# bitwise operation(s) to truncate the last two digits of a number

I have an integer `n`, and I'd like to truncate the last two digits of the number using only bitwise operations.

So, in regular arithmetic, it'd be as simple as `n /= 100`. But how would this be done with bitwise operation(s)?

Thanks,

(This is in c++, by the way)

: For instance, given the number `1234`, I'd like to get `12`. (truncate the last two digits `34`)

[Edit2:] Let me rephrase the question. I'm trying to understand why a particular function that's supposed to truncate the last two digits of a number kind of screws things up when given a negative input. (And I don't have the code for this function)

Here's the set of inputs and their corresponding outputs

-200901 ==> 186113241

-200801 ==> 186113242

-200701 ==> 186113243

-200601 ==> 186113244

-190001 ==> 186113350

-190101 ==> 186113349

-190201 ==> 186113348

-190301 ==> 186113347

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So are are you trying to turn the number 1234 into the number 12? Or trying to get the number 34 out of the number 1234? Or trying to turn 1234 into 1200? (I think you are trying to turn it into 12, but want to make sure). – SirPentor May 30 '12 at 19:14
1234 ===> 12 is what I'm trying to do – One Two Three May 30 '12 at 19:15
What's wrong with `n /= 100`? – Jeffrey May 30 '12 at 19:16
@OneTwoThree if it's java you always can decompile it and see source code – Nikita Beloglazov May 30 '12 at 19:46
These comments are getting long. Consider using the Stack Overflow Chat link to move the conversation to chat. When you start a chat, it automatically imports the comments to the chat so you don't lose any of the context. – jmort253 May 31 '12 at 4:24

Here you want to divide by a constant : 100

Following How can i multiply and divide with only using bit shifting and adding? that was given by Suraj Chandran in his comments,

You can re-interpret this as a multiplication by 1/100.

In base 2, 1/100 can be approximated to 1/2^7 * ( 1/2^0 + 1/2^2 + 1/2^6+ 1/2^7+ 1/2^8+ 1/2^9 + 1/2^11+ 1/2^13+ 1/2^14+ 1/2^15+ 1/2^20+ 1/2^22 + 1/2^26 + 1/2^27 + 1/2^28 1/2^29)

so you have and approximation with (n >> 0 + n >> 2 + n >> 6 + n >> 7 + n >> 8 + n >> 9 + n >> 11 + n >> 13 + n >> 14 + n >> 15 + n >> 20 + n >> 22 + n >> 26 + n >> 27 + n >> 28 + n >> 29) >> 7

Is this more or less what you have in your legacy code ?

I wouldn't dare saying that this will always give you the correct answer as I have done no scrutiny on the effects of the approximations here and there may very well be rounding issues in some cases.

In java code that would be

remaining = (( n>>0 ) + (n >> 2) + (n >> 6) + (n >> 7) + (n >> 8) + (n >> 9) + (n >> 11) + (n >> 13) + (n >> 14) + (n >> 15) + (n >> 20) + (n >> 22) + (n >> 26) + (n >> 27) + (n >> 28) + (n >> 29)) >> 7;

I coulnd't find a way to replace the additions by bitwise operations + could not reproduce the results you have with your negative values

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I don't know. Really. I don't have access to the code. But if this'd produce the same output for the negative cases I listed, then I guess you're right~ :) – One Two Three May 30 '12 at 20:26
Well, sorry, just to clarify. So this in Java code would be: `n = n >> 7 ^ n >> 9 ^ n >> 13 ^ n >> 14 ^ n >> 15 ^ n >> 16 ^n >> 18 ^ n >> 20 ^ n >> 21 ^ n >> 22 ^ n >> 27 ^ n >> 29;` ? I tried that and always got 1976 as the output no matter what the value of n was initialized to – One Two Three May 30 '12 at 20:28
let me check this – Jerome WAGNER May 30 '12 at 20:33
Did you figure it out yet? – One Two Three May 30 '12 at 20:45
modified my answer with a java example. Still looking into xor and your negative corner cases – Jerome WAGNER May 30 '12 at 21:00

Ok, another approach.

``````1234 : 100 = 12, remainder 34
``````

Now in binary, I hope I didn't mess it up:

`````` 100 1101 0010 : 110 0100 = 1100 Result
- 11 0010 0
-----------
1 1011 00
-1 1001 00
----------
0010 001
-       0
---------
010 0010
-       0
---------
10 0010 remaining
``````

Have fun converting that to an algorithm. It will be slow as hell compared to `x /= 100`, no matter how you do it.

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