double Parameters::calculate_fy(int area_number, double x, double y)
{
if(Testing_parameters::test == 1)
switch(area_number)
{
case 0: return 1.0 / calculate_rho(area_number) * 0;
case 1: return 1.0 / calculate_rho(area_number) * 0;
default: return 1.0;
}
if (Testing_parameters::test == 2)
switch (area_number)
{
case 0: return 0.0;
case 1: return 0.0;
default: return 0.0;
}
if(Testing_parameters::test == 3)
switch(area_number)
{
case 0: return -calculate_lambda(area_number) * (60 * x * x - 60 * y * y) +
1.0 / calculate_rho(area_number) * (60 * x * x - 60 * y * y) +
400 * pow_i(4, x) * pow_i(3, y) + 100 * (pow_i(7, y)
- pow_i(4, x) * pow_i(3, y));
case 1: return -calculate_lambda(area_number) * (60 * x * x - 60 * y * y) +
1.0 / calculate_rho(area_number) * (60 * x * x - 60 * y * y) +
400 * pow_i(4, x) * pow_i(3, y) + 100 * (pow_i(7, y)
- pow_i(4, x) * pow_i(3, y));
default: return 1.0;
}
return 1.0;
}
int main()
{
int b, e;
while (std::cin >> b >> e) {
std::cout << pow_r(b, e) << '\n';
std::cout << pow_i(b, e) << '\n';
}
return 0;
}
double Parameters::calculate_fx(int area_number, double x, double y)
{
if(Testing_parameters::test == 1)
switch(area_number)
{
case 0: return 1.0 / calculate_rho(area_number) * 0;
case 1: return 1.0 / calculate_rho(area_number) * 0;
default: return 1.0;
}
if (Testing_parameters::test == 2)
switch (area_number)
{
case 0: return 0.0;
case 1: return 0.0;
default: return 0.0;
}
if(Testing_parameters::test == 3)
switch(area_number)
{
case 0: return -calculate_lambda(area_number) * 120 * x * y +
1.0 / calculate_rho(area_number) * 120 * x * y +
400 * x * pow_i(6, y) + 300 * (pow_i(5, x) * y * y
- x * pow_i(6, y));
case 1: return -calculate_lambda(area_number) * 120 * x * y +
1.0 / calculate_rho(area_number) * 120 * x * y +
400 * x * pow_i(6, y) + 300 * (pow_i(5, x) * y * y
- x * pow_i(6, y));
default: return 1.0;
}
return 1.0;
}
