Comment by Davidzheng
18 hours ago
but degradation from servers being overloaded would be the type of degradation this SHOULD measure no? Unless it's only intended for measuring their quietly distilling models (which they claim not to do? idk for certain)
Load just makes LLMs behave less deterministically and likely degrade. See: https://thinkingmachines.ai/blog/defeating-nondeterminism-in...
They don't have to be malicious operators in this case. It just happens.
> malicious
It doesn't have to be malicious. If my workflow is to send a prompt once and hopefully accept the result, then degradation matters a lot. If degradation is causing me to silently get worse code output on some of my commits it matters to me.
I care about -expected- performance when picking which model to use, not optimal benchmark performance.
Non-determinism isn’t the same as degradation.
The non-determinism means that even with a temperature of 0.0, you can’t expect the outputs to be the same across API calls.
In practice people tend to index to the best results they’ve experienced and view anything else as degradation. In practice it may just be randomness in either direction from the prompts. When you’re getting good results you assume it’s normal. When things feel off you think something abnormal is happening. Rerun the exact same prompts and context with temperature 0 and you might get a different result.
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this is about variance of daily statistics, so I think the suggestions are entirely appropriate in this context.
The question I have now after reading this paper (which was really insightful) is do the models really get worse under load, or do they just have a higher variance? It seems like the latter is what we should expect, not it getting worse, but absent load data we can't really know.
Explain this though. The code is deterministic, even if it relies on pseudo random number generation. It doesn't just happen, someone has to make a conscious decision to force a different code path (or model) if the system is loaded.
Its not deterministic. Any individual floating point mul/add is deterministic, but in a GPU these are all happening in parallel and the accumulation is in the order they happen to complete.
When you add A then B then C, you get a different answer than C then A then B, because floating point, approximation error, subnormals etc.
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Not deterministic. https://thinkingmachines.ai/blog/defeating-nondeterminism-in...
For all practical purposes any code reliant on the output of a PRNG is non-deterministic in all but the most pedantic senses... And if the LLM temperature isn't set to 0 LLMs are sampling from a distribution.
If you're going to call a PRNG deterministic then the outcome of a complicated concurrent system with no guaranteed ordering is going to be deterministic too!
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Floating point math isn't associative for operations that are associative in normal math.
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It takes a different code path for efficiency.
e.g
if (batch_size > 1024): kernel_x else: kernel_y
There's a million algorithms to make LLM inference more efficient as a tradeoff for performance, like using a smaller model, using quantized models, using speculative decoding with a more permissive rejection threshold, etc etc
It's very clearly a cost tradeoff that they control and that should be measured.
The primary (non malicious, non stupid) explanation given here is batching. But I think you would find looking at large-scale inference the batch sizes being ran on any given rig are fairly static - there is a sweet spot for any given model part ran individually between memory consumption and GPU utilization, and generally GPUs do badly at job parallelism.
I think the more likely explanation is again with the extremely heterogeneous compute platforms they run on.
That's why I'd love to get stats on load/hardware/location of where my inference is running. Looking at you Trainiuim.
noob question: why would increased demand result in decreased intelligence?
An operator at load capacity can either refuse requests, or move the knobs (quantization, thinking time) so requests process faster. Both of those things make customers unhappy, but only one is obvious.
This is intentional? I think delivering lower quality than what was advertised and benchmarked is borderline fraud, but YMMV.
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I'd wager that lower tok/s vs lower quality of output would be two very different knobs to turn.
It would happen if they quietly decide to serve up more aggressively distilled / quantised / smaller models when under load.
Or just reducing the reasoning tokens.
They advertise the Opus 4.5 model. Secretly substituting a cheaper one to save costs would be fraud.
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I've seen some issues with garbage tokens (seemed to come from a completely different session, mentioned code I've never seen before, repeated lines over and over) during high load, suspect anthropic have some threading bugs or race conditions in their caching/inference code that only happen during very high load
from what I understand this can come from the batching of requests.
So, a known bug?
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I've personally witnessed large variability in behaviour even within a given session -- which makes sense as there's nothing stopping Anthropic from shuttling your context/session around load balanced through many different servers, some of which might be quantized heavily to manage load and others not at all.
I don't know if they do this or not, but the nature of the API is such you could absolutely load balance this way. The context sent at each point is not I believe "sticky" to any server.
TLDR you could get a "stupid" response and then a "smart" response within a single session because of heterogeneous quantization / model behaviour in the cluster.
I've defended opus in the last weeks but the degradation is tangible. It feels like it degraded by a generation tbh.
it's just extremely variable