- floating point variables are only approximate representation, not precise one. Not every number can "fit" into float variable. For example, there is no way to put 1/10 (0.1) into binary variable, just like it's not possible to put 1/3 into decimal one (you can only approximate it with endless 0.33333)
- when outputting such variables, it's usual to apply many rounding options. Unless you set them all, you can never be sure which of them are applied. This is especially true for << operators, as the stream can be told how to round BEFORE <<.
Printf also does some rounding. Consider http://codepad.org/LLweoeHp:
float t = 0.1f;
printf("result: %f\n", t);
Well, it looks fine. Why? Because printf defaulted to some precision and rounded up the output. Let's dial in 50 places after decimal point: http://codepad.org/frUPOvcI
float t = 0.1f;
printf("result: %.50f\n", t);
That's different, isn't it? After 625 the float ran out of capacity to hold more data, that's why we see zeroes.
A double can hold more digits, but 0.1 in binary is not finite. Double has to give up, eventually: http://codepad.org/RAd7Yu2r
double t = 0.1;
printf("result: %.70f\n", t);
In your example, 321.12 alone is enough to cause trouble: http://codepad.org/cgw3vUKn
float t = 321.12f;
printf("and the result is: %.50f\n", t);
This is why one has to round up floating point values before presenting them to humans.
Calculator programs don't use floats or doubles at all. They implement decimal number format. eg:
int mantissa; //meaningfull digits
int exponent; //number of decimal zeroes
Ofc that requires reinventing all operations: addition, substraction, multiplication and division. Or just look for a decimal library.