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# leading bit in binary32 float(IEEE)

the background for question - specifications of binary32 float

My question is about assumption, that first (leading) bit is always 1, so we do not need to store it. That's true, but it has another role in number.. we know, where it starts. So after extracting that first non-zero bit, we don't know where number starts, unless there's another non-zero bit right afterwards.

In that wiki article, they use number (1.100011)binary. So fraction is 100011 and we can build up that number back without problem. However, what about (1.000011)binary? we extract 1 and we're left with 000011, and as we can't store leading zeroes inside zero-initialized bitfield, we get 11. But what happens, when we want to build it back? we get 1.11 and that's wrong.

So how we can freely extract that leading bit in arbitrary number?

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The number of leading zeroes is implied by the size of the bitfield. – Raymond Chen Dec 9 '11 at 20:41
imagine zero filled bit field 00000000... copy there 000011.. you get 00000011... no shifts ;) And you still don't know how much zeroes there were in first place – Raven Dec 9 '11 at 20:52
The mantissa is stored in a 23-bit field. The value you have is 11. That is only 2 bits. Therefore there must be 21 leading 0 bits. Remember, it's a fixed-size field. There are 23 bits being stored. If the value you want to store is only two bits, then the other bits are zero. Those are the leading zero bits. – Raymond Chen Dec 9 '11 at 21:15
Are you forgetting about the exponent? – David Heffernan Dec 9 '11 at 22:06
You would never put the number 1000011 into the mantissa of a floating point value because it is not normalized. (There must be a single 1 before the binary point.) If the mantissa is 1.00011, then that is encoded as [1.]00011000000000000000000 where the leading 1 and binary point are not actually stored. When reading back, the value is 00011000000000000000000. The implied leading 1 and binary point are restored, yielding 1.00011000000000000000000 as desired. – Raymond Chen Dec 10 '11 at 0:47

## 1 Answer

However, what about (1.000011)binary? we extract 1 and we're left with 000011, and as we can't store leading zeroes inside zero-initialized bitfield, we get 11.

In fact you do store leading zeros. What is stored is 000011 and when the 1 is added back in you are back where you started. Storing the leading zeros (after the leading 1 has been removed) is what makes it work.

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I don't know why you're getting upvotes.. You can't store 000011 inside bitfield.. you can store just 11 (or anything else - 110,1100 - but it must start with 1). You can't store leading zeros. What's the difference between set to leading zero and initialized to zero? There's only difference if 0 is after 1. The only possible assumption is that we use full size of bitfield but then, how you store 7 digit number with leading 0 in, for example 10 digit bitfield? Thanks – Raven Dec 9 '11 at 22:04
I don't know what you mean by bitfields. There are just 23 bits set aside for the mantissa. Each one is well identified and ordered. They can all be zero, or all one, or any other pattern. – David Heffernan Dec 9 '11 at 22:05
@Raven: "I don't know why you're getting upvotes." Because David knows what he's talking about, and you don't. Why don't you look at the binary representations of a few floating-point numbers, and see for yourself? – TonyK Dec 9 '11 at 22:13
"bitfield = ordered array of bits.. in c++ it's std::vector<bool>". I understand how bitfields can look like.. last shot. Imagine binary numbers 10011 and 111, and 2 bitfields of 4 bits(0000).. So, according to IEEE we can extract leading 1. We get 0011 and 11 (in fact we can't get 0011 because it's instantly 11, but that's what you write). Now, store it in bitfield: first number looks like 0011, second 0011. They are exactly same! But 10011 and 111 aren't the same. – Raven Dec 9 '11 at 22:14
@TonyK I just did.. ad I found what I've expected... but it looks like I had my idea of how float numbers work quite wrong.. anyway this seems like good answer at last – Raven Dec 9 '11 at 22:57