I would have dared say that the numeric values computed by Fortran and C++ would be way more similar. However, from what I am experiencing, it turns out that the calculated numbers start to diverge after too few decimal digits. I have come across this problem during the process of porting some legacy code from the former language to the latter. The original Fortran 77 code...

```
INTEGER M, ROUND
DOUBLE PRECISION NUMERATOR, DENOMINATOR
M = 2
ROUND = 1
NUMERATOR=5./((M-1+(1.3**M))**1.8)
DENOMINATOR = 0.7714+0.2286*(ROUND**3.82)
WRITE (*, '(F20.15)') NUMERATOR/DENOMINATOR
STOP
```

... outputs **0.842201471328735**, while its C++ equivalent...

```
int m = 2;
int round = 1;
long double numerator = 5.0 / pow((m-1)+pow(1.3, m), 1.8);
long double denominator = 0.7714 + 0.2286 * pow(round, 3.82);
std::cout << std::setiosflags(std::ios::fixed) << std::setprecision(15)
<< numerator/denominator << std::endl;
exit(1);
```

... returns **0.842201286195064**. That is, the computed values are equal **only up to the sixth decimal**. Although not particularly a Fortran advocator, I feel inclined to consider its results as the 'correct' ones, given its legitimate reputation of number cruncher. However, I am intrigued about the cause of this difference between the computed values. Does anyone know what the reason for this discrepancy could be?

`0.8422012861950640318689334181`

– J.F. Sebastian May 3 '10 at 10:45`gfortran -fdefault-real-8`

produces the same result as C++. – J.F. Sebastian May 3 '10 at 10:54speed, not accuracy. The numerics model in C and C++ is actually stricter (and lots of other related issues are a bit tighter in C and C++, like literals being double-precision by default as you saw here). – Stephen Canon May 3 '10 at 15:02