# Exponent in IEEE 754

Why exponent in float is displaced by 127?
Well, the real question is : What is the advantage of such notation in comparison to 2's complement notation?

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Since the exponent as stored is unsigned, it is possible to use integer instructions to compare floating point values. the the entire floating point value can be treated as a signed magnitude integer value for purposes of comparison (not twos-compliment).

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Wouldn't it worked the same if we used 2's complement notation? –  Tomek Tarczynski Feb 14 '10 at 22:04
This isn't quite true. Two negative floating-point values do not compare properly as signed integers. All the other cases work properly. –  Stephen Canon Feb 15 '10 at 5:04
@Stephen: Yes that's true, floating point numbers can be compared as signed magnitude integers, not twos compliment integers, the sign bit requires some special case handling. –  John Knoeller Feb 15 '10 at 5:49
"the entire floating point value can be treated as a signed integer value" is definitely untrue. Consider changing the answer? –  Potatoswatter Feb 15 '10 at 23:46
@Potatoswatter: I changed/clarified the answer –  John Knoeller Feb 16 '10 at 0:19

Note that there is a slight difference in the representable range for the exponent, between biased and 2's complement. The IEEE standard supports exponents in the range of (-127 to +128), while if it was 2's complement, it would be (-128 to +127). I don't really know the reason why the standard chooses the bias form, but maybe the committee members thought it would be more useful to allow extremely large numbers, rather than extremely small numbers.

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The IEEE standard actually supports single-precision exponents from -126 to +127; the exponent encodings that would ordinarily map to -127 and +128 have special meanings (zeros and denormals, infinities and NaNs). –  Stephen Canon Feb 16 '10 at 17:16

@Stephen Canon, in response to ysap's answer (sorry, this should have been a follow up comment to my answer, but the original answer was entered as an unregistered user, so I cannot really comment it yet).

Stephen, obviously you are right, the exponent range I mentioned is incorrect, but the spirit of the answer still applies. Assuming that if it was 2's complement instead of biased value, and assuming that the 0x00 and 0xFF values would still be special values, then the biased exponents allow for (2x) bigger numbers than the 2's complement exponents.

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Oh, I agree entirely. Here, have some rep so you can comment =) –  Stephen Canon Feb 19 '10 at 23:47

The exponent in a 32-bit float consists of 8 bits, but without a sign bit. So the range is effectively [0;255]. In order to represent numbers < 2^0, that range is shifted by 127, becoming [-127;128].

That way, very small numbers can be represented very precisely. With a [0;255] range, small numbers would have to be represented as `2^0 * 0.mantissa` with lots of zeroes in the mantissa. But with a [-127;128] range, small numbers are more precise because they can be represented as `2^-126 * 0.mantissa` (with less unnecessary zeroes in the mantissa). Hope you get the point.

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I believe he's asking why an offset is used instead of, say, 2's complement. –  Anon. Feb 14 '10 at 21:57
Sorry, didn't know what U2 meant. –  AndiDog Feb 14 '10 at 22:14
Hmmm I found somewhere the name 'U2' notation, and I thought that is is some abbreviation :| Now as I google it, I think that it was some kind of mistake. Obvouisly I was thinking about 2's complement notation. –  Tomek Tarczynski Feb 14 '10 at 22:29
Just to correct some misinformation: it is `2^n * 1.mantissa`, the 1 infront of the fraction is implicitly stored.
The exponents -127 and 128 (binary 0 and 255) are special ranges for small numbers (including +-0) and infinite/NaN. For binary 1, the formular is `+- 2^-126 * 1.mantissa`, but for binary 0, the formula is `+- 2^-126 * 0.mantissa`, resulting in a coherent range of numbers. I guess by "cutoff" you mean the smallest representable (non-zero) number? - That would be the denormalized number with the last bit of the mantissa set = `2^-126 * 0.mantissa` = `2^-126 * 2^-23`. I can't see anything incorrect in my answer. –  AndiDog Feb 16 '10 at 19:00