This can get kind of ugly. The compiler looks at the types of the operands for a *single* operation, and promotes both to the "larger" type (e.g., if one is `int`

and the other `double`

, it'll convert the `int`

to `double`

, then do the operation).

In your case, that could have some rather unexpected results. Right now you have: `2*pi*j*X*Y/n`

. The operators group from left to right, so this is equivalent to `((((2*pi)*j)*X)*Y)/n`

. In this case, that'll probably work out reasonably well -- one of the operands in the "first" operation is a float, so all the other operands will be converted to float as you want. If, however, you rearrange the operands (even in a way that seems equivalent in normal math) the result could be completely different. Just for example, if you rearranged it to `2*Y/n*pi*j*X`

, the `2*Y/n`

part would be done using *integer* arithmetic because `2`

, `Y`

, and `n`

are all integers. This means the division would be done on integers, giving an integer result, and only *after* that integer result was obtained would that integer be converted to a float for multiplication by `pi`

.

Bottom line: unless you're dealing with something like a large array so converting to smaller types is likely to really save quite a bit of memory, you're generally much better off keeping all the operands of the same type if possible. I'd also note that in this case, your attempt at "managing memory intelligently" probably won't do any good anyway -- on a typical current machine, a `long int`

and a `float`

are both 32 bits, so they both use the same amount of memory in any case. Also note that `exp`

takes a `double`

as its operand, so even if you do `float`

math for the rest, it'll be promoted to a `double`

anyway. Also note that conversions from `int`

to `float`

(and back) can be fairly slow.

If you're really only dealing with a half dozen variables or so, you're almost certainly best off leaving them as `double`

and being done with it. Converting to a combination of `float`

and `long`

will save about 14 bytes of data storage, but then add (around) 14 bytes of extra instructions to handle all the conversions between `int`

, `float`

, and `double`

at the right times, so you'll end up with slower code that uses just as much memory anyway.