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The following C code

int main(){
    int n=10;    
    int t1=pow(10,2);
    int t2=pow(n,2);
    int t3=2*pow(n,2);
    return (0);

gives the following output


I am using a devcpp compiler. It does not make any sense, right? Any ideas? (That pow(10,2) is maybe something like 99.9999 does not explain the first output. Moreover, I got the same output even if I include math.h)

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pow returns a double, which is a floating-point type. You're using it as an int. It does make sense. –  Dan Fego Jun 4 '13 at 16:48
pow returns double not int, you are truncating the non integer part from the number. –  Alex Jun 4 '13 at 16:48
Your code is not valid C because you call pow without declaring it. –  R.. Jun 4 '13 at 16:48
printf("%.9lf", 2*pow(n,2)); –  Nicholaz Jun 4 '13 at 16:50
Well this question is certainly interesting, but since the question contains fake code (missing includes, etc.) that makes it difficult to diagnose the actual problem, I'm hesitant to +1 it... –  R.. Jun 4 '13 at 19:45

3 Answers 3

You are using a poor-quality math library. A good math library returns exact results for values that are exactly representable.

Generally, math library routines must be approximations both because floating-point formats cannot exactly represent the exact mathematical results and because computing the various functions is difficult. However, for pow, there are a limited number of results that are exactly representable, such as 102. A good math library will ensure that these results are returned correctly. The library you are using fails to do that.

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No - this can be lead to a slower implementation, which may be unacceptable (or less desirable) for developers using floating point math correctly. –  djechlin Jun 4 '13 at 17:04
1) I concur with your 1st statement about "poor-quality math library". A good, and fast too, pow() rolled in binary64 (typical double) or binary32 (typical float) in unusual to have resulted in a non-exact answer given pow(10, 2), even without resorting to "exactly representable" tests. But functions like pow() are allowed it be 1 ULP off, so it becomes a teachable moment for OP. 2) For the pow(x,y), integer exactness test is required of y when when x (exact integer or not) is < 0 as in pow(-2.1, -3.0). –  chux Jun 4 '13 at 18:37
@chux: (1) I do not see a 1-ULP requirement in the C standard except in the non-normative Annex H, and it refers to a clause (5.2.8) that I do not find in the current version (2012(E)) of LIA-1. I do not see an accuracy specification in the normative but optional Annex F. (2) The requirement for an exact integer y for negative x is an issue about the domain of the function, not the accuracy of the result, and it is not relevant in this question. –  Eric Postpischil Jun 4 '13 at 19:19
@djechlin: A good math library is both fast and accurate. –  Eric Postpischil Jun 4 '13 at 19:20
@chux: Usually, anybody implementing a library with ≤ 1 ULP accuracy would actually aim for < 1 ULP. This is called “faithful rounding”, and there is an important reason for it. Faithful rounding guarantees that there is no error at all in cases where the mathematical result is actually representable, because, if the returned result is x and the mathematical result is x, then |x–x| < 1 ULP guarantees that x cannot be any representable value except x. Thus, a library implementing faithful rounding must return the exact result for pow(10, 2). –  Eric Postpischil Jun 4 '13 at 20:12

Store the result computations as doubles. Print as double, using %f instead of %d. You will see that the 99 is really more like 99.999997, and this should make more sense.

In general, when working with any floating point math, you should assume results will be approximate; that is, a little off in either direction. So when you want exact results - like you did here - you're going to have trouble.

You should always understand the return type of functions before you use them. See, e.g. cplusplus.com:

double pow (double base, double exponent); /* C90 */

From other answers I understand there are situations when you can expect pow or other floating-point math to be precise. Once you understand the necessary imprecision that plagues floating point math, please consult these.

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This is not an issue about the return type of the function or about how floating-point arithmetic works. The pow function can return an exact result in this case. It does not because the implementation is poor, not because the format cannot support it or because the result cannot be calculated. –  Eric Postpischil Jun 4 '13 at 19:23
Moreover, IEEE mandates correct results when the correct answer is exact, so failure to deliver is a bug. –  R.. Jun 4 '13 at 19:44
@R..: Are you referring to IEEE 754-2008 or another standard? Which clause? 754-2008 9.2 recommends that language standards define certain functions, including pow, to be implemented with correct rounding, but it does not mandate this. It uses “should” and defines “should” to means that one of several possibilities is particularly suitable but does not exclude others or is preferred but not required. Is there additional text regarding exactly representable cases? –  Eric Postpischil Jun 4 '13 at 20:46
@EricPostpischil see edit. I focused my answer to the extent that I understood floating point math. I think the more important point is the OP understand the necessary imprecision, before understanding when it's okay to expect exact results. In other words, were the OP using a more precise pow function, the results would have been right, for coincidental reasons, given the OP's prior knowledge of float and precision. –  djechlin Jun 5 '13 at 2:05

Your variables t1, t2 and t3 must be of type double because pow() returns double.

But if you do want them to be of type int, use round() function.

int t1 = pow(10,2);
int t2 = round(pow(n,2));
int t3 = 2 * round(pow(n,2));

It rounds the returned values 99.9... and 199.9... to 100.0 and 200.0. And then t2 == 100 because it is of type int and so does t3.

The output will be:


Because the round function returns the integer value nearest to x rounding half-way cases away from zero, regardless of the current rounding direction.

UPDATE: Here is comment from math.h:

/* Excess precision when using a 64-bit mantissa for FPU math ops can
cause unexpected results with some of the MSVCRT math functions.  For
example, unless the function return value is stored (truncating to
53-bit mantissa), calls to pow with both x and y as integral values
sometimes produce a non-integral result. ... */
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ok... now numbers like 100.00001 are going to go up to 101. –  djechlin Jun 4 '13 at 17:01
In user2452591's case each value will be 99.9998 or 143.9997 ot 624.9998 and so on... user2452591 would like to pow t1, t2 and t3 which are of type int. Thay can't be like 100.00001. For 100 the result will alvays be 99.99999... because of double type's specifications. So ceil() rounds it up to 100 and it is the required result. –  id_yulian Jun 4 '13 at 17:06
They're of type double, not type int. –  djechlin Jun 4 '13 at 17:07
@JulianKhlevnoy: Wrong. double values certainly can be exactly an integer; they just aren't required to be. (and the results of mathematical computations frequently won't be) –  SLaks Jun 4 '13 at 17:35
Removed downvote. I don't quite think it's a good answer because it covers up the OP's seeming obliviousness to how doubles work, but I think this is at least correct code for the situation now. –  djechlin Jun 4 '13 at 18:06

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