There are a set of conversions called the usual arithmetic conversions that are used prior to the evaluation of most arithmetic operators.

Basically, you can consider there to be a few rules for arithmetic on integers:

First, integer arithmetic is never performed with operands "smaller than" `int`

, so in the case of `short * signed char`

, both the `short`

and the `signed char`

operands are promoted to `int`

, the two `int`

values are multiplied, and then the result is an `int`

.

Second, if one or both of the types are "larger than" `int`

, the compiler selects a type that is at least "as large" as the type of the largest operand. So, if you have `long * int`

, the `int`

is promoted to a `long`

and the result is a `long`

.

Third, if either operand is `unsigned`

, then the result is unsigned. So, if you have `long * unsigned int`

, the `long`

and the `unsigned int`

are both promoted to an `unsigned long`

and the result is an `unsigned long`

.

If either operand has floating point type, then floating point arithmetic is performed: `float`

, `double`

, or `long double`

is used (which one depends on the types of the operands; the full table used to determine the result type can be found on the page linked at the beginning of this answer).

Note that *the result type is not dependent upon the values of the operands*. The type has to be selected by the compiler at compile time, before the values are known.

If the result of `s * i * i`

is out of range of the result type (`int`

, in your scenario), then you're out of luck: your program can't decide at runtime, "oh, I should switch to use a `long`

!" because the result type had to be selected at compile time.