# Do bitwise values have to be exponential?

In all bitwise examples, I see values being incremented exponentially (1, 2, 4, 8, etc). However, in the following Enum, I use 1, 2, 3, 4 (and pardon the VB, if you will):

``````<Flags()>
Enum BitWiseTest
One = 1
Two = 2
Three = 3
Four = 4
End Enum
``````

To my surprise, the following code works:

``````Dim TestBits As BitWiseTest

TestBits = TestBits Or BitWiseTest.One
TestBits = TestBits Or BitWiseTest.Two
TestBits = TestBits Or BitWiseTest.Three
TestBits = TestBits Or BitWiseTest.Four

Dim BitToRemove As BitWiseTest

BitToRemove = BitWiseTest.Two

TestBits = Not BitToRemove

Console.WriteLine(TestBits And BitToRemove)
``````

Commenting out the line `TestBits = Not BitToRemove` will show you that not removing the bit will show you that it's still on. Channging `BitToRemove = BitWiseTest.Two` to use another enum value will show you that it works for other bits, as well.

It appears to be working flawlessly, so what's up with the exponential incrementation of values that I am seeing everywhere regarding bitwise?

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Have you checked what happens if you set both `One` and `Two`? Or when you set `Three` and unset `One`? – CodesInChaos Feb 21 '13 at 14:56
Ah, setting Three and unsetting One brokeded it! I learned something with bitwise today. – oscilatingcretin Feb 21 '13 at 15:05

There are generally two kinds of enums. For an enum:

1. One of the values is used.
2. A combination of values is used.

### One of the values is used

In this case you can just number the enum members any way you like. You can even have two members with the same value if they mean the same. For example:

``````Enum Comparison
None = 0
CaseSensitive = 1
IgnoreCase = 2

Default = 1
End Enum
``````

### A combination of values is used

A value is now boolean: it is either on (used, specified) or off (not used or specified). This converts nicely to bits, which are 1 (on) or 0 (off). To be able to distinguish the values from one another, you should use powers of two. Then there is for any particular bit only one value that can set that bit on or off.

``````<Flags()>
Enum NumberStyles
None = 0                    ' Binary:          0
AllowLeadingWhite = 1       ' Binary:          1
AllowTrailingWhite = 2      ' Binary:         10
AllowLeadingSign = 4        ' Binary:        100
AllowTrailingSign = 8       ' Binary:       1000
AllowParentheses = 16       ' Binary:      10000
AllowDecimalPoint = 32      ' Binary:     100000
AllowThousands = 64         ' Binary:    1000000
AllowExponent = 128         ' Binary:   10000000
AllowCurrencySymbol = 256   ' Binary:  100000000
AllowHexSpecifier = 512     ' Binary: 1000000000
End Enum
``````

Now you can combine two values to get a new one, and you can distinguish the values:

``````Dim testBits As NumberStyles
testBits = NumberStyles.AllowHexSpecifier _
Or NumberStyles.AllowTrailingWhite _
Or NumberStyles.AllowLeadingWhite       ' Binary: 1000000011

' If (1000000011 And 1000000000) <> 0 Then
If testBits.HasFlag(NumberStyles.AllowHexSpecifier) Then
' Do something
End If
``````

And you can add those combinations to the enum too, if it makes sense:

``````<Flags()>
Enum NumberStyles
' ...
Integer = 7                 ' Binary:        111
Number = 111                ' Binary:    1101111
Float = 167                 ' Binary:   10100111
Currency = 383              ' Binary:  101111111
HexNumber = 515             ' Binary: 1000000011
End Enum
``````

Look at the binary values of your example. Values `One`, `Two` and `Four` are powers of two, but `Three` is not. If I extend your example, maybe you can see the problem:

``````<Flags()>
Enum BitWiseTest
One = 1     ' Binary:    1
Two = 2     ' Binary:   10
Three = 3   ' Binary:   11
Four = 4    ' Binary:  100
Five = 5    ' Binary:  101
Six = 6     ' Binary:  110
Seven = 7   ' Binary:  111
End Enum
``````

Now, doing `Six Or Three = Seven`, which is usually not what you want. Also `value And Two` is `True` when `value` is `Three`, `Six` or `Seven`, which is also probably now what you want. The reason is that the one bit that is set in `Two` is also present in `Three`, `Six` and `Seven` due to how you chose the values.

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They don't have to be exponential, there's no language limitation for that.

For most cases it makes sense to define them exponential so they are independent from one-another. In a very few cases you may benefit from combining the exponential flag values with predefined state values:

``````public enum KitchenState{
NothingHappening = 0,

PanOnStove = 1,
StoveOn = 2,
Preheating = 3,

EggsInPan = 4,
EggsCooking = 7,
}
``````

In this case Preheating and EggsCooking are states and PanOnStove, StoveOn and EggsInPan are flags. This is mostly a gimmick but it can come handy on occasion

-

It appears to be working flawlessly

It depends on what you mean by "flawlessly".

Do you really want `BitWiseTest.One` Or `BitwiseTest.Two` to equal `BitwiseTest.Three`? That's what you'll get at the moment, which isn't normally ideal... Typically you want the flags to be independent, which means that they need to be represented by independent bits in the binary representation - and that's precisely what you get by using values of 1, 2, 4, 8, 16 etc.

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As demonstrated by CodesInChaos' answer, it appears that it's not so much a matter of whether or not it's ideal as it is a matter of causing bitwise operations so simply not work properly. Setting three and removing one then checking for three resulted in two when I would have expected it to result in three. – oscilatingcretin Feb 21 '13 at 15:20
@oscilatingcretin the bitwise operations there are still working properly, you just made them do something that doesn't match your intentions – harold Feb 21 '13 at 15:23
@oscilatingcretin: "ideal" was used somewhat sarcastically here - although there are certainly cases where you do want combinations. Look at `NumberStyles.HexNumber` for example. Bitwise operations "work properly" - in that they behave as expected when you understand what they do. But you do need to understand them first... – Jon Skeet Feb 21 '13 at 15:31