It's been a while since we last talked about the one-reputation voting change. We are still pursuing this because stagnating participation on the network is a concern for all of us, and we want to think about ways to grow the active community on the network. We have, by design, utilized rep as a ...
@flawr It wastes a lot by having so many different NaNs, and two zeros. In a 64-bit FP it doesn’t matter much. In a 4-bit FP it becomes painfully obvious.
Many years ago U talked to someone at a conference that designed a different FP representation that is much more efficient. He showed how you can get so much better precision out of calculations and so on. I understand chip manufacturers don’t want to change their designs for this, but you’d think that if you introduce a 4-bit FP processor you’d look for a better FP representation?
Please do not do this. I get you need to make money but burning down the site that made buying it attractive is not the way to go about it. We have way too much work to do already and we do this work for free. I am about to say F it and just walk away pretty soon. I guess one user doesn't matter but I think others are in the same boat as I am. — NathanOliver32 mins ago
@flawr yeah, it looks like you could get more precision if you used signed integers… Does a NN even need NaN? The only thing you then have left is the overflow marker. A signed integer with saturation arithmetic would be much better.
The Open Compute Project specifies FP4 as sign, 1 mantissa and 2 exponent bits, no Inf or NaN. That gives you +/- [0, 0.5, 1, 1.5, 2, 3, 4, 6].
There’s also a “radix-4 FP4 format”: sign, 3 exponent, and 0 mantissa bits. That gives probably +/- [0, 0.25, 0.5, 1, 2, 4, 8, 16]? Limits depending on how the exponent offset is defined.
No, the radix-4 FP4 format uses 4 as a radix, not 2. Duh! It does +/- [0, 1/64, 1/16, 1/4, 1, 4, 16, 64]. Neat!
Still the minus 0 though… I prefer two’s complement.