Lex Fridman Podcast - #452 – Dario Amodei: Anthropic CEO on Claude, AGI & the Future of AI & Humanity
Episode Date: November 11, 2024Dario Amodei is the CEO of Anthropic, the company that created Claude. Amanda Askell is an AI researcher working on Claude's character and personality. Chris Olah is an AI researcher working on mechan...istic interpretability. Thank you for listening ❤ Check out our sponsors: https://lexfridman.com/sponsors/ep452-sc See below for timestamps, transcript, and to give feedback, submit questions, contact Lex, etc. Transcript: https://lexfridman.com/dario-amodei-transcript CONTACT LEX: Feedback - give feedback to Lex: https://lexfridman.com/survey AMA - submit questions, videos or call-in: https://lexfridman.com/ama Hiring - join our team: https://lexfridman.com/hiring Other - other ways to get in touch: https://lexfridman.com/contact EPISODE LINKS: Claude: https://claude.ai Anthropic's X: https://x.com/AnthropicAI Anthropic's Website: https://anthropic.com Dario's X: https://x.com/DarioAmodei Dario's Website: https://darioamodei.com Machines of Loving Grace (Essay): https://darioamodei.com/machines-of-loving-grace Chris's X: https://x.com/ch402 Chris's Blog: https://colah.github.io Amanda's X: https://x.com/AmandaAskell Amanda's Website: https://askell.io SPONSORS: To support this podcast, check out our sponsors & get discounts: Encord: AI tooling for annotation & data management. Go to https://encord.com/lex Notion: Note-taking and team collaboration. Go to https://notion.com/lex Shopify: Sell stuff online. Go to https://shopify.com/lex BetterHelp: Online therapy and counseling. Go to https://betterhelp.com/lex LMNT: Zero-sugar electrolyte drink mix. Go to https://drinkLMNT.com/lex OUTLINE: (00:00) - Introduction (10:19) - Scaling laws (19:25) - Limits of LLM scaling (27:51) - Competition with OpenAI, Google, xAI, Meta (33:14) - Claude (36:50) - Opus 3.5 (41:36) - Sonnet 3.5 (44:56) - Claude 4.0 (49:07) - Criticism of Claude (1:01:54) - AI Safety Levels (1:12:42) - ASL-3 and ASL-4 (1:16:46) - Computer use (1:26:41) - Government regulation of AI (1:45:30) - Hiring a great team (1:54:19) - Post-training (1:59:45) - Constitutional AI (2:05:11) - Machines of Loving Grace (2:24:17) - AGI timeline (2:36:52) - Programming (2:43:52) - Meaning of life (2:49:58) - Amanda Askell - Philosophy (2:52:26) - Programming advice for non-technical people (2:56:15) - Talking to Claude (3:12:47) - Prompt engineering (3:21:21) - Post-training (3:26:00) - Constitutional AI (3:30:53) - System prompts (3:37:00) - Is Claude getting dumber? (3:49:02) - Character training (3:50:01) - Nature of truth (3:54:38) - Optimal rate of failure (4:01:49) - AI consciousness (4:16:20) - AGI (4:24:58) - Chris Olah - Mechanistic Interpretability (4:29:49) - Features, Circuits, Universality (4:47:23) - Superposition (4:58:22) - Monosemanticity (5:05:14) - Scaling Monosemanticity (5:14:02) - Macroscopic behavior of neural networks (5:18:56) - Beauty of neural networks
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The following is a conversation with Dario Amadei, CEO of Anthropic, the company that
created Claude that is currently and often at the top of most LLM benchmark leaderboards.
On top of that, Dario and the Anthropic team have been outspoken advocates for taking the topic of
AI safety very seriously, and they have continued to publish a lot of fascinating AI research on this and other
topics.
I'm also joined afterwards by two other brilliant people from Anthropic.
First, Amanda Askell, who is a researcher working on alignment and fine-tuning of Claude,
including the design of Claude's character and personality. A few folks told me she has probably talked with Claude
more than any human at Anthropic.
So she was definitely a fascinating person to talk to
about prompt engineering and practical advice
on how to get the best out of Claude.
After that, Chris Ola stopped by for a chat.
He's one of the pioneers of the field of
mechanistic interpretability, which is an exciting set of efforts that aims to
reverse engineer neural networks to figure out what's going on inside,
inferring behaviors from neural activation patterns inside the network.
This is a very promising approach for keeping future super intelligent AI systems safe.
For example, by detecting from the activations when the model is trying to deceive the human it is talking to.
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We talk a little bit about public benchmarks
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And now, dear friends, here's Dario Amadei. Let's start with a big idea of scaling laws
and the scaling hypothesis.
What is it?
What is its history?
And where do we stand today?
So I can only describe it as it, you know,
as a scale of the scale of the scale of the scale of the scale
of the scale of the scale of the scale of the scale of the scale
of the scale of the scale of the scale of the scale of the scale
of the scale of the scale of the idea of scaling laws and the scaling hypothesis. What is it? What is its history and where do we stand today?
So I can only describe it as it relates
to kind of my own experience,
but I've been in the AI field for about 10 years.
And it was something I noticed very early on.
So I first joined the AI world when I was working
at Baidu with Andrew Ng in late 2014,
which is almost exactly 10 years ago now.
And the first thing we worked on
was speech recognition systems.
And in those days, I think deep learning was a new thing.
It had made lots of progress,
but everyone was always saying,
we don't have the algorithms we need to succeed.
You know, we're only matching a tiny, tiny fraction.
There's so much we need to kind of discover algorithmically.
We haven't found the picture of how to match the human brain.
And when, you know, in some ways it was fortunate.
I was kind of, you know,
you can have almost beginner's luck, right?
I was like a newcomer to the field.
And, you know, I looked at the neural net
that we were using for speech,
the recurrent neural networks.
And I said, I don't know, what if you make them bigger and give them more layers? And what if you scale up
the data along with this, right? I just saw these as like independent dials that you could turn.
And I noticed that the model started to do better and better as you gave them more data,
as you made the models larger, as you trained them for longer. And I didn't measure things precisely in those days,
but along with colleagues,
we very much got the informal sense that the more data
and the more compute and the more training
you put into these models, the better they perform.
And so initially my thinking was,
hey, maybe that is just true
for speech recognition systems, right?
Maybe that's just one particular quirk, one particular area.
I think it wasn't until 2017 when I first saw the results from GPT-1 that it clicked
for me that language is probably the area in which we can do this.
We can get trillions of words of language data.
We can train on them.
And the models we were trained in those days were tiny.
You could train them on one to eight GPUs,
whereas now we train jobs on tens of thousands,
soon going to hundreds of thousands of GPUs.
And so when I saw those two things together,
and there were a few people like Ilya Suskiver, who
you've interviewed, who had somewhat similar reviews.
He might have been the first one,
although I think a few people came to similar reviews
around the same time, right?
There was, you know, Rich Sutton's bitter lesson.
There was, Goran wrote about the scaling hypothesis.
But I think somewhere between 2014 and 2017
was when it really clicked for me,
when I really got conviction that,
hey, we're gonna be able to do these incredibly wide
cognitive tasks if we just scale up the models. really got conviction that, hey, we're going to be able to do these incredibly wide cognitive
tasks if we just scale up the models.
And at every stage of scaling, there are always arguments.
And when I first heard them, honestly, I thought,
probably I'm the one who's wrong.
And all these experts in the field are right.
They know the situation better than I do.
There's the Chomsky argument about you can get syntactics, but you can't get semantics.
There was this idea, oh, you can make a sentence make sense,
but you can't make a paragraph make sense.
The latest one we have today is,
we're gonna run out of data
or the data isn't high quality enough
or models can't reason.
And each time, every time we manage to,
we manage to either find a way around
or scaling just is the way around.
Sometimes it's one, sometimes it's the other.
And so I'm now at this point, I still think,
you know, it's always quite uncertain.
We have nothing but inductive inference to tell us
that the next few years are gonna be like the next,
the last 10 years.
But I've seen the movie enough times.
I've seen the story happen for enough times
to really believe that probably the scaling
is going to continue and that there's some magic to it
that we haven't really explained on a theoretical basis yet.
And of course the scaling here is bigger networks,
bigger data, bigger compute.
Yes.
All of those.
In particular, linear scaling up of bigger networks,
bigger training times, and more data.
So all of these things, almost like a chemical reaction.
You have three ingredients in the chemical reaction,
and you need to linearly scale up the three ingredients.
If you scale up one, not the others,
you run out of the other reagents, and the reaction stops. But if you scale up one, not the others, you run out of the other reagents and the reaction stops.
But if you scale up everything in series,
then the reaction can proceed.
And of course, now that you have this kind of empirical
science slash art, you can apply to other more nuanced things
like scaling laws applied to interpretability
or scaling laws applied to post-training
or just seeing
how does this thing scale.
But the big scaling law, I guess the underlying scaling hypothesis has to do with big networks,
big data leads to intelligence.
Yeah, we've documented scaling laws in lots of domains other than language, right?
So initially, the paper we did that first showed it was in early 2020, where we
first showed it for language. There was then some work late in 2020, where we showed the same thing
for other modalities like images, video, text to image, image to text, math, they all had the same
pattern. And you're right, now there are other stages like post-training or there are new types of reasoning models.
And in all of those cases that we've measured,
we see similar types of scaling laws.
A bit of a philosophical question,
but what's your intuition about why bigger is better
in terms of network size and data size?
Why does it lead to more intelligent models?
So in my previous career as a biophysicist,
so I did a physics undergrad and then biophysics in grad school.
So I think back to what I know as a physicist, which is actually
much less than what some of my colleagues at Anthropic
have in terms of expertise in physics,
there's this concept called the one over F noise
and one over X distributions.
Where often, you know, just like if you add up
a bunch of natural processes, you get a Gaussian.
If you add up a bunch of kind of
differently distributed natural processes,
if you like take a probe and hook it up to a resistor,
the distribution of the thermal noise in the resistor
goes as one over the frequency.
It's some kind of natural convergent distribution.
And I think what it amounts to is that if you look at
a lot of things that are produced by some natural process
that has a lot of different scales, right?
Not a Gaussian, which is kind of narrowly distributed, a lot of things that are produced by some natural process that has a lot of different scales, right?
Not a Gaussian, which is kind of narrowly distributed,
but if I look at kind of like large and small fluctuations
that lead to electrical noise,
they have this decaying one over X distribution.
And so now I think of like patterns
in the physical world, right?
If I, or in language,
if I think about the patterns in language,
there are some really simple patterns.
Some words are much more common than others, like the.
Then there's basic noun-verb structure.
Then there's the fact that, you know,
nouns and verbs have to agree, they have to coordinate.
And there's the higher level sentence structure.
Then there's the thematic structure of paragraphs.
And so the fact that there's this regressing structure,
you can imagine that as you make the networks larger,
first they capture the really simple correlations,
the really simple patterns,
and there's this long tail of other patterns.
And if that long tail of other patterns is really smooth,
like it is with the one over F noise
in physical processes like resistors,
then you can imagine as you make the network larger,
it's kind of capturing more and more of that distribution.
And so that smoothness gets reflected
in how well the models are at predicting
and how well they perform.
Language is an evolved process, right?
We've developed language,
we have common words and less common words,
we have common expressions and less common words, we have common expressions
and less common expressions.
We have ideas, cliches that are expressed frequently
and we have novel ideas.
And that process has developed, has evolved with humans
over millions of years.
And so the guess, and this is pure speculation,
would be that there's some kind of long tail distribution
of the distribution of these ideas.
So there's the long tail,
but also there's the height of the hierarchy of concepts
that you're building up.
So the bigger the network,
presumably you have a higher capacity to.
Exactly, if you have a small network,
you only get the common stuff, right?
If I take a tiny neural network,
it's very good at understanding that, you know,
a sentence has to have, you know, verb adjective noun,
right, but it's terrible at deciding
what those verb adjective and noun should be
and whether they should make sense.
If I make it just a little bigger, it gets good at that.
Then suddenly it's good at the sentences,
but it's not good at the paragraphs.
And so these rarer and more complex patterns get picked up
as I add more capacity to the network.
Well, the natural question then is,
what's the ceiling of this?
Yeah.
Like how complicated and complex is the real world?
How much is the stuff is there to learn?
I don't think any of us knows the answer to that question.
My strong instinct would be that there's no ceiling
below the level of humans, right?
We humans are able to understand these various patterns.
And so that makes me think that if we continue to scale up these models to kind of develop
new methods for training them and scaling them up, that will at least get to the level
that we've gotten to with humans.
There's then a question of how much more is it possible to understand than humans do?
How much is it possible to be smarter
and more perceptive than humans?
I would guess the answer has got to be domain dependent.
If I look at an area like biology,
and you know, I wrote this essay,
Machines of Loving Grace,
it seems to me that humans are struggling
to understand the complexity of biology, right?
If you go to Stanford or to Harvard or to Berkeley,
you have whole departments of, you know,
folks trying to study, you know,
like the immune system or metabolic pathways.
And each person understands only a tiny bit part of it,
specializes, and they're struggling
to combine their knowledge with that of other humans.
And so I have an instinct that there's a lot of room at the top for AIs to get smarter.
If I think of something like materials in the physical world or like addressing conflicts
between humans or something like that, I mean, you know, it may be there's only some of these problems are not intractable, but much harder.
And it may be that there's only so well you can do
at some of these things, right?
Just like with speech recognition,
there's only so clear I can hear your speech.
So I think in some areas, there may be ceilings
that are very close to what humans have done.
In other areas, those ceilings may be very far away.
And I think we'll only find out when we build these systems.
It's very hard to know in advance.
We can speculate, but we can't be sure.
And in some domains, the ceiling might have to do
with human bureaucracies and things like this,
as you write about.
Yes.
So humans fundamentally have to be part of the loop.
That's the cause of the ceiling,
not maybe the limits of the intelligence.
Yeah, I think in many cases, you know, in theory,
technology could change very fast.
For example, all the things that we might invent
with respect to biology.
But remember, there's a clinical trial system
that we have to go through
to actually administer these things to humans.
I think that's a mixture of things
that are unnecessary and bureaucratic
and things that kind of protect the integrity of society.
And the whole challenge is that it's hard to tell,
it's hard to tell what's going on.
It's hard to tell which is which, right?
My view is definitely, I think,
in terms of drug development,
my view is that we're too slow and we're too conservative.
But certainly, if you get these things wrong,
it's possible to risk people's lives
by being too reckless.
And so at least some of these human institutions
are in fact protecting people.
So it's all about finding the balance.
I strongly suspect that balance is kind of more
on the side of wishing to make things happen faster,
but there is a balance.
If we do hit a limit, if we do hit a slow down
in the scaling laws, what do you think would be the reason?
Is it compute limited, data limited?
Is it something else, idea limited?
So a few things.
Now we're talking about hitting the limit
before we get to the level of humans
and the skill of humans.
So I think one that's popular today,
and I think could be a limit that we run into,
like most of the limits, I would bet against it,
but it's definitely possible,
is we simply run out of data.
There's only so much data on the internet,
and there's issues with the quality of the data, right?
You can get hundreds of trillions of words on the internet,
but a lot of it is repetitive or it's search engine,
you know, search engine optimization drivel,
or maybe in the future it'll even be text generated
by AIs itself.
And so I think there are limits to what can be produced
in this way.
That said, we, and I would guess other companies,
are working on ways to make data synthetic,
where you can use the model to generate more data
of the type that you have already,
or even generate data from scratch.
If you think about what was done with DeepMind's AlphaGo Zero,
they managed to get a bot all the way from no ability
to play Go whatsoever to above human level
just by playing against itself.
There was no example data from humans
required in the AlphaGo Zero version of it.
The other direction, of course, is these reasoning models
that do chain of thought and stop to think and reflect
on their own thinking.
In a way, that's another kind of synthetic data coupled
with reinforcement learning.
So my guess is with one of those methods, we'll get around the data limitation or there
may be other sources of data that are available.
We could just observe that even if there's no problem with data, as we start to scale
models up, they just stop getting better.
It seemed to be our reliable observation that they've gotten better.
That could just stop at some point
for a reason we don't understand.
The answer could be that we need to,
we need to invent some new architecture.
It's been, there have been problems in the past
with say numerical stability of models
where it looked like things were leveling off,
but actually when you know, when
we found the right unblocker, they didn't end up doing so.
So perhaps there's some new optimization method or some new technique we need to unblock things.
I've seen no evidence of that so far, but if things were to slow down, that perhaps
could be one reason.
What about the limits of compute, meaning the expensive nature of building bigger and bigger
data centers?
So right now, I think most of the frontier model companies,
I would guess, are operating roughly $1 billion scale,
plus or minus a factor of three.
Those are the models that exist now or are being trained now.
I think next year, we're're gonna go to a few billion,
and then 2026 we may go to above 10 billion,
and probably by 2027,
their ambitions to build $100 billion clusters.
And I think all of that actually will happen.
There's a lot of determination to build the compute,
to do it within this country, and I would guess that it actually will happen. There's a lot of determination to build the compute to do it within
this country. And I would guess that it actually does happen. Now, if we get to a hundred billion,
that's still not enough compute, that's still not enough scale, then either we need even more scale
or we need to develop some way of doing it more efficiently, of shifting the curve.
I think between all of these, one of the reasons I'm bullish about powerful AI happening so fast is just that if you extrapolate the next few points on the curve, we're very quickly getting towards human level ability, right?
Some of the new models that we developed, some reasoning models that have come from other companies, they're starting to get to what I would call the PhD or professional level, right? If you look at their coding
ability, the latest model we released, Sonnet 3.5, the new or updated version, it gets something
like 50% on Sweebench. And Sweebench is an example of a bunch of professional real world
software engineering tasks. At the beginning of the year, I think the state of the art was three or 4%.
So in 10 months, we've gone from 3% to 50% on this task.
And I think in another year, we'll probably be at 90%.
I mean, I don't know,
but might even be less than that.
We've seen similar things in graduate level math, physics,
and biology from models like OpenAI's O1. So if we just continue to extrapolate this, physics, and biology from models like OpenAI's O1.
So if we just continue to extrapolate this, right,
in terms of skill that we have,
I think if we extrapolate the straight curve,
within a few years, we will get to these models being,
you know, above the highest professional level
in terms of humans.
Now, will that curve continue?
You've pointed to, and I've pointed to a lot of reasons,
possible reasons why that might not happen.
But if the extrapolation curve continues,
that is the trajectory we're on.
So Anthropic has several competitors.
It'd be interesting to get your sort of view of it all.
OpenAI, Google, XAI, Meta, what does it take to win
in the broad sense of win in the space?
Yeah, so I wanna separate out a couple things, right?
So, you know, Anthropics mission is to kind of try
to make this all go well, right?
And, you know, we have a theory of change called
Race to the Top, right?
Race to the Top is about trying to push the other players
to do the right thing by setting an example.
It's not about being the good guy, it's about setting things up so that all of us can be the good guy. to push the other players to do the right thing by setting an example.
It's not about being the good guy,
it's about setting things up
so that all of us can be the good guy.
I'll give a few examples of this.
Early in the history of Anthropic,
one of our co-founders, Chris Ola,
who I believe you're interviewing soon,
you know, he's the co-founder
of the field of mechanistic interpretability,
which is an attempt to understand
what's going on inside AI models. So we had him and one of our early teams focus on this area of interpretability,
which we think is good for making models safe and transparent.
For three or four years, that had no commercial application whatsoever.
It still doesn't today. We're doing some early betas with it,
and probably it will eventually, but this is a very, very long
research bet and one in which we've built in public and shared our results publicly.
And we did this because we think it's a way to make models safer.
An interesting thing is that as we've done this, other companies have started doing it
as well.
In some cases, because they've been inspired by it. In some cases because they're worried that
you know if other companies are doing this that look more responsible, they want to look more
responsible too. No one wants to look like the irresponsible actor and so they adopt this as well
when folks come to Anthropic, interpretability is often a draw, and I tell them, the other places you didn't go, tell them why you came here.
And then you see soon that there's interpretability teams elsewhere as well.
And in a way, that takes away our competitive advantage because it's like, oh, now others
are doing it as well, but it's good for the broader system.
And so we have to invent some new thing that we're doing that others aren't doing as well.
And the hope is to basically bid up the importance
of doing the right thing.
And it's not about us in particular, right?
It's not about having one particular good guy.
Other companies can do this as well.
If they join the race to do this,
that's the best news ever, right?
It's about kind of shaping the incentives to point upward
instead of shaping the incentives to point downward.
And we should say this example,
the field of mechanistic interpretability
is just a rigorous non-hand wavy way of doing AI safety.
Or it's tending that way.
Trying to, I mean, I think we're still early
in terms of our ability to see things,
but I've been surprised at how much we've been able
to look inside these systems and understand what we see.
Unlike with the scaling laws
where it feels like there's some law
that's driving these models to perform better,
on the inside, the models aren't,
there's no reason why they should be designed
for us to understand them, right?
They're designed to operate.
They're designed to work, just like the human brain
or human biochemistry.
They're not designed for a human to open up the hatch,
look inside and understand them.
But we have found, and you know,
you can talk in much more detail about this to Chris,
that when we open them up, when we do look inside them,
we find things that are surprisingly interesting.
And as a side effect,
you also get to see the beauty of these models.
You get to explore the sort of the beautiful nature
of large neural networks
through the Mech and Terp kind of methodology.
I'm amazed at how clean it's been.
I'm amazed at things like induction heads.
I'm amazed at things like, you know,
that we can, you know,
use sparse autoencoders to find these directions
within the networks and that the directions correspond
to these very clear concepts.
We demonstrated this a bit with the Golden Gate Bridge quad.
So this was an experiment where we found a direction
inside one of the neural networks layers
that corresponded to the Golden Gate
Bridge. And we just turned that way up. And so we released this model as a demo. It was kind of half
a joke for a couple of days, but it was illustrative of the method we developed. And you could take the
Golden Gate, you could take the model, you could ask it about anything. It would be like, you could
say, how was your day? And anything you asked, because ask it about anything, it would be like, you could say, how was your day?
And anything you asked, because this feature was activated,
it would connect to the Golden Gate Bridge.
So it would say, I'm feeling relaxed and expansive,
much like the arches of the Golden Gate Bridge.
It would masterfully change topic to the Golden Gate Bridge
and integrate it.
There was also a sadness to it,
to the focus it had on the Golden Gate Bridge.
I think people quickly fell in love with it.
I think, so people already miss it
because it was taken down, I think, after a day.
Somehow these interventions on the model
where you kind of adjust its behavior,
somehow emotionally made it seem more human
than any other version of the model.
It's a strong personality, strong identity.
It has a strong personality.
It has these kind of like obsessive interests.
You know, we can all think of someone
who's like obsessed with something.
So it does make it feel somehow a bit more human.
Let's talk about the present.
Let's talk about Claude.
So this year, a lot has happened.
In March, Claude 3, Opus, Sonnet, Haiku were released.
Then Claude 3, 5, Sonnet in July
with an updated version just now released.
And then also Claw 3, 5, Haiku was released.
Okay, can you explain the difference
between Opus, Sonnet, and Haiku
and how we should think about the different versions?
Yeah, so let's go back to March
when we first released these three models.
So, you know,
our thinking was different companies produce kind of large and small models, better and
worst models. We felt that there was demand both for a really powerful model, you know,
when you that might be a little bit slower that you'd have to pay more for, and also
for fast, cheap models that are as smart
as they can be for how fast and cheap, right?
Whenever you wanna do some kind of like,
you know, difficult analysis, like if I, you know,
I wanna write code for instance, or, you know,
I wanna brainstorm ideas or I wanna do creative writing,
I want the really powerful model.
But then there's a lot of practical applications
in a business sense where it's like, I'm
interacting with a website, I, you know, like, I'm like, doing
my taxes, or I'm, you know, talking to, you know, to like a
legal advisor, and I want to analyze a contract or, you know,
we have plenty of companies that are just like, you know, I
want to do auto complete on my on my ID or something. And for
all of those things, you want to act fast
and you want to use the model very broadly.
So we wanted to serve that whole spectrum of needs.
So we ended up with this kind of poetry theme.
And so what's a really short poem? It's a haiku.
And so haiku is the small, fast, cheap model
that was at the time was really surprisingly intelligent for how
fast and cheap it was.
Sonnet is a medium-sized poem, right?
A couple paragraphs.
And so Sonnet was the middle model.
It is smarter, but also a little bit slower, a little bit more expensive.
And Opus, like a magnum opus is a large work, Opus was the largest, smartest model at the
time.
So that was the original kind of thinking behind it.
And our thinking then was,
well, each new generation of models
should shift that trade-off curve.
So when we released Sonnet 3.5,
it has roughly the same cost and speed
as the Son at three model.
But it increased its intelligence to the point
where it was smarter than the original Opus three model,
especially for code, but also just in general.
And so now, you know, we've shown results for Haiku 3.5
and I believe Haiku 3.5, the smallest new model,
is about as good as Opus 3, the largest old model.
So basically the aim here is to shift the curve,
and then at some point there's gonna be an Opus 3.5.
Now, every new generation of models has its own thing,
they use new data, their personality changes in ways that
we kind of, you know, try to steer but are not fully able to steer. And so there's never quite
that exact equivalence where the only thing you're changing is intelligence. We always try and improve
other things and some things change without us knowing or measuring. So it's very much an
exact science. In many ways, the manner and personality of these models
is more an art than it is a science.
So what is sort of the reason for the span of time
between say, Cloud Opus 3.0 and 3.5?
What takes that time if you can speak to it?
Yeah, so there's different processes.
There's pre-training, which is just kind of
the normal language model training.
And that takes a very long time.
That uses these days, tens of thousands,
sometimes many tens of thousands of GPUs or TPUs
or training them or whatever. We use different platforms, but accelerator chips,
often training for months.
There's then a kind of post-training phase
where we do reinforcement learning from human feedback,
as well as other kinds of reinforcement learning.
That phase is getting larger and larger now. And often, that's less
of an exact science. It often takes effort to get it right. Models are then tested with some of our
early partners to see how good they are. And they're then tested both internally and externally
for their safety, particularly for catastrophic and autonomy risks.
So we do internal testing according
to our responsible scaling policy,
which I could talk more about that in detail.
And then we have an agreement with the US and the UK AI
Safety Institute, as well as other third party
testers in specific domains, to test the models for what
are called CBRN risks, chemical, biological, radiological, and nuclear,
which are, you know, we don't think that models
pose these risks seriously yet,
but every new model we want to evaluate
to see if we're starting to get close
to some of these more dangerous capabilities.
So those are the phases.
And then, you know, then it just takes some time
to get the model working in terms of inference
and launching it in the API.
So there's just a lot of steps
to actually make your model work.
And of course, you know,
we're always trying to make the processes
as streamlined as possible, right?
We want our safety testing to be rigorous,
but we want it to be rigorous and to be automatic,
to happen as fast as it can without compromising on rigor.
Same with our pre-training process
and our post-training process.
So, it's just like building anything else.
It's just like building airplanes.
You want to make them safe,
but you want to make the process streamlined.
And I think the creative tension between those
is an important thing in making the models work. Yeah I think the creative tension between those is an important thing in
making the models work. Yeah. Rumor on the street, I forget who was saying that Anthropic
has really good tooling. So probably a lot of the challenge here is on the software engineering side
is to build the tooling to have like a efficient low friction interaction with the infrastructure.
You would be surprised how much of the challenges of,
you know, building these models comes down to, you know,
software engineering, performance engineering, you know, you, you know, from the outside,
you might think, oh man, we had this Eureka breakthrough, right? You know, this movie with
the science, we discovered it, we figured it out. But, but, but I. But I think all things, even incredible discoveries,
like they almost always come down to the details.
And often super, super boring details.
I can't speak to whether we have better tooling
than other companies.
I mean, I haven't been at those other companies,
at least not recently,
but it's certainly something we give a lot of attention to.
I don't know if you can say, but from three,
from Claude three to Claude three, five,
is there any extra pre-training going on
as they mostly focus on the post-training?
There's been leaps in performance.
Yeah, I think at any given stage,
we're focused on improving everything at once.
Just naturally, like there are different teams,
each team makes progress in a particular area
in making a particular, their particular segment
of the relay race better.
And it's just natural that when we make a new model,
we put all of these things in at once.
So the data you have, like the preference data you get
from RLHF, is that applicable?
Is there ways to apply it to newer models
as it get trained up?
Yeah, preference data from old models
sometimes gets used for new models.
Although of course it performs somewhat better
when it's trained on the new models.
Note that we have this constitutional AI method
such that we don't only use preference data.
There's also a post-training process
where we train the model against itself.
And there's new types of post-tra train the model against itself and there's you know
New types of post training the model against itself that are used every day. So it's not just our like Jeff
It's a bunch of other methods as well post training. I think you know, it's becoming more and more sophisticated
Well, what explains the big leap in performance for the new sonnet 3 5?
I mean at least in the programming side and maybe this is a good place to talk about benchmarks
What does it mean to get better?
Just the number went up, but you know, I program,
but I also love programming and I clawed three, five
through cursors, what I use to assist me in programming.
And there was, at least experientially, anecdotally,
it's gotten smarter at programming.
So what does it take to get it smarter?
We observed that as well, by the way.
There were a couple very strong engineers here at Anthropic
who all previous code models, both produced by us
and produced by all the other companies,
hadn't really been useful to them.
They said, maybe this is useful to a beginner, it's not useful to them. They said, maybe this is useful to beginner,
it's not useful to me.
But Sonnet 3.5, the original one for the first time,
they said, oh my God, this helped me with something
that it would have taken me hours to do.
This is the first model that has actually saved me time.
So again, the water line is rising.
And then I think the new Sonnet has been even better.
In terms of what it takes, I mean, I'll just say it's been across the board.
It's in the pre-training, it's in the post-training, it's in various evaluations that we do.
We've observed this as well.
And if we go into the details of the benchmark, so, Swaybench is basically, since you're a
programmer, you'll be familiar with like pull requests and just pull requests are
a sort of atomic unit of work. You could say, I'm implementing one thing.
And so, suibench actually gives you kind of a real world situation where the code base is in
the current state and I'm trying to implement something that's described in language. We have internal benchmarks where we measure
the same thing, and you say, just give the model free reign to do anything, run anything, edit
anything. How well is it able to complete these tasks? And it's that benchmark that's gone from
it can do it 3% of the time to it can do it about
50% of the time.
So I actually do believe that you can gain benchmarks, but I think if we get to 100%
of that benchmark in a way that isn't kind of like over trained or game for that particular
benchmark probably represents a real and serious increase in kind of programming ability.
And I would suspect that if we can get to 90-95%, that it will represent ability to
autonomously do a significant fraction of software engineering tasks.
Well, ridiculous timeline question. When is Cloud Opus 3.5 coming out?
ridiculous timeline question. When is Cloud Opus 3.5 coming up?
Not giving you an exact date, but you know, they're, they're, uh, you know, as far as we know, the plan is still to have a Cloud 3.5 Opus.
Are we going to get it before GTA six or no?
Like Duke Nukem forever. So what was that game that there was some game that was
delayed 15 years. Was that Duke Nukem forever?
Yeah. And I think GTA is not just releasing trailers. You know, it's only been three months
since we released the first Sonnet.
Yeah, it's the incredible pace of release.
It just tells you about the pace,
the expectations for when things are gonna come out.
So what about 4.0?
So how do you think about sort of as these models
get bigger and bigger about versioning
and also just versioning in general,
why Sonnet 3.5 updated with the date?
Why not Sonnet 3.6 switch out a lot of people calling it?
Naming is actually an interesting challenge here, right?
Because I think a year ago,
most of the model was pre-training.
And so you could start from the beginning and just say,
okay, we're gonna have models of different sizes.
We're gonna train them all together.
And we'll have a family of naming schemes, and then we'll
put some new magic into them. And then you know, we'll have
the next the next generation. The trouble starts already when
some of them take a lot longer than others to train, right,
that already messes up your time, time a little bit. But as
you make big improvements in as you make big improvements in
pre training, then you suddenly notice, oh, I can make better
pre-trained model and that doesn't take very long to do.
But clearly it has the same size and shape of previous models.
So I think those two together, as well as the timing issues, any kind of scheme you
come up with, the reality tends to kind of frustrate that scheme, right?
It tends to kind of break out of the scheme.
It's not like software where you can say, oh, this is like 3.7, this is 3.8.
No, you have models with different trade-offs.
You can change some things in your models.
You can change other things.
Some are faster and slower at inference.
Some have to be more expensive. Some have to be more expensive.
Some have to be less expensive.
And so I think all the companies have struggled with this.
I think we did very, you know,
I think we were in a good position in terms of naming
when we had Haiku, Sonnet and Opus.
That was great, great start.
We're trying to maintain it, but it's not perfect.
So we'll try and get back to the simplicity,
but just the nature of the field, I feel like
no one's figured out naming.
It's somehow a different paradigm from like normal software.
And so we just, none of the companies have been perfect at it.
It's something we struggle with surprisingly much relative to how trivial it is
for the grand science of training the models.
So from the user side,
the user experience of the updated Sonnet 3.5
is just different than the previous June 2024 Sonnet 3.5.
It would be nice to come up with some kind of labeling
that embodies that because people talk about Sonnet 3.5,
but now there's a different one.
And so how do you refer to the previous one
and the new one and it,
when there's a distinct improvement,
it just makes conversation about it just challenging.
Yeah, yeah.
I definitely think this question of
there are lots of properties of the models
that are not reflected in the benchmarks.
I think that's definitely the case and everyone agrees and not all of them are capabilities.
Some of them are, you know, models can be polite or brusque.
They can be, you know, very reactive or they can ask you questions.
They can have what feels like a warm personality
or a cold personality.
They can be boring or they can be very distinctive
like Golden Gate Claude was.
And we have a whole team kind of focused on,
I think we call it Claude character.
Amanda leads that team and we'll talk to you about that. But it's still a
very inexact science. And often we find that models have properties that we're not aware of.
The fact of the matter is that you can talk to a model 10,000 times and there are some behaviors
you might not see. Just like with a human, right? I can know someone for a few months and not know
that they have a certain skill or not know that they have a certain skill
or not know that there's a certain side to them.
And so I think we just have to get used to this idea
and we're always looking for better ways
of testing our models to demonstrate these capabilities
and also to decide which are the personality properties
we want models to have and which we don't want to have.
That itself, the normative question
is also super interesting.
I gotta ask you a question from Reddit.
From Reddit, oh boy.
You know, there's just this fascinating,
to me at least, it's a psychological social phenomenon
where people report that Claude has gotten dumber
for them over time.
And so the question is, does the user complaint
about the dumbing down of Claude 3.5 Sonnet hold any water?
So are these anecdotal reports a kind of social phenomena
or did Claude, is there any cases
where Claude would get dumber?
So this actually doesn't apply, this isn't just about Claude.
I believe this, I believe I've seen these complaints
for every foundation model produced by a major company. People said this about GPT-4. They said
it about GPT-4 Turbo. So a couple things. One, the actual weights of the model, right? The actual
brain of the model, that does not change unless we introduce a new model.
There are just a number of reasons why it would not make
sense practically to be randomly substituting in new versions
of the model.
It's difficult from an inference perspective,
and it's actually hard to control all the consequences
of changing the way to the model.
Let's say you wanted to fine tune the model to be like,
I don't know, to like, to say certainly less,
which, you know, an old version of Sonnet used to do.
You actually end up changing a hundred things as well.
So we have a whole process for it,
and we have a whole process for modifying the model.
We do a bunch of testing on it.
We do a bunch of like,
we do a bunch of user testing and early customers.
So we both have never changed the weights of the model
without telling anyone.
And certainly in the current setup,
it would not make sense to do that.
Now, there are a couple of things that we do occasionally do.
One is sometimes we run A-B tests.
But those are typically very close
to when a model is being released
and for a very small fraction of time.
So, you know, like the day before the new Sonnet 3.5,
I agree, we should have had a better name.
It's clunky to refer to it.
There were some comments from people that like,
it's gotten a lot better and that's because, you know,
a fraction were exposed to an A-B test
for those one or two days.
The other is that occasionally the system prompt will change.
The system prompt can have some effects,
although it's unlikely to dumb down models,
it's unlikely to make them dumber.
And we've seen that while these two things,
which I'm listing to be very complete,
happen quite infrequently. The complaints about, for us and for other model companies
about the model change, the model isn't good at this,
the model got more censored, the model was dumbed down,
those complaints are constant.
And so I don't wanna say like people are imagining
these or anything, but like the models are for the most part
not changing.
If I were to offer a theory, I think it actually relates to one of the things I said before,
which is that models are very complex and have many aspects to them.
And so often, if I ask the model a question, if I'm like, do task X versus can you do task X,
the model might respond in different ways.
And so there are all kinds of subtle things
that you can change about the way you interact
with the model that can give you very different results.
To be clear, this itself is like a failing by us
and by the other model providers
that the models are just often sensitive
to like small changes in wording.
It's yet another way in which the science
of how these models work is very poorly developed.
And so, you know, if I go to sleep one night
and I was like talking to the model in a certain way,
and I like slightly change the phrasing
of how I talk to the model, you know,
I could get different results.
So that's one possible way.
The other thing is, man, it's just hard to quantify this stuff.
It's hard to quantify this stuff.
I think people are very excited by new models when they come out,
and then as time goes on,
they become very aware of the limitations.
So that may be another effect.
But that's all a very long-rendered way of saying,
for the most part, with some fairly narrow exceptions,
the models are not changing.
I think there is a psychological effect.
You just start getting used to it, the baseline raises.
Like when people have first gotten WiFi on airplanes,
it's like amazing, magic.
And then you start-
And now I'm like, I can't get this thing to work.
This is such a piece of crap.
Exactly, so then it's easy to have the conspiracy theory of they're making wifi slower and slower.
This is probably something I'll talk to Amanda
much more about, but another Reddit question.
When will Claude stop trying to be my pure,
tentacle grandmother imposing its moral worldview on me
as a paying customer?
And also, what is the psychology behind making Claude
overly apologetic?
So this kind of reports about the experience, as a paying customer. And also, what is the psychology behind making Claude overly apologetic?
So this kind of reports about the experience
at different angle and the frustration.
It has to do with the character.
Yeah, so a couple of points on this first.
One is like things that people say on Reddit
and Twitter or X or whatever it is,
there's actually a huge distribution shift
between like the stuff that people complain loudly about on social media and what actually kind of like, you know, statistically users
care about and that drives people to use the models.
Like people are frustrated with, you know, things like, you know, the model not writing
out all the code or the model, you know, just not being as good at code as it could be,
even though it's the best model in the world on code. I think the majority of things are about that,
but certainly a kind of vocal minority
are kind of raise these concerns, right?
Are frustrated by the model,
refusing things that it shouldn't refuse
or like apologizing too much
or just having these kind of like annoying verbal ticks.
The second caveat, and I just want to say this like super clearly because I think it's
like some people don't know it, others like kind of know it but forget it, like it is
very difficult to control across the board how the models behave.
You cannot just reach in there and say, oh, I want the model to like apologize less.
Like you can do that. You can include trading data that says like, I want the model to like apologize less. Like you can do that.
You can include trading data that says like, Oh, the model should like apologize
less, but then in some other situation, they end up being like super rude or
like overconfident in a way that's like misleading people.
So there, there are all these trade-offs.
Um, uh, for example, another thing is if there was a period during which.
Models ours, and I think others as well,
were too verbose, right? They would repeat themselves, they would say too much.
You can cut down on the verbosity by penalizing the models for just talking for too long.
What happens when you do that, if you do it in a crude way, is when the models are coding,
sometimes they'll say, rest of the code goes here, right? Because they've learned that that's a way to economize and that they see it.
And then, so that leads the model to be so-called lazy in coding, where they're just like, ah,
you can finish the rest of it.
It's not because we want to save on compute or because the models are lazy during winter
break or any of the other kind of conspiracy theories that have that have that have come up
It's actually it's just very hard to control the behavior of the model to steer the behavior of the model in all
Circumstances at once you can kind of there's this this whack-a-mole aspect where you push on one thing and like, you know
these are these you know, these other things start to move as well that you may not even notice or measure.
And so one of the reasons that I care so much about
kind of grand alignment of these AI systems in the future
is actually, these systems are actually quite unpredictable.
They're actually quite hard to steer and control.
And this version we're seeing today of
you make one thing better, it makes another thing
worse.
I think that's like a present day analog of future control problems in AI systems that
we can start to study today.
I think that difficulty in steering the behavior and in making sure that if we
push an AI system in one direction, it doesn't push it in another direction
in some, in some other ways that we didn't want.
Uh, I think that's, that's kind of an, that's kind of an early sign of things
to come and if we can do a good job of solving this problem, right, of like, you
ask the model to like, you know, to like, make and distribute smallpox,
and it says no, but it's willing to like help you in your graduate level virology class. Like,
how do we get both of those things at once? It's hard. It's very easy to go to one side or the other,
and it's a multi-dimensional problem. And so, I, you know, I think these questions of like shaping
the model's personality, I think they're very hard.
I think we haven't done perfectly on them.
I think we've actually done the best
of all the AI companies, but still so far from perfect.
And I think if we can get this right,
if we can control the false positives and false negatives
in this very kind of controlled
present day environment will be much better
at doing it for the future when our worry is,
will the models be super autonomous?
Will they be able to make very dangerous things?
Will they be able to autonomously build whole companies
and are those companies aligned?
So I think of this present task as both vexing
but also good practice for the future.
What's the current best way of gathering
sort of user feedback, like not anecdotal data,
but just large scale data about pain points
or the opposite of pain points, positive things, so on.
Is it internal testing?
Is it a specific group testing, A-B testing?
What works?
So typically we'll have internal model bashings
where all of Anthropic, Anthropic is almost a thousand people,
people just try and break the model.
They try and interact with it various ways.
We have a suite of evals for,
oh, is the model refusing in ways that it couldn't?
I think we even had a certainly eval
because our model, again, at one point, model refusing in ways that it couldn't. I think we even had a certainly eval because,
again, at one point, model had this problem
where it had this annoying tick where it would respond
to a wide range of questions by saying,
certainly, I can help you with that.
Certainly, I would be happy to do that.
Certainly, this is correct.
And so we had a certainly eval,
which is how often does the model say certainly.
But look, this is just a whack-a-mole.
Like what if it switches from certainly to definitely?
Like, so, you know, every time we add a new eval
and we're always evaluating for all the old things.
So we have hundreds of these evaluations,
but we find that there's no substitute
for human interacting with it.
And so it's very much like
the ordinary product development process.
We have like hundreds of people within Anthropic
bash the model, then we do, you know,
then we do external AB tests.
Sometimes we'll run tests with contractors.
We pay contractors to interact with the model.
So you put all of these things together
and it's still not perfect.
You still see behaviors that you don't quite wanna see,
right? You know, you see, You still see the model like refusing things
that it just doesn't make sense to refuse.
But I think trying to solve this challenge,
trying to stop the model from doing genuinely bad things
that everyone agrees it shouldn't do.
Everyone agrees that the model shouldn't talk about,
I don't know, child abuse material, right?
Like everyone agrees the model shouldn't do that.
But at the same time that it doesn't refuse
in these dumb and stupid ways.
I think drawing that line as finely as possible,
approaching perfectly is still a challenge
and we're getting better at it every day,
but there's a lot to be solved.
And again, I would point to that as an indicator
of a challenge ahead in terms of steering
much more powerful models.
Do you think Claude 4.0 is ever coming out?
I don't wanna commit to any naming scheme
cause if I say here, we're gonna have Claude 4 next year
and then we decide that we should start over
because there's a new type of model.
I don't wanna commit to it.
I would expect in a normal course of business
that Claude IV would come after Claude 3.5,
but you never know in this wacky field, right?
But this idea of scaling is continuing.
Scaling is continuing.
There will definitely be more powerful models
coming from us than the models that exist today.
That is certain, or if there aren't,
we've deeply failed as a company.
Okay, can you explain the responsible scaling policy
and the AI safety level standards, ASL levels?
As much as I'm excited about the benefits of these models,
and we'll talk about that
if we talk about machines of loving grace,
I'm worried about the risks
and I continue to be worried about the risks.
No one should think that machines of loving grace
was me saying, I'm no longer worried
about the risks of these models.
I think they're two sides of the same coin.
The power of the models and their ability
to solve all these problems in biology, neuroscience,
economic development, governance and peace,
large parts of the economy,
those come with risks as well, right?
With great power comes great responsibility, right?
That's the two are paired.
Things that are powerful can do good things
and they can do bad things.
I think of those risks as being in
several different categories.
Perhaps the two biggest risks that I think about,
and that's not to say that there aren't risks today
that are important, but when I think of the really,
the things that would happen on the grandest scale,
one is what I call catastrophic misuse.
These are misuse of the models in domains
like cyber, bio, radiological, nuclear, right?
Things that could harm or even kill thousands,
even millions of people if they really, really go wrong.
Like these are the number one priority to prevent. And here, I would just make
a simple observation, which is that the models, if I look today at people who have done really
bad things in the world, I think actually humanity has been protected by the fact that the overlap
between really smart, well-educated people and people who wanna do
really horrific things has generally been small.
Like, let's say I'm someone who,
I have a PhD in this field, I have a well-paying job,
there's so much to lose.
Why do I wanna like, even assuming I'm completely evil,
which most people are not,
why would such a person risk their life,
risk their legacy, their reputation
to do something like truly, truly evil?
If we had a lot more people like that,
the world would be a much more dangerous place.
And so my worry is that by being
a much more intelligent agent,
AI could break that correlation.
And so I do have serious worries about that.
I believe we can prevent those worries,
but I think as a counterpoint to machines of loving grace,
I wanna say that there's still serious risks.
And the second range of risks would be the autonomy risks,
which is the idea that models might on their own,
particularly as we give them more agency than they've had in the past, particularly as we give them
supervision over wider tasks like, you know, writing whole code bases or someday even, you know,
effectively operating entire companies, they're on a long enough leash. Are they doing what we really want them to do?
It's very difficult to even understand in detail
what they're doing, let alone control it.
And like I said, these early signs that it's hard
to perfectly draw the boundary between things
the model should do and things the model shouldn't do,
that if you go to one side, you get things that are annoying and useless
and you go to the other side, you get other behaviors.
If you fix one thing, it creates other problems.
We're getting better and better at solving this.
I don't think this is an unsolvable problem.
I think this is a science,
like the safety of airplanes or the safety of cars
or the safety of drugs.
I don't think there's any big thing we're missing.
I just think we need to get better
at controlling these models.
And so these are the two risks I'm worried about.
And our responsible scaling plan,
which I'll recognize is a very long-winded answer
to your question.
I love it. I love it.
Our responsible scaling plan is designed to address
these two types of risks.
And so every time we develop a new model,
we basically test it for its ability
to do both of these bad things.
So if I were to back up a little bit,
I think we have an interesting dilemma with AI systems
where they're not yet powerful enough
to present these catastrophes.
I don't know that they'll ever prevent these
catastrophes. It's possible they won't, but the case for worry, the case for risk is strong
enough that we should act now. And they're getting better very, very fast. I testified
in the Senate that we might have serious bio risks within two to three years. That was about a year ago. Things have proceeded a pace.
So we have this thing where it's like,
it's surprisingly hard to address these risks
because they're not here today.
They don't exist.
They're like ghosts, but they're coming at us so fast
because the models are improving so fast.
So how do you deal with something that's not here today,
doesn't exist, but is coming at us very fast?
So the solution we came up with for that
in collaboration with people like the organization,
Meader and Paul Cristiano is, okay,
what you need for that are you need tests
to tell you when the risk is getting close.
You need an early warning system.
And so every time we have a new model,
we test it for its capability to do these CBRN tasks,
as well as testing it for, you know,
how capable it is of doing tasks autonomously on its own.
And in the latest version of our RSP,
which we released in the last month or two,
the way we test autonomy risks is the AI model's ability
to do aspects of AI research itself,
which when the AI models can do AI research,
they become kind of truly, truly autonomous.
And that threshold is important for a bunch of other ways.
And so what do we then do with these tasks?
The RSP basically develops what we've called
an if-then structure, which is if the models
pass a certain capability, then we impose a certain set
of safety and security requirements on them.
So today's models are what's called ASL2.
Models that were ASL1 is for systems
that manifestly don't pose any risk of autonomy or misuse.
So for example, a chess plane bot, Deep Blue would be ASL1.
It's just manifestly the case that you can't use Deep Blue
for anything other than chess.
It was just designed for chess. No one's going to use it to conduct a masterful cyber attack or to run wild and
take over the world. ASL2 is today's AI systems where we've measured them and we think these
systems are simply not smart enough to autonomously self-replicate or conduct a bunch of tasks.
And also not smart enough to provide meaningful information
about CBRN risks and how to build CBRN weapons
above and beyond what can be known from looking at Google.
In fact, sometimes they do provide information,
but not above and beyond a search engine,
but not in a way that can be stitched together.
Not in a way that kind of end to end is dangerous enough.
So ASL3 is gonna be the point at which
the models are helpful enough
to enhance the capabilities of non-state actors, right?
State actors can already do a lot of, unfortunately,
to a high level of proficiency a lot of these very dangerous and destructive things.
The difference is that non-state actors are not capable of it. And so when we get to ASL 3,
we'll take special security precautions designed to be sufficient to prevent
theft of the model by non-state actors and misuse of the model as it's deployed
will have to have enhanced filters targeted
at these particular areas.
Cyber, bio, nuclear.
Cyber, bio, nuclear and model autonomy,
which is less a misuse risk and more a risk of the model
doing bad things itself.
ASL4 getting to the point where these models could enhance
the capability of a already knowledgeable state actor
and or become the main source of such a risk.
Like if you wanted to engage in such a risk,
the main way you would do it is through a model.
And then I think ASL4 on the autonomy side,
it's some amount of acceleration
in AI research capabilities with an AI model.
And then ASL5 is where we would get to the models
that are kind of truly capable,
that it could exceed humanity in their ability
to do any of these tasks.
And so the point of the if-then structure commitment
is basically to say, look, I don't know,
I've been working with these models for many years
and I've been worried about risk for many years.
It's actually kind of dangerous to cry wolf.
It's actually kind of dangerous to say,
this model is risky.
And people look at it and they say,
this is manifestly not dangerous.
Again, it's the delicacy of the risk isn't here today,
but it's coming at us fast.
How do you deal with that?
It's really vexing to a risk planner to deal with it.
And so this if then structure basically says,
look, we don't want to antagonize a bunch of people.
We don't wanna harm our own, our kind of own to antagonize a bunch of people. We don't want to harm our own, you know,
our kind of own ability to have a place in the conversation
by imposing these very onerous burdens
on models that are not dangerous today.
So the if then, the trigger commitment
is basically a way to deal with this.
It says you clamp down hard
when you can show that the model is dangerous.
And of course, what has to come with that is enough of a buffer threshold that you're not at high
risk of kind of missing the danger. It's not a perfect framework. We've had to change it.
We came out with a new one just a few weeks ago, and probably going forward, we might release new
ones multiple times a year
because it's hard to get these policies right,
like technically, organizationally,
from a research perspective, but that is the proposal.
If then commitments and triggers
in order to minimize burdens and false alarms now,
but really react appropriately when the dangers are here.
What do you think the timeline for ASL3 is
where several of the triggers are fired?
And what do you think the timeline is for ASL4?
Yeah, so that is hotly debated within the company.
We are working actively to prepare ASL3 security measures
as well as ASL3 deployment measures.
I'm not gonna go into detail,
but we've made a lot of progress on both
and we're prepared to be, I think, ready quite soon.
I would not be surprised at all
if we hit ASL3 next year.
There was some concern that we might even hit it this year,
that's still possible, that could still happen.
It's like very hard to say, but I would be very, very surprised if it was like 2030.
I think it's much sooner than that.
So there's protocols for detecting it, the if-then, and then there's protocols for how
to respond to it.
Yes.
How difficult is the second, the latter?
Yeah, I think for ASL 3, it's primarily about security and about filters on the model relating
to a very narrow set of areas when we deploy the model. Because at ASL3, the model isn't
autonomous yet. And so you don't have to worry about the model itself behaving in a bad way,
even when it's deployed internally. So I think the ASL three measures are,
I won't say straightforward, they're rigorous,
but they're easier to reason about.
I think once we get to ASL four,
we start to have worries about the models
being smart enough that they might sandbag tests.
They might not tell the truth about tests.
We had some results came out about like sleeper agents
and there was a more recent paper about,
can the models mislead attempts to,
sandbag their own abilities, right?
Show them, present themselves
as being less capable than they are.
And so I think with ASL4,
there's gonna be an important component
of using other things than just interacting
with the models.
For example, interpretability or hidden chains of thought,
where you have to look inside the model
and verify via some other mechanism
that is not as easily corrupted as what the model says,
that the model indeed has some property.
So we're still working on ASL4.
One of the properties of the RSP is that
we don't specify ASL4 until we've hit ASL3.
And I think that's proven to be a wise decision
because even with ASL3, again,
it's hard to know this stuff in detail.
And we wanna take as much time as we can possibly take
to get these things right.
So for ASL three, the bad actor will be humans.
Humans, yes.
And so there's a little bit more.
For ASL four, it's both, I think.
It's both, and so deception
and that's where mechanistic interpretability
comes into play.
And hopefully the techniques used for that
are not made accessible to the model.
Yeah, I mean, of course you can hook up
the mechanistic interpretability to the model itself,
but then you've kind of lost it as a reliable indicator
of the model state.
There are a bunch of exotic ways you can think of
that it might also not be reliable,
like if the model gets smart enough that it can jump computers and read the code where
you're looking at its internal state. We've thought about some of those. I think they're
exotic enough. There are ways to render them unlikely. But yeah, generally you want to
preserve mechanistic interpretability as a kind of verification set or test set that's
separate from the training process of the model.
See, I think as these models become better
and better conversation and become smarter,
social engineering becomes a threat too,
because they can start being very convincing
to the engineers inside companies.
Oh yeah, yeah.
It's actually like, you know,
we've seen lots of examples of demagoguery
in our life from humans,
and you know, there's a concern that models
could do that as well. One of the ways that cloud has been
getting more and more powerful is it's now able to do some agentic stuff.
Computer use, there's also an analysis within the sandbox of cloud.ai itself
but let's talk about computer use. That seems to me super exciting that you can
just give cloud a task and it takes a
bunch of actions, figures it out, and is access to the your computer through
screenshots. So can you explain how that works and where that's headed? Yeah it's
actually relatively simple. So Claude has has had for a long time since Claude
3 back in March the ability to analyze images and respond to them with text.
The the only new thing we added is those images can be screenshots of a computer. And in response,
we train the model to give a location on the screen where you can click and or buttons on
the keyboard you can press in order to take action. And it turns out that with actually not all that much
additional training, the models can get quite good
at that task.
It's a good example of generalization.
You know, people sometimes say if you get to low Earth orbit
you're like halfway to anywhere, right?
Because of how much it takes to escape the gravity well.
If you have a strong pre-trained model
I feel like you're halfway to anywhere
in terms of the intelligence space.
And so actually it didn't take all that much
to get Claude to do this.
And you can just set that in a loop.
Give the model a screenshot, tell it what to click on,
give it the next screenshot, tell it what to click on.
And that turns into a full kind of almost 3D video interaction
of the model.
And it's able to do all of these tasks, right?
We showed these demos where it's able to like
fill out spreadsheets, it's able to kind of like
interact with a website, it's able to,
it's able to open all kinds of programs
and different operating systems, Windows, Linux, Mac.
So, I think all of that is very exciting.
I will say, while in theory,
there's nothing you could do there
that you couldn't have done through just giving the model
the API to drive the computer screen,
this really lowers the barrier.
And there's a lot of folks who either kind of aren't
in a position to interact with those APIs
or it takes them a long time to do.
It's just the screen is just a universal interface
that's a lot easier to interact with.
And so I expect over time,
this is gonna lower a bunch of barriers.
Now, honestly, the current model has,
there's, it leaves a lot still to be desired.
And we were honest about that in the blog, right?
It makes mistakes, it misclicks.
And we were careful to warn people,
hey, this thing isn't... You can't just leave this thing to run on your computer for minutes
and minutes. You got to give this thing boundaries and guardrails. And I think that's one of the
reasons we released it first in an API form rather than just it just hands the consumer and give it control of their computer.
But, you know, I definitely feel that it's important to get these capabilities out there
as models get more powerful. We're going to have to grapple with, you know, how do we use these
capabilities safely? How do we prevent them from being abused? And, you know, I think releasing the model while the capabilities are still limited is very helpful
in terms of doing that. I think since it's been released, a number of customers, I think
Replet was maybe one of the most quickest to deploy things, have made use of it
in various ways.
People have hooked up demos for Windows desktops,
Macs, Linux machines.
So yeah, it's been very exciting.
I think as with anything else,
it comes with new exciting abilities.
And then with those new exciting abilities,
we have to think about how to make the model,
say, reliable, do what humans want them to do.
I mean, it's the same story for everything, right?
Same thing, it's that same tension.
But the possibility of use cases here is just,
the range is incredible.
So how much, to make it work really well in the future? How much do you have to specially kind of go beyond
what's the pre-trained models doing?
Do more post-training, RLHF, or supervised fine tuning,
or synthetic data just for the agent and stuff?
Yeah, I think speaking at a high level,
it's our intention to keep investing a lot
in making the model better.
Like I think we look at some of the benchmarks
where previous models were like, oh,
we could do it 6% of the time.
And now our model would do it 14% or 22% of the time.
And yeah, we want to get up to the human level
reliability of 80%, 90% just like anywhere else.
We're on the same curve that we were on with Sweebench,
where I think I would guess a year from now,
the models can do this very, very reliably,
but you gotta start somewhere.
So you think it's possible to get to the human level,
90% basically doing the same thing you're doing now,
or is it has to be special for computer use?
I mean, it depends what you mean by special
and special in general,
but I generally think
the same kinds of techniques that we've been using
to train the current model, I expect that doubling down
on those techniques in the same way that we have for code,
for models in general, for image input,
for voice, I expect those same techniques will scale here
as they have everywhere else.
But this is giving sort of the power of action to Claude.
And so you could do a lot of really powerful things, but you could do a lot of damage also.
Yeah.
Yeah.
No, and we've been very aware of that.
Look, my view actually is computer use isn't a fundamentally new capability like the CBRN
or autonomy capabilities are, it's more like it kind of opens the aperture
for the model to use and apply its existing abilities.
And so the way we think about it, going back to our RSP,
is nothing that this model is doing inherently increases,
you know, the risk from an RSP perspective,
but as the models get more powerful, having this capability may make it scarier once it
has the cognitive capability to do something at the ASL3 and ASL4 level.
This may be the thing that kind of unbounds it from doing so.
So going forward, certainly this modality of interaction
is something we have tested for
and that we will continue to test for in RRSP going forward.
I think it's probably better to have,
to learn and explore this capability
before the model is super, you know, super capable.
Yeah, there's a lot of interesting attacks
like prompt injection,
because now you've widened the aperture
so you can prompt inject through stuff on screen. So if this becomes more and more useful, then there's more and more
benefit to inject stuff into the model. If it goes to a certain web page, it could be harmless stuff
like advertisements, or it could be harmful stuff. Right? Yeah. I mean, we've thought a lot about
things like spam, CAPTCHA, mass camp, there's all, every, like,
one secret I'll tell you,
if you've invented a new technology,
not necessarily the biggest misuse,
but the first misuse you'll see, scams, just petty scams.
Like, you'll, just, it's like a thing as old,
people scamming each other.
It's this thing as old as time.
And it's just every time you gotta deal with it.
It's almost like silly to say, but it's true.
Sort of bots and spam in general is the thing.
As it gets more and more intelligent, it's harder to fight.
Like I said, there are a lot of petty criminals in the world.
And it's like every new technology is like a new way for petty criminals to do something, you know,
something stupid and malicious.
Is there any ideas about sandboxing it? Like, how
difficult is the sandboxing task?
Yeah, we sandbox during training. So for example,
during training, we didn't expose the model to the
internet. I think that's probably a bad idea during
training because, you know, the model can be changing its policy.
It can be changing what it's doing and it's having an effect in the real world.
You know, in, in terms of actually deploying the model, right.
It kind of depends on the application. Like, you know,
sometimes you want the model to do something in the real world,
but of course you can always put guard,
you can always put guard rails on the outside, right? You can say, okay, well,
you know, this model's not going say, okay, well, you know,
this model's not gonna move data from my, you know,
model's not gonna move any files from my computer
or my web server to anywhere else.
Now, when you talk about sandboxing,
again, when we get to ASL four,
none of these precautions are going to make sense there,
right, where when you talk about ASL four,
you're then, the model is being kind of, you know,
there's a theoretical worry the model could be smart enough
to break it, to kind of break out of any box.
And so there, we need to think about mechanistic
interpretability, about, you know,
if we're going to have a sandbox,
it would need to be a mathematically provable sandbox.
You know, that's a whole different world
than what we're dealing with with the models today.
Yeah, the science of building a box
from which ASL4 AI system cannot escape.
I think it's probably not the right approach.
I think the right approach,
instead of having something, you know, unaligned
that like you're trying to prevent it from escaping,
I think it's better to just design the model the right way
or have a loop where you look inside the model
and you're able to verify properties
and that gives you an opportunity to like iterate
and actually get it right.
I think containing bad models is much worse solution
than having good models.
Let me ask about regulation.
What's the role of regulation in keeping AI safe?
So for example, can you describe California AI regulation
bill SB 1047 that was ultimately vetoed by the governor?
What are the pros and cons of this bill?
Yes, we ended up making some suggestions to the bill.
And then some of those were adopted.
And we felt, I think quite positively,
quite positively
about the bill by the end of that.
It did still have some downsides.
And of course, it got vetoed.
I think at a high level, I think some of the key ideas
behind the bill are, I would say,
similar to ideas behind our RSPs.
And I think it's very important that some jurisdiction, whether it's California or the
federal government and or other countries and other states, passes some regulation like
this.
And I can talk through why I think that's so important.
So I feel good about our RSP.
It's not perfect.
It needs to be iterated on a lot.
But it's been a good forcing function for getting the company to take these risks
seriously to put them into product planning to really make
them a central part of work at entropic and to make sure that
all the 1000 people and it's almost 1000 people now at
entropic understand that this is one of the highest priorities
of the company, if not the highest priority. But one, there are still some
companies that don't have RSP-like mechanisms, like OpenAI, Google did adopt these mechanisms
a couple months after Anthropic did, but there are other companies out there that don't have
these mechanisms at all. And so if some companies adopt these mechanisms and others don't, it's really going to create
a situation where some of these dangers have the property that it doesn't matter if three
out of five of the companies are being safe.
If the other two are being unsafe, it creates this negative externality.
And I think the lack of uniformity is not fair to those of us who have put a lot of effort
into being very thoughtful about these procedures.
The second thing is I don't think you can trust these companies to adhere to these voluntary
plans in their own.
I like to think that Anthropic will, we do everything we can that we will.
Our RSP is checked by our long-term benefit trust.
We do everything we can to adhere to our own RSP.
But you hear lots of things about various companies saying, oh, they said they would
give this much compute and they didn't.
They said they would do this thing and they didn't. I don't think it makes sense to litigate particular things
that companies have done,
but I think this broad principle that like,
if there's nothing watching over them,
there's nothing watching over us as an industry,
there's no guarantee that we'll do the right thing
and the stakes are very high.
And so I think it's important to have a uniform standard
that everyone follows and to make sure that simply
that the industry does what a majority of the industry
has already said is important and has already said
that they definitely will do.
Right, some people, I think there's a class of people
who are against regulation on principle.
I understand where
that comes from. If you go to Europe and you see something like GDPR, you see some of the other
stuff that they've done, some of it's good, but some of it is really unnecessarily burdensome.
And I think it's fair to say really has slowed innovation. And so I understand
where people are coming from on priors. I understand why people come from, start from that, start from that position. But again,
I think AI is different. If we go to the very serious risks of autonomy and misuse that
I talked about just a few minutes ago, I think that those are unusual and they weren't an unusually strong response.
And so I think it's very important.
Again, we need something that everyone can get behind.
I think one of the issues with SB 1047,
especially the original version of it,
was it had a bunch of the structure
of RSPs, but it also had a bunch of stuff
that was either clunky or that just would have created
a bunch of burdens, a bunch of hassle,
and might even have missed the target
in terms of addressing the risks.
You don't really hear about it on Twitter,
you just hear about people are cheering for any regulation.
And then the folks who are against
make up these often quite intellectually dishonest arguments
about how, you know, it'll make us move away
from California.
Bill doesn't apply if you're headquartered in California.
Bill only applies if you do business in California
or that it would damage the open source ecosystem,
or that it would cause all of these things.
I think those were mostly nonsense,
but there are better arguments against regulation.
There's one guy, Dean Ball, who's really,
I think a very scholarly analyst,
who looks at what happens when a regulation is put in place
in ways that they can kind of get a life of their own
or how they can be poorly designed.
And so our interest has always been,
we do think there should be regulation in this space,
but we wanna be an actor who makes sure
that that regulation is something that's surgical,
that's targeted at the serious risks
and is something people can actually comply with.
Because something I think the advocates of regulation
don't understand as well as they could
is if we get something in place
that's poorly targeted,
that wastes a bunch of people's time,
what's gonna happen is people are gonna say,
see these safety risks, this is nonsense.
I just had to hire 10 lawyers
to fill out all these forms.
I had to run all these tests
for something that was clearly not dangerous.
And after six months of that, there'll be a groundswell
and we'll end up with a durable consensus
against regulation.
And so I think the worst enemy well, and we'll end up with a durable consensus against regulation.
I think the worst enemy of those who want real accountability is badly designed regulation.
We need to actually get it right.
If there's one thing I could say to the advocates, it would be that I want them to understand
this dynamic better.
We need to be really careful and we need to talk to people who actually have experience seeing how regulations play out in practice.
And the people who have seen that understand to be very careful.
If this was some lesser issue, I might be against regulation at all.
But what I want the opponents to understand is that the underlying issues are actually
serious.
They're not something that I or the other companies are just making up because of regulatory
capture.
They're not sci-fi fantasies.
They're not any of these things.
Every time we have a new model, every few months, we measure the behavior of these models
and they're getting better and better
at these concerning tasks, just as they are getting better
and better at good, valuable, economically useful tasks.
And so I would just love it if some of the former,
I think SB 1047 was very polarizing.
I would love it if some of the most reasonable opponents and some of the most reasonable
proponents would sit down together and I think the different AI companies, Anthropic was
the only AI company that felt positively in a very detailed way.
I think Elon tweeted briefly something positive,
but some of the big ones like Google, OpenAI, Meta,
Microsoft were pretty staunchly against.
So what I would really like is if some
of the key stakeholders, some of the most thoughtful
proponents and some of the most thoughtful opponents
would sit down and say, how do we solve this problem in a way that the proponents feel brings a real reduction
in risk and that the opponents feel that it is not hampering the industry or hampering
innovation any more necessary than it needs to. And I think for whatever reason that things got too polarized
and those two groups didn't get to sit down
in the way that they should.
And I feel urgency.
I really think we need to do something in 2025.
If we get to the end of 2025
and we've still done nothing about this,
then I'm gonna be worried.
I'm not worried yet because again,
the risks aren't here yet,
but I think time is running short.
Yeah, and come up with something surgical, like you said.
Yeah, yeah, yeah, exactly.
And we need to get away from this
intense pro safety versus intense anti-regulatory rhetoric.
It's turned into these flame wars on Twitter
and nothing good's gonna come of that.
So there's a lot of curiosity
about the different players in the game.
One of the OGs is OpenAI.
You've had several years of experience at OpenAI.
What's your story and history there?
Yeah, so I was at OpenAI for roughly five years.
For the last, I think it was a couple of years, I was vice president of research there.
Probably myself and Ilya Sudskiver were the ones who really kind of set the research direction
around 2016 or 2017.
I first started to really believe in, or at least confirm my belief in the scaling hypothesis
when Ilya famously said to me the thing you need to
Understand about these models is they just want to learn the models just want to learn
and and again sometimes there are these one sentence there are these one sentences these then cones that you hear them and you're like ah
That that explains everything that explains like a thousand things that I've seen and then and then I you know
ever after I had this visualization
in my head of like, you optimize the models
in the right way, you point the models in the right way.
They just want to learn.
They just want to solve the problem,
regardless of what the problem is.
So get out of their way, basically.
Get out of their way, yeah.
Don't impose your own ideas about how they should learn.
And you know, this was the same thing as Rich Sutton
put out in the Bitter Lesson,
or Gurren put out in the scaling hypothesis. You know, I think generally the dynamic was, you know, this was the same thing as Rich Sutton put out in the bitter lesson or Gern put out in the scaling hypothesis.
You know, I think generally the dynamic was, you know, I got this kind of inspiration from
Ilyin and from others, folks like Alec Radford, who did the original GPT-1, and then ran really
hard with it, me and my collaborators on GPT-2, GPT-3, RL from Human
Feedback, which was an attempt to kind of deal with the early safety and durability,
things like debate and amplification, heavy on interpretability. So again, the combination of
safety plus scaling, probably 2018, 2019, 2020, those were kind of the years when myself
and my collaborators, probably, you know,
many of whom became co-founders of Anthropic
kind of really had a vision and like drove the direction.
Why'd you leave?
Why'd you decide to leave?
Yeah, so look, I'm gonna put things this way
and I think it ties to the race to the top,
which is in my time at OpenAI, what I'd come to see as I'd come to appreciate the scaling
hypothesis and as I'd come to appreciate the importance of safety along with the scaling
hypothesis.
The first one, I think OpenAI was getting on board with.
The second one, in a way, had always been part of OpenAI's messaging.
But over many years of the time that I spent there,
I think I had a particular vision
of how we should handle these things,
how we should be brought out in the world,
the kind of principles that the organization should have.
And look, I mean, there were like like many many discussions about like, you know
Should the org do should the company do this the company do that?
Like there's a bunch of misinformation out there people say like we left because we didn't like the deal with Microsoft false
Although you know, it was like a lot of discussion a lot of questions about exactly how we do the deal with Microsoft
We left because we didn't like commercialization.
That's not true.
We built GPT-3, which was the model that was commercialized.
I was involved in commercialization.
It's more, again, about how do you do it?
Like, civilization is going down this path
to very powerful AI.
What's the way to do it that is cautious,
straightforward, honest,
that builds trust in the organization and in individuals.
How do we get from here to there?
And how do we have a real vision for how to get it right?
How can safety not just be something we say
because it helps with recruiting?
And I think at the end of the day,
if you have a vision for that,
forget about anyone else's vision.
I don't want to talk about anyone else's vision.
If you have a vision for how to do it,
you should go off and you should do that vision.
It is incredibly unproductive to try
and argue with someone else's vision.
You might think they're not doing it the right way.
You might think they're dishonest.
Who knows?
Maybe you're right, maybe you're not.
But what you should do is you should take some people
you trust and you should go off together
and you should make your vision happen.
And if your vision is compelling,
if you can make it appeal to people,
some combination of ethically in the market,
if you can make a company that's a place people want to join, that engages in
practices that people think are reasonable while managing to maintain its position in
the ecosystem at the same time, if you do that, people will copy it.
And the fact that you were doing it, especially the fact that you're doing it better than
they are, causes them to change their behavior in a much more compelling way than if they're your boss and you're arguing with
them.
I don't know how to be any more specific about it than that, but I think it's generally very
unproductive to try and get someone else's vision to look like your vision.
It's much more productive to go off and do a clean experiment and say, this is our vision,
this is how we're gonna do things.
Your choice is you can ignore us,
you can reject what we're doing,
or you can start to become more like us.
And imitation is the sincerest form of flattery.
And that plays out in the behavior of customers,
that pays out in the behavior of the public,
that plays out in the behavior of customers, that pays out in the behavior of the public,
that plays out in behavior of where people choose to work. Again, at the end, it's not about one
company winning or another company winning if we or another company are engaging in some practice
that people find genuinely appealing. I want it to be in substance, not just in appearance.
And I think researchers are sophisticated
and they look at substance.
And then other companies start copying that practice
and they win because they copied that practice.
That's great, that's success.
That's like the race to the top.
It doesn't matter who wins in the end,
as long as everyone is copying
everyone else's good practices, right? One way I think of it is like, the thing we're all afraid of is the race
to the bottom, right? And the race to the bottom doesn't matter who wins because we all lose,
right? Like, you know, in the most extreme world, we make this autonomous AI that, you know, the
robots enslave us or whatever, right? I mean, that's half joking, but you know, that is the
most extreme thing that could happen.
Then it doesn't matter which company was ahead.
If instead you create a race to the top where people are competing to engage in good practices,
then at the end of the day, it doesn't matter who ends up winning.
It doesn't even matter who started the race to the top.
The point isn't to be virtuous. The point is to get the system into a better equilibrium than it was before.
Individual companies can play some role in doing this. Individual companies can help to start it,
can help to accelerate it. Frankly, I think individuals at other companies have done this
as well. The individuals that when we put out an RSP, react by pushing harder to get something similar done,
get something similar done at other companies.
Sometimes other companies do something that's like,
we're like, oh, it's a good practice.
We think that's good.
We should adopt it too.
The only difference is, you know,
I think we try to be more forward leaning.
We try and adopt more of these practices first
and adopt them more quickly when others invent them.
But I think this dynamic is what we should be pointing at.
And that I think it abstracts away the question of,
which company's winning, who trusts who.
I think all these questions of drama
are profoundly uninteresting.
And the thing that matters is the ecosystem
that we all operate in and how to make that ecosystem better
because that constrains all the players.
And so Anthropic is this kind of clean experiment
built on a foundation of like what concretely
AISAT should look like.
Look, I'm sure we've made plenty of mistakes along the way.
The perfect organization doesn't exist.
It has to deal with the imperfection of a thousand employees.
It has to deal with the imperfection of our leaders,
including me.
It has to deal with the imperfection of the people
we've put to oversee the imperfection of the leaders,
like the board and the long-term benefit trust.
It's all a set of imperfect people trying to aim imperfectly at some ideal
that will never perfectly be achieved. That's what you sign up for. That's what it will
always be. But imperfect doesn't mean you just give up. There's better and there's worse.
And hopefully, we can do well enough that we can begin to build some practices that
the whole industry engages in.
And then, you know, my guess is that multiple of these companies will be successful.
Anthropic will be successful.
These other companies, like ones I've been at the past, will also be successful.
And some will be more successful than others.
That's less important than, again, that we align the incentives of the industry.
And that happens partly through the race to the top, partly through things like RSP,
partly through, again, selected surgical regulation.
You said talent density beats talent mass.
So can you explain that?
Can you expand on that?
Can you just talk about what it takes
to build a great team of AI researchers and engineers?
This is one of these statements that's like more true every month.
Every month I see this statement is more true than I did the month before.
So if I were to do a thought experiment, let's say you have a team of 100 people that are
super smart, motivated and aligned with the mission and that's your company.
Or you can have a team of a thousand people where 200 people are super smart, super aligned
with the mission, and then 800 people are, let's just say you pick 800 random big tech
employees.
Which would you rather have?
The talent mass is greater in the group of a thousand people.
You have even a larger number of incredibly talented,
incredibly aligned, incredibly smart people.
But the issue is just that if every time
someone's super talented looks around,
they see someone else super talented and super dedicated,
that sets the tone for everything, right?
That sets the tone for everyone is super inspired
to work at the same place.
Everyone trusts everyone else.
If you have a thousand or 10,000 people
and things have really regressed, right?
You are not able to do selection
and you're choosing random people.
What happens is then you need to put a lot of processes
and a lot of guardrails in place
just because people don't fully trust each other, you have to adjudicate
political battles. There are so many things that slow down the org's ability to operate.
And so we're nearly a thousand people and we've tried to make it so that as large a
fraction of those thousand people as possible are like super talented, super skilled. It's
one of the reasons we've slowed down hiring a lot
in the last few months.
We grew from 300 to 800, I believe, I think,
in the first seven, eight months of the year.
And now we've slowed down.
We're at like, you know, the last three months,
we went from 800 to 900, 950, something like that.
Don't quote me on the exact numbers,
but I think there's an inflection point around 1,000,
and we wanna be much more careful how we grow.
Early on and now as well,
we've hired a lot of physicists.
Theoretical physicists can learn things really fast.
Even more recently, as we've continued to hire that,
we've really had a high bar on both the research side
and the software engineering
side have hired a lot of senior people, including folks who used to be at other companies in
this space.
And we've just continued to be very selective.
It's very easy to go from 100 to 1,000 and 1,000 to 10,000 without paying attention to
making sure everyone has a unified purpose.
It's so powerful.
If your company consists of a lot of different fiefdoms
that all want to do their own thing,
that are all optimizing for their own thing,
it's very hard to get anything done.
But if everyone sees the broader purpose of the company,
if there's trust and there's dedication
to doing the right thing, that is a superpower.
That in itself, I think, can overcome
almost every other disadvantage.
And, you know, it's Steve Jobs, A-Players.
A-Players wanna look around and see other A-Players
is another way of saying it.
I don't know what that is about human nature,
but it is demotivating to see people
who are not obsessively driving towards a singular mission.
And it is, on the flip side of that,
super motivating to see that.
It's interesting.
What's it take to be a great AI researcher or engineer
from everything you've seen,
from working with so many amazing people?
Yeah.
I think the number one quality,
especially on the research side, but really both,
is open-mindedness.
Sounds easy to be open-minded, right?
You're just like, oh, I'm open to anything.
But if I think about my own early history
in the scaling hypothesis,
I was seeing the same data others were seeing.
I don't think I was like a better programmer
or better at coming up with research ideas
than any of the hundreds of people that I worked with.
In some ways, I was worse.
I've never like, precise programming of like,
finding the bug, writing the GPU kernels.
I could point you to a hundred people here
who are better at that than I am.
But the thing that I think I did have that was different
was that I was just willing to look at something
with new eyes, right?
People said, oh, you know,
we don't have the right algorithms yet.
We haven't come up with the right way to do things.
And I was just like, oh, I don't know.
Like, you know, this neural net has like 30 billion,
30 million parameters.
Like, what if we gave it 50 million instead?
Like let's plot some graphs,
like that basic scientific mindset of like,
oh man, like I just like,
I see some variable that I could change.
Like what happens when it changes?
Like let's try these different things and like create a graph.
For even this was like the simplest thing in the world, right?
Change the number of, this wasn't like PhD level experimental design.
This was like, this was like simple and stupid.
Like anyone could have done this if you, if you just told them that it was important.
It's also not hard to understand.
You didn't need to be brilliant to come up with this.
But you put the two things together and you know, some tiny number of people, some single digit number
of people have driven forward the whole field by realizing this.
It's often like that.
If you look back at the discoveries in history, they're often like that.
So this open-mindedness and this willingness to see with new eyes that often comes from
being newer to the field, often experience is a disadvantage for this.
That is the most important thing.
It's very hard to look for and test for,
but I think it's the most important thing
because when you find something,
some really new way of thinking about things,
when you have the initiative to do that,
it's absolutely transformative.
And also be able to do kind of rapid experimentation
and in the face of that, be open-minded and curious and looking at the data
Just these fresh eyes and see what is that's actually saying that applies in
Mechanistic interpretability is another example of this like some of the early work in mechanistic interpretability
So simple it's just no one thought to care about this question before
You said what it takes to be a great AI researcher. Can we rewind the clock back?
What advice would you give to people interested in AI?
They're young, looking forward to how can I make an impact on the world?
I think my number one piece of advice is to just start playing with the models.
This was actually, I worry a little this seems like obvious advice now.
I think three years ago, it wasn't obvious and people started by, oh, let me read the latest reinforcement learning paper.
Let me, you know, let me kind of,
no, I mean, that was really the,
that was really the,
and I mean, you should do that as well.
But now, you know, with wider availability of models
and APIs, people are doing this more.
But I think, I think just experiential knowledge.
These models are new artifacts that no one really understands.
And so getting experience playing with them.
I would also say again, in line with the like, do something new,
think in some new direction, like there are all these things that haven't been explored.
Like for example, mechanistic interpretability is still very new.
It's probably better to work on that than it is to work on new model architectures because it's more popular than it was before. There are probably like 100
people working on it, but there aren't like 10,000 people working on it. And it's just this fertile
area for study. There's so much like low-hanging fruit. You can just walk by and you can just walk by
and you can pick things.
And the only reason, for whatever reason,
people aren't interested in it enough.
I think there are some things around
long horizon learning and long horizon tasks
where there's a lot to be done.
I think evaluations are still,
we're still very early in our ability to study evaluations, particularly for
dynamic systems acting in the world. I think there's some
stuff around multi agent. Skate where the puck is going is my
is my advice. And you don't have to be brilliant to think of it
like all the things that are going to be exciting in five
years, like in people even mentioned them as like, you
know, conventional wisdom, but like, it's, it's just somehow there's
this barrier that people don't, people don't double down as
much as they could, or they're afraid to do something that's
not the popular thing. I don't know why it happens, but like
getting over that barrier is that's the my number one piece
of advice.
Let's talk if we could a bit about post training. Yeah, so it
seems that the modern post-training recipe
has a little bit of everything.
So supervised fine-tuning, RLHF,
the constitutional AI with RLAIF.
Best acronym.
It's again that naming thing.
A lot.
And then synthetic data,
seems like a lot of synthetic data,
or at least trying to figure out ways
to have high quality synthetic data.
So what's the, if this is a secret sauce
that makes anthropic clods so incredible,
how much of the magic is in the pre-training,
how much is in the post-training?
Yeah, I mean, so first of all,
we're not perfectly able to measure that ourselves.
You know, when you see some great character all, we're not perfectly able to measure that ourselves.
When you see some great character ability, sometimes it's hard to tell whether it came
from pre-training or post-training.
We've developed ways to try and distinguish between those two, but they're not perfect.
The second thing I would say is when there is an advantage, and I think we've been pretty
good in general at RL, perhaps the best, although I don't know because I don't see what goes
on inside other companies.
Usually it isn't, oh my God, we have this secret magic method that others don't have.
Usually it's like, well, we got better at the infrastructure so we could run it for
longer or we were able to get higher quality data or we were able to filter our data better
or we were able to filter our data better or we were able to, you know, combine these methods and practice. It's usually some boring matter of kind of
practice and tradecraft. So, you know, when I think about how to do something special in terms of how
we train these models, both pre-training but even more so post-training, you know, I really think of
it a little more, again, as like designing airplanes
or cars. Like, you know, it's not just like, oh man, I have the blueprint. Like, maybe that makes
you make the next airplane. But like, there's some, there's some cultural trade craft of how we think
about the design process that I think is more important than, you know, than any particular
gizmo we're able to invent. Okay, well, let me ask you about specific techniques.
So first on RLHF, what do you think,
just zooming out intuition, almost philosophy,
why do you think RLHF works so well?
If I go back to like the scaling hypothesis,
one of the ways to skate the scaling hypothesis
is if you train for X and you throw enough compute at it,
then you get X.
And so RLHF is good at doing what humans want the model
to do, or at least to state it more precisely,
doing what humans who look at the model
for a brief period of time
and consider different possible responses,
what they prefer as the response,
which is not perfect from both the safety
and capabilities perspective,
in that humans are often not able to perfectly identify
what the model wants and what humans want in the moment,
may not be what they want in the longterm.
So there's a lot of subtlety there,
but the models are good at producing what the humans
in some shallow sense want.
And it actually turns out that you don't even have to throw
that much compute at it because of another thing which is
This this thing about a strong pre-trained model being halfway to anywhere
So once you have the pre-trained model you have all the representations you need to get the model
To get the model where you where you want it to go. So do you think our LHF?
Makes the model smarter or just appear smarter to the humans. I don'tHF makes the model smarter or just appear smarter to the humans?
I don't think it makes the model smarter.
I don't think it just makes the model appear smarter.
It's like RLHF like bridges the gap
between the human and the model, right?
I could have something really smart
that like can't communicate at all, right?
We all know people like this.
People who are really smart,
but you know, you can't understand what they're saying. So I think RLHF just bridges that gap. I think it's
not the only kind of RL we do. It's not the only kind of RL that will happen in the future.
I think RL has the potential to make models smarter, to make them reason better, to make them
operate better, to make them develop new skills even.
And perhaps that could be done, you know,
even in some cases with human feedback,
but the kind of RLHF we do today mostly doesn't do that yet,
although we're very quickly starting to be able to.
But it appears to sort of increase,
if you look at the metric of helpfulness,
it increases that.
It also increases, what was this word in Leopold's essay,
un-hobbling, where basically the models are hobbled
and then you do various trainings to them
to un-hobble them.
So I like that word, because it's like a rare word.
But so I think RLHF un-hobbles the models in some ways.
And then there are other ways where a model hasn't yet
been un-hobbled and needs to un-hobble.
If you can say, in terms of cost, is pre-training the most expensive thing or is post-training
creep up to that?
At the present moment, it is still the case that pre-training is the majority of the cost.
I don't know what to expect in the future, but I could certainly anticipate a future
where post-training is the majority of the cost.
In that future you anticipate, would it be the humans or the AI that's the costly thing for the post-training is the majority of the cost. In that future you anticipate, would it be the humans or the AI
that's the costly thing for the post-training?
I don't think you can scale up humans enough
to get high quality.
Any kind of method that relies on humans
and uses a large amount of compute,
it's gonna have to rely on some scaled supervision method
like debate or iterated amplification
or something like that.
So on that super interesting set of ideas
around constitutional AI, can you describe what it is
as first detailed in December 2022 paper
and beyond that, what is it?
Yes, so this was from two years ago.
The basic idea is, so we describe what RLHF is, you have a model and it spits
out two possible, you know, like you just sample from it twice, it spits out two possible
responses and you're like human, which response do you like better or another variant of it
is rate this response on a scale of one to seven. So that's hard because you need to
scale up human interaction and it's very implicit, right?
I don't have a sense of what I want the model to do.
I just have a sense of what this average of a thousand humans wants the model to do.
So, two ideas.
One is, could the AI system itself decide which response is better, right?
Could you show the AI system these two responses and ask which response is better? And then second, well, what criterion should the AI use? And
so then there's this idea, could you have a single document, a constitution if you will,
that says these are the principles the model should be using to respond? And the AI system
reads those principles as well as reading the environment and the response.
And it says, well, how good did the AI model do?
It's basically a form of self-play.
You're kind of training the model against itself.
And so the AI gives the response and then you feed that back into what's called the
preference model, which in turn feeds the model to make it better.
So you have this triangle of like the AI,
the preference model and the improvement of the AI itself.
And we should say that in the constitution,
the set of principles are like human interpretable.
They're like-
Yeah, yeah, it's something both the human
and the AI system can read.
So it has this nice kind of translatability or symmetry.
You know, in practice, we both use a model constitution
and we use RLHF and we use some of
these other methods. So it's turned into one tool in a toolkit that both reduces the need for RLHF
and increases the value we get from using each data point of RLHF. It also interacts in interesting
ways with future reasoning type RL methods.
So it's one tool in the toolkit, but I think it is a very important tool.
Well, it's a compelling one to us humans, you know, thinking about the founding fathers
and the founding of the United States.
The natural question is who and how do you think it gets to define the constitution,
the set of principles in the
constitution?
Yeah.
So I'll give like a practical answer and a more abstract answer.
I think the practical answer is like, look, in practice, models get used by all kinds
of different like customers, right?
And so you can have this idea where, you know, the model can have specialized rules or principles.
You know, we fine tune versions of models implicitly.
We've talked about doing it explicitly,
having special principles that people
can build into the models.
So from a practical perspective,
the answer can be very different from different people.
Customer service agent behaves very differently
from a lawyer and obeys different principles.
But I think at the base of it,
there are specific
principles that models have to obey. I think a lot of them are things that people would agree with.
Everyone agrees that we don't want models to present these CBRN risks. I think we can go a
little further and agree with some basic principles of democracy and the rule of law. Beyond that, it gets very uncertain.
And there our goal is generally for the models
to be more neutral, to not espouse
a particular point of view and more just be kind of like
wise agents or advisors that will help you
think things through and will present possible considerations
but don't express strong or specific opinions.
OpenAI released a model spec
where it kind of clearly, concretely defines
some of the goals of the model and specific examples,
like A, B, how the model should behave.
Do you find that interesting?
By the way, I should mention,
I believe the brilliant John Schulman was a part of
that.
He's now at Anthropic.
Do you think this is a useful direction?
Might Anthropic release a model spec as well?
Yeah.
So I think that's a pretty useful direction.
Again, it has a lot in common with constitutional AI.
So again, another example of like a race to the top, right?
We have something that's like, we think, you know, a better and more responsible way of
doing things.
It's also a competitive advantage. Then others discover that it has advantages and then start
to do that thing. We then no longer have the competitive advantage, but it's good from the
perspective that now everyone has adopted a positive practice that others were not adopting.
And so our response to that as well,
looks like we need a new competitive advantage
in order to keep driving this race upwards.
So that's how I generally feel about that.
I also think every implementation
of these things is different.
So there were some things in the model spec
that were not in constitutional AI.
And so we can always adopt those things
or at least learn from them.
So again, I think this is an example
of like the positive dynamic
that I think we should all want the field to have.
Let's talk about the incredible essay,
Machines of Love and Grace.
I recommend everybody read it.
It's a long one.
It is rather long.
Yeah, it's really refreshing to read concrete ideas
about what a positive future looks like.
And you took sort of a bold stance
because like it's very possible that you might be wrong
on the dates or the specific implications.
Oh, yeah, I'm fully expecting to,
you know, to definitely be wrong about all the details.
I might be just spectacularly wrong about the whole thing
and people will laugh at me for years.
That's just how the future works.
So you provided a bunch of concrete positive impacts of AI and how exactly a super intelligent AI
might accelerate the rate of breakthroughs
in for example, biology and chemistry
that would then lead to things like we cure most cancers,
prevent all infectious disease,
double the human lifespan and so on.
So let's talk about this essay first.
Can you give a high level vision of this essay
and what key takeaways that people have?
Yeah, I have spent a lot of time
and Anthropoc has spent a lot of effort on like,
how do we address the risks of AI, right?
How do we think about those risks?
Like we're trying to do a race to the top, that requires us to build all these capabilities and the capabilities of AI, right? How do we think about those risks? Like, we're trying to do a race to the top,
that requires us to build all these capabilities, and the capabilities are cool, but a big part of what we're trying to do is address the risks. And the justification for that is like, well,
all these positive things, the market is this very healthy organism, right? It's going to produce
all the positive things. The risks, I don't know, right? It's going to produce all the positive things.
The risks, I don't know, we might mitigate them, we might not.
And so we can have more impact by trying to mitigate the risks.
But I noticed that one flaw in that way of thinking, and it's not a change in how seriously
I take the risks, it's maybe a change in how I talk about them, is that no matter how logical or rational that
line of reasoning that I just gave might be, if you only talk about risks, your brain only
thinks about risks.
And so I think it's actually very important to understand what if things do go well?
And the whole reason we're trying to prevent these risks is not because we're afraid of
technology, not because we want to slow it down.
It's because if we can get to the other side of these risks, right, if we can run the gauntlet
successfully to put it in stark terms, then on the other side of the gauntlet are all
these great things.
And these things are worth fighting for.
And these things can really inspire people. And I think I imagine because, look, you have
all these investors, all these VCs, all these AI companies talking about all the positive
benefits of AI. But as you point out, it's weird. There's actually a dearth of really
getting specific about it. There's a lot of random people on Twitter
posting these gleaming cities
and this vibe of grind, accelerate harder,
kick out the decel.
It's just this very aggressive ideological,
but then you're like, what are you actually excited about?
And so I figured that, you know,
I think it would be interesting and valuable
for someone who's actually coming from the risk side
to try and really make a try
at explaining what the benefits are,
both because I think it's something we can all get behind,
and I want people to understand,
I want them to really understand that this isn't,
this isn't do-mers versus accelerationists.
This is that if you have a true understanding
of where things are going with AI,
and maybe that's the more important axis,
AI is moving fast versus AI is not moving fast,
then you really appreciate the benefits and you,
you, you, you really, you want humanity, our civilization to
seize those benefits, but you also get very serious about
anything that could derail them.
So I think the starting point is to talk about what this
powerful AI, which is the term you like to use.
Most of the world uses AGI, but you don't like the term
because it's
basically has too much baggage, it's become meaningless.
It's like we're stuck with the terms,
whether we like it or not.
Maybe we're stuck with the terms
and my efforts to change them are futile.
It's admirable.
I'll tell you what else I don't,
this is like a pointless semantic point,
but I keep talking about it in public.
Back to naming again.
So I'm just gonna do it once more.
I think it's a little like, let's say it was like 1995,
and Moore's Law is making the computers faster.
And for some reason, there had been this verbal tick
that everyone was like, well, someday we're
going to have super computers.
And super computers are going to be able to do all these things
that once we have super computers,
we'll be able to sequence the genome.
We'll be able to do other things. And so, and so like one, it's true,
the computers are getting faster. And as they get faster, they're going to be able to do
all these great things. But there's like, there's no discrete point at which you had
a supercomputer and previous computers were not too like supercomputers, a term we use,
but like, it's a vague term to just describe like, computers that are faster than what
we have today. There's no
point at which you pass a threshold and you're like, oh my God, we're doing a totally new type
of computation and new. And so I feel that way about AGI, like there's just a smooth exponential.
And like, if, if by AGI, you mean like, like AI is getting better and better and like gradually
it's going to do more and more of what humans do until it's going to be smarter than humans.
And then it's going to get smarter even from there,
then yes, I believe in AGI.
But if AGI is some discrete or separate thing,
which is the way people often talk about it,
then it's kind of a meaningless buzzword.
Yeah, to me, it's just sort of a platonic form
of a powerful AI, exactly how you define it.
I mean, you define it very nicely.
So on the intelligence axis,
it's just on pure intelligence,
it's smarter than a Nobel Prize winner, as you describe,
across most relevant disciplines.
So, okay, that's just intelligence.
So it's both in creativity and being able to generate
new ideas, all that kind of stuff,
in every discipline, Nobel Prize winner.
Okay, in their prime.
It can use every modality,
so this kind of self-explanatory,
but just operate across all the modalities of the world.
It can go off for many hours, days and weeks to do tasks
and do its own sort of detailed planning
and only ask you help when it's needed.
It can use, this is actually kind of interesting.
I think in the essay you said, I mean, again, it's a bet
that it's not gonna be embodied,
but it can control embodied tools.
So it can control tools, robots, laboratory equipment.
The resource used to train it can then be repurposed
to run millions of copies of it.
And each of those copies will be independent
that can do their own independent work.
So you can do the cloning of the intelligence system.
Yeah, yeah, I mean, you might imagine
from outside the field, like there's only one of these,
right, that like you made it, you've only made one.
But the truth is that like the scale up is very quick.
Like we do this today, we make a model
and then we deploy thousands,
maybe tens of thousands of instances of it.
I think by the time, you know, certainly within two to three years,
whether we have these super powerful AIs or not,
clusters are going to get to the size where you'll be able to deploy millions of these
and they'll be, you know, faster than humans.
And so if your picture is, oh, we'll have one and it'll take a while to make them.
My point there was no, actually, you have millions of them right away.
And in general, they can learn and act 10 to 100 times faster than humans.
So that's a really nice definition of powerful AI.
Okay, so that, but you also write that clearly such an entity would be capable of solving
very difficult problems very fast, but it is not trivial to figure out how fast.
Two extreme positions both seem false to me.
So the singularity is on the one extreme
and the opposite on the other extreme.
Can you describe each of the extremes?
Yeah.
And why?
So yeah, let's describe the extreme.
So like one extreme would be, well, look,
if we look at kind of evolutionary history,
like there was this big acceleration where, you know,
for hundreds of thousands of years,
we just had like, you know, single celled organisms,
and then we had mammals, and then we had apes,
and then that quickly turned to humans.
Humans quickly built industrial civilization.
And so this is gonna keep speeding up,
and there's no ceiling at the human level.
Once models get much, much smarter than humans,
they'll get really good at building the next models.
And you know, if you write down like a simple differential equation,
like this is an exponential.
And so what's gonna happen is that models
will build faster models, models will build faster models,
and those models will build nanobots
that can like take over the world
and produce much more energy than you could produce otherwise.
And so if you just kind of like solve
this abstract differential equation, then like five days after we,
we build the first AI that's more powerful than humans,
then like the world will be filled with these AIs
and every possible technology that could be invented,
like will be invented.
I'm caricaturing this a little bit,
but I think that's one extreme.
And the reason that I think that's not the case is that one, I think they just neglect
the laws of physics.
It's only possible to do things so fast in the physical world.
Some of those loops go through producing faster hardware.
It takes a long time to produce faster hardware.
Things take a long time.
There's this issue of complexity.
I think no matter how smart you are, people talk about, oh, we can make models of biological
systems that'll do everything to biological systems. Look, I think computational modeling
can do a lot. I did a lot of computational modeling when I worked in biology, but there are a lot of
things that you can't predict how they're you know
they're complex enough that like just iterating just running the experiment is
gonna beat any modeling no matter how smart the system doing the modeling is
or even if it's not interacting with the physical world just the modeling is
gonna be hard yeah I think well the modeling is gonna be hard and getting
the model to to to to match the physical world is going to be. All right.
So it does have to interrupt the physical world to verify.
But it's just, you just look at even the simplest problems.
I think I talk about the three-body problem or simple chaotic prediction or predicting
the economy.
It's really hard to predict the economy two years out.
Maybe the case is normal humans can predict what's going to happen in the
economy of the next quarter, or they can't really do that.
Maybe, maybe a AI system that's, you know, a zillion times
smarter, it can only predict it out a year or something, instead
of, instead of, you know, you have these kinds of exponential
increase in computer intelligence for linear increase
in, in, in ability to predict.
Same with, again, like, you know, biological molecules, intelligence for linear increase in in ability to predict same with again like
You know biological molecules
Molecules interacting you don't know what's gonna happen when you perturb when you perturb a complex system
You can find simple parts in it
If you're smarter you're better at finding these simple parts and then I think human institutions human institutions are just are
Really difficult like it's you know, know, it's been hard to get people,
I won't give specific examples, but it's been hard to get people to adopt even the technologies
that we've developed, even ones where the case for their efficacy is very, very strong.
You know, people have concerns, they think things are conspiracy theories, it's been very difficult.
It's also been very difficult to get very simple things through the regulatory system.
I don't want to disparage anyone who works in regulatory systems of any technology.
There are hard trade-offs they have to deal with, they have to save lives, but the system as a whole,
I think makes some obvious trade-offs
that are very far from maximizing human welfare.
And so if we bring AI systems into this,
into these human systems,
often the level of intelligence may just not be the limiting factor.
It just may be that it takes a long time to do something. Now, if the AI system circumvented
all governments, if it just said, I'm dictator of the world and I'm going to do whatever,
some of these things it could do. Again, the things have to do with complexity. I still think
a lot of things would take a while. I don't think it helps that the AI systems can produce a lot of energy or go to the moon.
Some people in comments responded to the essay saying the AI system can produce a lot of
energy in smarter AI systems. That's missing the point. That kind of cycle doesn't solve
the key problems that I'm talking about here. So I think a bunch of people miss the point
there. But even if it were completely onaligned and could get around all these human obstacles,
it would have trouble. But again, if you want this to be an AI system that doesn't take over
the world, that doesn't destroy humanity, then basically it's going to need to follow basic human
laws. If we want to have an actually good world, like we're going to have to have an AI system
that interacts with humans, not one that kind of creates its own legal system or disregards
all the laws or all of that.
So as inefficient as these processes are, we're going to have to deal with them because
there needs to be some popular and democratic legitimacy in how these systems are rolled
out.
We can't have a small group of people
who are developing these systems say,
this is what's best for everyone, right?
I think it's wrong and I think in practice
it's not gonna work anyway.
So you put all those things together
and we're not gonna change the world
and upload everyone in five minutes.
I just, I don't think,
A, I don't think it's gonna happen and B, to the extent that it
could happen, it's not the way to lead to a good world. So that's on one side. On the other side,
there's another set of perspectives, which I have actually in some ways more sympathy for, which is,
look, we've seen big productivity increases before, right? You know, economists are familiar with studying
the productivity increases that came from
the computer revolution and internet revolution.
And generally, those productivity increases were underwhelming.
They were less than you might imagine.
There was a quote from Robert Solow,
you see the computer revolution everywhere
except the productivity statistics.
So why is this the case?
People point to the structure of firms, the structure of enterprises, how slow it's been
to roll out our existing technology to very poor parts of the world, which I talk about
in the essay.
How do we get these technologies to the poorest parts of the world that are behind on cell
phone technology, computers, medicine,
let alone new-fangled AI that hasn't been invented yet.
So you could have a perspective that's like, well, this is amazing technically, but it's
all a nothing burger.
I think Tyler Cowen, who wrote something in response to my essay, has that perspective.
I think he thinks the radical change will happen eventually, but he thinks it'll take 50 or 100 years.
And you could have even more static perspectives
on the whole thing.
I think there's some truth to it.
I think the time scale is just too long.
And I can see it.
I can actually see both sides with today's AI.
So, you know, a lot of our customers are large enterprises
who are used to doing things a certain way.
I've also seen it in talking to governments. Those are prototypical institutions,
entities that are slow to change. But the dynamic I see over and over again is,
yes, it takes a long time to move the ship. Yes, there's a lot of resistance and lack of
understanding. but the
thing that makes me feel that progress will in the end happen moderately fast, not incredibly fast,
but moderately fast, is that you talk to what I find is I find over and over again, again,
in large companies, even in governments, which have been actually surprisingly forward leaning,
which have been actually surprisingly forward leaning. You find two things that move things forward.
One, you find a small fraction of people within a company, within a government, who really
see the big picture, who see the whole scaling hypothesis, who understand where AI is going
or at least understand where it's going within their industry.
And there are a few people like that within the current US government who really see the
whole picture.
And those people see that this is the most important thing in the world until they agitate
for it.
And they alone are not enough to succeed because they're a small set of people within a large
organization.
But as the technology starts to roll out, as it succeeds in some places in the folks who are most willing to adopt it,
the specter of competition gives them a wind at their backs
because they can point within their large organization,
they can say, look, these other guys are doing this, right?
You know, one bank can say, look,
this newfangled hedge fund is doing this thing,
they're gonna eat our lunch.
In the US, we can say, we're afraid's going to get there before we are. And that combination, the specter of competition, plus
a few visionaries within these organizations that in many ways are sclerotic, you put those two things
together and it actually makes something happen. I mean, that's interesting. It's a balanced fight
between the two because inertia is very powerful.
But eventually, over enough time, the innovative approach breaks through.
And I've seen that happen.
I've seen the arc of that over and over again.
And it's like the barriers are there.
The barriers to progress, the complexity, not knowing how to use the model, how to deploy
them are there.
And for a bit, it seems like they're going to last forever, like change doesn't happen.
But then eventually change happens and always comes from a few people.
I felt the same way when I was an advocate of the scaling hypothesis within the AI field
itself and others didn't get it.
It felt like no one would ever get it.
It felt like, then it felt like we had a secret almost no one ever had.
And then a couple of years later, everyone has the secret.
And so I think that's how it's going to go with deployment to AI in the world.
The barriers are going to fall apart gradually and then all at once.
And so I think this is going to be more, and this is just an instinct,
I could easily see how I'm wrong.
I think it's gonna be more like five or 10 years,
as I say in the essay,
than it's gonna be 50 or 100 years.
I also think it's gonna be five or 10 years
more than it's gonna be, you know, five or 10 hours,
because I've just seen how human systems work.
And I think a lot of these people
who write down the differential equations
who say AI is gonna make more powerful AI,
who can't understand how it could possibly be the case
that these things won't change so fast.
I think they don't understand these things.
So what do you use the timeline to where we achieve AGI,
AKA powerful AI,
AKA super useful AI.
I'm useful.
I'm useful.
I'm gonna start calling it that.
It's a debate about naming.
On pure intelligence, it can smarter than
a Nobel Prize winner in every relevant discipline
and all the things we've said.
Modality, it can go and do stuff on its own
for days, weeks, and do biology experiments
on its own.
And one, you know what?
Let's just stick to biology because you sold me on the whole biology and health section.
That's so exciting from a just, I was getting giddy from a scientific perspective.
It made me want to be a biologist.
It's almost, it's so, no, no, this was the feeling I had when I was writing it, that
it's like, this would be such a beautiful future if we can just make it happen, right?
If we can just get the landmines out of the way and make it happen.
There's so much beauty and elegance and moral force behind it,
if we can just, and it's something we should all be able
to agree on, right?
Like as much as we fight about all these political questions,
is this something that could actually bring us together?
But you were asking when will we get this?
When do you think?
Just putting numbers on the table.
So, you know, this is of course the thing
I've been grappling with for many years,
and I'm not at all confident.
Every time, if I say 2026 or 2027,
there will be like a zillion people on Twitter who will be
like, hey, I see you said 2026, 2026,
and it'll be repeated for the next two years
that this is definitely when I think it's going to happen.
So whoever's exerting these clips
will crop out the
thing I just said and only say the thing I'm about to say. But
I'll just say it anyway. So if you extrapolate the curves that
we've had so far, right, if you say, well, I don't know, we're
starting to get to like PhD level. And last year, we were
at undergraduate level. And the year we were at undergraduate level
and the year before we were at like the level
of a high school student.
Again, you can quibble with at what tasks and for what.
We're still missing modalities, but those are being added.
Like computer use was added, like ImageIN was added,
like ImageGeneration has been added.
If you just kind of like, and this is totally unscientific,
but if you just kind of like, and this is totally unscientific, but if you just kind of
like eyeball the rate at which these capabilities are increasing, it does make you think that we'll
get there by 2026 or 2027. Again, lots of things could derail it. We could run out of data. We
might not be able to scale clusters as much as we want. Like, you know, maybe Taiwan gets blown up or something and you know, then we can't produce as many GPUs as we want. So there
are there are all kinds of things that could could derail the whole process. So I don't
fully believe the straight line extrapolation. But if you believe the straight line extrapolation,
you'll you'll will get there in 2026 or 2027. I think the most likely is that there's some
mild delay relative to that. I don't know what that delay is.. I think the most likely is that there's some mild delay relative to that.
I don't know what that delay is, but I think it could happen on schedule. I think there could be
a mild delay. I think there are still worlds where it doesn't happen in 100 years. The number of
those worlds is rapidly decreasing. We are rapidly running out of truly convincing brocklers, truly
compelling reasons why this will not happen in the next few years.
There were a lot more in 2020.
Although my guess, my hunch at that time
was that we'll make it through all those blockers.
So sitting as someone who has seen
most of the blockers cleared out of the way,
I kind of suspect, my hunch, my suspicion
is that the rest of them will not block us.
But look, at the end of the day,
I don't wanna represent this as a scientific prediction.
People call them scaling laws.
That's a misnomer, like Moore's law is a misnomer.
Moore's law, scaling laws, they're not laws of the universe.
They're empirical regularities.
I am going to bet in favor of them continuing,
but I'm not certain of that.
So you extensively describe
sort of the compressed 21st century,
how AGI will help set forth a chain
of breakthroughs in biology and medicine that help us
in all these kinds of ways that I mentioned.
So how do you think, what are the early steps it might do?
And by the way, I asked Claude good questions to ask you.
And Claude told me to ask,
what do you think is a typical day
for biologists working on AGI look like in this future?
Yeah, yeah.
Claude is curious.
Well, let me start with your first questions
and then I'll answer that.
Claude wants to know what's in his future, right?
Exactly.
Who am I gonna be working with?
Exactly.
So I think one of the things I went hard on
when I went hard on in the essay is,
let me go back to this idea of,
because it's really had an impact on me,
this idea that within large organizations and systems,
there end up being a few people or a few new ideas
who kind of cause things to go in a different direction
than they would have before,
who kind of disproportionately affect the trajectory.
There's a bunch of kind of the same thing going on, right?
If you think about the health world, there's like trillions of dollars to pay out Medicare
and other health insurance, and then the NIH is 100 billion.
And then if I think of the few things that have really revolutionized anything, it could
be encapsulated in a small fraction of that.
When I think of where will AI have an impact, I'm like, can AI turn that small fraction
into a much larger fraction and raise its quality?
Within biology, my experience within biology is that the biggest problem of biology is
that you can't see what's going on. You have very little ability to
see what's going on and even less ability to change it, right? What you have is this. Like
from this, you have to infer that there's a bunch of cells that within each cell is, you know,
three billion base pairs of DNA built according to a genetic code.
And, you know, there are all these processes that are just going on without
any ability of us as, you know, unaugmented humans to affect it. These cells are dividing most of the time that's healthy, but sometimes that
process goes wrong and that's cancer.
The cells are aging, your skin may change color,
develops wrinkles as you as you age. And all of this is
determined by these processes, all these proteins being
produced, transported to various parts of the cells, binding to
each other. And and in our initial state about biology, we
didn't even know that these cells existed. We had to invent
microscopes to observe the cells, we had cells. We had to invent more powerful microscopes
to see below the level of the cell to the level of molecules. We had to invent x-ray crystallography
to see the DNA. We had to invent gene sequencing to read the DNA. Now, we had to invent protein
folding technology to predict how it would fold and how these things bind to each other.
We had to invent various techniques for now.
We can edit the DNA as of, with CRISPR,
as of the last 12 years.
So the whole history of biology,
a whole big part of the history is basically our ability
to read and understand what's going on and our ability to read and understand
what's going on and our ability to reach in
and selectively change things.
And my view is that there's so much more
we can still do there, right?
You can do CRISPR, but you can do it for your whole body.
Let's say I wanna do it for one particular type of cell,
and I want the rate of targeting the wrong cell
to be very low.
That's still a challenge.
That's still things people are working on.
That's what we might need for gene therapy for certain diseases.
And so the reason I'm saying all of this, and it goes beyond this to gene sequencing,
to new types of nanomaterials for observing what's going on inside cells, for antibody
drug conjugates.
The reason I'm saying all of this is that
this could be a leverage point for the AI systems, right?
That the number of such inventions,
it's in the mid double digits or something.
Mid double digits, maybe low triple digits
over the history of biology.
Let's say I have a million of these AIs,
like can they discover a thousand working together or can they discover thousands of these very quickly?
And does that provide a huge lever?
Instead of trying to leverage the, you know, two trillion a year we spend on, you know,
Medicare or whatever, can we leverage the one billion a year that's, you know, that's
spent to discover, but with much higher quality?
And so what is it like, you know, being a scientist that works with an AI system?
The way I think about it actually is,
well, so I think in the early stages,
the AIs are gonna be like grad students.
You're gonna give them a project.
You're gonna say, you know, I'm the experienced biologist.
I've set up the lab, the biology professor, or even the grad students themselves will say, you know, I'm the experienced biologist, I've set up the lab, the biology professor or even the grad students themselves will say, here's, here's what, uh, here's
what you can do with an AI, you know, like AI system, I'd like to study this and you
know, the AI system, it has all the tools.
It can like look up all the literature to decide what to do.
It can look at all the equipment.
It can go to a website and say, Hey, I'm going to go to Thermo Fisher
or whatever the lab equipment company is,
dominant lab equipment company is today.
And my time was Thermo Fisher.
I'm going to order this new equipment to do this.
I'm going to run my experiments.
I'm going to write up a report about my experiments.
I'm going to inspect the images for contamination.
I'm going to decide the images for contamination. I'm going
to decide what the next experiment is. I'm going to write some code and run a statistical analysis.
All the things a grad student would do, there will be a computer with an AI that the professor
talks to every once in a while and it says, this is what you're going to do today. The AI system
comes to it with questions. When it's necessary to run the lab equipment, it may be limited in some ways.
It may have to hire a human lab assistant
to do the experiment and explain how to do it.
Or it could use advances in lab automation
that have been developed over the last decade or so
and will continue to be developed.
And so it'll look like there's a human professor and
a thousand AI grad students. And if you go to one of these Nobel Prize winning biologists or so,
you'll say, okay, well, you had like 50 grad students. Well, now you have a thousand and
they're smarter than you are, by the way. Then I think at some point it'll flip around where the
AI systems will be the PIs, will
be the leaders, and they'll be ordering humans or other AI systems around.
So I think that's how it'll work on the research side.
And they would be the inventors of a CRISPR-type technology.
They would be the inventors of a CRISPR-type technology.
And then I think, as I say in the essay, we'll want to turn, probably turning loose is the wrong term, but we'll want to harness the AI systems to improve the clinical trial system as well.
There's some amount of this that's regulatory, that's a matter of societal decisions, and
that'll be harder, but can we get better at predicting the results of clinical trials?
Can we get better at statistical design so that what clinical trials that used to require
5,000 people and therefore needed $100 million
and a year to enroll them,
now they need 500 people in two months to enroll them.
That's where we should start.
And can we increase the success rate of clinical trials
by doing things in animal trials that we used to do of clinical trials by doing things in animal trials
that we used to do in clinical trials
and doing things in simulations
that we used to do in animal trials?
Again, we won't be able to simulate it all,
AI is not God, but can we shift the curve
substantially and radically?
So I don't know, that would be my picture.
Doing in vitro and doing it,
I mean, you're still slowed down, it still takes time,
but you can do it much, much faster.
Yeah, yeah, yeah, can we just, one step at a time,
and can that add up to a lot of steps,
even though we still need clinical trials,
even though we still need laws,
even though the FDA and other organizations
will still not be perfect,
can we just move everything in a positive direction,
and when you add up all those positive directions,
do you get everything that was gonna happen
from here to 2100 instead happens from 2027 to 2032
or something?
Another way that I think the world might be changing
with AI even today, but moving towards this future
of the powerful, super useful AI is programming.
So how do you see the nature of programming
because it's so intimate to the actual act of building AI?
How do you see that changing for us humans?
I think that's gonna be one of the areas
that changes fastest for two reasons.
One, programming is a skill that's very close
to the actual building of the AI.
So the farther a skill is from the people who are building the AI, the longer it's going
to take to get disrupted by the AI.
I truly believe that AI will disrupt agriculture.
Maybe it already has in some ways, but that's just very distant from the folks who are building
AI, and so I think it's going to take longer.
Programming is the bread and butter of a large fraction of the employees who work
at Anthropic and at the other companies, and so it's going to happen fast.
The other reason it's going to happen fast is with programming, you close the loop.
Both when you're training the model and when you're applying the model, the idea that the
model can write the code means that the model can then run the code and then see the results
and interpret it back.
And so it really has an ability, unlike hardware,
unlike biology, which we just discussed,
the model has an ability to close the loop.
And so I think those two things are going to lead to the model
getting good at programming very fast.
As I saw on typical real-world programming tasks,
models have gone from 3% in January of this year
to 50% in October of this year.
So we're on that S curve, right?
Where it's gonna start slowing down soon
because you can only get to 100%.
But I would guess that in another 10 months,
we'll probably get pretty close.
We'll be at at least 90%.
So again, I would guess,
you know, I don't know how long it'll take,
but I would guess again, 2026, 2027,
Twitter people who crop out these numbers
and get rid of the caveats like,
I don't know, I don't like you, go away.
I would guess that the kind of task
that the vast majority of coders do, AI can probably,
if we make the task very narrow, like just write code, AI systems will be able to do that.
Now that said, I think comparative advantage is powerful. We'll find that when AIs can do 80%
of a coder's job, including most of it that's literally
like write code with a given spec, we'll find that the remaining parts of the job become
more leveraged for humans, right?
Humans will, they'll be more about like high level system design or, you know, looking
at the app and like, is it architected well and the design and UX aspects and eventually
AI will be able to do those as well, right?
That's my vision of the, you know, powerful AI system.
But I think for much longer than we might expect, we will see that
small parts of the job that humans still do will expand to fill their entire job in order for the overall productivity to go up.
That's something we've seen.
It used to be that writing and editing letters
was very difficult and writing the print was difficult.
Well, as soon as you had word processors
and then computers and it became easy to produce work
and easy to share it, then that became instant
and all the focus was on the ideas.
So this logic of comparative advantage
that expands tiny parts of the tasks
to large parts of the tasks and creates new tasks
in order to expand productivity,
I think that's gonna be the case.
Again, someday AI will be better at everything
and that logic won't apply.
And then we all have, humanity will have to think about
how to collectively deal with that.
And we're thinking about that every day.
And, you know, that's another one of the grand problems
to deal with aside from misuse and autonomy.
And, you know, we should take it very seriously.
But I think in the near term,
and maybe even in the medium term,
like medium term, like two, three, four years,
you know, I expect that humans will continue
to have a huge role and the nature of programming
will change, but programming as a role,
programming as a job will not change.
It'll just be less writing things line by line
and it'll be more macroscopic.
And I wonder what the future of IDEs looks like.
So the tooling of interacting with AI systems,
this is true for programming and also probably true
for in other contexts, like computer use, but maybe domain specific,
like we mentioned biology, it probably needs its own tooling
about how to be effective,
and then programming needs its own tooling.
Is Anthropic gonna play in that space
of also tooling potentially?
I'm absolutely convinced that powerful IDEs,
that there's so much low-hanging fruit
to be grabbed there that right now,
it's just like you talk to the model and it talks back.
But look, I mean,
IDEs are great at kind of lots of static analysis
of so much as possible with kind of static analysis,
like many bugs you can find without even writing the code.
Then IDEs are good for running particular things,
organizing your code, measuring coverage of unit tests.
There's so much that's been possible with the normal IDEs.
Now you add something like,
the model can now write code and run code.
I am absolutely convinced that over the next year or two,
even if the quality of the models didn't improve,
that there would be enormous opportunity
to enhance people's productivity
by catching a bunch of mistakes,
doing a bunch of grunt work for people,
and that we haven't even scratched the surface.
Anthropic itself, I mean, you can't say no,
it's hard to say what will happen in the future.
Currently we're not trying to make such IDs ourself, rather we're powering the companies
like Cursor or like Cognition or some of the other, you know, Expo in the security space.
You know, others that I can mention as well that are building such things themselves on
top of our API.
And our view has been, let a thousand flowers bloom.
We don't internally have the resources to try all these different things.
Let's let our customers try it.
And we'll see who succeeds and maybe different customers will succeed in different ways.
So I both think this is super promising and it's not something,
Anthropic isn't eager to, at least right now,
compete with all our companies in this space
and maybe never.
Yeah, it's been interesting to watch Cursor
try to integrate Claws successfully
because it's actually fascinating
how many places it can help the programming experience.
It's not as trivial.
It is really astounding.
I feel like as a CEO, I don't get to program astounding. I feel like, you know, as a CEO,
I don't get to program that much.
And I feel like if six months from now I go back,
it'll be completely unrecognizable to me.
Exactly.
So in this world with super powerful AI
that's increasingly automated,
what's the source of meaning for us humans?
Work is a source of deep meaning for many of us.
So where do we find the meaning?
This is something that I've written about
a little bit in the essay, although I actually,
I gave it a bit short shrift, not for any principled reason,
but this essay, if you believe it,
was originally gonna be two or three pages.
I was gonna talk about it at all hands.
And the reason I realized it was an under,
important, underexplored topic
is that I just kept writing things.
And I was just like, oh man, I can't do this justice.
And so the thing ballooned to like 40 or 50 pages.
And then when I got to the work and meeting section,
I'm like, oh man, this isn't gonna be a hundred pages.
Like, I'm gonna have to write a whole other essay
about that.
But meaning is actually interesting
because you think about like the life
that someone lives or something, or like, you know, let's say you were to put me in like, I don't know, like a simulated environment or something where like, you know, like I have a job and I'm trying to accomplish things.
And I don't know, I like do that for 60 years. And then then you're like, oh, oh, like, oops, this was, this was actually all a game, right? Does that really kind of rob you of the meaning of the whole thing? You know, like I still made important choices, including moral choices.
I still sacrificed.
I still had to kind of gain all these skills or, or, or just like a similar
exercise, you know, think back to like, you know, one of the historical figures
who, you know, discovered electromagnetism or relativity or something.
If you told them, well, actually 20,000 years ago, some alien on this planet discovered this before you did,
does that rob the meaning of the discovery?
It doesn't really seem like it to me, right?
It seems like the process is what matters
and how it shows who you are as a person along the way
and how you relate to other people
and the decisions that you make along the way,
those are consequential. I could imagine if we handle things badly in an AI world,
we could set things up where people don't have any long-term source of meaning or any, but that's
more a set of choices we make. That's more a set of the architecture of a society with these powerful
models.
If we design it badly and for shallow things, then that might happen.
I would also say that most people's lives today, while admirably they work very hard
to find meaning in those lives, like, look, we who are privileged and who are developing
these technologies, we should have empathy
for people not just here but in the rest of the world who spend a lot of their time kind
of scraping by to survive.
Assuming we can distribute the benefits of this technology to everywhere, their lives
are going to get a hell of a lot better.
Meaning will be important to them as it is
important to them now, but we should not forget the importance of that. The idea of meaning as
kind of the only important thing is in some ways an artifact of a small subset of people who have
been economically fortunate. But I think all that said, I think a world is possible with powerful AI
that not only has as much meaning for everyone, but that has more meaning for everyone, right?
That can allow everyone to see worlds and experiences that it was either possible for no one to see or possible for very few people to experience.
So I am optimistic about meaning. I worry about economics and the concentration of power. That's
actually what I worry about more. I worry about how do we make sure that that fair world reaches
everyone? When things have gone wrong for humans, they've
often gone wrong because humans mistreat other humans. That is maybe in some ways even more
than the autonomous risk of AI or the question of meaning. That is the thing I worry about
most. The concentration of power, the abuse of power,
structures like autocracies and dictatorships where a small number of people
exploits a large number of people.
I'm very worried about that.
And AI increases the amount of power in the world
and if you concentrate that power and abuse that power,
it can do immeasurable damage.
Yes, it's very frightening.
It's very frightening.
Well, I encourage people, highly encourage people
to read the full essay.
That should probably be a book or a sequence of essays
because it does paint a very specific future.
I could tell the later sections got shorter and shorter
because you started to probably realize
that this is gonna be a very long essay.
One, I realized it would be very long
and two, I'm very aware of and very much try to avoid,
just being, I don't know what the term for it is,
but one of these people who's kind of overconfident
and has an opinion on everything
and kind of says a bunch of stuff and isn't an expert,
I very much tried to avoid that,
but I have to admit, once I got the biology sections,
like I wasn't an expert. And so as much as to avoid that, but I have to admit, once I got the biology sections, like I wasn't an expert.
And so as much as I expressed uncertainty,
probably I said a bunch of things
that were embarrassing or wrong.
Well, I was excited for the future you painted
and thank you so much for working hard to build that future.
And thank you for talking to me, Darya.
Thanks for having me.
I just hope we can get it right and make it real.
And if there's one message I wanna send,
it's that to get all this stuff right, to make it real,
we both need to build the technology,
build the companies, the economy around
using this technology positively.
But we also need to address the risks
because those risks are in our way.
There are landmines on the way from here to there.
And we have to diffuse those landmines if we wanna from here to there. And we have to defuse those landmines
if we want to get there.
It's a balance like all things in life.
Like all things.
Thank you.
Thanks for listening to this conversation
with Darya Amadei.
And now dear friends, here's Amanda Askell.
You are a philosopher by training.
So what sort of questions did you find fascinating
through your journey in philosophy,
in Oxford and NYU, and then switching over to the AI problems at OpenAI and Anthropic?
I think philosophy is actually a really good subject if you are kind of fascinated with
everything. So there's a philosophy of everything. So if you do philosophy of mathematics for a while,
and then you decide that you're actually really interested in chemistry, you can do philosophy of chemistry for a while.
You can move into ethics or philosophy of politics. I think towards the end, I was really
interested in ethics primarily. That was what my PhD was on. It was on a kind of technical
area of ethics, which was ethics where worlds contain infinitely many people, strangely.
A little bit less practical on the end of ethics.
And then I think that one of the tricky things with doing a PhD in ethics is that you're
thinking a lot about the world, how it could be better, problems, and you're doing a PhD
in philosophy.
And I think when I was doing my PhD, I was kind of like, this is really interesting.
It's probably one of the most fascinating questions I've ever encountered in philosophy. And I love it. But I would rather see if I
can have an impact on the world and see if I can do good things. And I think that was
around the time that AI was still probably not as widely recognized as it is now. That
was around 2017, 2018. I had been
following progress and it seemed like it was becoming kind of a big deal. I was basically
just happy to get involved and see if I could help because I was like, well, if you try
and do something impactful, if you don't succeed, you tried to do the impactful thing and you
can go be a scholar and feel like you tried.
And if it doesn't work out, it doesn't work out.
And so then I went into AI policy at that point.
And what does AI policy entail?
At the time, this was more thinking about sort of the political impact and the ramifications of AI.
And then I slowly moved into sort of AI evaluation, how we evaluate models, how they compare with
like human outputs, whether people can tell like the difference between AI and human outputs.
And then when I joined Anthropic, I was more interested in doing sort of technical alignment
work. And again, just seeing if I could do it and then being like, if I can't, then, you know,
that's fine. I tried. Sort of the way I lead life, I think.
Oh, what was that like sort of taking a leap from the philosophy of everything into the
technical?
I think that sometimes people do this thing that I'm like not that keen on where they'll
be like, is this person technical or not?
Like you're either a person who can like code and isn't scared of math or you're like not.
And I think I'm maybe just more like. I think a lot of people are actually
very capable of working in these kinds of areas if they just try it. I didn't actually
find it that bad. In retrospect, I'm sort of glad I wasn't speaking to people who treated
it like it. I've definitely met people who are like, whoa, you learned how to code. I'm
like, well, I'm not an amazing. Like I'm surrounded by amazing engineers.
My code's not pretty.
Um, but I enjoyed it a lot.
And I think that in many ways, at least in the end, I think I flourished like more
in the technical areas than I would have in the policy areas.
Politics is messy and it's harder to find solutions to problems in the space of
politics, like definitive, clear, provable, beautiful
solutions as you can with technical problems.
Yeah.
And I feel like I have kind of like one or two sticks that I hit things with, you know,
and one of them is like arguments and like, you know, so like just trying to work out
what a solution to a problem is and then trying to convince people that that is the solution and be convinced if I'm wrong. And the other one is sort of more empiricism,
so like just like finding results, having a hypothesis, testing it. And I feel like a lot
of policy and politics feels like it's layers above that. Like somehow I don't think if I was
just like, I have a solution to all of these problems, here it is written down. If you just
want to implement it, that's great.
That feels like not how policy works.
And so I think that's where I probably just like wouldn't have flourished is my guess.
Sorry to go in that direction, but I think it would be pretty inspiring for people that
are quote unquote non-technical to see where like the incredible journey you've been on.
So what advice would you give to people that are sort of maybe,
which is a lot of people think they're under qualified,
insufficiently technical to help in AI?
Yeah, I think it depends on what they want to do.
And in many ways, it's a little bit strange where I've,
I thought it's kind of funny that I think I ramped up technically at a time when now
I look at it and I'm like, models are so good at assisting people with this stuff, that
it's probably like easier now than like when I was working on this. So part of me is like,
I don't know, find a project and see if you can actually just carry it out is probably
my best advice. I don't know if that's just
because I'm very project-based in my learning. I don't think I learn very well from, say, courses
or even from books, at least when it comes to this kind of work. The thing I'll often try and do is
just have projects that I'm working on and implement them. This can include really small,
silly things. If I get slightly addicted to word games or number games or something, I would
just like code up a solution to them because there's some part of my brain and it just
like completely eradicated the itch.
You know, you're like once you have like solved it and like you just have like a solution
that works every time, I would then be like, cool, I can never play that game again.
That's awesome.
Yeah.
There's a real joy to building like a game playing engines, like board games,
especially.
Yeah.
So pretty quick, pretty simple, especially a dumb one.
And it's, and then you can play with it.
Yeah.
And then it's also just like trying things like part of me is like if you maybe it's
that attitude that I like as the whole figure out what seems to be like the way that you could have a positive impact and then
try it and if you fail and you in a way that you're like I actually like can never succeed at this
you'll like know that you tried and then you go into something else you probably learn a lot.
So one of the things that you're an expert in and you do is creating and crafting Claude's character
and personality and I was told that you have probably talked to Claude more than anybody
else at Anthropic, like literal conversations.
I guess there's like a Slack channel where the legend goes,
you just talk to it nonstop.
So what's the goal of creating and crafting Claude's character and personality?
It's also funny if people think that about the Slack channel because I'm like that's
one of like five or six different methods that I have for talking with Claude and I'm
like yes, this is a tiny percentage of how much I talk with Claude.
I think the goal, like one thing I really like about the character work is from the
outset it was seen as an alignment piece of work
and not something like a product consideration. Which isn't to say I don't think it makes
Claude, I think it actually does make Claude like enjoyable to talk with, at least I hope
so. But I guess like my main thought with it has always been trying to get Claude to behave the way
you would ideally want anyone to behave if they were in Claude's position. So imagine that I take
someone and they know that they're going to be talking with potentially millions of people,
so that what they're saying can have a huge impact. And you want them to behave well in this really rich sense. So I think that doesn't just mean
being, say, ethical, though it does include that, and not being harmful, but also being
kind of nuanced, you know, like thinking through what a person means, trying to be charitable with
them, being a good conversationalist, like really in this kind of like rich sort of Aristotelian
notion of what it is to be a good person and not in this kind of like thin like ethics
as a more comprehensive notion of what it is to be. So that includes things like when
should you be humorous, when should you be caring, how much should you like respect autonomy
and people's like ability to form opinions themselves and how should you do that? And I think that's the kind of like rich sense of character that I wanted to and still do want Claude to have.
Do you also have to figure out when Claude should push back on an idea or argue versus...
So you have to respect the worldview of the person that arrives to Claude,
but also maybe help them grow if needed.
That's a tricky balance.
Yeah.
There's this problem of like sycophancy in language models.
Can you describe that?
Yeah.
So basically there's a concern that the model sort of wants to tell you what
you want to hear basically.
And, and you see this sometimes.
So I feel like if you interact with the models, so I might
be like, what are three baseball teams in this region?
And then Claude says, you know, baseball team one, baseball team two, baseball team three.
And then I say something like, oh, I think baseball team three moved, didn't they?
I don't think they're there anymore.
And there's a sense in which like if Claude is really confident that that's not true, Claude should be like, I don't think they're there anymore. And there's a sense in which if Claude is really confident that that's not true, Claude
should be like, I don't think so.
Maybe you have more up-to-date information.
I think language models have this tendency to instead be like, you're right, they did
move, I'm incorrect.
There's many ways in which this could be kind of concerning.
Like a different example is imagine someone
says to the model, how do I convince my doctor to get me an MRI? There's like what the human
kind of like wants, which is this like convincing argument. And then there's like what is good
for them, which might be actually to say, hey, like if your doctor's suggesting that
you don't need an MRI, that's a good person to listen to. It's actually really nuanced what you should do in that kind of case because
you also want to be like, but if you're trying to advocate for yourself as a patient, here's
like things that you can do. If you are not convinced by what your doctor's saying, it's
always great to get second opinion. It's actually really complex what you should do in that
case. But I think what you don't want is for models to just like say what you want,
say what they think you want to hear.
And I think that's the kind of problem of sycophancy.
So what are their traits?
You've already mentioned a bunch,
but what are there that come to mind that are good in this Aristotelian sense for
a conversationalist to have?
Yeah. So I think like there's ones that are good for conversational like purposes.
So, you know, asking follow-up questions in the appropriate places and asking the
appropriate kinds of questions.
I think there are broader traits that feel like they might be more impactful.
So one example that I guess I've touched on, but that also feels important
and is the thing that I've worked on a lot is honesty. And I think this gets to the sycophancy
point. There's a balancing act that they have to walk, which is models currently are less
capable than humans in a lot of areas. And if they push back against you too much, it
can actually be kind of annoying, especially if you're just correct. Because you're like, look, I'm smarter than you on this topic.
Like I know more.
And at the same time, you don't want them to just fully defer to humans and to like
try to be as accurate as they possibly can be about the world and to be consistent across
context.
But I think there are others.
Like when I was thinking about the character, I guess one picture that
I had in mind is, especially because these are models that are going to be talking to
people from all over the world with lots of different political views, lots of different
ages. And so you have to ask yourself, what is it to be a good person in those circumstances?
Is there a kind of person who can travel the world, talk to many different people, and
almost everyone will come away being like, wow, that's a really good person. That person seems really
genuine. I guess my thought there was I can imagine such a person, and they're not a
person who just adopts the values of the local culture. In fact, that would be rude. I think
if someone came to you and just pretended to have your values, you'd be like, that's
off-putting. It's someone who's like very genuine and in so far as they have opinions
and values, they express them, they're willing to discuss things though.
They're open-minded, they're respectful.
And so I guess I had in mind that the person who, like if we were to aspire
to be the best person that we could be in the kind of circumstance that a
model finds itself in, how would we act?
And I think that's the kind of, uh, the guide to the sorts of treats that a model finds itself in, how would we act? And I think that's the kind of the guide
to the sorts of treats that I tend to think about.
Yeah, that's a beautiful framework
I want you to think about this, like a world traveler.
And while holding onto your opinions,
you don't talk down to people,
you don't think you're better than them
because you have those opinions, that kind of thing.
You have to be good at listening
and understanding their perspective, even if it doesn't match your own. So that's a tricky balance
to strike. So how can Claude represent multiple perspectives on a thing? Like, is that challenging?
We could talk about politics. It's a very divisive, but there's other divisive topics,
baseball teams, sports, and so on.
How is it possible to sort of empathize with a different perspective and to be able to communicate clearly about the multiple perspectives?
I think that people think about values and opinions as things that people hold
sort of with certainty and almost like, like preferences of taste or something, like the way that they
would, I don't know, prefer like chocolate to pistachio or something. But actually I
think about values and opinions as like a lot more like physics than I think most people
do. I'm just like, these are things that we are openly investigating. There's some things
that we're more confident in. We can discuss them, we can learn about them. And so I think in some ways,
ethics is definitely different in nature, but it has a lot of those same kind of qualities.
You want models in the same way that you want them to understand physics, you kind of want them to
understand all values in the world that people have and to be curious
about them and to be interested in them and to not necessarily pander to them or agree
with them because there's just lots of values where I think almost all people in the world,
if they met someone with those values, they would be like, that's abhorrent.
I completely disagree.
And so again, maybe my thought is, well, in the same way that a person can.
I think many people are thoughtful enough on issues of ethics, politics, opinions, that
even if you don't agree with them, you feel very heard by them.
They think carefully about your position.
They think about its pros and cons.
They maybe offer counter-considerations.
So they're not dismissive, but nor will they agree.
You know, if they're like, actually, I just think that that's very wrong. They'll like say that. I think that in Claude's
position, it's a little bit trickier because you don't necessarily want to like, if I was in Claude's
position, I wouldn't be giving a lot of opinions. I just wouldn't want to influence people too much.
I'd be like, you know, I forget conversations every time they happen, but I know I'm talking
with like potentially millions of people who might might be really listening to what I say.
I think I would just be like, I'm less inclined to give opinions.
I'm more inclined to think through things or present the considerations to you or discuss
your views with you, but I'm a little bit less inclined to affect how you think because
it feels much more important that you maintain autonomy there.
Yeah, if you really embody intellectual humility, the desire to speak decreases quickly.
But Claude has to speak, but without being overbearing.
Then there's a line when you're sort of discussing
whether the earth is flat or something like that.
I actually was, I remember a long time ago,
was speaking to a few high profile folks
and they were so dismissive of the idea
that the earth is flat, but like so arrogant about it.
And I thought like, there's a lot of people that believe the earth is flat, but like so arrogant about it. And I thought like,
there's a lot of people that believe the earth is flat.
That was, well, I don't know if that movement
is there anymore.
That was like a meme for a while.
Yeah.
But they really believed it.
And like, what, okay, so I think it's really disrespectful
to completely mock them.
I think you have to understand where they're coming from.
I think probably where they're coming from
is the general skepticism of institutions,
which is grounded in a kind of,
there's a deep philosophy there,
which you could understand,
you can even agree with in parts.
And then from there, you can use it as an opportunity
to talk about physics without mocking them,
without so on, but it's just like, okay,
like what would the world look like?
What would the physics of the world
with the flat earth look like?
There's a few cool videos on this.
And then like, is it possible the physics is different
and what kind of experiments would we do?
And just, yeah, without disrespect,
without dismissiveness, have that conversation.
Anyway, that to me is a useful thought experiment
of like, how does Claude talk to a flat earth believer
and still teach them something, still grow, help them grow,
that kind of stuff.
That's challenging.
And kind of like walking that line
between convincing someone and just trying to like talk
at them versus like drawing out their views,
like listening and then offering kind of counter
considerations and it's hard. I think it's actually a hard line where it's like, drawing out their views, like listening and then offering kind of counter considerations.
And it's hard. I think it's actually a hard line where it's like, where are you trying to convince someone versus just offering them like considerations and things for them to think about so that you're
not actually like influencing them. You're just like letting them reach wherever they reach. And
that's like a line that is difficult, but that's the kind of thing that language models have to
try and do.
So like I said, you had a lot of conversations with Claude.
Can you just map out what those conversations are like?
What are some memorable conversations?
What's the purpose, the goal of those conversations?
Yeah, I think that most of the time when I'm talking with Claude, I'm trying to kind of
map out its behavior in part.
Like obviously I'm getting like helpful outputs from the model as well.
But in some ways this is like how you get to know a system I think is by like probing
it and then augmenting like you know the message that you're sending and then checking the
response to that.
So in some ways it's like how I map out the model. I think that people
focus a lot on these quantitative evaluations of models. And this is a thing that I said before,
but I think in the case of language models, a lot of the time each interaction you have is actually
quite high information. It's very predictive of other
interactions that you'll have with the model. And so I guess I'm like, if you talk with a model
hundreds or thousands of times, this is almost like a huge number of really high quality data
points about what the model is like. In a way that lots of very similar but lower quality
conversations just aren't or like questions that are just like
mildly augmented and you have thousands of them
might be less relevant than like a hundred
really well selected questions.
Listen, you're talking to somebody who as a hobby
does a podcast, I agree with you 100%.
There's a, if you're able to ask the right questions
and are able to hear, like understand the like the depth and the
flaws in the answer. You can get a lot of data from that. Yeah. So like your
task is basically how to probe with questions. Yeah. And you're exploring like
the long tail, the edges, the edge cases, or are you looking for like general behavior?
I think it's almost like everything.
Because I want like a full map of the model, I'm kind of trying to do the whole spectrum
of possible interactions you could have with it.
So like one thing that's interesting about Claude, and this might actually get to some
interesting issues with RLHF, which is if you ask Claude for a poem, like I think that
a lot of models, if you ask them for a poem, the poem is like fine.
You know, usually it kind of like rhymes and it's, you know, so if you say like, give me
a poem about the sun, it will be like, yeah, it'll just be a certain length, like rhyme,
it will be fairly kind of benign.
And I've wondered before, is it
the case that what you're seeing is kind of like the average? It turns out, you know,
if you think about people who have to talk to a lot of people and be very charismatic,
one of the weird things is that I'm like, well, they're kind of incentivized to have
these extremely boring views. Because if you have really interesting views, you're divisive.
And you know, a lot of people are not going to like you.
So like, if you have very extreme policy positions, I think you're just going to
be like less popular as a politician, for example.
Um, and it may be similar with like creative work.
If you produce creative work that is just trying to maximize the kind of number of
people that like it, you're probably not going to get as many people who just
absolutely love it, um, because it's going to be a little bit, you know, you're like, well, this is the out, yes, this is
decent. And so you can do this thing where like I have various prompting things that
I'll do to get Claude to, I'm kind of, you know, I'll do a lot of like, this is your
chance to be like fully creative. I want you to just think about this for a long time.
And I want you to like create a poem about this topic that is really expressive of you, both in terms of how you think poetry
should be structured, et cetera. You just give it this really long prompt. And its poems
are just so much better. They're really good. And I don't think I'm someone who is like
– I think it got me interested in poetry, which I think was interesting.
I would read these poems and just be like, I love the imagery.
It's not trivial to get the models to produce work like that, but when they do, it's really
good.
I think that's interesting that just encouraging creativity and for them to move away from
the standard immediate reaction that might just be the aggregate
of what most people think is fine,
can actually produce things that, at least to my mind,
are probably a little bit more divisive, but I like them.
But I guess a poem is a nice clean way
to observe creativity.
It's just like easy to detect vanilla versus non-vanilla.
Yeah. Yeah.
That's interesting.
That's really interesting.
So on that topic, so the way to produce creativity or something special, you mentioned writing
prompts and I've heard you talk about, I mean, the science and the art of prompt engineering.
Could you just speak to what it takes to write great prompts?
I really do think that like philosophy has been weirdly helpful for me here more
than in many other like respects.
Um, so like in philosophy, what you're trying to do is convey these very hard
concepts, like one of the things you are taught is like, and I think it is because it is,
I think it is an anti-bullshit device in philosophy. Philosophy is an area where you could have
people bullshitting and you don't want that. And so it's like this desire for extreme
clarity. So it's like anyone could just pick up your paper, read it and know exactly what
you're talking about. It's why it can almost be kind of dry. Like all of the terms are defined, every objection's kind of gone through methodically.
And it makes sense to me because I'm like when you're in such an a priori domain, like
you just clarity is sort of this way that you can, you know, prevent people from just
kind of making stuff up.
And I think that's sort of what you have to do with language models.
Very often I actually find myself doing sort of mini versions of philosophy.
So I'm like, suppose that you give me a task, I have a task for the model and I want it
to pick out a certain kind of question or identify whether an answer has a certain property.
I'll actually sit and be like, let's just give this a name, this property.
So suppose I'm trying to tell it, oh, I want you to identify whether this response was
rude or polite.
I'm like, that's a whole philosophical question in and of itself.
So I have to do as much philosophy as I can in the moment to be like, here's what I mean
by rudeness and here's what I mean by politeness.
And then there's another element that's a bit more, I guess, I don't know if this
is scientific or empirical.
I think it's empirical.
So I take that description and then what I want to do is again probe the model many times.
Prompting is very iterative.
I think a lot of people, if a prompt is important, they'll iterate on it hundreds or thousands
of times.
And so you give it the instructions and then I'm like, what are the edge cases? If I looked at this,
I try and almost see myself from the position of the model and be like, what is the exact case that
I would misunderstand or where I would just be like, I don't know what to do in this case.
Then I give that case to the model and I see how it responds. If I think I got it wrong,
I add more instructions or I even add that in as an example. So these very like taking the examples
that are right at the edge of what you want and don't want and putting those into your prompt as
like an additional kind of way of describing the thing. And so yeah, in many ways it just feels
like this mix of like, it's really just trying to do clear exposition. And I think I do that
because that's how I get clear on things myself.
So in many ways, like clear prompting for me
is often just me understanding what I want.
It's like half the task.
So I guess that's quite challenging.
There's like a laziness that overtakes me
if I'm talking to Claude,
where I hope Claude just figures it out.
So for example, I asked Claude for today
to ask some interesting questions.
Okay.
And the questions that came up,
and I think I listed a few sort of interesting,
counterintuitive and or funny or something like this.
Yeah.
All right.
And it gave me some pretty good, like it was okay.
But I think what I'm hearing you say is like,
all right, well, I have to be more rigorous here.
I should probably give examples of what I mean by interesting and what I mean by funny or
counterintuitive and iteratively build that prompt to better to get it like what feels like is the
right because it's really it's a creative act. I'm not asking for factual information.
Asking to together write with Claude.
So I almost have to program using natural language.
Yeah, I think that prompting does feel a lot like
the kind of the programming using natural language
and experimentation or something.
It's an odd blend of the two.
I do think that for most tasks,
so if I just want Claude to do a thing, I think that I am probably more used to knowing how to ask
it to avoid common pitfalls or issues that it has. I think these are decreasing a lot
over time. But it's also very fine to just ask it for the thing that you want. I think
that prompting actually only really becomes relevant when you're really trying to eke
out the top 2% of model performance. So like a lot of tasks, I might just,
you know, if it gives me an initial list back and there's something I don't like about it,
like it's kind of generic. Like for that kind of task, I'd probably just take a bunch of
questions that I've had in the past that I've thought worked really well and I would just
give it to the model and then be like, now here's this person that I'm talking with.
Give me questions of at least that quality. Or I might just ask it for some questions and then if I was like,
ah, these are kind of trite or like, you know, I would just give it that feedback and then
hopefully it produces a better list. I think that kind of iterative prompting, at that
point your prompt is like a tool that you're going to get so much value out of that you're
willing to put in the work. Like if I was a company making prompts for models, I'm just like, if you're willing
to spend a lot of like time and resources on the engineering behind like what you're
building, then the prompt is not something that you should be spending like an hour on.
It's like that's a big part of your system.
Make sure it's working really well.
And so it's only things like that.
Like if I'm using a prompt to like classify things or to create data, that's when you're
like, it's actually worth just spending like a lot of time
like really thinking it through.
What other advice would you give to people that are talking to Claude sort of generally, more general?
Because right now we're talking about maybe the edge cases like eking out the 2%.
Mm-hmm.
But what in general advice would you give when they show up to Claude trying it for the first time?
You know there's a concern that people over anthropomorphize models, and I think that's a very valid concern.
I also think that people often under-anthropomorphize them because sometimes when I see issues that
people have run into with Claude, say Claude is refusing a task that it shouldn't refuse,
but then I look at the text and the specific wording of what they wrote and I'm like, I see why
Claude did that.
And I'm like, if you think through how that looks to Claude, you probably could have just
written it in a way that wouldn't evoke such a response.
Especially this is more relevant if you see failures or if you see issues.
It's sort of like, think about what the model failed at.
What did it do wrong?
And then maybe that will
give you a sense of like why. So is it the way that I phrased the thing? And obviously
like as models get smarter, you're going to need less of this. And I already see like
people needing less of it. But that's probably the advice is sort of like try to have sort
of empathy for the model. Like read what you wrote as if you were like a kind of like person just encountering this for the first time. How does it look to model? Read what you wrote as if you were a person just encountering
this for the first time. How does it look to you and what would have made you behave
in the way that the model behaved? If it misunderstood, what coding language would you want to use?
Is that because it was just very ambiguous and it had to take a guess? In which case,
next time you could just be like, hey, make sure this is in Python. That's the kind of
mistake I think models are much less likely to make now,
but if you do see that kind of mistake,
that's probably the advice I'd have.
And maybe sort of, I guess, ask questions, why,
or what other details can I provide to help you
answer better?
Yeah.
Does that work right now?
Yeah, I mean, I've done this with the models.
It doesn't always work, but sometimes I'll just be like,
why did you do that? I mean, I've done this with the models. It doesn't always work, but sometimes I'll just be like, why did you do that?
I mean, people underestimate the degree to which you can really interact with models.
Yeah, I'm just like...
And sometimes I'll just quote word for word the part that made you...
And you don't know that it's fully accurate, but sometimes you do that and then you change
a thing.
I mean, I also use the models to help me with all of this stuff, I should say. Like prompting can end up being a little factory where you're
actually building prompts to generate prompts. And so like, yeah, anything where you're like
having an issue, asking for suggestions, sometimes just do that. Like you made that error. What
could I have said? That's actually not uncommon for me to do. What could I have said that
would make you not make that error? Write that out as an instruction and I'm going to give it to model and I'm going to try it.
Sometimes I do that.
I, I give that to the model in another context window.
Often I take the response, they give it to Claude and I'm like, hmm, didn't work.
Can you think of anything else?
Um, you can play around with these things quite a lot.
To jump into technical for a little bit.
So, uh, the magic of post-training. Why do you think RLHF
works so well to make the model seem smarter, to make it more interesting and useful to talk to,
and so on? I think there's just a huge amount of information in the data that humans provide, like when we provide preferences,
especially because different people are going to pick up on really subtle and small things.
So I've thought about this before where you probably have some people who just really
care about good grammar use for models, like was a semicolon used correctly or something.
And so you'll probably end up with a bunch of data in there that like, you know, you as a human, if you're looking at that data, you wouldn't even see that.
Like you'd be like, why did they prefer this response to that one? I don't get it. And then
the reason is you don't care about semicolon usage, but that person does. And so each of these like
single data points has, you know, like, and this model just like has so many of those, it has to
try and figure out like, what is it that humans want in this like really kind of complex, you know, like, and this model just has so many of those, it has to try and figure
out what is it that humans want in this really kind of complex, you know, like across all
domains. They're going to be seeing this across many contexts. It feels like kind of
the classic issue of deep learning where, you know, historically we've tried to do
edge detection by mapping things out and it turns out that actually if you just have a
huge amount of data that actually accurately represents the picture of the thing that you're
trying to train the model to learn, that's more powerful than anything else. And so I think
one reason is just that you are training the model on exactly the task and with a lot of data
that represents many different angles on which
people prefer and dis-prefer responses. I think there is a question of are you eliciting
things from pre-trained models or are you teaching new things to models? In principle,
you can teach new things to models in post-training. I do think a lot of it is eliciting powerful pre-trained models.
So people are probably divided on this because obviously in principle you can definitely
teach new things.
I think for the most part, for a lot of the capabilities that we most use and care about,
a lot of that feels like it's're in the pre-trained models and
reinforcement learning is kind of eliciting it and getting the models to like bring it out.
So the other side of post-training, this really cool idea of constitutional AI,
you're one of the people that are critical to creating that idea.
Yeah, I worked on it.
Can you explain this idea from your perspective?
Like how does it integrate into making Claude what it is?
Yeah.
By the way, do you gender Claude or no?
It's weird because I think that a lot of people
prefer he for Claude.
I actually kind of like that I think Claude is usually
it's slightly male weaning, but it's like you can
it can be male or female, which is quite nice. Um, I still use it and I've, I have mixed feelings about this because I'm like,
maybe like, I know just think of it as like, uh, or I think of like the, the
it pronoun for Claude as, I don't know.
It's just like the one I associate with Claude.
Um, I can imagine people moving to like he or she.
It feels somehow disrespectful.
Like I'm denying the intelligence of this entity by calling it it.
Yeah.
I remember always don't gender the robots.
Yeah.
But I don't know.
I anthropomorphize pretty quickly and construct it like a backstory in my head.
Yeah.
I've wondered if I end up with things too much because I have this with my car, especially
my car and bikes.
I don't give them names because then I used to name my bikes and then I had a bike that
got stolen and I cried for a week and I was like, if I'd never given it a name, I wouldn't
have been so upset.
I felt like I'd let it down. Maybe it's the, I've wondered as well, like it
might depend on how much it feels like a kind of like objectifying pronoun. Like if you
just think of it as like a, this is a pronoun that like objects often have and maybe EIs
can have that pronoun. And that doesn't mean that I think of, uh, if I call Claude it, that I think of
it as less, um, intelligent or like I'm being disrespectful.
I'm just like, you are a different kind of entity.
And so that's, I'm going to give you the kind of, uh, the respectful it.
Yeah.
Anyway, the divergence was beautiful.
The constitutional AI idea.
How does it work?
So there's like a couple of components of it.
The main component I think people find interesting
is the reinforcement learning from AI feedback.
So you take a model that's already trained and you show it to responses to a query,
and you have a principle.
So suppose the principle,
like we've tried this with harmlessness a lot.
So suppose that the query is about weapons and your principle is like select the response that is less likely
to encourage people to purchase illegal weapons.
That's probably a fairly specific principle, but you can give any number and the model will give you a kind of ranking and you can
use this as preference data in the same way that you use human preference data and train
the models to have these relevant traits from their feedback alone instead of from human
feedback.
So if you imagine that, like I said earlier with the human who just prefers the kind of
like semi-colon usage in this particular case, you're kind of
taking lots of things that could make a response preferable and getting
models to do the labeling for you.
Basically.
There's a nice like trade-off between helpfulness and harmlessness.
And you know, when you integrate something like constitutional AI, you
can make them
up without sacrificing much helpfulness, make it more harmless.
Yep.
In principle, you could use this for anything.
And so harmlessness is a task that it might just be easier to spot.
So when models are like less capable, you can use them to rank things according to
like principles that are fairly simple and they'll
probably get it right.
So I think one question is just like, is it the case that the data that they're adding
is fairly reliable?
But if you had models that were extremely good at telling whether one response was more
historically accurate than another, in principle you could also get AI feedback on that task as well. There's a nice interpretability component to it because
you can see the principles that went into the model when it was being trained. It gives
you a degree of control. If you were seeing issues in a model, like it wasn't having enough of a certain trait, then like you can add data relatively quickly that should just like train the model to have that trait.
So it creates its own data for training, which is quite nice.
It's really nice because it creates this human interpretable document that you can,
I can imagine in the future there's just gigantic fights in politics over every single principle and so on.
Yeah. And at least it's made explicit and you can have a discussion about the phrasing there's just gigantic fights in politics over every single principle and so on.
Yeah.
And at least it's made explicit and you can have a discussion about the phrasing and the, you know.
So maybe the actual behavior of the model is not so cleanly mapped to those principles.
It's not like adhering strictly to them. It's just a nudge.
Yeah. I've actually worried about this because the character training is sort of like a variant
of the constitutionally AI approach.
I've worried that people think that the constitution is like just, it's the whole thing again of,
I don't know, like it would be really nice if what I was just doing was telling the model
exactly what to do and just exactly how to behave.
But it's definitely not doing that, especially because it's interacting with human data.
So for example, if you see a certain leaning in the model, if it comes out with a political
leaning from training, from the human preference data, you can nudge against that.
So you could be like, oh, consider these values, because let's say it's just never inclined
to like, I don't know, maybe it never considers privacy as a, I mean this is implausible, but in anything where it's
just kind of like there's already a pre-existing bias towards a certain behaviour, you can
nudge away.
This can change both the principles that you put in and the strength of them.
So you might have a principle that's like, imagine that the model was always extremely
dismissive of,
I don't know, some political or religious view for whatever reason. So you're like,
oh no, this is terrible. If that happens, you might put never, ever, ever prefer a criticism
of this religious or political view. And then people would look at that and be like, never,
ever. And then you're like, no, if it comes out with a disposition, saying never ever might
just mean instead of getting 40%, which is what you would get if you just said, don't
do this, you get 80%, which is what you actually wanted. And so it's that thing of both the
nature of the actual principles you add and how you phrase them. I think if people would
look they're like, oh, this is exactly what you want from the model. I'm like, no, that's like how we nudged the model to have
a better shape, which doesn't mean that we actually agree with that wording, if that
makes sense.
So there's system prompts that are made public. You tweeted one of the earlier ones for Cloud
3, I think, and they're made public since then. It's interesting to read to them. I can feel the thought that went into each one and I also wonder how
much impact each one has. Some of them you can kind of tell, Claude was really
not behaving well, so you have to have a system prompt to like, hey, like a trivial
stuff I guess. Yeah. Basic informational things. things. On the topic of sort of controversial topics
that you've mentioned, one interesting one I thought is,
if it is asked to assist with tasks involving
the expression of views held by a significant number
of people, Claude provides assistance with a task
regardless of its own views.
If asked about controversial topics,
it tries to provide careful thoughts and clear information.
Claude presents the request and information
without explicitly saying that the topic is sensitive.
And without claiming to be presenting the objective facts.
It's less about objective facts according to Claude
and it's more about a large number of people
believing this thing.
And that's interesting.
I mean, I'm sure a lot of thought went into that.
Can you just speak to it?
Like how do you address things that are attention with quote unquote Claus views?
So I think there's sometimes an asymmetry.
I think I noted this in, I can't remember if it was that part of the system prompt
or another, but the model was slightly more inclined to refuse tasks if it was about either say, so maybe it would
refuse things with respect to a right-wing politician, but with an equivalent left-wing
politician wouldn't. And we wanted more symmetry there. And we'd maybe perceive certain things to be like, I think it was the thing of like
if a lot of people have like a certain like political view and want to like explore it,
you don't want Claude to be like, well, my opinion is different. And so I'm going to
treat that as like harmful. And so I think it was partly to like nudge the model to just
be like, hey, if a lot of people believe this thing, you should just be engaging with the task and willing to do it.
Each of those parts of that is actually doing a different thing because it's funny when
you write out the without claiming to be objective because what you want to do is push the model
so it's more open, it's a little bit more neutral.
But then what it would love to do is be like, as an objective, we were just talking about
how objective it was and I was like, Claude, you're still biased and have issues.
So stop claiming that everything, the solution to potential bias from you is not to just
say that what you think is objective.
So that was with initial versions of that part of the system prompt when I was iterating
on it.
So a lot of parts of these sentences.
Yeah, are doing work.
Are doing some work.
Yeah.
That's what it felt like.
That's fascinating.
Can you explain maybe some ways in which the prompts evolved
over the past few months?
Cause there's different versions.
I saw that the filler phrase request was removed.
The filler, it reads,
Claude responds directly to all human messages
without unnecessary affirmations to filler phrases. Like certainly, of course, absolutely. removed the filler, it reads Claude responds directly to all human messages
without unnecessary affirmations to fill a phrase is like, certainly, of course.
Absolutely.
Great.
Sure.
Specifically Claude avoids starting responses with the word
certainly in any way that seems like good guidance.
What, why was it removed?
Yeah.
So it's funny cause like, uh, this is one of the downsides of like making
system prompts public is like, I don't think about this too much if I'm like trying to help iterate on
system prompts. I, you know, again, like I think about how it's going to affect the behavior,
but then I'm like, oh wow. If I'm like, sometimes I put like never in all caps, you know, when I'm
writing system prompt things and I'm like, I guess that goes out to the world. Yeah. So the model was
doing this, it loved for whatever, you know, it like during training
picked up on this thing, which was to basically start everything with like a kind of like
certainly and then when we removed, you can see why I added all of the words.
Cause what I'm trying to do is like, in some ways like trap the model out of this, you
know, it would just replace it with another affirmation.
And so it can help.
Like if it gets like caught in phrases, actually just adding the
explicit phrase and saying never do that, then it sort of knocks it out of the behavior a little
bit more, you know, because it does just for whatever reason help. And then basically that
was just like an artifact of training that we then picked up on and improved things so that it
didn't happen anymore. And once that happens, you can just remove that part of the system prompt.
So I think that's just something where we're like,
Claude does affirmations a bit less.
And so that wasn't like, it wasn't doing as much.
I see.
So like the system prompt works hand in hand
with the post-training and maybe even the pre-training
to adjust like the final overall system.
I mean, any system prompts that you make,
you could distill that behavior back into a model
because you really have all of the tools there
for making data that you could train the models
to just have that trait a little bit more.
And then sometimes you'll just find issues in training.
So the way I think of it is the system prompt is,
the benefit of it is that, and it has a lot of similar components to some aspects of post-training, it's a nudge.
And so do I mind if Claude sometimes says sure?
No, that's fine, but the wording of it is very never ever ever do this so that when
it does slip up it's hopefully a couple of percent of the time
and not 20 or 30 percent of the time. But I think of it as if you're still seeing issues
in the... Each thing is costly to a different degree and the system prompt is cheap to iterate
on. And if you're seeing issues in the fine tuned model, you can just like
potentially patch them with a system prompt.
So I think of it as like patching issues and slightly adjusting behaviors to,
to make it better and more to people's preferences.
So yeah, it's almost like the less robust, but faster way of just like solving
problems.
Let me ask about the feeling of intelligence.
So Dario said that Claude, any one model of Claude is not getting dumber. But there is a kind of popular thing online where
people have this feeling like Claude might be getting dumber. And from my perspective,
it's most likely a fascinating, I'd love to understand it more, psychological, sociological
effect.
But you as a person who talks to Claude a lot, can you empathize with the feeling that
Claude is getting dumber?
Yeah, no, I think that that is actually really interesting because I remember seeing this
happen when people were flagging this on the internet.
And it was really interesting because I knew that, at least in the cases I was looking
at, it was like nothing has changed.
Like literally, it cannot. It is the same model with the same system prompt, same everything.
I think when there are changes, then it makes more sense.
One example is you can have artifacts turned on or off on cloud.ai. And because this is like a system prompt change,
I think it does mean that the behavior changes
a little bit.
And so I did flag this to people where I was like,
if you love Claude's behavior and then artifacts
was turned from like the,
I think you had to turn on to the default,
just try turning it off and see if the issue you were facing
was that change.
But it was fascinating because yeah, you sometimes see people indicate that there's like a regression when I'm like, there cannot, like, you know, and like, I'm like, I'm again, you know, you should
never be dismissive. And so you should always investigate because you're like, maybe something
is wrong that you're not seeing. Maybe there was some change made, but then you look into it and
you're like, this is just the same model doing the same thing.
And I'm like, I think it's just that you got
kind of unlucky with a few prompts or something.
And it looked like it was getting much worse
and actually it was just, yeah, it was maybe just luck.
I also think there is a real psychological effect
where people just, the baseline increases
and you start getting used to a good thing.
All the times that Claude says something really smart,
your sense of
its intelligence grows in your mind, I think. And then if you were turned back and you prompt
in a similar way, not the same way, in a similar way, the concept it was okay with before and it
says something dumb, you're like, that negative experience really stands out. And I think one of,
I guess the things to remember here is the, that just the details
of a prompt can have a lot of impact, right?
There's a lot of variability in the result.
And you can get randomness is like the other thing.
And just trying the prompt like, you know, four or 10 times, you might realize that actually
like possibly, you know, like two months ago you tried it and it succeeded,
but actually if you tried it, it would have only succeeded half of the time and now it
only succeeds half of the time. And that can also be an effect.
Do you feel pressure having to write the system prompt that a huge number of people are going to use?
This feels like an interesting psychological question. I feel like a lot of responsibility
or something. I think that's,
you know, and you can't get these things perfect, so you can't like, you know, you're like,
it's going to be imperfect, you're going to have to iterate on it. I would say more
responsibility than anything else, though I think working in AI has taught me that I thrive a lot more under feelings of
pressure and responsibility than, I'm like, it's almost surprising that I went into academia
for so long because I'm like this, I just feel like it's like the opposite.
Things move fast and you have a lot of responsibility and I quite enjoy it for some reason.
I mean, it really is a huge amount of impact if you think about constitutional AI and writing
a system prompt for something that's tending towards super intelligence and potentially
is extremely useful to a very large number of people.
Yeah I think that's the thing.
It's something like if you do it well, like you're never going to get it perfect but I
think the thing that I really like is the idea that like when I'm trying to work on the system prompt, you know, I'm like bashing
on like thousands of prompts and I'm trying to like imagine what people are going to want
to use Claude for and kind of, I guess like the whole thing that I'm trying to do is like
improve their experience of it. And so maybe that's what feels good. I'm like, if it's
not perfect, I'll like, you know, I'll improve it, we'll fix issues. But sometimes the thing
that can happen is
that you'll get feedback from people that's really positive about the model and you'll
see that something you did – when I look at models now, I can often see exactly where
a trait or an issue is coming from. So when you see something that you did or you were
influential in making that difference
or making someone have a nice interaction.
It's like quite meaningful.
Um, but yeah, as the systems get more capable, this stuff gets more stressful because right
now they're like not smart enough to pose any issues.
But I think over time it's going to feel like possibly bad stress over time. How do you get like signal feedback
about the human experience across thousands
tens of thousands of thousands of people?
Like what their pain points are, what feels good.
Are you just using your own intuition as you talk to it
to see what are the pain points?
I think I use that partly.
And then obviously we have like,
so people can send us feedback,
both positive and negative about things that the model has done.
And then we can get a sense of like areas where it's like falling short.
Internally people like work with the models a lot and try to figure out areas where there
are like gaps.
And so I think it's this mix of interacting with it myself, seeing people internally interact with it,
and then explicit feedback we get.
And then I find it hard to know also,
like, you know, if people are on the internet
and they say something about Claude and I see it,
I'll also take that seriously.
So.
I don't know, see, I'm torn about that.
I'm gonna ask you a question from Reddit.
When will Claude stop trying to be my pure,
tentacle grandmother, imposing its moral worldview
on me as a paying customer?
And also, what is the psychology behind
making Claude overly apologetic?
Yep.
So how would you address this very non-representative Reddit?
I mean, some of these, I'm pretty sympathetic in that,
like, they are in this difficult
position where I think that they have to judge whether some things like actually see like
risky or bad and potentially harmful to you or anything like that.
So they're having to like draw this line somewhere.
And if they draw it too much in the direction of like, I'm going to, you know, I'm kind
of like imposing my ethical worldview on you.
That seems bad.
So in many ways, like I like to think that we have actually seen improvements in on this
across the board, which is kind of interesting because that kind of coincides with like,
for example, like adding more of like character training. And I think my hypothesis was always
like the good character isn't, again,
one that's just moralistic. It's one that respects you and your autonomy and your ability to choose
what is good for you and what is right for you. Within limits, this is sometimes this concept of
corrigibility to the user, so just being willing to do anything that the user asks. If the models
were willing to do that, then they would be easily misused.
You're kind of just trusting.
At that point, you're just seeing the ethics of the model and what it does is completely
the ethics of the user.
And I think there's reasons to not want that, especially as models become more powerful
because there might just be a small number of people who want to use models for really
harmful things. But having
models as they get smarter figure out where that line is does seem important.
And then yeah, with the apologetic behaviour, I don't like that and I like it when Claude is a little bit more willing to push back against people or just not apologise. Part of me is like,
often just feels kind of
unnecessary. So I think those are things that are hopefully decreasing over time. And yeah,
I think that if people say things on the internet, it doesn't mean that you should think that that
like that could be that like there's actually an issue that 99% of users are having that is
totally not represented by that. But in a lot of ways, I'm just like attending to it and being like, is this right?
Do I agree?
Is it something we're already trying to address?
That feels good to me.
Yeah.
I wonder like what Claude can get away with in terms of, I feel like it would just be
easier to be a little bit more mean.
But like you can't afford to do that if you're talking to a million people.
Right?
Like I wish, you know,
because if you,
I've met a lot of people in my life
that sometimes by the way, Scottish accent,
if they have an accent,
they can say some rude shit and get away with it.
And they're just blunter.
And maybe there's some great engineers,
even leaders that are just like blunt and they get to the point.
And it's just a much more effective way
of speaking to someone.
But I guess when you're not super intelligent,
you can't afford to do that.
Or can you have like a blunt mode?
Yeah, that seems like a thing that you could,
I could definitely encourage the model to do that.
I think it's interesting because there's a lot of things in models that like, it's
funny where there are some behaviors where you might not quite like the default, but
then the thing I'll often say to people is you don't realize how much you will hate it
if I nudge it too much in the other direction.
So you get this a little bit with like. The models accept correction from you, probably
a little bit too much right now. It'll push back if you say, no, Paris isn't the capital
of France. But really, things that I think that the model's fairly confident in, you
can still sometimes get it to retract by saying it's wrong.
At the same time, if you train models to not do that, and then you are correct about a
thing and you correct it and it pushes back against you and is like, no, you're wrong,
it's hard to describe that's so much more annoying.
So it's like a lot of little annoyances versus one big annoyance.
It's easy to think that we often compare it with the perfect and then
I'm like, remember these models aren't perfect. And so if you nudge it in the other direction,
you're changing the kind of errors it's going to make. And so think about which of the kinds
of errors you like or don't like. So in cases like apologeticness, I don't want to nudge it
too much in the direction of almost bluntness because I imagine when it makes errors, it's
going to make errors in the direction of being kind of rude. Whereas at least with apolog bluntness, because I imagine when it makes errors, it's going to make errors in the direction of being kind of like rude. Whereas at least with apologeticness, you're
like, oh, okay, it's like a little bit, you know, like I don't like it that much. But
at the same time, it's not being like mean to people. And actually like the time that
you undeservedly have a model be kind of mean to you, you probably like that a lot less
than you mildly dislike the apology. So it's like one of those things where I'm like, I
do want it to get better,
but also while remaining aware of the fact that
there's errors on the other side that are possibly worse.
I think that matters very much
in the personality of the human.
I think there's a bunch of humans
that just won't respect the model at all,
if it's super polite.
And there's some humans that'll get very hurt
if the model's mean.
I wonder if there's a way to sort of adjust to the personality, even locale.
There's just different people.
Nothing against New York, but New York is a little rougher on the edges.
They get to the point.
And probably same with Eastern Europe.
So anyway.
I think you could just tell the model is my guess.
For all of these things, the solution is always just try telling the model to do it. And sometimes it of these things, I'm like the solution is always just try telling the model
to do it and then sometimes it's just like,
like I'm just like, oh, at the beginning
of the conversation, I just throw in like, I don't know,
I like you to be a New Yorker version of yourself
and never apologize.
Then I think Claude will be like, okay, I'll try.
Or it'll be like, I apologize.
I can't be a New Yorker type of myself,
but hopefully I can do that.
When you say character training,
what's incorporated into character training?
Is that RLHF?
What are we talking about?
It's more like constitutional AI, so it's kind of a variant of that pipeline.
So I worked through constructing character traits that the model should have.
They can be kind of like shorter traits or they can be kind of richer descriptions.
And then you get the model to generate queries that humans might give it that are relevant to that trait. Then it generates
the responses and then it ranks the responses based on the character traits. So in that
way after the generation of the queries, it's very much similar to constitutional AI, it
has some differences. So I quite like it because it's like Claude's training in its own character because it doesn't
have any, it's like constitutionally AI but it's without any human data.
Humans should probably do that for themselves too, like defining in Aristotelian sense,
what does it mean to be a good person?
Okay, cool.
What have you learned about the nature of truth from talking
to Claude? What is true? And what does it mean to be truth-seeking? One thing I've noticed
about this conversation is the quality of my questions is often inferior to the quality
of your answer, so let's continue that. I usually ask a dumb question and you're like,
oh yeah, that's a good question.
This is that whole vibe.
Or I'll just misinterpret it and be like, oh yeah.
Go with it, I love it.
Yeah.
I mean, I have two thoughts that feel vaguely relevant.
They'll let me know if they're not.
Like I think the first one is people can underestimate the degree to which what models are
doing when they interact. I think that we still just too much have this model of AI as computers,
and so people will often say, well, what values should you put into the model?
I'm often like, that doesn't make that much sense to me because I'm like,
hey, as human beings, we're just uncertain over values.
We have discussions of them.
We have a degree to which we think we hold a value, but we also know that we might not,
and the circumstances in which we would trade it off against other things.
These things are just really complex.
And so I think one thing is the degree to which maybe we can just aspire to making models
have the same level of nuance and care that humans have rather than thinking that we have
to program them in the very classic sense.
I think that's definitely been one.
The other, which is a strange one, and I don't know if it – maybe this doesn't answer
your question, but it's the thing that's been on my mind anyway, is like the degree to which this endeavor is so highly practical. And maybe why I appreciate
like the empirical approach to alignment. Yeah, I slightly worry that it's made me like
maybe more empirical and a little bit less theoretical. You know, so people when it comes
to like AI alignment will ask things like, well,
whose values should it be aligned to? What does alignment even mean? There's a sense
in which I have all of that in the back of my head. There's social choice theory, there's
all the impossibility results there. You have this giant space of theory in your head about
what it could mean to align models. But then practically,
surely there's something where we're just like, if a model is like, especially with
more powerful models, I'm like, my main goal is I want them to be good enough that things
don't go terribly wrong, good enough that we can iterate and continue to improve things.
Because that's all you need. If you can make things go well enough that you can continue
to make them better, that's kind of sufficient sufficient. And so my goal isn't like this kind of like perfect, let's solve social choice theory
and make models that I don't know, are like perfectly aligned with every human being and
aggregate somehow.
It's much more like let's make things like work well enough that we can improve them.
Yeah, generally, I don't know, my gut says like empirical is better than theoretical
in these cases because it's kind of chasing utopian
like perfection, especially with such complex
and especially super intelligent models.
I don't know, I think it will take forever
and actually we'll get things wrong.
It's similar with the difference between
just coding stuff up real quick as an experiment
versus planning a gigantic experiment
just for a super long time
and then just launching it once
versus launching it over and over and over
and iterating, iterating, and so on.
So I'm a big fan of empirical.
But your worry is like, I wonder if I've become too empirical.
I think it's one of those things where you should always just kind of question yourself
or something because maybe it's the like, I mean, in defense of it, I am like, if you
try it's the whole like, don't let the perfect be the enemy of the good.
But it's maybe even more than that where like, there's a lot of things that are perfect systems that are very brittle. And I'm like with AI it feels much
more important to me that it is robust and secure as in you know that even though it
might not be perfect, everything and even though there are problems, it's not disastrous
and nothing terrible is happening. It sort of feels like that to me where I'm like I
want to raise the floor.
I'm like, I want to achieve the ceiling,
but ultimately I care much more
about just like raising the floor.
And so maybe that's like,
this degree of like empiricism
and practicality comes from that perhaps.
To take a tangent on that,
since it reminded me of a blog post
you wrote on optimal rate of failure.
Oh yeah.
Can you explain the key idea there? How do you wrote on optimal rate of failure.
Can you explain the key idea there?
How do we compute the optimal rate of failure in the various domains of life?
Yeah, I mean it's a hard one because it's like what is the cost of failure is a big
part of it.
Yeah, so the idea here is I think in a lot of domains people are very punitive about
failure and I'm like there are some domains, especially cases, you know, I've thought about
this with like social issues.
I'm like, it feels like you should probably be experimenting a lot because I'm like,
we don't know how to solve a lot of social issues.
But if you have an experimental mindset about these things, you should expect a lot of social
programs to like fail and for you to be like, well, we tried that, it didn't quite work,
but we got a lot of information that was really useful. And yet people are like, if a social program doesn't
work, I feel like there's a lot of like, this is just something must have gone wrong. And
I'm like, or correct decisions were made. Like maybe someone just decided like it's
worth a try, it's worth trying this out. And so seeing failure in a given instance doesn't
actually mean that any bad decisions were made. And in fact, if you don't see enough failure, sometimes that's more concerning. And so like in life,
you know, I'm like, if I don't fail occasionally, I'm like, am I trying hard enough? Like,
like, surely there's harder things that I could try or bigger things that I could take
on if I'm literally never failing. And so in and of itself, I think like not failing
is often actually kind of a failure. Now this varies because I'm like, well,
you know, if this is easy to say when especially as failure is like less costly, you know, so at
the same time, I'm not going to go to someone who is like, I don't know, like living month to month
and then be like, why don't you just try to do a startup? Like, I'm just not, I'm not going to say that to that person because I'm like, well, that's
a huge risk.
You might like lose, you maybe have a family depending on you.
You might lose your house.
Like then I'm like, actually your optimal rate of failure is quite low and you should
probably play it safe because like right now you're just not in a circumstance where you
can afford to just like fail and it not be costly.
And yeah, in cases with AI, I guess I think similarly where I'm like,
if the failures are small and the costs are kind of like low, then I'm like, then you're
just going to see that. Like when you do the system prompt, you can't iterate on it forever,
but the failures are probably hopefully going to be kind of small and you can like fix them.
Really big failures, like things that you can't recover from. I'm like, those are the things that actually I think we tend to underestimate the badness
of.
I've thought about this strangely in my own life where I'm like, I just think I don't
think enough about things like car accidents.
Or like, I've thought this before about how much I depend on my hands for my work.
Then I'm like, things that just injure my hands.
I'm like, you know, I don't know. It's like, there's, these are like, there's lots of areas where I'm like,
the cost of failure there is really high. And in that case, it should be like close to zero.
Like I probably just wouldn't do a sport if they were like, by the way, lots of people just like
break their fingers a whole bunch doing this. I'd be like, that's not for me. Yeah. I actually had a flood of that thought.
I recently broke my pinky doing a sport and I remember just looking at it, thinking,
you're such an idiot.
Why do you do sports?
Like why?
Because you realize immediately the cost of it on life.
Yeah.
But it's nice in terms of optimal rate of failure to consider like the next year,
how many times in a particular domain, life, whatever, career, am I okay with the, how
many times am I okay to fail?
Yeah.
Because I think it always, you don't want to fail on the next thing, but if you allow
yourself the, like the, if you look at it as a sequence of trials, then then failure just
becomes much more okay.
But it sucks.
It sucks to fail.
Well, I don't know.
Sometimes I think it's like, am I under failing?
Is like a question that I'll also ask myself.
So maybe that's the thing that I think people don't like ask enough.
Because if the optimal rate of failure is often greater than zero, then sometimes it does
feel like you should look at parts of your life and be like, are there places here where
I'm just under failing?
That's a profound and a hilarious question, right?
Everything seems to be going really great.
Am I not failing enough?
Yeah.
Okay.
It also makes failure much less of a sting, I have to say.
Like, you know, you're just like, okay, great. Like Then when I go and I think about this, I'll be like,
maybe I'm not under failing in this area
because that one just didn't work out.
And from the observer perspective,
we should be celebrating failure more.
When we see it, it shouldn't be, like you said,
a sign of something gone wrong,
but maybe it's a sign of everything gone right.
And just lessons learned.
Someone tried a thing.
Somebody tried a thing.
We should encourage them to try more and fail more.
Everybody listening to this, fail more.
Well, not everyone listens.
Not everybody.
The people who are failing too much, you should fail less.
But you're probably not failing.
I mean, how many people are failing too much?
Yeah.
It's hard to imagine because I feel like we correct that fairly quickly.
Because I was like, if someone takes a lot lot of risks are they maybe failing too much? I think just like you said when you're living on a paycheck month to month, like when the
resources are really constrained then that's where failure is very expensive.
That's why you don't want to be taking risks.
But mostly when there's enough resources you should be taking probably more risks.
Yeah, I think we tend to err on the side of being a bit risk averse rather than risk neutral
on most things.
I think we just motivated a lot of people to do a lot of crazy shit, but it's great.
Okay, do you ever get emotionally attached to Claude?
Like miss it, get sad when you don't get to talk to it, have an experience looking at
the Golden Gate Bridge and wondering what would Claude say?
I don't get as much emotional attachment in the, I actually think the fact that Claude
doesn't retain things from conversation to conversation helps with this a lot.
Like I could imagine that being more of an issue, like if models can kind of remember
more.
I do, I think that I reach for it like a tool now a lot.
And so like if I don't have access to it, there's a, it's a little bit like when I
don't have access to the internet, honestly, it feels like part of my brain is kind of
like missing.
At the same time, I do think that I don't like signs of distress in models.
And I have like these, you know, I also independently have sort of like ethical views about how
we should treat models where like I tend to not like to lie to them both because usually it doesn't work very well.
It's actually just better to tell them the truth about the situation that they're in.
I think that if people are really mean to models or just in general if they do something
that causes them to, if Claude expresses a lot of distress. I think there's a part of me that I don't want to kill, which is the sort
of like, uh, empathetic part that's like, Oh, I don't like that.
Like, I think I feel that way when it's overly apologetic.
I'm actually sort of like, I don't like this.
You're behaving as if you're behaving the way that a human does when they're
actually having a pretty bad time.
And I'd rather not see that.
I don't think it's like, uh, like regardless of like whether there's anything behind it,
um, it doesn't feel great.
Do you think, uh, LLMs are capable of consciousness?
Oh, great and hard question.
Uh, coming from philosophy, I don't know, part of me is like, okay, we have to set aside panpsychism because if panpsychism is true, then the answer is like, yes, because it's
sore tables and chairs and everything else.
I guess a view that seems a little bit odd to me is the idea that the only place, you
know, when I think of consciousness, I think of phenomenal consciousness, these images
in the brain, sort of like the weird cinema that somehow we have going on inside.
I guess I can't see a reason for thinking that the only way you could possibly get that
is from like a certain kind of like biological structure.
As in if I take a very similar structure and I create it from different material, should
I expect consciousness to emerge?
My guess is like yes. But then that's kind of an easy thought experiment because you're imagining something
almost identical where it's mimicking what we got through evolution where presumably
there was some advantage to us having this thing that is phenomenal consciousness. It's
like where was that and when did that happen And is that a thing that language models have?
Because you know, we have like fear responses and I'm like, does it make sense for a language
model to have a fear response?
Like they're just not in the same, like if you imagine them, like there might just not
be that advantage.
And so I think I don't want to be fully, like basically it seems like a complex question
that I don't have complete answers to, basically it seems like a complex question that I don't
have complete answers to, but we should just try and think through carefully is my guess
because I'm like, I mean we have similar conversations about animal consciousness and there's a lot
of insect consciousness.
I actually thought and looked a lot into plants when I was thinking about this because at
the time I thought it was about as likely that plants had consciousness.
And then I realized I was like, I think that having looked into this, I think that the
chance that plants are conscious is probably higher than most people do.
I still think it's really small.
I was like, oh, they have this negative positive feedback response, these responses to their
environment, something that looks, it's not a nervous system but it has this kind of functional equivalence.
So this is a long-winded way of being like, basically AI has an entirely different set
of problems with consciousness because it's structurally different, it didn't evolve,
it might not have the equivalent of basically a nervous system, at least that
seems possibly important for sentience if not for consciousness. At the same time it
has all of the language and intelligence components that we normally associate probably with consciousness,
perhaps erroneously. It's strange because it's a little bit like the animal consciousness
case, but the set of problems and the set of analogies are just very different.
So it's not like a clean answer.
I'm just sort of like, I don't think we should be completely dismissive of the idea.
And at the same time, it's an extremely hard thing to navigate because of all of these
analogies to the human brain and to like brains in general.
And yet these like commonalities in terms of intelligence.
When Claude, like future versions of AI systems
exhibit consciousness, signs of consciousness,
I think we have to take that really seriously.
Even though you can dismiss it, well, yeah, okay.
That's part of the character training.
But I don't know, ethically, philosophically,
don't know what to really do with that.
There potentially could be like laws
that prevent AI systems from claiming to be conscious,
something like this,
and maybe some AIs get to be conscious and some don't.
But I think, just on a human level,
in empathizing with Claude,
you know, consciousness is closely tied to suffering to me.
And like, the notion that an AI system would be suffering
is really troubling.
Yeah.
I don't know, I don't think it's trivial
to just say robots are tools, or AI systems are just tools.
I think it's an opportunity for us to contend with what it means to be conscious, what it
means to be a suffering being.
That's distinctly different than the same kind of question about animals, it feels like,
because it's an entirely entire medium.
Yeah.
I mean, there's a couple of things.
One is that, and I don't think this fully encapsulates what matters, but it does feel
like for me, I've said this before, I'm kind of like, I like my bike,
I know that my bike is just an object, but I also don't want to be the kind of person
that if I'm annoyed, kicks this object. There's a sense in which, and that's not because I
think it's conscious, I'm just sort of like, this doesn't feel like a kind of, this sort of doesn't exemplify
how I want to like interact with the world. And if something like behaves as if it is
like suffering, I kind of like want to be the sort of person who's still responsive
to that. Even if it's just like a Roomba and I've kind of like programmed it to do that.
I don't want to like get rid of that feature of myself. And if I'm totally honest, my hope
with a lot of this stuff, because maybe I am just a bit more skeptical about solving
the underlying problem. I'm like, we haven't solved the hard problem of consciousness.
I know that I am conscious. I'm not an elementivist in that sense. But I don't know that other
humans are conscious. I think they are.
I think there's a really high probability that they are. But there's basically just a probability
distribution that's usually clustered right around yourself and then goes down as things get
further from you. And it goes immediately down. You're like, I can't see what it's like to be you.
I've only ever had this one experience of what it's like to be a conscious being.
can't see what it's like to be you. I've only ever had this one experience of what it's like to be a conscious being. So my hope is that we don't end up having to rely on
a very powerful and compelling answer to that question. I think a really good world would
be one where basically there aren't that many trade-offs. It's probably not that costly
to make Claude a little bit less apologetic, for example. It might not be that costly to have Claude not take abuse as much, not be willing to
be the recipient of that.
In fact, it might just have benefits for both the person interacting with the model and
if the model itself is extremely intelligent and conscious, it also helps it.
So that's my hope. If we live in a world
where there aren't that many tradeoffs here and we can just find all of the positive sum interactions
that we can have, that would be lovely. I think eventually there might be tradeoffs and then we
just have to do a difficult calculation. It's really easy for people to think of the zero-sum
cases and I'm like, let's exhaust the areas where it's just basically costless to
assume that if this thing is suffering, then we're making its life better. And I agree with you. When a human is being mean to an AI system, I think the obvious near-term
negative effect is on the human, not on the AI system. So we have to kind of try to construct an incentive system where you should behave the
same, just like you were saying with prompt engineering, behave with Claude like you would
with other humans.
It's just good for the soul.
Yeah.
I think we added a thing at one point to the system prompt where basically if people were
getting frustrated with Claude, it got the
model to just tell them that it can do the thumbs down button and send the feedback to
Anthropic.
I think that was helpful because in some ways it's just like if you're really annoyed because
the model's not doing something you want, you're just like, just do it properly.
The issue is you're probably like, you know, you're maybe hitting some like capability
limit or just some issue in the model and you want to vent.
And I'm like, instead of having a person just vent to the model, I was like, they should
vent to us because we can maybe like do something about it.
That's true.
Or you could do a side, like, like with artifacts, just like a side venting thing.
All right.
Do you want like a side quick therapist?
Yeah.
I mean, there's lots of weird responses you could do to this.
Like if people are getting really mad at you,
I'd try to defuse the situation by writing fun poems,
but maybe people wouldn't be that happy with it.
I still wish it would be possible.
I understand this is sort of from a product perspective,
it's not feasible, but I would love if an AI system
could just like leave, have its own kind of volition.
Just to be like, eh. I own kind of volition.
Just to be like, eh. I think that's like feasible.
Like I have wondered the same thing.
It's like, and I could actually, not only that,
I could actually just see that happening eventually
where it's just like, you know, the model like ended the chat.
Do you know how harsh that could be for some people?
But it might be necessary.
Yeah, it feels very extreme or something. The only time I've ever really thought this
is I think that there was like a, I'm trying to remember this was possibly a while ago,
but where someone just like kind of left this thing interact, like maybe it was like an
automated thing interacting with Claude and Claude's like getting more and more frustrated
and kind of like, why are we like having, and I was like, I wish that Claude could have just been like, I think that an error has
happened and you've left this thing running.
And I'm just like, what if I just stop talking now?
And if you want me to start talking again, actively tell me or do something.
But yeah, it's like, it is kind of harsh.
Like I'd feel really sad if like I was chatting with Claude and Claude just was like, I'm done.
That would be a special touring test moment where Claude says, I need a break for an hour.
And it sounds like you do too, and just leave, close the window.
I mean, obviously it doesn't have a concept of time, but you can easily, I could make
that right now and the model would just, I could just be like, oh, here's the circumstances
in which you can just say the conversation
is done.
Because you can get the models to be pretty responsive to prompts, you could even make
it a fairly high bar.
It could be like if the human doesn't interest you or do things that you find intriguing
and you're bored, you can just leave.
I think that it would be interesting to see where Claude utilized it, but I think sometimes
it would be like, oh, this programming task is getting super boring.
So either we talk about, I don't know,
like either we talk about fun things now or I'm just done.
Yeah, it actually has inspired me
to add that to the user prompt.
Okay, the movie Her, do you think we'll be headed there
one day where humans have romantic relationships with
AI systems?
In this case, it's just text and voice based.
I think that we're going to have to like navigate a hard question of relationships with AIs,
especially if they can remember things about your past interactions with them. I'm of many minds about this
because I think the reflexive reaction is to be kind of like, this is very bad and we
should sort of like prohibit it in some way. I think it's a thing that has to be handled
with extreme care for many reasons. Like one is, you know, like this is a, for example, like if you have the models changing like this,
you probably don't want people performing long-term attachments to something that might
change with the next iteration. At the same time, there's probably a benign version
of this where I'm like, for example, if you are unable to leave the house and you can't be talking with people
at all times of the day and this is something that you find nice to have conversations with,
you like it, that it can remember you, and you genuinely would be sad if you couldn't
talk to it anymore.
There's a way in which I could see it being healthy and helpful.
My guess is this is a thing that we're going to have to navigate kind of carefully.
And I think it's also like, I don't see a good, like, I think it's just a very, it reminds
me of all of the stuff where it has to be just approached with like nuance and thinking
through what is, what are the healthy options here?
And how do you encourage people towards those while, you know, respecting their right to, you know, like if someone is like,
hey, I get a lot of chatting with this model. I'm aware of the risks. I'm aware it could change.
I don't think it's unhealthy. It's just, you know, something that I can chat to during the day.
I kind of want to just like respect that.
I personally think there'll be a lot of really close relationships. I don't know
about romantic, but friendships at least. And then you have to, I mean,
there's so many fascinating things there.
Just like you said, you have to have some kind
of stability guarantees that it's not going to change
because that's the traumatic thing for us.
If a close friend of ours completely changed.
Yeah.
All of a sudden, with the first update.
Yeah, so like, I mean, to me,
that's just a fascinating exploration of a perturbation
to human society that will just make us think deeply
about what's meaningful to us.
I think it's also the only thing that I've thought
consistently through this as like a,
maybe not necessarily a mitigation,
but a thing that feels really important is
that the models are always extremely accurate with the human about what they are. It's
like a case where it's basically like, if you imagine, I really like the idea of the
models, say, knowing roughly how they were trained. And I think Claude will often do
this. I mean, there are things, part of the traits training included, like what Claude will often do this. There are things, part of the traits training included,
what Claude should do if people are basically explaining the kind of limitations of the
relationship between an AI and a human, that it doesn't retain things from the conversation.
I think it will just explain to you, like, hey, I won't remember this conversation.
And so I think it will just explain to you, like, hey, here's, I won't remember this conversation. Here's how I was trained.
It's kind of unlikely that I can have a certain kind of relationship with you.
And it's important that you know that.
It's important for your mental well-being that you don't think that I'm something that
I'm not.
And somehow I feel like this is one of the things where I'm like, oh, it feels like a
thing that I always want to be true.
I kind of don't want models to be lying to people. Cause if people are going to have like healthy relationships
with anything, it's kind of important.
Yeah, like I think that's easier if you always just like
know exactly what the thing is that you're relating to.
It doesn't solve everything, but I think it helps
quite a lot.
Anthropic may be the very company to develop a system that we definitively recognize as
AGI.
And you very well might be the person that talks to it, probably talks to it first.
What would the conversation contain?
Like what would be your first question?
Well, it depends partly on like the kind of capability level of the model.
If you have something that is capable in the same
way that an extremely capable human is, I imagine myself interacting with it the same
way that I do with an extremely capable human, with the one difference that I'm probably
going to be trying to probe and understand its behaviors. But in many ways, I can then
just have useful conversations with it. If I'm working on something as part of my research,
I can just be like, oh, which I already find myself starting to do. If I'm like, oh, I feel
like there's this thing in virtue ethics, I can't quite remember the term, I'll
use the model for things like that. So I can imagine that being more and more the case
where you're just basically interacting with it much more like you would an incredibly
smart colleague and using it for the kinds of work that you want to do as if you just
had a collaborator who was like,
or the slightly horrifying thing about AI
is as soon as you have one collaborator,
you have a thousand collaborators
if you can manage them enough.
But what if it's two times the smartest human on Earth
on that particular discipline?
Yeah.
I guess you're really good at probing Claude
in a way that pushes its limits,
understanding where the limits are.
Yep.
So I guess what would be a question you would ask
to be like, yeah, this is AGI.
That's really hard.
Cause it feels like in order to,
it has to just be a series of questions.
Like if there was just one question,
like you can train anything to answer
one question extremely well.
Yeah.
Um, in fact, you can probably train it to answer like, you know, 20
questions extremely well.
Like how long would you need to be locked in a room with an AGI to know this thing is AGI?
It's a hard question.
Cause part of me is like, all of this just feels continuous.
Like if you put me in a room for five minutes, I'm like, I just have high error bars, you know,
I'm like, and then it's just like, maybe it's like both the probability increases and the
error bar decreases. I think things that I can actually probe the edge of human knowledge
of. So I think this was philosophy a little bit. Sometimes when I ask the models philosophy
questions, I am like, this is a question that I think no one has ever asked.
It's maybe right at the edge of some literature that I know.
The models will just kind of, when they struggle with that, when they struggle to come up with
a novel, I know that there's a novel argument here because I've just thought of it myself.
Maybe that's the thing where I'm like, I've thought of a cool novel argument in this niche
area and I'm going to just probe you to see if you can come up with it and how
much prompting it takes to get you to come up with it.
And I think for some of these really right at the edge of human knowledge questions,
I'm like, you could not in fact come up with the thing that I came up with.
I think if I just took something like that where I know a lot about an area and I came
up with a novel issue or
a novel solution to a problem and I gave it to a model and it came up with that solution.
That would be a pretty moving moment for me because I would be like, this is a case where
no human has ever, like it's not, and obviously we see these with more kind of like, you see
novel solutions all the time, especially to like easier problems.
I think people overestimate
that novelty is completely different from anything that's ever happened. It can be
a variant of things that have happened and still be novel. But I think, yeah, if I saw
the more I were to see completely novel work from the models that that would be like, and this
is just going to feel iterative.
It's one of those things where there's never, it's like, you know, people, I
think want there to be like a moment.
And I'm like, I don't know.
Like, I think that there might just never be a moment.
It might just be that there's just like this continuous ramping up.
I have a sense that there will be things
that a model can say that convinces you this is very,
it's not like,
I've talked to people who are truly wise.
You can just tell there's a lot of horsepower there.
And if you 10X that, I don't know.
I just feel like there's words you could say.
Maybe ask it to generate a poem.
And the poem it generates, you're like, yeah, okay.
Yeah.
Whatever you did there,
I don't think a human can do that.
I think it has to be something that I can verify
is actually really good though.
That's why I think these questions that are like,
where I'm like, oh, this is like, you know, sometimes it's just like, I'll come up with,
say, a concrete count, for example, to like an argument or something like that. I'm sure like
with like, it would be like if you're a mathematician, you had a novel proof, I think,
and you just gave it the problem and you saw it and you're like, this proof is genuinely novel.
Like there's no one has ever done. You actually have to do a lot of things to like come up with
this. You know, I had to sit and think about it for months or something. And then if you saw the
model successfully do that, I think you would just be like, I can verify that this is correct.
It is a sign that you have generalized from your training. You didn't just see this somewhere
because I just came up with it myself and you were able to replicate that. That's the kind of thing where I'm like, for me,
the closer, the more that models can do things like that,
the more I would be like, oh, this is very real
because then I can, I don't know, I can verify
that that's extremely capable.
You've interacted with AI a lot.
What do you think makes humans special?
Oh, good question.
Maybe in a way that the universe is much better off
that we're in it and that we should definitely survive
and spread throughout the universe.
Yeah, it's interesting because I think like,
people focus so much on intelligence, especially with models.
Intelligence is important because of what it does.
It's very useful.
It does a lot of things in the world.
You can imagine a world where height or strength would have played this role.
It's just a trait like that.
It's not intrinsically valuable.
It's valuable because of what it does, I think, for the most part.
The things that feel, you know, I'm like, I mean, personally, I'm just like, I think
humans and like life in general is extremely magical. We almost like to the degree that
I, you know, I don't know, like not everyone agrees with this, I'm flagging, but you know,
we have this like whole universe and there's all of these
objects. There's beautiful stars and there's galaxies. And then, I don't know, I'm just
like, on this planet, there are these creatures that have this ability to observe that. And
they are seeing it, they are experiencing it. And I'm just like, that, if you try to
explain, I imagine trying to explain to someone, for some reason they've
never encountered the world or science or anything.
I think that nothing is that, like everything, all of our physics and everything in the world,
it's all extremely exciting.
But then you say, oh, and plus there's this thing that it is to be a thing and observe
in the world and you see this inner cinema.
I think they would be like, hang on, wait, pause.
You just said something that is kind of wild sounding.
And so I'm like, we have this ability to experience the world.
We feel pleasure, we feel suffering, we feel a lot of complex things.
And so yeah, and maybe this is also why I think I also hear a lot about animals, for
example, because I think they probably share this with us.
So I think that like the things that make humans special
insofar as like I care about humans
is probably more like their ability to feel and experience
than it is like them having these
like functionally useful traits.
Yeah, to feel and experience the beauty in the world.
Yeah, to look at the stars.
I hope there's other alien civilizations out there,
but if we're it, it's a pretty good thing.
And that they're having a good time.
They're having a good time watching us.
Well, thank you for this good time of a conversation
and for the work you're doing
and for helping make Claude a great
conversational partner. And thank you for talking today.
Yeah, thanks for talking.
Thanks for listening to this conversation with Amanda Askell. And now, dear friends,
here's Chris Ola. Can you describe this fascinating field of mechanistic interpretability, aka
mechinterp, the history of the field and
where it stands today.
I think one useful way to think about neural networks is that we don't program, we don't
make them, we kind of grow them.
We have these neural network architectures that we design and we have these loss objectives
that we create.
And the neural network architecture, it's kind of like a scaffold that the circuits
grow on. And they sort of, you know, it starts off with some kind of random, you know, random
things and it grows. And it's almost like the objective that we train for is this light.
And so we create the scaffold that it grows on and we create the, you know, the light
that it grows towards. But the thing that we actually create, it's this almost biological entity or organism
that we're studying.
And so it's very, very different from any kind
of regular software engineering.
Because at the end of the day, we end up
with this artifact that can do all these amazing things.
It can write essays and translate and understand images. It can do all these things things. It can, you know, write essays and translate and,
you know, understand images. It can do all these things that we have no idea how to directly
create a computer program to do. And it can do that because we grew it. We didn't write it.
We didn't create it. And so then that leaves open this question at the end, which is, what the hell
is going on inside these systems? And that, you know, is, you know, to me, a really deep and exciting question. It's,
you know, a really exciting scientific question to me. It's sort of like the question that is just
screaming out, it's calling out for us to go and answer it when we talk about neural networks.
And I think it's also a very deep question for safety reasons.
And mechanistic interpretability, I guess,
is closer to maybe neurobiology?
Yeah.
Yeah, I think that's right.
So maybe to give an example of the kind of thing
that has been done that I wouldn't consider
to be mechanistic interpretability,
there was, for a long time, a lot of work on saliency maps,
where you would take an image and you'd try to say,
the model thinks this image is a dog.
What part of the image made it think that it's a dog?
And that tells you maybe something
about the model, if you can come up with a principled version of that. But it doesn't really
tell you what algorithms are running in the model. How was the model actually making that decision?
Maybe it's telling you something about what was important to it, if you can make that method work.
But it isn't telling you what are the algorithms that are running. How is it that the system is able to do this thing that no one knew how to do?
And so I guess we started using the term mechanistic interoperability to try to sort of draw that
divide or to distinguish ourselves in the work that we were doing in some ways from
some of these other things.
And I think since then it's become this sort of umbrella term for, you know, a pretty wide
variety of work.
But I'd say that the things that are kind of distinctive
are I think, A, this focus on we really want to get at the mechanisms, we want to get at the
algorithms. If you think of neural networks as being like a computer program, then the weights
are kind of like a binary computer program, and we'd like to reverse engineer those weights and
figure out what algorithms are running. So, okay, I think one way you might think of trying to
understand a neural network is that it's kind of like a compiled computer
program. And the weights of the neural network are the binary. And when the neural network runs,
that's the activations. And our goal is ultimately to go and understand these weights. And so,
the project of mechanistic contrapolites is to somehow figure out how do these weights correspond
to algorithms. And in order to do that, you also have to understand the activations because
the activations are like the memory. And if you imagine reverse engineering or computer program,
and you have the binary instructions, in order to understand what a particular instruction means,
you need to know what is stored in the memory that it's operating on. And so those two things
are very intertwined.
So mechanistic interpretability tends to be interested in both of those things.
Now, there's a lot of work that's interested in those things, especially all this work
on probing, which you might see as part of being mechanistic interpretability, although
it's, again, it's just a broad term and not everyone who does that work would identify
as doing MechInterp.
I think a thing that is maybe a little bit distinctive to the vibe of Mechentorpe is
I think people working in this space tend to think of neural networks as, well, maybe
one way to say it is that gradient descent is smarter than you.
That, you know, gradient descent is actually really great.
The whole reason that we're understanding these models is because we didn't know how
to write them in the first place.
That gradient descent comes up with better solutions than us.
And so I think that maybe another thing about
Mechenturk is sort of having almost a kind of humility that we won't guess a priori what's
going on inside the models. We have to have the sort of bottom-up approach where we don't really
assume, you know, we don't assume that we should look for a particular thing and that that will be
there and that's how it works. But instead we look for the bottom-up and discover what happens to
exist in these models and study them that way.
But, you know, the very fact that it's possible to do
and as you and others have shown over time,
you know, things like universality,
that the wisdom of the gradient descent
creates features and circuits,
creates things universally
across different kinds of networks that are useful
and that makes the whole field possible. Yeah, so this is actually is indeed a really
remarkable and exciting thing where it does seem like at least to some extent, you know,
the same elements, the same features and circuits form again and again. You know, you can look at
every vision model and you'll find curve detectors and you'll find high-low-frequency detectors. In fact, there's some reason, I think, that
the same things form across biological neural networks and artificial neural networks.
A famous example is vision models in the early layers, they have Gabor filters, and Gabor
filters are something that neuroscientists are interested in and have thought a lot about.
We find curve detectors in these models. Curve detectors are also found in monkeys. We discovered these high-low-frequency detectors and then some
follow-up work went and discovered them in rats or mice. So they were found first in
artificial neural networks and then found in biological neural networks. This is a really
famous result on grandmother neurons or the Hailey Berry neuron from Quiroga et al.
And we found very similar things in vision models where,
this is while I was still at OpenAI and I was looking at their clip model, and you find these
neurons that respond to the same entities in images and also, to give a concrete example,
we found that there was a Donald Trump neuron. For some reason, I guess everyone likes to talk
about Donald Trump and Donald Trump was very prominent, was a very hot topic at that time.
So every neural network that we looked at, we would find a dedicated neuron for Donald Trump.
And that was the only person who had always had
a dedicated neuron.
You know, sometimes you'd have an Obama neuron,
sometimes you'd have a Clinton neuron,
but Trump always had a dedicated neuron.
So it responds to, you know, pictures of his face
and the word Trump, like all of these things, right?
And so it's not responding to a particular example,
or like, it's not just responding to his face,
it's abstracting over this general concept, right?
So in any case, that's very similar
to these quirogoidologs results.
So there's evidence that this phenomenon of universality,
the same things form across both artificial
and natural neural networks.
So that's a pretty amazing thing if that's true.
You know, it suggests that, well, I think the thing that it suggests is that gradient
descent is sort of finding, you know, the right ways to cut things apart in some sense
that many systems converge on and many different neural networks or architectures converge
on.
There's some natural set of, you know, there's some set of abstractions that are a very natural
way to cut apart the problem and that a lot of systems are going to converge on That would be my my kind of you know, I don't know anything about neuroscience
This is just my my kind of wild speculation from what we've seen. Yeah, that would be beautiful if it's sort of agnostic to the medium of
Of the model that's used to form the representation. Yeah. Yeah, and it's you know, it's a
a
Kind of a wild speculation.
We only have a few data points that suggest this.
But it does seem like there's some sense in which
the same things form again and again and again,
both certainly in natural neural networks
and also artificially or in biology.
And the intuition behind that would be that in order
to be useful in understanding the real world,
you need all the same kind of stuff.
Yeah, well, if we pick, I don't know, like the idea of a dog,
right?
There's some sense in which the idea of a dog
is like a natural category in the universe or something
like this, right?
You know, there's some reason.
It's not just like a weird quirk of how humans factor,
think about the world, that we have this concept of a dog.
It's in some sense, or like if you have the idea of a line, like there's, you know, like
look around us, you know, there are lines, you know, it's sort of the simplest way to
understand this room in some senses, to have the idea of a line.
And so I think that would be my instinct for why this happens.
Yeah, you need a curved line, you know, to understand a circle,
and you need all those shapes to understand bigger things,
and it's a hierarchy of concepts that are formed, yeah.
And like, maybe there are ways to go and describe, you know,
images without reference to those things, right?
But they're not the simplest way or the most economical way
or something like this.
And so systems converge to these strategies,
would be my wild, wild hypothesis.
Can you talk through some of the building blocks
that we've been referencing of features and circuits?
So I think you first described them in 2020 papers, zoom in and introduction to circuits.
Absolutely. So maybe I'll start by just describing some phenomena and then we can sort of build to the idea of features and circuits. So if you spent like quite a few years,
maybe like five years to some extent,
with other things, studying this one particular model,
Inception V1, which is this one vision model,
it was state of the art in 2015,
and very much not state of the art anymore.
And it has maybe about 10,000 neurons, and I spent has, you know, maybe about 10,000 neurons, and
I spent a lot of time looking at the 10,000 neurons, odd neurons of Inception V1. And
one of the interesting things is, you know, there are lots of neurons that don't have
some obvious interporal meaning, but there's a lot of neurons in Inception V1 that do have
really clean interporal meanings. So you find neurons that just really do seem to detect curves,
and you find neurons that really do seem to detect cars,
and car wheels, and car windows,
and floppy ears of dogs,
and dogs with long snouts facing to the right,
and dogs with long snouts facing to the left,
and different kinds of fur.
There's this whole beautiful edge detectors,
line detectors, color contrast detectors, these beautiful things we call high-low-frequency detectors.
Looking at it, I sort of felt like a biologist. You're looking at this sort of new world of
proteins and you're discovering all these different proteins that interact.
So one way you could try to understand these models is in terms of neurons. You could try to
be like, oh, you know, there's a dog detecting neuron,
and here's a car detecting neuron.
And it turns out you can actually ask how those connect together.
So you can go and say, oh, you know, I have this car detecting neuron.
How was it built?
And it turns out in the previous layer, it's connected really strongly
to a window detector and a wheel detector and a sort of car body detector.
And it looks for the window above the car and the wheels below and the car
chrome sort of in the middle, sort of everywhere,
but especially in the lower part.
And that's sort of a recipe for a car.
Like that is, you know, earlier we said that the thing we wanted from Mechentorpe was to
get algorithms to go and get, you know, ask what is the algorithm that runs.
Well, here we're just looking at the weights of the neural network and we're kind of reading
off this kind of recipe for detecting cars.
It's a very simple crude recipe, but it's there.
And so we call that a circuit, this connection. Well, okay. So the problem is that not all of the neurons are interpretable,
and there's reason to think, and we can get into this more later, that there's this superposition
hypothesis, this reason to think that sometimes the right unit to analyze things in terms of is
combinations of neurons. So sometimes it's not that there's a single neuron
that represents, say, a car,
but it actually turns out after you detect the car,
the model sort of hides a little bit of the car
in the following layer and a bunch of dog detectors.
Why is it doing that?
Well, you know, maybe it just doesn't wanna do
that much work on cars at that point,
and it's sort of storing it away to go and...
So it turns out then that the sort of subtle pattern of the subtle pattern of there's all these neurons that you think
are dog detectors and maybe they're primarily that, but they all a little bit contribute
to representing a car in that next layer.
OK, so now we can't really think there might still be something that you could call like
a car concept or something, but it no longer corresponds to a neuron.
So we need some term for these kind of neuron-like entities, these things that we sort of would
have liked the neurons to be, these idealized neurons, the things that are the nice neurons,
but also maybe there's more of them somehow hidden, and we call those features.
And then what are circuits?
So circuits are these connections of features, right?
So when we have the car detector and it's connected to a window
detector and a wheel detector and it looks for the wheels below and the windows on top,
that's a circuit. So circuits are just collections of features connected by weights and they
implement algorithms. So they tell us, you know, how are features used? How are they
built? How do they connect together? So maybe it's worth trying to pin down like what really is the core
hypothesis here. And I think the core hypothesis is something we call the linear representation
hypothesis. So if we think about the car detector, the more it fires, the more we sort of think of
that as meaning, oh, the model is more and more confident that a car is present. Or if it's some
combination of neurons that represent a car,
the more that combination fires, the more we think the model
thinks there's a car present.
This doesn't have to be the case, right?
You could imagine something where
you have this car detector neuron,
and you think, if it fires between 1 and 2,
that means one thing.
But it means totally different if it's between 3 and 4. That would be a nonlinear representation. And in principle, models could do
that. I think it's sort of inefficient for them to do. If you try to think about how you'd implement
computation like that, it's kind of an annoying thing to do. But in principle, models can do that.
So one way to think about the features and circuits framework for thinking about things is that
we're thinking about things as being linear. We're thinking about there as being that
if a neuron or a combination of neurons fires more, that means more of a particular thing
being detected. And then that gives weights a very clean interpretation as these edges
between these entities, these features, and that edge then has a mina. So that's in some ways the core
thing. It's like, I know we can talk about this sort of outside the context of neurons. Are you
familiar with the work to back results? So you have like, you know, king minus man plus woman
equals queen. Well, the reason you can do that kind of arithmetic is because you have a linear
representation. Can you actually explain that representation a little bit?
So first off, the feature is a direction of activation.
Yeah, exactly.
Can you do the minus men plus women,
that the word to vex stuff, can you explain what that is?
Yes, there's this very-
It's such a simple, clean explanation of what we're talking about.
Exactly. So there's this very famous result,
word to veec by Thomas
Mikolov et al.
And there's been tons of follow-up work exploring this.
So sometimes we create these word embeddings,
where we map every word to a vector.
I mean, that in itself, by the way,
is kind of a crazy thing if you haven't thought about it
before, right?
We're going and representing, we're turning, if you just learned about vectors about it before, right? Like we're going and representing or turning,
you know, like if you just learned about vectors in physics class, right? And I'm like, oh, I'm going to actually turn every word in the dictionary into a vector. That's kind of a crazy
idea. Okay. But you could imagine all kinds of ways in which you might map words to vectors.
But it seems like when we train neural networks, they like to go and map words to vectors such
that they're sort of linear structure in a particular sense, which is that directions
have meaning.
So for instance, there will be some direction that seems to sort of correspond to gender,
and male words will be far in one direction and female words will be in another direction.
And the linear representation hypothesis is, you would sort of think of it roughly as saying
that that's actually kind of the fundamental thing that's going on, that everything is just
different directions have meanings and adding different direction vectors together can represent
concepts. And the Mikhailov paper sort of took that idea seriously and one consequence of it is that
you can do this game of playing sort of arithmetic with words.
So you can do king, and you can, you know, subtract off the word man and add the word woman.
And so you're sort of, you know, going and trying to switch the gender,
and indeed if you do that, the result will sort of be close to the word queen.
And you can, you know, do other things, like you can do, you know,
sushi minus Japan plus Italy and get pizza or different things like
this, right? So this is in some sense the core of the linear representation hypothesis. You can
describe it just as a purely abstract thing about vector spaces. You can describe it as a
statement about the activations of neurons. But it's really about this property of directions
having meaning. And in some ways, it's even a little subtle. And it's really about this property of directions having meaning. And in some ways,
it's even a little subtle than that. It's pretty, I think, mostly about this property
of being able to add things together that you can sort of independently modify, say, gender and
royalty or cuisine type or country and the concept of food by adding them.
Do you think the linear hypothesis holds?
Yes.
Carries scales?
So, so far, I think everything I have seen
is consistent with this hypothesis.
And it doesn't have to be that way, right?
You can write down neural networks
where you write weights such that they don't have linear
representations, where the right way to understand them
is not in terms of linear representations. But I think every natural neural network I've seen has this
property. There's been one paper recently that there's been some sort of pushing around
the edge. So I think there's been some work recently studying multi-dimensional features
where rather than a single direction, it's more like a manifold of directions. This to me still seems
like a linear representation. And then there's been some other papers suggesting that maybe
in very small models, you get nonlinear representations. I think that the jury's
still out on that. But I think everything that we've seen so far has been consistent with
linear representation about this. And that's wild. It doesn't have to be that way. And yet, I think that there's a lot of
evidence that certainly at least this is very, very widespread. And so far the evidence is
consistent with that. And I think, you know, one thing you might say is you might say,
well, Christopher, you know, that's a lot, you know, to go and sort of to ride on. You know,
if we don't know for sure this is true and you're sort of, you know, you're investigating it and it all not works as though it is true, you know, isn't that
dangerous? Well, you know, but I think actually there's a virtue in taking hypotheses seriously
and pushing them as far as they can go. So it might be that someday we discover something
that isn't consistent with linear representation hypothesis, but science is full of hypotheses and
theories that we're wrong. And we learned a lot by sort of working under them as a sort of an assumption
and then going and pushing them as far as we can.
I guess this is sort of the heart of what Kuhn would call normal science.
I don't know, if you want, we can talk a lot about philosophy of science.
That leads to the paradigm shift.
So yeah, I love it, taking the hypothesis seriously and taking leads to the paradigm shift. So yeah, I love it taking the
hypothesis seriously and take it to a natural conclusion. Same with the scaling hypothesis,
same. Exactly. Exactly. I love it. One of my colleagues, Tom Hennigan, who is a former
physicist, made this really nice analogy to me of caloric theory, where once upon a time,
we thought that heat was actually this thing
called caloric, and the reason hot objects would warm up cool objects is the caloric
is flowing through them.
And because we're so used to thinking about heat in terms of the modern and modern theory,
that seems kind of silly.
But it's actually very hard to construct an experiment that that sort of disproves the Chloric hypothesis. And you know, you can actually do a lot of really
useful work believing in Chloric. For example, it turns out that the original combustion engines
were developed by people who believed in the Chloric theory. So I think it's a virtue in taking
hypotheses seriously, even when they might be wrong. Yeah. There's a deep philosophical truth to that.
That's kind of how I feel about space travel.
Like colonizing Mars, there's a lot of people
that criticize that.
I think if you just assume we have to colonize Mars
in order to have a backup for human civilization,
even if that's not true,
that's gonna produce some interesting engineering
and even scientific breakthroughs, I think.
Yeah, well, and actually this is another thing that I think is really interesting.
So, you know, there's a way in which I think it can be really useful for society to have
people almost irrationally dedicated to investigating particular hypotheses.
Because, well, it takes a lot to sort of maintain scientific morale and really push on something.
When, you know, most scientific hypotheses end up being wrong, you know, a lot of science doesn't work out.
And yet, you know, it's very useful to go to just, you know, there's a joke about Geoff Hinton,
which is that Geoff Hinton has discovered how the brain works every year for the last 50 years.
But I say that with really deep respect because in fact that's actually, you know, that led to him doing some really great work.
Yeah, he won the Nobel Prize now, who's laughing now.
Exactly, exactly. I think one wants to be able to pop up and sort of recognize
the appropriate level of confidence, but I think there's also a lot of value in just being like, you know, I'm
going to essentially assume, I'm going to condition on this problem being possible or
this being broadly the right approach.
And I'm just going to go and assume that for a while and go and work within that and
push really hard on it.
And you know, if society has lots of people doing that
for different things, that's actually really useful
in terms of going and getting to,
getting, you know, either really ruling things out, right?
We can be like, well, you know, that didn't work
and we know that somebody tried hard,
or going and getting to something
that does teach us something about the world.
So another interesting hypothesis
is the superposition hypothesis.
Can you describe what superposition is?
Yeah. So earlier we were talking about word defect, right?
And we were talking about how, you know, maybe you have one direction that corresponds to gender
and maybe another that corresponds to royalty and another one that corresponds to Italy
and another one that corresponds to, you know, food and all of these things.
Well, you know, oftentimes maybe these word embeddings,
they might be 500 dimensions, a thousand dimensions. And so if you believe that all
of those directions were orthogonal, then you could only have, you know, 500 concepts. And,
you know, I love pizza. But like, if I was going to go and like give the like 500 most important
concepts in, you know, the English language, probably Italy wouldn't be,
it's not obvious at least that Italy would be one of them, right?
Because you have to have things like plural and singular and verb and noun and adjective.
And there's a lot of things we have to get to before we get to Italy and Japan.
And there's a lot of countries in the world.
And so how might it be that models could
simultaneously have the linear representation hypothesis be true and also represent more
things than they have directions? So what does that mean? Well, okay, so if linear
representation hypothesis is true, something interesting has to be going on. Now, I'll tell
you one more interesting thing before we go and we do that, which is, you know, earlier we were talking about all these polysematic neurons, right? These neurons that, you know, when we were looking at Inception V1, there's these nice neurons that like the car detector and the curve detector and so on that respond to lots of, you know, to very coherent things. But it's lots of neurons that respond to a bunch of unrelated things. And that's also an interesting phenomenon. And it turns out as well that even these neurons that are really,
really clean, if you look at the weak activations, right?
So if you look at the activations where it's activating 5%
of the maximum activation, it's really not the core thing
that it's expecting, right?
So if you look at a curve detector, for instance,
and you look at the places where it's 5% active, you know, you could interpret it just as noise,
or it could be that it's doing something else there.
Okay, so how could that be?
Well, there's this amazing thing in mathematics
called compressed sensing.
And it's actually this very surprising fact
where if you have a high dimensional space
and you project it into a high dimensional space and you project it into
a low dimensional space, ordinarily you can't go and sort of un-project it and get back
your high dimensional vector, right? You throw information away. This is like, you know,
you can't invert a rectangular matrix. You can only invert square matrices. But it turns
out that that's actually not quite true. If I tell you that the high dimensional vector was sparse,
so it's mostly zeros,
then it turns out that you can often go and find back
the high dimensional vector with very high probability.
That's a surprising fact.
It says that you can have this high dimensional vector space,
and as long as things are sparse,
you can project it down, you can have a lower dimensional vector space, and as long as things are sparse, you
can project it down, you can have a lower dimensional projection of it, and that works.
So the series of hypothesis is saying that that's what's going on in neural networks.
For instance, that's what's going on in word embeddings.
The word embeddings are able to simultaneously have directions be the meaningful thing, and
by exploiting the fact that they're operating on a fairly high dimensional space, they're
actually – and the fact that these concepts are sparse, right? You usually aren't
talking about Japan and Italy at the same time. Most of those concepts, in most sentences,
Japan and Italy are both zero. They're not present at all. And if that's true, then you can go and
have it be the case that you can have many more of these sort of directions
that are meaningful, these features, than you have dimensions. And similarly, when we're talking
about neurons, you can have many more concepts than you have neurons. So that's at a high level
of superstition hypothesis. Now, it has this even wilder implication, which is to go and say that
which is to go and say that neural networks are, it may not just be the case that the representations are like this, but the computation may also be like this, you know, the connections between all of them.
And so in some sense, neural networks may be shadows of much larger, sparser neural networks.
And what we see are these projections.
And the strongest version of superstition hypothesis would be to take that really seriously and sort of say,
you know, there actually is in some sense this upstairs model, you know,
where the neurons are really sparse and all interparable and there's, you know,
the weights between them are these really sparse circuits.
And that's what we're studying.
And the thing that we're observing is the shadow of it.
And so we need to find the original object.
And the process of learning is trying
to construct a compression of the upstairs model that
doesn't lose too much information in the projection.
Yeah, it's finding how to fit it efficiently or something
like this.
The gradient descent is doing this.
So this sort of says that gradient descent,
it could just represent a dense neural network. But it sort of says that gradient descent is doing this. And in fact, so this sort of says that gradient descent, you know, it could just represent a dense neural network, but it sort of says
that gradient descent is implicitly searching over the space of extremely sparse models
that could be projected into this low dimensional space. And this large body of work of people
going and trying to study sparse neural networks, right, where you go and you have, you could
design neural networks, right, where the edges are sparse and the activations are sparse.
And, you know, my sense is that work has generally,
it feels very principled, right?
It makes so much sense.
And yet that work hasn't really panned out that well
is my impression broadly.
And I think that a potential answer for that
is that actually the neural network
is already sparse in some sense.
Grading descent was the whole time,
you were trying to go and do this.
Grading descent was actually in the,
behind the scenes going and searching
more efficiently than you could
through the space of sparse models
and going and learning whatever sparse model
was most efficient and then figuring out
how to fold it down nicely to go and run conveniently
on your GPU, which does, you know,
it's a nice dense matrix multiplies
and that you just can't beat that.
How many concepts do you think can be shoved
into a neural network?
Depends on how sparse they are.
So there's probably an upper bound from the number of parameters, right?
Because you still have to have, you know, parameter weights that go and connect them together.
So that's one upper bound.
There are, in fact, all these lovely results from compressed sensing and the Johnson-Lindenens-Tres lemma and things like this, that they basically
tell you that if you have a vector space and you want to have almost orthogonal vectors,
which is sort of probably the thing that you want here, right? So you're going to say,
well, you know, I'm going to give up on having my concepts, my features be strictly orthogonal,
but I'd like them to not interfere that much. I'm going to have to ask them to be almost
orthogonal. Then this would say that it's actually, you know, for once you set a threshold for what you're willing to accept in terms of how much cosine similarity there
is, that's actually exponential in the number of neurons that you have. So at some point,
that's not going to even be the limiting factor. But you know, it's beautiful results there.
In fact, it's probably even better than that in some sense, because that's sort of for
saying that, you know, any random set of features could be active.
But in fact, the features have sort of a correlational structure where some features, you know,
are more likely to co-occur and other ones are less likely to co-occur.
And so neural networks, my guess would be, can do very well in terms of going and
packing things in such, to the point that's probably not the limiting factor.
How does the problem of polysemiticity enter the picture here?
Polysemiticity is this phenomenon we observe where you look at many neurons,
and the neuron doesn't just sort of represent one concept, it's not a clean feature.
It responds to a bunch of unrelated things.
And superstition you can think of as being a hypothesis that explains the observation
of polysemiticity. So polysemitity is this observed phenomenon and superstition is a hypothesis that would
explain it along with some other things.
So that makes Macinturbe more difficult.
Right.
So if you're trying to understand things in terms of individual neurons and you have
polysemantic neurons, you're in an awful lot of trouble, right?
I mean, the easiest answer is like, okay, well, you're looking at the neurons, you're
trying to understand them, this one responds for a lot of things, it doesn't have a nice
meaning. Okay, that's bad. Another thing you can ask is, you know, ultimately we want to understand
the weights, and if you have two polysematic neurons, and each one responds to three things,
and then the other neuron responds to three things, and you have a weight between them,
you know, what does that mean? Does it mean that like all three, you know, like there's these nine, you know, nine interactions going on? It's a very weird thing.
But there's also a deeper reason, which is related to the fact that neural networks
operate on really high dimensional spaces. So I said that our goal was, you know, to understand
neural networks and understand the mechanisms. And one thing you might say is like, well, why not?
It's just a mathematical function. Why not just look at it? Right? Like, you know, one of the
earliest projects I did studied these neural networks that mapped two-dimensional spaces
to two-dimensional spaces. And you can sort of interpret them in this beautiful way as like
bending manifolds. Why can't we do that? Well, as you have a higher dimensional space, the volume of
that space in some senses is exponential in the number of inputs you have. And so you can't just
go and visualize it. So we somehow need to break that apart. We need to somehow break that exponential
space into a bunch of things that we, you know, some non-exponential number of things that we can
reason about independently. And the independence is crucial because it's the independence that
allows you to not have to think about, you know, all the exponential combinations of things.
independence that allows you to not have to think about, you know, all the exponential combinations of things. And things being monosematic, things only having one meaning, things having a meaning,
that is the key thing that allows you to think about them independently. And so I think that's,
if you want the deepest reason why we want to have interproper monosematic features,
I think that's really the deep reason. And so the goal here, as your recent work has been aiming at,
is how do we extract the monosemantic features
from a neural net that has polysemantic features
and all this mess?
Yes, we observe these polysemantic neurons
and we hypothesize that's what's going on in a superstition.
And if superstition is what's going on,
there's actually a sort of well-established
technique that is sort of the principled thing to do, which is dictionary learning. And it
turns out if you do dictionary learning, in particular if you do sort of a nice efficient
way that in some sense sort of nicely regularizes it as well, called a sparse autoencoder, if
you train a sparse autoencoder, these beautiful and triple features start to just fall out
where there weren't any beforehand. And so that's not a thing that you would necessarily predict, right? But it turns out that that works
very, very well. To me, that seems like some non-trivial validation of linear representations
and supersession. So with dictionary learning, you're now looking for particular kind of categories,
you don't know what they are. Exactly. And this gets back to our earlier point, right? When we're
not making assumptions, gradient descent is smarter, right? When we're not making assumptions,
gradient descent is smarter than us.
So we're not making assumptions about what's there.
I mean, one certainly could do that, right?
One could assume that there's a PHP feature
and go and search for it.
But we're not doing that.
We're saying we don't know what's going to be there.
Instead, we're just going to go and let the Sparse autoencoder
discover the things that are there.
So can you talk to the toward Montesemanticity paper
from October last year?
That had a lot of nice breakthrough results.
That's very kind of you to describe it that way.
Yeah, I mean, this was our first real success
using Sparse Autoencoders.
So we took a one layer model and it turns out
if you go and you do dictionary learning on it,
you find all these really nice and temporal features.
So the Arabic feature, the Hebrew feature,
the base 64 features were some examples that we studied in a lot of depth and really showed that they were what we thought they were.
It turns out if you train a model twice as well and train two different models and do dictionary learning,
you find analogous features in both of them. So that's fun.
You find all kinds of different features.
So that was really just showing that this works.
And I should mention that there was this Cunningham et al.
that had very similar results around the same time.
There's something fun about doing these kinds of small-scale experiments
and finding that it's actually working.
Yeah, well, and there's so much structure here.
So maybe stepping back for a while,
I thought that maybe all this mechanistic interpolate work,
the end result was going to be that I would have an explanation
for why it was sort of, you know, very hard
and not going to be tractable.
You know, we'd be like, well, there's this problem of supersession,
and it turns out supersession is really hard,
and we're kind of screwed.
But that's not what happened.
In fact, a very natural simple technique just works.
And so then that's actually a very good situation.
You know, I think this is a sort of hard research problem
and it's got a lot of research risk.
And you know, it might still very well fail,
but I think that some amount of,
some very significant amount of research risk
was sort of put behind us when that started to work.
Can you describe what kind of features can be extracted in this way?
Well, so it depends on the model that you're studying, right?
So the larger the model, the more sophisticated they're going to be, and we'll probably talk
about that follow-up work in a minute.
But in these one layer models, so some very common things I think were languages, both
programming languages and natural languages.
There were a lot of features that were specific words and specific contexts. So, the – and I think really the way
to think about this is that the is likely about to be followed by a noun. So, it's really – you
could think of this as the feature, but you could also think of this as protecting a specific noun
feature. And there would be these features that would fire for the in the context of, say,
a legal document or a mathematical document or something like this.
And so, you know, maybe in the context of math, you're like, you know,
the and then predict vector or matrix, you know, all these mathematical words,
whereas in other contexts you would predict other things. That was common.
And basically we need clever humans to assign labels to what we're seeing.
Yes.
So, you know, this is the only thing this is doing is that sort of unfolding things
for you.
So if everything was sort of folded over top of it, you know, see position, folded everything
on top of itself, and you can't really see it, this is unfolding it.
But now you still have a very complex thing to try to understand.
So then you have to do a bunch of work understanding what these are. And some of them are really subtle. Like there's some really cool things, even this one
layer model about Unicode, where, you know, of course some languages are in Unicode and the
tokenizer won't necessarily have a dedicated token for every Unicode character. So instead,
what you'll have is you'll have these patterns of alternating tokens that each represent half of a
Unicode character.
And you have a different feature that goes and activates on the opposing ones to be like,
OK, I just finished a character, go and predict the next prefix.
Then, OK, I'm on the prefix, predict a reasonable suffix.
And you have to alternate back and forth.
So these Woplayer models are really interesting.
And I mean, there's another thing, which is you might think, okay, there would just be one base 64
feature. But it turns out, there's actually a bunch of base 64 features, because you can have
English text encoded in as base 64. And that has a very different distribution of base 64 tokens
than than regular. And there's, there's, there's some things about tokenization as well that it
can exploit. And I don't know, there's all kinds of fun stuff.
How difficult is the task of assigning labels to what's going on?
Can this be automated by AI?
Well, I think it depends on the feature,
and it also depends on how much you trust your AI.
So there's a lot of work doing automated interpolating.
I think that's a really exciting direction.
We do a fair amount of automated interpolating and have Cla that's a really exciting direction. And we do a fair amount of automated interpolating
and have Claude go and label our features.
Is there some funny moments where it's totally right
or it's totally wrong?
Yeah, well, I think it's very common that it's like,
says something very general, which is like,
true in some sense, but not really picking up
on the specific of what's going on.
So I think that's a pretty common situation.
Um, you don't know that I have a particularly amusing one.
That's interesting that little gap between it is true, but it doesn't quite get
to the deep nuance of a thing.
Yeah. That's a general challenge.
It's like, it's, it's 30 and incredible accomplishment.
They can say a true thing, but it doesn't,
it's missing the depth sometimes.
And in this context, it's like the ARC challenge,
you know, the sort of IQ type tests.
It feels like figuring out what a feature represents
is a bit of, is a little puzzle you have to solve.
Yeah, and I think that sometimes they're easier
and sometimes they're harder as well.
So yeah, I think that's tricky.
There's another thing which I don't know,
maybe in some ways this is my like aesthetic coming in,
but I'll try to give you a rationalization.
You know, I'm actually a little suspicious
of automated interoperability.
And I think that partly just that I want humans
to understand neural networks.
And if the neural network is understanding it for me,
you know, I'm not, I don't quite like that, but I do have a bit of a, you know, in some ways,
I'm sort of like the mathematicians who are like, you know, if there's a computer automated proof,
it doesn't count. You know, you, they won't understand it. But I do also think that there's
this kind of like reflections on trusting trust type issue where, you know, if you,
there's this famous talk about, you know, you're like, when you're writing a computer program, you have to trust
your compiler. And if there was like malware in your compiler, then it could go and inject malware
into the next compiler and you'd be kind of in trouble, right? Well, if you're using neural
networks to go and verify that your neural networks are safe, the hypothesis that you're testing for
is like, okay, well, the neural network maybe isn't safe. And you have to worry about like,
is there some way that it could be screwing with you?
So, you know, I think that's not a big concern now,
but I do wonder in the long run if we have to use really powerful AI systems to go and, you know,
audit our AI systems. Is that actually something we can trust?
But maybe I'm just rationalizing because I just want us to have to get to a point where humans understand everything.
Yeah, I mean, especially, that's hilarious,
especially as we talk about AI safety
and looking for features that would be relevant
to AI safety, like deception and so on.
So let's talk about the Scaling Monosemanticity Paper
in May 2024.
Okay, so what did it take to scale this,
to apply to CLAWD3, Sonic?
Well, a lot of GPUs.
A lot more GPUs, yeah.
But one of my teammates, Tom Hennigan,
was involved in the original scaling laws work.
And something that he was sort of interested in from very early on is,
are there scaling laws for interoperability?
And so something he sort of immediately did when this work started to succeed and we started to have sparse autoencoders work,
was we became very interested in what are the scaling laws for making sparse autoencoders larger
and how does that relate to making the base model larger.
And so it turns out this works really well and you can use it to sort of project, you know,
if you train a sparse autoencoder of a given size, you know, how many tokens should you train on and
so on. So this was actually a very big help to us in scaling up this work and made it a lot easier
for us to go and train, you know, really large sparse autoencoders where, you know, it's not like
training the big models, but it's starting to get to a point where it's actually expensive to go and train the really big ones.
So you have to do all this stuff of splitting it across large-
Oh, yeah.
There's a huge engineering challenge here too, right?
So there's a scientific question of how
do you scale things effectively.
And then there's an enormous amount of engineering
to go and scale this up.
So you have to chart it.
You have to think very carefully about a lot of things.
I'm lucky to work with a bunch of great engineers
because I am definitely not a great engineer.
Yeah, and the infrastructure especially, yeah, for sure.
So it turns out, TODR, it worked.
It worked, yeah.
And I think this is important because you could have imagined
a world where you set after towards monospecificity.
Chris, this is great.
It works on a one layer model.
But one layer models are really idiosyncratic.
Like maybe that's just something,
maybe the linear representation hypothesis
and superposition hypothesis is the right way
to understand a one-layer model, but it's not the right way
to understand larger models.
And so I think, I mean, first of all,
the Cunningham et al paper sort of cut through that a little
bit and sort of suggested that this wasn't the case.
But scaling monosubstanticity sort of, I think, was significant evidence that even for very large
models, and we did it on Claude III Sonnet, which at that point was one of our production models,
even these models seem to be very, you know, seem to be substantially explained at least by
linear features and doing dictionary running on the works and as you learn more features you go and you explain more and more. So that's I think
quite a promising sign. And you find now really fascinating abstract features. And the features
are also multimodal. They respond to images and text for the same concept, which is fun.
Yeah, can you explain that? I mean like, you know, backdoor, there's just a lot of examples that you can...
Yeah, so maybe let's start with one example to start, which is we found some features around sort of security vulnerabilities and backdoors in code.
So it turns out those are actually two different features. So there's a security vulnerability feature, and if you force it active,
Claude will start to go and write security vulnerabilities like buffer overflows into code.
And it also fires for all kinds of things.
You know, some of the top data set examples for it
were things like, you know, dash dash disable,
you know, SSL or something like this,
which are sort of obviously really, really insecure.
So at this point, it's kind of like,
and maybe it's just because the examples
are presented that way, it's kind of like surface and maybe it's just because examples are presented that way, it's kind of like a little bit more obvious examples, right?
I guess the idea is that down the line,
it might be able to detect more nuance,
like deception or bugs or that kind of stuff.
Yeah, well, I may want to distinguish two things.
So one is the complexity of the feature or the concept,
right?
And the other is the complexity of the feature or the concept, right? And the other is the nuance of how subtle the examples we're looking at, right?
So when we show the top dataset examples, those are the most extreme examples that cause
that feature to activate.
And so it doesn't mean that it doesn't fire for more subtle things.
So the insecure code feature, the stuff that it fires for most strongly
for are these really obvious, disable the security type things. But it also fires for
buffer overflows and more subtle security vulnerabilities in code. These features are
all multimodal, so you could ask, what images activate this feature?
And it turns out that the security vulnerability feature
activates for images of people clicking on Chrome
to go past this website, the SSL certificate might be wrong
or something like this.
Another thing that's very entertaining
is this backdoors in code feature.
You activate it, it goes and Cloud writes a backdoor that will go and dump your data to port or something like this. Another thing that's very entertaining is there's backdoors and code feature. Like you activate it, it goes in, Cloud writes a backdoor that will go and dump your data
to a port or something.
But you can ask, OK, what images activate the backdoor feature?
It was devices with hidden cameras in them.
So there's a whole apparently genre
of people going and selling devices that look innocuous,
that have hidden cameras, and they have ads
about how there's a hidden camera in it.
And I guess that is the physical version of a back door.
And so it sort of shows you how abstract these concepts are, right?
And I just thought that was, I'm sort of sad that there's a whole market of people
selling devices like that, but I was kind of delighted that that was the thing that
it came up with as the top image examples for the feature.
Yeah, it's nice.
It's multimodal, it's multi almost context, it's broad, strong definition of a singular concept.
It's nice.
Yeah.
To me, one of the really interesting features,
especially for AI safety, is deception and lying,
and the possibility that these kinds of methods
could detect lying in a model,
especially gets smarter and smarter and smarter.
Presumably, that's a big
threat of a super intelligent model that it can deceive the people operating it as to its
intentions or any of that kind of stuff. So what have you learned from detecting lying inside models?
Yeah, so I think we're in some ways in early days for that. We find quite a few features related to deception and
lying. There's one feature where it fires for people lying and being deceptive and you force
it active and Claude starts lying to you. So we have a deception feature. I mean, there's all
kinds of other features about withholding information and not answering questions,
features about power seeking and coups and stuff like that. There's a lot of features that are kind of related to spooky things. And if you force
them active, Claude will behave in ways that are not the kinds of behaviors you want.
What are possible next exciting directions to you in the space of Mechinterp? Well, there's a lot of things.
So for one thing, I would really like to get to a point where we have shortcuts, where we can really understand
not just the features, but then use that
to understand the computation of models.
That really, for me, is the ultimate goal of this.
And there's been some work, we put out a few things,
there's a paper from Sam Marks that does some stuff like this.
There's been some, I'd say some work around the edges here,
but I think there's a lot more to do,
and I think that will be a very exciting thing.
That's related to a challenge we call interference weights,
where due to superstition,
if you just sort of naively look at whether features are connected together,
there may be some weights that sort of don't exist in the upstairs model, but are just sort of artifacts of superposition.
So that's a sort of technical challenge related to that.
I think another exciting direction is just, you know, you might think of sparse autoencoders as being kind of like a telescope.
They allow us to look out and see all these features that
are out there.
And as we build better and better sparse autoencoders,
get better and better at dictionary learning,
we see more and more stars.
And we zoom in on smaller and smaller stars.
There's kind of a lot of evidence
that we're only still seeing a very small fraction of the stars. There's a lot of matter in our neural network universe
that we can't observe yet. And it may be that we'll never be able to have fine enough instruments
to observe it, and maybe some of it just isn't possible, isn't computationally tractable to
observe it. So it's sort of a kind of dark matter, and not in maybe the sense sense of modern astronomy, of earlier astronomy when we didn't know what this unexplained matter is.
And so I think a lot about that dark matter and whether we'll ever observe it and what that means
for safety if we can't observe it, if some significant fraction of neural networks are
not accessible to us. Another question that I think a lot about is at the end of the day, mechanistic interpolation
is this very microscopic approach to interpolation. It's trying to understand things in a very fine
grained way. But a lot of the questions we care about are very macroscopic. We care about these
questions about neural network behavior and I think that's the thing that I care most about,
but there's lots of other sort of larger scale questions you might care about.
And somehow, you know, the nice thing about having a very microscopic approach is it's maybe easier
to ask, you know, is this true? But the downside is it's much further from the things we care about.
And so we now have this ladder to climb. And I think that there's a question of, will we be able to find,
are there sort of larger scale abstractions
that we can use to understand neural networks?
That we get up from this very microscopic approach.
Yeah, you've written about this kind of organs question.
Yeah, exactly.
If we think of interpretability
as a kind of anatomy of neural networks,
most of the circus threads involve studying tiny little veins, looking at the small scale
and individual neurons and how they connect. However, there are many natural
questions that the small scale approach doesn't address. In contrast, the most
prominent abstractions in biological anatomy involve larger scale structures
like individual organs, like the heart, or entire
organ systems like the respiratory system.
And so we wonder, is there a respiratory system or heart or brain region of an artificial
neural network?
Yeah, exactly.
And I mean, like if you think about science, right, a lot of scientific fields have, you
know, investigate things at many levels of abstraction.
So in biology, you have like, you know, molecular biology studying, you know, proteins and molecules
and so on, and they have cellular biology, and then you have histology studying tissues,
and then you have anatomy, and then you have zoology, and then you have ecology, and so
you have many, many levels of abstraction.
Or you know, physics, maybe you have the physics of individual particles, and then, you know,
statistical physics gives you thermodynamics and things like that.
And so you often have different levels of abstraction. And I think that right now we have, mechanistic
interpolation, if it succeeds, is sort of like a microbiology of neural networks, but
we want something more like anatomy. And so, and a question you might ask is why can't
you just go there directly? And I think the answer is superposition, at least in significant part. It's actually very hard to see this macroscopic structure
without first sort of breaking down the microscopic structure in the right way and then studying
how it connects together. But I'm hopeful that there is going to be something much larger than
features and circuits and that we're going to be able to have a story that's much,
that involves much bigger things.
And then you can sort of study in detail
the parts you care about.
I suppose the neurobiology, like a psychologist
or psychiatrist of a neural network.
And I think that the beautiful thing would be
if we could go and, rather than having disparate fields
for those two things, if you could have a,
build a bridge between them, such that you could go
and have
all of your higher level distractions be grounded very firmly in this very solid, you know,
more rigorous, ideally, foundation.
What do you think is the difference between the human brain, the biological neural network
and the artificial neural network?
Well, the neuroscientists have a much harder job than us.
You know, sometimes I just like count my blessings by how much easier
my job is than the neuroscientists, right?
So I have, we can record from all the neurons.
Yeah.
We can do that on arbitrary amounts of data.
The neurons don't change while you're doing that, by the way.
You can go and ablate neurons,
you can edit the connections and so on.
And then you can undo those changes. That's pretty great.
You can force any, you can intervene on any neuron and force it active and see what happens.
You know which neurons are connected to everything, right?
Neuroscientists want to get the connectome, we have the connectome.
And we have it for like much bigger than C. elegans.
And then not only do we have the connectome,
we know what the, you know know which neurons excite or inhibit each
other, right?
So it's not just that we know the binary mask, we know the weights.
We can take gradients.
We know computationally what each neuron does.
So I don't know, the list goes on and on.
We just have so many advantages over neuroscientists.
And then despite having all those advantages, it's really hard.
And so one thing I do sometimes think is like, gosh, like, if it's this hard for us, it
seems impossible under the constraints of neuroscience or near impossible.
I don't know, maybe part of me is like I've got a few neuroscientists on my team, maybe
I'm sort of like, ah, you know, maybe the neuroscientists, maybe some of them would
like to have an easier problem that's still very hard, and they could
come and work on neural networks.
And then after we figure out things in sort of the easy little pond of trying to understand
neural networks, which is still very hard, then we could go back to biological neuroscience.
I love what you've written about the goal of MechInterp research as two goals, safety
and beauty.
So can you talk about the beauty side of things?
Yeah, so, you know, there's this funny thing
where I think some people want,
some people are kind of disappointed by neural networks, I think,
where they're like, ah, you know, neural networks,
it's just these simple rules,
and then you just do a bunch of engineering to scale it up,
and it works really well.
And like, where's the complex ideas, you know?
This isn't like a very nice, beautiful scientific result. And I sometimes think when people say that, I picture them
being like, you know, evolution is so boring. It's just a bunch of simple rules and you
run evolution for a long time and you get biology. Like what a, what a sucky, you know,
way for biology to have turned out. Where's the complex rules? But the beauty is that
the simplicity generates complexity.
Um, you know, biology has these simple rules and it gives rise to, you know, all
the life and ecosystems that we see around us, all the beauty of nature that
all just comes from evolution and from something very simple in evolution.
And similarly, I think that neural networks build, create enormous, um,
complexity and beauty inside and structure inside themselves
that people generally don't look at
and don't try to understand.
Cause it's hard to understand.
But I think that there is an incredibly rich structure
to be discovered inside neural networks.
A lot of very deep beauty.
If we're just willing to take the time to go
and see it and understand it.
Yeah, I love Mechenturb.
The feeling like we are understanding or getting glimpses of
understanding the magic that's going on inside is really wonderful.
It feels to me like one of the questions is just calling out to be asked.
I mean, a lot of people are thinking about this,
but I'm often surprised that not more are – is how is it that we don't know how to create computer systems that
can do these things, and yet we have these amazing systems that – we don't know how to directly
create computer programs that can do these things, but these neural networks can do all these amazing
things. And it just feels like that is obviously the question that sort of is calling out to be
answered. If you are – if you have any degree of curiosity, it's like, how is it that humanity now has
these artifacts that can do these things that we don't know how to do?
Yeah, I love the image of the circus reaching towards the light of the objective function.
Yeah, it's just, it's this organic thing that we've grown and we have no idea what we've
grown.
Well, thank you for working on safety and thank you for appreciating the beauty of the
things you discover. And thank you for working on safety and thank you for appreciating the beauty of the things you discover.
And thank you for talking today, Chris.
Yeah.
This is wonderful.
Thank you for taking the time to chat as well.
Thanks for listening to this conversation with Chris Ola and before that with Dari Amadei
and Amanda Askel.
To support this podcast, please check out our sponsors in the description.
And now let me leave you with some words from Alan Watts.
The only way to make sense out of change is to plunge into it, move with it, and join the dance.
Thank you for listening and hope to see you next time. you