How many digits will be after converting from one numeral system to another

The main question: How many digits?

Let me explain. I have a number in binary system: 11000000 and in decimal is 192.

After converting to decimal, how many digits it will have (in dicimal)? In my example, it's 3 digits. But, it isn't a problem. I've searched over internet and found one algorithm for integral part and one for fractional part. I'm not quite understand them, but (I think) they works.

When converting from binary to octal, it's more easy: each 3 bits give you 1 digit in octal. Same for hex: each 4 bits = 1 hex digit.

But, I'm very curious, what to do, if I have a number in P numeral system and want to convert it to the Q numeral system? I know how to do it (I think, I know :)), but, 1st of all, I want to know how many digits in Q system it will take (u no, I must preallocate space).

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There was an error in my previous answer: look at the comment by Ben Schwehn. Sorry for the confusion, I found and explain the error I made in my previous answer below.

Please use the answer provided by Paul Tomblin. (rewritten to use P, Q and n)

``````Y = ln(P^n) / ln(Q)
Y = n * ln(P) / ln(Q)
``````

So Y (rounded up) is the number of characters you need in system Q to express the highest number you can encode in n characters in system P.

I have no answer (that wouldn't convert the number already and take up that many space in a temporary variable) to get the bare minimum for a given number 1000(bin) = 8(dec) while you would reserve 2 decimal positions using this formula.

If a temporary memory usage isn't a problem, you might cheat and use (Python):

``````len(str(int(otherBaseStr,P)))
``````

This will give you the number of decimals needed to convert a number in base P, cast as a string (otherBaseStr), into decimals.

If you have a number in P numeral system of length n Then you can calculate the highest number that is possible in n characters:

``````P^(n-1)
``````

To express this highest number in number system Q you need to use logarithms (because they are the inverse to exponentiation):

``````log((P^(n-1))/log(Q)
(n-1)*log(P) / log(Q)
``````

For example 11000000 in binary is 8 characters. To get it in Decimal you would need:

``````(8-1)*log(2) / log(10) = 2.1 digits (round up to 3)
``````

Reason it was wrong:

The highest number that is possible in n characters is

``````(P^n) - 1
``````

not

``````P^(n-1)
``````
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Looks like in the formula (n-1)*log(P) / log(Q) you use n to mean the number of characters when in base P. I am afraid that is not correct. Eg binary 11.1111.1111 -> n = 10 -> (10-1)*log(2) / log(10) = 2.7 -> round up -> 3. However 11.1111.1111 is 1023 in decimal, needing 4 decimals, not 3! –  Ben Schwehn Jun 7 '09 at 20:03
Your example at the end isn't accurate: 10000000 takes fewer decimal digits than 11111111. –  Nick Johnson Jun 7 '09 at 20:39
Binary 10000000 and 11111111 both take 3 decimal digits (128 and 255). –  Rick Regan Jun 7 '09 at 23:24
Ben Schwehn is right. I must have made a mistake in this answer! Beware! –  Jorisslob Jun 8 '09 at 6:05

Writing n in base b takes ceiling(log base b (n)) digits.

The ratio you noticed (octal/binary) is log base 8 (n) / log base 2 (n) = 3.

(From memory, will it stick?)

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Shoudn't this be ceiling(log base b (n+1)) digits. e.g log10(1000) = 3, but 1000 needs 4 digits –  Ben Schwehn Jun 7 '09 at 17:19
or floor(log base b(n)) + 1 which is equivalent –  Ben Schwehn Jun 7 '09 at 17:25

If you have a number that's X digits long in base B, then the maximum value that can be represented is B^X - 1. So if you want to know how many digits it might take in base C, then you have to find the number Y that C^Y - 1 is at least as big as B^X - 1. The way to do that is to take the logarithm in base C of B^X-1. And since the logarithm (log) of a number in base C is the same as the natural log (ln) of that number divided by the natural log of C, that becomes:

``````Y = ln((B^X)-1) / ln(C) + 1
``````

and since ln(B^X) is X * ln(B), and that's probably faster to calculate than ln(B^X-1) and close enough to the right answer, rewrite that as

``````Y = X * ln(B) / ln(C) + 1
``````

Covert that to your favourite language. Because we dropped the "-1", we might end up with one digit more than you need in some cases. But even better, you can pre-calculate ln(B)/ln(C) and just multiply it by new "X"s and the length of the number you are trying to convert changes.

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Note that your formula is correct, but the largest value that can be represented is actually 'B ^ X - 1' (X digits that are all B - 1). –  jerryjvl Jun 8 '09 at 4:48
@jerryjvl, you're right, but it's "close enough for government work". –  Paul Tomblin Jun 8 '09 at 15:18

Calculating the number of digit can be done using the formulas given by the other answers, however, it might actually be faster to allocate a buffer of maximum size first and then return the relevant part of that buffer instead of calculating a logarithm.

Note that the worst case for the buffer size happens when you convert to binary, which gives you a buffer size of 32 characters for 32-bit integers.

Converting a number to an arbitrary base could be done using the C# function below (The code would look very similar in other languages like C or Java):

``````public static string IntToString(int value, char[] baseChars)
{
// 32 is the worst cast buffer size for base 2 and int.MaxValue
int i = 32;
char[] buffer = new char[i];
int targetBase= baseChars.Length;

do
{
buffer[--i] = baseChars[value % targetBase];
value = value / targetBase;
}
while (value > 0);

char[] result = new char[32 - i];
Array.Copy(buffer, i, result, 0, 32 - i);

return new string(result);
}
``````
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I know your suggestion, but I'm interesting in minimizing memory usage ;-) So... –  AlannY Jun 7 '09 at 18:14
Yes, this is not the most memory-efficient way ;) –  Dirk Vollmar - 0xA3 Jun 7 '09 at 19:25

look at the logarithms base P and base Q. Round down to nearest integer.

The logarithm base P can be computed using your favorite base (10 or e): log_P(x) = log_10(x)/log_10(P)

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You need to compute the length of the fractional part separately.

For binary to decimal, there are as many decimal digits as there are bits. For example, binary 0.11001101001001 is decimal 0.80133056640625, both 14 digits after the radix point.

For decimal to binary, there are two cases. If the decimal fraction is dyadic, then there are as many bits as decimal digits (same as for binary to decimal above). If the fraction is not dyadic, then the number of bits is infinite.

(You can use my decimal/binary converter to experiment with this.)

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