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.)