The first addition adds the 16-bit number, stored in `c`

:
`1111 1111 0000 0000`

Plus the number that is coded as the value of the ASCII char enclosed between ' '. But in C you can specify a character as an hexadecimal code prefixed by `\x`

like this `'\xNN'`

where `NN`

is a two hex digit number. The ASCII code of that character is the value of `NN`

itself. So `'\xFF'`

is a somewhat unusual way to say `0xFF`

.

The addition is to be performed using a `signed short`

(16 bits, signed) plus a `char`

(8 bits, signed). For it, the compiler promotes that 8-bit value to a 16-bit value, preserving the original sign by doing a sign-extension conversion.

So before the addition, `'xFF'`

is decoded as the 8-bit signed number `0xFF`

`(1111 1111)`

, which in turn is promoted to the 16-bit number `1111 1111 1111 1111`

(the sign must be preserved)

The final addition is

```
1111 1111 0000 0000
1111 1111 1111 1111
-------------------
1111 1110 1111 1111
```

Which is the hexadecimal number `0xFEFF`

. That is the new value in variable `c`

.

Then, there is `d=c;`

`d`

is `unsigned short`

: it has the same size of a `signed short`

, but sign is not considered here; the MSb is just another bit. As both variables have the same size, the value in `d`

is exactly the same we had in `c`

. That is:

```
d = 1111 1110 1111 1111
```

The difference is that any aritmetic or logical operation with this number won't take sign into account. This means, for example, that conversions that change the size of the number won't extend the sign.

```
e = d >> 2;
```

`e`

gets the value of `d`

shifted two bits to the right. The `>>`

operator behaves differently depending upon the left operand is signed or not. If it is signed, the shifting is performed preserving the sign (bits entering the number from the left will have the same value as the original sign the number had before the shifting). If it is not, there will be zeroes entering from the left.

`d`

is unsigned, so the value `e`

gets is the result of shifting `d`

two bits to the right, entering zeroes from the left:

```
e = 0011 1111 1011 1111
```

Which is `0x3FBF`

.

Finally, values printed are `c,d,e`

:

`0xFEFF, 0xFEFF, 0x3FBF`

But you may see `0xFFFFFEFF`

as the first printed number. This is because `%x`

expects an `int`

, not a `short`

. The `4`

in `"%4x"`

means: *"use at least 4 digits to print the number, but if the amount of digits needed is more, use as much as needed"*. To print `0xFEFF`

as an `int`

(32-bit int actually), it must be promoted again, and as it's signed, this is done with sign-extension. So `0xFEFF`

becomes `0xFFFFFEFF`

, which needs 8 digits to be printed, so it does.

The second and third `%4x`

print unsigned values (`d`

and `e`

). These values are promoted to 32-bit ints, but this time, unsigned. So the second value is promoted to `0x0000FEFF`

and the third one, to `0x00003FBF`

. These two numbers don't actually need 8 digits to be printed, but 4, so it does so and you see only 4 digits for each number (try changing the two last `%4x`

by `%2x`

and you will see that the numbers are still printed with 4 digits)