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With unsigned char you can store a number from 0 to 255

255(b10) = 11111111(b2)             <=    that's 1 byte

This will make it easy to preform operations like +,-,*...

Now how about:

255(b10) = 10101101(b2)

Following this method will make it possible to represent up to 399 using unsigned char?

399(b10) = 11111111(b2)

Can someone propose an algorithm to preform addition using the last method?

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It is very unclear what you are talking about. A char is a char and it has a definition which is based on bits. If you want a special datatype which is based on bits with three states, and then want to use that in a programming language, you first need to build the appropriate computer and compilers for it. –  Irfy Mar 6 '12 at 3:22
Are you trying to define your own datatype which will simply "store" a char in an array of "tri-state bits"? The only way you can do this is to use "bits" to represent "tri-state bits", and then use those to represent your own numbers. Why in the world would you want to do this? –  Irfy Mar 6 '12 at 3:23
representing big numbers –  Jonas Mar 6 '12 at 3:26
When you say 255(b10) = 10101101(b?), do you mean that 144 = 0b0000000, which is to say, that you're redefining a char to be 144-399 instead of 0-255? –  rob05c Mar 6 '12 at 3:28
Jonas, write down all the possible values between 00000000 and 11111111: 00000000, 00000001, 00000010, 00000011, etc. Count how many values you get. Assign one bit pattern to each successive natural number: 0, 1, 2, 3, etc. If you write down more than 256 values, you've either made a mistake, or you've made the discovery of the millennium. Nobody necessarily wants to stop at 255. It's just the laws of nature and mathematics that force us to. Look up the "pigeon-hole principle": You can't stuff 400 pigeons in only 256 holes. –  Rob Kennedy Mar 6 '12 at 3:44

4 Answers 4

up vote 5 down vote accepted

With eight bits there are only 256 possible value (28), no matter how you slice and dice it.

Your scheme to encode digits in a 2-3-3 form like:

255 = 10 101 101
399 = 11 111 111

ignores the fact that those three-bit sequences in there can only represent eight values (0-7), not ten (ie, that second one would be 377, not 399).

The trade-off is that this means you gain the numbers '25[6-7]' (2 values) '2[6-7][0-7]' (16 values) and '3[0-7][0-7]' (64 values) for a total of 82 values.

Your sacrifice for that gain is that you can no longer represent any numbers containing 8 or 9: '[8-9]' (2 values), '[1-7][8-9]' (14 values), '[8-9][0-9]' (20 values), '1[0-7][8-9]' (16 values), '1[8-9][0-9]' (20 values) or '2[0-4][8-9]' (10 values), for a total of 82 values.

The balance there (82 vs. 82) shows that there are still only 256 possible values for an eight-bit data type.

So your encoding scheme is based on a flawed premise, which makes the second part of your question (how to add them) irrelevant, I'm afraid.

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what was I thinking!! never stay up till 3AM again =) –  Jonas Mar 6 '12 at 3:44
+1 for deciphering his "encoding". –  Ilian Pinzon Mar 6 '12 at 4:06
and here I was hoping he simply wanted to represent 144-399 with 8 bits, so I could come up with some amusing-but-useless bit shifting arithmetic :( –  rob05c Mar 6 '12 at 4:07

A unsigned char type can only mathematically hold values between 0 and 255 as determined by the rule 2^n - 1 for the maximum unsigned value that the amount of bits n can represent. There is no way to "improve" a char range, you probably want to use an unsigned short which holds two bytes instead.

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You're mistaken.

In your scheme, 255 would be 010101101, which is 9 bits. The leading zero is important. I'm assuming here you're using something that looks like the octal representation. 3 bits/digit. Any other alternative means you cannot represent all the other digits.


9 in binary is 1001. So you can't use 3 bits per digit. You need to use 4 bits if you want to represent 8 and 9. Again, I'm trying to assume here that you're encoding each digit separately. So, 399 according to you would be: 001110011001 - 12 bits. By comparison, binary does 399 in 110001111 - 9 bits.

So binary is the most efficient, because encoding digits from 0 to 9 in your system means that the maximum number you can store without any information loss in 8 bits is 99 - 10011001 :)

One way to think of binary, is a path that is the result of a log search to find the number.

If you really want to condense the number of bits needed to represent a number, what you're really after is some sort of compression and not the way binary is done.

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What you want to do is mathematically impossible. You can only represent 256 discrete values with 8 boolean values.

To test this, make a chart of all possible values, in decimal and binary. I.e.

000 = 00000000
001 = 00000001
002 = 00000010
003 = 00000011
004 = 00000100


254 = 11111110
255 = 11111111

You will see that after 255, you need a ninth bit.

You can let 255 = 10101101, but if you work backwards from that, you will run out before you reach 0.

You seem to hope you can somehow use a different counting mechanism to store more values. This is not mathematically possible. See the Pidgeonhole Principle.

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