# Choosing values for constants

One thing I've never really understood is why in many libraries, constants are defined like this:

``````public static final int DM_FILL_BACKGROUND = 0x2;
public static final int DM_FILL_PREVIOUS = 0x3;
public static final int TRANSPARENCY_MASK = 1 << 1;
public static final int TRANSPARENCY_PIXEL = 1 << 2;
``````

What's up with the 0x and << stuff? Why aren't people just using ordinary integer values?

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In what way is `0x2` not an “ordinary integer value”? It is completely normal. As for `1 << 1`, of course it’s an expression rather than a single value, but its result is still an “ordinary integer value”. –  Timwi Aug 21 '10 at 6:09

The bit shifting of `1` is usually for situations where you have non-exclusive values that you want to store.

For example, say you want to be able to draw lines on any side of a box. You define:

``````LEFT_SIDE   = 1 << 0  # binary 0001 (1)
RIGHT_SIDE  = 1 << 1  # binary 0010 (2)
TOP_SIDE    = 1 << 2  # binary 0100 (4)
BOTTOM_SIDE = 1 << 3  # binary 1000 (8)
----
0111 (7) = LEFT_SIDE | RIGHT_SIDE | TOP_SIDE
``````

Then you can combine them for multiple sides:

``````DrawBox (LEFT_SIDE | RIGHT_SIDE | TOP_SIDE) # Don't draw line on bottom.
``````

The fact that they're using totally different bits means that they're independent of each other. By `OR`ing them you get `1 | 2 | 4` which is equal to `7` and you can detect each individual bit with other boolean operations (see here and here for an explanation of these).

If they were defined as 1, 2, 3 and 4 then you'd probably either have to make one call for each side or you'd have to pass four different parameters, one per side. Otherwise you couldn't tell the difference between `LEFT and RIGHT` (`1 + 2 = 3`) and `TOP` (`3`), since both of them would be the same value (with a simple addition operation).

The `0x` stuff is just hexadecimal numbers which are easier to see as binary bitmasks (each hexadecimal digit corresponds exactly with four binary digits. You'll tend to see patterns like `0x01`, `0x02`, `0x04`, `0x08`, `0x10`, `0x20` and so on, since they're the equivalent of a single `1` bit moving towards the most significant bit position - those values are equivalent to binary `00000001`, `00000010`, `00000100`, `00001000`, `00010000`, `00100000` and so on.

Aside: Once you get used to hex, you rarely have to worry about the `1 << n` stuff. You can instantly recognise `0x4000` as binary `0100 0000 0000 0000`. That's less obvious if you see the value 16384 in the code although some of us even recognise that :-)

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Well said. I like the 1 << BitNo format for flags because you know which bit it is by looking at the definition. I have a generic snippet that is defined as <FlagsAttribute()> _ Public Enum _Flag As Integer with 32 predefined flags. –  dbasnett Aug 21 '10 at 14:03
Regarding `<<` stuff: this in my preferred way.
When I need to define the constant with 1 in the bit 2 position, and 0 in all other bits, I can define it as `4`, `0x4` or `1<<2`. `1<<2` is more readable, to my opinion, and explains exactly the purpose of this constant.
`1<<2` may well be more readable. It's certainly more accurate, given that the value is `4`, not `7` :-) –  paxdiablo Aug 21 '10 at 6:14