The a16z Show - Marc Andreessen on AI Winters and Agent Breakthroughs
Episode Date: April 3, 2026This episode originally aired on the Latent Space Podcast. swyx and Alessio Fanelli speak with Marc Andreessen about the arc of AI from its origins in 1943 to today's breakthroughs in reasoning, codin...g agents, and self-improvement. They cover the parallels between AI scaling laws and Moore's Law, the architectural insight behind Claude Code and the Unix shell, the coming supply crunch in compute, and why the messy reality of 8 billion people means both AI utopians and doomers are too optimistic about the pace of change. Follow Marc Andreessen on X: https://twitter.com/pmarca Follow Shawn "swyx" Wang on X: https://twitter.com/swyx Follow Alessio Fanelli on X: https://twitter.com/FanaHOVA Listen to Latent Space. Stay Updated:Find a16z on YouTube: YouTubeFind a16z on XFind a16z on LinkedInListen to the a16z Show on SpotifyListen to the a16z Show on Apple PodcastsFollow our host: https://twitter.com/eriktorenberg Please note that the content here is for informational purposes only; should NOT be taken as legal, business, tax, or investment advice or be used to evaluate any investment or security; and is not directed at any investors or potential investors in any a16z fund. a16z and its affiliates may maintain investments in the companies discussed. For more details please see a16z.com/disclosures. Hosted by Simplecast, an AdsWizz company. See pcm.adswizz.com for information about our collection and use of personal data for advertising.
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This episode originally aired on the Latent Space podcast.
Mark Andresen has watched AI cycle through summers and winters for more than 35 years,
from coding and LISP in 1989 to backing the foundation model companies today.
He argues that the current moment is not another false start,
but the payoff from eight decades of foundational research,
catalyzed by four distinct breakthroughs,
large language models, reasoning, agents, and self-improvement,
He also makes the case that the combination of a language model, a Unix shell, and a file system
represent one of the most important software architectures in a generation.
Swix and Alessio Finnelli speak with Mark Andresen,
co-founder and general partner at A16Z.
Something about AI that causes the people in the field, I would say,
to become both excessively utopian and excessively apocalyptic.
Having said that, I think what's actually happened is an enormous amount of tactical progress
that built up over time.
And like, for example, we now know the neural network is the correct architect.
And I will tell you, like, there was a 60-year run where that was like a, you know, or even 70 years or that was controversial.
And so the way I think about what's happening is basically, I think about basically the period we're in right now is it's, I call it 80-year overnight success.
Right.
Which is like, it's an overnight success because it's like, bam, you know, chat GPT hits and then, you know, open-cloth hits and then, you know, open, these are like overnight, like radical overnight transformative successes.
But they're drawing on an 80-year sort of well-spring backlog, you know, of ideas and think.
It's not just that it's all brand new,
it's an unlock of all of these decades
of very serious hardcore research.
By 18, this is what I would be spending all of my time on.
This is like such an incredible conceptual breakthrough.
Before we get into today's episode,
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Now let's get into it.
Hey, everyone.
Welcome to the Lit In Space Podcast.
This is Alasio, founder of Colonel Labs, and I'm joined by Spix, Editor of Bladed and Space.
Hello, and we're in A16 with A. MarkaGIS and welcome.
Yes.
Yes, A and what, half of 16?
A1.
Exactly.
Apparently, this is the final few days in your current office.
You're moving across the road.
We have a limous and we have some projects underway, but yeah, this is actually, this is the original.
We're in actually the original office.
We're in the, we're in the whole thing started.
It's beautiful.
Yeah, great.
Thank you.
So I have to come out.
This is a, you know, I wanted to pick a spicy.
start. In October 22, I just made friends with Roon. And I wanted to give him something to
sort of be spicy about. And I said, it'll never not be funny that A16Z was constantly going,
the future is where the smart people choose to spend their time and then going deep into crypto
and not in AI. And that was in October 22, 22. And Roon says there was an internal meeting
in the A16C to reorient around Gen.A.I. Obviously, you have. But was there a meeting?
What was that? I mean, I don't look. I've been doing AI since the late 80s.
Yeah. So I don't know.
As far as I'm concerned, this stuff is all Johnny come lately.
Yeah, I mean, look, we've been doing AI our entire existence.
I mean, we've been doing AI machine learning deep, you know, deeply.
We've been doing this stuff way from the beginning, obviously.
AIA is just core to computer science.
I actually view them as like quite, quite continuous.
You know, Ben and I both have computer science degrees.
You know, we both, Ben and I actually both are rolled enough to remember the actual AI boom in the 1980s.
There was a big AI boom at the time.
And there was one of her names like expert systems.
and there of like LISP and LIS machines.
I coded it LISP.
I was coding a LISP in 1989 when that was the language of the AI future.
Yeah, so this is something that we're like completely,
you're completely comfortable with,
I've been doing the whole time and are very enthusiastic about.
Is there as strong, like this time is different?
Because my closest analog was 2016-17, Noseles and AI boom,
and it petered out very, very quickly.
It just in terms of investing.
Sort of, sort of.
Investment excitement.
Although that's really when the NVIDIA phenomenon really,
I would say it was in that period when it was very clear that at the time, the vocabulary was more machine learning,
but it was very clear at that time that machine learning was hitting some sort of takeoff point.
Yeah.
Well, and as you guys, you guys have talked about this at length on your thing.
But, you know, if you really track what happened, I think the real story is it was, it was the Alex Net basically breakthrough in like 2013.
That was the real knee in the curve.
And then it was obviously the transformer breakthrough in 17.
Yeah.
And then everything that followed.
But, but, you know, look, machine learning, you know, there were, you know, look, I mean, look, I've been working, you know, I've been working with,
one of my kind of projects working with Facebook since 2004 and on the board since 2007.
And, of course, they started using machine learning very early.
And, you know, I've used it basically, you know, for like 20 years for, you know, content, you know, feed optimization and advertising optimization.
And obviously many, you know, financial services, you know, many, many, many, many companies, many different sectors have been doing this.
And so it's like one of these things.
It's like, it's not a single thing.
Like it's like layers, right?
And the layers arrive at different paces.
But they kind of build up.
Yeah.
They kind of build up over time.
And then, yeah, and then look, in retrospect, it was 2017 was kind of the, you know,
the key point with the transformer.
And then as you guys know, there was this really weird, like, four-year period where it's like
the transformer existed.
And then it was just like, let's go.
Yeah.
Well, but between 2017 and 2021, I mean, that was the era of which, like, companies like Google
had internal chatbots, but they weren't letting anybody use them.
Yeah.
Right.
And then, you know, and then OpenAI developed chat GPD2 or GPT2.
And then they told everybody this is way too dangerous to deploy.
Right.
We can't possibly let normal people, normal people use this thing.
And then you guys, I'm sure remember AI dungeon.
So there was like a year where like the only way for a normal person to use GPT3 was in AI dungeon.
And so we would do this.
You'd go in there and you'd pretend to play Dungeons and Dragons.
In reality, you're just trying to talk to GPT.
And so there was this, you know, there was this long, you know, the big companies, you know, big companies are cautious.
And, you know, the big companies were cautious.
By the way, it took open AI.
You know, they talk about this.
It took open AI time to actually adjust, you know, kind of read,
direct their research path. I think so it was at Rosewood, right? The dinner that
founded Open AI was right there. Right. But that dinner would have taken place in
2018. The formation of Open AI as late as 2018? I'm sorry. No, I'm wrong.
It should be 20. They just celebrated a 10 year anniversary, so it is 2025. Yeah. So 2015.
Yeah, 2015. Yeah, 2015. But then Alec Radford did GPT1 in what, probably 17, 18.
17, 18. So it's, yeah, and then they didn't really, and then GPT3 was
what, 2020, 2020?
Because that became co-pilot immediately.
Even Open AI, which has been, you know, the leader of this thing in the last decade,
you know, even they had to adapt and lean into the new thing.
And so, yeah, I think it's just this process of basically sort of wave after wave,
layer after layer, you know, building on itself.
And then you kind of get these catalytic moments where the whole thing pops.
And obviously that's what's happening now.
Is it useful to think about, will there be any winter because there's always these patterns?
Like, is this endless summer?
It's something I constantly think about because.
Because do I get, do I just like, just get endlessly hyped and just trust that I'll only be early and never wrong?
Or will there be a winter?
So there's something about, say the following, there's something about AI that has led to this repeated pattern.
And you guys know this, but it's winter, summer winter, summer winter.
And it goes back 80 years.
80 years.
So the original neural network paper was 1943, right, which is amazing.
It was far back that long.
And then there was, if you guys have ever talked about this on your show, but there was this, there was a big, there was an AGI conference at Dartmouth University in 1955. 55.
And they got an NSF grant to, for all the AI experts at the time to spend the summer together.
And they figured if they had 10 weeks together, they could get AGI.
Of the other end.
And they got there, by the way, they got the grant.
They got the 10 weeks.
And then, you know, 1950.
You know, no AGI.
And like I said, I lived through the 80s version of this where there was a big boom in a crash.
And so there is this thing.
And there is something about AI that causes the people in the field, I would say, to become both.
both excessively utopian and excessively apocalyptic.
And it's probably on both sides of like the boom bus cycle.
You kind of see that play out.
Having said that,
I think what's actually happened is like just in,
you know,
we now know in retrospect,
like an enormous amount of technical progress
that built up over time.
And like, for example,
we now know the neural network is the correct architecture.
And I will tell you,
like there was a 60 year run where that was like a,
you know,
or even 70 years or that was controversial.
And we now know that that's the case.
And so we now,
you know,
everything we're building on today
just sort of derives from the original idea in 1944.
And so in retrospect,
back, we now know that like these guys were right, you know, they would get the timing wrong and
they thought, you know, capabilities would arrive faster or they were, it could be turned
into businesses sooner or whatever. But like they were fundamentally, the scientists who worked
on this over the course of decades were fundamentally correct about what they were doing.
And the payoff from all their work is happening now. And so the way I think about what's happening
is basically, I think about basically the period we're in right now is it's, I call it 80 year
overnight success, right? Which is like, it's an overnight success because it's like, bam,
you know, chat GPT hits and then in then 01 hits and then, you know,
know, open- claw hits. And like, you know, these are open, these are, these are like
radical overnight transformative successes, but they're drawing on an 80-year sort of
wellspring backlog, you know, of, of ideas and thinking. It's not just that it's all
brand new. It's that it's an unlock of all of these decades of like very serious hardcore
research and thinking. Look, there were AI researchers who spent their entire lives.
They got their PhD. They worked for, they've researched for 40 years. They retired. In a lot of
cases, they passed away and they never actually saw it at work. Yeah. So sad. It is, it is sad.
I think Jeff Hinton was like the last guy.
Yeah, yeah.
Well, there were the guys that I think it was an guy, Alan Newell.
I mean, there's tons of John McCarthy.
John McCarthy was like one of the inventors of the field.
He's one of the guys that organized the Dartmouth conference.
And, you know, he taught at Stanford for 40 years and passed, you know, passed away.
I don't know, whatever, 10 years ago or something.
Never actually got to see it happen.
But like, it is amazing in retrospect.
Like, these guys were incredibly smart and they worked really hard and they were correct.
So anyway, so then it's like, okay, you know, as I say history doesn't repeat, but it rhymes.
It's like, okay, does that mean that there's going to be another, like, you know, basically boom,
boom, bus cycle?
And I will tell you, like, look, in a sense, like, yes, everything goes through cycles and, you know, people get overly enthusiastic and overly depressed.
And there's a time there's a timelessness to that. Having said that, there's just no question.
So the foremost dangerous words in investing are this time is different.
Do you know the 12 most dangerous words of investing?
No.
The four most dangerous words in investing are this time is different.
The 12 most dangerous words.
And so, like, I tell you what's different.
Like, now it's working.
Like, there's just no, I mean, look, there's just no question.
And by the way, I'll just give you guys my take.
Like LLM's like from from basically the Chad GPT moment through to spring of 25, I think you could still,
I think well intention, well informed skeptics could still say, oh, this is just pattern completion.
And oh, these things don't really understand what they're doing.
And, you know, the hallucination rates are way too high.
And, you know, this is going to be great for creative writing and creating, you know, Shakespearean sonnets and, you know, as rap lyrics or whatever.
Like, it's going to be great at all that stuff.
But we're not going to be able to harness this to make this relevant.
in coding or in medicine or in law
and, you know, kind of feels that, you know,
kind of really, really matter.
And I think basically it was the reasoning breakthrough.
It was 01 and then R1 that basically answered that question
and basically said, oh, no, we're going to be able to actually turn this
into something that's going to work in the real world.
And then obviously the coding breakthrough over the,
basically of the coding breakthrough that kind of catalyzed over the holiday break
was kind of the third step in that.
But he was like, all right, if, you know,
if Linus Torvalds is saying that AI coding is not better than he is,
like, that's never happened before.
That's the benchmark.
That's never happened before.
Now we know that it's going to sweep through coding.
And then we know, you know, we know that if it's going to work in coding, it's going to work in everything else.
Right.
It's just that because that's like, that's like the hardest, in many ways, that's the hardest example.
And now everything else is going to be a derivative of that.
And then on top of that, we just got the agent breakthrough, you know, with OpenClaw, which is fantastic, which is amazing and incredibly powerful.
And then we just got the auto research, you know, the self improvement.
You know, we're now into the self-improvement breakthrough.
And so the way I think about it is we've had four fundamental breakthroughs and functionality, LLM's reasoning,
agents and then now RSI. And they're all actually working. And so I'm just, as you can, I'm jumping
out of my shoes. Like, this is it. Like, this is the culmination of 80 years worth of work. And this is
the time it's becoming real. I'm completely convinced. I think the anxiety that people feel is like,
during the transistor era, you had morsela and it's like, all right, we understand why these
things are getting better. We understand the physics of it. With AI, it's so jagged and like the jumps.
where like you said, it's like in three months, you have like this huge jump.
Like, and people are like, well, this can't keep happening, right?
But then it keeps happening.
It will keep happening.
And so like, how do you think about also timelines of like what's we're building?
I think we always have this question with guess, which is like, you know, should you spend
time building harness for a model versus like the next model just going to do it one shot in the
lead in space?
And how does that inform like how you think about the shape of the technology?
You know, you talk about how it's a new computing platform.
If you have a computing platform that like every six months, like,
drastically changes in what it looks like.
It's hard to build companies on top of it.
Yeah, so a couple things.
One is like, look, Moore's Law was what we now call a scaling law.
Like Moore's Law was a scaling law.
And for your younger viewers, Moore's Law was every chip.
Chips either get twice as powerful or twice as cheap every 18 months.
And that, and that, you know, that it's gotten more complicated in the last few years.
But like that, that was like the 50-year trajectory of the computer industry.
And then, by the way, and that's what took the mainframe computer from a $25 million
current dollar thing into, you know, the phone in your pocket being, you know, a million
times were powerful than that.
like that, you know, for 500 bucks.
And so that was a scaling law.
And then, and then key to any scaling law, including Moore's law and the AI scaling laws is,
you know, they're not really laws, right?
They're, they're, their predictions.
But when they work, they become self-fulfilling predictions because they set a benchmark.
And then the entire industry, right, all the smart people in the industry kind of
work to make sure that that actually happens.
And so they kind of motivate the breakthroughs that are required to keep that going.
And in chips, that was a 50-year run, right?
And it was amazing.
And it's still happening in some areas of chips.
I think the same thing is happening with the core scaling laws.
The core scaling laws in AI, you know, they're not really laws, but like they are basically
their predictions and then they're motivating catalysts for the research work that is required
to be.
And by the way, also the investment dollars are, you know, required to basically keep, you know,
keep the curves going.
And look, it's going to be complicated and it's going to be variable.
And, you know, there are going to be walls that are going to look like they're fast approaching
and then they're going to be, you know, engineers are going to get to work and they're
going to figure out a way to punch through the walls.
And obviously, that's, you know, that's been happening a lot.
And then look, there's going to be times when it looks like the walls have, you know, the laws have petered out, and then they're going to pick up again and surge.
And then it appears what's happening to the eye is there's not multiple, you know, multiple scaling laws.
There's multiple areas of improvement.
And I think, you know, I don't know how many more there are already yet to be discovered, but there are probably some more that we don't know about yet.
You know, like, for example, there's probably some scaling law around world models and robotics that we don't fully understand, you know, kind of acquisition of data at scale in the real world that we don't fully understand yet.
So that one will probably kick in at some point here.
There's a bunch of really smart people working on that.
And so, yeah, I think the expectation is that, you know, the scaling laws generally are going to continue.
Yeah, the pace of improvement will continue to move really fast.
To your question on, like, what to build.
So I'm a complete believer, the scaling laws are going to continue.
I'm a complete believer, the capabilities are going to keep getting amazing, you know, leaps and bounds.
The part where I kind of part ways a little bit with what I would describe as the AI purists, you know,
which I would characterize as like the people who are in many ways the smartest people in the field,
but also the people who spend their entire life like in a lab,
and I would say have very little experience in the outside world.
The nuance I would offer is the outside world of 8 billion people
and institutions and governments and companies and economic systems
and social systems is really complicated.
And doesn't, you know, 8 billion people making collective decisions on planet Earth
is not a simple process of like, just like, you see this happening.
It's like a bunch of the AI CEOs have this thing,
which is just like, well, there's just this.
They just all have this kind of thing when they talk in public where they're just like,
well,
there's these obvious set of things that society used to do.
And then they're like,
society's not doing any of those things.
Right.
And it's like,
how can society not,
you know,
whatever their theory is,
how can society not see X,
XYZ?
And the answer is,
well,
society is number one,
there's no single society.
It's like eight billion people.
And they like all have a voice and they all have a vote like at the end of the day of how they react
to change.
And then,
you know,
it's just,
human reality is just really complicated and messy.
And so the specific answer to your question is like,
as usual,
it depends.
It depends.
There's no question people are going to like,
there's no question there are going to be companies that's already happening.
There are companies that think that they're building value on top of the models,
then they're just going to get blest by the next model.
There's no question that's happening.
But I think there's no question also that just the process of adaptation of any technology
into the real messy world of humanity is just going to be messy and complicated.
It's not going to be simple and straightforward.
It's going to be messy and complicated.
And there are going to be a lot of companies and a lot of products
and, in fact, entire industries that are going to get built
to basically actually help all of this technology
actually reach real people.
The amount of capital going into these companies,
I mean, Dario talked about it on the Dork Cash podcast,
and Dork Cash was like,
why don't you just buy 10x more GPUs?
And he's like, because I'm going to go bankrupt
if the model doesn't exactly hit the performance level.
How do you think about that?
Also, as a risk on, you know,
you guys are investors.
I know how many I and thinking machines and world apps?
It seems like we're leveraging the scaling loss at a pretty high rate.
Like, how comfortable, I guess, do you feel with the,
downsized scenario. Like, and say like things Peter Al, you think you can kind of like
restructure these buildouts and, you know, capital investments. Yeah. So I should start by saying,
so I live through the dot com crash. And I can tell you stories for hours about the dot com crash.
And it was horrible. No, it was awful. It was, it was apocalyptic. By the way, a lot of the
dot com crash was actually at the time, it was actually a telecom crash. It was a bandwidth crash.
Like the thing that actually crashed that wiped out all the money with the telecom companies.
Global crossing. Global, global, global, yeah. I'm from Singapore. And I'm from Singapore. And
They laid so much cable over our oceans.
Actually, it was the scaling law in the dot-com era,
and it was literally the U.S. Commerce Department put out a report in 1996,
and they said internet traffic was doubling every quarter.
And actually in 1995 and 1996, internet traffic actually did double every quarter.
And so that became the scaling law.
So what all these telecom entrepreneurs did was they went out and they raised money
to build fiber anticipating that the demand for bandwidth was going to keep doubling every quarter.
Doubling every quarter, though, is like, you know, grains of chess and the chessboard.
Like at some point, the numbers become extremely large, right?
And it really, and really what happened was the internet, by the way,
continuously kept growing basically since inception.
It's, you know, it's continuously grown.
It's never shrunk.
And it's grown really fast compared to anything else, you know, in human history.
But it wasn't doubling every quarter as of 1998, 1998, 1999.
And so there was this gap in the expectation of what they thought was a scaling law versus reality.
And that's actually what caused the dot-com crash, which was they, they weigh over,
companies like Global Crossing way, overbuilt fiber, which is sort of the, by the way,
fiber, telecom equipment, you know, so all the networking gear, you know, and then, and then,
And then by the way, the actual physical data center.
So, like, that was the beginning of the, of the data center build and then the data center
overbuild.
And so you had that, but it was, it was literally, I think it was like two trillion dollars got wiped
out, right?
It was like, it was like a big, and by the way, the other, the other subtlety in it
was the internet companies themselves never really had any debt because tech companies
generally don't run on debt, but the telecom companies run on debt.
Physical infrastructure companies run on debt.
And so the company's like, well, we're crossing, not just raised a lot of equity.
They also raised a lot of debt.
So they're highly levered.
And so then you just do the thing.
It's just like, okay, you have a,
a highly levered thing where you're just overbuilding capacity.
Demand is growing, but not as fast as you hoped.
And then, boom, bankrupt, right?
And then it's like they say about the hotel industry, which is it's always the third
owner of a hotel that makes money.
It has to go bankrupt twice, right?
To wash out all of the over-optimistic exuberance before it gets to actually a stable
state and then it makes money.
So by the way, all of those data centers and all of those, all the fiber that they're in use,
it's all in use today, but 25 years later.
But it took, and actually the elapsed time was it took 15 years.
It took 15 years from 2000 to 2015 to actually fill up all that capacity.
The cautionary warning is the overbuild can happen.
And you know, you get into this thing where basically everybody,
everybody who basically has any sort of institutional capital is like,
wow, it's just I don't know how to invest in these crazy software things,
but for sure I can put build data centers and for sure I can buy GPUs
and I can deploy, you know, compute grids and all these things.
And so, you know, if you're a pessimist, you can look at this and you can say,
wow, this is like really set up to be able to basically replicate, you know,
what we went through in 2000.
Obviously, that would be bad.
The counter argument, which is the one I agree with,
which is the counterment on the other side is a couple of things.
One is the companies that are investing all the,
the companies that are investing in the money are like the bluest chip of companies.
And so back in the,
like Global Crossing was like an entrepreneur.
It was like a new venture.
But like the money that's being deployed now at scale is Microsoft and, you know,
and Amazon and Google and Facebook and Facebook and Vidaia and, you know,
these, and now, you know, by the way,
open Aina Anthropic,
which are now like, you know, really serious size.
you know, as companies with, you know, very serious revenue.
These are very large-scale companies with like lots, lots of cash,
lots of debt capacity that they've never used.
And so this is institutional in a way that that really wasn't at the time.
And then the other is, at least for now,
every dollar that's being put into anything that results in a running GPU
is being turned into revenue right away.
Like so, and you guys know this, like everybody starve for capacity,
everybody starve for compute capacity and then, you know,
all the associated things, memory and interconnect and everything else,
data center space.
And so every dollar right now that's being put in the ground is turning into revenue.
And in fact, I actually think there's an interesting thing happening, which is because everybody
start for capacity, the models that we actually have that we can use today are inferior versions
of what we would have, if not for the supply constraints.
Right.
Suppose a hypothetical universe in which GPUs were 10 times cheaper and 10 times more plentiful.
The models would be much better because you would just allocate a lot more money to training
and you'd just build better models and they would be better.
And so we're actually getting the sandbag version of the technology.
No, what?
Everything we use is quantized because the labs have to keep the full versions.
Right.
We're not even getting the good stuff.
But getting the good stuff is just, even if technical progress stops, once there's
a much bigger build of like GPU manufacturing capacity and memory, you know, all the things
that have to happen in the course of the next five or 10 years, once it happens, even the current
technology is going to get, going to get much better.
And then, as you know, like, there's just like a million ways to use this stuff.
Like there's just like a million use cases for this.
Like, you know, this isn't just sending packets across a thing, whatever.
and hoping people find something to do with it.
This is just like, oh, we apply intelligence in every domain of human activity.
And then it works, like, incredibly well.
Here's what I know.
Here's what I know.
In the next three or four years, it's like somewhere between three or four years out,
basically everything is selling out.
So, like, the entire supply chain is sold out or selling out.
And so there's no, like, we're just going to have, like, chronic supply shortage for, you know,
for years to come.
There's going to be a response from the market that's going to result in an enormous,
you know, it's happening now, an enormous flood of investment in a new fat capacity.
and everything else to be able to do that.
At some point, the supply chain constraints will unlock,
at least to some degree.
That will be another accelerant to industry growth when that happens
because the products will get better
and everything will get cheaper.
So I know that's going to happen.
I know that the deployments,
the actual use cases are really compelling.
And then, like I said, with reasoning and agents and so forth,
I know they're just going to get much, much better from here.
And so I know the capabilities are like really real and serious.
I also know that the technical progress is not going to stop.
It is accelerating.
the breakthroughs are tremendous.
I mean, even just month over a month, the breakthroughs are really dramatic.
And so, you know, I think if you were a cynic and there are cynics, you can look at 2000,
you can find echoes, but I can't even imagine betting that this is going to like somehow
disappoint in, you know, at least four years to come.
I think it would be essentially suicidal to make that bet.
It was that Michael Burry.
That's an interesting guy, huh?
We'll pick on a guy.
We'll pick on one guy.
Well, because he did.
He came out with it.
He doesn't mind.
He was the Nvidia short, right?
He came out of the Nvidia short.
And then you guys probably talked about this, which is the, it's a lot.
Analysis now that the current models are getting better, faster at such a rate that if you are running an
if you're running an Nvidia inference chip today, that's three years old, you're making more money
on it today than you did three years ago? Because the pace of improvement of the software is
faster than the depreciation cycle of the chip. And then my understanding is Google is running,
I don't know exactly what. These are rumors that I've heard, or maybe it's public, but I think
Google's running very old TPUs, very profit. And very profitably. And so it actually turns out,
as far as I can tell, it's actually the opposite of the brewery thesis.
this is actually, he was actually 180 degrees wrong.
It's actually the old Nvidia chips are getting more valuable,
which is something that's like literally never happened before.
Like, it's never been the case that you have an older model chip
that becomes more valuable, not less valuable.
And again, that's an expression of that just a ferocious pace of software progress,
ferocious pace of capability payoff that you're getting on the other side of this.
And so I just, the idea of betting against that, like, yeah, yeah.
It's like an invitation to get your face ripped up.
One of my early hits was like modeling the lifespan of the H-100 and H-200s and going like, you know, usually they advise like four to seven years and it was, you know, maybe you sort of realistically care cut it down to two to three.
But actually it's going up and not down.
And that's, I mean, I think that's the dream.
We are finding utilization.
And I think utilization solves all problems.
Like you can you can find use cases for even like the poor, like even memory we're having a shortage, right?
And even like the shittier versions of memory that we do have, we are finding use cases.
for it. So it's great.
How important is open source AI and kind of like edge inference in a world in which you have
three years of supply crunch?
Like do you think in the like, you know, if you fast forward like five years, like how do you
think about inference in the data center versus at the edge?
Well, so just to start, yeah.
So I think I think open source is very important for a bunch of reasons.
I think edge inference is very important for a bunch of reasons.
I think just practically speaking, if we're just going to have fundamental construct supply
crunches for the next.
I mean, you guys not, if you just project forward demand over the next three years relative
to supply. One of the dismaying predictions you can do is what's going to happen to the cost
of inference in the core over the next three years. And like it may rise dramatically. Right.
So, so what is, you know, like the big model competition is subsidizing heavily right now.
Right. And so what's the, what will be the average person's, you know, per day per month
token cost, you know, three years from now to do all the things that they want to do? And I don't
know, it's going to be, I mean, I have, you guys probably have friends. I have friends today who are paying
$1,000 a day for open claw, for cloud tokens to run open claw. Right. And so, okay, $30,000.
month, right? And by the way, those friends have like a thousand more ideas of the things that
they want their claw to do, right? And so you can imagine there's like latent demand of up to,
I don't know, five or $10,000 a day of tokens for a fully deployed, you know, personal agent.
And obviously, consumers can't pay that, right? And so, but it gives you a sense of the future
scope of demand. And so even if there's a 10x improvement in price performance, that still, you know,
goes to $100 a day, which is still way beyond what people can pay. So there's just going to be like
ferocious to, by the way, the agent thing, the other interesting thing is I think the agent thing,
up until now, a lot of the constraints have GPU constraints. I think the agent thing now
also translates into CPU constraints. CPU and memory, right? And so like the entire chip
ecosystem is just going to get with a network constraints. That will be the killer. It's all
bottlenecked potentially for years. And so I think that Brad, and I think it's actually possible,
I mean, generally inference costs are going to keep coming down. But I think, let's put it this
way, the rate of decline, I think may level out here for a bit because of these supply constraints.
And then at some point, maybe the lab stopped subsidizing so much. And that again will be
an issue. And so there's just going to be so much more demand for inference than can be satisfied,
you know, kind of with the centralized model. And then, and then you know, you guys know,
you guys know, just the dramatic, I mean, just the dramatic innovations that have happened in the
Apple Silicon to be able to do inferences. It's quite amazing. A level of effort being put, like the
open source guys are putting an incredible effort into getting, you know, this recurring pattern
where the big model will never run on a PC and then six months later, it runs in a PC. Right. It's like
amazing. And there's very smart people working on that. So there's all that. And then look, there's also,
you know, there's also like other, there's other motivators. There's other motivators, which is just like, okay, how much trust are the big centralized model providers? You know, how much trust are they building in the market versus, you know, how much are, you know, at least for in certain cases with some people for certain use cases, people being like, well, I'm not willing to just like turn everything over. So there's all the trust issues. By the way, there's also just like straight up price optimization. There's many uses of AI where you don't need Einstein in the cloud. You just need like a smart local model. There's also performance issues where you want to, you know, you want, you know, you want, you know, you
you're going to want your do
doornaop to have an AI model in it,
you know,
to be able to, you know,
do,
you know,
to be able to do access control.
Obviously,
like everything with a chip is going to have an AI model in it.
A lot of those are going to be local.
And so, yeah,
no, like,
I think,
I think you're going to have,
and then you're going to,
by the way,
also wearable devices,
you know,
you don't want to do a complete round trip.
You want,
you know, whatever your smart devices are.
You want it to be like super low latency.
The question,
do we care who makes it?
One of the biggest news this week was the collapse of AI2,
the Allen Institute,
one of the actual American open source model labs.
And I'm not that optimistic on American open source.
You guys invested in Mistral, and Mistral is doing extremely well outside of China.
That's about it.
Yeah, we'll see.
We'll see.
Number one, I do think we care.
I do think we care who makes it.
I would say this.
The previous presidential administration wanted to kill it in the U.S.
They wanted to drown in the bathtub.
And so they wanted to kill it.
So at least we have a government now that actually wants it to happen.
And you're on the council?
And the new P-Cast, yeah.
So for whatever other political issues people have, which are many, you know, this administration has, I think, a very enlightened view.
And in particular, an enlightened view on AI, and in particular on open-source AI.
And so they're very supportive.
My read is the Chinese have a various Chinese companies have a very specific reason to do open source,
which is they don't fundamentally, they don't think they can sell commercial AI outside of China right now,
or at least specifically not in the U.S.
for a combination of reasons.
And so they kind of view, I think, open-source AI is a bit of a loss leader against basically,
domestic, you know, paid, paid services, and then kind of, you know, kind of ancillary products.
You know, they're very excited about it. By the way, I think it's great. I think it's great that
they're doing it. You know, I think DeepSeek was like a gift to the world. I think the great thing
open source, open source, the impact of open source is felt two ways. One is you get the software
for free. But the other is you get to learn how it works. Right. And so like the paper.
The paper, the paper and the code. And so like, for example, I thought this was amazing. So
Open AI comes out with 01. And it's an amazing technical breakthrough. And it's a
It's just like absolutely fantastic.
But of course, they don't explain how it works in detail.
And then, of course, they hide the reasoning traces, right?
And then everybody's like, okay, this is great.
But like, who's going to be able to replicate this?
Are other people going to be able to do this?
You know, is there a secret sauce in there.
And then R1 comes out and it's just like, there's the code and there's the paper.
And now the whole world knows how to do it.
And then, you know, three months later, every other AI model is adding reasoning.
And so you get this kind of double, like even if the Chinese models themselves are not the models that use,
the education that's taken place to the rest of the world, the information diffusion, you know, is incredibly
powerful. So that happens. And then I don't know, we'll see. And, you know, there are a bunch of
American, you know, open source, you know, AI model companies. I mean, look, there's going to be
tremendous, you know, there's going to be tremendous, there's tremendous competition
among the primary model companies, you know, there's, depending on how you count, there's like
four or five, you know, big co model companies now that are, you know, kind of neck and neck
in different ways, you know, and, you know, and then obviously, both both, both, you know,
huge, you know, huge attempts to, you know, to kind of leapfrog underway. And then you've got,
you know, a whole fleet of startups, new companies, including a whole bunch that we're back
in that are, you know, trying to come out with different approaches. And then you've got whatever
it is, I don't know, how many, how many, like main line foundation model companies are there
in China at this point? It's probably six. It's five tigers, it's what they call it.
Quinn is questionable because there's change in leadership. Right. Yeah. But that does that include,
that includes like Moonshot? Yes. Kimmy, Deepseek, Z-A-I, Quinn,
01 is in there.
Right.
And then bite dance.
Bight dance would be like the next tier.
They weren't as prominent.
They weren't have a leading model yet.
Yeah, but at least, you know, C dance is very inspiring.
And presumably they have more stuff coming.
And 10th and probably has more stuff coming and so forth.
And so, so like, look, here would be a thing you can anticipate, which is there are not,
these markets, they're not going to be, between the U.S. and China right now,
there's like a dozen primary foundation model companies that are like at scale at some level
of like critical mass.
It's not going to be a dozen in three years, right?
Like, just because these industries don't bear a dozen.
And it's going to be three or four big winners or maybe one or two big winners.
And so there's going to be like a whole bunch of those guys that are going to have to
figure out alternate strategies.
And I think like open source is one of those strategies.
And so I think you could see like a whole.
I think the questions like who's going to do open source,
I think that could change really fast.
I think that's a very dynamic thing.
I think it's very hard to predict what happens.
And I think it's very important.
Invite is doing a lot.
Well, I was going to say, well, exactly.
And then you got invidia.
And then just to get an industrial for, there's an old thing in business strategy,
which is called commoditize the compliment.
And so if your Jensen is just kind of obvious, of course you want to commoditize the software.
And to his enormous credit, he's putting enormous resources behind that.
And so maybe it's literally in video.
And I think that would be great.
Yeah.
Narrative violation to European projects in the 80s.
Damn.
I'm hosting my Europe conference soon and I got both of them.
They got us.
They got us, Mark.
Wait a minute.
Where was Peter?
So where was Steinberger when he did it was in Austria?
Yeah, yeah.
He was in Vienna.
Oh, he was in Vienna.
And then where is he now?
he's moving to SF.
Okay, okay.
All right, okay, there we go.
And then, yeah, the Pi guy, all right, the Pi guys are European.
Yeah, they're in Australia.
Mario is also there.
Right.
And are they, yeah, they haven't announced yet any sort of changed or have they?
No, they're deval company there.
Okay, good, okay, good, yeah, yeah.
Anyway, I think pie and OpenClaw are very important software things.
And I just wanted you to just go off on what do you think.
Yeah.
So I think in the combination of the two of them, I think is one of the 10 most important software.
OpenClaw.
all the attention, but...
Right. Talk about Pi.
Pie. Pie is kind of the architectural breakthrough.
For those of us who are older, there was this whole thing that was very important in the
world of software, basically, from like 1970 to, I don't know, it still is very important,
but like from 1970 through to like basically the creation of Linux, which is basically this,
this thing used to call like the Unix mindset.
Like so, so, because there were all these different, you know, theories, there are all
these different operating systems and mainframes and then, you know, all these windows
and Mac and all these things.
And then there was this, but kind of behind it all was this idea of the Unix mindset.
And the Unix mindset was this thing where basically you don't have these like,
like in the old days, like the operating system that like made the computer industry really work like in the 1960s was this thing called OS 360,
which was this big operating system that IBM developed that was supposed to basically run everything.
And it was this like giant monolithic architecture in the sky.
It was like a, you know, it was like a giant castle of software.
And by the way, it worked really well and they were very successful with it.
But like it was this huge castle in the sky.
But it was this thing.
It was almost unapproachable, which is like you had to be kind of inside IBM or very close to IBM.
And you had to really understand every aspect how the system works.
And then the Unix guys originally out of AT&T and then out of Berkeley, you know, came out and they said, no, let's have a completely different architecture.
And the way architecture is going to have, we're going to have a prompt and a shell.
And then all the functionality is going to be in the form of these discrete modules.
And then you're going to be able to chain the modules together.
And so like it's almost like the operating system itself is going to be a programming language.
And then that led to the sort of the sort of, you know, basically chaining the other Unix tools.
and then that led to the emergence of these scripting languages like Pearl,
where you could basically kind of very easily do this.
And then the shells got more sophisticated.
And then looked, like, you know, that, number one, that worked.
And that was the world I grew up in.
Like, I was a Unix guy, you know, sort of from, call it, 1988, you know,
kind of all the way through my work.
And it worked really well.
It's in the background, you know, normal people don't need to,
didn't need to necessarily know about it.
But like, if you were doing like system architecture, application development,
you knew all about it.
And then, you know, it's been in the background ever since.
And, you know, look, your Mac still has a Unix shell, you know, kind of in there,
and your iPhone still has a Unix shell kind of buried in there somewhere.
So they're kind of in there.
And then, you know, the Windows shell is kind of a, you know, sort of a weird derivative of that.
But, you know, but look, the Internet runs on Unix and then smartphones.
Actually, both iOS and Android are Unix derivatives.
And so, you know, kind of Unix did end up winning.
But anyway, and then we just started taking that for granted.
And then so basically the way I think about what happened with Pi and then with OpenClaw is basically
what those guys figured out is, I always say the great breakthroughs are obvious in retrospect,
right, which is the best kind.
The best kind.
They weren't obvious at the time or somebody else would have done them already.
And so there is a real conceptual leap.
But then you look at it sort of the backwards looking and you're just like, oh, of course.
To me, those are always the best breakthrough.
So actually, language models themselves are like that.
It's just like, oh, next token completion.
Oh, of course.
Yeah.
What other objective mattered?
Yeah, exactly.
But like it was saying it wasn't obvious until somebody actually did it, right?
And so the conceptual breakthrough is real and deep and powerful and very important.
And so the way I think about pie and open claw is it's basically marrying the language model mindset to the Unix,
basically shell prompt mindset.
And so it's basically this idea that what, what is an agent?
Right.
And as you know, many smart people have been trying to figure out what an agent is for decades.
And they've had many architectures to build agents and the whole thing.
And it turns out what is an agent is an agent is the following.
So it's a language model.
And then above that, it's a bash shell.
So it's a Unix shell.
And then the agent has access to the shell, hopefully in a sandbox, maybe in a sandbox.
So it's the model.
It's the shell.
And then it's a file system.
And then the state is stored in files.
And then, you know, there's the markdown format for the, you know, for the files themselves.
And then there's basically what in Unix is called a cron job.
There's a loop.
And then there's a heartbeat.
And the thing basically wakes up, wakes up.
So it's basically LLM plus shell plus file system plus markdown plus cron.
And it turns out that's an agent.
And every part of that other than the model is something that we already completely know and understand.
And in fact, it turns out the like the latent power of the Unix shell is like extraordinary.
because basically like all, like there's just like, there's just enormous latent power in the shell.
There's enormous numbers of Unix commands.
There's enormous number of command line interfaces into all kinds of things already in the, you know, your entire,
I mean, your entire, just to start with your computer runs on a shell.
If you're writing a Mac or a phone, your computer's running on a shell already.
And so like the full power of your computer is available at the command line level.
And then it turns out it's really easy to expose other functions as a command line interface.
And so like this whole idea where we need like MCP and these like fancy protocols, whatever,
it's like, no, we don't.
we just need like a command line thing.
So that's the architecture.
And then it turns out what is your agent?
Your agent is a bunch of files stored in a file system.
And then there's the thing that just like completely blew my mind when I write my head
around it as a result of this, which is like, okay, this means your agent is now actually
independent of the model that is running on because you can actually swap out a different
LLM underneath your agent.
And your agent will change personality somewhat because the model is different, but all of
the state stored in the files will be retained.
Different instruction sets, but you just compile that.
Right, exactly.
And it's all right.
It's like swapping out of ship and recompiling.
But it's still your agent with.
all of its memories and with all of its capabilities.
And then, by the way, you can also swap out the shell.
So you can move it to a different execution environment that is also a bas-shell.
By the way, you can also switch out the file system, right?
And you can, and you can swap out the heartbeat, the Cron framework, the loop, the agent
framework itself.
And so your agent basically is, basically at the end of the day, it's just its files.
And then there is a course, call.
Yeah, it's basically, it's just the files.
And then by the way, as a consequence of that, the agent, and then the agent itself,
it turns out a couple important things.
So one is it can migrate itself, right?
And so you can instruct your agent, migrate yourself to a different runtime environment,
migrate yourself to a different file system, migrate yourself to a different,
you know, like we swap out the language model.
Your agent will do all that stuff for you.
And then there's the final thing, which is just amazing,
which is the agent is actually has full introspection.
And actually it actually knows about its own files and it can rewrite its own files, right?
Which, by the way, is basically no widely deployed software system in history
where the thing that you're using actually has full introspective knowledge of how it
itself works and is able to modify itself like that.
That, I mean, there have been toy systems that have had that, but there, there's never been a widely to play system that has a capability.
And then that leads you to the capability that just like completely blew my mind when I wrap my head around it, which is you can tell the agent to add new functions and features to itself.
And it can do that.
Right.
Extend yourself.
Like, extend yourself.
Give yourself a new capability.
Right.
And so literally, it's just like you're running to somebody at a party and they're like, oh, I have my open claw, do whatever.
Connect to my eat sleep bed and it gives me better advice and sleep.
And you go home at night and you tell your claw, or if they're at the party, by the way, you tell your claw, oh, add this capability.
to yourself and your claw will say, oh, okay, no problem.
And it'll go out on the internet and it'll figure out whatever it needs.
And then it'll go out to cloud code or whatever.
It'll write whatever it needs.
And the next thing you know, it has this new capability.
And so you don't even have to, like, you can have it upgrade itself without even having to,
without having to do anything other than tell it that you wanted to do that.
And so anyway, so the combination of all this is just, I mean, this is just like a massive,
incredible.
I mean, it's just incredible.
Like, if I were, if I were 18, like, this is what I would be spending all of my time on.
This is like such an incredible conceptual breakthrough.
And again, people are going to look at it.
They already get this response.
People are going to look at it.
They're going to say, oh, well, where's the breakthrough?
Because all of these components were already known before.
But this is the key.
The key to the breakthrough was by using all these components that were known before,
you get all of the underlying capability that's buried in there.
And so, for example, computer use all of a sudden just kind of false trivial.
Of course, it's going to be able to use your computer.
It has full access to the shell.
Right.
And then you give it access to a browser, and then you've got the computer in the browser,
and off and away it goes.
And then you've got all the abilities of the browser also.
And so the capability unlock here is profound.
my friends who are deepest into this
are having their claw do like
literally like a thousand things in their lives
they have new ideas every day
they're just like constantly throwing your challenges
with the thing and by the way
it's early and you know these are
these are prototypes and there's you know
as you guys know there's security issues
and so you know there's a bunch of stuff to be ironed out
but the unlock of capability
is just incredible
and I have absolutely no doubt that
everybody in the world is going to have at least
you know an agent like this if not an entire family of agents
and we're going to be living in a world where
I think it's almost inevitable now that this is the way people are going to use computers.
I was going to say for someone who is deeply familiar with social networks,
the next step is your claw talking to my claw, posting on claw Facebook,
posting their jobs on claw LinkedIn and posting their tweets on claw xAI or whatever.
I do think that that is how, you know, we get into some danger there in terms of like alignment
and whether or not we want these things to run.
You guys know a rentahuman.com?
Yeah, it's Fiverr.
It's task of it.
Sure, of course.
Mechanical Turk.
Yeah, but flipped.
Right for agent hiring the people.
Which, of course, is going to happen.
That's obviously going to happen.
I'm curious if you have any thoughts on the engineering side.
So when you build the browser, the internet, you know, just a bunch of mostly plain text
file plus some images.
And today, every website and app is like so complex.
And like somehow, you know, the browser kept evolving to fit that in.
Are there any design choices that were made like early in the browser?
and kind of like the internet and the protocols,
that you're seeing agents similar today.
It's like, hey, this thing is just not going to work for like this type of new compute.
And we should just rip it out right now.
There were a whole bunch, but I'll give you a couple.
So one is, and we didn't, you know, to be clear, like this, this was not, you know,
this was totally different.
We didn't have the capabilities we have today, but we didn't have the language models
underneath this.
But we did have this idea of that human readability actually mattered a great deal.
And so, and specifically in those days, it was not so much English language,
but it was, there was a design decision to be made.
between binary protocols and text protocols.
And basically every, every, every basically old school systems architect that had grown up
between like the 1960s and the 1990s basically said, you know, the internet, what do you know
about the internet?
It's star for bandwidth.
You just, you have these very narrow straws.
You know, look, people, when we did the work on mosaic, like people who had the internet at home
had a 14-kilobit modem, right?
So you're trying to like hyper-optimize every bit of data that travels over the network.
And so obviously, if you're going to design a protocol like HTTP, you're going to want it
to be a binary, you know, highly compressed binary protocol for maximum pitch.
and you're going to have it be like a single connection that persists.
And the last thing you're going to want to do is like bring up and tear down new connections.
And definitely you're not going to want a text protocol.
And so, for us, we said, no, we actually want to go completely the other direction.
It's obviously we only want text protocols.
By the way, same thing in HTML itself.
We want HTML to be relatively verbose.
You know, we want the tags to actually be like human readable.
The most inefficient things possible.
Yeah, we want to do the inefficient things.
You're the original token maxer.
Yeah, exactly.
Yeah, yeah.
Yeah, basically it's just like, yeah.
Well, yeah, well, actually, this was.
This was actually the conscious thing, which basically says just, like, assume a future of infinite bandwidth built for that.
And then basically what it was, is it was a bet that it was a bet that if the system was, if the latent capabilities of the system were powerful enough and that was obvious enough to people that would create the demand for the bandwidth that would cause the supply of bandwidth to get built that would actually make the whole thing work.
And then specifically what we wanted was we wanted everything to be human readable because at the engineering level, we wanted people to be able to read the protocol coming over the wire and be able to understand it with their bare eyes without having to like disassemble it or whatever, right?
have it converted out of binary.
All the, you know, HTTP and everything else were it was always text protocols.
And the same thing with HTML.
And in many ways, some people say that the key breakthrough in the browser was the view source option,
which is every webpage you go to, you could view source, which means you could see how it worked,
which means you could teach yourself how to build, right, new, to build new webpages.
There was that.
So human readability, and again, human readability in those days still met technical, you know,
specs, you know, now it means English language.
But there's an incredible latent power in giving everybody who uses the system,
option to be able to drop down and actually understand I see how it's working.
And that worked really well for the web, and I think it's working really well for AI.
That was one.
What was the other?
A big part of the idea of web servers was to actually surface the underlying latent capability
of the operating system and to be able to surface also the underlying latent capability of the database.
Because basically, what was a web server?
What is a web server fundamentally architecturally?
It's the operating system.
So it's the operating system's ability to, you know, it's running on top of an OS.
So it's the OS's ability to manage the file system and do everything else that you want to do,
process everything.
And then, of course, a lot of websites are financed databases.
And so you wanted to unleash the underlying latent power of whether it was an Oracle database
or some other, you know, some other Postgres or whatever it was.
And so a lot of the function of the web server was to just bridge from that internet connection
coming in to be able to unlock the underlying power of the OS in the database.
And again, people looked at it at the time and they were like, well, is this really, does this really matter?
Like, is this important because we've had databases forever and we've always had, you know,
user interfaces for databases and this is just another user interface for a database.
It's like, okay, yeah, fair enough.
But on the other side of that,
this is now a much better interface to databases
and one that 8 billion people are going to use
and is going to be far easier to use
and far more flexible.
And you're not just going to have old databases.
Now you have a system where people can actually understand
why they want to build a million times more database apps
than they have in the past.
And then the number of databases in the world exploded.
And so again, this goes to this thing of like building in layers.
Some of the smartest people in industry
look at any new challenge and they're like, okay,
I need to build a new kind of application.
So the first thing I need to do is build a new programming language.
right and then the next thing I need to do is build a new operating system right and the next thing I need to do is I need to build a new chip right and they kind of want to reinvent everything and I've I've always had maybe it's just I don't know pragmatic mentality or something or maybe in engineering over science mentality but it's more like no you have just like all of this latent power in the existing systems and you don't want to be held back by their constraints but what you want to do is you want to kind of liberate that power and open it up yeah so I think I think and I think the web did that for those reasons and I think it's the same thing now this happening it's a good perspective from the web the programming language just is another good thing
We have Brett Taylor on the podcast and we were talking about rust.
And, you know, rust is memory safe by the fault.
And so why are we teaching the model to not write memory unsafe?
Because it just use rusts and then you get it for free.
How much do you think there's like time to be spent like recreating some of these things instead of taking them from granite?
I'll be like, oh, okay, Python is kind of slow.
Python typescript.
You know, it's like, yeah.
As imperfect as they are, they are the lingua franca.
I mean, I think this is going to change a lot because I don't think the models care what language they program in.
And I think they're going to be good at programming every language.
And I think they're going to be good at transatlage.
translating from any language to any other language.
Like, okay, so this gets into the coding side of things.
I think we're going through a really fundamental change.
And I look, I grew up, you know, I grew up handcode.
You know, I grew pancoding.
Everything I did was actually, everything I did actually was written in C.
I wasn't.
Back in the days.
I wasn't even using C++.
So I, or like Java or any of this stuff, right?
And so everything, everything I ever did, I was like managing my own memory at the level of C.
And then I, you know, I'm still from the generation that, you know, I knew assembly
language and, you know, so I could drop down and do things.
right on the chip. And so we've just, all of us, we've always lived in a world in which software
is like this precious thing that like you have to think about very carefully and it's like really
hard to generate good software and there's only a small number of people who can do it. And like,
you have to be very like jealous in terms of thinking about like how do you allocate, like,
what are your engineers working on and how many good engineers do you actually have and how much
software can they write and how can how much software can human beings, you know, kind of
maintain. And I think like all those assumptions are being shot right out the window right now.
Like I think they're, I think those days are just over. And I think the new world is like actually
high quality software is just like infinitely available.
And if you need new software to do XYZ, like you're just going to wave your hand and you're
going to get it.
And then if it's, if you don't like the language is written and you just tell the thing, all right,
I want the right now I want the rest version.
Or, you know, secure, you know, security, by the way, we're about to go through computer
security is about to go through the most dramatic change ever, which is number one, like every
single latent security bug is about to be exposed.
So we're going to have like the, we're set up here for like the computer security
apocalypse for a while.
But on the other side of it, now we have coding agents that can go in and actually fix all
the security bucks. And so how are you going to secure a software in the future? You're going to tell
the bot to secure it and it's going to go through and fix it all. And so this thing that was
this incredibly scarce resource of high quality software is just going to become a completely
fungible thing that you're just going to have as much as you want. And that has like, you know,
that has like tons and tons of consequences. In some sense, the answer to the question that
you posed, I think it's just somewhat, I don't know, simple or something or straightforward, which is just
if you want all your software and rest, you just tell the bot, you want all your suffer and rest.
like things that used to be like hard or even like seem like an insurmountable mountain to get to get through all of a sudden I think become very easy.
I think Brett had a theory that there would be a more optimal language for LMs.
And so the contention is there isn't.
Like just don't bother.
Just whatever humans already use LMs are perfectly capable porting.
I think we're pretty close to being.
I don't know if this works today.
I think we're pretty close to being able to ask the AI what would its optimal language be and let it design it.
It's true.
Okay.
question. Are you even going to have programming languages in the future?
Or are the A is just going to be emitting binaries? Let's assume for a moment that humans aren't
coding anymore. Let's assume it's all bots. What levels of intermediate abstraction to the
bots even need? Or are they just coding binary directly? Did you see there's actually
an experience? Somebody just did this thing where they have a language model now that actually
emits model weights for a new language model. Right. And so will the bots be...
Just predict the weights? Yeah. Will the bots literally be emitting not just coding binaries,
but will they actually be admitting weights for new models?
Directly, directly.
And conceptually, there's no reason why they can't do both of those things.
Architecturally, both of those things seem completely possible.
Very inefficient.
You're basically very inefficient.
Simulation of a simulation and a simulation inside of weights.
Yeah, very inefficient.
But like, look, LMs are already like incredibly inefficient.
I'm a favorite thing.
Ask Claude add 2 plus 2 equals 4, right?
It's just like, you know, it's like, you know, it's like whatever,
billions and billions of times more inefficient than using.
your pocket calculator.
But yet, the payoff is so great of the general capability.
So anyway, like, I kind of think in 10 years, like, I'm not sure, yeah, like, I'm not
sure there will even be a salient concept of a programming language in the way that we
understand today.
And in fact, what we may be doing more and more is a form of interpretability, which is we're
trying to understand why the bots have decided to structure code in the way that they
have.
If you play it through, you don't need browsers then.
That's the depth of the browser.
Well, so I would take it a step further, which is you may not need to use your interfaces.
So who is going to use software in the future?
Other bots?
Yeah, the bots.
Yeah.
You still need to, I don't know, pipe information in and out.
Really?
Well, what are you going to do then?
Are you sure?
You're just going to log off and touch grass?
Whatever you want, exactly.
Isn't that better?
I want software to do stuff for me.
But isn't that better?
I mean, you know, I don't look, like, you know, you know, all the arguments here, you know,
it was not that long ago that 99% of humanity was behind a plow.
Right? And what are people going to do if they're not plowing fields all day to grow food?
And it just turns out there's like much better ways for people to spend time than plowing fields.
Yeah. Do it's growing.
Yeah, exactly.
Exactly.
You know, talking to their friends.
And look, I'm not an absolutist and I'm not a utopian.
And to be clear, like I have an 11-year-old and he's learning how to code.
And like, I think it's still a really good idea to learn how to code and so forth.
But I just, if you project forward, you just have to think forward to a world in which it's just like, okay,
I'm just going to tell the thing what I need and it's going to do it.
And then it's going to do it in whatever way is most optimal for it to do it.
Unless I tell it to do it non-optimely.
Like, if I tell it to do it in Java or in Rust or whatever, it'll do it, I'm sure.
But, like, if I'm just going to tell it to do it, it's going to do it in whatever way is, like, the optimal way to do it.
And then if I need to understand how it works, I'm going to ask it to explain to me how it works.
Right.
And so it's going to be doing its own interpret.
It's going to be the engine of interpretability to explain itself.
And I just am not convinced that that that, I'm not convinced that in that world you have these historical, the goals of the abstractions will be whatever the boss need out with you.
Right. Yeah.
Yeah.
Well, I'm curious, like, if that's true, then.
shouldn't the models, providers, be building some internal language representation that they can do extreme kind of like RL and reward modeling around?
Because it's like today they're kind of like tied to like TabScript and Python because the users need to write in that language versus they can have their own thing internally.
And like they don't need to teach it to anybody.
They just need to teach their model.
And I think that's how you get maybe the version between the models.
Like going back to like the pie open cloud thing.
It's like, oh, I built all the software using the open AI model.
and I'll switch to the enthrobic model,
but the entropic model doesn't understand the thing.
So it feels like there still needs to be some obstruction,
but maybe not.
Maybe that's the lock-in that the model providers want to have.
I'm not even sure that's lock-in, though,
because why can't the second model just learn what the first model has done?
Exactly.
Okay, giving an example.
As you know, models can now reverse-engineer software by the right?
Isn't it the whole thing now where people are reverse engineering,
like, Nintendo game binaries?
Yeah.
So you have, like, I've seen a bunch of reports like this
where somebody has like a favorite game for the 1980s.
And the source code is like long dead, but they have like a binary birded into a chip or something.
And now they reverse engineer negative version of their Mac.
Right.
And so if you reverse it, this is why I kind of say, if you're reversing like x86 binaries,
then why can't you reverse engineer?
Whatever they're great.
Yeah.
And because we're all on a Unix-based system, it has to be reversible because it needs to run on the target.
Yeah.
Yeah, yeah, yeah, yeah, yeah, basically.
And so I just, I just think it's this thing where it's just like, and by the way,
and everything we're describing is something that human beings in theory could have done before,
but just with, right, yeah, but with enormous, where,
But it was just always like cost and labor prohibitive.
Reverse engineer.
I learned how to reverse engineer.
Human beings can reverse engineer binaries.
It's just for any complex binary, I need like a thousand years to do it.
But now with the model, you don't.
And so all of a sudden you get these things.
Or another way to think about it is so much of human built system sort of compensate for the human limitations.
Right.
And if you don't have the human limitations anymore, then all of a sudden you have.
And it's not that you won't have abstractions, but you'll have a different kind of abstraction.
Yeah.
I have two topics to bring us to close.
and you could pick whichever ones.
Just talking about protocols.
Was it you or someone else?
I forget my internet history who said that the biggest mistake that we didn't figure out in the early days was payments.
Yes.
Was that you?
Yes.
It was a 402.
402 payment required.
We have a chance now.
I don't think we're going to figure it out.
I don't know.
What's your take?
Oh, I think we will.
Yeah.
No, now I think it's going to happen for sure.
Yeah.
And there's two reasons that's going to have internet native money now in the form of
stable coins.
Stable coins and crypto.
And I think this is the grand unification basically of AI crypto is what's about to happen now.
I think AI is the crypto killer app, I think, is where this is really going to come out.
And then the other is just, I mean, it's just, I think it's now obvious.
It's like obviously AI agents are going to need money.
And it's already happening, right?
If you've got a claw and you want it to buy things for you, you have to give it money in some form.
I would say the adoption is probably like 0.1% if that, but yeah.
Oh, today.
Yeah, yeah, yeah.
But think forward.
Like, where is it going?
Forward thinking.
The ultimate principle of everything and everything that I think we do is the William Gibson quote,
which is the future is already here.
It just isn't distributed.
isn't distributed yet.
My friends who are the most aggressive users of OpenClaw
just have given their Clause bank accounts,
and not only they've done it,
it's obvious that they needed to do it
because it's obvious that they needed to be able to spend money on their back.
It's just completely obvious.
And so, and again, like,
so the number of people who have done that today to your point
is like, I don't know, probably 5,000 or something.
But that's how these things start.
Actually, I mean, since you keep mentioning it.
And by the way, OpenClaught, by the way,
if you don't give it a bank account,
it's just going to break into your court.
It's going to be breaking up.
High Agency.
It's going to break into your bank account anyway and take your money.
So you might as well do it.
You might as well do it.
By the way, I really love, I got to tell you, I really love the phenomenon.
I love the YOLO.
I'm not doing it myself, to be clear, but I love the people that are just like,
yeah, what is it?
Skip, yeah.
Dangerously.
Which, by the way, it's a Facebook thing.
Okay.
Because in Facebook, they have this culture to name the thing dangerous so that you are aware
when you enable the flag that you are opting into a dangerous thing.
Okay, good.
They brought it into Open AI.
And of course, that makes it.
enticing. Sam runs Codex with skip permissions on his laptop. Yes, 100%. And so I think the way to
actually see the future is to find the people who are doing that. There's a madness, you know,
they're, you know, log everything, you know, just watch it. Watch the logs. But like, let's actually
find out what the thing can do. And the way to find out what the thing can do is just like, yeah,
let it try everything. Let it try everything. By the way, that's how you're going to find all the good stuff
it can do. By the way, that's also how you're going to find all the flaws. I think the people who
turn that on for bots are like, they're like martyrs to the progress of human civilization.
Like, I feel very bad for their descendants that their bank accounts are going to get looted by
their bots in the first, like, 20 minutes.
But I think the contribution that they're making to the future of our species is amazing.
It's a gentleman science.
Yes, yes, yes.
It's a, Ben Franklin out with trying to get lightning strike his balloon and seeing if he gets electrocuted.
Yeah.
It's Jonas Salk with the polio vaccine, right?
Injecting it.
Yes.
So, yes, I think we should have like a glory should have like flags and like we should have like monuments
to the people that just let open clover run their lives.
More anecdotes.
What are the craziest or interesting things that people listening to this
should go home and do?
I mean,
this is,
the extreme thing is just like the straight yolo.
Like just,
yeah,
turn your life off.
That's a general capability.
Yeah,
yeah.
Like a specific story that was like,
wow.
And everyone in the group chat just lit up.
I mean,
like,
you know,
so there's tons of,
there's already tons of health.
You know,
the health dashboard stuff is just,
it's just absolutely amazing.
The number of stories on,
I just don't want to violate people's,
you know,
obviously personal.
Autonomize.
But,
You know, one of the things OpenClaught is really good at is hacking into all this stuff in your land.
It's really good.
So, you know, Internet of Things, aka Internet of shit.
Super insecure, but great.
It's discoverable.
It's discoverable.
OpenClau is happy to scan your network, identify all the things.
And then my friends who are most aggressive at this are having OpenClaught take over everything in their house.
Yeah.
It takes over their security cameras.
It takes over their, you know, whatever their access control systems.
It takes over their webcams.
I have a friend whose claw watches them sleep.
Put a webcam in your bedroom.
and put the claw on a loop.
I have it wake up frequently and have it watch it.
Just tell him, watch me sleep.
And I've seen the transcripts and it's literally like, Joe's asleep.
This is good.
This is good that Joe's asleep because, you know, I have, I have his health day.
And I know that he hasn't been getting enough sleep.
And so it's really good that he's getting asleep.
I really hope he gets his full, whatever, you know, five hours around sleep.
Joe's moving.
Joe's moving.
Joe might be waking up.
This is a real pro.
If Joe wakes up now, he's going to ruin his sleep cycle.
Oh, okay.
It's okay.
Joe just rolled over.
Okay, he's gone back to bed.
Okay, good.
all right, okay, I can relax.
This is fine.
He's monitoring the situation.
Monitoring the situation.
And being a bot, like, you know, is just like very focused.
Right.
It's just like, this is like, it's reason for existence is to watch Joe's sleep.
And then I was talking my friend who did this is like, you know, on the one hand,
it's like, all right, this is weird and creepy.
And I need to, I need to, maybe this is taking on my life.
And then the other thing is like, you know what?
If I had a heart attack in the middle of the night, this thing literally would like freak out
and call 911.
Like, there's no question this thing would figure out how to like alert medical authorities.
And like probably someone in SWAT teams.
and do whatever would be required to save my life, right?
And so it's like, you know, like, yeah, like that's happening.
What else?
If it's a company Unitary that makes the robot dogs,
then I actually have one at home, which is actually really fun with the Chinese companies.
The Chinese companies are so aggressive at adopting new technology,
but they don't always like, let's take the time to really package it,
package it and maybe think it all the way through.
And so at least the Unitary dog I have.
So it has a old non-LL
just control system, which by the way is not very good.
It markets well, but in practice, it's not that good.
It has trouble with stairs and so forth, and so it's not quite what it should be.
But then the language model thing comes out in the voice.
So they add, so they add LLM capability and then they add a voice mode to it.
But that LLM capability is not at all connected to the control system.
So you've got this schizophrenic dog that, like, is a complete idiot when it comes to
climbing the stairs, but it will happily teach you quantum mechanics.
Right, in like a plummy English accent, right?
It's just like absolutely amazing.
Jagged intelligence.
Yeah, talk about Jagging.
Now, obviously what's going to happen in the future is they're going to connect together.
But right now, and so right now it's not that useful.
And so I have a friend who has one of these who had his claw, basically, hack in and rewrite the code,
write new firmware.
Yeah.
Right new firmware for the unitry robot.
And now it's, now it's an actual pet dog for his kids.
You should do that before, after, like the motion.
Yeah, it's good.
You said it's completely different.
He said it's a complete transformation.
And whenever there's an issue in the thing now, the claw just like rewrites the code, you know, you go says the code.
And so it kind of goes to your thing here.
So, like, all of a sudden, this is why we want to think about AI code.
AI coding is not just, like, writing new apps.
It's also going in and rewriting all the old stuff that should have worked that never worked.
And so, like, I think, I think basically, I think the internet, the internet of shit is basically over.
Like, I think everything, there's the potential here where, like, all these devices in your house that have been, like, basically marginal or, you know, basically dumb, you know, like, all of a sudden they might all get really smart.
Now, you have to decide if, yes, there are horror movies in which this is the premise.
And so you have to decide if you want this.
But this is the first time I can say with confidence,
I now know how you could actually have a smart home
with 30 different kinds of things with chips and Internet access
where it actually all makes sense.
It all works together and it's all coherent in the whole thing.
And to have that unlock without a human being having to go do any of that work,
like, you know.
I'm waiting for a sorry, Mark.
I can't let you open that fridge door.
Exactly.
Yes.
Because you're not supposed to eat right now.
I have all of yes.
I have every spread of health information, you know,
and I know what you think you're doing, you know,
I don't know.
I don't think you can do this, but you know, are you really, you know, are you really sure?
And, you know, you told, you know, you told me last night, you really don't want me to let you do this.
So, you know, I'm sorry, but the fridge door is locked.
Open the fridge doors.
Exactly.
And by the way, I know you're supposed to be studying for a test.
So why don't we, why don't you go, when you can pass the test, I will open the fridge door for you.
Yeah.
Final protocol.
And then we can wrap up proof of human.
Yes.
Right?
Yeah. That's the last piece that we got to figure out.
Yeah.
So I would say there's, there's two massive, I would say, sort of asymmetries in the
world right now where we've known these asymmetries exist and we we societally have been unwilling
to grapple with them and I think they're both tipping right now and they're they're they're they're
the same thing it's virtual world version it's a physical world version so the virtual world version is
the is the bot is just like the internet internet is just like a wash and bots internet's a wash and
fake people it has been forever um by the way a lot of that has to do with lack of money you know and so
this is yeah this is my spicy take was these two are the same thing and corporations of people too
you know so interesting yeah yeah yeah okay so a maga account is proof of human yeah okay okay
Okay. Yeah, until you give the bots make accounts. Yeah, exactly. So, okay. Yeah, so there's that. But yeah, look,
look, the bot, I mean, every social media user knows this. The bot problem is a big problem.
You know, the bot problem has been a big problem forever. It's a huge problem. And it's never really
been confronted directly, like at any point. By the way, the physical world version of this is the drone,
the drone problem. Right. And so we've known for, you know, we've known for 20 years now that the
asymmetric threat, both in military, in actual military conflict, but also in just like security,
like security on the home front.
The big threat is the cheap attack drone, right?
The cheap, the cheap, the cheap, suicide, you know, drone with a bomb.
And we've known that forever.
And by the way, like, you know, it's very disconcerting how, like, every, you know,
every office complex in the, you know, in the world is like unprotected from drone attacks.
Every, every stadium, every school, every prison, like, is like, is like,
sure.
Okay, we've known that.
We've never done anything about it.
One possibility is just leave them unprotected forever and live in a world of, like,
asymmetric terrorism forever.
The other is take the problem seriously and figure out the set of techniques.
and technology is required to be able to deal with that, whether those are lasers or jammers or
early warning systems or, you know, personal force fields.
Kinetic personal force fields.
Personal force fields.
Exactly.
And in both cases, these are economic asymmetries.
These are economic asymmetries, right?
Because it's really cheap to feel a bot, but it's very hard to tell something about.
It's very cheap to feel a drone.
It's very expensive to defend against a drone.
But you see what I'm saying is it's the virtual version of the problem and it's the physical
version of the problem.
The virtual version of the problem, what we need quite literally is proof of human.
The reason is because you're not going to have proof of bot.
Especially now, the bots are too good.
The bots can pass the Turing test.
And if the bots can pass the Turing test, then you can't screen for bot.
You can't have proof of not a bot.
But what you can have is you can have proof of human.
You can have cryptographically validated.
This is definitely a person.
And then you can have cryptographically validated.
This is definitely like something that a person said.
This video is real, right?
Just to double click on, do you think Alex Blania with World?
Do you think he's got it or is there an alternative?
Oh, so I mean, there's going to be, I think there will be,
I think many people will try.
We're one of the key participants in the world in the World Project.
I don't know.
Yeah.
So we're partisans.
But yeah, I think, so we think world is exactly correct.
Okay.
And the reason is it has to be, it has to be proof of human.
It has, because you can't do proof of not bought.
You have to do proof of human.
To do proof human, you need biological validation.
You needed to start with this was actually a person, right?
Because otherwise, you have bought signing up as fake people.
Right.
So you have to have like something.
You have to have a biometric.
And then you have to have cryptographic validation and then the ability to do,
to do the lookup.
And then by the way, the other thing you need,
which you also need the selective disclosure.
So you need to be able to proof of human without
privacy,
all the underlying information.
By the way,
another thing you're going to need,
you're going to prove of age,
right?
Because there's all these laws in all these different countries now around.
You need to be 13 or 16 or 18 or whatever to do different things.
And so you're going to need,
you know,
sort of validate a proof of age,
you know,
to be able to legally operate,
right?
And so that's coming.
And then you're going to want,
like, proof of credit score and, you know,
proof of like,
you know,
a tricky one.
It is a tricky one.
but you're going to, there's no reason, like, if somebody's checking on your credit,
somebody shouldn't, give you an example, somebody shouldn't need to know your name in order to be able to find out whether you're credit worthy.
I see independently verifiable pieces of pieces of information.
It's like, just like, just likely disclosed.
And this is the answer to the privacy problem at large, which is I only need to prove and I need to prove at that moment.
So like, you're going to need that.
And I think their architecture makes sense.
So that needs to get solved.
I think language models have tip, the bots are now too good.
And so they're undetectable.
And so as a consequence, we now need to confront that problem directly.
And then like I said, and then the other problem is we need to go actually confront the drone problems.
The Ukraine conflict has really unlocked a lot of thinking on that.
And now the Iran situation is also unlocking that.
And so I think there's going to be just like this incredible explosion of both drone and counter.
Our Jones are buried in their guns.
Is it to keep it that way?
Yeah.
And counter drones.
I think we're going to sneak in one more question.
I'm trying to tie together a lot of things that you said over the year.
So at the Milken Institute debate with teal, which is amazing.
You talked about the lag between a new technology and kind of like the GDP impact of it.
The other idea you talked about is bourgeois capitalism and how, you know,
this kind of managerial class was needed because of this complexity.
And I think if you bring AI into the fold, you have like much higher leverage of people.
So like if you have, you know, the Musk industries and you give Elon a GI, you can run a lot more things at once.
And then you have the social contract.
And I know you were to do it a clip of Sam Alman saying.
were rethinking the whole thing and you're like, absolutely not.
Yes.
And I was at an event with Sam last night.
And he actually said in the last couple of weeks,
if now people are taking that seriously.
So I'm just curious, like, how you're seeing the structure of organization changing,
especially when you invest in early stage companies.
And, yeah, just like how the impact of work structure and all of that is playing out.
Yeah.
So there's a whole bunch of, there's a whole bunch of times.
I know, yeah.
We could spend, by the way, we'd be happy to spend more time,
but we could spend more time on all that.
So just for people who haven't followed this.
So this term managerial comes from this thinker in the 20th century, James Burnham,
who is one of the great kind of 20th century political thinkers, societal thinkers.
And he sort of said, and he was writing in like the 1940s, 1950s.
And he said kind of the whole history capitalism until that point had been in two phases.
Number one had been what he called bourgeois capitalism, which was thinking about as like name on the door.
Like Ford motor company because Henry Ford runs the company.
And Henry, it's like a dictatorial model.
And Henry Ford just like tells everybody what to do.
And he said the problem with bourgeois capitalism is it doesn't scale because Henry Ford can only tell so many
people to do so many things, and then he runs out of time in the day. And so he said the second
phase of capitalism was what he called managerial capitalism, which was the creation of a
professional class of managers that are trained not to be like car experts or to be whatever
experts in any particular field, but are trained to be experts in management. And then that led to,
you know, the importance of like Harvard business, you know, business schools and management
consulting firms and all these things. And then you look at every big company today. And like most
of the executives and most of the Fortune 500 companies are not domain experts in whatever the company does.
and they're certainly not the founders of those companies, but they're professional managers.
And in fact, in the course of their careers, they'll probably manage many different kinds of businesses.
They'll rotate around and they might work in healthcare for a while and then work in financial services and then go work in something else, you know, come work in tech.
And what Burnham said is he said that transition is absolutely required because the problem with bourgeois capitalism is it doesn't scale,
Henry Ford doesn't scale.
And so if you're going to run capitalist enterprises that are going to have millions to billions to customers,
you're going to need to, they're going to be operating a level of scale and complexity that's going to require this professional.
management class. And he said, look, the professional management class has its downsides.
Like, they're not necessarily experts of doing the thing. They're not as inventive.
You know, they're not going to create the next breakthrough thing. But he's like, whether you
think that's good or bad or whatever is what's going to be required. And basically,
that's what happened. Right. And so he wrote that book originally like 1940. You know,
over the course of the next 50 years, basically managerialism, well, I mean, today, up till
today, managerialism basically took over everything. And, you know, what I'm describing is basically
how all big companies run and how all governments run and how large scale nonprofits run and kind of
everything runs. Basically, what venture capital does is we basically are a rump sort of protest
movement to that to try to find the next Henry Ford, or just to say, Elon Musk, or the next, or the next
Elon Musk, or the next Steve Jobs, the next Bill Gates, the next Mark Zuckerberg. And so we,
we start these companies in the old model, right? We start them out as in the Henry Ford model.
And so we start them out with a founder or a, or a founder with colleagues, but, you know,
there's a founder CEO. And then we basically bet that, we basically bet that the start
is going to be able to do things specifically innovate in ways that the big incumbents in that
industry are not going to be able to do. And so it's a bet that by basically by relighting
this sort of name on the door kind of thing, this new innovative thing with like a king
monarchical political structure, that they're going to be able to innovate in a way that the incumbent
is not going to be able to because the incumbent is being run by managers. Right. And by the way,
and of course, venture being what it is. Sometimes that works. Sometimes it doesn't. But we're
constantly doing that. But I've always viewed it my entire life as like we're like raging
against the dying of the light.
Like we're sort of constantly trying to fight off managerialism,
just basically swamping everything and everything,
getting basically boring and gray and dumb and old, right?
And we're trying to keep some level of energy vitality in the system.
AI is the thing that would lead you to think, wow, maybe there's a third model.
Right.
And a way to think about it would be maybe it's a combination of the two.
Maybe the new Henry Ford or the new Elon or the new Steve Jobs plus AI is the best of both,
right?
Because it's sort of the spark of genius of,
the name on the door model, the Henry Ford model, but then it's give that person AI superpowers
to do all the managerial stuff and let the boss drill the managerial stuff. That may be the actual
secret formula. And we've never even known that we wanted this because we never even thought
it was a possibility. But I mean, you know this. What is the thing that these bots are really good,
they're really good at doing paperwork. Like, they're really good at filling out forms.
Like, they're really good at writing reports. They're really good at reading, they're really good
at doing all the managerial work. Like, they're amazing at it. And so, yeah, so I think, I think
the, 100%, I think the answer, the answer very well might be to get the best of both worlds
by doing this. And then the challenge is going to be twofold. The challenge is going to be for
the innovators to really figure out how to leverage AI to actually do this. And then the other
challenge is going to be for the incumbents that are managerial to figure out, okay, what does that
mean? Because now they're going to, they're going to be facing a different kind of insurgent
competitor that has a different set of capabilities than they're used to. And so this really, I think,
is going to force a lot of big companies to kind of figure out innovation. Either, I say, figure out
innovation or die trying. Do you feel like that structure accelerates the impact on the actual GDP
and economy? If you guys, SpaceX, it's like the growth is like so fast. And like instead of
having these companies kind of like peter out and growth and impact, they can kind of like keep going,
if not accelerating. That's for sure the hope. The challenge and, you know, and look, the AI utopian
view is of course, of course. And that's going to be the future of economy and it's going to grow a 10x
and 100x and a thousand X. And we're entering this regime of like much higher economic growth forever.
And consumer chronocopy of everything. And it's, it's going to.
be great. And I hope that's true. I hope that's like the, you know, that's the current
kind of utopian vision. I hope that's true. The problem is, goes back again, the real world is
really messy. And I'll give you an example of how the real world is really messy. It requires
900 hours of professional certification training to become a hairdresser in the state of California.
So it's like 35% of the economy, something like that, you have to get some sort of professional
certification to do the job. It was just to say that the professions are all cartels, right? And so
you have to get licensed as a doctor. You have to get licenses as a lawyer. You have to get licenses as a
lawyer. You have to get licensed as a, you have to get into a union. By the way, to work for the
government, you need to be, you have both civil service protections and you have public sector unions.
You have two layers of insulation against ever getting fired for anything or anything, anything ever
changing. I'll give you another example. The dock workers went on strike a couple of years ago
because they're, you know, robotics. If you go look at a modern dock like in Asia, it's all robots.
If you go to American dock, it's like all still guys, dragon, strike, dragon stuff by hand. The dock workers
are on a strike. It turns out there are 25,000 dock workers working on docs in America. It turns out
they have incredible political power because it's one of these unified blocks of things. They won
their strike. And so they got commitments from the dock owners to not implement more automation.
We learned a couple of things in that. So number one, we learned even a union as small as 25,000
people still has like tremendous political stroke. We also learn that they, it actually turns out
the dock workers union has 50,000 people in it because there's 20, they have 25,000 people working at
They've 25,000 people during full paycheck sitting at home from prior union agreements.
Oh, my God.
From prior union agreements.
I'll give you another great example.
There are government agencies.
There are federal government agencies where the employees, right, have civil service protections
and they're in public sector unions.
There are entire federal government agencies that struck new collective bargaining agreements
during COVID, where not only have their jobs guaranteed in perpetuity, but they only have
to report to work in an office one day per month.
And so there are entire office buildings in Washington, D.C., that are empty 29 out of
30 days of the year that are still operating and are still, we're all still paying for.
And then what they do, it turns out what the employees do is they're very smart in
this way. And so they figure out, they come in on the last day of a month and the first day
of the next month. And so they're in there, they're in the office two days per 60 days,
which means these buildings are empty for 58 days at a time. And you see where I'm
heading with this. Like, this is like locked in. Right. This is like locked in a way that has
nothing to do with like, and people say capitalists, it's like anti-capitalistic. It's like,
It's basically it's restrictions on trade.
It's restrictions on the ability to, like, change the workforce.
And so so much of our economy is, you know, I'm describing the entire healthcare system.
I'm describing the entire legal profession.
I'm describing the entire housing industry.
I'm describing the entire education system.
Right.
K through 12 schools in the United States, they're a literal government monopoly.
How are we going to apply A& education?
The answer is we're not because it's a literal government monopoly.
It is never going to change the end and there is nothing to do.
By the way, you can create an.
an entirely new school system.
Like, that's the one thing you can do is you can do what Alpha School is doing.
You can create an entirely new school system.
Other than that, you're not going to go in and change what's happening in the American
classroom like K through 12.
There's no chance.
The teachers are 100% opposed to it.
It's 100% not going to happen.
So you see what I'm saying is like there's this like massive slippage that's going to take place.
Both the AI utopians and the AI Dumerers are far too optimistic.
Right.
You see what I'm saying?
Because they believe that because the technology makes something possible that 8 billion people
all of a sudden are going to change how they behave.
And it's just like, no.
so much of how the existing economy works,
it's just like wired in.
And so we're going to be lucky,
as a society,
we're going to be lucky if AI adoption happens quickly.
Right,
because if it doesn't,
we're just going to have a stagnation.
Awesome, Mark, I know you got to run.
Yeah, I don't know.
Or stay welcome,
but it was such a pleasure talking to you.
We're truly living in an age of science fiction coming to real life.
Yes, yes.
Could not be more exciting.
Really, thank you, Marth, you guys.
Awesome.
Thank you.
That's it.
Good.
Thank you.
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