My C++ code includes a class Fraction with the variables "zaehler" (numerator) and "nenner" (denominator). These Fractions should be added, subtracted, multiplied and divided.

I used operator overloading, to do the calculations and the basic combinations work fine and the results are reduced correctly:

When it comes to combining the operators, it mostly worked as expected, but here comes my problem:

The first three are correct, but the combination of multiply and subtracted messes up. While debugging I noticed that one variable seems to have two values:

How can the variables (dif.zaehler and dif.nenner) have different values?

The class and the overloadings (ggT = greatest common divisor, kgV = smallest common denominator):

``````Fraction::Fraction()
{
zaehler = 1;
nenner = 1;
}

unsigned int Fraction::ggT(unsigned int a, unsigned int b)
{
if (b != 0)     //b = 0, wenn a % b = 0, bedeutet Division ohne Rest
{
return ggT(b, a % b);
}
else
{
return a;
}
}

unsigned int Fraction::kgV(unsigned int a, unsigned int b)
{
int facA[30], facB[30];

for (int i = 0; i < 30; i++)
{
facA[i] = a * (i + 1);
facB[i] = b * (i + 1);
}
for (int i = 0; i < 30; i++)
{
for (int k = 0; k < 30; k++)
{
if (facB[k] == facA[i])
{
return facA[i];
}
}
}
}

Fraction Fraction::operator-(const Fraction& b)
{
Fraction dif;
int temp_zaehler;

int zaehler_a = ((float)this->zaehler / this->nenner) * kgV(this->nenner, b.nenner);
int zaehler_b = ((float)b.zaehler / b.nenner) * kgV(this->nenner, b.nenner);
dif.zaehler = (zaehler_a - zaehler_b);
dif.nenner = kgV(this->nenner, b.nenner);

if (dif.zaehler < 0)
{
temp_zaehler = dif.zaehler;
dif.zaehler /= ggT(dif.zaehler*-1, dif.nenner);
dif.nenner /= ggT(temp_zaehler*-1, dif.nenner);
}
else
{
temp_zaehler = dif.zaehler;
dif.zaehler /= ggT(dif.zaehler, dif.nenner);
dif.nenner /= ggT(temp_zaehler, dif.nenner);
}

return dif;
}

Fraction Fraction::operator*(const Fraction& b)
{
Fraction prod;
int temp_zaehler;
prod.zaehler = (this->zaehler) * b.zaehler;
prod.nenner = (this->nenner) * b.nenner;

if (prod.zaehler < 0)
{
temp_zaehler = prod.zaehler;
prod.zaehler /= ggT(prod.zaehler * -1, prod.nenner);
prod.nenner /= ggT(temp_zaehler * -1, prod.nenner);
}
else
{
temp_zaehler = prod.zaehler;
prod.zaehler /= ggT(prod.zaehler, prod.nenner);
prod.nenner /= ggT(temp_zaehler, prod.nenner);
}
return prod;
}
``````

And the line in main.cpp (getString outputs the numerator and denominator as string):

``````std::cout << "d * e - b = " << d.getString() << " * " << e.getString() << " - " << b.getString() << " = " << (d * e - b).getString() << "\n";
``````
• It looks like you get an integer overflow Commented Jun 24, 2023 at 10:25
• Be careful with implicit conversions between unsigned and signed. The fact that one of the factions is printed as `-2 / 5` means that at least the numerator is signed. Converting a `int` value of `-2` to `unsigned`, which is likely happening implicitly somewhere in your code, yields `4294967294` Commented Jun 24, 2023 at 10:47
• Btw: the standard library has `std::gcd` and `std::lcm`. Consider using that implementation instead of implemeneting your own... Commented Jun 24, 2023 at 10:49
• I don't recommend using float btw. This can result in inaccuracies being introduced. Rather than doing `int zaehler_a = ((float)this->zaehler / this->nenner) * kgV(this->nenner, b.nenner); ...` I'd recommend `auto resultDenominator = std::lcm(nenner, b.nenner); auto resultNumerator = (zaehler * (resultDemominator / nenner)) - (b.zaehler * (resultDenominator / b.nenner)); auto factor = std::gcm(resultDenominator, resultNumerator); return {resultNumerator/ factor, resultDenominator/factor};` (you'll still need to make sure to not have any implicit casts from signed to unsigned messing this up... Commented Jun 24, 2023 at 11:03
• Furthermore I'd recommend implementing the operators at namespace scope to allow implicit conversions to take place. E.g. `class Fraction{ ... Fraction(int numerator = 0, int denominator = 1); };` would allow for `auto x = 1 + Fraction{1, 2};` with an operator implementation at namespace scope, but your implementation wouldn't allow this. Furthermore default value of arithmetic types is 0 and I recommend you use this convention for your class too, to be consistent with this; initialize to `0 / 1` in the default constructor instead of to `1 / 1`... Commented Jun 24, 2023 at 11:09