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With Single precision (32 bits): the bits division goes like this :

enter image description here

So we have 23 bits of mantissa/Significand .

So we can represent 2^23 numbers (via 23 bits ) : which is 8388608 --> which is 7 digit long.


I was reading that the mantissa is normalized (the leading digit in the mantissa will always be a 1) - so the pattern is actually 1.mmm and only the mmm is represented in the mantissa.

for example : look here :

enter image description here

0.75 is represented but it's actually 1.75

Question #1

So basically it adds 1 more precision ?

If so then we have 8 Significand !

So why does msdn says : 7 ?

enter image description here

Question #2

In double there are 52 bits for mantissa. (0..51)

If I add 1 for the normalized mantissa so its 2^53 possibilites which is : 9007199254740992 ( 16 digits)

and MS does say : 15-16 :

enter image description here

Why is this inconsistency ? am I missing something ?

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up vote 4 down vote accepted

It doesn't add one more decimal digit - just a single binary digit. So instead of 23 bits, you have 24 bits. This is handy, because the only number you can't represent as starting with a one is zero, and that's a special value.

In short, you're not looking at 2 ^ 24 (that would be a decimal number, base-10) - you're looking at 2 ^ (-24). That's the most important difference between float-double and decimal. decimal is what you imagine floats to be, ie. a simple exponent-shifted, base-10 number. float and double aren't that.

Now, decimal digits versus binary digits is a tricky matter. You're mistaken in your understanding that the precision has anything to do with the 2 ^ 24 figure - that would only be true if you were talking about e.g. the decimal type, which actually stores decimal values as decimal point offsets of a normal (huge-ass) integer.

Just like 1 / 3 cannot be written in decimal (0.333333...), many simple decimal numbers can't be represented in a float precisely (0.2 is the typical example). decimal doesn't have a problem with that - it's just 2 shifted one digit to the right, easy peasy. For floats, however, you have to represent this value as a sum of negative powers of two - 0.5, 0.25, 0.125 ... The same would apply in the opposite direction if 2 wasn't a factor of 10 - every finite binary "decimal" can be represented with finite precision in decimal.

Now, in fact, float can easily represent a number with 24 decimal digits - it just has to be 2 ^ (-24) - a number you're not going to encounter in your usual day job, and a weird number in decimal. So where does the 7 (actually more like 7.22...) come from? Simple, just do a decimal logarithm of 2 ^ (-24).

The fact that it seems that 0.2 can be represented "exactly" in a float is simply because everytime you e.g. convert it to a string, you're rounding. So, even though the number isn't 0.2 exactly, it ends up that way when you convert it to a decimal number.

All this means that when you need decimal precision, you want to use decimal, as simple as that. This is not because it's a better base for calculations, it's simply because humans use it, and they will not be happy if your application gives different results from what they calculate on a piece of paper - especially when dealing with money. Accountants are very focused on having everything correct to the least significant digit.

Floats are used where it's not about decimal precision, but rather about generally having some sort of precision - this makes them well suited for physics calculations and similar, because you don't actually care about having the number come up the same in decimal - you're working with a given precision, and you're going to get that - 24 significant binary "decimals".

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it doesn't matter - it's a digit. I already know that decimal is decimal floating point vs float /double which is binary floating point. but still - both represents values. 95% of your answer explain not related info ( 0.333 , decimal vs float , minus at power , humans read decimal..... ). 2^24 vs 2^-24 , it doesn't matter - the job of the mantissa is to provide significant numbers. – Royi Namir Apr 22 '14 at 7:41
@RoyiNamir The job of the mantissa in a float is to provide significant binary digits. 1.1111111f.ToString("f10") will give you "1.111111" - the "guaranteed" 7 decimal digits. However, 1.1920928955078125.ToString("f20") will give you 17 decimal digits. Your question makes it pretty clear you don't understand the difference between decimal and float (So we can represent 2^23 numbers (via 23 bits ) : which is 8388608 --> which is 7 digit long.). – Luaan Apr 22 '14 at 7:47
with 23 bits I can represent max value : 2^23 - 1 - it doesnt matter where i put the dot. that's the exponent job. anyway - can you go to chat ?… – Royi Namir Apr 22 '14 at 8:07

The implied leading 1 adds one more binary digit of precision, not decimal.

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