change. This makes a barely negative value like -1 into a huge unsigned number (unsigned max), and this would make that loop run for a long time if the code inside didn't do something that would crash the program by accessing memory it shouldn't.

Its all perfectly logical, just not necessarily the logic you expected.


$ cat foo.c
#include <stdio.h>

int main (int a, char** v) {
  unsigned int foo = 1;
  int bar = -1;

  if(foo < bar) printf("wat\n");
  return 0;

$ gcc -o foo foo.c
$ ./foo
share|improve this answer
Whether the computer stores the value as two's complement is irrelevant. static_cast<unsigned type>(-1) is the same value on a two's complement computer as a sign magnitude computer. See the answer to… – David Stone Aug 28 '12 at 4:42
But that's not what his code does. His code has an implicit cast, and that's the way those work. – Bill Aug 28 '12 at 4:52
Do you have a citation in the standard for that? My understanding was that an implicit cast is the same as a static_cast in pretty much every situation, including this one. – David Stone Aug 28 '12 at 5:01
I do not, but the standard doesn't compile my code either. I've attached an example. If you think it works differently, I would like to know how. Thanks. – Bill Aug 28 '12 at 5:36
I'm not saying that you are wrong on a two's-complement architecture. I'm saying that the architecture doesn't matter. Your test would pass on one's complement or sign-magnitude, as well, so it doesn't distinguish between our views. Comparison between int and unsigned promotes the int to unsigned, which is the same as performing static_cast<unsigned>(value_of_int). – David Stone Sep 1 '12 at 0:24

In C and C++ languages when unsigned type has the same or greater width than signed type, mixed signed/unsigned comparisons are performed in the domain of unsigned type. The singed value is implicitly converted to unsigned type. There's nothing about the "compiler" doing anything "blindly" here. It was like that in C and C++ since the beginning of times.

This is what happens in your example. Your rebuildIndex is implicitly converted to vector<cv::Mat>::size_type. I.e. this

rebuildIndex >= rebuiltFaces.size()

is actually interpreted as

(vector<cv::Mat>::size_type) rebuildIndex >= rebuiltFaces.size()

When signed value are converted to unsigned type, the conversion is performed in accordance with the rules of modulo arithmetic, which is a well-known fundamental principle behind unsigned arithmetic in C and C++.

Again, all this is required by the language, it has absolutely nothing to do with how numbers are represented in the machine etc and which bits are stored where.

share|improve this answer
It wasn't like that from the beginning of time, and I can remember using C compilers that converted unsigned to int when comparing the two. Which way it went tended to vary until ANSI standardized C in 1989. – James Kanze Aug 28 '12 at 9:16
@James Kanze: Well, it is still a matter of figuring out whether that was the intent of that compiler, just an unplanned side-effect of the underlying hardware architecture or even a plain bug. As for the language itself, one pre-standard document I see is "C Reference Manual", and it doesn't mention any unsigned types at a all. I wonder what old versions of K&R said about it, if anything... – AnT Aug 28 '12 at 15:15
I'm not sure, but I believe it was the intent of K&R. I know that there was a great deal of discussion about it when C was standardized, because there is no "correct" solution (other than banning such comparisons completely). What is certain is that during standardization, different vendors argued for what their compilers did, as if they'd done it intentionally. Whether it was actually intentional, or just defending their version of the status quo, I don't know. – James Kanze Aug 28 '12 at 15:25

Regardless of the underlying representation (two's complement being the most popular, but one's complement and sign magnitude are others), if you cast -1 to an unsigned type, you will get the largest number that can be represented in that type.

The reason is that unsigned 'overflow' behavior is strictly defined as converting the value to the number between 0 and the maximum value of that type by way of modulo arithmetic. Essentially, if the value is larger than the largest value, you repeatedly subtract the maximum value until your value is in range. If your value is smaller than the smallest value (0), you repeatedly add the largest value until it's in range. So if we assume a 32-bit size_t, you start with -1, which is less than 0. Therefore, you add 2^32, giving you 2^32 - 1, which is in range, so that's your final value.

Roughly speaking, C++ defines promotion rules like this: any type of char or short is first promoted to int, regardless of signedness. Smaller types in a comparison are promoted up to the larger type in the comparison. If two types are the same size, but one is signed and one is unsigned, then the signed type is converted to unsigned. What is happening here is that your rebuildIndex is being converted up to the unsigned size_t. 1 is converted to 1u, 0 is converted to 0u, and -1 is converted to -1u, which when cast to an unsigned type is the largest value of type size_t.

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