# Dividing large double by large int

I'm coding a physical simulation and recently I was encountering anomalous results. I managed to debug my program, the error was in the division of a large double by a large int, something of the form:

``````cout << my_large_double/my_large_int << endl
``````

with my_large_double of the order -10^{9} and the product of my two ints is of the order 10^{9} was returning something positive of the order 1. I fixed it by imposing a conversion to double in the denominator:

``````cout << my_large_double/( (double)my_large_int1*my_large_int2) << endl
``````

But I would like to understand where is the mistake coming from, and are there ways to prevent them from happening usually?

Update: I skipped a detail that matters in my first question: the int is actually the product of two ints.

-
Might be due to loopback as in the max value of int might be reached and so it looped back –  AsG Nov 26 '13 at 16:38
@john Experience tells me that it solved the problem, try doing it on your side if you want. –  Liam Nov 26 '13 at 16:39
I believe Your question has been answered here: stackoverflow.com/questions/3051135/… –  Ivan Berloga Nov 26 '13 at 16:39
@AakashGoyal: Right int can't be larger than 2*10^9, so it should work if upgraded to int_64t, is there a way to know when you overflow a variable at running time? –  Liam Nov 26 '13 at 16:40
@Liam, that does make all the difference –  john Nov 26 '13 at 16:45

It depends on exactly how the expression was written.

If you write this:

``````my_large_double / my_large_int1 / my_large_int2
``````

then it's equivalent to:

``````(my_large_double / my_large_int1) / my_large_int2
``````

which should give you reasonably accurate results; `my_large_int1` is promoted to `double` before the first division, and `my_large_int2` is promoted to `double` before the second division.

If you write this:

``````my_large_double / (my_large_int1 * my_large_int2)
``````

then the multiplication is done in the type of the two integer variables, and depending on their values you could have an overflow (which can give you a much smaller value than the mathematical product -- though strictly speaking the behavior of signed integer overflow is undefined).

The important thing to remember is that, in most cases, each C expression is effectively evaluated in isolation; its type is not affected by the context in which it appears. The expression `my_large_int1 * my_large_int2` is an integer multiplication, even if the result is the operand of a floating-point division or is assigned to a floating-point variable.

Any operation whose operands are both integers is an integer operation. If one operand is `double` and the other is `int`, the `int` operand is promoted to `double`.

Even this:

``````double temp = my_large_int1 * my_large_int2;
... my_large_double / temp ...
``````

will perform an integer multiplication before using the result to initialize `temp`, and this:

``````my_large_double / (double)(my_large_int1 * my_large_int2)
``````

has the same problem.

As you've found, the solution is to cast one or both of the integer operands to `double`:

``````my_large_double / ((double)my_large_int1 * (double)my_large_int2)
``````

(You might as well cast both of them, just for symmetry and clarity.)

-

An IEEE format `double` can hold an `int` without precision loss up to 53 bits, versus the 31 bits typical for an `int`. Your solution is a good one, convert to `double` up front so that you don't hit an integer overflow in the multiply.

-
Yes, is there a general way to prevent int from overflowing at running time? –  Liam Nov 26 '13 at 18:11
use double or long long? –  gregory561 Nov 26 '13 at 18:19
@gregory561: There's no actual guarantee that `long long` is wider than `int` (though it typically is). –  Keith Thompson Nov 26 '13 at 19:15