As stated in the question, assume 16-bit `short`

and 32-bit `int`

.

```
unsigned short a = 0xFFFF;
```

This initializes `a`

to `0xFFFF`

, or `65535. The expression`

0xFFFF`is of type`

int`; it's implicitly converted to`

unsigned short`, and the value is preserved.

```
signed short b = 0xFFFF;
```

This is a little more complicated. Again, `0xFFFF`

is of type `int`

. It's implicitly converted to `signed short`

-- but since the value is outside the range of `signed short`

the conversion cannot preserve the value.

Conversion of an integer to a signed integer type, when the value can't be represented, yields an implementation-defined value. In principle, the value of `b`

could be anything between `-32768`

and `+32767`

inclusive. In practice, it will almost certainly be `-1`

. I'll assume for the rest of this that the value is `-1`

.

```
unsigned int u16tou32 = a;
```

The value of `a`

is `0xFFFF`

, which is converted from `unsigned short`

to `unsigned int`

. The conversion preserves the value.

```
unsigned int s16tou32 = b;
```

The value of `b`

is `-1`

. It's converted to `unsigned int`

, which clearly cannot store a value of `-1`

. Conversion of an integer to an unsigned integer type (unlike conversion to a signed type) is defined by the language; the result is reduced modulo `MAX + 1`

, where `MAX`

is the maximum value of the unsigned type. In this case, the value stored in `s16tou32`

is `UINT_MAX - 1`

, or `0xFFFFFFFF`

.

```
signed int u16tos32 = a;
```

The value of `a`

, `0xFFFF`

, is converted to `signed int`

. The value is preserved.

```
signed int s16tos32 = b;
```

The value of `b`

, `-1`

, is converted to `signed int`

. The value is preserved.

So the stored values are:

```
a == 0xFFFF (65535)
b == -1 (not guaranteed, but very likely)
u16tou32 == 0xFFFF (65535)
s16tou32 == 0xFFFFFFFF (4294967295)
u16tos32 == 0xFFFF (65535)
s16tos32 == -1
```

To summarize the integer conversion rules:

If the target type can represent the value, the value is preserved.

Otherwise, if the target type is unsigned, the value is reduced module `MAX-1`

, which is equivalent to discarding all but the low-order N bits. Another way to describe this is that the value `MAX-1`

is repeatedly added to or subtracted from the value until you get a result that's in the range (this is actually how the C standard describes it). Compilers don't actually generate code to do this repeated addition or subtraction; they just have to get the right result.

Otherwise, the target type is signed and cannot represent the value; the conversion yields an implementation-defined value. In almost all implementations, the result discards all but the low-order N bits using a two's-complement representation. (C99 added a rule for this case, permitting an implementation-defined signal to be raised instead. I don't know of any compiler that does this.)

`a`

and`b`

, as you may be surprised as to what they are. – WhozCraig Oct 9 '13 at 4:14