Really fascinating how this works; it's basically context-aware decoding. From the paper:

> Code interleaves fork positions, where several continuations are genuinely plausible and may correspond to different solution approaches, with lock positions, where syntax and semantics leave little ambiguity but a low-probability distractor tail still remains… The best global decoding setting is therefore necessarily a compromise; we call this tension the precision-exploration conflict.

In other words, just like us, the model needs to shift from "exploration" in "fork" mode (divergent thinking to produce a creative solution) to "precision" in "lock" mode (producing syntactically correct code).

What this paper shows is that their simple technique (SSD) can improve the ranking of optimal tokens in both lock and fork positions, meaning the model is more likely to explore when it should be exploring, and more likely to be precise when it needs to be.

I love that we're still learning the emergent properties of LLMs!

Another example of the mindf@#$ these systems are: I was doing some fine tuning to a small model, take data fields and make a sentence out of it. I was running into mode collapse (basically when the AI simplifies too much and always output the same thing).

I got unstuck by randomizing the field order for each row?!? At training, and now I'm thinking I should do the same at inference time...