With these definitions and assuming `unsigned short`

== 16 bit and `int`

== 16 bit and `unsigned long`

== 32 bit (note that the size of `int`

is important):

```
unsigned short a, b;
unsigned long c;
```

These two statements will do different things:

```
c = (unsigned long)(a + b);
c = (unsigned long)a + b;
```

The first one -- the one you showed -- will first add the numbers as unsigned shorts, discarding any overflow -- and *then* expand to an unsigned long. This may be why you're asking. The second will cast `a`

to an unsigned long, then add the two numbers, expanding `b`

to an unsigned long as well before doing the addition.

You could also do this:

```
c = (unsigned long)a + (unsigned long)b;
```

but it's unnecessary as the presence of one unsigned long in the calculation will cause the other to be automatically promoted from short to long size.

Thus:

```
a = 0x8001;
b = 0x8001;
c = (unsigned long)(a + b); /* c is assigned 0x00000002 */
c = (unsigned long)a + b; /* c is assigned 0x00010002 */
```

All of this depends on your specific compiler and on the size of its variables. It depends specifically on the size of an `int`

on your compiler, as all values are automatically promoted to `int`

or `unsigned int`

during calculations. You mentioned hardware with 16 bit accumulators, and C compilers will typically (but not always) use the native register size as the size of `int`

, which is why I assumed an `int`

as 16 bits.