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The answer to this sample homework problem is "1,000,000", but I do not understand why:

What is the output of the following code?

int main(void) {
  float k = 1;
  while (k != k + 1) {
    k = k + 1;
  }
  printf(“%g”, k); // %g means output a floating point variable in decimal
}

If the program runs indefinitely but produces no output, write INFINITE LOOP as the answer to the question. All of the programs compile and run. They may or may not contain serious errors, however. You should assume that int is four bytes. You should assume that float has the equivalent of six decimal digits of precision. You may round your answer off to the nearest power of 10 (e.g., you can say 1,000 instead of 210 (i.e., 1024)).

I do not understand why the loop would ever terminate.

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3  
is this a copy-paste of a homework or test question? –  Doug T. Jan 27 '10 at 1:55
3  
This is definitely homework. –  Alok Singhal Jan 27 '10 at 1:55
1  
I tend to ask the OP if it's homework and let them make the decision. It's up to them if they want to cheat, after all, and they would be foolish to think their educators do not watch sites like this. In any case, there's ample precedent of people using homework-like questions for self education. Case in point is all the questions in books like K&R or teach-yourself-whatever. –  paxdiablo Jan 27 '10 at 2:07
2  
this is a sample question, and the answer has been provided. but i couldn't figure out how to reach that answer, so i asked the community for help. im not cheating on my homework –  user133466 Jan 27 '10 at 2:12
2  
I doubt that, @marion, you just didn't wait long enough. This is a good idea why executing the code is not always the right thing to do. For a start, you probably don't have a float with 6 digits precision. Secondly, you're not thinking. Even the dumbest of scientists will hypothesise before blindly coming up with experiments :-) No offence intended. This question is supposed to make you think about the answer and how computers work. –  paxdiablo Jan 27 '10 at 2:25

4 Answers 4

up vote 15 down vote accepted

It doesn't run forever for the simple reason that floating point numbers are not perfect.

At some point, k will become big enough so that adding 1 to it will have no effect.

At that point, k will be equal to k+1 and your loop will exit.

Floating point numbers can be differentiated by a single unit only when they're in a certain range.

As an example, let's say you have an integer type with 3 decimal digits of precision for a positive integer and a single-decimal-digit exponent.

With this, you can represent the numbers 0 through 999 perfectly as 000x100 through 999x100 (since 100 is 1):

What happens when you want to represent 1000? You need to use 100x101. This is still represented perfectly.

However, there is no accurate way to represent 1001 with this scheme, the next number you can represent is 101x101 which is 1010.

So, when you add 1 to 1000, you'll get the closest match which is 1000.

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The code is using a float variable.

As specified in the question, float has 6 digits of precision, meaning that any digits after the sixth will be inaccurate. Therefore, once you pass a million, the final digit will be inaccurate, so that incrementing it can have no effect.

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I suggest you run the OP's code and see that you are completely wrong. On typical implementations, the result will be about 16 million (or it might not stop at all). –  gnasher729 Sep 30 '14 at 9:10

The output of this program is not specified by the C standard, since the semantics of the float type are not specified. One likely result (what you will get on a platform for which float arithmetic is evaluated in IEEE-754 single precision) is 2^24.

All integers smaller than 2^24 are exactly representable in single precision, so the computation will not stop before that point. The next representable single precision number after 2^24, however, is 2^24 + 2. Since 2^24 + 1 is exactly halfway between that number and 2^24, in the default IEEE-754 rounding mode it rounds to the one whose trailing bit is zero, which is 2^24.

Other likely answers include 2^53 and 2^64. Still other answers are possible. Infinity (the floating-point value) could result on a platform for which the default rounding mode is round up, for example. As others have noted, an infinite loop is also possible on platforms that evaluate floating-point expressions in a wider type (which is the source of all sorts of programmer confusion, but allowed by the C standard).

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Actually, on most C compilers, this will run forever (infinite loop), though the precise behavior is implementation defined.

The reason that most compilers will give an infinite loop is that they evaluate all floating point expressions at double precision and only round values back to float (single) precision when storing into a variable. So when the value of k gets to about 2^24, k == k + 1 will still evaluate as false (as a double can hold the value k+1 without rounding), but the k = k + 1 assignment will be a noop, as k+1 needs to be rounded to fit into a float

edit

gcc on x86 gets this infinite loop behavior. Interestingly on x64 it does not, as it uses sse instructions which do the comparison in float precision.

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Which C compilers did you try this on? I tried on GCC and it halted almost instantly. –  Amuck Jan 27 '10 at 3:26
    
even if you use double it will stop at about 1e16-1e17. Because floating point is always finite. Floats have 6-7 digits of precision so it stops at 1e6. The same for doubles which have 16-17 digits of precision. If there's any difference, that's because you're using different compiler options for floating point math –  Lưu Vĩnh Phúc Aug 3 '13 at 1:28
1  
@LưuVĩnhPhúc: No, it won't stop. The comparison is done in double precision, but the addition uses float. So once the float reaches 2^24, it doesn't increase anymore, but the comparison never fails. If you used double for the variable, it would stop after a very long time (unless you have an extremely optimising compiler which would just set the result to 2^53). –  gnasher729 Sep 30 '14 at 9:14
    
@gnasher729 I didn't think of the promotion rule at the time of this comment –  Lưu Vĩnh Phúc Sep 30 '14 at 9:42

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