I would love to see a comparison of the energy, water, hardware and time that goes into this compared to just you know doing maths on a cpu like a sane person.
Well, addition is built into the instruction set of any CPU, so it only takes one operation. On the other hand, one evaluation of a neural net involves several repeated matrix-vector multiplies followed by the application of a nonlinear "activation function". Matrix-vector multiply for a square matrix will take 2020=400 multiply operations and about 2019 addition operations for a 20-dimensional input. So we'll say maybe on the order of 1,000-10,000 times more operations depending on how many layers?
This is up to 200 digit numbers, so you'd actually need to use a custom implementation for representing the integers and software addition but then a naive algorithm would still be like... 200 operations. Could probably drastically reduce that as well.
200bit numbers only require like 10 registers. X86-64 has 16 general purpose registers so doing operations with 200 digit numbers should hypothetically only require 20 loads and 10 multiplies. So a well written bit of code could do it in under 100 ops (probably under 50). So assuming this LLM implementation is running on a big server, it's probably doing the same calculation, less accurately, with some exponentially larger amount of operations.
I would love to see a comparison of the energy, water, hardware and time that goes into this compared to just you know doing maths on a cpu like a sane person.
Capitalism truly is the most efficient system.
Well, addition is built into the instruction set of any CPU, so it only takes one operation. On the other hand, one evaluation of a neural net involves several repeated matrix-vector multiplies followed by the application of a nonlinear "activation function". Matrix-vector multiply for a square matrix will take 2020=400 multiply operations and about 2019 addition operations for a 20-dimensional input. So we'll say maybe on the order of 1,000-10,000 times more operations depending on how many layers?
This is up to 200 digit numbers, so you'd actually need to use a custom implementation for representing the integers and software addition but then a naive algorithm would still be like... 200 operations. Could probably drastically reduce that as well.
200bit numbers only require like 10 registers. X86-64 has 16 general purpose registers so doing operations with 200 digit numbers should hypothetically only require 20 loads and 10 multiplies. So a well written bit of code could do it in under 100 ops (probably under 50). So assuming this LLM implementation is running on a big server, it's probably doing the same calculation, less accurately, with some exponentially larger amount of operations.