When I use floating point numbers, do I lose precision if I limit the range?

I tried to read on the IEEE standard about floating point implementation but it is quite advanced for me and I don't program for a living.

This is something I wondered.

Suppose I have a float variable between 0 and N and I will scale it up when needed, but intermediary calculations will be done in this unnormalized value.

Logically, the range `[0.0, 1.0]` will be enough. But if I limit my numbers between 0 and 1, do I lose precision some way? Do I gain anything if I use `[0, 10.0]`, or `[0, 1000000.0]`?

Thank you.

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How do you propose to "limit" your values? –  Hot Licks Jun 6 '12 at 2:01
IEEE floating point numbers already work on that principle internally. The mantissa is between 1.0b and 1.11..1b with an exponent to handle the "scale" (so to speak). –  user7116 Jun 6 '12 at 2:02

your idea is a good one, but you don't save anything because, in a sense, floating point numbers are designed to do this for you.

internally, a float has two parts, called mantissa and exponent. the mantissa is equivalent to your range, and the exponent is the scaling needed to get it to the "real" value.

any number you give is normalised to a range like [1-9.999...] plus a power of 10 multiplier. so you get the precision of the mantissa for almost all values (the only exceptions are when you get to the extremes of the exponent - these are called "denormalized numbers" (or "subnormal"), but are extremely small (close to zero) or large, and not something you need worry about, normally).

so whether you enter 1.23 or 12.3 or 123, it's stored as 1.23 (the mantissa) plus a factor (1, 10 or 100, the exponent) internally.

actually, that's not quite true, because it uses powers of 2 (binary) rather than powers of ten (decimal) (see the comment from sixlettervariable), but it's the same general idea.

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The mantissa is between 1.0b and 1.1111111111111111111111111b (~1.9999998) for Single precision normalized numbers and 0.00000000000000000000001b and 0.11111111111111111111111b for single precision denormalized numbers. –  user7116 Jun 6 '12 at 2:04
yep and i've fixed my decimal mantissa range, which was wrong. binary 1.111111... is "the same idea" as 9.99999... in that it's as close as you can get to the next scaling factor (2 in binary, 10 in decimal) –  andrew cooke Jun 6 '12 at 2:06
Interestingly enough IEEE floats don't store the leading 1 as it is assumed unless the exponent is 0 and the mantissa is non-zero. Hence denormal values. –  user7116 Jun 6 '12 at 2:07
"floating point numbers are designed to do this for you." Thank you this was what I suspected and what I was looking for. Or programming would be a lot more complicated. –  floatyourboat Jun 6 '12 at 2:13