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Code [GCC, compiled with -O2 flag]

int main()
{
    vector< vector<int> > matrixa(8);
    int ff = 5;
    int s = pow(ff, matrixa.size());
    int ss = pow(double(ff), int(matrixa.size()));
    vector< vector<int> > comb(s);
    cout << ff << "^" << matrixa.size() << " = " << s << endl;
    cout << ss << endl;
    return 0;
}

Output

5^8 = 390624
390625

I'm wondering why s = 390624 when it should be 390625. If I compile the code without -O2 flag, then s = 390625. Also, the casting for ss seems to correct the problem.

What's going on?

My OS is Windows 7 Ultimate x64. Not sure about the GCC version, it comes with Code::Blocks 10.05.

share|improve this question
    
I think the one that comes is 4.4.1 IIRC. –  chris Jul 12 '12 at 16:14
    
double pow(double, int) is removed in C++11 BTW –  user195488 Jul 12 '12 at 16:16
    
Works correctly here (gcc-4.5.1, linux). –  Daniel Fischer Jul 12 '12 at 16:16
    
It probably computes powers by numeric approximation (probably newtons method). It's possible that with optimization turned up it will run fewer iterations (and be less accurate). What do you get if you do not cast the output to an int? –  Wug Jul 12 '12 at 16:17
    
@wug: not sure what you're asking. i haven't cast any output. –  Donotalo Jul 12 '12 at 16:19

2 Answers 2

up vote 6 down vote accepted

Because floating-point arithmetic is not perfect and when you do

int s = pow(ff, matrixa.size());

the result of pow is actually something more like 390624.99999 and when you truncate it to int it effectively is flattened down to 390624. If you expect an integer value there (a floating-point with .0 fractional part), you should probably round the result of pow.

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3  
This error is not caused by floating-point arithmetic. pow(5, 8) is exactly representable as a double, so a good math library should return exactly 390625. Even a library that only guarantees faithful rounding (less than 1 ULP) rather than correct rounding (no more than 1/2 ULP with ties rounded to even) would get the correct answer here. So, if pow is not returning the correct answer, the problem is library quality, not floating-point arithmetic. –  Eric Postpischil Jul 12 '12 at 18:02
1  
@EricPostpischil Yes, but if floating-point arithmetic was absolutely ideal (which is not and it was the point of my answer), even the (poor) algorithm behind that implementation of pow would not produce any deviations. So one can actually say it was caused by IEEE floating-point arithmetic. But I agree with you completely, it's the implementation of pow to blame in this particular case.. –  Desmond Hume Jul 12 '12 at 18:27
1  
Ideal arithmetic, in the sense that each operation produced exact mathematical results, would not cause pow to produce correct results. This is because floating-point arithmetic provides only addition, subtraction, multiplication, division, square root, and some utility operations. These are insufficient to compute pow (for general arguments; obviously specific cases like pow(5, 8) can be computed), because the arithmetic operations can compute only rational functions extended with square roots. Therefore, pow and other math library functions must be approximated, even with perfect arithmetic. –  Eric Postpischil Jul 12 '12 at 18:36

Try assigning the result to a double and output it (with possible bigger std::setprecision) settings. You will see that due to rounding errors, the value will be something like 390624.99999999999 (or similar).

Casting to an int truncates the fractional part, thus leaving you with 390624. Use std::round to get the desired result.

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