Discrete distribution of numbers in binary?

I heard somewhere that there are more numbers between .9 and 1 than between 0 and .1, when representing them as discrete finite bits (let's assume 32-bit floats for sake of argument). Can someone explain to me why this is the case and give an example of a number between 0 and .1 that can't be represented but its corresponding number between .9 and 1 (found by mathematically adding .9) can be represented by a float?

(This is relevant to rngs because they may be biased toward different ranges.)

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The basic reason why your reasoning is wrong is that adding `0.9` is not an invertable operation. However you have it backwards. There are more floating point numbers between 0.0 and 0.1 than between 0.9 and 1.0.

As for how to make an unbiased floating point RNG, you should initially generate numbers in the range [1.0,2.0) then translate and scale the result accordingly. This works because the interval [1.0,2.0) has uniform precision across the entire range (the exponent is the same for all numbers in this range).

If you're working with IEEE single precision, which has the form:

``````s eeeeeeee mmmmmmmmmmmmmmmmmmmmmmm
``````

Just fix the sign and exponent bits, and use a uniform random PRNG for integers to fill the mantissa bits. The same would apply to double.

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