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identifier: 2106

model: gemini-2.5-pro-exp-03-25| input-price: 1.25 output-price: 10.0 max-context-length: 128_000

host: 217.15.157.112

https://www.youtube.com/watch?v=RzOQHazjXvE

include_comments: None

include_timestamps: 1

include_glossary: None

output_language: en

cost: 0.0305525

Okay, here is the abstract and summary for the provided transcript, following the requested format.

*Abstract:*

This video documents an attempt to measure the relative frequency stability of two vintage HP 5061A cesium atomic clocks as a preliminary step towards potentially observing relativistic time dilation effects, similar to the Hafele-Keating experiment. The measurement setup utilizes HP timing generators to derive 1-pulse-per-second (1PPS) signals from each clock's 5 MHz output, an HP 5334B counter to measure the time interval between these pulses, and a restored HP 5087A distribution amplifier with a frequency doubler providing the necessary 10 MHz reference for the counter. Allan Variance is discussed as the relevant stability metric. Initial measurements revealed significant relative drift (tens of nanoseconds overnight), far exceeding the stability required for relativistic measurements. Attempts were made to improve stability by finely adjusting the C-field (magnetic field) of one clock. A vintage HP-IB logging system, comprising an HP 85 computer, HP 59501B DAC, and HP 7132A chart recorder, was implemented to track the drift over time. Despite the successful operation of the all-HP measurement chain, the logged data showed continued drift and discrete jumps in the time difference, indicating persistent instability likely originating from one of the clocks. The experiment concludes that further clock repair is necessary before achieving the required stability, while highlighting the successful performance of the vintage test equipment setup.

*Comparing Two Atomic Clocks: Stability Test for a Relativity Experiment*

*   *0:00:32 Goal:* The primary aim is to compare two HP 5061A atomic clocks to assess their relative stability, as a precursor to attempting a measurement of relativistic time dilation (inspired by the Hafele-Keating experiment).
*   *0:01:02 Initial Check:* The first step is confirming the clocks' stability relative to each other while stationary in the lab, aiming for sub-nanosecond drift over days.
*   *0:01:50 Measurement Setup:* Comparing two imperfect clocks means only their relative difference can be measured. The setup aims to precisely track this difference.
*   *0:02:13 Clock Outputs:* The HP 5061A units are frequency standards providing 5 MHz, 1 MHz, and 100 kHz outputs, unlike the time-of-day clocks used in the original Hafele-Keating experiment.
*   *0:02:43 1PPS Generation:* HP 59308A Timing Generators are used to divide the 5 MHz output from each clock down to a precise 1 pulse-per-second (1PPS) signal.
*   *0:03:31 Time Interval Measurement:* An HP 5334B counter measures the time interval between the 1PPS signals from the two clocks with 0.1 ns resolution. The counter's math function zeros the initial arbitrary delay.
*   *0:04:04 Counter Reference Challenge:* The counter requires a 10 MHz reference, but the clocks output 5 MHz.
*   *0:04:17 Frequency Doubling Solution:* A restored HP 5087A Distribution Amplifier with its frequency doubler option converts the 5 MHz output from one clock to the required 10 MHz reference for the counter.
*   *0:04:56 Stability Metric (Allan Variance):* Allan Variance is introduced as the standard measure for clock stability over different time scales. The target stability for the relativity experiment (around 1 part in 10^13) is noted as challenging for these specific clocks.
*   *0:06:52 First Overnight Result:* The initial overnight test shows a significant relative drift of ~35 nanoseconds, far too unstable for the intended experiment.
*   *0:08:31 Second Overnight Result:* After restarting, the drift is lower (~6.7 nanoseconds) but still too high.
*   *0:08:58 C-Field Adjustment:* An attempt is made to finely tune the frequency of one clock relative to the other using its C-field adjustment (tuning the magnetic field affecting the cesium resonance), aiming for minimal relative drift.
*   *0:10:31 Characterization vs. Tuning:* It's noted that the original Hafele-Keating experiment characterized clock drift against a master standard rather than attempting to tune the clocks perfectly relative to each other.
*   *0:11:04 Long-Term Logging:* A vintage, all-HP logging system is assembled to record the drift continuously.
*   *0:11:08 Logging Components:* The system uses an HP 7132A chart recorder driven by an HP 59501B DAC, controlled by an HP 85 computer via the HP-IB bus. An HP 3478A DVM monitors the DAC output.
*   *0:11:56 Control Program:* A simple 13-line BASIC program on the HP 85 reads the time interval from the counter, scales it, and sends the value to the DAC for plotting.
*   *0:14:10 Third Result (Logged):* The chart recording shows ~14 nanoseconds of drift overnight.
*   *0:14:20 Drift Instability:* Crucially, the recording reveals the drift isn't smooth but includes significant, abrupt jumps, indicating underlying instability.
*   *0:14:44 Conclusion:* The clocks (or at least one of them) are currently too unstable, exhibiting both drift and jumps ("atomic gremlins").
*   *0:15:03 Measurement System Success:* Despite the clock instability, the entire vintage HP measurement and logging system performed flawlessly.
*   *0:15:11 Next Steps:* More atomic clock repair work is required before the desired stability measurements and the subsequent relativity experiment can be successfully performed.

I used gemini-2.5-pro-exp-03-25| input-price: 1.25 output-price: 10.0 max-context-length: 128_000 on rocketrecap dot com to summarize the transcript.
Cost (if I didn't use the free tier): $0.03
Input tokens: 14098
Output tokens: 1293

Okay, here is the abstract and summary for the provided transcript, following the requested format.

Abstract:

This video documents an attempt to measure the relative frequency stability of two vintage HP 5061A cesium atomic clocks as a preliminary step towards potentially observing relativistic time dilation effects, similar to the Hafele-Keating experiment. The measurement setup utilizes HP timing generators to derive 1-pulse-per-second (1PPS) signals from each clock's 5 MHz output, an HP 5334B counter to measure the time interval between these pulses, and a restored HP 5087A distribution amplifier with a frequency doubler providing the necessary 10 MHz reference for the counter. Allan Variance is discussed as the relevant stability metric. Initial measurements revealed significant relative drift (tens of nanoseconds overnight), far exceeding the stability required for relativistic measurements. Attempts were made to improve stability by finely adjusting the C-field (magnetic field) of one clock. A vintage HP-IB logging system, comprising an HP 85 computer, HP 59501B DAC, and HP 7132A chart recorder, was implemented to track the drift over time. Despite the successful operation of the all-HP measurement chain, the logged data showed continued drift and discrete jumps in the time difference, indicating persistent instability likely originating from one of the clocks. The experiment concludes that further clock repair is necessary before achieving the required stability, while highlighting the successful performance of the vintage test equipment setup.

Comparing Two Atomic Clocks: Stability Test for a Relativity Experiment

• 0:00:32 Goal: The primary aim is to compare two HP 5061A atomic clocks to assess their relative stability, as a precursor to attempting a measurement of relativistic time dilation (inspired by the Hafele-Keating experiment).
• 0:01:02 Initial Check: The first step is confirming the clocks' stability relative to each other while stationary in the lab, aiming for sub-nanosecond drift over days.
• 0:01:50 Measurement Setup: Comparing two imperfect clocks means only their relative difference can be measured. The setup aims to precisely track this difference.
• 0:02:13 Clock Outputs: The HP 5061A units are frequency standards providing 5 MHz, 1 MHz, and 100 kHz outputs, unlike the time-of-day clocks used in the original Hafele-Keating experiment.
• 0:02:43 1PPS Generation: HP 59308A Timing Generators are used to divide the 5 MHz output from each clock down to a precise 1 pulse-per-second (1PPS) signal.
• 0:03:31 Time Interval Measurement: An HP 5334B counter measures the time interval between the 1PPS signals from the two clocks with 0.1 ns resolution. The counter's math function zeros the initial arbitrary delay.
• 0:04:04 Counter Reference Challenge: The counter requires a 10 MHz reference, but the clocks output 5 MHz.
• 0:04:17 Frequency Doubling Solution: A restored HP 5087A Distribution Amplifier with its frequency doubler option converts the 5 MHz output from one clock to the required 10 MHz reference for the counter.
• 0:04:56 Stability Metric (Allan Variance): Allan Variance is introduced as the standard measure for clock stability over different time scales. The target stability for the relativity experiment (around 1 part in 10^13) is noted as challenging for these specific clocks.
• 0:06:52 First Overnight Result: The initial overnight test shows a significant relative drift of ~35 nanoseconds, far too unstable for the intended experiment.
• 0:08:31 Second Overnight Result: After restarting, the drift is lower (~6.7 nanoseconds) but still too high.
• 0:08:58 C-Field Adjustment: An attempt is made to finely tune the frequency of one clock relative to the other using its C-field adjustment (tuning the magnetic field affecting the cesium resonance), aiming for minimal relative drift.
• 0:10:31 Characterization vs. Tuning: It's noted that the original Hafele-Keating experiment characterized clock drift against a master standard rather than attempting to tune the clocks perfectly relative to each other.
• 0:11:04 Long-Term Logging: A vintage, all-HP logging system is assembled to record the drift continuously.
• 0:11:08 Logging Components: The system uses an HP 7132A chart recorder driven by an HP 59501B DAC, controlled by an HP 85 computer via the HP-IB bus. An HP 3478A DVM monitors the DAC output.
• 0:11:56 Control Program: A simple 13-line BASIC program on the HP 85 reads the time interval from the counter, scales it, and sends the value to the DAC for plotting.
• 0:14:10 Third Result (Logged): The chart recording shows ~14 nanoseconds of drift overnight.
• 0:14:20 Drift Instability: Crucially, the recording reveals the drift isn't smooth but includes significant, abrupt jumps, indicating underlying instability.
• 0:14:44 Conclusion: The clocks (or at least one of them) are currently too unstable, exhibiting both drift and jumps ("atomic gremlins").
• 0:15:03 Measurement System Success: Despite the clock instability, the entire vintage HP measurement and logging system performed flawlessly.
• 0:15:11 Next Steps: More atomic clock repair work is required before the desired stability measurements and the subsequent relativity experiment can be successfully performed.

Below, I will provide input for an example video (comprising of title, description, and transcript, in this order) and the corresponding abstract and summary I expect. Afterward, I will provide a new transcript that I want you to summarize in the same format. 

**Please give an abstract of the transcript and then summarize the transcript in a self-contained bullet list format.** Include starting timestamps, important details and key takeaways. 

Example Input: 
Fluidigm Polaris Part 2- illuminator and camera
mikeselectricstuff
131K subscribers
Subscribed
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5,857 views Aug 26, 2024
Fluidigm Polaris part 1 : • Fluidigm Polaris (Part 1) - Biotech g...
Ebay listings: https://www.ebay.co.uk/usr/mikeselect...
Merch https://mikeselectricstuff.creator-sp...
Transcript
Follow along using the transcript.
Show transcript
mikeselectricstuff
131K subscribers
Videos
About
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40 Comments
@robertwatsonbath
6 hours ago
Thanks Mike. Ooof! - with the level of bodgery going on around 15:48 I think shame would have made me do a board re spin, out of my own pocket if I had to.
1
Reply
@Muonium1
9 hours ago
The green LED looks different from the others and uses phosphor conversion because of the "green gap" problem where green InGaN emitters suffer efficiency droop at high currents. Phosphide based emitters don't start becoming efficient until around 600nm so also can't be used for high power green emitters. See the paper and plot by Matthias Auf der Maur in his 2015 paper on alloy fluctuations in InGaN as the cause of reduced external quantum efficiency at longer (green) wavelengths.
4
Reply
1 reply
@tafsirnahian669
10 hours ago (edited)
Can this be used as an astrophotography camera?
Reply
mikeselectricstuff
·
1 reply
@mikeselectricstuff
6 hours ago
Yes, but may need a shutter to avoid light during readout
Reply
@2010craggy
11 hours ago
Narrowband filters we use in Astronomy (Astrophotography) are sided- they work best passing light in one direction so I guess the arrows on the filter frames indicate which way round to install them in the filter wheel.
1
Reply
@vitukz
12 hours ago
A mate with Channel @extractions&ire could use it
2
Reply
@RobertGallop
19 hours ago
That LED module says it can go up to 28 amps!!! 21 amps for 100%. You should see what it does at 20 amps!
Reply
@Prophes0r
19 hours ago
I had an "Oh SHIT!" moment when I realized that the weird trapezoidal shape of that light guide was for keystone correction of the light source.
Very clever.
6
Reply
@OneBiOzZ
20 hours ago
given the cost of the CCD you think they could have run another PCB for it
9
Reply
@tekvax01
21 hours ago
$20 thousand dollars per minute of run time!
1
Reply
@tekvax01
22 hours ago
"We spared no expense!" John Hammond Jurassic Park.
*(that's why this thing costs the same as a 50-seat Greyhound Bus coach!)
Reply
@florianf4257
22 hours ago
The smearing on the image could be due to the fact that you don't use a shutter, so you see brighter stripes under bright areas of the image as you still iluminate these pixels while the sensor data ist shifted out towards the top. I experienced this effect back at university with a LN-Cooled CCD for Spectroscopy. The stripes disapeared as soon as you used the shutter instead of disabling it in the open position (but fokussing at 100ms integration time and continuous readout with a focal plane shutter isn't much fun).
12
Reply
mikeselectricstuff
·
1 reply
@mikeselectricstuff
12 hours ago
I didn't think of that, but makes sense
2
Reply
@douro20
22 hours ago (edited)
The red LED reminds me of one from Roithner Lasertechnik. I have a Symbol 2D scanner which uses two very bright LEDs from that company, one red and one red-orange. The red-orange is behind a lens which focuses it into an extremely narrow beam.
1
Reply
@RicoElectrico
23 hours ago
PFG is Pulse Flush Gate according to the datasheet.
Reply
@dcallan812
23 hours ago
Very interesting. 2x
Reply
@littleboot_
1 day ago
Cool interesting device
Reply
@dav1dbone
1 day ago
I've stripped large projectors, looks similar, wonder if some of those castings are a magnesium alloy?
Reply
@kevywevvy8833
1 day ago
ironic that some of those Phlatlight modules are used in some of the cheapest disco lights.
1
Reply
1 reply
@bill6255
1 day ago
Great vid - gets right into subject in title, its packed with information, wraps up quickly. Should get a YT award! imho
3
Reply
@JAKOB1977
1 day ago (edited)
The whole sensor module incl. a 5 grand 50mpix sensor for 49 £.. highest bid atm
Though also a limited CCD sensor, but for the right buyer its a steal at these relative low sums.
Architecture Full Frame CCD (Square Pixels)
Total Number of Pixels 8304 (H) × 6220 (V) = 51.6 Mp
Number of Effective Pixels 8208 (H) × 6164 (V) = 50.5 Mp
Number of Active Pixels 8176 (H) × 6132 (V) = 50.1 Mp
Pixel Size 6.0 m (H) × 6.0 m (V)
Active Image Size 49.1 mm (H) × 36.8 mm (V)
61.3 mm (Diagonal),
645 1.1x Optical Format
Aspect Ratio 4:3
Horizontal Outputs 4
Saturation Signal 40.3 ke−
Output Sensitivity 31 V/e−
Quantum Efficiency
KAF−50100−CAA
KAF−50100−AAA
KAF−50100−ABA (with Lens)
22%, 22%, 16% (Peak R, G, B)
25%
62%
Read Noise (f = 18 MHz) 12.5 e−
Dark Signal (T = 60°C) 42 pA/cm2
Dark Current Doubling Temperature 5.7°C
Dynamic Range (f = 18 MHz) 70.2 dB
Estimated Linear Dynamic Range
(f = 18 MHz)
69.3 dB
Charge Transfer Efficiency
Horizontal
Vertical
0.999995
0.999999
Blooming Protection
(4 ms Exposure Time)
800X Saturation Exposure
Maximum Date Rate 18 MHz
Package Ceramic PGA
Cover Glass MAR Coated, 2 Sides or
Clear Glass
Features
• TRUESENSE Transparent Gate Electrode
for High Sensitivity
• Ultra-High Resolution
• Board Dynamic Range
• Low Noise Architecture
• Large Active Imaging Area
Applications
• Digitization
• Mapping/Aerial
• Photography
• Scientific
Thx for the tear down Mike, always a joy
Reply
@martinalooksatthings
1 day ago
15:49 that is some great bodging on of caps, they really didn't want to respin that PCB huh
8
Reply
@RhythmGamer
1 day ago
Was depressed today and then a new mike video dropped and now I’m genuinely happy to get my tear down fix
1
Reply
@dine9093
1 day ago (edited)
Did you transfrom into Mr Blobby for a moment there?
2
Reply
@NickNorton
1 day ago
Thanks Mike. Your videos are always interesting.
5
Reply
@KeritechElectronics
1 day ago
Heavy optics indeed... Spare no expense, cost no object. Splendid build quality. The CCD is a thing of beauty!
1
Reply
@YSoreil
1 day ago
The pricing on that sensor is about right, I looked in to these many years ago when they were still in production since it's the only large sensor you could actually buy. Really cool to see one in the wild.
2
Reply
@snik2pl
1 day ago
That leds look like from led projector
Reply
@vincei4252
1 day ago
TDI = Time Domain Integration ?
1
Reply
@wolpumba4099
1 day ago (edited)
Maybe the camera should not be illuminated during readout.
From the datasheet of the sensor (Onsemi): saturation 40300 electrons, read noise 12.5 electrons per pixel @ 18MHz (quite bad). quantum efficiency 62% (if it has micro lenses), frame rate 1 Hz. lateral overflow drain to prevent blooming protects against 800x (factor increases linearly with exposure time) saturation exposure (32e6 electrons per pixel at 4ms exposure time), microlens has +/- 20 degree acceptance angle
i guess it would be good for astrophotography
4
Reply
@txm100
1 day ago (edited)
Babe wake up a new mikeselectricstuff has dropped!
9
Reply
@vincei4252
1 day ago
That looks like a finger-lakes filter wheel, however, for astronomy they'd never use such a large stepper.
1
Reply
@MRooodddvvv
1 day ago
yaaaaay ! more overcomplicated optical stuff !
4
Reply
1 reply
@NoPegs
1 day ago
He lives!
11
Reply
1 reply
Transcript
0:00
so I've stripped all the bits of the
0:01
optical system so basically we've got
0:03
the uh the camera
0:05
itself which is mounted on this uh very
0:09
complex
0:10
adjustment thing which obviously to set
0:13
you the various tilt and uh alignment
0:15
stuff then there's two of these massive
0:18
lenses I've taken one of these apart I
0:20
think there's something like about eight
0:22
or nine Optical elements in here these
0:25
don't seem to do a great deal in terms
0:26
of electr magnification they're obiously
0:28
just about getting the image to where it
0:29
uh where it needs to be just so that
0:33
goes like that then this Optical block I
0:36
originally thought this was made of some
0:37
s crazy heavy material but it's just
0:39
really the sum of all these Optical bits
0:41
are just ridiculously heavy those lenses
0:43
are about 4 kilos each and then there's
0:45
this very heavy very solid um piece that
0:47
goes in the middle and this is so this
0:49
is the filter wheel assembly with a
0:51
hilariously oversized steper
0:53
motor driving this wheel with these very
0:57
large narrow band filters so we've got
1:00
various different shades of uh
1:03
filters there five Al together that
1:06
one's actually just showing up a silver
1:07
that's actually a a red but fairly low
1:10
transmission orangey red blue green
1:15
there's an excess cover on this side so
1:16
the filters can be accessed and changed
1:19
without taking anything else apart even
1:21
this is like ridiculous it's like solid
1:23
aluminium this is just basically a cover
1:25
the actual wavelengths of these are um
1:27
488 525 570 630 and 700 NM not sure what
1:32
the suffix on that perhaps that's the uh
1:34
the width of the spectral line say these
1:37
are very narrow band filters most of
1:39
them are you very little light through
1:41
so it's still very tight narrow band to
1:43
match the um fluoresence of the dies
1:45
they're using in the biochemical process
1:48
and obviously to reject the light that's
1:49
being fired at it from that Illuminator
1:51
box and then there's a there's a second
1:53
one of these lenses then the actual sort
1:55
of samples below that so uh very serious
1:58
amount of very uh chunky heavy Optics
2:01
okay let's take a look at this light
2:02
source made by company Lumen Dynamics
2:04
who are now part of
2:06
excelitas self-contained unit power
2:08
connector USB and this which one of the
2:11
Cable Bundle said was a TTL interface
2:14
USB wasn't used in uh the fluid
2:17
application output here and I think this
2:19
is an input for um light feedback I
2:21
don't if it's regulated or just a measur
2:23
measurement facility and the uh fiber
2:27
assembly
2:29
Square Inlet there and then there's two
2:32
outputs which have uh lens assemblies
2:35
and this small one which goes back into
2:37
that small Port just Loops out of here
2:40
straight back in So on this side we've
2:42
got the electronics which look pretty
2:44
straightforward we've got a bit of power
2:45
supply stuff over here and we've got
2:48
separate drivers for each wavelength now
2:50
interesting this is clearly been very
2:52
specifically made for this application
2:54
you I was half expecting like say some
2:56
generic drivers that could be used for a
2:58
number of different things but actually
3:00
literally specified the exact wavelength
3:02
on the PCB there is provision here for
3:04
385 NM which isn't populated but this is
3:07
clearly been designed very specifically
3:09
so these four drivers look the same but
3:10
then there's two higher power ones for
3:12
575 and
3:14
520 a slightly bigger heat sink on this
3:16
575 section there a p 24 which is
3:20
providing USB interface USB isolator the
3:23
USB interface just presents as a comport
3:26
I did have a quick look but I didn't
3:27
actually get anything sensible um I did
3:29
dump the Pi code out and there's a few
3:31
you a few sort of commands that you
3:32
could see in text but I didn't actually
3:34
manage to get it working properly I
3:36
found some software for related version
3:38
but it didn't seem to want to talk to it
3:39
but um I say that wasn't used for the
3:41
original application it might be quite
3:42
interesting to get try and get the Run
3:44
hours count out of it and the TTL
3:46
interface looks fairly straightforward
3:48
we've got positions for six opto
3:50
isolators but only five five are
3:52
installed so that corresponds with the
3:54
unused thing so I think this hopefully
3:56
should be as simple as just providing a
3:57
ttrl signal for each color to uh enable
4:00
it a big heat sink here which is there I
4:03
think there's like a big S of metal
4:04
plate through the middle of this that
4:05
all the leads are mounted on the other
4:07
side so this is heat sinking it with a
4:09
air flow from a uh just a fan in here
4:13
obviously don't have the air flow
4:14
anywhere near the Optics so conduction
4:17
cool through to this plate that's then
4:18
uh air cooled got some pots which are
4:21
presumably power
4:22
adjustments okay let's take a look at
4:24
the other side which is uh much more
4:27
interesting see we've got some uh very
4:31
uh neatly Twisted cable assemblies there
4:35
a bunch of leads so we've got one here
4:37
475 up here 430 NM 630 575 and 520
4:44
filters and dcro mirrors a quick way to
4:48
see what's white is if we just shine
4:49
some white light through
4:51
here not sure how it is is to see on the
4:54
camera but shining white light we do
4:55
actually get a bit of red a bit of blue
4:57
some yellow here so the obstacle path
5:00
575 it goes sort of here bounces off
5:03
this mirror and goes out the 520 goes
5:07
sort of down here across here and up
5:09
there 630 goes basically straight
5:13
through
5:15
430 goes across there down there along
5:17
there and the 475 goes down here and
5:20
left this is the light sensing thing
5:22
think here there's just a um I think
5:24
there a photo diode or other sensor
5:26
haven't actually taken that off and
5:28
everything's fixed down to this chunk of
5:31
aluminium which acts as the heat
5:32
spreader that then conducts the heat to
5:33
the back side for the heat
5:35
sink and the actual lead packages all
5:38
look fairly similar except for this one
5:41
on the 575 which looks quite a bit more
5:44
substantial big spay
5:46
Terminals and the interface for this
5:48
turned out to be extremely simple it's
5:50
literally a 5V TTL level to enable each
5:54
color doesn't seem to be any tensity
5:56
control but there are some additional
5:58
pins on that connector that weren't used
5:59
in the through time thing so maybe
6:01
there's some extra lines that control
6:02
that I couldn't find any data on this uh
6:05
unit and the um their current product
6:07
range is quite significantly different
6:09
so we've got the uh blue these
6:13
might may well be saturating the camera
6:16
so they might look a bit weird so that's
6:17
the 430
6:18
blue the 575
6:24
yellow uh
6:26
475 light blue
6:29
the uh 520
6:31
green and the uh 630 red now one
6:36
interesting thing I noticed for the
6:39
575 it's actually it's actually using a
6:42
white lead and then filtering it rather
6:44
than using all the other ones are using
6:46
leads which are the fundamental colors
6:47
but uh this is actually doing white and
6:50
it's a combination of this filter and
6:52
the dichroic mirrors that are turning to
6:55
Yellow if we take the filter out and a
6:57
lot of the a lot of the um blue content
7:00
is going this way the red is going
7:02
straight through these two mirrors so
7:05
this is clearly not reflecting much of
7:08
that so we end up with the yellow coming
7:10
out of uh out of there which is a fairly
7:14
light yellow color which you don't
7:16
really see from high intensity leads so
7:19
that's clearly why they've used the
7:20
white to uh do this power consumption of
7:23
the white is pretty high so going up to
7:25
about 2 and 1 half amps on that color
7:27
whereas most of the other colors are
7:28
only drawing half an amp or so at 24
7:30
volts the uh the green is up to about
7:32
1.2 but say this thing is uh much
7:35
brighter and if you actually run all the
7:38
colors at the same time you get a fairly
7:41
reasonable um looking white coming out
7:43
of it and one thing you might just be
7:45
out to notice is there is some sort
7:46
color banding around here that's not
7:49
getting uh everything s completely
7:51
concentric and I think that's where this
7:53
fiber optic thing comes
7:58
in I'll
8:00
get a couple of Fairly accurately shaped
8:04
very sort of uniform color and looking
8:06
at What's um inside here we've basically
8:09
just got this Square Rod so this is
8:12
clearly yeah the lights just bouncing
8:13
off all the all the various sides to um
8:16
get a nice uniform illumination uh this
8:19
back bit looks like it's all potted so
8:21
nothing I really do to get in there I
8:24
think this is fiber so I have come
8:26
across um cables like this which are
8:27
liquid fill but just looking through the
8:30
end of this it's probably a bit hard to
8:31
see it does look like there fiber ends
8:34
going going on there and so there's this
8:36
feedback thing which is just obviously
8:39
compensating for the any light losses
8:41
through here to get an accurate
8:43
representation of uh the light that's
8:45
been launched out of these two
8:47
fibers and you see uh
8:49
these have got this sort of trapezium
8:54
shape light guides again it's like a
8:56
sort of acrylic or glass light guide
9:00
guess projected just to make the right
9:03
rectangular
9:04
shape and look at this Center assembly
9:07
um the light output doesn't uh change
9:10
whether you feed this in or not so it's
9:11
clear not doing any internal Clos Loop
9:14
control obviously there may well be some
9:16
facility for it to do that but it's not
9:17
being used in this
9:19
application and so this output just
9:21
produces a voltage on the uh outle
9:24
connector proportional to the amount of
9:26
light that's present so there's a little
9:28
diffuser in the back there
9:30
and then there's just some kind of uh
9:33
Optical sensor looks like a
9:35
chip looking at the lead it's a very
9:37
small package on the PCB with this lens
9:40
assembly over the top and these look
9:43
like they're actually on a copper
9:44
Metalized PCB for maximum thermal
9:47
performance and yeah it's a very small
9:49
package looks like it's a ceramic
9:51
package and there's a thermister there
9:53
for temperature monitoring this is the
9:56
475 blue one this is the 520 need to
9:59
Green which is uh rather different OB
10:02
it's a much bigger D with lots of bond
10:04
wise but also this looks like it's using
10:05
a phosphor if I shine a blue light at it
10:08
lights up green so this is actually a
10:10
phosphor conversion green lead which
10:12
I've I've come across before they want
10:15
that specific wavelength so they may be
10:17
easier to tune a phosphor than tune the
10:20
um semiconductor material to get the uh
10:23
right right wavelength from the lead
10:24
directly uh red 630 similar size to the
10:28
blue one or does seem to have a uh a
10:31
lens on top of it there is a sort of red
10:33
coloring to
10:35
the die but that doesn't appear to be
10:38
fluorescent as far as I can
10:39
tell and the white one again a little
10:41
bit different sort of much higher
10:43
current
10:46
connectors a makeer name on that
10:48
connector flot light not sure if that's
10:52
the connector or the lead
10:54
itself and obviously with the phosphor
10:56
and I'd imagine that phosphor may well
10:58
be tuned to get the maximum to the uh 5
11:01
cenm and actually this white one looks
11:04
like a St fairly standard product I just
11:06
found it in Mouse made by luminous
11:09
devices in fact actually I think all
11:11
these are based on various luminous
11:13
devices modules and they're you take
11:17
looks like they taking the nearest
11:18
wavelength and then just using these
11:19
filters to clean it up to get a precise
11:22
uh spectral line out of it so quite a
11:25
nice neat and um extreme
11:30
bright light source uh sure I've got any
11:33
particular use for it so I think this
11:35
might end up on
11:36
eBay but uh very pretty to look out and
11:40
without the uh risk of burning your eyes
11:43
out like you do with lasers so I thought
11:45
it would be interesting to try and
11:46
figure out the runtime of this things
11:48
like this we usually keep some sort
11:49
record of runtime cuz leads degrade over
11:51
time I couldn't get any software to work
11:52
through the USB face but then had a
11:54
thought probably going to be writing the
11:55
runtime periodically to the e s prom so
11:58
I just just scope up that and noticed it
12:00
was doing right every 5 minutes so I
12:02
just ran it for a while periodically
12:04
reading the E squ I just held the pick
12:05
in in reset and um put clip over to read
12:07
the square prom and found it was writing
12:10
one location per color every 5 minutes
12:12
so if one color was on it would write
12:14
that location every 5 minutes and just
12:16
increment it by one so after doing a few
12:18
tests with different colors of different
12:19
time periods it looked extremely
12:21
straightforward it's like a four bite
12:22
count for each color looking at the
12:24
original data that was in it all the
12:26
colors apart from Green were reading
12:28
zero and the green was reading four
12:30
indicating a total 20 minutes run time
12:32
ever if it was turned on run for a short
12:34
time then turned off that might not have
12:36
been counted but even so indicates this
12:37
thing wasn't used a great deal the whole
12:40
s process of doing a run can be several
12:42
hours but it'll only be doing probably
12:43
the Imaging at the end of that so you
12:46
wouldn't expect to be running for a long
12:47
time but say a single color for 20
12:50
minutes over its whole lifetime does
12:52
seem a little bit on the low side okay
12:55
let's look at the camera un fortunately
12:57
I managed to not record any sound when I
12:58
did this it's also a couple of months
13:00
ago so there's going to be a few details
13:02
that I've forgotten so I'm just going to
13:04
dub this over the original footage so um
13:07
take the lid off see this massive great
13:10
heat sink so this is a pel cool camera
13:12
we've got this blower fan producing a
13:14
fair amount of air flow through
13:16
it the connector here there's the ccds
13:19
mounted on the board on the
13:24
right this unplugs so we've got a bit of
13:27
power supply stuff on here
13:29
USB interface I think that's the Cyprus
13:32
microcontroller High speeded USB
13:34
interface there's a zyink spon fpga some
13:40
RAM and there's a couple of ATD
13:42
converters can't quite read what those
13:45
those are but anal
13:47
devices um little bit of bodgery around
13:51
here extra decoupling obviously they
13:53
have having some noise issues this is
13:55
around the ram chip quite a lot of extra
13:57
capacitors been added there
13:59
uh there's a couple of amplifiers prior
14:01
to the HD converter buffers or Andor
14:05
amplifiers taking the CCD
14:08
signal um bit more power spy stuff here
14:11
this is probably all to do with
14:12
generating the various CCD bias voltages
14:14
they uh need quite a lot of exotic
14:18
voltages next board down is just a
14:20
shield and an interconnect
14:24
boardly shielding the power supply stuff
14:26
from some the more sensitive an log
14:28
stuff
14:31
and this is the bottom board which is
14:32
just all power supply
14:34
stuff as you can see tons of capacitors
14:37
or Transformer in
14:42
there and this is the CCD which is a uh
14:47
very impressive thing this is a kf50 100
14:50
originally by true sense then codec
14:53
there ON
14:54
Semiconductor it's 50 megapixels uh the
14:58
only price I could find was this one
15:00
5,000 bucks and the architecture you can
15:03
see there actually two separate halves
15:04
which explains the Dual AZ converters
15:06
and two amplifiers it's literally split
15:08
down the middle and duplicated so it's
15:10
outputting two streams in parallel just
15:13
to keep the bandwidth sensible and it's
15:15
got this amazing um diffraction effects
15:18
it's got micro lenses over the pixel so
15:20
there's there's a bit more Optics going
15:22
on than on a normal
15:25
sensor few more bodges on the CCD board
15:28
including this wire which isn't really
15:29
tacked down very well which is a bit uh
15:32
bit of a mess quite a few bits around
15:34
this board where they've uh tacked
15:36
various bits on which is not super
15:38
impressive looks like CCD drivers on the
15:40
left with those 3 ohm um damping
15:43
resistors on the
15:47
output get a few more little bodges
15:50
around here some of
15:52
the and there's this separator the
15:54
silica gel to keep the moisture down but
15:56
there's this separator that actually
15:58
appears to be cut from piece of
15:59
antistatic
16:04
bag and this sort of thermal block on
16:06
top of this stack of three pel Cola
16:12
modules so as with any Stacks they get
16:16
um larger as they go back towards the
16:18
heat sink because each P's got to not
16:20
only take the heat from the previous but
16:21
also the waste heat which is quite
16:27
significant you see a little temperature
16:29
sensor here that copper block which
16:32
makes contact with the back of the
16:37
CCD and this's the back of the
16:40
pelas this then contacts the heat sink
16:44
on the uh rear there a few thermal pads
16:46
as well for some of the other power
16:47
components on this
16:51
PCB okay I've connected this uh camera
16:54
up I found some drivers on the disc that
16:56
seem to work under Windows 7 couldn't
16:58
get to install under Windows 11 though
17:01
um in the absence of any sort of lens or
17:03
being bothered to the proper amount I've
17:04
just put some f over it and put a little
17:06
pin in there to make a pinhole lens and
17:08
software gives a few options I'm not
17:11
entirely sure what all these are there's
17:12
obviously a clock frequency 22 MHz low
17:15
gain and with PFG no idea what that is
17:19
something something game programmable
17:20
Something game perhaps ver exposure
17:23
types I think focus is just like a
17:25
continuous grab until you tell it to
17:27
stop not entirely sure all these options
17:30
are obviously exposure time uh triggers
17:33
there ex external hardware trigger inut
17:35
you just trigger using a um thing on
17:37
screen so the resolution is 8176 by
17:40
6132 and you can actually bin those
17:42
where you combine multiple pixels to get
17:46
increased gain at the expense of lower
17:48
resolution down this is a 10sec exposure
17:51
obviously of the pin hole it's very uh
17:53
intensitive so we just stand still now
17:56
downloading it there's the uh exposure
17:59
so when it's
18:01
um there's a little status thing down
18:03
here so that tells you the um exposure
18:07
[Applause]
18:09
time it's this is just it
18:15
downloading um it is quite I'm seeing
18:18
quite a lot like smearing I think that I
18:20
don't know whether that's just due to
18:21
pixels overloading or something else I
18:24
mean yeah it's not it's not um out of
18:26
the question that there's something not
18:27
totally right about this camera
18:28
certainly was bodge wise on there um I
18:31
don't I'd imagine a camera like this
18:32
it's got a fairly narrow range of
18:34
intensities that it's happy with I'm not
18:36
going to spend a great deal of time on
18:38
this if you're interested in this camera
18:40
maybe for astronomy or something and
18:42
happy to sort of take the risk of it may
18:44
not be uh perfect I'll um I think I'll
18:47
stick this on eBay along with the
18:48
Illuminator I'll put a link down in the
18:50
description to the listing take your
18:52
chances to grab a bargain so for example
18:54
here we see this vertical streaking so
18:56
I'm not sure how normal that is this is
18:58
on fairly bright scene looking out the
19:02
window if I cut the exposure time down
19:04
on that it's now 1 second
19:07
exposure again most of the image
19:09
disappears again this is looks like it's
19:11
possibly over still overloading here go
19:14
that go down to say say quarter a
19:16
second so again I think there might be
19:19
some Auto gain control going on here um
19:21
this is with the PFG option let's try
19:23
turning that off and see what
19:25
happens so I'm not sure this is actually
19:27
more streaking or which just it's
19:29
cranked up the gain all the dis display
19:31
gray scale to show what um you know the
19:33
range of things that it's captured
19:36
there's one of one of 12 things in the
19:38
software there's um you can see of you
19:40
can't seem to read out the temperature
19:42
of the pelta cooler but you can set the
19:44
temperature and if you said it's a
19:46
different temperature you see the power
19:48
consumption jump up running the cooler
19:50
to get the temperature you requested but
19:52
I can't see anything anywhere that tells
19:54
you whether the cool is at the at the
19:56
temperature other than the power
19:57
consumption going down and there's no
19:59
temperature read out
20:03
here and just some yeah this is just
20:05
sort of very basic software I'm sure
20:07
there's like an API for more
20:09
sophisticated
20:10
applications but so if you know anything
20:12
more about these cameras please um stick
20:14
in the
20:15
comments um incidentally when I was
20:18
editing I didn't notice there was a bent
20:19
pin on the um CCD but I did fix that
20:22
before doing these tests and also
20:24
reactivated the um silica gel desicant
20:26
cuz I noticed it was uh I was getting
20:28
bit of condensation on the window but um
20:31
yeah so a couple of uh interesting but
20:34
maybe not particularly uh useful pieces
20:37
of Kit except for someone that's got a
20:38
very specific use so um I'll stick a
20:42
I'll stick these on eBay put a link in
20:44
the description and say hopefully
20:45
someone could actually make some uh good
20:47
use of these things
Example Output:
**Abstract:**

This video presents Part 2 of a teardown focusing on the optical components of a Fluidigm Polaris biotechnology instrument, specifically the multi-wavelength illuminator and the high-resolution CCD camera.

The Lumen Dynamics illuminator unit is examined in detail, revealing its construction using multiple high-power LEDs (430nm, 475nm, 520nm, 575nm, 630nm) combined via dichroic mirrors and filters. A square fiber optic rod is used to homogenize the light. A notable finding is the use of a phosphor-converted white LED filtered to achieve the 575nm output. The unit features simple TTL activation for each color, conduction cooling, and internal homogenization optics. Analysis of its EEPROM suggests extremely low operational runtime.

The camera module teardown showcases a 50 Megapixel ON Semiconductor KAF-50100 CCD sensor with micro-lenses, cooled by a multi-stage Peltier stack. The control electronics include an FPGA and a USB interface. Significant post-manufacturing modifications ("bodges") are observed on the camera's circuit boards. Basic functional testing using vendor software and a pinhole lens confirms image capture but reveals prominent vertical streaking artifacts, the cause of which remains uncertain (potential overload, readout artifact, or fault).

**Exploring the Fluidigm Polaris: A Detailed Look at its High-End Optics and Camera System**

* **0:00 High-End Optics:** The system utilizes heavy, high-quality lenses and mirrors for precise imaging, weighing around 4 kilos each.
* **0:49 Narrow Band Filters:** A filter wheel with five narrow band filters (488, 525, 570, 630, and 700 nm) ensures accurate fluorescence detection and rejection of excitation light. 
* **2:01 Customizable Illumination:** The Lumen Dynamics light source offers five individually controllable LED wavelengths (430, 475, 520, 575, 630 nm) with varying power outputs. The 575nm yellow LED is uniquely achieved using a white LED with filtering.
* **3:45 TTL Control:**  The light source is controlled via a simple TTL interface, enabling easy on/off switching for each LED color.
* **12:55 Sophisticated Camera:**  The system includes a 50-megapixel Kodak KAI-50100 CCD camera with a Peltier cooling system for reduced noise.
* **14:54 High-Speed Data Transfer:** The camera features dual analog-to-digital converters to manage the high data throughput of the 50-megapixel sensor, which is effectively two 25-megapixel sensors operating in parallel.
* **18:11 Possible Issues:** The video creator noted some potential issues with the camera, including image smearing. 
* **18:11 Limited Dynamic Range:** The camera's sensor has a limited dynamic range, making it potentially challenging to capture scenes with a wide range of brightness levels.
* **11:45 Low Runtime:** Internal data suggests the system has seen minimal usage, with only 20 minutes of recorded runtime for the green LED.
* **20:38 Availability on eBay:** Both the illuminator and camera are expected to be listed for sale on eBay.

Here is the real transcript. Please summarize it: 
00:00:08 two clocks are functioning and locked,  
00:00:14 we have lots of beam current on both.
00:00:17 and they hover about a few nanoseconds.  
00:00:22 see if it can maintain that measurement.
00:00:32 Hello and welcome back. If you follow the channel,  
00:00:34 clock. The goal is to compare two atomic clocks,  
00:00:41 theory of relativity for ourselves.
00:00:46 Hafele and Keating experiments of 1971,  
00:00:51 of time dilation as predicted by  
00:00:55 HP 5061A clocks around the world.
00:01:02 check that our tired eBay clocks still  
00:01:06 when next to each other, at rest in the lab.
00:01:13 to measure a shift of about 20  
00:01:16 at elevated altitude over a few days,  
00:01:22 original experiment. So our two clocks  
00:01:28 few days to give us a fighting chance.
00:01:33 in the series, one of the clocks failed,  
00:01:38 about to measure it. Fortunately,  
00:01:43 we think, so let's try this measurement again.
00:01:50 But first, let's look at the measurement setup.
00:01:56 clocks, which is man's worst nightmare. Which  
00:02:02 answer is neither, and all we can do is  
00:02:08 us an idea of their ultimate stability.
00:02:13 and Keating's clocks were equipped with  
00:02:19 generated a sharp tick every second,  
00:02:24 clock face on the front panel. Unfortunately,  
00:02:30 Ours are merely frequency standards:  
00:02:35 signals at 5 MHz, 1 MHz and 100 kHz.
00:02:43 two HP 59308A Timing Generators. We'll  
00:02:50 atomic clock, and do the same with the  
00:02:55 programmable digital dividers. We'll set  
00:03:01 microseconds, representing each of the clocks.
00:03:09 we can observe on a scope. The interval between  
00:03:15 will depend on when the dividers randomly started.
00:03:22 constant, atomically stable.  
00:03:26 measure any changes on the scope itself.
00:03:31 pulses, we'll use an HP 5334B counter instead.  
00:03:39 measuring the interval from the first tick to  
00:03:45 function, we can zero out the mean delay,  
00:03:52 give us a resolution of 0.1 nanoseconds. Hopefully  
00:03:59   
00:04:04 we will also slave it to one of the atomic  
00:04:09 counter can only take a 10 MHz reference input,  
00:04:17 MHz output. Not to worry! We'll use  
00:04:23 restored and upgraded in a previous episode,  
00:04:30 its newly installed frequency doubler option,  
00:04:36 the resulting 10 MHz for the counter reference.
00:04:44 our previous HP restoration efforts pay off,  
00:04:49 equipment that works. Let's measure atomic time!
00:04:56 other Time Nuts in the comments,  
00:05:00 characterize the frequency stability  
00:05:04 Variance or its modified alternatives.
00:05:10 but in essence, this is the variance of the  
00:05:16 It's a statistical measure of the likely clock  
00:05:22 being a day in our case. It is expressed in  
00:05:29 so it's a dimensionless quantity. A day being  
00:05:35 to the 13th nanoseconds, if we targeted a  
00:05:43 we'd want a clock with Allan variance of about  
00:05:51 plots provided by HP, that is stretching what our  
00:05:59 It should be within the reach of an HP 5061A  
00:06:07 what a standard tube can do. Plus now, we have  
00:06:14 know it's going to be dicey. But we'll try anyhow.
00:06:21 our pile of HP measurement instruments.
00:06:28 repaired clock B on the right,  
00:06:31 nanoseconds difference between each other.
00:06:36 see if it stays there. If that's the case,  
00:06:41 relativity for ourselves.
00:06:46 I'm not too sure about that, we'll see...
00:06:49 (The next morning...)
00:06:52 experiment half succeeded and half failed.
00:07:00 locked. They are both on green,  
00:07:06 would unlock before the repair.
00:07:11 They drifted 34, 35 nanoseconds,  
00:07:22 a short duration experiment.
00:07:29 200 nanoseconds. But in our experiment,  
00:07:36 around the world in opposite directions.
00:07:40 which will be less than minus 34 nanoseconds.
00:07:48 not warm enough, maybe something happened.
00:07:52 So I'm going to restart it.
00:08:00 So right now they, are 598 apart.
00:08:06 So I'll enter this, 598...
00:08:12 Minus 9... Enter... Enter...
00:08:27 let it run for another day.
00:08:31 (The following day...)
00:08:33 and I have invited Einstein to the party,  
00:08:39 it's only about 6.7 nanoseconds of drift.
00:08:51 but much better than what we had before.
00:08:58 And what I have done is,  
00:08:59 same direction, and always the same value.
00:09:05 the clocks, so that both match.
00:09:11 graduation, or half a graduation of the  
00:09:17 is already a fine fine fine pot over here.
00:09:25 time is atomic time and that is it,  
00:09:30 seen in the Zeeman alignment episode,  
00:09:36 atomic line frequency due to the magnetic field,  
00:09:42 Zeeman and that bears his name to this day. Here  
00:09:48 way. Therefore, there is quite an elaborate  
00:09:54 in the Cesium tube, known as the C-Field,  
00:10:00 here, we are pushing the clocks to their limits,  
00:10:06 to put the clocks right on top of each other.
00:10:12 experiment, they didn't even bother with that.  
00:10:16 to each other. But they characterized  
00:10:21 much larger national metrology lab master clock.
00:10:29 [Marc] It's moving to this left.
00:10:30 [Eric] Yeah.
00:10:31 adjust the results afterwards. And by the way,  
00:10:36 Yes, they flew not just one, but 4 clocks.
00:10:42 to a better master clock,  
00:10:45 clocks are not drifting vs. each other  
00:10:49 stability directly from this simple experiment.
00:10:56 clocks to more or less track each other,  
00:11:00 over long periods of time,  
00:11:04 a little bit more of HP equipment.
00:11:08 7132A as our chart recorder. It can record for  
00:11:16 analog instrument, so we'll need the HP  
00:11:21 conveniently repaired two episodes ago. We'll  
00:11:29 good measure, we'll also add an HP 3478A DVM,  
00:11:37 course, to monitor the DAC output voltage.
00:11:43 to serve as our HP-IB controller. It will  
00:11:50 send it over to the DAC over the HP-IB bus.
00:11:56 a simple BASIC program, and our  
00:11:59 100% vintage HP metrology setup is good to go.
00:12:03 by the minute, or the nanosecond here.
00:12:09 newest of my oldest computers.
00:12:15 the nanosecond tracking of the two clocks.
00:12:27 is 14 lines of vintage BASIC - no OS to load,  
00:12:33 no drivers, no version of Python to check,  
00:12:36 all this natively, out of the box.
00:12:43 just realized we don't use anywhere,  
00:12:47 so make this 13 lines of BASIC.
00:12:50 bus, in case we get stuck for more  
00:12:55 500 and clear the bus and start again.
00:13:00 from the counter at address 703.
00:13:05 Line 40 scales it to get rid of the exponent,  
00:13:08 around 500, so it fits our DAC scale.
00:13:15 the valid DAC values, from 0 to 999.
00:13:23 line towards the bottom of the screen,  
00:13:28 so we can check it's doing the right thing.
00:13:31 to the DAC at address 706,  
00:13:36 preceded by a 2 to indicate the -10 to +10V range.
00:13:41 And that's pretty much it.
00:13:42 a voltage out of it, changes that into a  
00:13:49 A transforms it into a real voltage,  
00:13:58 recorder, so we can follow the trends.
00:14:04 one direction, or if it's getting big skips.
00:14:10 (The next morning...)
00:14:12 great. We have drifted almost 14 nanosecond.
00:14:20 And not only there is drift, but the way it  
00:14:23 here. I have this big jumps.
00:14:32 there's one there, there's some here,  
00:14:39 is not going to get us there.
00:14:44 is going all over the place, and even jumps,  
00:14:50 strongly suspect that it's just one of the clocks,  
00:14:56 are more atomic gremlins hiding in that one.
00:15:03 However, there is one piece of really good news.  
00:15:05 of vintage HP equipment, works perfectly.
00:15:11 We just need more work before we can check on  
00:15:16 more atomic clock repairs in our near future.

Copy Summary Copy Prompt

identifier: 2105

model: gemini-2.5-pro-exp-03-25| input-price: 1.25 output-price: 10.0 max-context-length: 128_000

host: 194.230.160.66

https://youtu.be/ENviIxDTmUA?feature=shared

include_comments: None

include_timestamps: 1

include_glossary: None

output_language: en

cost: 0.09736

Okay, here is the abstract and summary for the provided transcript featuring Chris Lattner discussing Mojo.

*Abstract:*

This interview features Chris Lattner, creator of Swift, LLVM, Clang, and the Mojo programming language. Lattner discusses the motivations behind creating Mojo: primarily to address performance challenges in AI/ML and effectively utilize modern hardware like GPUs and accelerators, while integrating seamlessly with the existing Python ecosystem. He contrasts Mojo's approach ("Python++" superset focusing on adding capabilities) with attempts to simply optimize existing Python code, emphasizing Mojo's design philosophy of providing explicit control and predictability for performance-critical tasks via features like structs, static typing (`fn` functions), and first-class SIMD support. The discussion covers lessons learned from Swift's design, particularly regarding type system complexity and operator overloading. Lattner details Mojo's use of MLIR alongside LLVM for its compiler infrastructure, enabling advanced optimizations and features like compile-time metaprogramming. He also touches upon specific design choices around numeric types (including SIMD and integer overflow behavior) and memory management, positioning Mojo as a systems language that empowers library developers and provides flexibility for different programmer personas.

*Mojo Language Design and Philosophy with Chris Lattner*

*   *0:00:47 Why Create Mojo?* Mojo wasn't the initial goal of Modular. It emerged from the need to program next-generation hardware (GPUs, accelerators) effectively, leveraging the MLIR compiler framework, and requiring a user-friendly syntax, leading them to build upon Python.
*   *0:01:21 Learning from Swift:* Creating a new language syntax is complex and time-consuming. Mojo prioritizes powerful semantics, compiler infrastructure for performance, and meeting the large existing Python community where they are.
*   *0:03:55 Python Implementation Limitations:* CPython interpreter isn't very fast, lacks modern compiler techniques, has packaging challenges, and fundamentally cannot target GPUs or embedded systems requiring minimal dependencies.
*   *0:04:56 Importance of API Design:* Good API design is crucial, including what it *disallows*. Swift's string API (bytes vs. grapheme clusters) is praised for simplifying by removing confusing concepts. The goal is to make safe defaults easy to reach for.
*   *0:09:29 Mojo as "Python++":* Aims to be a superset of Python over time, allowing use of the existing ecosystem. It adds new capabilities (like `struct` for value types) alongside Python's features (`class`). The goal is to allow gradual adoption and upgrading of Python code, potentially replacing complex Python+C extensions with pure Mojo.
*   *0:17:48 Against Magic Optimization:* Mojo deliberately avoids trying to magically speed up unmodified Python code. Such approaches (like PyPy, Codon) create unpredictable performance cliffs and reduce programmer control. Mojo instead provides explicit tools (types, structs, `fn`) to unlock performance, working backward from hardware capabilities.
*   *0:25:09 Compiler Strategy (MLIR + LLVM):* Mojo uses MLIR for high-level, parallelizable optimizations (like its own inliner) and selectively uses LLVM for backend code generation, disabling parts like LLVM's auto-vectorizer to ensure predictability.
*   *0:28:15 Balancing Control and Dynamism:* Mojo offers `def` for Python-like dynamic behavior (defaulting to object types) and `fn` for systems programming requiring explicit types and offering more control and performance predictability. This caters to different user needs within one language.
*   *0:39:03 Compile-Time Metaprogramming:* Inspired by languages like Zig, Mojo uses the same language for compile-time and runtime code, simplifying macros, templates, etc., enabling powerful library abstractions.
*   *0:39:41 First-Class SIMD:* Mojo treats SIMD types as fundamental, defined in the standard library using compile-time parameters for element type and width. Scalar types (like `Float32`) are defined as single-element SIMD vectors (`SIMD<Float32, 1>`), allowing numeric libraries (like `sin`, `cos`) to be written generically for both scalars and vectors.
*   *0:43:47 Hardware Abstraction:* Low-level hardware intrinsics (Neon, AVX, etc.) are exposed. Libraries can use compile-time checks (`if target == ...`) to use specific hardware features, abstracting hardware differences away from the end-user. Mojo pushes complexity from the compiler into libraries.
*   *0:52:51 Functional Programming Influence & Mutation:* Mojo embraces value semantics (like Swift) to prevent spooky action at a distance but allows efficient in-place mutation where appropriate (e.g., via copy-on-write or explicit unsafe code in library internals), unlike pure functional languages that can suffer performance penalties.
*   *1:02:42 Integer Overflow Handling:* Mojo consistently uses wrapping (two's complement) semantics for integer overflow for both signed and unsigned types. This differs from C++ (UB for signed) and Swift (traps by default) but is necessary for SIMD performance and predictability. It distinguishes between Python's arbitrary-precision `int` (heap object) and Mojo's fixed-width `Int` (struct, fast).
*   *1:13:35 Type Inference Approach:* Mojo avoids complex Hindley-Milner type inference (which caused issues in Swift due to interaction with overloading, literals, etc.). It uses a simpler, more localized type checking approach consistent with Python's dynamic feel, aiming for predictable compile times and clear error messages. Function signatures are generally required for `fn` functions.
*   *1:29:11 Operator Overloading Strategy:* Mojo currently allows overloading existing Python operators via Dunder methods (`__add__`, etc.). It avoids adding custom operators (like Swift did) to keep the language simpler initially, recognizing that the complexity might not pay for itself. This allows libraries to define numeric types (like `Complex`, `BFloat16`) without needing compiler changes.
*   *1:38:50 Complex Numbers & Hardware:* While Mojo doesn't privilege complex numbers, its library-centric design and compile-time features allow a `Complex` type's multiply operator to internally check the target hardware and use specialized instructions (if available on platforms like IBM mainframes) for acceleration.
*   *1:41:37 Arbitrary Bitwidth Integers:* MLIR supports arbitrary bitwidths. While not exposed in Mojo's standard library *yet*, it could be added purely as a library feature without compiler changes.
*   *1:43:43 Allocator Philosophy:* Mojo currently doesn't have a pervasive allocator parameter system like Zig. Instead, it focuses on providing different *types* with different allocation strategies (e.g., a `List` type potentially taking a parameter for inline storage like `SmallVector`) rather than making allocators a universal generic parameter.
*   *1:47:32 Slices and Ownership:* Mojo has an ownership system, allowing efficient, safe slices that refer back to the original data structure's lifetime, often using copy-on-write semantics.
*   *1:48:23 Community and Status:* Mojo is still early but has an active community on Discord. It's being used for various applications beyond AI, including web development and GUIs. Users are encouraged to explore the documentation and get involved.

I used gemini-2.5-pro-exp-03-25| input-price: 1.25 output-price: 10.0 max-context-length: 128_000 on rocketrecap dot com to summarize the transcript.
Cost (if I didn't use the free tier): $0.10
Input tokens: 65072
Output tokens: 1602

Okay, here is the abstract and summary for the provided transcript featuring Chris Lattner discussing Mojo.

Abstract:

This interview features Chris Lattner, creator of Swift, LLVM, Clang, and the Mojo programming language. Lattner discusses the motivations behind creating Mojo: primarily to address performance challenges in AI/ML and effectively utilize modern hardware like GPUs and accelerators, while integrating seamlessly with the existing Python ecosystem. He contrasts Mojo's approach ("Python++" superset focusing on adding capabilities) with attempts to simply optimize existing Python code, emphasizing Mojo's design philosophy of providing explicit control and predictability for performance-critical tasks via features like structs, static typing (fn functions), and first-class SIMD support. The discussion covers lessons learned from Swift's design, particularly regarding type system complexity and operator overloading. Lattner details Mojo's use of MLIR alongside LLVM for its compiler infrastructure, enabling advanced optimizations and features like compile-time metaprogramming. He also touches upon specific design choices around numeric types (including SIMD and integer overflow behavior) and memory management, positioning Mojo as a systems language that empowers library developers and provides flexibility for different programmer personas.

Mojo Language Design and Philosophy with Chris Lattner

• 0:00:47 Why Create Mojo? Mojo wasn't the initial goal of Modular. It emerged from the need to program next-generation hardware (GPUs, accelerators) effectively, leveraging the MLIR compiler framework, and requiring a user-friendly syntax, leading them to build upon Python.
• 0:01:21 Learning from Swift: Creating a new language syntax is complex and time-consuming. Mojo prioritizes powerful semantics, compiler infrastructure for performance, and meeting the large existing Python community where they are.
• 0:03:55 Python Implementation Limitations: CPython interpreter isn't very fast, lacks modern compiler techniques, has packaging challenges, and fundamentally cannot target GPUs or embedded systems requiring minimal dependencies.
• 0:04:56 Importance of API Design: Good API design is crucial, including what it disallows. Swift's string API (bytes vs. grapheme clusters) is praised for simplifying by removing confusing concepts. The goal is to make safe defaults easy to reach for.
• 0:09:29 Mojo as "Python++": Aims to be a superset of Python over time, allowing use of the existing ecosystem. It adds new capabilities (like struct for value types) alongside Python's features (class). The goal is to allow gradual adoption and upgrading of Python code, potentially replacing complex Python+C extensions with pure Mojo.
• 0:17:48 Against Magic Optimization: Mojo deliberately avoids trying to magically speed up unmodified Python code. Such approaches (like PyPy, Codon) create unpredictable performance cliffs and reduce programmer control. Mojo instead provides explicit tools (types, structs, fn) to unlock performance, working backward from hardware capabilities.
• 0:25:09 Compiler Strategy (MLIR + LLVM): Mojo uses MLIR for high-level, parallelizable optimizations (like its own inliner) and selectively uses LLVM for backend code generation, disabling parts like LLVM's auto-vectorizer to ensure predictability.
• 0:28:15 Balancing Control and Dynamism: Mojo offers def for Python-like dynamic behavior (defaulting to object types) and fn for systems programming requiring explicit types and offering more control and performance predictability. This caters to different user needs within one language.
• 0:39:03 Compile-Time Metaprogramming: Inspired by languages like Zig, Mojo uses the same language for compile-time and runtime code, simplifying macros, templates, etc., enabling powerful library abstractions.
• 0:39:41 First-Class SIMD: Mojo treats SIMD types as fundamental, defined in the standard library using compile-time parameters for element type and width. Scalar types (like Float32) are defined as single-element SIMD vectors (SIMD<Float32, 1>), allowing numeric libraries (like sin, cos) to be written generically for both scalars and vectors.
• 0:43:47 Hardware Abstraction: Low-level hardware intrinsics (Neon, AVX, etc.) are exposed. Libraries can use compile-time checks (if target == ...) to use specific hardware features, abstracting hardware differences away from the end-user. Mojo pushes complexity from the compiler into libraries.
• 0:52:51 Functional Programming Influence & Mutation: Mojo embraces value semantics (like Swift) to prevent spooky action at a distance but allows efficient in-place mutation where appropriate (e.g., via copy-on-write or explicit unsafe code in library internals), unlike pure functional languages that can suffer performance penalties.
• 1:02:42 Integer Overflow Handling: Mojo consistently uses wrapping (two's complement) semantics for integer overflow for both signed and unsigned types. This differs from C++ (UB for signed) and Swift (traps by default) but is necessary for SIMD performance and predictability. It distinguishes between Python's arbitrary-precision int (heap object) and Mojo's fixed-width Int (struct, fast).
• 1:13:35 Type Inference Approach: Mojo avoids complex Hindley-Milner type inference (which caused issues in Swift due to interaction with overloading, literals, etc.). It uses a simpler, more localized type checking approach consistent with Python's dynamic feel, aiming for predictable compile times and clear error messages. Function signatures are generally required for fn functions.
• 1:29:11 Operator Overloading Strategy: Mojo currently allows overloading existing Python operators via Dunder methods (__add__, etc.). It avoids adding custom operators (like Swift did) to keep the language simpler initially, recognizing that the complexity might not pay for itself. This allows libraries to define numeric types (like Complex, BFloat16) without needing compiler changes.
• 1:38:50 Complex Numbers & Hardware: While Mojo doesn't privilege complex numbers, its library-centric design and compile-time features allow a Complex type's multiply operator to internally check the target hardware and use specialized instructions (if available on platforms like IBM mainframes) for acceleration.
• 1:41:37 Arbitrary Bitwidth Integers: MLIR supports arbitrary bitwidths. While not exposed in Mojo's standard library yet, it could be added purely as a library feature without compiler changes.
• 1:43:43 Allocator Philosophy: Mojo currently doesn't have a pervasive allocator parameter system like Zig. Instead, it focuses on providing different types with different allocation strategies (e.g., a List type potentially taking a parameter for inline storage like SmallVector) rather than making allocators a universal generic parameter.
• 1:47:32 Slices and Ownership: Mojo has an ownership system, allowing efficient, safe slices that refer back to the original data structure's lifetime, often using copy-on-write semantics.
• 1:48:23 Community and Status: Mojo is still early but has an active community on Discord. It's being used for various applications beyond AI, including web development and GUIs. Users are encouraged to explore the documentation and get involved.

Below, I will provide input for an example video (comprising of title, description, and transcript, in this order) and the corresponding abstract and summary I expect. Afterward, I will provide a new transcript that I want you to summarize in the same format. 

**Please give an abstract of the transcript and then summarize the transcript in a self-contained bullet list format.** Include starting timestamps, important details and key takeaways. 

Example Input: 
Fluidigm Polaris Part 2- illuminator and camera
mikeselectricstuff
131K subscribers
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5,857 views Aug 26, 2024
Fluidigm Polaris part 1 : • Fluidigm Polaris (Part 1) - Biotech g...
Ebay listings: https://www.ebay.co.uk/usr/mikeselect...
Merch https://mikeselectricstuff.creator-sp...
Transcript
Follow along using the transcript.
Show transcript
mikeselectricstuff
131K subscribers
Videos
About
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40 Comments
@robertwatsonbath
6 hours ago
Thanks Mike. Ooof! - with the level of bodgery going on around 15:48 I think shame would have made me do a board re spin, out of my own pocket if I had to.
1
Reply
@Muonium1
9 hours ago
The green LED looks different from the others and uses phosphor conversion because of the "green gap" problem where green InGaN emitters suffer efficiency droop at high currents. Phosphide based emitters don't start becoming efficient until around 600nm so also can't be used for high power green emitters. See the paper and plot by Matthias Auf der Maur in his 2015 paper on alloy fluctuations in InGaN as the cause of reduced external quantum efficiency at longer (green) wavelengths.
4
Reply
1 reply
@tafsirnahian669
10 hours ago (edited)
Can this be used as an astrophotography camera?
Reply
mikeselectricstuff
·
1 reply
@mikeselectricstuff
6 hours ago
Yes, but may need a shutter to avoid light during readout
Reply
@2010craggy
11 hours ago
Narrowband filters we use in Astronomy (Astrophotography) are sided- they work best passing light in one direction so I guess the arrows on the filter frames indicate which way round to install them in the filter wheel.
1
Reply
@vitukz
12 hours ago
A mate with Channel @extractions&ire could use it
2
Reply
@RobertGallop
19 hours ago
That LED module says it can go up to 28 amps!!! 21 amps for 100%. You should see what it does at 20 amps!
Reply
@Prophes0r
19 hours ago
I had an "Oh SHIT!" moment when I realized that the weird trapezoidal shape of that light guide was for keystone correction of the light source.
Very clever.
6
Reply
@OneBiOzZ
20 hours ago
given the cost of the CCD you think they could have run another PCB for it
9
Reply
@tekvax01
21 hours ago
$20 thousand dollars per minute of run time!
1
Reply
@tekvax01
22 hours ago
"We spared no expense!" John Hammond Jurassic Park.
*(that's why this thing costs the same as a 50-seat Greyhound Bus coach!)
Reply
@florianf4257
22 hours ago
The smearing on the image could be due to the fact that you don't use a shutter, so you see brighter stripes under bright areas of the image as you still iluminate these pixels while the sensor data ist shifted out towards the top. I experienced this effect back at university with a LN-Cooled CCD for Spectroscopy. The stripes disapeared as soon as you used the shutter instead of disabling it in the open position (but fokussing at 100ms integration time and continuous readout with a focal plane shutter isn't much fun).
12
Reply
mikeselectricstuff
·
1 reply
@mikeselectricstuff
12 hours ago
I didn't think of that, but makes sense
2
Reply
@douro20
22 hours ago (edited)
The red LED reminds me of one from Roithner Lasertechnik. I have a Symbol 2D scanner which uses two very bright LEDs from that company, one red and one red-orange. The red-orange is behind a lens which focuses it into an extremely narrow beam.
1
Reply
@RicoElectrico
23 hours ago
PFG is Pulse Flush Gate according to the datasheet.
Reply
@dcallan812
23 hours ago
Very interesting. 2x
Reply
@littleboot_
1 day ago
Cool interesting device
Reply
@dav1dbone
1 day ago
I've stripped large projectors, looks similar, wonder if some of those castings are a magnesium alloy?
Reply
@kevywevvy8833
1 day ago
ironic that some of those Phlatlight modules are used in some of the cheapest disco lights.
1
Reply
1 reply
@bill6255
1 day ago
Great vid - gets right into subject in title, its packed with information, wraps up quickly. Should get a YT award! imho
3
Reply
@JAKOB1977
1 day ago (edited)
The whole sensor module incl. a 5 grand 50mpix sensor for 49 £.. highest bid atm
Though also a limited CCD sensor, but for the right buyer its a steal at these relative low sums.
Architecture Full Frame CCD (Square Pixels)
Total Number of Pixels 8304 (H) × 6220 (V) = 51.6 Mp
Number of Effective Pixels 8208 (H) × 6164 (V) = 50.5 Mp
Number of Active Pixels 8176 (H) × 6132 (V) = 50.1 Mp
Pixel Size 6.0 m (H) × 6.0 m (V)
Active Image Size 49.1 mm (H) × 36.8 mm (V)
61.3 mm (Diagonal),
645 1.1x Optical Format
Aspect Ratio 4:3
Horizontal Outputs 4
Saturation Signal 40.3 ke−
Output Sensitivity 31 V/e−
Quantum Efficiency
KAF−50100−CAA
KAF−50100−AAA
KAF−50100−ABA (with Lens)
22%, 22%, 16% (Peak R, G, B)
25%
62%
Read Noise (f = 18 MHz) 12.5 e−
Dark Signal (T = 60°C) 42 pA/cm2
Dark Current Doubling Temperature 5.7°C
Dynamic Range (f = 18 MHz) 70.2 dB
Estimated Linear Dynamic Range
(f = 18 MHz)
69.3 dB
Charge Transfer Efficiency
Horizontal
Vertical
0.999995
0.999999
Blooming Protection
(4 ms Exposure Time)
800X Saturation Exposure
Maximum Date Rate 18 MHz
Package Ceramic PGA
Cover Glass MAR Coated, 2 Sides or
Clear Glass
Features
• TRUESENSE Transparent Gate Electrode
for High Sensitivity
• Ultra-High Resolution
• Board Dynamic Range
• Low Noise Architecture
• Large Active Imaging Area
Applications
• Digitization
• Mapping/Aerial
• Photography
• Scientific
Thx for the tear down Mike, always a joy
Reply
@martinalooksatthings
1 day ago
15:49 that is some great bodging on of caps, they really didn't want to respin that PCB huh
8
Reply
@RhythmGamer
1 day ago
Was depressed today and then a new mike video dropped and now I’m genuinely happy to get my tear down fix
1
Reply
@dine9093
1 day ago (edited)
Did you transfrom into Mr Blobby for a moment there?
2
Reply
@NickNorton
1 day ago
Thanks Mike. Your videos are always interesting.
5
Reply
@KeritechElectronics
1 day ago
Heavy optics indeed... Spare no expense, cost no object. Splendid build quality. The CCD is a thing of beauty!
1
Reply
@YSoreil
1 day ago
The pricing on that sensor is about right, I looked in to these many years ago when they were still in production since it's the only large sensor you could actually buy. Really cool to see one in the wild.
2
Reply
@snik2pl
1 day ago
That leds look like from led projector
Reply
@vincei4252
1 day ago
TDI = Time Domain Integration ?
1
Reply
@wolpumba4099
1 day ago (edited)
Maybe the camera should not be illuminated during readout.
From the datasheet of the sensor (Onsemi): saturation 40300 electrons, read noise 12.5 electrons per pixel @ 18MHz (quite bad). quantum efficiency 62% (if it has micro lenses), frame rate 1 Hz. lateral overflow drain to prevent blooming protects against 800x (factor increases linearly with exposure time) saturation exposure (32e6 electrons per pixel at 4ms exposure time), microlens has +/- 20 degree acceptance angle
i guess it would be good for astrophotography
4
Reply
@txm100
1 day ago (edited)
Babe wake up a new mikeselectricstuff has dropped!
9
Reply
@vincei4252
1 day ago
That looks like a finger-lakes filter wheel, however, for astronomy they'd never use such a large stepper.
1
Reply
@MRooodddvvv
1 day ago
yaaaaay ! more overcomplicated optical stuff !
4
Reply
1 reply
@NoPegs
1 day ago
He lives!
11
Reply
1 reply
Transcript
0:00
so I've stripped all the bits of the
0:01
optical system so basically we've got
0:03
the uh the camera
0:05
itself which is mounted on this uh very
0:09
complex
0:10
adjustment thing which obviously to set
0:13
you the various tilt and uh alignment
0:15
stuff then there's two of these massive
0:18
lenses I've taken one of these apart I
0:20
think there's something like about eight
0:22
or nine Optical elements in here these
0:25
don't seem to do a great deal in terms
0:26
of electr magnification they're obiously
0:28
just about getting the image to where it
0:29
uh where it needs to be just so that
0:33
goes like that then this Optical block I
0:36
originally thought this was made of some
0:37
s crazy heavy material but it's just
0:39
really the sum of all these Optical bits
0:41
are just ridiculously heavy those lenses
0:43
are about 4 kilos each and then there's
0:45
this very heavy very solid um piece that
0:47
goes in the middle and this is so this
0:49
is the filter wheel assembly with a
0:51
hilariously oversized steper
0:53
motor driving this wheel with these very
0:57
large narrow band filters so we've got
1:00
various different shades of uh
1:03
filters there five Al together that
1:06
one's actually just showing up a silver
1:07
that's actually a a red but fairly low
1:10
transmission orangey red blue green
1:15
there's an excess cover on this side so
1:16
the filters can be accessed and changed
1:19
without taking anything else apart even
1:21
this is like ridiculous it's like solid
1:23
aluminium this is just basically a cover
1:25
the actual wavelengths of these are um
1:27
488 525 570 630 and 700 NM not sure what
1:32
the suffix on that perhaps that's the uh
1:34
the width of the spectral line say these
1:37
are very narrow band filters most of
1:39
them are you very little light through
1:41
so it's still very tight narrow band to
1:43
match the um fluoresence of the dies
1:45
they're using in the biochemical process
1:48
and obviously to reject the light that's
1:49
being fired at it from that Illuminator
1:51
box and then there's a there's a second
1:53
one of these lenses then the actual sort
1:55
of samples below that so uh very serious
1:58
amount of very uh chunky heavy Optics
2:01
okay let's take a look at this light
2:02
source made by company Lumen Dynamics
2:04
who are now part of
2:06
excelitas self-contained unit power
2:08
connector USB and this which one of the
2:11
Cable Bundle said was a TTL interface
2:14
USB wasn't used in uh the fluid
2:17
application output here and I think this
2:19
is an input for um light feedback I
2:21
don't if it's regulated or just a measur
2:23
measurement facility and the uh fiber
2:27
assembly
2:29
Square Inlet there and then there's two
2:32
outputs which have uh lens assemblies
2:35
and this small one which goes back into
2:37
that small Port just Loops out of here
2:40
straight back in So on this side we've
2:42
got the electronics which look pretty
2:44
straightforward we've got a bit of power
2:45
supply stuff over here and we've got
2:48
separate drivers for each wavelength now
2:50
interesting this is clearly been very
2:52
specifically made for this application
2:54
you I was half expecting like say some
2:56
generic drivers that could be used for a
2:58
number of different things but actually
3:00
literally specified the exact wavelength
3:02
on the PCB there is provision here for
3:04
385 NM which isn't populated but this is
3:07
clearly been designed very specifically
3:09
so these four drivers look the same but
3:10
then there's two higher power ones for
3:12
575 and
3:14
520 a slightly bigger heat sink on this
3:16
575 section there a p 24 which is
3:20
providing USB interface USB isolator the
3:23
USB interface just presents as a comport
3:26
I did have a quick look but I didn't
3:27
actually get anything sensible um I did
3:29
dump the Pi code out and there's a few
3:31
you a few sort of commands that you
3:32
could see in text but I didn't actually
3:34
manage to get it working properly I
3:36
found some software for related version
3:38
but it didn't seem to want to talk to it
3:39
but um I say that wasn't used for the
3:41
original application it might be quite
3:42
interesting to get try and get the Run
3:44
hours count out of it and the TTL
3:46
interface looks fairly straightforward
3:48
we've got positions for six opto
3:50
isolators but only five five are
3:52
installed so that corresponds with the
3:54
unused thing so I think this hopefully
3:56
should be as simple as just providing a
3:57
ttrl signal for each color to uh enable
4:00
it a big heat sink here which is there I
4:03
think there's like a big S of metal
4:04
plate through the middle of this that
4:05
all the leads are mounted on the other
4:07
side so this is heat sinking it with a
4:09
air flow from a uh just a fan in here
4:13
obviously don't have the air flow
4:14
anywhere near the Optics so conduction
4:17
cool through to this plate that's then
4:18
uh air cooled got some pots which are
4:21
presumably power
4:22
adjustments okay let's take a look at
4:24
the other side which is uh much more
4:27
interesting see we've got some uh very
4:31
uh neatly Twisted cable assemblies there
4:35
a bunch of leads so we've got one here
4:37
475 up here 430 NM 630 575 and 520
4:44
filters and dcro mirrors a quick way to
4:48
see what's white is if we just shine
4:49
some white light through
4:51
here not sure how it is is to see on the
4:54
camera but shining white light we do
4:55
actually get a bit of red a bit of blue
4:57
some yellow here so the obstacle path
5:00
575 it goes sort of here bounces off
5:03
this mirror and goes out the 520 goes
5:07
sort of down here across here and up
5:09
there 630 goes basically straight
5:13
through
5:15
430 goes across there down there along
5:17
there and the 475 goes down here and
5:20
left this is the light sensing thing
5:22
think here there's just a um I think
5:24
there a photo diode or other sensor
5:26
haven't actually taken that off and
5:28
everything's fixed down to this chunk of
5:31
aluminium which acts as the heat
5:32
spreader that then conducts the heat to
5:33
the back side for the heat
5:35
sink and the actual lead packages all
5:38
look fairly similar except for this one
5:41
on the 575 which looks quite a bit more
5:44
substantial big spay
5:46
Terminals and the interface for this
5:48
turned out to be extremely simple it's
5:50
literally a 5V TTL level to enable each
5:54
color doesn't seem to be any tensity
5:56
control but there are some additional
5:58
pins on that connector that weren't used
5:59
in the through time thing so maybe
6:01
there's some extra lines that control
6:02
that I couldn't find any data on this uh
6:05
unit and the um their current product
6:07
range is quite significantly different
6:09
so we've got the uh blue these
6:13
might may well be saturating the camera
6:16
so they might look a bit weird so that's
6:17
the 430
6:18
blue the 575
6:24
yellow uh
6:26
475 light blue
6:29
the uh 520
6:31
green and the uh 630 red now one
6:36
interesting thing I noticed for the
6:39
575 it's actually it's actually using a
6:42
white lead and then filtering it rather
6:44
than using all the other ones are using
6:46
leads which are the fundamental colors
6:47
but uh this is actually doing white and
6:50
it's a combination of this filter and
6:52
the dichroic mirrors that are turning to
6:55
Yellow if we take the filter out and a
6:57
lot of the a lot of the um blue content
7:00
is going this way the red is going
7:02
straight through these two mirrors so
7:05
this is clearly not reflecting much of
7:08
that so we end up with the yellow coming
7:10
out of uh out of there which is a fairly
7:14
light yellow color which you don't
7:16
really see from high intensity leads so
7:19
that's clearly why they've used the
7:20
white to uh do this power consumption of
7:23
the white is pretty high so going up to
7:25
about 2 and 1 half amps on that color
7:27
whereas most of the other colors are
7:28
only drawing half an amp or so at 24
7:30
volts the uh the green is up to about
7:32
1.2 but say this thing is uh much
7:35
brighter and if you actually run all the
7:38
colors at the same time you get a fairly
7:41
reasonable um looking white coming out
7:43
of it and one thing you might just be
7:45
out to notice is there is some sort
7:46
color banding around here that's not
7:49
getting uh everything s completely
7:51
concentric and I think that's where this
7:53
fiber optic thing comes
7:58
in I'll
8:00
get a couple of Fairly accurately shaped
8:04
very sort of uniform color and looking
8:06
at What's um inside here we've basically
8:09
just got this Square Rod so this is
8:12
clearly yeah the lights just bouncing
8:13
off all the all the various sides to um
8:16
get a nice uniform illumination uh this
8:19
back bit looks like it's all potted so
8:21
nothing I really do to get in there I
8:24
think this is fiber so I have come
8:26
across um cables like this which are
8:27
liquid fill but just looking through the
8:30
end of this it's probably a bit hard to
8:31
see it does look like there fiber ends
8:34
going going on there and so there's this
8:36
feedback thing which is just obviously
8:39
compensating for the any light losses
8:41
through here to get an accurate
8:43
representation of uh the light that's
8:45
been launched out of these two
8:47
fibers and you see uh
8:49
these have got this sort of trapezium
8:54
shape light guides again it's like a
8:56
sort of acrylic or glass light guide
9:00
guess projected just to make the right
9:03
rectangular
9:04
shape and look at this Center assembly
9:07
um the light output doesn't uh change
9:10
whether you feed this in or not so it's
9:11
clear not doing any internal Clos Loop
9:14
control obviously there may well be some
9:16
facility for it to do that but it's not
9:17
being used in this
9:19
application and so this output just
9:21
produces a voltage on the uh outle
9:24
connector proportional to the amount of
9:26
light that's present so there's a little
9:28
diffuser in the back there
9:30
and then there's just some kind of uh
9:33
Optical sensor looks like a
9:35
chip looking at the lead it's a very
9:37
small package on the PCB with this lens
9:40
assembly over the top and these look
9:43
like they're actually on a copper
9:44
Metalized PCB for maximum thermal
9:47
performance and yeah it's a very small
9:49
package looks like it's a ceramic
9:51
package and there's a thermister there
9:53
for temperature monitoring this is the
9:56
475 blue one this is the 520 need to
9:59
Green which is uh rather different OB
10:02
it's a much bigger D with lots of bond
10:04
wise but also this looks like it's using
10:05
a phosphor if I shine a blue light at it
10:08
lights up green so this is actually a
10:10
phosphor conversion green lead which
10:12
I've I've come across before they want
10:15
that specific wavelength so they may be
10:17
easier to tune a phosphor than tune the
10:20
um semiconductor material to get the uh
10:23
right right wavelength from the lead
10:24
directly uh red 630 similar size to the
10:28
blue one or does seem to have a uh a
10:31
lens on top of it there is a sort of red
10:33
coloring to
10:35
the die but that doesn't appear to be
10:38
fluorescent as far as I can
10:39
tell and the white one again a little
10:41
bit different sort of much higher
10:43
current
10:46
connectors a makeer name on that
10:48
connector flot light not sure if that's
10:52
the connector or the lead
10:54
itself and obviously with the phosphor
10:56
and I'd imagine that phosphor may well
10:58
be tuned to get the maximum to the uh 5
11:01
cenm and actually this white one looks
11:04
like a St fairly standard product I just
11:06
found it in Mouse made by luminous
11:09
devices in fact actually I think all
11:11
these are based on various luminous
11:13
devices modules and they're you take
11:17
looks like they taking the nearest
11:18
wavelength and then just using these
11:19
filters to clean it up to get a precise
11:22
uh spectral line out of it so quite a
11:25
nice neat and um extreme
11:30
bright light source uh sure I've got any
11:33
particular use for it so I think this
11:35
might end up on
11:36
eBay but uh very pretty to look out and
11:40
without the uh risk of burning your eyes
11:43
out like you do with lasers so I thought
11:45
it would be interesting to try and
11:46
figure out the runtime of this things
11:48
like this we usually keep some sort
11:49
record of runtime cuz leads degrade over
11:51
time I couldn't get any software to work
11:52
through the USB face but then had a
11:54
thought probably going to be writing the
11:55
runtime periodically to the e s prom so
11:58
I just just scope up that and noticed it
12:00
was doing right every 5 minutes so I
12:02
just ran it for a while periodically
12:04
reading the E squ I just held the pick
12:05
in in reset and um put clip over to read
12:07
the square prom and found it was writing
12:10
one location per color every 5 minutes
12:12
so if one color was on it would write
12:14
that location every 5 minutes and just
12:16
increment it by one so after doing a few
12:18
tests with different colors of different
12:19
time periods it looked extremely
12:21
straightforward it's like a four bite
12:22
count for each color looking at the
12:24
original data that was in it all the
12:26
colors apart from Green were reading
12:28
zero and the green was reading four
12:30
indicating a total 20 minutes run time
12:32
ever if it was turned on run for a short
12:34
time then turned off that might not have
12:36
been counted but even so indicates this
12:37
thing wasn't used a great deal the whole
12:40
s process of doing a run can be several
12:42
hours but it'll only be doing probably
12:43
the Imaging at the end of that so you
12:46
wouldn't expect to be running for a long
12:47
time but say a single color for 20
12:50
minutes over its whole lifetime does
12:52
seem a little bit on the low side okay
12:55
let's look at the camera un fortunately
12:57
I managed to not record any sound when I
12:58
did this it's also a couple of months
13:00
ago so there's going to be a few details
13:02
that I've forgotten so I'm just going to
13:04
dub this over the original footage so um
13:07
take the lid off see this massive great
13:10
heat sink so this is a pel cool camera
13:12
we've got this blower fan producing a
13:14
fair amount of air flow through
13:16
it the connector here there's the ccds
13:19
mounted on the board on the
13:24
right this unplugs so we've got a bit of
13:27
power supply stuff on here
13:29
USB interface I think that's the Cyprus
13:32
microcontroller High speeded USB
13:34
interface there's a zyink spon fpga some
13:40
RAM and there's a couple of ATD
13:42
converters can't quite read what those
13:45
those are but anal
13:47
devices um little bit of bodgery around
13:51
here extra decoupling obviously they
13:53
have having some noise issues this is
13:55
around the ram chip quite a lot of extra
13:57
capacitors been added there
13:59
uh there's a couple of amplifiers prior
14:01
to the HD converter buffers or Andor
14:05
amplifiers taking the CCD
14:08
signal um bit more power spy stuff here
14:11
this is probably all to do with
14:12
generating the various CCD bias voltages
14:14
they uh need quite a lot of exotic
14:18
voltages next board down is just a
14:20
shield and an interconnect
14:24
boardly shielding the power supply stuff
14:26
from some the more sensitive an log
14:28
stuff
14:31
and this is the bottom board which is
14:32
just all power supply
14:34
stuff as you can see tons of capacitors
14:37
or Transformer in
14:42
there and this is the CCD which is a uh
14:47
very impressive thing this is a kf50 100
14:50
originally by true sense then codec
14:53
there ON
14:54
Semiconductor it's 50 megapixels uh the
14:58
only price I could find was this one
15:00
5,000 bucks and the architecture you can
15:03
see there actually two separate halves
15:04
which explains the Dual AZ converters
15:06
and two amplifiers it's literally split
15:08
down the middle and duplicated so it's
15:10
outputting two streams in parallel just
15:13
to keep the bandwidth sensible and it's
15:15
got this amazing um diffraction effects
15:18
it's got micro lenses over the pixel so
15:20
there's there's a bit more Optics going
15:22
on than on a normal
15:25
sensor few more bodges on the CCD board
15:28
including this wire which isn't really
15:29
tacked down very well which is a bit uh
15:32
bit of a mess quite a few bits around
15:34
this board where they've uh tacked
15:36
various bits on which is not super
15:38
impressive looks like CCD drivers on the
15:40
left with those 3 ohm um damping
15:43
resistors on the
15:47
output get a few more little bodges
15:50
around here some of
15:52
the and there's this separator the
15:54
silica gel to keep the moisture down but
15:56
there's this separator that actually
15:58
appears to be cut from piece of
15:59
antistatic
16:04
bag and this sort of thermal block on
16:06
top of this stack of three pel Cola
16:12
modules so as with any Stacks they get
16:16
um larger as they go back towards the
16:18
heat sink because each P's got to not
16:20
only take the heat from the previous but
16:21
also the waste heat which is quite
16:27
significant you see a little temperature
16:29
sensor here that copper block which
16:32
makes contact with the back of the
16:37
CCD and this's the back of the
16:40
pelas this then contacts the heat sink
16:44
on the uh rear there a few thermal pads
16:46
as well for some of the other power
16:47
components on this
16:51
PCB okay I've connected this uh camera
16:54
up I found some drivers on the disc that
16:56
seem to work under Windows 7 couldn't
16:58
get to install under Windows 11 though
17:01
um in the absence of any sort of lens or
17:03
being bothered to the proper amount I've
17:04
just put some f over it and put a little
17:06
pin in there to make a pinhole lens and
17:08
software gives a few options I'm not
17:11
entirely sure what all these are there's
17:12
obviously a clock frequency 22 MHz low
17:15
gain and with PFG no idea what that is
17:19
something something game programmable
17:20
Something game perhaps ver exposure
17:23
types I think focus is just like a
17:25
continuous grab until you tell it to
17:27
stop not entirely sure all these options
17:30
are obviously exposure time uh triggers
17:33
there ex external hardware trigger inut
17:35
you just trigger using a um thing on
17:37
screen so the resolution is 8176 by
17:40
6132 and you can actually bin those
17:42
where you combine multiple pixels to get
17:46
increased gain at the expense of lower
17:48
resolution down this is a 10sec exposure
17:51
obviously of the pin hole it's very uh
17:53
intensitive so we just stand still now
17:56
downloading it there's the uh exposure
17:59
so when it's
18:01
um there's a little status thing down
18:03
here so that tells you the um exposure
18:07
[Applause]
18:09
time it's this is just it
18:15
downloading um it is quite I'm seeing
18:18
quite a lot like smearing I think that I
18:20
don't know whether that's just due to
18:21
pixels overloading or something else I
18:24
mean yeah it's not it's not um out of
18:26
the question that there's something not
18:27
totally right about this camera
18:28
certainly was bodge wise on there um I
18:31
don't I'd imagine a camera like this
18:32
it's got a fairly narrow range of
18:34
intensities that it's happy with I'm not
18:36
going to spend a great deal of time on
18:38
this if you're interested in this camera
18:40
maybe for astronomy or something and
18:42
happy to sort of take the risk of it may
18:44
not be uh perfect I'll um I think I'll
18:47
stick this on eBay along with the
18:48
Illuminator I'll put a link down in the
18:50
description to the listing take your
18:52
chances to grab a bargain so for example
18:54
here we see this vertical streaking so
18:56
I'm not sure how normal that is this is
18:58
on fairly bright scene looking out the
19:02
window if I cut the exposure time down
19:04
on that it's now 1 second
19:07
exposure again most of the image
19:09
disappears again this is looks like it's
19:11
possibly over still overloading here go
19:14
that go down to say say quarter a
19:16
second so again I think there might be
19:19
some Auto gain control going on here um
19:21
this is with the PFG option let's try
19:23
turning that off and see what
19:25
happens so I'm not sure this is actually
19:27
more streaking or which just it's
19:29
cranked up the gain all the dis display
19:31
gray scale to show what um you know the
19:33
range of things that it's captured
19:36
there's one of one of 12 things in the
19:38
software there's um you can see of you
19:40
can't seem to read out the temperature
19:42
of the pelta cooler but you can set the
19:44
temperature and if you said it's a
19:46
different temperature you see the power
19:48
consumption jump up running the cooler
19:50
to get the temperature you requested but
19:52
I can't see anything anywhere that tells
19:54
you whether the cool is at the at the
19:56
temperature other than the power
19:57
consumption going down and there's no
19:59
temperature read out
20:03
here and just some yeah this is just
20:05
sort of very basic software I'm sure
20:07
there's like an API for more
20:09
sophisticated
20:10
applications but so if you know anything
20:12
more about these cameras please um stick
20:14
in the
20:15
comments um incidentally when I was
20:18
editing I didn't notice there was a bent
20:19
pin on the um CCD but I did fix that
20:22
before doing these tests and also
20:24
reactivated the um silica gel desicant
20:26
cuz I noticed it was uh I was getting
20:28
bit of condensation on the window but um
20:31
yeah so a couple of uh interesting but
20:34
maybe not particularly uh useful pieces
20:37
of Kit except for someone that's got a
20:38
very specific use so um I'll stick a
20:42
I'll stick these on eBay put a link in
20:44
the description and say hopefully
20:45
someone could actually make some uh good
20:47
use of these things
Example Output:
**Abstract:**

This video presents Part 2 of a teardown focusing on the optical components of a Fluidigm Polaris biotechnology instrument, specifically the multi-wavelength illuminator and the high-resolution CCD camera.

The Lumen Dynamics illuminator unit is examined in detail, revealing its construction using multiple high-power LEDs (430nm, 475nm, 520nm, 575nm, 630nm) combined via dichroic mirrors and filters. A square fiber optic rod is used to homogenize the light. A notable finding is the use of a phosphor-converted white LED filtered to achieve the 575nm output. The unit features simple TTL activation for each color, conduction cooling, and internal homogenization optics. Analysis of its EEPROM suggests extremely low operational runtime.

The camera module teardown showcases a 50 Megapixel ON Semiconductor KAF-50100 CCD sensor with micro-lenses, cooled by a multi-stage Peltier stack. The control electronics include an FPGA and a USB interface. Significant post-manufacturing modifications ("bodges") are observed on the camera's circuit boards. Basic functional testing using vendor software and a pinhole lens confirms image capture but reveals prominent vertical streaking artifacts, the cause of which remains uncertain (potential overload, readout artifact, or fault).

**Exploring the Fluidigm Polaris: A Detailed Look at its High-End Optics and Camera System**

* **0:00 High-End Optics:** The system utilizes heavy, high-quality lenses and mirrors for precise imaging, weighing around 4 kilos each.
* **0:49 Narrow Band Filters:** A filter wheel with five narrow band filters (488, 525, 570, 630, and 700 nm) ensures accurate fluorescence detection and rejection of excitation light. 
* **2:01 Customizable Illumination:** The Lumen Dynamics light source offers five individually controllable LED wavelengths (430, 475, 520, 575, 630 nm) with varying power outputs. The 575nm yellow LED is uniquely achieved using a white LED with filtering.
* **3:45 TTL Control:**  The light source is controlled via a simple TTL interface, enabling easy on/off switching for each LED color.
* **12:55 Sophisticated Camera:**  The system includes a 50-megapixel Kodak KAI-50100 CCD camera with a Peltier cooling system for reduced noise.
* **14:54 High-Speed Data Transfer:** The camera features dual analog-to-digital converters to manage the high data throughput of the 50-megapixel sensor, which is effectively two 25-megapixel sensors operating in parallel.
* **18:11 Possible Issues:** The video creator noted some potential issues with the camera, including image smearing. 
* **18:11 Limited Dynamic Range:** The camera's sensor has a limited dynamic range, making it potentially challenging to capture scenes with a wide range of brightness levels.
* **11:45 Low Runtime:** Internal data suggests the system has seen minimal usage, with only 20 minutes of recorded runtime for the green LED.
* **20:38 Availability on eBay:** Both the illuminator and camera are expected to be listed for sale on eBay.

Here is the real transcript. Please summarize it: 
00:00:01 welcome to software unscripted I'm your
00:00:01 host Richard Feldman today I'm talking
00:00:03 with Chris latner creator of Swift llvm
00:00:06 clang and most recently the Mojo
00:00:08 programming language at modular
00:00:10 Incorporated we talk about a lot of
00:00:12 different topics including Mojo language
00:00:14 design and API design performance both
00:00:16 compiler performance and runtime
00:00:17 performance and ecosystem
00:00:19 Evolution I want to give a massive thank
00:00:21 you to everyone who's been supporting
00:00:22 software unscripted on patreon if you
00:00:25 enjoy these episodes and you'd like to
00:00:26 become a supporter too check out
00:00:33 and now Mojo with Chris
00:00:33 latner all right Chris welcome awesome
00:00:36 Richard I'm very excited to be here it's
00:00:38 it's super funny I hear you talking to
00:00:40 my ears all the time and so it's it's
00:00:41 great to be able to talk with you well
00:00:44 likewise I've seen a bunch of your talks
00:00:45 and uh so so now you're making this
00:00:47 language called Mojo uh what's it all
00:00:49 about uh great question and like why why
00:00:52 is it a good idea to make a new
00:00:53 programming language have you ever
00:00:54 wondered that for your own I've never
00:00:56 been asked that yeah like everybody that
00:01:00 programming language are a bad idea why
00:01:01 would you ever do this right and so in
00:01:03 the case of Mojo it's it's a combination
00:01:05 of uh it's it's basically just a way to
00:01:08 solve a problem and so in in my
00:01:10 background uh as you probably know I've
00:01:12 built like the clang C++ implementation
00:01:15 and the Swift programming language and a
00:01:16 bunch of other stuff that's less uh
00:01:18 wellknown but um what I learned from
00:01:21 that is that building a programming
00:01:22 language is really expensive really hard
00:01:24 and you have to have really good reason
00:01:25 to do this and so when we started
00:01:27 modular our goal wasn't to create a new
00:01:30 programming language what we wanted to
00:01:31 do is we wanted to solve a bunch of very
00:01:34 hard tech let's go make gpus go Burr
00:01:37 let's go make accelerators that are even
00:01:40 weirder than gpu's work let's make it so
00:01:42 we can program this entirely new next
00:01:43 generation of hardware and we had some
00:01:46 tools we had this ml compiler framework
00:01:48 thingy had a whole bunch of new
00:01:50 algorithms and stuff like this but then
00:01:52 we decided we needed to have a way to
00:01:53 actually express it and for normal
00:01:55 programmers to be able to participate
00:01:57 and so coming out of that we decided to
00:01:59 make Mojo which is a solution to a
00:02:02 series of equations of we have this
00:02:04 programming model that we need to expose
00:02:06 how where do we get
00:02:08 syntax that's that's where that's where
00:02:10 Mojo came from actually
00:02:12 originally right so you're like we've
00:02:14 decided that we have problems where the
00:02:16 solution is in the shape of a
00:02:17 programming language ml is a big part of
00:02:20 that and now we need some sort of syntax
00:02:22 to put on top of this now you could have
00:02:24 just gone with like let's let's make up
00:02:26 a new syntax that's fun it's you bik
00:02:28 shed for for that b b there done that
00:02:31 with Swift and and and what I learned
00:02:34 and I I mean I could just share the
00:02:35 experience there is that it's a lot of
00:02:37 fun like being able to go through all
00:02:39 the the Lessons Learned on all these
00:02:41 different things integrate what you like
00:02:42 about all these different things into a
00:02:43 new system like that's a lot of fun it's
00:02:45 also really hard also takes a lot of
00:02:47 time you spend a lot of your energy on I
00:02:50 don't know people would say bike
00:02:51 shedding but I would say it's it's
00:02:52 design which is which is a really
00:02:55 difficult skill um and what we wanted to
00:02:57 spend our time on is two things one is
00:03:01 the actual semantics and the execution
00:03:03 platform the compiler stuff like how it
00:03:06 actually runs fast and how we express
00:03:08 the full capabilities of Hardware that's
00:03:10 what we wanted to spend our time on and
00:03:11 second we wanted to meet people where
00:03:13 they are and in our case in the AI and
00:03:16 and other space everybody's in Python
00:03:19 right and so we thought okay well I mean
00:03:21 I know Swift pretty well like should we
00:03:23 just use Swift and hack Swift up or
00:03:24 should I hack up C++ or hack up a domain
00:03:27 specific embedded language in Scola or
00:03:29 or whatever did not really think about
00:03:31 that by the way but um uh but I love
00:03:35 schola but yeah what we realized was we
00:03:37 realize that because the entire
00:03:39 Community was around python what we
00:03:41 wanted is we wanted Mojo to be a strong
00:03:43 member of the Python family and look and
00:03:44 feel and allow transferable skill set so
00:03:46 programmers didn't have to like retach
00:03:48 themselves how to overload the plus
00:03:50 operator but we didn't like any of the
00:03:52 implementation of python and so fast
00:03:55 enough well it's it's there's I mean
00:03:59 should I be uh positive about python CU
00:04:02 I love it uh well so I love python the
00:04:05 language but the implementation of
00:04:06 cpython is both not very fast it's an
00:04:09 interpreter it uh is not even using
00:04:11 state-of-the-art interpreter techniques
00:04:13 like Justin time compilers and things
00:04:14 like this um it also has certain like
00:04:18 software dependency problems which
00:04:19 people feel in packaging like that
00:04:23 that's a problem there's also no way
00:04:25 that python would ever run on a on a GPU
00:04:27 M right and and for for example example
00:04:30 like you've done some great work in rock
00:04:31 where you need to be able to build down
00:04:34 to effectively an embedded system like
00:04:36 you have your whole platform abstraction
00:04:38 and things like this right and so and so
00:04:41 that you have to design for that and if
00:04:43 you design for that then you can achieve
00:04:46 that you can make zero dependence you
00:04:47 can make you know 40 kilobyte hello
00:04:49 world or something like that but but
00:04:51 python can never do that right just
00:04:52 because the entire system was never
00:04:54 built for that well also there's I mean
00:04:56 something you've said before is like API
00:04:58 design is kind of the main thing it's
00:05:00 like the biggest thing and I think uh
00:05:02 this is sort of an underrated concept I
00:05:04 think people think a lot about languages
00:05:05 and a lot about like libraries and stuff
00:05:07 like that in terms of like what can they
00:05:09 do what do they let you do but I think
00:05:12 it's just as important like what don't
00:05:13 they let you do like what do they rule
00:05:15 out a thing that people ask me all the
00:05:17 time is like hey can we just compile
00:05:19 Rock to JavaScript and that sounds like
00:05:21 a really easy thing to say until you
00:05:23 think about like our standard Library
00:05:25 it's like when you ask for the length of
00:05:26 the list we give you a 64-bit unsigned
00:05:28 integer like what's that going to be in
00:05:30 JavaScript is that going to be a big int
00:05:31 are we going to convert that to like be
00:05:33 really slow if you do yeah right it's
00:05:35 going to be super slow Heap allocated
00:05:36 and then like if we convert it to float
00:05:38 which 64-bit float which is what sort of
00:05:40 JavaScript likes well now we have
00:05:42 different lengths and we have like there
00:05:43 there's a whole new set of problems
00:05:45 there well and when you get really big
00:05:46 you start dropping precision and that's
00:05:48 not also super great either right yeah
00:05:50 so there's there's a lot of potential
00:05:52 problems there something I really like
00:05:53 about Swift's API design is that when
00:05:57 you have um like a the string library
00:06:00 for example like you have this concept
00:06:02 of like we have the btes that are
00:06:04 underneath the string and they're utf8
00:06:06 and then we have uh graphine clusters or
00:06:08 extended graphine clusters and those are
00:06:11 sort of the two units like I haven't
00:06:13 seen any other standard library that
00:06:14 does that that that sort of draws that
00:06:16 distinction and says like we don't have
00:06:18 a thing called like a character in the
00:06:20 sense of like a code code point or
00:06:24 because those are not useful unless
00:06:25 you're writing like an implementation of
00:06:27 graphine clustering or something like
00:06:29 that 99% of the time yeah it's super
00:06:32 funny you mention that I mean I I
00:06:33 haven't thought about that for a long
00:06:34 time but um but the way that emerged is
00:06:36 that you know one of the benefits of
00:06:38 building a new language or a system is
00:06:39 you get to reevaluate age-old problems
00:06:42 right and so Swift is like 14 years old
00:06:44 now right and so you go back to some of
00:06:46 these decisions made and they were made
00:06:48 in uh like 2012 you know kind of time
00:06:52 frame right yeah but but even at that
00:06:54 time it was it was very clear Java for
00:06:56 example and um Windows had started with
00:06:59 saying okay well internationalization is
00:07:01 important and so we can't use 8bit
00:07:03 characters let's use 16bit characters
00:07:06 right it's like okay wait that's not
00:07:08 good enough well now we need 32bit
00:07:10 characters well yeah wait a second 32bit
00:07:12 characters also don't make sense because
00:07:13 you have composing characters and so you
00:07:16 have a and then you have the hat and
00:07:18 they're two different Unicode code
00:07:19 points and and you know one of the
00:07:21 things I think that was amazing about
00:07:22 Apple and is amazing is that they're
00:07:24 very enduser Centric and so you want to
00:07:27 build a UI app for people to use
00:07:30 to write to build you know people are
00:07:32 building applications for normal normal
00:07:33 humans not programmers right and so you
00:07:36 you want all this stuff to just work and
00:07:37 when you when you SL when you highlight
00:07:39 some text in a little window you don't
00:07:41 want to take a graph like the hat before
00:07:44 it takes the a or something like this
00:07:46 right and so graphing clusters are
00:07:47 actually the human visible normal
00:07:49 default thing that people should think
00:07:51 about and as you say like the is it 8
00:07:54 Bits 16 bits variable size this and that
00:07:56 the other thing like okay well yes utf8
00:07:59 is actually strictly better than any of
00:08:00 the other Alternatives and so cool use
00:08:02 that but that was really just more a
00:08:04 consequence of a caring but also B
00:08:06 learning from the mistakes of the past
00:08:08 so yeah and I think from an API design
00:08:11 perspective what's amazing to me is the
00:08:13 fact that Swift's design says it it
00:08:16 subtracts it says like it's not saying
00:08:18 like oh yeah you got you got characters
00:08:20 that mean this you got characters in
00:08:21 that sense and characters in that sense
00:08:22 it's like no no no we're just going to
00:08:24 take out like you have extended graphine
00:08:26 clusters which makes sense and then you
00:08:27 have bites which you need
00:08:31 purp intermediate if you what you're
00:08:33 doing you canes that but we're not going
00:08:36 to make that part of the standard
00:08:37 library because that's a really really
00:08:39 Niche weird thing to be doing and people
00:08:41 trip over it all the time thinking that
00:08:43 that's the right thing they should reach
00:08:44 for and unfortunately as it happens if
00:08:47 you reach for like scalers or uh code
00:08:50 points or something like that like if
00:08:52 your test cases are simple enough you
00:08:54 won't realize that you have lingering
00:08:56 bugs it'll everything will look fine um
00:08:58 and that sort of subtraction is the only
00:09:00 way to get the programmer benefit in my
00:09:02 mind well and I I think that a lot of
00:09:04 your point is um make it this comes back
00:09:07 to the design aspect right which is make
00:09:09 it the thing that people naturally reach
00:09:11 for is the safe default totally right
00:09:14 and you don't have to you don't have to
00:09:15 prevent people from having lowlevel
00:09:17 access and bit banging or something like
00:09:19 that but but you want to make it so that
00:09:21 uh that that's something that you opt
00:09:23 into not something you accidentally get
00:09:25 without thinking about it right and so I
00:09:27 think that that's that's a big thing
00:09:29 bringing that back to Mojo like we were
00:09:31 talking about the sort of the Python
00:09:33 ecosystem and stuff like that where on
00:09:35 the one hand there's lots of really
00:09:36 useful python code out there that if you
00:09:39 can just access that immediately that
00:09:41 gives people a really nice bootstrapped
00:09:43 ecosystem on the other hand uh so so
00:09:47 let's talk about a little bit about some
00:09:48 of those API design trade-offs that you
00:09:50 have to deal with in terms of if you
00:09:52 want the python compatibility so I
00:09:54 believe you said that one of Mojo's
00:09:56 goals is to be a super set of python is
00:09:57 that right yeah so over time you can
00:09:59 think of is like a python Plus+ and so
00:10:01 the same way that C++ is a super set of
00:10:03 C you can think of python and mojo as
00:10:06 being kind of co-evolving over time but
00:10:09 the goal of Mojo is to be a python Plus+
00:10:12 now you know often smart people like you
00:10:15 will give me a hard time and say okay
00:10:16 well but you took a new keyword and
00:10:17 therefore you're not a superet etc etc
00:10:19 ET right and well so did so did C++ C++
00:10:23 took a whole bunch of different keywords
00:10:24 right and it's not like C stopped
00:10:26 evolving just because C++ came on the
00:10:28 scene and so and so what happens
00:10:29 naturally is you get effective super set
00:10:32 even though technically there's little
00:10:34 things on the edge that that you know
00:10:37 have an issue it's like super set unless
00:10:38 you happen to name a variable class
00:10:40 which is a keyword now yeah right that
00:10:41 type of thing exactly exactly which I
00:10:44 think an important distinction there is
00:10:46 it's like we also we we also have ways
00:10:48 to solve for that too so but but sorry
00:10:50 keep going cool okay that's interesting
00:10:52 I'm I'm curious to hear about that later
00:10:54 maybe but uh one of the things that's
00:10:56 interesting to me about the suet
00:10:58 approach is that it it raises this
00:11:01 intriguing trade-off in my mind around
00:11:02 so you have this big ecosystem and a lot
00:11:05 of it is written using sort of python
00:11:07 idioms and things that I'm not going to
00:11:09 say they're necessarily fast or slow in
00:11:10 Python but it's like they make sense in
00:11:12 Python and on the one hand you want to
00:11:14 access that ecosystem but on the other
00:11:15 hand like you said at the beginning the
00:11:17 the big motivation for Mojo is to solve
00:11:19 these really hard especially performance
00:11:20 oriented problems so how do you think
00:11:22 about sort of you know using that
00:11:25 ecosystem but also probably evolving
00:11:28 replacement parts guessing for for that
00:11:30 that are written in lower level ways or
00:11:32 or not you're very smart guy that's
00:11:34 exactly what we're doing okay so let me
00:11:37 give you an example this uh python has a
00:11:40 data class right a data class is roughly
00:11:43 a aggregation of different fields Mojo
00:11:46 sure you can have classes someday and
00:11:48 like you can have all these different
00:11:49 things and that's fine we don't want to
00:11:50 remove those but we can also have a
00:11:52 struct a struct allows you to have an
00:11:54 inline collection of fields that's what
00:11:56 you actually want most of the time and
00:11:59 so so now our our approach on this is
00:12:01 not to remove the data class we'll
00:12:04 support it it can be compatible and it
00:12:06 can have the same reference semantic
00:12:07 behavior and things like this you'd
00:12:09 expect that's awesome it's not that
00:12:11 that's a bad thing but we can add a new
00:12:13 thing and um and it has these other
00:12:15 advantages it's like in line it's faster
00:12:17 it has all the stuff it's more
00:12:19 predictable etc etc um let me give you
00:12:22 let me zoom out in generalized from my
00:12:24 past history so when we brought up Swift
00:12:27 we we're doing exactly the same thing to
00:12:29 Objective C as Mojo is doing to python
00:12:32 right and it's it's different in many
00:12:35 and it was much harder for Swift because
00:12:37 Swift was very different syntax than
00:12:39 Objective C but one of the things we
00:12:41 were doing is we were bringing a new
00:12:42 language that had for example enums and
00:12:45 pattern matching and things like this
00:12:46 right in into a ecosystem that didn't
00:12:49 and so Objective C just like python has
00:12:51 a whole bunch of different ways to be
00:12:52 able to kind of work around the
00:12:54 limitations of not having these things
00:12:56 everything with massively objectoriented
00:12:58 programming patterns and things like
00:13:00 this and so what we did with swift was
00:13:02 we said
00:13:03 okay guess what all all of you objectiv
00:13:05 see programmers in that case we're
00:13:07 changing the syntax completely because
00:13:09 that was part of the job to be done um
00:13:11 but but but we need all the iOS sdks to
00:13:14 work the same way and so when Swift one
00:13:16 launched we said all of the patterns
00:13:19 that you've already developed all of
00:13:21 your API knowledge all of that comes
00:13:24 over and now you can build an app in
00:13:26 Swift or you could build a feature in
00:13:28 Swift into your Objective C app um and
00:13:31 all of that knowledge comes over but in
00:13:33 that case you have to learn new syntax
00:13:35 and so but Swift also has enums for
00:13:38 example and a lot of the journey that
00:13:40 object C programmers went through is
00:13:41 they're like okay well learning how to
00:13:43 not use square brackets from Objective C
00:13:45 or whatever um is kind of weird but now
00:13:47 I get it oh wow this is easy okay I get
00:13:49 going oh wow I discovered enums wow this
00:13:51 is really cool I've never seen pattern
00:13:54 matching before oh wow this is like and
00:13:57 to me to me that's success and some
00:13:59 other people for a long time would stay
00:14:01 writing the classical
00:14:03 objectoriented oopy patterns and stuff
00:14:05 like that and that those also still
00:14:06 worked and so it wasn't a we're trying
00:14:08 to like brainwash you or force you into
00:14:09 a thing it's that we're giving you
00:14:11 access to pretty well understood
00:14:13 technology from a PL perspective um yeah
00:14:16 in in a way that you can now access and
00:14:18 makes your life better and so a lot of
00:14:19 this is what we're doing with Mojo and
00:14:21 so this is the journey that I see a lot
00:14:23 of python programmers go through when
00:14:24 they come to Mojo is they say okay well
00:14:27 right now Mojo is not a full super that
00:14:29 python is missing a bunch of features um
00:14:31 but it's still really useful for a bunch
00:14:33 of different things and one of our goals
00:14:35 that we're building into for this fall
00:14:36 is make it super easy to make a python
00:14:39 package from Mojo and so you can say I
00:14:42 want to I'm actually going to take a
00:14:44 python package I'm going to upgrade part
00:14:46 of it and instead of being split between
00:14:48 Python and c I just want to write in
00:14:49 Mojo and what you're doing is you're
00:14:51 subtracting all the complexity of
00:14:53 interoperating with c and all this
00:14:54 different kind of stuff and providing
00:14:57 you know the same performance or better
00:14:58 that you get for C or C++ but now it's
00:15:00 just way easier to build one of these
00:15:02 packages and and that that's a thing
00:15:04 where Suddenly It's very valuable and
00:15:06 useful for people and also if you have
00:15:08 like new new PL technology available
00:15:11 then people can learn in place but they
00:15:12 don't have to learn a new way to
00:15:14 overload the plus operator things like
00:15:16 this right right and so it sounds like I
00:15:19 mean maybe the ideal is if you look at
00:15:21 something like um you know just to put
00:15:23 the python part aside if you look at
00:15:25 like a typescript for example um you
00:15:27 could say that typescript is kind of
00:15:29 taking the like package ecosystem of
00:15:32 thesis approach to npm where it's like
00:15:34 At first nothing is in typescript and
00:15:36 then oh typescript here and there and
00:15:38 then also that affects the the new API
00:15:40 like when version 2.0 comes out or 3.0
00:15:42 comes out they do it with typescript in
00:15:44 mind and then now eventually you end up
00:15:46 having npm being a primarily or maybe
00:15:48 even eventually completely typescript
00:15:50 ecosystem even though it started out
00:15:52 with zero yeah I mean so ship aesus
00:15:55 that's what you're referring to uh where
00:15:56 you rebuild the whole thing and you
00:15:58 place one board at a time but you get to
00:16:00 the same ship but all the parts are
00:16:02 different right and that's kind that's
00:16:04 kind of equivalent to what happened to
00:16:05 iOS right is IOS was completely
00:16:07 Objective C and over time they've been
00:16:10 rewriting big chunks of it in Swift and
00:16:11 you kind of ships ship of thesis I guess
00:16:14 um but but more broadly like if you look
00:16:16 at PL communities it's super funny you
00:16:18 talk about
00:16:19 JavaScript JavaScript was not built for
00:16:22 nodejs you know that was not it was it
00:16:25 was designed for onclick handlers and
00:16:27 things like this so one one of the again
00:16:30 obviously javascript's amazing and it's
00:16:31 come a long ways but uh but the uh but
00:16:34 the natural thing that happens with
00:16:36 successful language communities is that
00:16:37 programmers want to bring their skill
00:16:39 sets forward and as they do this they
00:16:42 bring it into adjacent domains that they
00:16:44 want to apply the technology to and so
00:16:46 this is something that that natural
00:16:48 thing that that happens with scaling
00:16:51 communities because it's a community
00:16:52 aspect it's not a technology aspect it's
00:16:54 it's a consequence of the community
00:16:56 that's what Mojo is really built for
00:16:58 right and so in modular we're building
00:17:00 Mojo because we care about a lot of AI
00:17:02 and GPU and accelerator stuff like this
00:17:04 but a lot of the folks in the Mojo
00:17:06 Community are very happy building gooey
00:17:07 libraries and you know I want a faster
00:17:11 fast API or you know whatever kind of
00:17:13 thing and and so it's amazing to see
00:17:16 that and that's one of the things where
00:17:18 if you get these fundamental lower level
00:17:20 Technologies right you can get something
00:17:22 that's very generally useful and then
00:17:24 you can also scale into this and then
00:17:26 when you're writing a web server for
00:17:28 example there's a kajillion packages out
00:17:30 there that are really really really
00:17:32 important that you need to be able to
00:17:34 talk to and not saying that you know
00:17:36 fixing the cold start problem of like
00:17:38 you can just import any of them and they
00:17:39 just work today in Mojo is actually
00:17:42 extremely valuable and then if you want
00:17:43 to ship a thesia something then you can
00:17:45 totally do that over time right have you
00:17:48 thought about like talking about that
00:17:49 use case of um developing python
00:17:52 packages in Mojo have you thought about
00:17:54 doing things like optimizing to be like
00:17:57 oh well we we'll import this python
00:17:59 package as a dependency but we see that
00:18:02 they're like through static inference we
00:18:04 can figure out that they're only using
00:18:06 this data class in a way that it could
00:18:07 have been a struct and so we'll just you
00:18:09 know what we'll just pretend that they
00:18:11 said struct and then you know move on
00:18:13 from
00:18:14 there so so you're saying have I thought
00:18:16 about that or what do I think about it
00:18:17 or yeah yeah or do you plan to do that
00:18:19 or seem out of scope that that is a very
00:18:21 common idea I think it's a terrible idea
00:18:24 okay no
00:18:25 offense so so get asked about this all
00:18:27 the time and so so again I'm I'm being
00:18:30 provocative to try to be you know more
00:18:33 funny right but uh it's it's not a
00:18:35 terrible idea get ask about this all the
00:18:37 time there's probably I don't know 30
00:18:40 different things in the python ecosystem
00:18:42 of the form let's take python that's
00:18:44 Dynamic and try to make it static and
00:18:46 therefore faster there's piie there's
00:18:49 codon there's there's a million of these
00:18:51 inscript unlean swallow not inscripted
00:18:53 unlean swallow back in the day like
00:18:55 there's a million of these different
00:18:56 things right and and here's here's the
00:18:58 challenge with this so sorry by the way
00:19:00 I identify as oldfashioned compiler guy
00:19:04 who learned who's learned a lot across
00:19:07 the ears right um the the challenge with
00:19:10 this is that if you build you know that
00:19:12 sufficiently smart compiler that will
00:19:14 make your code
00:19:16 fast what actually happens is that um
00:19:20 you optimize for some Benchmark right
00:19:22 you make some marketing claim you you
00:19:24 you make it so that some combination of
00:19:26 the source code that you have today plus
00:19:28 the mag magic compiler gives you an
00:19:30 outcome that you like and maybe it's a
00:19:32 10x speed up right um the challenge with
00:19:36 that is that now you go fix a bug in the
00:19:38 code it breaks compiler and you get a
00:19:39 10x
00:19:40 slowdown sure right and so what you've
00:19:43 built is you've built a demo you've
00:19:45 built something that can look really
00:19:47 good on a marketing slide or something
00:19:49 like that and yeah it's probably useful
00:19:51 and like again pipie for example it
00:19:53 provides like a 20x speed up or
00:19:54 something like that over python code and
00:19:56 stuff like this but for a programmer the
00:19:58 problem is you have no control and now
00:20:00 you have to understand both your code
00:20:01 which you keep Simple because it's all
00:20:03 Dynamic but then you have to understand
00:20:05 the compiler thing and where it's
00:20:07 sufficiently smart and where it falls
00:20:09 off the cliff and then you have to know
00:20:11 all of that complexity in order to get
00:20:13 the outcome that you care about which is
00:20:14 way faster right and so Mojo's approach
00:20:16 is saying again there's so much stuff in
00:20:18 the python Community that's been about
00:20:20 like let's make python un unmodified go
00:20:22 fast and you can get 20x speed ups and
00:20:25 stuff like this but Mojo is saying let's
00:20:27 not work forward for from Python and try
00:20:29 to make python a little bit better we're
00:20:31 saying let's work backwards from the
00:20:33 speed of light of Hardware unlock the
00:20:35 full power of Hardware which isn't just
00:20:37 you know int being fast and not boxed
00:20:40 but it's also like accelerators and simd
00:20:42 and like all these kinds of things and
00:20:45 um and do that and this is where again
00:20:47 it depends on your workload but you know
00:20:48 we have a blog post showing that Mojo
00:20:50 can be 65,000 times faster than python
00:20:52 right and and and the the usual push
00:20:56 back on that is it's like well you would
00:20:57 never write numeric code that's doing
00:20:59 math and dense dense arithmetic in
00:21:03 Python but that's literally the point of
00:21:06 Mojo is to make it so all that code you
00:21:08 would never write in Python you can
00:21:09 write in a language that's coherent and
00:21:11 consistent with python so you don't have
00:21:13 to switch languages right and so right
00:21:15 and you can write it right next to your
00:21:16 python code in the same file that's
00:21:18 right that's right and so this is this
00:21:19 is this is a big deal and so a lot of
00:21:21 that comes back to anyways so again I
00:21:22 was being provocative and you know being
00:21:24 being mean to you here but but but a
00:21:27 more neutral way saying this is that
00:21:29 instead of prioritizing magic and like
00:21:32 look you know there's an instant uh like
00:21:36 we're a better python in that way what
00:21:38 we're saying is we're saying we give you
00:21:39 tools we give you stroks we give you
00:21:42 type annotations we give you these
00:21:43 things these are very powerful and if
00:21:45 you want something to be an inline
00:21:47 64-bit thing on your stack use colon int
00:21:50 if you want it to be a boxed object
00:21:52 don't it's fine you
00:21:54 choose right something this reminds me
00:21:56 of is that I think that examp Le of you
00:21:59 write the code and it gets optimized
00:22:01 great and it's amazing performance 10x
00:22:03 faster and then later on you make one
00:22:05 slight tweak and then it de optimizes by
00:22:07 10x and now you know everything's
00:22:09 terrible um that actually reminds me of
00:22:11 it optimization in general is like that
00:22:14 right like I mean like we use lvm for
00:22:16 rock thank you for creating that by the
00:22:17 way um I like how fast it makes our
00:22:19 compiled Rock
00:22:21 programs um but uh but at the end of the
00:22:24 day we we do have those same kinds of
00:22:26 considerations where in a lot of cases
00:22:27 we're thinking about as we're writing
00:22:29 the code okay what's lvm going to do
00:22:31 with this and that's like you know
00:22:33 somewhat behind the scenes and it seems
00:22:35 to me that there is somewhat of an
00:22:38 inherent uh sort of spectrum and
00:22:40 trade-off along the lines of like
00:22:42 explicitness to how much the compiler is
00:22:45 able to help you and on the one extreme
00:22:47 end of explicitness you have handwrite
00:22:49 your assembly and don't optimize it at
00:22:50 all that's right and as we've known
00:22:52 since like 1950 with Fortran like
00:22:55 compilers can do better than that like
00:22:56 if you think you're going to outdo a
00:22:57 compiler Optimizer by just handwriting
00:22:59 everything you're probably wrong you
00:23:02 know the human brains get at a scope of
00:23:04 like 10 or 15 machine instructions or
00:23:06 something but when you get into tens of
00:23:07 thousands then like you just don't have
00:23:09 the attention span to do that right but
00:23:11 then on on the extreme well not the
00:23:12 extreme but like on the other end of
00:23:14 that like something that like when I'm
00:23:15 writing rust code for example all the
00:23:16 time I'm thinking about coves so for
00:23:19 those who aren't familiar with C move
00:23:20 instructions that's like you have an if
00:23:22 and an else and there's a certain
00:23:25 processor instruction that has
00:23:26 significantly better performance
00:23:28 character istics if you can get it and
00:23:30 the way that you get it is what you do
00:23:32 inside the if Branch what you do inside
00:23:33 the elf Branch El branch have to be very
00:23:35 very restricted and if they are
00:23:36 restricted in exactly the right way then
00:23:39 the optimizer will emit a SE move
00:23:40 instruction instead of a normal
00:23:41 branching instruction and life is good
00:23:44 performance-wise to oversimplify a huge
00:23:46 amount of things of course c c c move is
00:23:48 also really bad if you have a uh very
00:23:51 predictable Branch like yeah right so
00:23:54 that's one of the many things I'm
00:23:55 oversimplifying here yeah it can't be a
00:23:57 DE optimis
00:23:59 right but generally speaking as I
00:24:01 understand it pretty much always
00:24:02 optimizers will turn into a c move if
00:24:04 they have the ability to um because in
00:24:06 the typical case it's so much better but
00:24:09 that's an example of the type of thing
00:24:10 where you don't have to go all the way
00:24:11 to Assembly Language to have like if you
00:24:13 wanted to you could have a language
00:24:14 level construct of I want a c Move
00:24:16 versus I want a branch and maybe you
00:24:17 have a linter that like tells you hey
00:24:19 this could have been a c move you know
00:24:20 are you sure um but that type of thing
00:24:24 is there's this huge amount of language
00:24:26 design space in there where you can you
00:24:28 can make it like I I would say on Rock's
00:24:31 side we are much more on the side of
00:24:33 pretend there is no Optimizer like don't
00:24:35 give you a lot of low-l knobs to tweak
00:24:36 and we're gonna optimize things and
00:24:38 hopefully do a good enough job for the
00:24:40 type of language that rock is I think
00:24:41 that makes sense but it sounds like Mojo
00:24:43 is more in the space of like you have
00:24:46 access to higher level constructs in the
00:24:47 form of python things but also you have
00:24:50 access to more explicit lowlevel things
00:24:52 and the expectation is that if you want
00:24:54 to become a really expert Mojo
00:24:55 programmer you you can there's like more
00:24:57 and more you can learn that's not just
00:25:00 here's what the optimizer is doing it's
00:25:01 like I can be more and more explicit
00:25:03 about the exact instructions that I want
00:25:05 to come out or the mli I guess that I'm
00:25:07 feeding to lvf sure is that right well
00:25:09 so so so the way I would I would
00:25:10 separate this out into a couple of
00:25:12 different pieces right there's um you
00:25:14 know if you're a compiler nerd
00:25:16 implementing an Optimizer you have a
00:25:17 bunch of design trade-offs you have to
00:25:19 make when you're doing that right and so
00:25:21 I I gave a talk at the cgo
00:25:24 conference 12 years ago or something a
00:25:26 long time ago talking about the par bars
00:25:28 of heroic compiler optimizations and the
00:25:30 tldr on that is this thing that we're
00:25:33 talking about which is if you give a 10x
00:25:35 performance Improvement then you take it
00:25:37 away when you change your code that's
00:25:38 not actually great for ux but instead
00:25:41 what you can do is you can do static
00:25:42 analysis tools and you can tell the
00:25:44 programmer hey change your array of
00:25:47 structs into structs of arrays or
00:25:48 whatever whatever the thing is and now
00:25:50 you get a 10x performance Improvement
00:25:52 and then the programmer can put that in
00:25:54 their code and then they own it it's
00:25:56 it's explicit right and so it's the
00:25:58 predictability thing that actually in my
00:26:00 opinion really matters um and so how you
00:26:04 design a compiler
00:26:05 Optimizer uh really affects it now lvm
00:26:09 is a very useful one uh it has some good
00:26:11 things it has some bad things it's also
00:26:12 over 20 years old so glad it's useful um
00:26:16 in the case of Mojo we use some of it
00:26:18 but we've also disabled a lot of the
00:26:19 optimizer and so interesting um I we
00:26:23 gave a talk uh this last fall at the lvm
00:26:26 developer meeting talking about we use
00:26:27 lvm the Parts oh and and just if you
00:26:31 don't mind just let me give me I'll
00:26:32 write down a list of the exact
00:26:33 optimizations that you've enabled and
00:26:35 and we'll make sure to use those we Bas
00:26:37 we basically use lvm as a per
00:26:39 function Optimizer code generator we
00:26:41 disable the vectorizer there's a bunch
00:26:43 of stuff that anyways but the uh but do
00:26:46 you do your own inlining first or yeah
00:26:48 we have our own inliner yeah okay okay
00:26:50 got it that makes sense and so we've
00:26:51 we've reimplemented a ton of the
00:26:53 compiler pipeline in ml which is a
00:26:55 higher level compiler stack um but the
00:26:57 uh uh for uh one one problem that lvm
00:27:00 has for example is that lvm IR uh cannot
00:27:04 be optimized
00:27:07 multi-threaded and so have you ever been
00:27:09 on a computer with more than one core uh
00:27:12 maybe it's happened yeah it's yeah turn
00:27:15 out multicore is no longer the future
00:27:17 and so like being able to paralyze your
00:27:18 compilation is actually a pretty big
00:27:20 deal and so M can do that LM is not
00:27:23 super great at that um anyways there's
00:27:25 ways to work around this and and get
00:27:26 that to work but that's really important
00:27:27 for build times um but uh so so I mean
00:27:31 there's a bunch of stuff that goes in
00:27:32 there but then where I going is that
00:27:34 when you're designing an Optimizer from
00:27:36 scratch there's a bunch of trade-offs
00:27:37 you can choose to
00:27:39 make you and we use a huge amount of lvm
00:27:43 and it for better or worse it makes a
00:27:44 bunch of decisions on C moves and stuff
00:27:46 like this and so and so as a consequence
00:27:49 of what lvm chooses to do we have to
00:27:50 kind of live with it and work around or
00:27:51 decide to disable it or hack it or you
00:27:54 know you're working with a a useful pile
00:27:57 of stuff that has trade-offs right and
00:27:59 then from that you then build your
00:28:01 language sematic on top of that right
00:28:03 and you say okay well you as an as a
00:28:06 language implementer have to know a lot
00:28:07 about the compiler end to end and how
00:28:09 all the pieces compos together do your
00:28:11 users well that's that's a choice right
00:28:13 and so what we've decided to do with
00:28:15 Mojo and the contract we want to provide
00:28:17 to our users is that if you're writing a
00:28:21 high performance matrix multiplication
00:28:22 or something really low level and you or
00:28:24 you're writing GPU code and want to get
00:28:26 Peak flops out of your h100 00 and use
00:28:29 the tensor memory accelerator and blah
00:28:30 blah blah blah blah like okay well
00:28:32 you're pretty hardcore and what you want
00:28:35 is control if you're writing Dynamic
00:28:38 code and you're kind of a python
00:28:40 programmer and you know the 8020 rule
00:28:42 most code doesn't matter for performance
00:28:45 or you're hacking out a script or your
00:28:46 researcher or whatever well you
00:28:47 shouldn't have to care about any of that
00:28:50 it's fine so and so the balance is
00:28:52 really how do you get dynamism and uh
00:28:55 flexibility without without cting
00:28:58 against control and this is where types
00:29:00 for example are pretty cool because if
00:29:02 you opt into types then you can have a
00:29:04 lot of control and you get things like
00:29:06 inline allocation if you choose not to
00:29:08 well you get boxing and Heap and blah
00:29:09 blah blah all the usual stuff and it's
00:29:12 super obvious you know it's easy to
00:29:14 control it's easy to reason about and so
00:29:15 that's that's great yeah I do think
00:29:18 about um you mentioned the the sort of
00:29:20 the static analysis route where it's
00:29:21 like hey let me just tell you about the
00:29:23 optimizations you could do in line to
00:29:25 your code to make it run faster I I
00:29:28 think that's a really interesting
00:29:29 concept and in my mind it's more or less
00:29:32 useful depending on how lowlevel your
00:29:34 code sort of wanted to be if that makes
00:29:35 sense because on the one hand if you're
00:29:37 like to give your example of like you're
00:29:38 writing a matrix multiply like really
00:29:40 complicated low level like this is all
00:29:42 gonna I want I want really really
00:29:43 precise control then like yeah telling
00:29:45 me what to do gives me even more control
00:29:47 that's awesome if I'm writing a web
00:29:49 server I probably don't want my code to
00:29:51 look like that because now refactoring
00:29:52 it means I have to refactor all the
00:29:54 lowlevel stuff that the the static
00:29:56 analysis told me to write it into so so
00:29:58 it's it's an interesting balance of like
00:30:00 you know the I'm I'm a generally default
00:30:03 explicit person I like explicitness I'm
00:30:05 not like oh let's let's hide this and
00:30:07 that um but at the same time I
00:30:10 appreciate that like explicitness does
00:30:12 have downsides and that seems like it's
00:30:13 one of them well so so but pick the web
00:30:16 server example what what you're
00:30:18 presumably doing right and I assume I
00:30:21 assume this but tell me if I'm off base
00:30:23 but you're using you're using a
00:30:25 framework right potentially yeah right
00:30:28 and so if you're using and so if you're
00:30:29 using a framework then what you're doing
00:30:31 is you're bringing its threading model
00:30:33 its concurrency patterns it's uh you
00:30:35 know whatever all all the different ways
00:30:37 you set up and respond to the requests
00:30:39 and like all this and so the framework
00:30:40 provides that for you and you don't
00:30:42 really have so much of a choice now if
00:30:43 you're in the case of rock maybe you're
00:30:45 going all the way down and you're
00:30:47 building a tcpip stack or something
00:30:48 right I mean there are different
00:30:50 extremes or you're you know putting down
00:30:52 an fbga or something but in that case
00:30:54 it's it's really about how to use the
00:30:56 API right that's that's a great point
00:30:58 yeah and so and so what these tools need
00:31:00 to do is they need to map to the
00:31:03 abstraction that the programmer is
00:31:04 thinking in and if they can do that they
00:31:06 can be very effective um when I when I
00:31:09 complain about this really uh it's it's
00:31:12 not that you know heroic optimizations
00:31:14 are a bad thing is that um they get used
00:31:17 when they get used contextually when you
00:31:19 can't change the
00:31:21 code and so that's so for example in C
00:31:24 compilers there's this Benchmark Library
00:31:26 called specken and specint is the way
00:31:29 that people would you know bet test CPUs
00:31:32 against each other but also see
00:31:33 compilers against each other and things
00:31:35 like this and it's GCC faster than lovm
00:31:37 and you go you go try spec right but
00:31:39 spec because they're it's an industry
00:31:41 Consortium they want to be very
00:31:43 hardcoded is you know the source code is
00:31:46 fixed and so you incentivize the
00:31:48 compiler people myself in a former life
00:31:51 right uh to to go make the compiler take
00:31:53 the code and without modification make
00:31:55 it go fast right but but the observation
00:31:58 is that if you're an app programmer or
00:31:59 you're building anything that matters
00:32:02 about performance really you can change
00:32:04 the code and so and and and often it's
00:32:08 way easier to change the code than it is
00:32:10 to go write meta coding into a compiler
00:32:14 and then do all this kind of stuff and
00:32:15 so it's not that that's bad it's it's
00:32:17 just that it's it's designed for a
00:32:19 specific thing and when you're designing
00:32:20 language you can decide where in that
00:32:21 Spectrum you want to be and what
00:32:22 tradeoffs you want in the case of Mojo
00:32:24 what we have is we have a lot of a lot
00:32:26 of the ability to choose because we're
00:32:28 replacing a lot of lovm and a lot of
00:32:30 this kind of stuff and we're not
00:32:32 building on the python implementation um
00:32:34 and so we have a lot of choice there and
00:32:36 it gives us a lot of freedom but not
00:32:38 full Freedom right because we are still
00:32:39 building on parts of lvm and so like
00:32:41 coves you picked in very interesting
00:32:43 example C moves are a very simple thing
00:32:46 where um you know lvm will flatten
00:32:50 sufficiently small things just like
00:32:51 you're saying and it gives you almost no
00:32:53 control over that as a language author
00:32:56 like there's no way to express this in
00:32:57 lvm like don't do that and and that can
00:33:01 be really bad for very very narrow but
00:33:04 for very specific things and so there
00:33:06 are some workarounds but it's it's not
00:33:09 great yeah well even bigger example is
00:33:11 inlining um so like inlining in general
00:33:14 like uh anytime a language gives me an
00:33:17 option to control inlining and say like
00:33:19 inline always or inline never something
00:33:20 like that one of the things I always
00:33:22 think about and because a question that
00:33:23 I've had for rock is like should we
00:33:24 introduce something like that we don't
00:33:25 currently have it should we is that
00:33:27 every single time I write a function I
00:33:28 always think about that a little bit
00:33:30 little part of me is like every single
00:33:31 time like should should I should I try
00:33:33 to control the inlining it and then if
00:33:34 it's like a oneline function I'm like
00:33:36 it's gonna get inlined anyway it's fine
00:33:38 you know but past a certain point I'm
00:33:39 like do I want to make sure it's in line
00:33:41 or do I not want it to be in or never
00:33:43 this and then you get people that just
00:33:45 put always in line on everything and now
00:33:46 your compile time is just ridiculous and
00:33:48 your code size is ridiculous and they
00:33:50 don't actually but they're just pulling
00:33:52 it Forward because they see it somewhere
00:33:53 else so well in a lot of cases it's
00:33:55 probably oh yeah that could that could
00:33:56 totally happen oh but in a lot of cases
00:33:58 I assume it's probably just like
00:34:00 harmless in the sense that the optimizer
00:34:01 was GNA I've heard the joke that I think
00:34:03 this is about LM actually that the like
00:34:05 the inline her istic is yes like it's
00:34:08 like always in line
00:34:09 basically yeah I'm sure it's not quite
00:34:12 true obviously but yeah I think that's
00:34:14 not quite true but I mean I could see
00:34:15 how you could feel that way um so in the
00:34:18 space of ner nerdery right I mean in a
00:34:20 zeroc cost substraction language where
00:34:22 you're composing very simple things so
00:34:24 uh Mojo for example is a zeroc cost
00:34:28 substraction language built on top of ml
00:34:30 at the bottom right so it's turtles in
00:34:32 terms of strs and functions and stuff
00:34:34 like this kind of similar to a rust or
00:34:36 C++ but it's like turtles all the way
00:34:37 down and then at the very bottom um in
00:34:40 our case int for example is not built
00:34:43 into the language int is just a struct
00:34:46 okay and so in is a struct int is a
00:34:49 struct tuple is a struct like all the
00:34:51 like array obviously is like a struct
00:34:53 and things like this but yeah int is not
00:34:55 built into the Mojo language at all
00:34:58 right there's nothing oh I see so it's
00:35:00 like a struct of bites or bits even like
00:35:03 and so what's inside of it what's inside
00:35:04 of it is an ml magic thingy right and
00:35:08 what what Mojo is is it's syntactic
00:35:10 sugar for ML at the bottom of that stack
00:35:14 right now I see so ml will see like this
00:35:16 is a one field struct like ml will
00:35:18 recognize that like by struct you mean
00:35:20 32-bit integer well so we use there's
00:35:23 like an ml magic thing that you can get
00:35:25 direct access to anything in ml in
00:35:28 and so what int is is int is um you know
00:35:32 a struct but then also implements all
00:35:34 the operators that You' expect for an
00:35:36 integer to have like plus and and it
00:35:38 implements them in terms of all the mlr
00:35:39 magic and so it's just like in a seed
00:35:41 language you'd have like built-in pop
00:35:43 count or something like that um it's
00:35:46 just way more fancy than that but it's
00:35:48 the same kind of idea and you you won't
00:35:50 don't want to sprinkle built-in pop
00:35:51 count into all of your code what you do
00:35:53 is you write some big in class or
00:35:56 something you'd have a popc count method
00:35:57 right and and stuff like this and so
00:35:59 it's the same kind of idea but um but
00:36:01 anyways in terms of inlining like
00:36:03 there's a small bit of nerdery you might
00:36:04 want to think about for rock uh which is
00:36:07 um if you're at the very bottommost
00:36:09 level of the stack you don't want people
00:36:11 to see these
00:36:13 abstractions and so Plus on int you
00:36:16 don't want to step into that in a
00:36:18 debugger and so a thing you might want
00:36:20 to look at is not just always in line
00:36:23 but always in line and throw away the
00:36:24 debug info and so l do that and this is
00:36:28 something where that way you don't step
00:36:30 into Plus on your integer because that's
00:36:33 not something anybody actually wants to
00:36:35 do and it can make a better U ux as well
00:36:37 as yeah make sure that plus gets
00:36:39 inlined right yeah we've we've thought
00:36:42 about that um so our we we call them
00:36:44 built-ins like our standard Library just
00:36:46 because it's like baked into the
00:36:47 compiler but um we we have them
00:36:50 implemented in a mix of uh Rock and also
00:36:53 in like lower level magic things that
00:36:55 only the compiler has access to so if
00:36:57 you look at some of the built-in files
00:36:59 sometimes it'll just have like a
00:37:01 function and it's just a type annotation
00:37:02 there's no implementation and that's
00:37:04 because the compiler just magically
00:37:05 inserts one so for things like that we
00:37:07 certainly have to be like yeah no no
00:37:08 debug info past this point you know stop
00:37:10 here um but then there's other ones
00:37:12 where we've thought about like maybe we
00:37:14 want to just not do debug info on them
00:37:15 just because we want to reserve the
00:37:17 right to change the implementation we
00:37:19 kind of want it to appear like a black
00:37:20 box like look don't someday it might
00:37:22 become one of those internal only things
00:37:23 so don't assume that this is what's
00:37:24 actually happening just because it
00:37:26 happens to be right now yeah that's
00:37:28 right well so it's it's a fun thing that
00:37:29 you get to design and control a lot of
00:37:31 these different things and there isn't
00:37:32 one right answer and so you can iterate
00:37:34 a so yeah so speaking of numbers I was
00:37:37 actually there there's two aspects of
00:37:39 Mojo's number system that I'm really
00:37:41 curious about uh one is you mentioned um
00:37:44 in in the previous talk you gave about
00:37:45 Mojo you sort of hinted at um Hardware
00:37:48 accelerated complex numbers which I'm
00:37:50 kind of curious about um and the other
00:37:52 thing is uh you made reference to the
00:37:55 fact that numbers are sort of all
00:37:57 vectorized by default in some sense and
00:38:00 the scalers are sort of a special case
00:38:01 of that it's like like a 8bit integer is
00:38:05 like a one
00:38:06 lane8 bit Vector something like that so
00:38:10 yeah I just love to know more about
00:38:11 those things yeah so so let me let me
00:38:13 frame this by explaining um something
00:38:16 that for example C++ programmers will
00:38:17 have seen right so in
00:38:19 C++ um again a language I've written
00:38:22 millions of lines of code in literally
00:38:24 and so I am allowed to have an opinion
00:38:26 on this
00:38:28 it it It suffers from a lot of history
00:38:30 okay and so in C++ for example int and
00:38:33 Float are built into the language they
00:38:35 have magic promotion roles there's a
00:38:36 whole bunch of really weird stuff that
00:38:38 happens like this simd still isn't
00:38:41 really first class there are various
00:38:43 extensions for example clang and GCC
00:38:44 both support extensions but it's not
00:38:46 really first class um C++ also has a
00:38:50 fairly horrible but getting better
00:38:52 metaprogramming system around coner and
00:38:55 templates and stuff like this okay so so
00:38:57 just to frame this uh Mojo solves all
00:39:01 these problems so first
00:39:03 metaprogramming Mojo learns from
00:39:05 languages like Zig and says let's not
00:39:08 use a different language for programming
00:39:10 than we used for meta programming so
00:39:12 don't say you write you know void Fu
00:39:14 parthy parenthese to write a function
00:39:17 but you write template blah blah blah
00:39:18 blah blah blah blah to write a meta
00:39:19 program instead just WR a function and
00:39:22 now you can use the function both at
00:39:23 comp time and at runtime and so so Mojo
00:39:26 Mojo does that and so that unifies a
00:39:29 huge amount of stuff that often hangs
00:39:31 out in macro land or pre-processor land
00:39:33 or template land and things like this
00:39:35 into a very uh very nice thing right
00:39:38 second thing we do is we say all of the
00:39:41 numbers and values and things like this
00:39:43 are defined in the standard Library so
00:39:45 Mojo's standard library is very open
00:39:47 source you can go check out struct int
00:39:49 and float and things like this and go
00:39:52 check it out and see all the Mr uh
00:39:54 low-level stuff inside of it um and so
00:39:57 as a consequence of that we can choose
00:39:59 how we want to implement this and so
00:40:00 when we Implement first of all simd we
00:40:03 have a simd type simd takes a element
00:40:06 type so are you a float 32 or 64 or B
00:40:08 float 16 or a float 8 or float 4 there's
00:40:12 lots of complexity these days in this um
00:40:14 but then also as you say what how how
00:40:16 big is the simd vector so do you have
00:40:18 four elements or eight or 64 or whatever
00:40:21 right and so having simd as a struct in
00:40:24 Mojo using parametric
00:40:27 meta programming now means that the lane
00:40:30 Dimension so how wide is it is now
00:40:33 parameterized in comp time okay the
00:40:36 element type the dtype is parameterized
00:40:38 in comp time right and so now what that
00:40:40 means is you can build and and it has
00:40:42 very nice methods for swizzling and all
00:40:44 the things you'd want it's all very
00:40:45 natural it's all it all feels very first
00:40:47 class and oh by the way all processors
00:40:49 have have simd since like the late 90s
00:40:52 and so like why is it that no languages
00:40:54 have embraced modern computers it's
00:40:56 unclear to me
00:40:58 and so what that means though is think
00:41:00 about this from a library ecosystem so
00:41:02 when you start if you're a numeric
00:41:03 programmer and you want to use simd well
00:41:05 sure you want to do plus and minus and
00:41:08 things like this but you also want to do
00:41:10 things like sign and cosine mhm and so
00:41:13 as a C++ programmer it's like cool I
00:41:14 have sign and cosine they come from libm
00:41:16 where do I get a 4X float sign oh now
00:41:20 you're in the mode of there's 497
00:41:22 different libraries none of which are
00:41:23 compatible and now there's this
00:41:24 fragmentation at the bottom of the stack
00:41:26 and now stuff built on top of sign and
00:41:28 cosine like an AI
00:41:30 framework or a ray Tracer or whatever
00:41:33 right they get built on top of different
00:41:34 libraries and now the whole software
00:41:36 ecosystem is not unified because simd at
00:41:38 the very bottom is a mess so what Mojo
00:41:42 does is we say okay well a couple of
00:41:44 things one is have a comp time meta
00:41:46 programming system second is put all
00:41:48 these core types in the library and use
00:41:51 the comp time but then what you're
00:41:52 referring to is we go one step further
00:41:55 and we say our scaler types are just a
00:41:57 special case of the simd types and so if
00:42:00 you go look up uh float 32 for example
00:42:03 float 32 is just a type alius for simd
00:42:06 of float 32 comma 1 and so what that
00:42:10 means is that means that we can now
00:42:12 write things like s and cosine write
00:42:15 them parametric across the length of the
00:42:18 vector and so it's just paramet you pass
00:42:20 in and now we have one implementation of
00:42:22 sign that works on vectors it also works
00:42:24 on scalers and what and what you're
00:42:27 incentivizing as you're incentivizing
00:42:28 people that are writing numeric
00:42:29 algorithms they're already generally
00:42:31 thinking about genericity because they
00:42:32 care about both float 32 and Float 64
00:42:35 right and so what you do is you say like
00:42:37 okay we'll just add yeah if it's an
00:42:38 element wise op it's trivial to make it
00:42:40 work uh for any length and now your
00:42:42 whole ecosystem at the bottom becomes
00:42:44 simpler and this just defines away a ton
00:42:45 of complexity for the software Library
00:42:49 ecosystem so does that mean that you can
00:42:51 have Vector operations that are defined
00:42:53 for scalers like for example can you
00:42:54 Swizzle an 8bit integer uh yes but the
00:42:57 index space is only uh zero so you can
00:43:00 Swizzle zero with itself yes okay yeah
00:43:03 that makes sense so uh one of the other
00:43:05 things that I've thought about is so I
00:43:07 haven't written that much syb code um
00:43:09 compared to you certainly compared to
00:43:11 plent of other people um but one of the
00:43:13 things I have noticed is that often
00:43:15 times if I'm writing like a Syd
00:43:17 algorithm that's going to do something
00:43:19 fairly complicated or fairly tricky and
00:43:22 then I implement it for like Neon versus
00:43:25 if I implement it for like x64
00:43:27 um they they end up using in some cases
00:43:30 just pretty fundamentally different
00:43:32 instructions that have different apis so
00:43:35 is that something you think about like
00:43:36 do you do you expose like different
00:43:38 intrinsics for different architectures
00:43:40 or do you try to unify those and say
00:43:42 like here's a way we can patch over
00:43:44 those differences yeah great question so
00:43:47 this this is a really important question
00:43:48 and this you're also talking about like
00:43:50 uh complex numbers and accelerating uh
00:43:52 there's this whole Space of accelerating
00:43:54 block operations like a lot of processes
00:43:56 these days have like little matrix
00:43:58 multiplication operations or you have
00:43:59 tensor cores on GPU and things like this
00:44:02 so our approach on that is multi-layered
00:44:04 one is expose the full power of the
00:44:07 hardware and so if you want to use a
00:44:09 neon uh thing or you want to use altc or
00:44:13 you want to use viz on spark or you want
00:44:15 to
00:44:16 use MMX on Intel whatever like you could
00:44:20 totally go nuts and you do whatever that
00:44:23 chip wants chip at the very low level
00:44:25 and then it's specific to that chip
00:44:26 uhhuh you have Target specific
00:44:28 compilation you're like this I'm
00:44:29 building this Mojo code just for Intel
00:44:31 yeah okay yep and and and now you can
00:44:34 say on top of that at param at comp time
00:44:37 at parameter time you can say if I'm on
00:44:39 this target use this code path okay
00:44:42 right so think of it as ifs but way
00:44:44 cooler and um and so now if you do that
00:44:48 then that what that allows that allows
00:44:49 Library developers to be able to build a
00:44:51 higher level abstraction like let's do a
00:44:53 blend which is a generally understood
00:44:55 thing or let's do a linear interpolation
00:44:58 or let's do like you you can Define
00:44:59 these higher level Library abstractions
00:45:01 and then what that allows you to do is
00:45:03 that you compose one into the other and
00:45:05 you say okay well um if I'm building a
00:45:07 matrix multiplication for example you
00:45:09 can Implement in terms of
00:45:11 scalar multiplies and ads at the very
00:45:13 bottommost level of the stack but then
00:45:15 you say okay well the API I give out to
00:45:18 my users at the top level is this go go
00:45:21 apply mmol to a big block of memory you
00:45:23 know an array or a tensor and then what
00:45:26 that allow in that whole algorithm has
00:45:27 recursive decomposition and a whole
00:45:29 bunch of complexity within it and so
00:45:31 then what you allow is you allow
00:45:32 different layers at the at the within
00:45:36 that implementation be able to Fork off
00:45:37 to Hardware specific implementations and
00:45:40 so this way you allow Library developers
00:45:42 to build that Hardware abstraction
00:45:43 instead of having the the compiler have
00:45:45 to do this and one of the major things
00:45:47 that Mojo does in general is it's about
00:45:49 forcing complexity out of the compiler
00:45:51 and force it into the libraries and the
00:45:54 rationale for this is that that very few
00:45:56 people people can't even work on
00:45:58 compilers I mean you've noticed it's
00:46:00 kind of a different art but lots of
00:46:02 people can build libraries and
00:46:03 particularly if you and particularly if
00:46:05 you make it super easy to build these
00:46:07 things you make the language super
00:46:08 consistent and simple by making
00:46:11 everything be a library then what you're
00:46:13 doing is you're encouraging very high
00:46:15 power highly expressive libraries to be
00:46:17 built and then you allow the ecosystem
00:46:19 figure out the abstractions that make
00:46:21 sense for them and even subdomains like
00:46:23 Graphics versus rate tracing or
00:46:25 something they they can have different
00:46:27 different careabout and they can have
00:46:28 different abstractions that make sense
00:46:29 for them yeah yeah that makes a lot of
00:46:32 sense I I've thought about um it's
00:46:34 almost like a funnel where you have
00:46:36 application developers and there's a
00:46:37 huge number of application developers
00:46:39 out there and then a subset of
00:46:40 application developers are also Library
00:46:42 developers I guess theoretically you
00:46:43 could have someone who's exclusively
00:46:44 Library that's really hard to find and
00:46:46 then within that you get a much smaller
00:46:48 percentage of those that are like
00:46:49 framework authors and then Bel that you
00:46:52 have compiler authors as like the sliver
00:46:54 among all application authors and yeah
00:46:57 it's it's definitely increasingly niche
00:47:00 as you as you go further and further
00:47:01 down those l and a lot of a lot of my
00:47:03 quests with Mojo is about um so I built
00:47:06 a lot of compilers I know a lot of
00:47:07 compiler Engineers across my career and
00:47:10 I love them all and and very special but
00:47:13 but that pyramid or funnel or however
00:47:15 you look at it is is really interesting
00:47:18 because compiler Engineers are special
00:47:20 and beautiful and wonderful and I love
00:47:22 them in their own way but they also
00:47:23 don't know a lot about the domain
00:47:24 problems yeah right
00:47:27 some things and and but and so what you
00:47:29 get is it's not that compiler Engineers
00:47:31 are smarter better looking than the
00:47:34 other I mean I
00:47:36 mean I mean I mean yeah so but the uh
00:47:41 but what you get is you you I think
00:47:43 about this as an ecosystem of talent
00:47:45 yeah right and like when you're
00:47:47 programming a GPU there's there's this
00:47:49 whole range of recently there's all
00:47:51 these like special compilers for ML and
00:47:53 a lot of them compilers for machine
00:47:55 learning and a lot of it is like like
00:47:57 let's go put these algorithms into a
00:47:58 compiler but the compiler Engineers
00:48:00 don't know the best way to get full
00:48:02 power of the GPU they don't know all the
00:48:04 numeric tricks they don't know how to
00:48:06 cheat in the case that you know the low
00:48:09 Precision blah blah blah blah blah
00:48:11 thingy or the the fancy Swizzle that the
00:48:13 GPU does internally and stuff like this
00:48:15 and making that happen in a very general
00:48:17 way is very difficult whereas a numeric
00:48:19 kernel programmer knows gpus really well
00:48:21 but doesn't know compilers they know all
00:48:23 the tricks they they they they know how
00:48:25 the profile works sometimes they design
00:48:27 the hardware themselves right and so I
00:48:29 look at you know my my quest with Mojo
00:48:31 is really about unlocking those people
00:48:33 and giving them superp Powers rather
00:48:36 than a trend that I've seen over the
00:48:37 last 5 10 years in the space of like put
00:48:41 sophistication into the compiler lock it
00:48:42 up throw away the key and trust us us
00:48:45 compiler people have got it because you
00:48:47 know what I've seen is that that's not
00:48:49 actually really that true right instead
00:48:51 what I see is compiler folk and library
00:48:54 and Newar kernel and application Level
00:48:56 and domain people like they all come at
00:48:58 the prom and they bring different skill
00:48:59 sets to bear and a compiler is rarely
00:49:02 going to give you TX Improvement but
00:49:05 somebody working at the application
00:49:06 domain because they know the application
00:49:08 totally can because they can use the
00:49:10 right tool for the job right yeah and
00:49:12 that that seems to be especially true
00:49:13 when it comes to simd like autov
00:49:15 vectorization historically has had a
00:49:17 really low success rate in terms of
00:49:19 approaching what a a human programmer
00:49:21 can do or maybe now on llm but I'll make
00:49:24 fun of us as an industry again I hope
00:49:27 you know that I love compiler people you
00:49:29 know like I love PL people but but let
00:49:32 me make fun of us as a category um it
00:49:35 was the late
00:49:36 90s early 2000s where like at least us
00:49:40 and working on PCS and things like this
00:49:42 is like oh multicore is coming multicore
00:49:44 is the future like parallel Computing is
00:49:46 going to be here like we need to have
00:49:48 these fancy abstractions so we can do
00:49:50 parallel compute and a lot of people
00:49:52 talked about it there were things like
00:49:53 Silk obviously open MP and MPI and
00:49:56 things like this fast forwarded today
00:49:58 people are still using p threads like
00:50:00 after models that are still obscure like
00:50:02 I mean there's like all this stuff that
00:50:03 really hasn't penetrated and so much
00:50:05 code is still single threaded like lvm
00:50:08 for example but also yeah a lot of other
00:50:11 code the progress we've made has been
00:50:13 mostly in like there's actually a dual
00:50:16 world of there's the really structured
00:50:18 HPC style compute and then there's the
00:50:19 actor models and things like this that
00:50:21 are very good at decentralized
00:50:23 asynchronous compute and it's super
00:50:25 funny when you look at that that
00:50:27 like Auto paralyzing compilers didn't
00:50:29 solve the problem what we did is we
00:50:32 built higher level things and then we
00:50:33 allowed experts to be able to express
00:50:35 them and that that was where progress
00:50:36 came from not not the silk or you know
00:50:39 the magic Solutions like that well and I
00:50:41 think I mean this is where a lot of
00:50:43 people listening are being like this is
00:50:44 why functional programming will will
00:50:45 ride to the rescue because uh there was
00:50:48 also I think around the 90s like the
00:50:49 paper that always comes to mind is John
00:50:51 Hughes like why does functional
00:50:52 programming matter and he talks about
00:50:53 Mo's laws coming to an end and you know
00:50:56 more cores are the future and therefore
00:50:58 we need to be able to write pure
00:50:59 functions that can be distributed across
00:51:01 cores without you know data rases and so
00:51:03 on so forth a classic example that
00:51:05 people give of this is quick sort and
00:51:07 when they say quicksort they don't mean
00:51:09 the classic quick sort that's like
00:51:10 here's a flat array and we're going to
00:51:12 go through and swap elements in the
00:51:14 array back and forth and what ends up
00:51:16 happening in this hasal implementation
00:51:18 of quote unquote quick sort is that it's
00:51:21 doing like five allocations per
00:51:23 iteration and then that like gets
00:51:25 potentially worse than that depending on
00:51:27 like how the data is arranged and it's
00:51:29 this totally but it's three lines of
00:51:32 code right and it's it looks very
00:51:34 elegant and it looks much nicer than
00:51:36 quick sort which perhaps is because it's
00:51:38 not quicksort but I I just I look at
00:51:40 that and I'm just very frustrated
00:51:42 because when I see people talk about
00:51:44 this like oh look and and let me show
00:51:45 you this beautiful graph of you can take
00:51:47 this algorithm and unlike traditional
00:51:49 quicksort you can run it across end
00:51:51 cores and it just keeps getting faster
00:51:53 and faster it's amazing and I'm like
00:51:54 well but how does it compare to actual
00:51:56 regular quicksort if you run them side
00:51:58 by side I'm like I already know the
00:52:00 answer to that it's going to get
00:52:01 absolutely obliterated there like if you
00:52:02 draw if you put actual quick sort on the
00:52:04 graph it's going to be one pixel at the
00:52:06 bottom because this is so much slower
00:52:08 than that and every no matter how many
00:52:09 cores you throw at it and that sort of
00:52:12 thing is the the type of thing that to
00:52:14 me there's in the functional programming
00:52:16 Community a little bit of a mismatch
00:52:18 between in my mind what the observable
00:52:21 benefits of a functional programming
00:52:22 style are where you're like maximizing
00:52:24 pure functions and things like that and
00:52:26 what are the theoretical benefits that I
00:52:28 think are a lot harder to achieve in
00:52:30 practice than people there's a lot of
00:52:32 hand waving going on I guess is what I'm
00:52:33 trying to say and I I I think it's uh
00:52:35 unfair it's it's not
00:52:37 reasonable well uh how can I react to
00:52:41 that do you want me to well you can you
00:52:43 can push back and say Richard you're
00:52:44 totally wrong about that if that's what
00:52:46 you believe but I kind of have a
00:52:47 suspicion that you probably agree
00:52:49 already well so so what I would say is
00:52:51 that um the definition of functional
00:52:54 programming is extremely controversial
00:52:57 true so scholar programmers think
00:52:59 they're functional programmers even
00:53:00 though they have massive reference
00:53:02 sematic mutable State all over the place
00:53:04 and it's more of a a branding than it is
00:53:07 a reality and so if you talk to Haso
00:53:10 programmer they'd say that ok camel is
00:53:12 not a functional programming language
00:53:13 because it's strict right and so that's
00:53:16 that's not functional right and so I
00:53:18 think that the the the you know the
00:53:20 religious wars can be fought on the back
00:53:22 the it's a big things that I don't care
00:53:25 about
00:53:27 so I'll tell you I'll tell you what I
00:53:28 care about I love functional programming
00:53:30 because it gives you it defines way
00:53:32 spooky action at a at a distance right
00:53:35 and if I were to pick camps like in
00:53:37 terms of like a a reasonable a language
00:53:40 I would like to use to build things
00:53:42 that's in the functional Spectre I would
00:53:44 prefer okam rather than hasal just
00:53:47 because okam is strict it is fits better
00:53:51 more control things like this and OK
00:53:53 camel achieves lack of spooky action a
00:53:56 mostly um because of uh things that
00:54:00 really have nothing to do with
00:54:00 strictness right but now the challenge
00:54:02 with this is if you take it all the way
00:54:04 to its extreme you say okay well I'm not
00:54:06 going to allow mutation like so some
00:54:08 functional some people Define functional
00:54:10 programming as no mutation then um one
00:54:13 of the challenges you get into is that
00:54:15 you as you say quick sorting an array
00:54:19 means that you cannot do imp Place
00:54:20 mutation of the array and so every
00:54:23 change to every element ends up being an
00:54:25 O of n operation cuz you have to
00:54:26 reallocate the end elements or the end
00:54:29 buckets right and so you're destroying
00:54:31 algorithmic complexity for the sake of
00:54:33 Purity and so this is where um hey I hey
00:54:36 I I heard there's this cool language
00:54:37 called Rock but there's also other
00:54:38 languages like Swift and things like
00:54:40 this that give you the benefit of
00:54:42 functional programming but allow in
00:54:44 place mutation and that's way better for
00:54:46 the actual machine and you know what
00:54:48 Swift calls this is value sematics yeah
00:54:51 and saying look you can Define first
00:54:53 class values first class values Define a
00:54:54 way spooky at action in a distance yes
00:54:56 you can have an array of array of
00:54:57 dictionaries of strings of whatever
00:55:00 right and it's purely value semantic
00:55:02 just like it would be in a functional
00:55:03 programming language but because of
00:55:05 behavior in the language and in the
00:55:06 library and how it's implemented you get
00:55:08 in place mutation yeah and that's a huge
00:55:11 you get the benefit of the functional
00:55:13 programming style without the curse of
00:55:14 having to reallocated the entire tree
00:55:17 just because you want to change one of
00:55:18 the leaves yeah and I mean the thing
00:55:20 that uh is as far as I know rock is
00:55:22 unique in like among functional
00:55:24 languages that are not just research
00:55:26 language like there's research languages
00:55:27 that have done this but we're trying to
00:55:28 actually be like a you know commercially
00:55:29 used language um is that we have the
00:55:32 concept of there is no language level
00:55:35 user facing concept of mutation it's
00:55:37 purely an optimization and so uh like
00:55:40 the really simple example of this is
00:55:42 like if the reference count is one we're
00:55:44 not cloning that we're just gonna use
00:55:45 the one you got in in place like we do
00:55:47 AOA reference counting but then we also
00:55:49 have static analysis that says you don't
00:55:50 even need to check the reference count
00:55:51 at run time we just know yep um I gave a
00:55:54 talk I don't know if you've seen this um
00:55:55 like in 2021 strange Loop called uh
00:55:57 outperforming imperative with uh purely
00:55:59 functional languages or something like
00:56:00 that and um the the punchline of the
00:56:03 talk is I'm going to spoil the ending
00:56:04 for those who haven't seen it is that we
00:56:06 do a quick sort Benchmark that's actual
00:56:08 quick sort and it's like we have C++
00:56:10 Rock um go Java and JavaScript and we
00:56:15 didn't put Swift in there I don't know
00:56:16 how swift would have done but um but at
00:56:18 the end with all of Rock's optimizations
00:56:19 we actually and The Rock implementation
00:56:21 looks much worse than the others because
00:56:23 you have to do recursion and stuff and
00:56:25 it's relying on tail call optimization
00:56:26 and stuff like that but it does actually
00:56:28 we we were second only to C++ C++ was
00:56:31 faster no surprise there but we actually
00:56:32 were managed to get it to be faster than
00:56:34 go slightly faster than go not a lot but
00:56:36 slightly faster than go which of course
00:56:37 all the other ones were just using
00:56:39 explicit Direct in place mutation and to
00:56:41 me and that that by the way that's not
00:56:43 going to be paralyzable in the same way
00:56:45 like for free that the has is fair
00:56:47 enough um but it's not trying to be like
00:56:49 the point in my mind is that but but to
00:56:52 your point you're training off otation
00:56:53 for the the ability to use multiple
00:56:55 cores that's kind of
00:56:57 yeah well but I mean I think there is a
00:56:59 there is a relevant distinction in that
00:57:01 like one of the things that I've been
00:57:02 asked as recently as earlier this week
00:57:04 by somebody else on Rox zulip was um
00:57:06 somebody was asking about um like hey
00:57:08 like isn't isn't rust essentially a
00:57:10 functional programming language because
00:57:12 or like I would argue that rust is and
00:57:14 my having spent a lot of time using rust
00:57:16 it doesn't feel like a functional
00:57:17 programming language in any way I mean
00:57:19 again this this gets back to your your
00:57:21 arguing definitions of what functional
00:57:22 programming mean yeah right well so so
00:57:25 so I mean I that's a really so with rock
00:57:28 I'm a huge fan by the way I I think that
00:57:29 I haven't had a chance to use it but I'm
00:57:31 a huge fan of your work and I think that
00:57:32 you're working on very fundamental
00:57:33 things and I love that thank you um the
00:57:35 the I'm not aware of other languages
00:57:37 that have done that Swift's approach on
00:57:38 that was to say um mutation is explicit
00:57:42 but then um when you do something that
00:57:46 would require a copy and it works the
00:57:48 same way with ref count equal one
00:57:49 basically right um don't make the copy
00:57:52 if ref count is greater than one make
00:57:54 the copy and so it's just it's like a
00:57:55 slight different bites it's not right in
00:57:57 a functional style it's right in an
00:57:59 imperative style but it gives you
00:58:00 functional Behavior yeah and so it's a
00:58:02 diff different different trade-off and I
00:58:03 agree with you it's a very different
00:58:04 thing but um one of the benefits of this
00:58:07 is that it enables you to beat
00:58:09 C++ things like this and allows you to
00:58:11 paraliz things and because you can now
00:58:13 say hey I I give me a view on these
00:58:16 elements and uh so one of the problems
00:58:18 with with any of these languages that if
00:58:20 you compare again C++ is that just
00:58:22 indexing in the array reasonable
00:58:24 languages want to bounce check that
00:58:25 index yeah right and so one of the
00:58:28 things that Swift can do is you can say
00:58:30 okay well give me a view on this array
00:58:34 um and give me an unsafe view and say
00:58:37 just I'm going to write generic code a
00:58:40 generic algorithm that works on any
00:58:42 sequence or any collection and your
00:58:44 generic algorithm you can apply either
00:58:46 to the array or you could apply it to an
00:58:48 unsafe view on the same array and so
00:58:52 then what you can do is you can say Okay
00:58:53 I I care about performance of bounce
00:58:56 checking or something for some reason
00:58:58 and say you know with one line of code
00:59:00 you can swap from saying okay well I
00:59:01 have the safe thing to the unsafe thing
00:59:02 and I don't have to rewrite the entire
00:59:03 algorithm if it was written in a generic
00:59:05 way so our version of that is to have
00:59:08 like because this is kind of the style
00:59:10 and functional languages anyway is to
00:59:11 have like standard Library operations
00:59:14 that use unsafe behind the scenes but
00:59:16 Pro provide only a safe API to that so
00:59:18 great example of this is map like list.
00:59:20 map you're like I want to transform
00:59:21 every element in this under the hood
00:59:23 we're doing a for loop with you know
00:59:25 unsafe you know pointer bumps but you
00:59:27 never see that and but you don't pay for
00:59:28 the bounce check either I mean Swift and
00:59:30 Mojo do the same thing right so in our
00:59:32 case we don't put in the the language
00:59:34 and we don't have special built-ins we
00:59:36 just put in the library like Russ is a
00:59:38 very interesting community in a culture
00:59:40 because a lot of people don't like
00:59:42 unsafe code but rust has a very weird UB
00:59:47 filled definition of what unsafe means I
00:59:49 know it's it's a very sharp there's a
00:59:52 very sharp tool that's being held there
00:59:54 but but in Swift remote
00:59:56 the the observation is it's like array
00:59:59 which is built into the library not into
01:00:01 the compiler like it is at R like is
01:00:04 implemented with effectively malakin
01:00:06 free and unsafe pointer stuff on the
01:00:08 inside but then the API to array is safe
01:00:12 even though the implementation's unsafe
01:00:14 right and so a lot of a lot of the idea
01:00:16 just like you're talking about is you
01:00:18 you use unsafe constructs to build a
01:00:20 safe API and it's an API design problem
01:00:22 um but again with Russ it's super
01:00:25 interesting how they have this culture
01:00:26 and the theory of like let's get unsafe
01:00:28 out of the packages entirely and that's
01:00:31 just a very different cultural position
01:00:33 then right it is but I actually see it
01:00:35 as a cultural dysfunction of the Russ
01:00:36 community and I can say that because I
01:00:38 spent a huge amount of time writing Russ
01:00:39 code and I do it my day job at Zed so
01:00:41 like I I always imagine the Drake meme
01:00:43 where he's like you know looking at one
01:00:45 thing like oh yeah that's great looking
01:00:46 at the other one like oh no and it's
01:00:48 like he when he looks at the thing and
01:00:50 says oh no it's unsafe keyword being
01:00:53 used in my code base and then for the
01:00:55 like oh yeah this is great it's like
01:00:57 literally cut the code out of my code
01:00:59 base and put it into a package and then
01:01:01 publish the package and now it's like
01:01:03 yeah now it's great like as long as it's
01:01:05 behind a package that's got to you know
01:01:07 like separately published somewhere
01:01:09 else well I agree with you I wouldn't
01:01:12 say it that strongly but what I would
01:01:13 say is like the thing I'm identifying
01:01:14 here is that different programmers will
01:01:16 will balance religion versus pragmatism
01:01:20 sure and so if you want to call into an
01:01:22 existing sea Library it's going to be
01:01:23 unsafe because God knows what the C code
01:01:26 is doing right and so and there's a lot
01:01:28 of really useful code out there and it's
01:01:30 dusty deck and you don't want to have to
01:01:31 change it and so it's very pragmatic to
01:01:34 build on top of unsafe code now Malik is
01:01:36 one example of that it's unsafe like or
01:01:39 free you know Malik may be aafe but free
01:01:42 right yeah and so um but but that
01:01:46 doesn't mean that Mal and free are bad
01:01:48 what it means is you don't want to
01:01:49 expose like you talking about earlier
01:01:51 the the first thing you reach for should
01:01:53 be a type safe array that is memory safe
01:01:57 but that array can be built out of
01:01:59 unsafe components right and in the case
01:02:01 of rust they just hardcode the array
01:02:04 into the language which they had to
01:02:06 because of some of the language design
01:02:08 decisions they made I guess or maybe it
01:02:10 was an accident of History maybe they
01:02:11 don't have to I can't speak to that but
01:02:13 U but in the case of moo we're like no
01:02:15 well rays are not special they're just
01:02:17 they're called list actually because of
01:02:19 python DNA but um uh but actually
01:02:23 there's lots of kinds of arrays there's
01:02:25 inline arrays there's fix size arrays
01:02:28 there's Heap allocated thingies there's
01:02:29 all like we don't want just one kind of
01:02:31 array we there's a lot of a big world
01:02:33 out there and we want them all to be
01:02:34 first class or field first class to
01:02:37 library developers and so hardcoding any
01:02:38 one of them into the library or into the
01:02:40 language would be a little bit weird
01:02:42 yeah there's this whole spectrum of
01:02:45 Concepts around error handling and it's
01:02:47 sort of weird to me that um we the the
01:02:50 way that we think about error handling
01:02:52 and performance in particular has some
01:02:54 strange trade-offs so some examples um
01:02:57 if I'm talking about scaler integer
01:03:00 Edition uh that can overflow and if it
01:03:02 overflows it wraps around like by
01:03:04 default at the CPU level and that can
01:03:06 cause all sorts of horrendous bugs um I
01:03:08 was asking people about overflow bugs
01:03:09 they've seen and somebody talked about
01:03:10 like a router or something having an
01:03:13 overflow bug and it resulted in just
01:03:14 like total disasters but at the same
01:03:16 time I mean for for for for reference uh
01:03:19 Swift uh traps on overflow by yeah okay
01:03:22 so which totally makes sense that's rock
01:03:24 rock does the same thing um
01:03:26 now rust what rust does in that space is
01:03:29 it says well in debug builds uh we trap
01:03:31 on overflow but in release builds we
01:03:34 don't do that and I believe that's what
01:03:35 C++ does I don't know what Mojo does but
01:03:38 I thought about that design decision we
01:03:39 talked about it but the thing that I
01:03:40 don't like about it is that that is
01:03:42 exactly the type of bug that is unlikely
01:03:44 to be hit by any of your tests and like
01:03:47 if you're if you don't do the bounce
01:03:49 check at runtime that's most likely when
01:03:51 you're going to see like after you got
01:03:53 it deployed in production and somebody
01:03:54 hit it with a really weird data set
01:03:56 that's when it's going to hit the
01:03:57 Overflow and so it feels like it's it's
01:03:59 like you might as well just you know
01:04:01 acknowledge that you're just going to
01:04:02 have those bugs well better performance
01:04:04 but but but so I actually don't even
01:04:06 know in Rust in release build is it UB
01:04:08 when you do that or is it question uh I
01:04:11 don't it rap so so I I don't I don't
01:04:14 know what uh rust does I will tell you
01:04:18 the pit of Hell that is
01:04:19 C++ I'll tell you what we did in Swift
01:04:22 and I'll tell you what we did in Mojo
01:04:23 and they're all different and I'll tell
01:04:24 you why because again like this this is
01:04:27 um I think illustrative of language
01:04:29 design and it's it's a simple and
01:04:30 accessible thing but it it actually
01:04:32 these decisions really matter and there
01:04:34 isn't one right answer so in in C++ so
01:04:37 please don't do this if you're out there
01:04:38 building a language C++ if you have an
01:04:40 unsigned number it is defined to wrap
01:04:43 with two's complement on overflow and
01:04:45 this is not actually literally True by
01:04:48 the language spec as far as I know but
01:04:51 because there's ones complement machines
01:04:53 theoretically and stuff but in practice
01:04:55 PC and clang and all reasonable c
01:04:57 compilers will guarantee two's
01:04:59 complement overflow and then it is UB if
01:05:03 you overflow a signed integer okay and
01:05:07 so what this allows this allows a c
01:05:10 compiler to say if you take like an INT
01:05:12 and you multiply it by two and then you
01:05:14 divide it by two it can just delete that
01:05:17 and just say I * 2ide by two is equal to
01:05:20 I because if it would have overflowed
01:05:22 then it would have been UB I've heard
01:05:24 about this so that that is that is crazy
01:05:29 and as far as I can tell it comes down
01:05:31 to um like so there is a practical
01:05:33 reason that c compilers need to be able
01:05:35 to cheat on this is It's because on
01:05:37 64-bit targets lots of people use int
01:05:40 which is 32 bits as an induction
01:05:42 variable in a for Loop and if you do
01:05:44 that then you get all these sign
01:05:46 extensions from 32bit to 64-bit and they
01:05:49 tank performance on Loop algorithms and
01:05:51 so there's a reason to do that and so
01:05:53 the problem that c c and C++ have is
01:05:55 they don't like the standard integer
01:05:57 type is not size T uhhuh and so in Swift
01:06:02 int and uint are size T we care a lot
01:06:05 about correctness I think Swift is
01:06:08 massively over it jumped the shark on
01:06:10 correctness and it tried to it tried way
01:06:12 too hard and I mean that's a different
01:06:15 topic but um but so therefore it traps
01:06:17 if you either overflow an unsigned in or
01:06:19 assigned in and then it has specific
01:06:21 operators to do two's complement math
01:06:23 and so you can use plus to do trapping
01:06:26 on overflow math and then Amper stand
01:06:28 plus to do tw's complement math and you
01:06:30 can opt into it so that's the way it
01:06:31 went now as you're saying like the
01:06:33 consequence of this is that all code
01:06:35 everywhere and you can there's crazy
01:06:38 flags that very few people use to turn
01:06:40 the stuff off but but roughly nobody
01:06:42 does um so now there's as you say like
01:06:47 very few people hit these errors and
01:06:48 then when they do it's not clear that
01:06:50 they're going to hit them in debug
01:06:52 they're going to hit them mostly in
01:06:53 production and even then like what does
01:06:56 it mean to trap is that actually great
01:06:58 it's it's unclear um there's actually so
01:07:00 when we got to Mojo there's actually a
01:07:02 bigger problem which is um come back to
01:07:06 simd right integers in simd registers
01:07:09 like in8 for example the whole reason
01:07:12 that you're doing simd math is that you
01:07:14 care about performance like that's
01:07:16 that's actually pretty important and so
01:07:19 you can't say every time you do plus on
01:07:21 a simd of in8 you're going to do an
01:07:24 overflow check yep
01:07:26 not going to happen like that that
01:07:27 completely destroys the entire purpose
01:07:29 of doing this and we want consistency
01:07:31 between scalers and
01:07:33 vectors what we decid to do I don't
01:07:35 think simy even offers like a like a
01:07:37 single instruction way to say like did
01:07:39 any of these overflow at least not that
01:07:41 I could
01:07:41 find I mean you
01:07:44 you so it can be done maybe not in a
01:07:47 single cycle but you you could there's a
01:07:49 design point where you could choose to
01:07:51 enforce overflow at extreme cost but but
01:07:54 yeah I mean I I agree with you
01:07:56 it would be it would be ridiculous and
01:07:58 so and roughly all CD programmers
01:08:00 everywhere are used to thinking to
01:08:01 compliment and so it's just a mess and
01:08:03 so we had this choice of like do we want
01:08:05 to have different behavior for scaler of
01:08:07 one or do we want to have it consistent
01:08:10 with simd and like we were talking about
01:08:11 before we decided let's make it
01:08:13 consistent yeah and we we could have had
01:08:16 like I mean even within our design
01:08:17 because we have fancy parametric
01:08:18 metaprogramming stuff we could have said
01:08:19 that scaler of one has special behavior
01:08:21 but then you have inconsistency in your
01:08:23 software ecosystem Y and so what we
01:08:25 decided to do is just everything's to
01:08:27 compliment super consistent it's fast
01:08:30 you don't have like you know Runing to
01:08:33 bug mode is different than release mode
01:08:35 like you know you're not going to be
01:08:36 able to catch these classes of errors
01:08:39 but guess what you can't catch all
01:08:40 classes of Errors anyways so I think
01:08:42 that's a totally reasonable design and I
01:08:44 could imagine a world in which that's
01:08:46 what we go with and rock and in that
01:08:47 world it would be a world specifically
01:08:49 where we've decided that like simd is a
01:08:51 much more like right now we just
01:08:53 basically don't have any simd support
01:08:54 and that might turn out not to be
01:08:56 acceptable someday like it might just be
01:08:58 like the the way the world's going it's
01:09:00 just like you got to be able to write
01:09:02 like it the compiler is not smart enough
01:09:04 to use these instructions and even if it
01:09:06 did you still couldn't have the bounce
01:09:08 checking overflow and get any reasonable
01:09:10 performance they'd be a deoptimization
01:09:11 so there's there's a world where well
01:09:14 and and and with with Swift like that
01:09:15 that's the thing it's like an autov
01:09:16 vectorizer can't vectorize code that is
01:09:18 doing bounce checks right or overflow
01:09:21 checks yeah overflow sorry overflow
01:09:23 checks yeah yeah which makes total sense
01:09:25 and it's also another thing that I think
01:09:27 about a lot is um what are the errors
01:09:29 that people are cognizant of and
01:09:31 thinking about handling because if you
01:09:33 say for example like something we
01:09:34 experimented with early on was um let's
01:09:37 try to make it so that floating Point
01:09:39 division returns uh like an error type
01:09:42 right and and like you have to check it
01:09:43 every time because hey division by zero
01:09:45 can like cause all these problems we can
01:09:47 we can Define away all those nasty edge
01:09:49 cases around not a number and you know
01:09:51 not being equal to itself and so forth
01:09:53 at the hardware level but what we found
01:09:55 very quickly is that what that means is
01:09:58 in practice whenever anyone does
01:09:59 division they will immediately say with
01:10:01 default zero like I don't worry about it
01:10:03 if it if it if it would have caused a
01:10:05 problem just put it put it at zero and
01:10:07 just ignore it and so in my mind that's
01:10:10 a worse outcome because that's because
01:10:12 man managing the the error explicitly is
01:10:15 just not worth it like nobody wants to
01:10:17 do that right and so in my mind it's
01:10:19 better to say look there are these usual
01:10:21 floating Point error cases now in our
01:10:23 case we do offer like a fix Point
01:10:24 decimal like in the standard library
01:10:26 that you can use instead of that so in a
01:10:27 lot of Ed cases that's going to be
01:10:29 better but if you actually are doing
01:10:30 floating Point math the point is like
01:10:32 here there be dragons like you need to
01:10:34 actually be aware of this and and think
01:10:36 about these edge cases and in some cases
01:10:38 I think that is the best API is to is to
01:10:40 not try to hide it and just say like
01:10:42 it's not that it's you well maybe you
01:10:44 say it's UB or maybe you say it's always
01:10:45 going to wrap but like the point is you
01:10:47 say this is an edge case you need to be
01:10:49 aware of and thinking about whenever
01:10:50 you're doing this type of
01:10:52 arithmetic yeah well so I mean I think
01:10:54 that it really comes down to what is the
01:10:55 goal of your language right and so that
01:10:57 you can so you don't have to
01:11:00 use i e floating point right to your
01:11:04 point you could use rational numbers or
01:11:06 decimals or lots of other things you can
01:11:08 invent your own floating Point format
01:11:09 you could not you could Define away Nan
01:11:12 somehow like all the stuff the reason
01:11:13 you use i e is that then you get
01:11:15 Hardware acceleration yes yep soft float
01:11:18 is not fast right and so um and so and
01:11:21 what I'm saying is uh Mojo cares about
01:11:24 simd well why is that well it's because
01:11:27 you know effectively every CPU has a 4X
01:11:30 float on it and so if you're doing float
01:11:33 arithmetic and you're not using simd
01:11:35 you're one quarter of the utilization of
01:11:37 the machine and sure maybe the
01:11:39 vectorizer will pick it up for you or
01:11:40 something in some cases but but 4X is a
01:11:43 pretty big deal like in terms of power
01:11:46 power consumption latency and everything
01:11:48 Etc and so like being native and
01:11:50 supporting that not forcing people to do
01:11:51 it but but uh making it easy is is
01:11:54 pretty valuable and similarly with
01:11:55 threads like make parallelism easy and
01:11:57 then people use it right and so but that
01:12:00 doesn't mean that particularly uh like
01:12:02 you and I we want practically useful in
01:12:05 production kind of languages and that's
01:12:06 where we're biased towards um but there
01:12:08 are also huge space for research
01:12:10 languages like and so I I love to see
01:12:13 the the the just like intended for
01:12:15 research don't actually care about
01:12:16 performance
01:12:18 um exploration of the stuff and uh even
01:12:21 more so I love and what what I think is
01:12:23 cool about Mojo is you can just like you
01:12:25 don't have to have a different language
01:12:26 to explore these things you can just
01:12:27 Define your own float type right right
01:12:30 and and in the case of you're talking
01:12:32 about should divide return zero should
01:12:34 it clamp should it do this should it
01:12:36 throw an error whatever like you can
01:12:37 just Define like Divi The Divide
01:12:40 operator has Behavior X and then I have
01:12:43 a method that has Behavior y right and
01:12:46 because floats are just structs you can
01:12:47 add methods to them it's fine you can
01:12:49 say div with error whatever so you can
01:12:54 enable people to opt into the
01:12:55 yeah yeah that makes a lot of sense I um
01:12:59 uh speaking of like the relationship
01:13:01 between like research and uh industrial
01:13:04 languages and stuff like that um I I we
01:13:06 were talking a little bit before the we
01:13:08 started recording and I I mentioned this
01:13:10 and I guess you hadn't heard of this but
01:13:11 there was I think it was Hacker News or
01:13:13 Reddit or something but like uh somebody
01:13:15 latched on to a comment you made pretty
01:13:16 offhandedly and your actually company
01:13:19 internal presentation about Mojo at
01:13:21 modular um where you mentioned that
01:13:24 there's an internal uprising and people
01:13:25 like we should totally publish this I'm
01:13:27 like uh okay I would have prepared a
01:13:29 little bit better if that were the cas
01:13:32 okay um but anyway the comment that
01:13:35 people were uh talking about was you
01:13:37 mentioned about uh like type inference
01:13:39 and you said like we we didn't we could
01:13:41 have done something like what we did
01:13:42 with swift which was uh Henley mner
01:13:44 bidirectional type checking really fancy
01:13:46 full type inference Yad yada but there
01:13:49 were two problems that you saw with that
01:13:50 in Swift one was uh that the compile
01:13:52 times um were a problem and then second
01:13:56 that uh the error messages were a
01:13:58 problem because they you could get
01:13:59 really like non-local um it wasn't clear
01:14:02 where the where the era came from and
01:14:05 the the fight that I saw was from like
01:14:07 the pro hinley Milner Henley Milner
01:14:09 Defenders saying you know Henley m is
01:14:11 great and look at Elm elm's hinley M has
01:14:13 like the best error messages ever and
01:14:15 then uh and and you know his compiles
01:14:17 really fast and then uh and then the
01:14:19 anti- hinley mil people saying like Ah
01:14:21 that's just a bunch of you know academic
01:14:22 stuff like of course you know if you
01:14:24 want to do real program you got to so
01:14:26 I'm kind of curious to just I don't know
01:14:28 just expand on on your thoughts on that
01:14:30 some more based on your experiences with
01:14:32 Swift yeah well so okay so so maybe I
01:14:35 misspoke and it came across not like I
01:14:38 intended where's the fun in that let's
01:14:40 just pretend you said common right but
01:14:44 but but here here's what I meant to say
01:14:46 um using Henley Milner in Swift was a
01:14:48 mistake in my opinion you can still get
01:14:52 expression is too complex to type check
01:14:53 and Swift and it
01:14:55 on pretty reasonable things and today
01:14:58 people Swift programmers are taught to
01:15:00 break long lines into separate
01:15:02 statements just to kind of work around
01:15:04 compile time interesting um and a thing
01:15:06 I could say is like today Swift is like
01:15:08 14 years old it's not like it's never
01:15:10 been worked on in fact Engineers have
01:15:12 spent years of effort trying to make
01:15:14 this work better right yeah now so so I
01:15:17 could say I think that that was a
01:15:18 mistake in Swift now I think that
01:15:22 reasonable people can give me a hard
01:15:24 time and I could it by the way and I I
01:15:26 say the wrong thing all the time so it's
01:15:27 not unusual and uh I I I read all those
01:15:31 really angry comments with love if if I
01:15:33 see them um I'm impressed that's that's
01:15:35 that's not an easy thing to do all the
01:15:37 time well I try to but yeah anyways I'm
01:15:39 I'm this is the benefit of having a
01:15:41 thick skin and having been around
01:15:42 programmers for a long time but the uh
01:15:44 but but the the mistake in the statement
01:15:46 is it's not Henley Milner's fault right
01:15:49 the actually the actual fault is the
01:15:50 fact that Swift has other things like
01:15:53 function overloading
01:15:55 and uh literals that can be inferred to
01:15:57 different types and many other things
01:16:00 that now make type- checking this thing
01:16:02 an exponential time problem yeah and so
01:16:05 if you make type checking exponential
01:16:07 time well sure you can push it down you
01:16:10 can make certain things work better and
01:16:11 stuff like this but the actual bad thing
01:16:13 that's happened there is is an
01:16:15 exponential time algorithm now what that
01:16:18 means is TW fold one is which is compile
01:16:20 times can tank and can become
01:16:21 unpredictable for users and stuff like
01:16:23 this and they have to learn patterns to
01:16:24 work around the Imp a stuff like this
01:16:26 but also means that if it's taking
01:16:27 exponential time to even decide like
01:16:30 solve decidability of can I type check
01:16:33 this thing well then of course the airs
01:16:34 are not going to be great just because
01:16:36 you have this exponential permutation of
01:16:38 different things that somebody could be
01:16:39 trying to express and so then trying to
01:16:41 infer that and explain it back is is
01:16:43 Frau so I don't know I mean I'm very
01:16:45 impressed with Elm and the the the
01:16:47 quality work they put into the air
01:16:48 messages I think it's amazing I don't
01:16:50 know the the set of trade-offs and
01:16:52 decisions and how they intersect and how
01:16:54 they go into that but um rust for
01:16:56 example doesn't have function
01:16:58 overloading right right and so it
01:16:59 decided like let's not do part of this
01:17:02 and therefore they
01:17:03 solved this in a different way right and
01:17:07 so what Mojo is doing is MoJo's um
01:17:11 saying okay well let's not use Henley
01:17:13 Miler at all right what's the benefit of
01:17:16 that well it makes error reporting
01:17:18 really easy that's great because it
01:17:20 means that it's very predictable that
01:17:22 means the contract with the programmer
01:17:23 is very predictable uh it's roughly what
01:17:26 C++ has been doing of course we have our
01:17:27 own twist on it but uh and therefore
01:17:29 it's proven it's like it doesn't require
01:17:32 years of engineering an R&D to like try
01:17:35 to make it work right meaning we're
01:17:37 putting our time into things that
01:17:38 actually matter like it's super funny if
01:17:40 you think about python well python
01:17:42 people will tell you it's untyped or
01:17:43 something right I would say it's
01:17:45 dynamically typed it's funny if you say
01:17:48 X Plus Y and then parentheses time Z
01:17:51 right well the X + Y gets type checked
01:17:55 when you run plus and it doesn't know
01:17:57 about the time Z that's coming
01:17:59 afterwards and so all python programmers
01:18:02 are exposed to a system that can only
01:18:05 work inside and out on the expression
01:18:08 tree anyways and so if that's the case
01:18:10 then why not make the static type
01:18:11 Checker work the same way like that way
01:18:12 it's consistent yeah and if you make it
01:18:14 different then there's a burden of like
01:18:16 why make it different yeah so Sor right
01:18:19 so there's a lot of things that lead to
01:18:20 a very simple and predictable
01:18:21 programming model it also makes compile
01:18:24 time deterministically reasonable and
01:18:26 and things like this and so I think
01:18:28 that's just kind of the set of decisions
01:18:30 we decide to make and it's not hinley or
01:18:32 Milner's
01:18:34 fault okay so so the function
01:18:36 overloading being you think like that
01:18:37 was kind of the the the intersection of
01:18:39 hinley Miler and function overloading in
01:18:41 Swift is kind of like the I don't the
01:18:44 main culprit in in your mind is that
01:18:45 accurate or so I mean there there's a
01:18:47 bunch of things that Swift does by the
01:18:49 way Swift is a very fancy language and
01:18:50 it has a bunch of magic built into it
01:18:52 and has a ton of complexity and there's
01:18:54 a whole bunch of stuff with uh uh
01:18:57 protocol it's it's equivalent of traits
01:18:59 uh overload resolution and all all this
01:19:02 kind of stuff the uh literals are very
01:19:04 fancy um there there's a whole bunch of
01:19:07 of cool stuff uh that went into there if
01:19:09 you're interested in more of what makes
01:19:11 Swift interesting but also very
01:19:13 complicated there's a cool series of
01:19:14 blog posts written by a friend of mine
01:19:16 named Doug Gregor um it's in Doug's
01:19:18 compiler Corner um and it's the blog
01:19:20 post are called Swift for C++
01:19:22 practitioners nice and he kind of
01:19:24 explained explains like how swift a
01:19:27 language built by a bunch of people that
01:19:28 were very experienced with C++ by the
01:19:30 way uh how Swift uh is different and
01:19:33 better and for example in Swift you can
01:19:35 Define your own operators and you can
01:19:36 Define your own precedence groups and
01:19:38 you can relate this operator to other
01:19:40 existing precedence groups and and stuff
01:19:42 like this and so Swift is a very very
01:19:44 very fancy language um our goal for Mojo
01:19:47 is don't have any of that fanciness like
01:19:50 just keep it simple it's fine like I
01:19:51 don't want it to be nearly as
01:19:53 complicated as Swift ended up in the end
01:19:55 so I assume this means that um in Mojo
01:19:58 you have to there's some point where
01:20:00 type annotations are required such as
01:20:01 like functions have to have have to be
01:20:03 type annotated is that right the way it
01:20:06 works is that if you don't put a type
01:20:07 annotation on WE default object and then
01:20:09 you get basically python Behavior right
01:20:11 so then it's all Dynamic and stuff like
01:20:13 this and so um and then you can and so
01:20:15 this is actually really important for
01:20:17 python compatibility let me give you
01:20:18 some intuition on this again going back
01:20:21 to TI tie tie a loop back around uh
01:20:23 sufficiently smart compilers and stuff
01:20:25 like this so in Python Python's integers
01:20:28 are big integers like you can make an
01:20:31 arbitrary sized integer and it's a heap
01:20:33 allocated thing and it's reference
01:20:34 semantics all this stuff they have
01:20:35 identity yeah and so you can use right
01:20:38 and so this this is a this is a pretty
01:20:40 interesting from a I need to implement
01:20:42 this in fast way on a GPU thing where in
01:20:45 a GPU can't do Malik and so how do you
01:20:47 do a bigin yeah right and we want to be
01:20:49 compatible and we want to be a good
01:20:50 superet of python over time and so we
01:20:52 have to support this Behavior um on the
01:20:55 other hand we don't want it to be the
01:20:56 first thing you reach for if you care
01:20:58 about performance right and so what we
01:21:00 do is we keep the names like lowercase
01:21:03 int because python has Type annotations
01:21:05 and they're kind of cursed in their own
01:21:07 way and there's a bunch of challenges
01:21:09 with the linters that use these things
01:21:12 but it's generally known as lowercase
01:21:13 INT in in the python world right and the
01:21:17 list in Python is generally known as
01:21:18 lowercase list L right and so our
01:21:21 approach on building standard library is
01:21:23 say okay well we can now have a capital
01:21:25 int Capital int is a struct capital int
01:21:29 is inline on your stack and it's size t
01:21:32 or you know the size of your pointer
01:21:33 right and it has these behaviors it has
01:21:36 a very very similar but slightly
01:21:38 different um operator set so for example
01:21:41 python int if you divide you get a float
01:21:43 back
01:21:44 out and so
01:21:47 oh sure yeah makes sense how's that for
01:21:49 solving a problem right yeah for us we
01:21:51 say okay well you get an integer back
01:21:53 out when you divide integers and there's
01:21:54 a different operation to to do this
01:21:56 thing right and um and so there's a
01:21:58 bunch of different design tradeoffs but
01:22:00 but it's compatible with existing python
01:22:02 because if you use lowercase in you
01:22:03 still get an object on the Heap that's
01:22:05 dynamically sized and it's an arbitrary
01:22:07 Precision integer and you have to opt
01:22:09 into I want Capital int and if you use
01:22:12 that you get way better performance you
01:22:13 get better predictability it will run on
01:22:15 a GPU etc etc um and it's not about one
01:22:18 being better than the other it's about a
01:22:20 a trade-off and you can make and so
01:22:22 that's that's kind of how we handle that
01:22:24 and similarly with list like lowercase
01:22:26 list it's an array of objects it's
01:22:28 untyped it's all Dynamic okay cool um
01:22:31 Capital list takes a type parameter and
01:22:33 it has an element type and it's a
01:22:34 homogeneous array in line and it's got
01:22:37 none of the the fanciness it's more like
01:22:39 a STD Vector in C++ right um and then
01:22:43 you as a programmer can use the right
01:22:44 tool for the job that makes a lot of
01:22:46 sense yeah a thing that we have to
01:22:48 contend within rock is if I just put in
01:22:50 the number five and I don't put any type
01:22:51 annotations anywhere um what type we so
01:22:55 we have a default but in practice it
01:22:56 almost the default almost never comes up
01:22:58 outside the reppel in the reppel if
01:22:59 you're just like playing around it can
01:23:00 totally come up um but uh actually the
01:23:03 more interesting one is what happens if
01:23:04 you do decimals so you say like 5.1 or
01:23:06 something like that because let's say I
01:23:08 put in 5.1 instead of five um now what
01:23:11 we do is we actually use our standard
01:23:13 libraries built-in fix Point Decimal
01:23:15 System so what that means is that by
01:23:17 default we're kind of prioritizing
01:23:18 correctness if you put into 0.1 plus 0.2
01:23:21 into the reppel it gives you back 0.3 um
01:23:24 but at the end of the day most of the
01:23:26 time it's just going to be inferring it
01:23:27 from surrounding context of of types
01:23:29 that are there um I think the uh so I'm
01:23:33 curious what you think about this we
01:23:34 talked a little bit about type inference
01:23:36 uh in past episodes and uh one of the
01:23:38 things that comes up is even if you have
01:23:40 the ability which I'm not sure if Swift
01:23:42 does or not but um to say I'm not going
01:23:44 to annotate even any of my top level
01:23:46 functions just no type annotations
01:23:47 anywhere at all um doesn't go that far
01:23:50 okay so yeah swi Swift requires you to
01:23:52 have signatures and Mojo as well so you
01:23:55 know you have to have a statically
01:23:56 understandable signature so you don't do
01:23:58 whole program type inference okay so
01:23:59 that's where the the bidirectional part
01:24:00 comes in so you require that so you can
01:24:04 yeah and and Swift is even limited to
01:24:06 just inference within a statement it
01:24:08 doesn't go across statements in a
01:24:09 function interesting all right good to
01:24:11 know okay so that explains why it would
01:24:12 f it still can't it can't still can't
01:24:14 solve individual statements okay yeah
01:24:18 well so so in Rockets like the whole the
01:24:20 whole thing is just like annotations are
01:24:21 completely optional and we don't even
01:24:22 have a compil error that says hey you
01:24:24 need to annotate this um right but uh
01:24:27 basically the the consequence of that is
01:24:29 that if you want to use Rock for like a
01:24:31 scripting in the sense of like as a bash
01:24:33 replacement you can do that and in that
01:24:35 world you kind of like don't want to
01:24:36 annotate your functions usually um or
01:24:38 you can start by writing your whole
01:24:40 program without annotations then add
01:24:41 them later or ask the editor to infer
01:24:43 them for you things like that um yeah
01:24:45 and I've always thought that's pretty
01:24:46 cool but I have heard a counter argument
01:24:48 that like it's so important that you
01:24:50 should annotate your types that it's
01:24:52 like actually a feature that you are
01:24:53 required to all the time as opposed to
01:24:55 it just being a cultural norm which it
01:24:57 is in El and hll and so forth well I
01:24:59 think it's really about your programmer
01:25:01 expectation right and if you're
01:25:03 intending to write types then it's
01:25:05 useful to help people that are intending
01:25:06 to write types if they're intending not
01:25:08 to write types or they don't care then
01:25:10 it's nice to not hassle them yeah
01:25:13 although I do like the ability to write
01:25:15 the implementation and then ask the
01:25:16 editor to infer the types for you so you
01:25:18 don't have to write out the types
01:25:20 upfront if that makes sense before you
01:25:22 can try it out that's how I used to
01:25:23 write h was the hasal would just say
01:25:26 like okay every time you're in the Rael
01:25:28 would say okay well it's a t t t and
01:25:29 you're like awesome copy and paste that
01:25:31 put it in the source code and then and
01:25:33 then when I'm reading a code later I
01:25:34 don't have to like be repping it to
01:25:36 understand what the signature is yeah
01:25:38 now I have heard that I think this was O
01:25:40 but okay people can correct me on this
01:25:41 but um I have heard that there are some
01:25:43 cultural norms where you just don't
01:25:45 annotate the top level functions at all
01:25:47 which to me is wild I would just like
01:25:48 it's like that sounds gross to me like
01:25:50 you don't you don't annotate any of them
01:25:51 like no you should it's like it's it's
01:25:53 really helpful information um not just
01:25:56 because it helps the error messages get
01:25:57 better and stuff like that but no
01:25:59 because easier to read and understand
01:26:00 the expectations of the interface yeah
01:26:02 for sure again I think there's personal
01:26:04 preference here but I'm in the same camp
01:26:05 as you for what it's worth that's my my
01:26:07 natural proclivity yeah yeah so Mojo has
01:26:11 uh a couple of problems to solve one is
01:26:14 we need to be a good Python and so
01:26:16 python doesn't really have types it has
01:26:18 Type annotations but it doesn't really
01:26:20 have stag types and the type annotations
01:26:21 are
01:26:22 cursed um
01:26:24 uh the other problem we have to solve is
01:26:26 we have to run on a GPU right and so if
01:26:29 you're on GPU you want full control and
01:26:31 here talk about GPU embedded system like
01:26:34 whatever the there's a class of people
01:26:35 that want full control and low-level
01:26:37 predictability um we also want to be
01:26:39 able to write low-level libraries like
01:26:41 sign and cosine and int and stuff like
01:26:42 this and have them composable by people
01:26:44 who don't want to care about this stuff
01:26:46 right yeah um and so the way we solve
01:26:49 that is actually uh and and to your
01:26:51 point x equals 5 five in Python means
01:26:57 create an object on the Heap with five
01:26:59 in it or maybe a tagged integer or
01:27:01 something but create a create an object
01:27:03 that is got you know that or you say
01:27:05 quote Fu you get a python string object
01:27:09 thingy right and we want a fancy
01:27:13 inline you know closer to what C++ to
01:27:16 have um and so the way we handle this is
01:27:19 we have two different keywords for
01:27:20 defining functions we have def which is
01:27:23 python and in deps like you know you
01:27:26 don't need Types on any of the arguments
01:27:28 and they get inferred to being python
01:27:29 object you can put a type on but if you
01:27:32 don't then it's just an object type and
01:27:34 and so everything is statically got a
01:27:36 type it's just defaults to object um and
01:27:39 then within it now you can say okay well
01:27:41 things default to their python behavior
01:27:44 and then we have FN and so if you choose
01:27:46 to Define your functions as FN well then
01:27:50 you have to have types things default in
01:27:52 a different way and then what you can do
01:27:54 is you can self-identify by the kind of
01:27:56 code you're writing do I want to be more
01:27:57 scripty or do I want to be more systemy
01:27:59 and then we make it so that you're
01:28:01 telling the compiler what world you want
01:28:02 to be in and without without judgment
01:28:04 right you can choose where you want to
01:28:06 be and that's fine and that also helps
01:28:07 both this um compatibility python but
01:28:10 also the Persona issue that makes a lot
01:28:13 of sense so I guess that also means that
01:28:14 if you wanted to given that you have a
01:28:16 different top level keyword for like I'm
01:28:18 in I'm in FN land now if you wanted to
01:28:20 you could also change the syntax of fun
01:28:22 function declarations to use your own
01:28:24 type annotation syntax I don't know if
01:28:25 you do that or not but uh we just use
01:28:28 the same syntax because it's fine it's
01:28:29 nice um but you could choose to do that
01:28:31 the only tradeoff then is now you have
01:28:33 like two a two two world problem and so
01:28:35 we want two worlds when it comes to some
01:28:37 of this Behavior but we don't want it to
01:28:38 be like let's so our generics use square
01:28:41 brackets because that's how python works
01:28:43 and and things like this you don't want
01:28:45 to have like angle brackets like C++ in
01:28:48 the same language or you don't want to
01:28:49 say I mean again a different language
01:28:52 could choose to do this but you could
01:28:53 say like uses indentation for scoping
01:28:56 and then uh FN uses curly braces and
01:28:58 semicolons you know you could
01:29:00 theoretically do that but but that's not
01:29:03 what we've chosen to do we've chosen to
01:29:05 be consistent except for providing this
01:29:07 one big fork that allows us to serve two
01:29:09 different kinds of use cases yeah that
01:29:11 makes sense so going back to uh numbers
01:29:13 and uh and sort of uh Hardware
01:29:16 accelerated complex numbers um I I just
01:29:18 love to learn more about that because
01:29:20 something that people have asked about
01:29:21 in rock is that currently I'm actually
01:29:24 leaning towards someday adding this but
01:29:25 currently we don't actually support
01:29:27 operator overloading if we do in the
01:29:28 future it'll be basically the way Russ
01:29:30 does it um because we have an equivalent
01:29:31 of rust traits but uh but the question
01:29:34 is like should we do it at all like Java
01:29:35 famously didn't didn't support that and
01:29:37 you know after C++ did and there there
01:29:39 trade-offs um but one of the things that
01:29:41 people brought up is you know well what
01:29:43 if I want to implement my own complex
01:29:44 numbers and one of the questions or like
01:29:46 I want to implement big in or something
01:29:48 like that and one of my questions is
01:29:49 always like what's the performance of
01:29:50 that even going to be like like how how
01:29:53 good could it be and Hardware
01:29:55 accelerated complex numbers is just not
01:29:56 something I'd heard about at all so I
01:29:57 just love to learn more about like how
01:29:59 do you how does that fit into Mojo is
01:30:00 that something that there's like demand
01:30:02 for in the scientific Computing
01:30:03 Community or how how does that work let
01:30:05 me unwind this a little bit and talk
01:30:07 about operator overloading and I can't
01:30:09 tell you what the right thing is for
01:30:10 rock I can I can I can give and share
01:30:12 some experiences and lessons learn right
01:30:14 I've used C++ quite a bit but also
01:30:16 hasool and other languages like that to
01:30:18 allow you to Define your own operators
01:30:19 and so C++ was always very frustrating
01:30:22 to me because it had a limited oper set
01:30:24 and people want to overload them and so
01:30:25 you got shift left for Io right you know
01:30:29 IO streams shift left and so and so with
01:30:32 swift what we decided to do is much more
01:30:34 of a
01:30:35 hollish thing where you can define an
01:30:37 arbitrary or nearly arbitrary symbol to
01:30:40 be a uh you know a punctuation character
01:30:43 can be an operator you can Define that
01:30:44 you can define a precedence level and
01:30:46 then you can go overload it to your
01:30:47 heart's content Swift even allows you to
01:30:49 use Unicode and so you can use like set
01:30:51 inclusion and things like this as operat
01:30:54 and go nuts with it
01:30:56 um that I think is useful theoretically
01:31:01 and one of the ways that I would always
01:31:03 defend that is you know in C++ you see
01:31:06 these these types that go overload like
01:31:09 shift left or Plus or whatever you don't
01:31:12 know something weird is happening and so
01:31:14 part of my thesis was okay well if I see
01:31:16 some crazy weird Unicode operator I
01:31:20 don't know what it is at first glance
01:31:21 maybe but at least I know it's not Plus
01:31:25 at least I know it's something weird and
01:31:27 I can go do a Google Search and try to
01:31:28 figure out what's happening and then I
01:31:29 can go I know I don't know right now
01:31:32 yeah in practice um nobody in the Swift
01:31:34 ecosystem picked up unic code operators
01:31:36 and so that was very theoretical um in
01:31:40 practice very few people Define their
01:31:41 own operators and so it seems like it's
01:31:43 not very valuable and so in Mojo we're
01:31:46 just saying at least for now just allow
01:31:48 the python style stuff keep the grammar
01:31:51 fixed keep the language simple like yes
01:31:53 it can can be solved or it could be
01:31:55 extended someday but the burden should
01:31:56 be why do we want to make the language
01:31:58 more complicated and does it pay for its
01:32:02 complexity cost in the language um
01:32:05 versus in Swift it was much more of a
01:32:06 hey wow this thing could be useful and
01:32:08 wow wouldn't this be fun and cool and we
01:32:09 added it very early and then spend a
01:32:11 bunch of time trying to polish it and
01:32:12 make it better and so just you know
01:32:14 that's some different opinions and
01:32:16 theories over time about operators and
01:32:18 it's not that one is right or wrong but
01:32:20 it's just different things but I'm
01:32:22 generally Pro allow over
01:32:24 Operator overloading by the way yeah I
01:32:26 mean well so the feedback I've heard is
01:32:28 there's certain use cases where people
01:32:30 talk about like um remember I think it
01:32:32 was Casey murator uh mentioning like he
01:32:34 does a lot of game development obviously
01:32:36 um he said like he basically likes C
01:32:39 better than C++ but he uses a C++
01:32:41 compiler just to get operator
01:32:42 overloading because it's like that
01:32:43 important if you're doing that much like
01:32:45 Matrix math and stuff like that um and
01:32:48 that's that's those are the types of use
01:32:49 cases people have asked for it in rock
01:32:51 um and I'm pretty dead set on not adding
01:32:55 custom operators like where you can add
01:32:57 cuz Elm had them and then removed them
01:32:59 after seeing what they got used for in a
01:33:02 lot of cases well okay I mean a lot of
01:33:04 people so Swift also allows you to have
01:33:06 Unicode oper or Unicode function names
01:33:08 and stuff like this and so you know yes
01:33:10 there there are the memes where you have
01:33:11 pile of poop function and stuff like
01:33:13 this but but there are also people that
01:33:15 you know don't speak English and they
01:33:16 want to use like you know their native
01:33:18 language and go right yeah well this was
01:33:21 more about like you have your operators
01:33:23 asky characters but it's like six asky
01:33:25 characters in a row you know because and
01:33:27 you're like no really this I made this
01:33:28 beautiful DSL it's like this this is not
01:33:31 nice code to read anymore um yes but uh
01:33:35 but thinking about overloading I the
01:33:36 downside there is exactly what you said
01:33:38 about C++ where people use it to make
01:33:40 dsls that are not math related like
01:33:42 there it's like now right bit shift
01:33:45 means IO or or something like that do
01:33:48 you worry about that in Mojo or you just
01:33:49 sort of like it's the cost of doing
01:33:51 business like we got to have it again I
01:33:54 so we we have we're not making forever
01:33:56 decisions here we're making a set of
01:33:58 starting point decisions and the
01:33:59 starting point decision is complexi has
01:34:01 to pay for itself now you're right I've
01:34:04 seen the bad things I've also solved the
01:34:06 bad things in Swift and then the in my
01:34:08 opinion having lived with it for 14
01:34:10 years uh the solution was worse than
01:34:13 the The Cure was worse than the curse or
01:34:17 whatever the poison yeah you weren't
01:34:19 poison or yeah and so and so I don't
01:34:22 think it actually was the right tra off
01:34:24 um now some beautiful things were built
01:34:26 with it some problems I'm sure were
01:34:27 avoided but it also added a ton of
01:34:29 complexity and makes the language more
01:34:30 complicated for people who don't care
01:34:33 right and so my current position with
01:34:34 Mojo and part of this is forced by
01:34:36 python but is allow the goofy underbar
01:34:41 ad Dunder style syntax so you can
01:34:43 overload operators same way python does
01:34:45 and I think that's good enough but let
01:34:47 me tell you the benefit to you as a
01:34:49 language designer if you choose to add
01:34:51 operator overloading and Swift and Mojo
01:34:55 take it so Swift took it quite far Mojo
01:34:58 takes it even further um the benefit is
01:35:00 is that you don't have to have
01:35:01 privileged types in your language
01:35:03 Actually I don't even know is is I think
01:35:05 rock is a zero overhead language is it
01:35:08 not as much as possible yeah I mean uh I
01:35:10 the only overhead that really comes in
01:35:12 the standard library is that um I guess
01:35:15 you could call we do the small string
01:35:16 optimization you could call that
01:35:17 overhead depending I mean obviously
01:35:19 hopefully but I mean if if you define a
01:35:20 struct a structure or method that gets
01:35:22 in line then
01:35:24 yeah it's the same as okay so and and
01:35:25 you're using lvm and stuff like so so so
01:35:28 the benefit of that is that you can say
01:35:29 look I don't have to privilege types in
01:35:32 C uh they had to add complex numbers to
01:35:36 c99 and so they built it into the
01:35:38 language because they have no ability to
01:35:40 find an STD complex number and so that
01:35:43 made the language more complicated and
01:35:45 they had to have all the overload
01:35:47 resolution rules and c99 actually even
01:35:50 added imaginary numbers I don't know if
01:35:51 you know this I didn't know that so what
01:35:54 ends up happening is if you can say uh
01:35:56 libraries can be expressive then what
01:35:57 you do is you put back pressure on this
01:35:59 and you allow the language to be simpler
01:36:00 which makes then Library developers able
01:36:04 to Define their own expressive
01:36:05 abstractions for their domain and then
01:36:07 you can allow them to go and so Mo Mojo
01:36:10 again takes us extremely far and makes
01:36:11 int not be built into the language and
01:36:14 things like this um and that's actually
01:36:16 great because um in the domain that we
01:36:19 work in there's all kinds of numeric
01:36:20 data types so there's float and double
01:36:23 for example fine uh there's also B float
01:36:26 16 and Float 8 and all like couple of
01:36:29 float 8s with different mantis and
01:36:31 exponent and like and so there's this
01:36:33 huge range of innovation that's
01:36:34 happening in numeric data types and
01:36:36 having to rev the compiler every time
01:36:38 somebody wants to go do something it
01:36:40 would be very
01:36:42 annoying and so instead we can just have
01:36:44 people to find these things in libraries
01:36:45 and that's actually great and it reduces
01:36:47 pressure on the language from having to
01:36:48 churn with all the hardware rock is
01:36:50 probably in a different space since you
01:36:52 don't care about float 4 or something
01:36:54 yeah I mean not today certainly not not
01:36:56 on our radar um Java is an interesting
01:36:59 example where essentially what they did
01:37:01 which is what rock is doing today but
01:37:03 could change in the future is
01:37:05 essentially to say yeah you can Define
01:37:06 your own complex number in user space I
01:37:08 don't know if like I mean how much
01:37:10 overhead there might or might not be in
01:37:12 Java but you don't get custom operators
01:37:14 for it like you need to call do add if
01:37:16 you want to add two of these things and
01:37:17 do divide obviously that has ergonomics
01:37:19 downsides if you're trying to do
01:37:22 arithmetic well well but Java also
01:37:24 doesn't have zero cost subtractions
01:37:25 right and so it requires you to box
01:37:27 things and stuff like this and so
01:37:29 practically speaking you could Define a
01:37:31 complex number but it's going to be slow
01:37:33 anyways or unpredictable I mean jvms
01:37:35 have a lot of optimizations to work
01:37:37 around this um go back to Hero heroic
01:37:40 optimizations and when they're important
01:37:43 uh at least I haven't done Java in a
01:37:44 long time but the jvm didn't used to
01:37:46 have two-dimensional arrays it only had
01:37:48 one dimensional array really and so yes
01:37:51 and so if you want to allocate an array
01:37:54 of arrays you would have an array and
01:37:57 then each of the rows of the array can
01:37:58 be a different length yeah right right I
01:38:02 I did know that because that was true
01:38:03 back when I did Java yeah and so maybe
01:38:06 they've changed that now but um but but
01:38:08 one of the challenges with that is if
01:38:10 you write arrays of arrays that's way
01:38:11 slower than having an actually proper 2D
01:38:13 array and so this is again where a lot
01:38:15 of java implementations particularly for
01:38:17 benchmarks would go try to turn that
01:38:19 pattern match code do these heroic
01:38:22 static analysis thingies understand I
01:38:24 can prove the length of each of these
01:38:25 subarrays is the same and then and then
01:38:27 solve that and again that's that's cool
01:38:30 some Engineers work really hard on that
01:38:31 it's a it's
01:38:33 heroic but wow it's so much better to
01:38:35 have arrays of arrays actually in line
01:38:39 and predictable and two dimensional
01:38:40 arrays are actually a pretty valuable
01:38:42 thing and relying on compiler nerds to
01:38:44 go crazy to uh give you the thing that
01:38:46 you could have asked for in the first
01:38:48 place is pretty pretty rough I see okay
01:38:50 so so in in Mojo it's not that there are
01:38:52 like specific Hardware optimizations
01:38:54 that come up for complex numbers but
01:38:55 rather that it's like zero overhead
01:38:57 complex numbers if that makes sense okay
01:38:59 so sorry you're right I you I got
01:39:01 distracted on on operator overloading so
01:39:03 just in terms of complex numbers so I'm
01:39:05 not an expert on this but I'll tell you
01:39:06 my understanding which is that um
01:39:08 certain instruction sets including like
01:39:10 IBM mainframes and a bunch of other
01:39:12 stuff they kind of climbed this Tower of
01:39:14 let's have scalar floats now let's have
01:39:16 simd and I
01:39:18 have I have like uh so back in the day
01:39:21 it be like four floats or two doubles
01:39:24 kind of a thing and then you kind of
01:39:26 build into this and then some of these
01:39:28 chip people decide that okay well
01:39:30 complex math is really important and so
01:39:33 there are certain operations like
01:39:34 complex multiply that actually include
01:39:37 like I think four multiplies and two
01:39:40 adds plus some other goop that all come
01:39:44 together and they say I want to have one
01:39:45 Hardware instruction that does complex
01:39:47 multiply it takes see two two complex
01:39:50 numbers and simd registers or something
01:39:52 like this right and so once somebody
01:39:54 puts something into hardware and says
01:39:55 wow this is 10x faster than doing
01:39:57 individual multiplies and ads you kind
01:39:59 of have to say like okay well 10x
01:40:00 Improvement because they put into
01:40:02 silicon uh how do we expose that and
01:40:04 then make it so people can use the stuff
01:40:07 without having to know about it and so
01:40:08 this is where a benefit and there's many
01:40:11 different solutions to this the benefit
01:40:13 of what we do in Mojo is you can just
01:40:14 have a complex struct and you say again
01:40:17 complex struct well what is it it's just
01:40:19 a struct it has a float and imaginary it
01:40:20 has like simple Behavior has a bunch of
01:40:22 methods including multiply and then
01:40:25 inside the multiply you can say
01:40:26 effectively if def time yeah are we on
01:40:29 an IBM yeah time are we on that thing
01:40:32 and now you say okay well use the one
01:40:34 instruction and then boom everybody's
01:40:36 complex numbers can be accelerated they
01:40:37 don't have to worry about it and um and
01:40:39 then somebody who like open codes of
01:40:42 multiplication can be told just use star
01:40:44 and it's better for the amount of code
01:40:46 you write and things like this but you
01:40:47 also get it accelerated now other other
01:40:49 approaches and the traditional way of
01:40:51 doing this is you say okay well teach
01:40:53 something like lvm to pattern match it
01:40:55 and again this gets back into the okay
01:40:57 now you have somewhat flaky behavior and
01:40:59 when you have like a partially constant
01:41:02 thing it constant folds and you can't
01:41:04 pattern match it and then like there's
01:41:05 all these other problems that come in
01:41:07 and so this is where like making it more
01:41:08 predictable and building it at the
01:41:10 language level at the library level that
01:41:12 enables it to be way more predictable
01:41:13 and and um works better uh generally in
01:41:17 optimization you want to be lowering you
01:41:19 don't want to be raising and so this is
01:41:21 where taking something that's a higher
01:41:23 level of abstraction and then
01:41:26 decomposing it across the optimizer as
01:41:28 you go is it becomes more predictable
01:41:30 and structurally sound than starting
01:41:32 with something that's scaler and then
01:41:33 trying to vectorize and trying to find
01:41:35 parallelism and and build into it that
01:41:37 way totally an interesting example of
01:41:39 that is something that uh is number
01:41:41 related also a feature that I like about
01:41:42 Zig uh that's that's like comp time as
01:41:45 well as uh like well it's comp time
01:41:47 related is they have um sort of
01:41:50 non-standard bitwidth integers as like a
01:41:52 built-in thing like you say like I want
01:41:54 i7 for example um and at first I heard
01:41:57 about that I was like that's just kind
01:41:58 of cute but like you know I've never
01:41:59 actually use that and ever since I found
01:42:01 out about that I run into it on a
01:42:03 surprisingly regular basis like wanting
01:42:05 that in Rust um in some cases because
01:42:07 I'm doing like some bit packing thing
01:42:09 where I'm like well okay I've got 32-bit
01:42:11 integer but I'm actually only using 23
01:42:13 of those because seven of those are
01:42:14 being used for something else one case
01:42:16 comes up to me is I have a number I know
01:42:18 is small and then I want to put it in an
01:42:19 optional and I want the tag to not cause
01:42:22 another like a
01:42:24 slot yeah right that's that's a great
01:42:26 example yeah um does mojo have a concept
01:42:29 like that where you can say like I I I
01:42:32 want something that is going to end up
01:42:34 taking up you know eight bits but I'm
01:42:36 only using fewer than that so Mojo
01:42:38 Builds on top of ml ml has arbitrary
01:42:41 Precision integers and so yeah you can
01:42:42 have a 10,23 bit integer if you'd like
01:42:45 to do that um we haven't wrapped it up
01:42:48 into libraries and so we haven't gone so
01:42:50 far as to say I have int of n where n is
01:42:53 or like like AP in of with some bitwidth
01:42:58 as a parameter but somebody could
01:42:59 totally do that and so that's something
01:43:01 that Mojo allows you to express directly
01:43:03 in a library and so we don't have to add
01:43:05 compiler support again this is this is a
01:43:07 cool thing is like and you know for
01:43:09 some uh security AES crypto thingy like
01:43:13 maybe having
01:43:15 256bit accelerated stuff I mean actually
01:43:18 there are definitely AES instructions in
01:43:20 all these processors and so being able
01:43:21 to directly access that kind of stuff is
01:43:22 super valuable and being able to do that
01:43:24 for the domain specific uh expert only
01:43:28 kind of territory is really important
01:43:30 and then people like me that don't
01:43:33 understand any of this stuff can just
01:43:34 build on top of the libraries that
01:43:35 somebody else who does know how it works
01:43:37 works and then I can just take it for
01:43:39 granted and that's how most of software
01:43:40 engineering works yeah so I have one
01:43:43 last question about uh API design and
01:43:45 Mojo and uh so in zigg there is a
01:43:50 standard Library convention that when
01:43:52 you call a function that allocates on
01:43:54 the Heap you have to pass it an
01:43:55 allocator there's no concept of like a
01:43:57 built-in like I mean I guess there's a
01:44:00 there is a global allocator available
01:44:01 but culturally the way it's done is you
01:44:03 pass in allocators for everything I
01:44:05 really miss that in Rust I really like
01:44:07 that um I appreciate that if rust had
01:44:09 that there would be certain categories
01:44:11 of use cases that would be a lot less
01:44:13 ergonomic and maybe rust wouldn't be as
01:44:15 popular as it is um but for the type of
01:44:18 programming I do I actually love that
01:44:19 and I I wish that Russ had made that
01:44:22 decision because you could you can
01:44:23 totally build that yourself and that
01:44:24 kind of is what we do a little bit in
01:44:25 the Rock compiler um but I'm kind of
01:44:27 curious how you think about the concept
01:44:29 of allocators and like bump allocators
01:44:30 and stuff like that and um in the
01:44:33 context of Mojo especially given that
01:44:35 you have this you know coupling with
01:44:38 python um well so the python stuff is
01:44:40 kind of unrelated because python will do
01:44:42 what python does and like fair enough um
01:44:45 but but but great question um my today
01:44:48 opinion which reserve the right to
01:44:50 change my opinion but my today opinion
01:44:52 is that um what we need to do is build
01:44:57 different kinds of types into uh
01:45:02 so having an allocator abstraction is
01:45:05 not super uh appealing to me it can be
01:45:08 done C++ STL for example has a fairly
01:45:12 old school uh allocator abstraction and
01:45:15 you could make every type parameterized
01:45:16 on an allocator and then you could
01:45:18 choose to default it or make it explicit
01:45:20 or whatever uh we haven't done that just
01:45:22 because um I haven't seen the value to
01:45:24 be great often if you want to allocate
01:45:27 things with bump pointers and stuff like
01:45:28 this what you have is you have a bump
01:45:30 pointer abstraction and then you want to
01:45:32 be able to allocate instances of types
01:45:34 out of that and then what you get from a
01:45:36 bump pointer is fast allocation but then
01:45:38 you don't run the destructors right and
01:45:42 so because you want to just blow the
01:45:43 whole thing away at once and so it ends
01:45:45 up being a very particular kind of use
01:45:47 case that isn't actually that generic
01:45:49 and so I haven't I haven't seen that
01:45:53 actually work super well um and so I'd
01:45:56 rather keep the complexity out now there
01:45:58 are other things and so I give you an
01:46:00 example of
01:46:01 this um in in C++ for example it has an
01:46:06 SD Vector data type SD Vector as soon as
01:46:09 you push one element onto the vector it
01:46:10 has to go Malik some
01:46:12 space okay um there's another class in
01:46:15 in the lvm code base it's called small
01:46:17 Vector right where you say I want to
01:46:19 have some number of inline elements on
01:46:21 the stack and then if if I exceed that
01:46:23 then I go Malo some thing and the idea
01:46:26 is that many vectors actually have one
01:46:27 or two elements in them and if that's
01:46:30 true then just put on the stack and you
01:46:31 save a Malik you save IND Direction you
01:46:33 save cash misses like it's all it's all
01:46:35 win right and so um it's very
01:46:39 unfortunate that C++ had STD vector and
01:46:42 now there's a different zoo of different
01:46:45 things made by different Library vendors
01:46:47 to try to solve this problem right um
01:46:50 and so our approach which hasn't been
01:46:52 implemented yet but I think folks are
01:46:53 working on is to say well Mojo has a
01:46:55 list type list is basically like SD
01:46:57 Vector but it can take a parameter which
01:47:00 is number of inline elements parameter
01:47:02 happens at comp time and so then you can
01:47:04 have one data type make it consistent
01:47:06 and then you can make the decision of do
01:47:09 you want inline elements or not be
01:47:11 separate from okay what is are you an
01:47:13 array or a dictionary or things like
01:47:14 this and so you can get uh unification
01:47:17 at that level without trying to unify
01:47:19 the allocators do you do the small
01:47:21 string optimization then because that's
01:47:22 another example of that to okay yeah
01:47:24 yeah yeah exactly and so and strings are
01:47:26 very magic and you're talking about
01:47:27 graphium clusters and things like this
01:47:29 you want to be able to do all that kind
01:47:30 of stuff too yeah what about um like
01:47:32 sharing so something that we do in rock
01:47:34 that I only Java knows that does that I
01:47:36 know about is like we have we call it
01:47:38 seamless slices so if you do an
01:47:40 operation that's like split a list like
01:47:41 you get back a bunch of elements like
01:47:44 within that that are that are not it's
01:47:45 not a whole new Heap allocation but
01:47:46 rather it's just like bumping the
01:47:47 reference count that's right that has a
01:47:49 whole bunch of trade-offs but it's
01:47:50 worked out generally very well for us is
01:47:52 that something you're also looking into
01:47:53 in Mojo or uh yes Mojo has a whole
01:47:56 ownership system so you can get slices
01:47:58 and then they all refer to the lifetime
01:48:00 of the the array that you sliced out of
01:48:02 and so you can do all that kind of stuff
01:48:04 and S sear generally get back yes and
01:48:07 slices separate type but then it
01:48:09 conforms the same traits that other
01:48:10 collection types do makes sense awesome
01:48:13 wow we covered a lot of ground uh this
01:48:15 is a great conversation uh thank you so
01:48:18 much Chris I I really appreciate you're
01:48:19 taking the time to talk to me about all
01:48:21 this yeah well so I I mean if if folks
01:48:23 are interested in Mojo um I'd really
01:48:25 encourage them to check out our web page
01:48:26 like we have a ton of documentation the
01:48:27 community is amazing we have a Discord
01:48:29 Channel I think we have 20,000 people on
01:48:32 Discord all talking about different
01:48:33 stuff building things uh Mojo is also
01:48:35 not just an AI language it's also being
01:48:37 used to build web servers and guey
01:48:40 libraries and all kinds of stuff by the
01:48:41 community and so we'd love for people to
01:48:42 get involved and uh Mojo is still pretty
01:48:45 early and so we're still adding uh core
01:48:47 capabilities and building out the
01:48:48 libraries but uh we have a huge
01:48:51 community of people that really
01:48:52 enthusiastic and love for people to get
01:48:54 involved nice well well thanks so much
01:48:57 again and also thank you for all of your
01:48:58 great contributions to programming over
01:49:00 the
01:49:01 years well thank you for having such
01:49:03 interesting people on the show I've
01:49:04 learned a
01:49:06 lot that's it for this one I hope you
01:49:08 liked it you can find links to some of
01:49:10 the things we talked about in the show
01:49:11 notes and if you've been enjoying these
01:49:12 episodes consider supporting the show on

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Okay, here is the abstract and summary for the provided transcript based on the Modular Community Meetup.

*Abstract:*

This transcript captures the first Modular Community Meetup, featuring CEO Chris Lattner and engineer Jack Clayton. Chris Lattner outlines the significant challenges and complexity plaguing the current AI and GPU software ecosystem, heavily criticizing CUDA's limitations (vendor lock-in, proprietary nature, lagging innovation, usability issues) and explaining why alternatives like OpenCL, AI compilers (XLA, TVM), Triton, and MLIR haven't fully solved the problem. He introduces Modular's approach to rebuilding the stack with the Mojo programming language and the Max AI engine, emphasizing their design for performance, usability, portability across heterogeneous hardware, and independence from CUDA. Key announcements include a new, permissive "Modular Community License," the imminent open-sourcing of ~250,000 lines of Mojo GPU kernel code (Apache 2.0), upcoming pip support, and the revelation that Modular's stack currently runs the same binary on both Nvidia and AMD GPUs. Jack Clayton follows with a live demo showcasing Mojo for GPU programming, including writing basic kernels (Mandelbrot), inspecting generated PTX/assembly, creating custom ops for the Max engine via Python, and demonstrating the cross-vendor portability by running the identical Mojo code on both Nvidia A100 and AMD MI300X GPUs.

*Modular Community Meetup: Reshaping GPU Development with Mojo and Max*

*   *0:00:51 Event Kick-off:* Welcome to the first Modular Community Meetup, outlining talks by Chris Lattner (CEO) on Mojo/Max and Jack Clayton (Engineer) with a Mojo GPU programming demo.
*   *0:03:30 Chris Lattner: The Problem with GPU Software:* AI's importance is hampered by poor, complex software stacks, particularly around CUDA, which has become a "rickety moat" and a "swamp."
*   *0:07:12 CUDA's Shortcomings:* Identified issues include vendor lock-in (Nvidia only), hardware limitations (GPU-only, not even Nvidia CPUs), proprietary nature hindering innovation, poor Python integration, C++ complexities, and massive container sizes (15-50GB).
*   *0:09:43 Flawed Solutions - Fixed Function:* Approaches like NIMS optimize specific models but sacrifice the flexibility and innovation core to AI's value ("dystopian").
*   *0:12:26 DeepSeek as a Catalyst:* Highlighted performance gains possible by bypassing abstractions (going to PTX) but showed this requires immense resources, making it inaccessible for most ("dystopian"). Democratization is needed.
*   *0:14:32 Why Alternatives Failed (OpenCL, Compilers, Triton, MLIR):*
    *   OpenCL: Suffered from committee-driven slowness vs. CUDA's focused drive.
    *   AI Compilers (XLA/TVM): Hit performance ceilings and bottlenecked on compiler expertise; struggled to adapt to GenAI's complexity (e.g., FlashAttention).
    *   Triton: Improved usability (Pythonic, tile-based) but sacrifices performance (~20%), often rewritten in CUDA C++, and lacks portability/ASIC support. Validated need for usability but can't lose performance.
    *   MLIR: Successful infrastructure but doesn't provide a full AI stack; ecosystem projects often replicated XLA's limitations.
*   *0:23:47 Modular's Approach: Rebuilding the Stack:* A multi-year research effort to create new abstractions (Mojo language, Max engine) to fundamentally change the game.
*   *0:25:17 The Modular Stack:*
    *   *Mojo:* A Pythonic systems programming language designed for heterogeneous compute (CPUs, GPUs, ASICs), providing full hardware access and performance without C++ pain points. *Crucially, Modular's GPU code is written in Mojo, entirely replacing CUDA, CuDNN, Cutlass etc.*
    *   *Max:* An AI engine (initially inference-focused) built on Mojo, offering Python APIs, predictability, GenAI design, kernel fusion, and serving components.
    *   *Enterprise Platform:* Higher-level tools for managing large-scale GPU deployments.
*   *0:31:43 Deployment & Portability:* Simple Docker deployment. *Key Reveal:* The *same compiled binary* currently runs across both Nvidia (A100/H100) and AMD (MI300X) GPUs.
*   *0:32:25 Major Announcements: Licensing & Open Source:*
    *   *New Modular Community License:* Mojo & Max are free for non-commercial use, AND free for commercial/production use on x86/Nvidia hardware (with attribution). Goal: remove barriers to adoption.
    *   *Impending Open Source:* ~250,000 lines of high-performance Mojo GPU kernels (matmul, FlashAttention, etc.) for multiple GPUs coming in ~1-2 weeks under Apache 2.0 license.
    *   *Mojo Compiler Open Source:* Still planned (target tentative: 2026).
    *   *Pip Support:* Coming soon for easier integration.
*   *0:39:09 Resources:* `builds.modular-dot-com` provides access to hundreds of optimized models and easy deployment commands. Recipes for common AI tasks available.
*   *0:40:45 Q&A Highlights (Chris Lattner):* Mojo is general-purpose but currently optimized for AI use cases; Mac GPU support targeted for summer; C interop exists, Rust possible via C; Mojo supports various accelerators (if they have a program counter); Mojo uses powerful metaprogramming (inspired by Zig's `comptime`, dependent types) to build high-level abstractions (like tile-based programming) *as libraries*, not hardcoded in the compiler, offering more power and flexibility than Triton.
*   *1:01:03 Jack Clayton: Mojo GPU Programming Demo:* Introduction to writing GPU kernels in Mojo.
*   *1:01:31 Mandelbrot Kernel:* Live coding and execution of a Mandelbrot kernel on an Nvidia A100 GPU using Mojo syntax (`gpu_kernel`, `thread_idx`, `LayoutTensor`).
*   *1:03:20 Assembly Inspection:* Demonstrated dumping the generated PTX assembly code directly from Mojo.
*   *1:03:53 Custom Ops for Max:* Showcased creating Mojo GPU kernels (grayscale, brightness, blur) and integrating them as custom operations within a Python script using the Max engine for an image processing pipeline.
*   *1:08:48 Cross-Vendor Portability Demo:* *Key Demo:* Ran the *exact same Mojo code* (Mandelbrot, image pipeline, even low-level warp shuffles) successfully on an AMD MI300X GPU, demonstrating true write-once-run-anywhere capability between vendors. Showed dumping AMD GPU assembly.
*   *1:09:47 Demo Resources & Challenge:* Provided links to GPU guides, example repositories, and issued a challenge to refactor a kernel for swag.
*   *1:11:28 Q&A Highlights (Jack Clayton):* Apple Metal support not yet available (planned); confirmed AMD GPU was MI300X; Collab support being investigated; graphics/video possible but not specifically explored yet.
*   *1:14:11 Closing:* Call for hiring announcements, mention of upcoming hackathon and community forum.

I used gemini-2.5-pro-exp-03-25| input-price: 1.25 output-price: 10.0 max-context-length: 128_000 on rocketrecap dot com to summarize the transcript.
Cost (if I didn't use the free tier): $0.07
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Okay, here is the abstract and summary for the provided transcript based on the Modular Community Meetup.

Abstract:

This transcript captures the first Modular Community Meetup, featuring CEO Chris Lattner and engineer Jack Clayton. Chris Lattner outlines the significant challenges and complexity plaguing the current AI and GPU software ecosystem, heavily criticizing CUDA's limitations (vendor lock-in, proprietary nature, lagging innovation, usability issues) and explaining why alternatives like OpenCL, AI compilers (XLA, TVM), Triton, and MLIR haven't fully solved the problem. He introduces Modular's approach to rebuilding the stack with the Mojo programming language and the Max AI engine, emphasizing their design for performance, usability, portability across heterogeneous hardware, and independence from CUDA. Key announcements include a new, permissive "Modular Community License," the imminent open-sourcing of ~250,000 lines of Mojo GPU kernel code (Apache 2.0), upcoming pip support, and the revelation that Modular's stack currently runs the same binary on both Nvidia and AMD GPUs. Jack Clayton follows with a live demo showcasing Mojo for GPU programming, including writing basic kernels (Mandelbrot), inspecting generated PTX/assembly, creating custom ops for the Max engine via Python, and demonstrating the cross-vendor portability by running the identical Mojo code on both Nvidia A100 and AMD MI300X GPUs.

Modular Community Meetup: Reshaping GPU Development with Mojo and Max

• 0:00:51 Event Kick-off: Welcome to the first Modular Community Meetup, outlining talks by Chris Lattner (CEO) on Mojo/Max and Jack Clayton (Engineer) with a Mojo GPU programming demo.
• 0:03:30 Chris Lattner: The Problem with GPU Software: AI's importance is hampered by poor, complex software stacks, particularly around CUDA, which has become a "rickety moat" and a "swamp."
• 0:07:12 CUDA's Shortcomings: Identified issues include vendor lock-in (Nvidia only), hardware limitations (GPU-only, not even Nvidia CPUs), proprietary nature hindering innovation, poor Python integration, C++ complexities, and massive container sizes (15-50GB).
• 0:09:43 Flawed Solutions - Fixed Function: Approaches like NIMS optimize specific models but sacrifice the flexibility and innovation core to AI's value ("dystopian").
• 0:12:26 DeepSeek as a Catalyst: Highlighted performance gains possible by bypassing abstractions (going to PTX) but showed this requires immense resources, making it inaccessible for most ("dystopian"). Democratization is needed.
• 0:14:32 Why Alternatives Failed (OpenCL, Compilers, Triton, MLIR):
  • OpenCL: Suffered from committee-driven slowness vs. CUDA's focused drive.
  • AI Compilers (XLA/TVM): Hit performance ceilings and bottlenecked on compiler expertise; struggled to adapt to GenAI's complexity (e.g., FlashAttention).
  • Triton: Improved usability (Pythonic, tile-based) but sacrifices performance (~20%), often rewritten in CUDA C++, and lacks portability/ASIC support. Validated need for usability but can't lose performance.
  • MLIR: Successful infrastructure but doesn't provide a full AI stack; ecosystem projects often replicated XLA's limitations.
• 0:23:47 Modular's Approach: Rebuilding the Stack: A multi-year research effort to create new abstractions (Mojo language, Max engine) to fundamentally change the game.
• 0:25:17 The Modular Stack:
  • Mojo: A Pythonic systems programming language designed for heterogeneous compute (CPUs, GPUs, ASICs), providing full hardware access and performance without C++ pain points. Crucially, Modular's GPU code is written in Mojo, entirely replacing CUDA, CuDNN, Cutlass etc.
  • Max: An AI engine (initially inference-focused) built on Mojo, offering Python APIs, predictability, GenAI design, kernel fusion, and serving components.
  • Enterprise Platform: Higher-level tools for managing large-scale GPU deployments.
• 0:31:43 Deployment & Portability: Simple Docker deployment. Key Reveal: The same compiled binary currently runs across both Nvidia (A100/H100) and AMD (MI300X) GPUs.
• 0:32:25 Major Announcements: Licensing & Open Source:
  • New Modular Community License: Mojo & Max are free for non-commercial use, AND free for commercial/production use on x86/Nvidia hardware (with attribution). Goal: remove barriers to adoption.
  • Impending Open Source: ~250,000 lines of high-performance Mojo GPU kernels (matmul, FlashAttention, etc.) for multiple GPUs coming in ~1-2 weeks under Apache 2.0 license.
  • Mojo Compiler Open Source: Still planned (target tentative: 2026).
  • Pip Support: Coming soon for easier integration.
• 0:39:09 Resources: builds.modular.com provides access to hundreds of optimized models and easy deployment commands. Recipes for common AI tasks available.
• 0:40:45 Q&A Highlights (Chris Lattner): Mojo is general-purpose but currently optimized for AI use cases; Mac GPU support targeted for summer; C interop exists, Rust possible via C; Mojo supports various accelerators (if they have a program counter); Mojo uses powerful metaprogramming (inspired by Zig's comptime, dependent types) to build high-level abstractions (like tile-based programming) as libraries, not hardcoded in the compiler, offering more power and flexibility than Triton.
• 1:01:03 Jack Clayton: Mojo GPU Programming Demo: Introduction to writing GPU kernels in Mojo.
• 1:01:31 Mandelbrot Kernel: Live coding and execution of a Mandelbrot kernel on an Nvidia A100 GPU using Mojo syntax (gpu_kernel, thread_idx, LayoutTensor).
• 1:03:20 Assembly Inspection: Demonstrated dumping the generated PTX assembly code directly from Mojo.
• 1:03:53 Custom Ops for Max: Showcased creating Mojo GPU kernels (grayscale, brightness, blur) and integrating them as custom operations within a Python script using the Max engine for an image processing pipeline.
• 1:08:48 Cross-Vendor Portability Demo: Key Demo: Ran the exact same Mojo code (Mandelbrot, image pipeline, even low-level warp shuffles) successfully on an AMD MI300X GPU, demonstrating true write-once-run-anywhere capability between vendors. Showed dumping AMD GPU assembly.
• 1:09:47 Demo Resources & Challenge: Provided links to GPU guides, example repositories, and issued a challenge to refactor a kernel for swag.
• 1:11:28 Q&A Highlights (Jack Clayton): Apple Metal support not yet available (planned); confirmed AMD GPU was MI300X; Collab support being investigated; graphics/video possible but not specifically explored yet.
• 1:14:11 Closing: Call for hiring announcements, mention of upcoming hackathon and community forum.

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Fluidigm Polaris Part 2- illuminator and camera
mikeselectricstuff
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Fluidigm Polaris part 1 : • Fluidigm Polaris (Part 1) - Biotech g...
Ebay listings: https://www.ebay.co.uk/usr/mikeselect...
Merch https://mikeselectricstuff.creator-sp...
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mikeselectricstuff
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40 Comments
@robertwatsonbath
6 hours ago
Thanks Mike. Ooof! - with the level of bodgery going on around 15:48 I think shame would have made me do a board re spin, out of my own pocket if I had to.
1
Reply
@Muonium1
9 hours ago
The green LED looks different from the others and uses phosphor conversion because of the "green gap" problem where green InGaN emitters suffer efficiency droop at high currents. Phosphide based emitters don't start becoming efficient until around 600nm so also can't be used for high power green emitters. See the paper and plot by Matthias Auf der Maur in his 2015 paper on alloy fluctuations in InGaN as the cause of reduced external quantum efficiency at longer (green) wavelengths.
4
Reply
1 reply
@tafsirnahian669
10 hours ago (edited)
Can this be used as an astrophotography camera?
Reply
mikeselectricstuff
·
1 reply
@mikeselectricstuff
6 hours ago
Yes, but may need a shutter to avoid light during readout
Reply
@2010craggy
11 hours ago
Narrowband filters we use in Astronomy (Astrophotography) are sided- they work best passing light in one direction so I guess the arrows on the filter frames indicate which way round to install them in the filter wheel.
1
Reply
@vitukz
12 hours ago
A mate with Channel @extractions&ire could use it
2
Reply
@RobertGallop
19 hours ago
That LED module says it can go up to 28 amps!!! 21 amps for 100%. You should see what it does at 20 amps!
Reply
@Prophes0r
19 hours ago
I had an "Oh SHIT!" moment when I realized that the weird trapezoidal shape of that light guide was for keystone correction of the light source.
Very clever.
6
Reply
@OneBiOzZ
20 hours ago
given the cost of the CCD you think they could have run another PCB for it
9
Reply
@tekvax01
21 hours ago
$20 thousand dollars per minute of run time!
1
Reply
@tekvax01
22 hours ago
"We spared no expense!" John Hammond Jurassic Park.
*(that's why this thing costs the same as a 50-seat Greyhound Bus coach!)
Reply
@florianf4257
22 hours ago
The smearing on the image could be due to the fact that you don't use a shutter, so you see brighter stripes under bright areas of the image as you still iluminate these pixels while the sensor data ist shifted out towards the top. I experienced this effect back at university with a LN-Cooled CCD for Spectroscopy. The stripes disapeared as soon as you used the shutter instead of disabling it in the open position (but fokussing at 100ms integration time and continuous readout with a focal plane shutter isn't much fun).
12
Reply
mikeselectricstuff
·
1 reply
@mikeselectricstuff
12 hours ago
I didn't think of that, but makes sense
2
Reply
@douro20
22 hours ago (edited)
The red LED reminds me of one from Roithner Lasertechnik. I have a Symbol 2D scanner which uses two very bright LEDs from that company, one red and one red-orange. The red-orange is behind a lens which focuses it into an extremely narrow beam.
1
Reply
@RicoElectrico
23 hours ago
PFG is Pulse Flush Gate according to the datasheet.
Reply
@dcallan812
23 hours ago
Very interesting. 2x
Reply
@littleboot_
1 day ago
Cool interesting device
Reply
@dav1dbone
1 day ago
I've stripped large projectors, looks similar, wonder if some of those castings are a magnesium alloy?
Reply
@kevywevvy8833
1 day ago
ironic that some of those Phlatlight modules are used in some of the cheapest disco lights.
1
Reply
1 reply
@bill6255
1 day ago
Great vid - gets right into subject in title, its packed with information, wraps up quickly. Should get a YT award! imho
3
Reply
@JAKOB1977
1 day ago (edited)
The whole sensor module incl. a 5 grand 50mpix sensor for 49 £.. highest bid atm
Though also a limited CCD sensor, but for the right buyer its a steal at these relative low sums.
Architecture Full Frame CCD (Square Pixels)
Total Number of Pixels 8304 (H) × 6220 (V) = 51.6 Mp
Number of Effective Pixels 8208 (H) × 6164 (V) = 50.5 Mp
Number of Active Pixels 8176 (H) × 6132 (V) = 50.1 Mp
Pixel Size 6.0 m (H) × 6.0 m (V)
Active Image Size 49.1 mm (H) × 36.8 mm (V)
61.3 mm (Diagonal),
645 1.1x Optical Format
Aspect Ratio 4:3
Horizontal Outputs 4
Saturation Signal 40.3 ke−
Output Sensitivity 31 V/e−
Quantum Efficiency
KAF−50100−CAA
KAF−50100−AAA
KAF−50100−ABA (with Lens)
22%, 22%, 16% (Peak R, G, B)
25%
62%
Read Noise (f = 18 MHz) 12.5 e−
Dark Signal (T = 60°C) 42 pA/cm2
Dark Current Doubling Temperature 5.7°C
Dynamic Range (f = 18 MHz) 70.2 dB
Estimated Linear Dynamic Range
(f = 18 MHz)
69.3 dB
Charge Transfer Efficiency
Horizontal
Vertical
0.999995
0.999999
Blooming Protection
(4 ms Exposure Time)
800X Saturation Exposure
Maximum Date Rate 18 MHz
Package Ceramic PGA
Cover Glass MAR Coated, 2 Sides or
Clear Glass
Features
• TRUESENSE Transparent Gate Electrode
for High Sensitivity
• Ultra-High Resolution
• Board Dynamic Range
• Low Noise Architecture
• Large Active Imaging Area
Applications
• Digitization
• Mapping/Aerial
• Photography
• Scientific
Thx for the tear down Mike, always a joy
Reply
@martinalooksatthings
1 day ago
15:49 that is some great bodging on of caps, they really didn't want to respin that PCB huh
8
Reply
@RhythmGamer
1 day ago
Was depressed today and then a new mike video dropped and now I’m genuinely happy to get my tear down fix
1
Reply
@dine9093
1 day ago (edited)
Did you transfrom into Mr Blobby for a moment there?
2
Reply
@NickNorton
1 day ago
Thanks Mike. Your videos are always interesting.
5
Reply
@KeritechElectronics
1 day ago
Heavy optics indeed... Spare no expense, cost no object. Splendid build quality. The CCD is a thing of beauty!
1
Reply
@YSoreil
1 day ago
The pricing on that sensor is about right, I looked in to these many years ago when they were still in production since it's the only large sensor you could actually buy. Really cool to see one in the wild.
2
Reply
@snik2pl
1 day ago
That leds look like from led projector
Reply
@vincei4252
1 day ago
TDI = Time Domain Integration ?
1
Reply
@wolpumba4099
1 day ago (edited)
Maybe the camera should not be illuminated during readout.
From the datasheet of the sensor (Onsemi): saturation 40300 electrons, read noise 12.5 electrons per pixel @ 18MHz (quite bad). quantum efficiency 62% (if it has micro lenses), frame rate 1 Hz. lateral overflow drain to prevent blooming protects against 800x (factor increases linearly with exposure time) saturation exposure (32e6 electrons per pixel at 4ms exposure time), microlens has +/- 20 degree acceptance angle
i guess it would be good for astrophotography
4
Reply
@txm100
1 day ago (edited)
Babe wake up a new mikeselectricstuff has dropped!
9
Reply
@vincei4252
1 day ago
That looks like a finger-lakes filter wheel, however, for astronomy they'd never use such a large stepper.
1
Reply
@MRooodddvvv
1 day ago
yaaaaay ! more overcomplicated optical stuff !
4
Reply
1 reply
@NoPegs
1 day ago
He lives!
11
Reply
1 reply
Transcript
0:00
so I've stripped all the bits of the
0:01
optical system so basically we've got
0:03
the uh the camera
0:05
itself which is mounted on this uh very
0:09
complex
0:10
adjustment thing which obviously to set
0:13
you the various tilt and uh alignment
0:15
stuff then there's two of these massive
0:18
lenses I've taken one of these apart I
0:20
think there's something like about eight
0:22
or nine Optical elements in here these
0:25
don't seem to do a great deal in terms
0:26
of electr magnification they're obiously
0:28
just about getting the image to where it
0:29
uh where it needs to be just so that
0:33
goes like that then this Optical block I
0:36
originally thought this was made of some
0:37
s crazy heavy material but it's just
0:39
really the sum of all these Optical bits
0:41
are just ridiculously heavy those lenses
0:43
are about 4 kilos each and then there's
0:45
this very heavy very solid um piece that
0:47
goes in the middle and this is so this
0:49
is the filter wheel assembly with a
0:51
hilariously oversized steper
0:53
motor driving this wheel with these very
0:57
large narrow band filters so we've got
1:00
various different shades of uh
1:03
filters there five Al together that
1:06
one's actually just showing up a silver
1:07
that's actually a a red but fairly low
1:10
transmission orangey red blue green
1:15
there's an excess cover on this side so
1:16
the filters can be accessed and changed
1:19
without taking anything else apart even
1:21
this is like ridiculous it's like solid
1:23
aluminium this is just basically a cover
1:25
the actual wavelengths of these are um
1:27
488 525 570 630 and 700 NM not sure what
1:32
the suffix on that perhaps that's the uh
1:34
the width of the spectral line say these
1:37
are very narrow band filters most of
1:39
them are you very little light through
1:41
so it's still very tight narrow band to
1:43
match the um fluoresence of the dies
1:45
they're using in the biochemical process
1:48
and obviously to reject the light that's
1:49
being fired at it from that Illuminator
1:51
box and then there's a there's a second
1:53
one of these lenses then the actual sort
1:55
of samples below that so uh very serious
1:58
amount of very uh chunky heavy Optics
2:01
okay let's take a look at this light
2:02
source made by company Lumen Dynamics
2:04
who are now part of
2:06
excelitas self-contained unit power
2:08
connector USB and this which one of the
2:11
Cable Bundle said was a TTL interface
2:14
USB wasn't used in uh the fluid
2:17
application output here and I think this
2:19
is an input for um light feedback I
2:21
don't if it's regulated or just a measur
2:23
measurement facility and the uh fiber
2:27
assembly
2:29
Square Inlet there and then there's two
2:32
outputs which have uh lens assemblies
2:35
and this small one which goes back into
2:37
that small Port just Loops out of here
2:40
straight back in So on this side we've
2:42
got the electronics which look pretty
2:44
straightforward we've got a bit of power
2:45
supply stuff over here and we've got
2:48
separate drivers for each wavelength now
2:50
interesting this is clearly been very
2:52
specifically made for this application
2:54
you I was half expecting like say some
2:56
generic drivers that could be used for a
2:58
number of different things but actually
3:00
literally specified the exact wavelength
3:02
on the PCB there is provision here for
3:04
385 NM which isn't populated but this is
3:07
clearly been designed very specifically
3:09
so these four drivers look the same but
3:10
then there's two higher power ones for
3:12
575 and
3:14
520 a slightly bigger heat sink on this
3:16
575 section there a p 24 which is
3:20
providing USB interface USB isolator the
3:23
USB interface just presents as a comport
3:26
I did have a quick look but I didn't
3:27
actually get anything sensible um I did
3:29
dump the Pi code out and there's a few
3:31
you a few sort of commands that you
3:32
could see in text but I didn't actually
3:34
manage to get it working properly I
3:36
found some software for related version
3:38
but it didn't seem to want to talk to it
3:39
but um I say that wasn't used for the
3:41
original application it might be quite
3:42
interesting to get try and get the Run
3:44
hours count out of it and the TTL
3:46
interface looks fairly straightforward
3:48
we've got positions for six opto
3:50
isolators but only five five are
3:52
installed so that corresponds with the
3:54
unused thing so I think this hopefully
3:56
should be as simple as just providing a
3:57
ttrl signal for each color to uh enable
4:00
it a big heat sink here which is there I
4:03
think there's like a big S of metal
4:04
plate through the middle of this that
4:05
all the leads are mounted on the other
4:07
side so this is heat sinking it with a
4:09
air flow from a uh just a fan in here
4:13
obviously don't have the air flow
4:14
anywhere near the Optics so conduction
4:17
cool through to this plate that's then
4:18
uh air cooled got some pots which are
4:21
presumably power
4:22
adjustments okay let's take a look at
4:24
the other side which is uh much more
4:27
interesting see we've got some uh very
4:31
uh neatly Twisted cable assemblies there
4:35
a bunch of leads so we've got one here
4:37
475 up here 430 NM 630 575 and 520
4:44
filters and dcro mirrors a quick way to
4:48
see what's white is if we just shine
4:49
some white light through
4:51
here not sure how it is is to see on the
4:54
camera but shining white light we do
4:55
actually get a bit of red a bit of blue
4:57
some yellow here so the obstacle path
5:00
575 it goes sort of here bounces off
5:03
this mirror and goes out the 520 goes
5:07
sort of down here across here and up
5:09
there 630 goes basically straight
5:13
through
5:15
430 goes across there down there along
5:17
there and the 475 goes down here and
5:20
left this is the light sensing thing
5:22
think here there's just a um I think
5:24
there a photo diode or other sensor
5:26
haven't actually taken that off and
5:28
everything's fixed down to this chunk of
5:31
aluminium which acts as the heat
5:32
spreader that then conducts the heat to
5:33
the back side for the heat
5:35
sink and the actual lead packages all
5:38
look fairly similar except for this one
5:41
on the 575 which looks quite a bit more
5:44
substantial big spay
5:46
Terminals and the interface for this
5:48
turned out to be extremely simple it's
5:50
literally a 5V TTL level to enable each
5:54
color doesn't seem to be any tensity
5:56
control but there are some additional
5:58
pins on that connector that weren't used
5:59
in the through time thing so maybe
6:01
there's some extra lines that control
6:02
that I couldn't find any data on this uh
6:05
unit and the um their current product
6:07
range is quite significantly different
6:09
so we've got the uh blue these
6:13
might may well be saturating the camera
6:16
so they might look a bit weird so that's
6:17
the 430
6:18
blue the 575
6:24
yellow uh
6:26
475 light blue
6:29
the uh 520
6:31
green and the uh 630 red now one
6:36
interesting thing I noticed for the
6:39
575 it's actually it's actually using a
6:42
white lead and then filtering it rather
6:44
than using all the other ones are using
6:46
leads which are the fundamental colors
6:47
but uh this is actually doing white and
6:50
it's a combination of this filter and
6:52
the dichroic mirrors that are turning to
6:55
Yellow if we take the filter out and a
6:57
lot of the a lot of the um blue content
7:00
is going this way the red is going
7:02
straight through these two mirrors so
7:05
this is clearly not reflecting much of
7:08
that so we end up with the yellow coming
7:10
out of uh out of there which is a fairly
7:14
light yellow color which you don't
7:16
really see from high intensity leads so
7:19
that's clearly why they've used the
7:20
white to uh do this power consumption of
7:23
the white is pretty high so going up to
7:25
about 2 and 1 half amps on that color
7:27
whereas most of the other colors are
7:28
only drawing half an amp or so at 24
7:30
volts the uh the green is up to about
7:32
1.2 but say this thing is uh much
7:35
brighter and if you actually run all the
7:38
colors at the same time you get a fairly
7:41
reasonable um looking white coming out
7:43
of it and one thing you might just be
7:45
out to notice is there is some sort
7:46
color banding around here that's not
7:49
getting uh everything s completely
7:51
concentric and I think that's where this
7:53
fiber optic thing comes
7:58
in I'll
8:00
get a couple of Fairly accurately shaped
8:04
very sort of uniform color and looking
8:06
at What's um inside here we've basically
8:09
just got this Square Rod so this is
8:12
clearly yeah the lights just bouncing
8:13
off all the all the various sides to um
8:16
get a nice uniform illumination uh this
8:19
back bit looks like it's all potted so
8:21
nothing I really do to get in there I
8:24
think this is fiber so I have come
8:26
across um cables like this which are
8:27
liquid fill but just looking through the
8:30
end of this it's probably a bit hard to
8:31
see it does look like there fiber ends
8:34
going going on there and so there's this
8:36
feedback thing which is just obviously
8:39
compensating for the any light losses
8:41
through here to get an accurate
8:43
representation of uh the light that's
8:45
been launched out of these two
8:47
fibers and you see uh
8:49
these have got this sort of trapezium
8:54
shape light guides again it's like a
8:56
sort of acrylic or glass light guide
9:00
guess projected just to make the right
9:03
rectangular
9:04
shape and look at this Center assembly
9:07
um the light output doesn't uh change
9:10
whether you feed this in or not so it's
9:11
clear not doing any internal Clos Loop
9:14
control obviously there may well be some
9:16
facility for it to do that but it's not
9:17
being used in this
9:19
application and so this output just
9:21
produces a voltage on the uh outle
9:24
connector proportional to the amount of
9:26
light that's present so there's a little
9:28
diffuser in the back there
9:30
and then there's just some kind of uh
9:33
Optical sensor looks like a
9:35
chip looking at the lead it's a very
9:37
small package on the PCB with this lens
9:40
assembly over the top and these look
9:43
like they're actually on a copper
9:44
Metalized PCB for maximum thermal
9:47
performance and yeah it's a very small
9:49
package looks like it's a ceramic
9:51
package and there's a thermister there
9:53
for temperature monitoring this is the
9:56
475 blue one this is the 520 need to
9:59
Green which is uh rather different OB
10:02
it's a much bigger D with lots of bond
10:04
wise but also this looks like it's using
10:05
a phosphor if I shine a blue light at it
10:08
lights up green so this is actually a
10:10
phosphor conversion green lead which
10:12
I've I've come across before they want
10:15
that specific wavelength so they may be
10:17
easier to tune a phosphor than tune the
10:20
um semiconductor material to get the uh
10:23
right right wavelength from the lead
10:24
directly uh red 630 similar size to the
10:28
blue one or does seem to have a uh a
10:31
lens on top of it there is a sort of red
10:33
coloring to
10:35
the die but that doesn't appear to be
10:38
fluorescent as far as I can
10:39
tell and the white one again a little
10:41
bit different sort of much higher
10:43
current
10:46
connectors a makeer name on that
10:48
connector flot light not sure if that's
10:52
the connector or the lead
10:54
itself and obviously with the phosphor
10:56
and I'd imagine that phosphor may well
10:58
be tuned to get the maximum to the uh 5
11:01
cenm and actually this white one looks
11:04
like a St fairly standard product I just
11:06
found it in Mouse made by luminous
11:09
devices in fact actually I think all
11:11
these are based on various luminous
11:13
devices modules and they're you take
11:17
looks like they taking the nearest
11:18
wavelength and then just using these
11:19
filters to clean it up to get a precise
11:22
uh spectral line out of it so quite a
11:25
nice neat and um extreme
11:30
bright light source uh sure I've got any
11:33
particular use for it so I think this
11:35
might end up on
11:36
eBay but uh very pretty to look out and
11:40
without the uh risk of burning your eyes
11:43
out like you do with lasers so I thought
11:45
it would be interesting to try and
11:46
figure out the runtime of this things
11:48
like this we usually keep some sort
11:49
record of runtime cuz leads degrade over
11:51
time I couldn't get any software to work
11:52
through the USB face but then had a
11:54
thought probably going to be writing the
11:55
runtime periodically to the e s prom so
11:58
I just just scope up that and noticed it
12:00
was doing right every 5 minutes so I
12:02
just ran it for a while periodically
12:04
reading the E squ I just held the pick
12:05
in in reset and um put clip over to read
12:07
the square prom and found it was writing
12:10
one location per color every 5 minutes
12:12
so if one color was on it would write
12:14
that location every 5 minutes and just
12:16
increment it by one so after doing a few
12:18
tests with different colors of different
12:19
time periods it looked extremely
12:21
straightforward it's like a four bite
12:22
count for each color looking at the
12:24
original data that was in it all the
12:26
colors apart from Green were reading
12:28
zero and the green was reading four
12:30
indicating a total 20 minutes run time
12:32
ever if it was turned on run for a short
12:34
time then turned off that might not have
12:36
been counted but even so indicates this
12:37
thing wasn't used a great deal the whole
12:40
s process of doing a run can be several
12:42
hours but it'll only be doing probably
12:43
the Imaging at the end of that so you
12:46
wouldn't expect to be running for a long
12:47
time but say a single color for 20
12:50
minutes over its whole lifetime does
12:52
seem a little bit on the low side okay
12:55
let's look at the camera un fortunately
12:57
I managed to not record any sound when I
12:58
did this it's also a couple of months
13:00
ago so there's going to be a few details
13:02
that I've forgotten so I'm just going to
13:04
dub this over the original footage so um
13:07
take the lid off see this massive great
13:10
heat sink so this is a pel cool camera
13:12
we've got this blower fan producing a
13:14
fair amount of air flow through
13:16
it the connector here there's the ccds
13:19
mounted on the board on the
13:24
right this unplugs so we've got a bit of
13:27
power supply stuff on here
13:29
USB interface I think that's the Cyprus
13:32
microcontroller High speeded USB
13:34
interface there's a zyink spon fpga some
13:40
RAM and there's a couple of ATD
13:42
converters can't quite read what those
13:45
those are but anal
13:47
devices um little bit of bodgery around
13:51
here extra decoupling obviously they
13:53
have having some noise issues this is
13:55
around the ram chip quite a lot of extra
13:57
capacitors been added there
13:59
uh there's a couple of amplifiers prior
14:01
to the HD converter buffers or Andor
14:05
amplifiers taking the CCD
14:08
signal um bit more power spy stuff here
14:11
this is probably all to do with
14:12
generating the various CCD bias voltages
14:14
they uh need quite a lot of exotic
14:18
voltages next board down is just a
14:20
shield and an interconnect
14:24
boardly shielding the power supply stuff
14:26
from some the more sensitive an log
14:28
stuff
14:31
and this is the bottom board which is
14:32
just all power supply
14:34
stuff as you can see tons of capacitors
14:37
or Transformer in
14:42
there and this is the CCD which is a uh
14:47
very impressive thing this is a kf50 100
14:50
originally by true sense then codec
14:53
there ON
14:54
Semiconductor it's 50 megapixels uh the
14:58
only price I could find was this one
15:00
5,000 bucks and the architecture you can
15:03
see there actually two separate halves
15:04
which explains the Dual AZ converters
15:06
and two amplifiers it's literally split
15:08
down the middle and duplicated so it's
15:10
outputting two streams in parallel just
15:13
to keep the bandwidth sensible and it's
15:15
got this amazing um diffraction effects
15:18
it's got micro lenses over the pixel so
15:20
there's there's a bit more Optics going
15:22
on than on a normal
15:25
sensor few more bodges on the CCD board
15:28
including this wire which isn't really
15:29
tacked down very well which is a bit uh
15:32
bit of a mess quite a few bits around
15:34
this board where they've uh tacked
15:36
various bits on which is not super
15:38
impressive looks like CCD drivers on the
15:40
left with those 3 ohm um damping
15:43
resistors on the
15:47
output get a few more little bodges
15:50
around here some of
15:52
the and there's this separator the
15:54
silica gel to keep the moisture down but
15:56
there's this separator that actually
15:58
appears to be cut from piece of
15:59
antistatic
16:04
bag and this sort of thermal block on
16:06
top of this stack of three pel Cola
16:12
modules so as with any Stacks they get
16:16
um larger as they go back towards the
16:18
heat sink because each P's got to not
16:20
only take the heat from the previous but
16:21
also the waste heat which is quite
16:27
significant you see a little temperature
16:29
sensor here that copper block which
16:32
makes contact with the back of the
16:37
CCD and this's the back of the
16:40
pelas this then contacts the heat sink
16:44
on the uh rear there a few thermal pads
16:46
as well for some of the other power
16:47
components on this
16:51
PCB okay I've connected this uh camera
16:54
up I found some drivers on the disc that
16:56
seem to work under Windows 7 couldn't
16:58
get to install under Windows 11 though
17:01
um in the absence of any sort of lens or
17:03
being bothered to the proper amount I've
17:04
just put some f over it and put a little
17:06
pin in there to make a pinhole lens and
17:08
software gives a few options I'm not
17:11
entirely sure what all these are there's
17:12
obviously a clock frequency 22 MHz low
17:15
gain and with PFG no idea what that is
17:19
something something game programmable
17:20
Something game perhaps ver exposure
17:23
types I think focus is just like a
17:25
continuous grab until you tell it to
17:27
stop not entirely sure all these options
17:30
are obviously exposure time uh triggers
17:33
there ex external hardware trigger inut
17:35
you just trigger using a um thing on
17:37
screen so the resolution is 8176 by
17:40
6132 and you can actually bin those
17:42
where you combine multiple pixels to get
17:46
increased gain at the expense of lower
17:48
resolution down this is a 10sec exposure
17:51
obviously of the pin hole it's very uh
17:53
intensitive so we just stand still now
17:56
downloading it there's the uh exposure
17:59
so when it's
18:01
um there's a little status thing down
18:03
here so that tells you the um exposure
18:07
[Applause]
18:09
time it's this is just it
18:15
downloading um it is quite I'm seeing
18:18
quite a lot like smearing I think that I
18:20
don't know whether that's just due to
18:21
pixels overloading or something else I
18:24
mean yeah it's not it's not um out of
18:26
the question that there's something not
18:27
totally right about this camera
18:28
certainly was bodge wise on there um I
18:31
don't I'd imagine a camera like this
18:32
it's got a fairly narrow range of
18:34
intensities that it's happy with I'm not
18:36
going to spend a great deal of time on
18:38
this if you're interested in this camera
18:40
maybe for astronomy or something and
18:42
happy to sort of take the risk of it may
18:44
not be uh perfect I'll um I think I'll
18:47
stick this on eBay along with the
18:48
Illuminator I'll put a link down in the
18:50
description to the listing take your
18:52
chances to grab a bargain so for example
18:54
here we see this vertical streaking so
18:56
I'm not sure how normal that is this is
18:58
on fairly bright scene looking out the
19:02
window if I cut the exposure time down
19:04
on that it's now 1 second
19:07
exposure again most of the image
19:09
disappears again this is looks like it's
19:11
possibly over still overloading here go
19:14
that go down to say say quarter a
19:16
second so again I think there might be
19:19
some Auto gain control going on here um
19:21
this is with the PFG option let's try
19:23
turning that off and see what
19:25
happens so I'm not sure this is actually
19:27
more streaking or which just it's
19:29
cranked up the gain all the dis display
19:31
gray scale to show what um you know the
19:33
range of things that it's captured
19:36
there's one of one of 12 things in the
19:38
software there's um you can see of you
19:40
can't seem to read out the temperature
19:42
of the pelta cooler but you can set the
19:44
temperature and if you said it's a
19:46
different temperature you see the power
19:48
consumption jump up running the cooler
19:50
to get the temperature you requested but
19:52
I can't see anything anywhere that tells
19:54
you whether the cool is at the at the
19:56
temperature other than the power
19:57
consumption going down and there's no
19:59
temperature read out
20:03
here and just some yeah this is just
20:05
sort of very basic software I'm sure
20:07
there's like an API for more
20:09
sophisticated
20:10
applications but so if you know anything
20:12
more about these cameras please um stick
20:14
in the
20:15
comments um incidentally when I was
20:18
editing I didn't notice there was a bent
20:19
pin on the um CCD but I did fix that
20:22
before doing these tests and also
20:24
reactivated the um silica gel desicant
20:26
cuz I noticed it was uh I was getting
20:28
bit of condensation on the window but um
20:31
yeah so a couple of uh interesting but
20:34
maybe not particularly uh useful pieces
20:37
of Kit except for someone that's got a
20:38
very specific use so um I'll stick a
20:42
I'll stick these on eBay put a link in
20:44
the description and say hopefully
20:45
someone could actually make some uh good
20:47
use of these things
Example Output:
**Abstract:**

This video presents Part 2 of a teardown focusing on the optical components of a Fluidigm Polaris biotechnology instrument, specifically the multi-wavelength illuminator and the high-resolution CCD camera.

The Lumen Dynamics illuminator unit is examined in detail, revealing its construction using multiple high-power LEDs (430nm, 475nm, 520nm, 575nm, 630nm) combined via dichroic mirrors and filters. A square fiber optic rod is used to homogenize the light. A notable finding is the use of a phosphor-converted white LED filtered to achieve the 575nm output. The unit features simple TTL activation for each color, conduction cooling, and internal homogenization optics. Analysis of its EEPROM suggests extremely low operational runtime.

The camera module teardown showcases a 50 Megapixel ON Semiconductor KAF-50100 CCD sensor with micro-lenses, cooled by a multi-stage Peltier stack. The control electronics include an FPGA and a USB interface. Significant post-manufacturing modifications ("bodges") are observed on the camera's circuit boards. Basic functional testing using vendor software and a pinhole lens confirms image capture but reveals prominent vertical streaking artifacts, the cause of which remains uncertain (potential overload, readout artifact, or fault).

**Exploring the Fluidigm Polaris: A Detailed Look at its High-End Optics and Camera System**

* **0:00 High-End Optics:** The system utilizes heavy, high-quality lenses and mirrors for precise imaging, weighing around 4 kilos each.
* **0:49 Narrow Band Filters:** A filter wheel with five narrow band filters (488, 525, 570, 630, and 700 nm) ensures accurate fluorescence detection and rejection of excitation light. 
* **2:01 Customizable Illumination:** The Lumen Dynamics light source offers five individually controllable LED wavelengths (430, 475, 520, 575, 630 nm) with varying power outputs. The 575nm yellow LED is uniquely achieved using a white LED with filtering.
* **3:45 TTL Control:**  The light source is controlled via a simple TTL interface, enabling easy on/off switching for each LED color.
* **12:55 Sophisticated Camera:**  The system includes a 50-megapixel Kodak KAI-50100 CCD camera with a Peltier cooling system for reduced noise.
* **14:54 High-Speed Data Transfer:** The camera features dual analog-to-digital converters to manage the high data throughput of the 50-megapixel sensor, which is effectively two 25-megapixel sensors operating in parallel.
* **18:11 Possible Issues:** The video creator noted some potential issues with the camera, including image smearing. 
* **18:11 Limited Dynamic Range:** The camera's sensor has a limited dynamic range, making it potentially challenging to capture scenes with a wide range of brightness levels.
* **11:45 Low Runtime:** Internal data suggests the system has seen minimal usage, with only 20 minutes of recorded runtime for the green LED.
* **20:38 Availability on eBay:** Both the illuminator and camera are expected to be listed for sale on eBay.

Here is the real transcript. Please summarize it: 
00:00:51 hello
00:00:51 everyone we're about to get started
00:00:55 welcome again to Modular Headquarters
00:00:58 and thank you so much for joining us for
00:01:00 our very first Modular Community Meetup
00:01:03 we are so excited to see all of you here
00:01:06 in person with us tonight and a special
00:01:09 shout out to everyone tuning in
00:01:10 virtually from LinkedIn and YouTube so
00:01:13 before we get started here's what we've
00:01:15 got planned for you tonight we'll kick
00:01:17 it off with a talk from Chris Latner our
00:01:20 co-founder and CEO who will share how
00:01:23 Max and Mojo are reshaping GPU
00:01:25 development and our mission to
00:01:27 democratize AI compute next we'll hand
00:01:31 it off to Jack Clayton Mojo standard
00:01:34 library engineer for an awesome live
00:01:36 demo of GPU programming in Mojo we'll
00:01:40 have time for a couple questions after
00:01:42 each segment so start thinking about
00:01:44 what you might want to ask and then at
00:01:46 the end we'll open the floor and if
00:01:48 you're hiring we'll give you the chance
00:01:50 to grab the mic and let us know where
00:01:52 you're hiring for where you're hiring uh
00:01:55 so that folks can come and find you
00:01:56 during the networking portion of
00:01:58 tonight's event so afterwards we'll
00:02:01 shift gears into networking mingling and
00:02:04 just hanging out until around 900 p.m or
00:02:06 so so without further ado please help me
00:02:09 give a very warm welcome to the
00:02:11 legendary Chris Latner
00:02:21 awesome thank you Carolyn um welcome
00:02:22 everyone super excited to see you all
00:02:23 this is an amazing turnout i'm really
00:02:25 glad that you've joined us here but also
00:02:26 on the live stream um we have never done
00:02:29 this before so prepare yourself this
00:02:32 could be a catastrophic fail but even if
00:02:35 it is hopefully it's fun so we'll see
00:02:37 how it goes and if it goes well then
00:02:39 maybe we'll do it again so we'll see how
00:02:40 this is so today as Caroline said I'm
00:02:43 going to be talking about kind of two
00:02:45 things one is this whole compute thing
00:02:49 right so I've been writing this blog
00:02:50 post series this takes a lot of my time
00:02:53 um is anybody reading this has anybody
00:02:55 heard this all right that's awesome
00:02:57 sometimes some you're like shouting into
00:02:59 the void and so you don't you don't
00:03:00 actually uh so I'll talk a little bit
00:03:02 about this and kind of do a condensed
00:03:04 form but then I'll also share some what
00:03:06 modular is doing about it which the blog
00:03:09 post series has not talked about
00:03:10 conveniently it's building up to it
00:03:12 we'll get there but not gone to talking
00:03:14 about it and then we'll also talk about
00:03:16 some things we've not shared with the
00:03:18 world yet that are pretty exciting how
00:03:20 we're opening things up so with that
00:03:23 I'll just jump in and also warning I've
00:03:25 never given this talk before and so be
00:03:28 nice so what what are we here to do well
00:03:30 we want to rebuild GPU software right ai
00:03:34 is super important to me i've been
00:03:35 working on this thing for years ai is so
00:03:38 so so important to the world but all the
00:03:39 software is so bad and so one of the
00:03:42 things that the blog series tries to do
00:03:44 is tries to dissect this understand why
00:03:48 it is that something so important with
00:03:50 so much money so much talent so many
00:03:52 people and energy and change and thrash
00:03:54 and all this stuff is still the software
00:03:56 is so
00:03:57 problematic and so we've seen what we as
00:04:01 an industry have seen is that with all
00:04:02 the different use cases with chat GPT
00:04:04 with all this different there's a huge
00:04:06 amount of demand right the applications
00:04:09 are endless the innovations are endless
00:04:12 but on the other hand and and what we've
00:04:14 got as a consequence of that is that all
00:04:16 the people builtware want to solve this
00:04:19 problem there's so much excitement so
00:04:21 many new ideas so many ways to build a
00:04:24 chip so many chips you can build because
00:04:27 it turns about yeah data center is a big
00:04:29 deal so are cell phones so are embedded
00:04:31 IoT so is like all the different use
00:04:33 cases that you might want to use AI in
00:04:35 this is technology that can touch
00:04:37 everything and of course while we say AI
00:04:39 like a million times in this talk it's
00:04:42 actually about heterogeneous compute
00:04:45 right and AI to me is also just an
00:04:47 excuse to tackle this long-standing
00:04:49 problem of heterogeneous compute CPUs
00:04:52 and GPUs AS6 like this entire realm of
00:04:55 accelerated compute and so what we're
00:04:57 doing is we really want to crack this
00:04:59 open because there hasn't been software
00:05:00 to do now there's a flip side of this so
00:05:05 there is a winner in this C
00:05:07 category and so it's it's amazing their
00:05:11 contribution right i mean Alexet
00:05:13 happened on CUDA for example right it's
00:05:15 amazing that this has happened but it we
00:05:18 are kind of at this inflection point
00:05:20 we're kind of stuck a little bit as an
00:05:21 industry and so uh tonight we're going
00:05:24 to dig into this and so I'll briefly
00:05:26 talk about what is CUDA and why hasn't
00:05:28 anything worked but the more exciting
00:05:30 and excite interesting part is talking
00:05:32 about hey okay modular people like
00:05:34 you've been working on this thing for
00:05:35 years like what does it mean and so
00:05:37 we'll talk about that so first thing I
00:05:40 wanted to say is that CUDA is an amazing
00:05:42 thing I have a respect and again I think
00:05:44 we as an industry have a lot of we need
00:05:47 to give CUDA a lot of its deserved
00:05:50 respect for catalyzing AI right it made
00:05:53 TensorFlow and PyTorch possible like a
00:05:54 lot of these things happened really
00:05:56 because of CUDA alexet again like that
00:05:58 was it catalyzed the deep learning
00:06:00 revolution tons of stuff has been built
00:06:02 on top of CUDA but there is the flip
00:06:04 side right which is CUDA is actually not
00:06:06 that great right cuda made sense 18
00:06:09 years ago whatever it was um but the
00:06:12 world's moved on cuda hasn't right and
00:06:15 so what CUDA has done is it's piled up
00:06:17 more and more and more stuff uh to scale
00:06:19 in new use cases but now it's this
00:06:22 rickety moat it's a moat but it's also a
00:06:25 swamp that is surrounding us and you can
00:06:27 feel this you can feel this in the
00:06:28 systems we have today so the systems we
00:06:30 have you know not to pick on any one but
00:06:33 there are this cobbled together pile of
00:06:35 different technologies come together
00:06:37 over the course of many years and many
00:06:40 really smart people have worked on these
00:06:42 systems like this is not negative about
00:06:44 any individual engineer or person or
00:06:46 product manager or whatever but
00:06:48 everybody's always looked at their part
00:06:49 of the problem and so how do we take
00:06:52 given all the stuff that exists how do I
00:06:54 have impact by making my thing better
00:06:57 given that everything else is somewhat
00:06:58 unfortunate but it's convenient and so
00:07:01 as you do this as you iterate as AI
00:07:03 changes as hardware changes as all these
00:07:04 things keep going you get
00:07:07 complexity complexity is the
00:07:10 enemy okay so what else is wrong with
00:07:12 CUDA okay obviously runs on one vendor's
00:07:15 hardware the other thing that's funny
00:07:17 about CUDA is that it only runs on GPUs
00:07:19 even Nvidia's building CPUs they have
00:07:21 this whole Grace thing they're very
00:07:23 proud of it cuda doesn't run on that
00:07:25 super interesting it's the complexity
00:07:28 the closeness the proprietariness and
00:07:30 innovation in around the broader
00:07:32 ecosystem and so we're also blocked
00:07:35 because if we want things to move fast
00:07:36 we need that vendor to go do this
00:07:39 um all all due respect to CUDA it is not
00:07:43 very Pythonic i find it very exciting
00:07:46 very flattering that Nvidia is now
00:07:48 adding tons of Pythony things and
00:07:50 they're trying to like fit all the stuff
00:07:52 that is Python with Nvidia specific
00:07:55 stuff but but core CUDA is not and a lot
00:07:58 of the ecosystem are not using the
00:08:00 technologies they're introducing and so
00:08:02 if you want to have state-of-the-art
00:08:03 best TCO best power of the hardware you
00:08:06 have to use CUDA
00:08:07 C++
00:08:09 is not very AIcentric and not very
00:08:12 Python uh C++ is I I'm think I'm
00:08:15 entitled to say this uh C++
00:08:18 sucks are not awesome compile times are
00:08:22 miserable um if you don't understand
00:08:25 that just ask me offline i can explain
00:08:27 this and and this whole stack just
00:08:29 requires deep intricate knowledge of
00:08:31 like all these things which are poorly
00:08:32 documented and so what does this mean if
00:08:34 you're actually building systems well it
00:08:36 means that like KUDNN for example is a
00:08:39 massive library ecosystem you put all
00:08:41 this stuff together all which is kind of
00:08:43 cobbled together and you get these big
00:08:44 containers and the containers vary but
00:08:47 15 gigs is not unusual sometimes you can
00:08:49 get 50 gigs like you know this packaging
00:08:52 dependency system just becomes a mess so
00:08:56 it's not just me that sees these
00:08:57 problems like we just picked a random
00:08:59 collection of the pain that people are
00:09:01 suffering out there just getting CUDA
00:09:03 versions to line up with PyTorch
00:09:05 nightmare if you want to do something on
00:09:06 AMD well you don't have CUDA and so you
00:09:09 have another nightmare or a different
00:09:10 set of problems if you want to have uh
00:09:12 you know any of these things going on
00:09:15 the one hand the demo looks really
00:09:16 appealing you can follow the little
00:09:18 tutorial and you stay on the happy path
00:09:20 you get to success but then you try
00:09:22 something slightly off the path
00:09:24 everything breaks the magic is gone and
00:09:26 now you have to go debug everything in
00:09:29 the soft back and try to figure out what
00:09:31 assumption at what layer didn't compose
00:09:33 on something else and so now you're
00:09:35 stuck because the beautiful demo didn't
00:09:37 fail so this is AI development today
00:09:41 so there are different theories on how
00:09:43 to fix this so um one one one approach
00:09:46 which lots of people take uh for example
00:09:48 NIMS say okay well all this software all
00:09:50 this ecosystem is such a nightmare
00:09:51 nobody can get it to work but there are
00:09:53 very specific use cases if you want
00:09:56 llama 3 we can go tackle all this
00:09:58 complexity get llama 3 in this one
00:10:00 config to be super optimal and perfect
00:10:02 put in a fake
00:10:04 box and that that works um but the
00:10:08 problem with that is you've destroyed a
00:10:09 lot of the value of AI a lot of the
00:10:11 value of AI is it's not about one thing
00:10:13 a wide variety of use cases you might
00:10:16 care about latency not just throughput
00:10:18 you might care about a slightly
00:10:20 different model you might want to put in
00:10:21 a Laura adapter or something and so a
00:10:24 lot of what the power and the magic of
00:10:26 AI is about the innovation the research
00:10:29 the the velocity in which people can
00:10:31 move and so I find this like make
00:10:33 everything fixed function solution to be
00:10:36 fairly dystopian like it it destroys a
00:10:39 lot of what I believe in in terms of
00:10:40 innovation and and the velocity and the
00:10:42 progress in the real meaning of what has
00:10:44 made AI
00:10:45 successful and so why hasn't given all
00:10:48 these problems why hasn't anything
00:10:50 worked well blog post series kind of
00:10:51 goes into this first you have to
00:10:53 understand why it succeeded and so this
00:10:56 is something that again people different
00:10:59 people look at different technologies in
00:11:01 different ways what I try to do is I try
00:11:02 to understand and look look into it and
00:11:04 understand okay well it's not an
00:11:07 accident that things become successful
00:11:09 let's go understand what happened well
00:11:12 CUDA succeeded for a number of reasons
00:11:14 including luck but not just luck they
00:11:17 built an
00:11:18 amazing gaming ecosystem they built on
00:11:21 their install base they had P with
00:11:24 laptop GPUs and things like this so it
00:11:27 enabled people to learn how to program
00:11:29 CUDA on inexpensive devices and then
00:11:31 scale that's actually a really big deal
00:11:33 that's something that for example if
00:11:35 you're building just a data center line
00:11:37 you you lose out on um of course they
00:11:40 invested early even when it was like
00:11:42 almost physically irresponsible to do so
00:11:44 like Nvidia the GeForce 3 I'm super
00:11:46 impressed it was like a huge bet for the
00:11:48 company on programmability and so they
00:11:50 made really big bets when it was obvious
00:11:53 which I have tons of respect for but
00:11:56 then what they did is they said well as
00:11:58 AI is evolving as Tensflow and PyTorch
00:12:00 have evolving you know in in apparently
00:12:03 good interest go make it go fast on our
00:12:05 hardware the consequence of that is that
00:12:07 then they also said okay well all these
00:12:09 frameworks were now co-designed and
00:12:11 locked to their hardware because to CUDA
00:12:14 and therefore it was very difficult for
00:12:15 anything else to come in and so PyTorch
00:12:18 and Tensflow both have a you know they
00:12:20 they accidentally knited
00:12:23 CUDA so deepse was a big deal and so
00:12:26 that was the excuse for starting blog
00:12:28 post series because I think to me
00:12:29 deepseek was it's just another day in
00:12:32 the neighborhood of AI right it's like
00:12:33 okay well you wake up and now things go
00:12:35 10x faster faster than they used to
00:12:36 because new research right but I think
00:12:39 deepseek was more than that of the world
00:12:41 deepseek both the geopolitical
00:12:43 ramifications but also the technological
00:12:45 ramifications caused a huge wakeup call
00:12:48 and I think a lot of people were talking
00:12:49 about compute in a really new way and so
00:12:52 one of the things that was super
00:12:54 interesting to me is that they got a lot
00:12:56 of attention by air quotes going down to
00:12:59 PTX this is something that if you're a
00:13:01 GPU programmer you kind of have to
00:13:03 routinely do because tensor cores
00:13:05 are you to do this right and I I think
00:13:08 the world didn't realize just how
00:13:10 problematic the CUDA ecosystem is in the
00:13:12 fact that it's not just DeepSec that
00:13:14 does this like lots of people have to do
00:13:16 this and this is a bug not a feature
00:13:19 um uh what I believe to be true and
00:13:22 others as well is that efficiency gains
00:13:24 like what deepseek brought lead to
00:13:26 increased consumption more use cases
00:13:28 more demand AI goes to more places
00:13:30 because as a cost curve changes as you
00:13:32 make things less expensive suddenly you
00:13:34 can do that
00:13:35 technology as Satcha point out Jven
00:13:38 Jven's paradox which is a very
00:13:40 interesting way to look at this now but
00:13:43 the problem is is that okay well if you
00:13:45 go look at deepseek and I'm again I'm
00:13:47 super impressed with their work they've
00:13:48 been opening a lot they've been
00:13:49 publishing a lot i mean they've massive
00:13:51 contribution to the AI
00:13:53 ecosystem they are so advanced they they
00:13:57 as well as some of the top research labs
00:13:59 are doing things at such an advanced and
00:14:02 incredible level but you have to be at
00:14:04 that incredible level where you can
00:14:06 afford to pay hundreds of researchers
00:14:07 and do this kind of work to be able to
00:14:09 unlock the power of the silicon and to
00:14:11 me like on the one hand it's amazing
00:14:13 what can be done but it's also again
00:14:16 kind of dystopian if only the top five
00:14:18 research groups in the industry can
00:14:20 afford to do it i don't think that's a
00:14:22 path to success for us as an industry
00:14:24 and so this is where democratizing has
00:14:26 many different meanings but let's like
00:14:28 get more people able to participate in
00:14:30 this now there's lots of attempts to
00:14:32 solve this problem i'm going to go
00:14:33 through this lightning lightning speed
00:14:36 open CL is the one that should have won
00:14:38 right it was the industry standard
00:14:41 it's it's a a great technology i worked
00:14:43 on it when I was much earlier in my
00:14:45 career um uh but the problem is is it
00:14:48 turned into a committee project right it
00:14:50 moved with comm tensor cores had a lot
00:14:54 of problems that prevented from actually
00:14:55 scaling into the AI ecosystem and um and
00:14:58 you know what in contrast you look at
00:15:00 CUDA CUDA had a strong leader that look
00:15:03 you know what I'm going to solve the
00:15:05 most important use cases in their
00:15:06 opinion and they could drive it much
00:15:08 stronger in a specific direction which
00:15:10 you may or may not agree with but it
00:15:13 showed a lot of velocity and I think
00:15:14 this is the problem that I see with a
00:15:16 lot of community or you know standards
00:15:19 bodies type
00:15:20 approaches what about I'm Hey I'm a I'm
00:15:23 a fan of compilers does anybody else
00:15:24 like compilers here so compilers are
00:15:27 good um so TVM is I think fading away
00:15:31 now xla is something that I happen to
00:15:32 work on so I know a lot more about it um
00:15:35 AI compilers are thing because you
00:15:37 getization kernels don't
00:15:40 generalize of in AI you have many
00:15:43 different kernels to fuse them and if
00:15:45 you have to write all permutations of
00:15:46 all fused kernels you quickly run out of
00:15:48 kernel engineers who can do the work to
00:15:50 actually tune it both for all
00:15:51 permutations of kernels but then all
00:15:53 generations of hardware then all the
00:15:55 dtypes and then all the you know all the
00:15:57 different use cases and suddenly you run
00:15:59 out of kernel engineers you just can't
00:16:00 scale and so compilers are awesome go
00:16:03 compiler
00:16:04 Um and it solved this by making it so
00:16:06 that you could synthesize in an
00:16:08 automated way a novel kernel by using
00:16:11 compiler techniques now the problem with
00:16:14 this is twofold one of which is that
00:16:15 many of projects never could deliver the
00:16:17 peak performance of a kernel author and
00:16:20 so a lot of them ended up using like the
00:16:22 CUDA libraries for matrix multiplication
00:16:24 for example and just did kernel fusion
00:16:26 for the easy cases one problem but there
00:16:29 there's a much bigger problem so the
00:16:31 much bigger problem and compiler folk I
00:16:33 love you um we make fun of the kernel
00:16:36 folk because they don't scale but it
00:16:38 turns out compiler folk don't scale
00:16:39 either so if you say you need a compiler
00:16:42 engineer in the loop to be able to in
00:16:44 innovate in algorithms then you quickly
00:16:46 run out of compiler engineers or you run
00:16:49 to this problem where you may have an
00:16:51 amazingly smart compiler but the
00:16:53 compiler engineer doesn't know the cross
00:16:55 product of the compiler algorithms the
00:16:58 hardware the dtypes the crazy new
00:17:01 research paper that just got published
00:17:03 the hack that the hardware has that
00:17:05 allows you to cut three cycles out of
00:17:06 the inner loop of the thingy and all of
00:17:09 that into one brain i mean to me what I
00:17:11 learned from XLA is it doesn't scale and
00:17:13 there are like when I was there there
00:17:15 was like two or three humans that could
00:17:18 do some of this work and it was just a
00:17:20 huge bottleneck for TPUs and it was a
00:17:22 huge problem now these technologies also
00:17:25 have a different problem that problem is
00:17:26 called Genai and so a lot of these
00:17:29 technologies were designed for
00:17:31 traditional AI and they made sense in
00:17:32 that context but when Genai came over it
00:17:34 really changed the it wasn't about
00:17:36 putting a reu onto a matrix
00:17:38 multiplication anymore it was about
00:17:40 flash attention right and so when when
00:17:42 these things happen when you get MLA you
00:17:45 get like these much more advanced
00:17:46 algorithms suddenly the world got so
00:17:48 much more complicated that the compiler
00:17:50 approaches or these this category of
00:17:52 compiler approaches just didn't scale
00:17:55 and so again we found ourselves as an
00:17:56 industry writing all the kernels and
00:17:58 when you're writing all the kernels
00:17:59 typically those kernels got written in
00:18:01 CUDA because that's where all the
00:18:02 installed hardware was and then again
00:18:05 everything got locked onto one vendor's
00:18:07 platform what about Triton so I'm a big
00:18:10 fan of Triton people like Triton
00:18:12 triton's a good thing too um Triton is
00:18:15 one of these things i said "Okay well
00:18:17 CUDA C++ not that great it's really hard
00:18:20 to use it's very low level." Triton and
00:18:23 Phil and other folks did a really job of
00:18:24 upleveling the programming paradigm and
00:18:26 saying "Let's get the world into Python
00:18:28 let's get people off of uh individual
00:18:31 threads and start thinking about a much
00:18:33 higher level tilebased programming
00:18:35 model." And I think this is a huge step
00:18:37 forward this has been very popular and
00:18:38 very successful in the industry um this
00:18:40 really held when PyTorch 2 came out with
00:18:43 this inductor and Dynamo and this
00:18:45 technology stack that really kind of
00:18:46 endorsed uh Triton the solution to
00:18:50 PyTorch now there's some problems with
00:18:52 it though so first of all it's again
00:18:54 it's a fancy compiler compilers and so
00:18:58 you get a lot of productivity but you
00:18:59 also give up you know it varies but
00:19:01 somewhere on the 20% of performance of
00:19:03 your
00:19:04 chip 20% of cost on a GPU is a lot and
00:19:10 so all of your experience what I've been
00:19:13 told by many folks is that train isn't
00:19:15 really used for state-of-the-art geni
00:19:17 inference like it's been very popular
00:19:20 for training and things like this where
00:19:22 tend to and velocity and things like
00:19:23 this and research are really important
00:19:25 but I've heard of many labs that use
00:19:28 Triton for research and prototyping and
00:19:30 things like this but then have to
00:19:31 rewrite in CUDA C++ and so that's that's
00:19:35 that's value that's contribution that's
00:19:36 awesome that they're making a use case
00:19:38 better but it's really deeply
00:19:40 unfortunate when you have like okay I
00:19:42 prototype in Visual Basic and I have to
00:19:43 rewrite in C++ or something right
00:19:47 and technologies i think Triton also has
00:19:50 another hidden secret which I don't know
00:19:52 if everybody in this room will agree
00:19:54 with me i'm sure some of you work on AS6
00:19:56 triton was not designed for AS6 and so
00:19:59 the programming model the way the memory
00:20:01 and the pointer model work like the like
00:20:03 all this stuff is very GPU specific and
00:20:05 so while it's appealing to think okay
00:20:07 well I can just write this code the the
00:20:10 inner secret of Triton is that you don't
00:20:12 even get portability across Nvidia
00:20:13 generations it's like you definitely
00:20:15 don't get portability off and and and
00:20:18 then you end up in this realm where okay
00:20:19 well you can't express the full power of
00:20:21 the hardware for your ASIC well suddenly
00:20:23 if you're building a chip it's really
00:20:25 quite problematic because giving up more
00:20:27 than 20% performance means your chip's
00:20:30 not competitive it's hard enough to keep
00:20:31 up with Nvidia on just flops and
00:20:34 features and things like this in the
00:20:35 hardware but if you're holding back the
00:20:36 hardware's potential based on software
00:20:38 like this it becomes an even bigger
00:20:40 challenge so yeah so I I what I learned
00:20:43 from this is really quite important
00:20:45 which is this is incredible validation
00:20:47 that CUDA C++ is too hard and I think
00:20:50 the world wants something that's much
00:20:51 easier to use and so I think this is it
00:20:53 has taught me a tremendous amount but
00:20:56 the flip side of it is we can't give up
00:20:58 what makes CUDA great and that's
00:21:01 performance what about ML well I'm also
00:21:04 a fan of MLR does anybody else like ML
00:21:06 here is this a good thing so so the blog
00:21:08 post talks about this because people
00:21:10 always ask me in particular like why
00:21:13 didn't MLR solve this like isn't isn't
00:21:15 it supposed to be the thing that solves
00:21:16 all this stuff and this is where I get
00:21:18 very sad because it's also very personal
00:21:21 and um and MLR is amazing i'm very
00:21:24 excited to see how wide it's gone and
00:21:26 like so many people use it for so many
00:21:27 things and it is the it is widely
00:21:31 successful across enabling a tremendous
00:21:33 number of chips i don't I know some of
00:21:34 them which is amazing i don't know all
00:21:36 of them but the problem is it doesn't
00:21:38 provide an endto-end AI stack and there
00:21:40 are things out in the ecosystem there's
00:21:42 Eerie and many of these things that have
00:21:44 come up and existed but they haven't
00:21:45 really solved this problem and what's
00:21:48 what happened is a lot of the ML
00:21:51 ecosystem tried to be tried to build a
00:21:53 better XLA is probably the easiest way
00:21:55 to explain it but XLA got left in the
00:21:58 dust by Genai and so a lot of the
00:22:01 technologies a lot of the dialects a lot
00:22:02 of stuff in the ml ecosystem is really
00:22:04 cool but it's really a it's like a
00:22:05 tinker toy set it's like a some assembly
00:22:07 required and so I think ML is an amazing
00:22:10 thing and it's a great I'm obviously
00:22:11 very proud of many of the people that
00:22:13 have helped make it possible but it's
00:22:16 not solving the CUDA problem it's
00:22:18 enabling people to build systems in in
00:22:20 the in this
00:22:21 space okay what about hardware companies
00:22:24 again uh hardware makers are awesome the
00:22:27 the challenge with bit innovating in
00:22:28 hardware is that the software teams are
00:22:31 just don't have a chance it's just so
00:22:33 hard to do this work and everything ends
00:22:36 up being stacked against you not only is
00:22:38 Nvidia seeding all of the software
00:22:40 ecosystem making it CUDA specific but
00:22:43 geni is changing so rapidly all the
00:22:45 technology is moving so fast there isn't
00:22:46 a thing really to build into it depends
00:22:48 on the company but hardware leadership
00:22:50 often doesn't understand how hard it is
00:22:51 to build software because the hardware
00:22:54 leadership again I don't know I don't
00:22:57 speak for every but hardware leaders
00:23:00 were built up were brought up you know
00:23:02 say 10 years ago or 15 years ago and
00:23:04 typically they're building a CPU or
00:23:06 they're building a networking thing
00:23:08 building some other ecosystem and if
00:23:10 you're building a CPU enabling software
00:23:13 means build a GCC or an LVM back end and
00:23:16 then I get Linux I get web browsers I
00:23:17 get
00:23:18 email I get I get everything with a
00:23:21 constrained investment in plugging into
00:23:23 a
00:23:24 thing ai doesn't work that way there is
00:23:28 and this is for everybody and so as a
00:23:30 consequence everybody ends up signing up
00:23:32 for this problem that seems like it's
00:23:34 easy to get a thing to work but then
00:23:35 when you get to the general case
00:23:37 suddenly it gets exponentially more
00:23:39 difficult of folks in the secret
00:23:44 so what if this is a long way of saying
00:23:47 this is what the world's been dealing
00:23:48 with and when we started modular we knew
00:23:51 a lot of this a lot of the details were
00:23:53 different but a lot of the lessons
00:23:55 learned I had experience with TPUs and
00:23:57 many other things and so what if we
00:24:00 could build this what if we could really
00:24:02 crack this what if we could change
00:24:04 change the trajectory what if we could
00:24:06 do something that could be a fundamental
00:24:08 contribution and help solve some of
00:24:09 these long-standing
00:24:11 problems I think this would be pretty
00:24:13 cool be a good thing but it's also
00:24:17 really hard right we can't expect to
00:24:21 just do the same thing that didn't work
00:24:22 before and have it work this time we
00:24:26 have to do something that's quite
00:24:28 different we have to change the we have
00:24:30 to redefine the rules and so this is
00:24:32 what again the crazy folks at Modular
00:24:34 have been doing for years is building
00:24:37 many of the different pieces and we've
00:24:38 been going through years of research
00:24:40 because it's pure research required to
00:24:43 be able to build new abstractions new
00:24:44 concepts new technologies new syntax new
00:24:47 things that all can come together that
00:24:48 we think can actually with this now
00:24:51 we're still very early right this is
00:24:53 this is not a small problem this is a
00:24:55 big problem have not and solve this
00:24:57 today but I am really really excited
00:25:00 that just this quarter the amount of
00:25:01 progress we've made just next quarter
00:25:03 what I know is going to happen and
00:25:05 through the rest of this year it's all
00:25:06 coming together and so I'm really happy
00:25:09 to talk about what this is what our
00:25:10 approach is and share this with you and
00:25:12 obviously if you're interested we'd love
00:25:13 to talk about it and so what is modular
00:25:17 building well we want to build a new
00:25:19 world without CUDA and so I love Nvidia
00:25:22 they're an amazing company their
00:25:24 hardware is amazing um the challenge I
00:25:26 see is with CUDA and and what I want to
00:25:29 see is something that can run really
00:25:30 well on Nvidia and run on other places
00:25:33 because that hardware is very important
00:25:35 to the world and so it's not really
00:25:38 Nvidia's fault it's it's just what CUDA
00:25:41 has done to us and so we want to go
00:25:42 build something that can help scale into
00:25:45 this how do we do this well this is a
00:25:48 big problem this is an industry scale
00:25:50 problem and so what we did was we broke
00:25:52 this down into pieces and so first
00:25:55 there's a language aspect so you run
00:25:57 squarely into this problem of domain
00:25:59 specific languages are difficult to use
00:26:02 they have bad tooling debugging all the
00:26:03 stuff that the Triton blog post thing
00:26:05 talked about but then on the other hand
00:26:07 you have all the existing languages like
00:26:09 you know Rust and Swift and C++ and
00:26:11 stuff like this they're not really
00:26:13 designed for GS compute some of them can
00:26:16 be used in some ways but they're not
00:26:18 designed for it and so one of the core
00:26:21 assumptions that we made is AI is
00:26:23 important and will gain an importance
00:26:24 and hardware is going to get more weird
00:26:26 and we need to be able to scale into all
00:26:28 of the things and so that squarely I
00:26:31 tried to resist this but I squarely ran
00:26:33 us into the language problem and then
00:26:36 dot dot dot I think what many of you
00:26:37 know is Mojo mojo comes out well so Mojo
00:26:41 is a really cool thing you'll see some
00:26:42 demos later um I'm very excited about
00:26:44 the pace that and the progress that
00:26:46 Mojo's made but what it enables you to
00:26:48 do is actually be able to get the full
00:26:50 power of the hardware have a development
00:26:52 experience be able to scale and run on
00:26:55 wide ranges of different devices and
00:26:57 it's designed for this heterogeneous
00:26:59 talk to weird tensor cores and all the
00:27:01 diff goofy things that hardware people
00:27:03 keep coming up with because that's
00:27:05 inherent to the problem and so it's not
00:27:09 solution but it's a really important
00:27:11 part of the solution and when we talk
00:27:12 about higher levels in the stack all of
00:27:14 the code that we use that uh runs on the
00:27:17 GPU is written in Mojo and this is what
00:27:19 we mean by not using CUDA so we don't
00:27:22 use CUDNN or vendor libraries or cutless
00:27:24 or like any any of that stuff we've
00:27:26 rebuilt that entire
00:27:27 ecosystem well if you take a step out
00:27:30 now you get to cool you can write GPU
00:27:32 kernels how do you actually use them
00:27:35 right and today I love people to write
00:27:37 GPU kernels and you'll learn more about
00:27:38 that later uh but but a lot of people
00:27:40 work at the AI layer right they work at
00:27:42 hey I have a matrix multiplications and
00:27:44 convolutions and I have a transformer i
00:27:46 have a a dense layer i I want these I
00:27:48 want a module this I want to think about
00:27:50 things in terms of AI and what we've
00:27:53 built is a very tiny be it's not fair to
00:27:56 call it an AI framework yet but it is a
00:28:00 very simple inference focused AI
00:28:02 framework in Python that allows you to
00:28:05 develop
00:28:07 models that are super predictable super
00:28:10 good control designed for Genai makes it
00:28:12 so we can solve these problems and get
00:28:14 the full power of the hardware which I
00:28:16 think is really really really important
00:28:18 now this framework again it's very early
00:28:20 and so it's it's exciting but still
00:28:22 still coming into its existence called
00:28:24 max has serving components it has the
00:28:26 kernels it has a bunch of different
00:28:28 things in this ecosystem but also gives
00:28:30 you an autofusing graph component you a
00:28:32 lot of the technologies that are quite
00:28:34 advanced and that even the existing uh
00:28:36 systems don't have yet which
00:28:38 dramatically simplifies it and designing
00:28:41 the abstractions this is why modular is
00:28:43 a project for three years was so key
00:28:45 designing the abstractions so you can
00:28:47 compose so that we to get this thing
00:28:48 simple at the bottom enables us to make
00:28:51 a scalable interface going
00:28:53 up uh we're just now bringing in even
00:28:57 bigger higher level pieces and so we've
00:28:59 only just started talking about this but
00:29:00 we have things like okay well once you
00:29:02 solve for the code that runs on AGPU and
00:29:05 now you start building pipelines and you
00:29:07 start doing the max very fancy KB cache
00:29:10 optimizations and like all this kind of
00:29:11 stuff well suddenly you get to the
00:29:13 problem of hey well I have 200 GPUs or
00:29:15 2,000 GPUs how do I them and so what our
00:29:18 technology is which we're not going to
00:29:20 talk much about today but if you curious
00:29:21 let's it is saying hey if you're an
00:29:24 enterprise and you have a lot of GPUs
00:29:25 and you're running a platform team and
00:29:27 need reliability you want your product
00:29:29 team to be able to innovate in models
00:29:31 and do stuff and then the platform team
00:29:33 shouldn't have to like chase AI research
00:29:34 they should be able to manage the GPUs
00:29:36 and so this a natural set of concentric
00:29:39 goals where everything builds together
00:29:40 and builds on top of each other and it's
00:29:42 actually uh very simple which
00:29:45 is so let's dig into each of these just
00:29:47 I'll give you the whirlwind tour so Mojo
00:29:49 assume that most of you are familiar
00:29:51 with this i'm not going to talk too much
00:29:52 about because Jack will talk about it
00:29:53 later well Mojo by definition hopefully
00:29:56 you know is a Pythonic language so it is
00:29:58 not Python but it is designed to be very
00:30:00 familiar to people who are are working
00:30:02 with this um by the way we Mojo Python
00:30:06 interrupt is coming really well and so
00:30:08 maybe in a month or something there will
00:30:10 be some really cool announcements about
00:30:11 this and so you can extend existing
00:30:13 Python Python packages in Mojo and make
00:30:16 that super easy but our focus has been
00:30:18 on GPUs right and this is the core
00:30:20 problem we need to solve which is we
00:30:22 need GPUs to go
00:30:23 fast advanced type system for example
00:30:26 Mojo has dependent types uh full power
00:30:29 of the hardware full access to ML full
00:30:31 power full access to like inline
00:30:32 assembly and tensor ptx and like all
00:30:35 this stuff but then it interoperates
00:30:38 with the existing world and this is
00:30:40 again the bottom of our stack but a
00:30:41 really really really important component
00:30:43 of this
00:30:44 um max I think I already talked about
00:30:46 this this is the framework level this
00:30:48 gives you something that's
00:30:50 VLM you get open compatible APIs if
00:30:53 you're serving but if you want you can
00:30:54 go down and say hey just run a subg
00:30:56 graph on a GPU and so you get a very
00:30:58 nice GPU programming experience um this
00:31:00 all you can use this in Mojo like the
00:31:02 preferred API is all Python the reason
00:31:05 we do this is just lots of people are
00:31:07 already used to technologies in space
00:31:08 using
00:31:09 Python mojo is required for getting GPU
00:31:13 per Python is fine for like I'm building
00:31:17 a graph and so we said okay we'll just
00:31:19 let's use Python for what it's good at
00:31:23 um by the way you say build a new
00:31:25 framework that sounds insane and it is
00:31:27 kind of insane but this is not something
00:31:29 where we have like ResNet 50 we're now
00:31:31 at the point where we have over 500
00:31:32 models and variants and things like this
00:31:34 in our native stack running on a wide v
00:31:37 variety of hardware which is pretty cool
00:31:39 and so we'll talk about where you can
00:31:40 find these later um deployment this is
00:31:43 also a pretty important thing we totally
00:31:45 believe in meeting people where they are
00:31:47 and so we make it super easy to get a
00:31:48 Docker container and we'll give you
00:31:50 preconfigured ones they're super small
00:31:53 this is one simple way to understand
00:31:54 what without CUDA means um these small
00:31:58 containers by the way it's kind of an
00:32:00 open secret please hush hush don't tell
00:32:01 anybody same binary runs on Nvidia and
00:32:04 AMD GPUs today we haven't announced that
00:32:07 please don't tell the world yet that's
00:32:09 actually a pretty big deal um and that's
00:32:11 that's a thing nobody's ever done before
00:32:13 right and so this is
00:32:16 very telling the world and telling the
00:32:19 story about this but this will have
00:32:22 professions so let's talk about license
00:32:25 so this is something I'll just be
00:32:26 straight with you i think we've done a
00:32:27 great job at
00:32:30 um I'll tell you the thinking but then
00:32:33 I'll also tell you why I'm very happy
00:32:34 it's time for new thinking so the
00:32:36 thinking was we're building a research
00:32:39 project it's turns out it took three
00:32:42 years to go from like that we have an
00:32:44 idea that we could build something great
00:32:45 to I believe it's working like the I
00:32:50 believe it's working moment was really
00:32:52 this December release that we called
00:32:54 246 which is where we could show we
00:32:56 could run state-of-the-art performance
00:32:57 on A100 with one model and the that
00:33:01 required the entire tech stack to line
00:33:02 up and work right and in that moment of
00:33:05 three years of development the decision
00:33:07 we made which you can agree is you can
00:33:10 agree or disagree is we said look the
00:33:12 risk is can we achieve our goal and so
00:33:15 we've kind of been wavering between do
00:33:17 we want people to adopt this not or is
00:33:19 it a distraction or is it helping us or
00:33:21 holding us back and I take full
00:33:24 ownership of this I've made bad
00:33:26 decisions and like we tried to keep the
00:33:28 license weird so it didn't grow too fast
00:33:30 and because if you grow too fast and you
00:33:32 get all these people and dependencies
00:33:33 and that's bad if you're changing it and
00:33:35 but we want to be open but super
00:33:38 confusing So we're fixing that and so
00:33:42 we're fixing it for a number of reasons
00:33:43 but the biggest reason is it's the right
00:33:45 time to do that and I'm happy i mean
00:33:48 obviously there's lots of I'm never
00:33:50 fully happy i think everything can
00:33:52 always be better but I'm I'm getting
00:33:54 happier with the uh we're really close
00:33:56 and so actually this is where I'm very
00:33:58 happy that we get to actually talk to
00:34:00 people and and do this and license and
00:34:02 availability
00:34:04 pieces also we've I've said this before
00:34:08 our plan is to open this stuff over
00:34:10 time so in about a week maybe two weeks
00:34:14 we're about to open about a quarter
00:34:16 million lines of Mojo
00:34:19 code which I think will be pretty
00:34:21 interesting and so this is all the all
00:34:25 the flash attentions and matrix
00:34:27 multiplications and all the high
00:34:28 performance kernels
00:34:30 for at least three
00:34:32 GPUs all open Apache license very
00:34:35 excited this will be I think a big
00:34:39 moment and I'm very very very
00:34:49 um this whole team doing this i'm so
00:34:49 proud of the team by the is like what
00:34:51 they're able to do is just ridiculous so
00:34:54 uh so this will be a big deal stay stay
00:34:56 tuned for this we're still going to open
00:34:58 source the Mojo compiler that's also
00:35:00 coming not quite there yet let's get
00:35:02 over this and see if it crushes the team
00:35:03 or not but uh but we're still on this on
00:35:07 track for this i think 2026 may be a
00:35:09 conservative but we'll see about that um
00:35:12 and we have a new license and so the the
00:35:15 license on Max has been super confusing
00:35:19 um and it's super confusing and let
00:35:22 before I tell you what we're doing I'll
00:35:24 tell you why it's super confusing early
00:35:27 when we first came out of stealth and we
00:35:29 were starting to talk about what we were
00:35:30 doing i this is me taking responsibility
00:35:33 i said is a technology we want to be
00:35:36 free and take over the world and people
00:35:38 to use it max is a commercial product
00:35:40 and like that's a different thing and
00:35:42 you know and we I I drew this line
00:35:45 between the two because that's what
00:35:47 we're thinking about it 18 months ago or
00:35:49 something like this but what we want is
00:35:51 we want everybody to use Mojo and Max
00:35:54 and so we can't do that if it has a
00:35:55 weird license so what we've done is
00:35:58 we've defined a new license which is way
00:36:01 better max community license or the
00:36:04 modular and so what it means is you can
00:36:08 go and use both Mojo and Max for
00:36:10 whatever you want for nonprouction
00:36:14 non-commercial use so if you're a
00:36:15 researcher all that stuff is super cool
00:36:18 oh by the way if you're production
00:36:20 commercial you can also use it for
00:36:22 anything you
00:36:23 want on x86 and Nvidia which is the only
00:36:27 hardware we support right now for other
00:36:29 things we'll figure it out we need to
00:36:30 actually do them first but we may relax
00:36:33 over time we're going to we're going to
00:36:34 be a little bit conservative that the
00:36:36 only requirement for commercial use is
00:36:38 please tell us and let us use your logo
00:36:41 it's like a small thing to ask scale it
00:36:44 on 10,000 Nvidia GPUs and do amazing
00:36:47 things that would be awesome just like
00:36:48 tell us so we know and so we can tell
00:36:50 our testers so that we bang for it and
00:36:52 do
00:36:54 stuff this is this is a big deal and so
00:36:58 what we're doing and just so you know is
00:37:00 we're trying to take away any of the
00:37:02 reason anybody would want to use
00:37:06 CUDA right so
00:37:08 CUDA proprietary closed closed source
00:37:12 kernels you cannot understand what's
00:37:14 happening if it breaks you get weird
00:37:16 stack
00:37:17 trace in two weeks uh the kernels will
00:37:20 be open source you can go look at them
00:37:22 you can change them you can enhance them
00:37:23 you can tell us that our engineers are
00:37:24 not as smart as your engineers or
00:37:26 whatever let's work together to fix this
00:37:28 and let's make this thing better if you
00:37:30 want to build a scalable LLM service and
00:37:33 compete like fine that you could do that
00:37:37 that would be annoying but this is the
00:37:38 way the world works but we want to see
00:37:40 the tech go far and wide and we want to
00:37:42 see what you can build with it and so
00:37:43 this I think is a really big moment for
00:37:46 us and to this has always been part of
00:37:49 the plan i don't think we've
00:37:50 communicated this well but this has
00:37:51 always been part of the plan but I'm
00:37:53 really really really excited we're we're
00:37:54 here and so this is a very special
00:37:56 moment for
00:37:57 me um if you're interested in using it
00:38:01 commercially and you want to scale we
00:38:03 have a very fancy enterprise edition and
00:38:05 so please let us know if you do have
00:38:07 hundreds or thousands of GPUs if you
00:38:10 want commercial support yeah you can pay
00:38:11 us for commercial support that's fine uh
00:38:13 we have other stuff that kind of goes in
00:38:15 this including the cluster management
00:38:17 other products like that but we want
00:38:19 this you can call it like the VLM and
00:38:22 down technology to be free for people to
00:38:25 be able to go use it and go do really
00:38:27 cool stuff and my my core hope my core
00:38:30 belief is that as we unlock this
00:38:32 industry as we break down these barriers
00:38:35 like new research will happen and I'm
00:38:37 really really really excited about
00:38:39 that okay so what does this mean so
00:38:42 there's lots of things another thing
00:38:43 that's about to drop is pip support this
00:38:46 is
00:38:47 another ongoing quest in terms of
00:38:49 figuring out packaging how we distribute
00:38:51 our stuff uh pip support i think this
00:38:54 command technically works if you know
00:38:56 the right URL you can bug other people
00:38:57 this is I don't actually understand how
00:38:59 pip works um uh this this is really
00:39:02 because now it integrates with all your
00:39:04 normal developer flows and all this kind
00:39:05 of stuff and so this is also another big
00:39:07 deal if you're interested in modu mo
00:39:09 models um we have this thing called
00:39:11 builds.mmodular.com this is where you
00:39:13 can find you know hundreds of models and
00:39:15 variants and things like this the cool
00:39:17 thing about this is you can click on
00:39:18 each of these things and then there's
00:39:20 like four four
00:39:22 commands run install this stuff and get
00:39:24 going this is the benefit of building a
00:39:26 vertical stack by the way again the my
00:39:29 enemy my number one arian nemesis is
00:39:32 complexity and so by getting right by
00:39:34 building this thing the right way we can
00:39:36 delete a lot of that complexity and make
00:39:38 stuff that actually just works and so
00:39:40 this is a lot of the value of what we're
00:39:41 doing here um there's also other things
00:39:44 recipes and other other examples can
00:39:46 follow the recipes are cool because you
00:39:48 can say "Hey I want to build an like
00:39:50 show me an example of a rag solution or
00:39:52 show me how to build an agent using this
00:39:55 stuff and we make it super easy." And
00:39:57 the cool thing about this is the stuff
00:39:59 plugs together really nicely and it
00:40:00 builds on standards like AI endpoint
00:40:03 standard um and you can get going really
00:40:05 quickly which
00:40:07 is so that is all I wanted to ramble
00:40:10 about i hope that's interesting you
00:40:12 teach a little bit about things that are
00:40:13 coming soon um we have obviously way way
00:40:15 way more stuff coming that'll come over
00:40:17 the next month but I'd love for Jack to
00:40:19 share yeah thank you so much Chris
00:40:31 uh before we let Chris go entirely uh
00:40:31 not getting away yet do I get Diet Coke
00:40:33 you do get a Diet Coke but you also get
00:40:35 some questions if there are any
00:40:37 questions in the audience yeah we'll
00:40:38 start over here
00:40:45 so you mentioned Triton is like
00:40:45 overoptimized for OpenAI's needs um do
00:40:49 you feel like you've made any
00:40:51 assumptions in the development of Mojo
00:40:53 that make it overoptimized for I mean
00:40:56 maybe it's overoptimized for AI and you
00:40:58 know I can't run molecular dynamics
00:41:01 simulations anymore um Mojo right now is
00:41:04 overoptimized
00:41:07 for let me be very honest with you sugar
00:41:09 coat it this is the problem with
00:41:11 building a language or something as
00:41:12 horizontal as Mojo is that um and again
00:41:16 I know this annoys people but um case
00:41:19 has been to build AI stuff it's really
00:41:23 hard and so what is constantly happened
00:41:25 is um there's several very smart mojo
00:41:28 engineers in the room here um uh you
00:41:32 know they're working on like okay I want
00:41:33 to
00:41:34 make lists work amazingly awesome and
00:41:37 fancy like Python and then they get
00:41:38 really pulled into how to split
00:41:40 compilation work again how do I make
00:41:42 compile time go
00:41:43 faster very fancy meta stuff for
00:41:46 tilebased layout okay we need to make
00:41:48 the compiler 10x faster right and so um
00:41:51 as far as I know there is nothing in the
00:41:53 software stack that is AI specific and
00:41:57 so if you want to do biochemistry or oil
00:41:58 and gas or something like this or game
00:42:00 of life like awesome go nuts you can
00:42:02 totally do that but the consequence of
00:42:05 our approach which by the way I think is
00:42:07 the right approach for building a
00:42:08 technology always dog food and build
00:42:10 something yourself is also why I wanted
00:42:11 in research mode so we could iterate
00:42:14 rapidly and be very focused um but the
00:42:16 consequence of that is that we haven't
00:42:18 built out all all of the features that
00:42:20 we want Mojo to have and so what you'll
00:42:22 see across even this year um allegedly
00:42:25 the Mojo team is publishing a road very
00:42:26 soon uh and what you'll see they're now
00:42:29 finally getting time to invest in
00:42:31 broader ecosystem enablement features
00:42:33 for example Mojo Python interrupting
00:42:34 things like this
00:42:42 hi uh thanks for Mojo it's really
00:42:42 awesome i love it so far um
00:42:45 uh when I run it on my Mac obviously it
00:42:48 doesn't have GPU support yet right so I
00:42:52 was trying to dig into how I could
00:42:54 possibly implement that myself i don't I
00:42:56 don't think those tools are available
00:42:58 yet is is that right that's correct so I
00:43:01 can't commit to anything but our hope is
00:43:03 that we'll enable that
00:43:05 summer so and then can help
00:43:14 hi this is Mahi uh we use Mojo because
00:43:14 primarily for the language I mean we
00:43:16 love it um it gives great productivity
00:43:20 uh we are an enduser app we run on iOS
00:43:22 and Android any future plans for edge
00:43:26 computing or iOS or Android um this is
00:43:30 outside my well so I mean I have some
00:43:32 experience with iOS but the um
00:43:36 uh I I I haven't spent a lot of time on
00:43:39 this the last few years um my
00:43:41 understanding is it runs fine on iOS and
00:43:43 Macs and people put on Raspberry Pies
00:43:45 and stuff like this but the best place
00:43:47 to ask is on this the discourse forum
00:43:50 forum the forum yeah forum that would be
00:43:52 the best place to ask
00:43:55 and there may be some weird API thing or
00:43:57 something that I don't know
00:44:06 hey Sean here uh I've got a question
00:44:06 about uh interop with native code beyond
00:44:08 CIS FFI uh in particular if you want to
00:44:12 reach into you know Rust ecosystem stuff
00:44:14 for like Apache Arrow or a bunch of the
00:44:16 great work that's been done there and
00:44:18 you want to like do a lot of data
00:44:19 processing and pull that in i'm curious
00:44:21 like where some of that stuff is going
00:44:23 uh so I I don't know of any work
00:44:25 specifically around Mojo Rust interop
00:44:28 that's super cool i'd love to to explore
00:44:30 that um Mojo does have good C interrupt
00:44:32 like you talked about the FFI module and
00:44:34 so I assume that Rust talks to C and has
00:44:38 this C decal type thing or something and
00:44:40 if that's the case mojo can talk to it
00:44:43 and like we can meet in the middle but I
00:44:45 don't I I don't know specifically how
00:44:46 that works um uh I also don't know how
00:44:49 the ownership systems getting them to
00:44:51 line up optimally would work but I would
00:44:53 suggest starting with like a uh like a a
00:44:57 glue generator or something that would
00:44:58 be an interesting way to just like
00:44:59 synthesize some bindings
00:45:11 uh Jeremy here i was wondering I mean
00:45:11 you've you mentioned a lot about GPUs
00:45:13 and things what about nonGPU
00:45:14 accelerators you know exotic data flow
00:45:17 architectures these sorts of things how
00:45:18 is that going to play into the Mojo
00:45:20 modular ecosystem um so uh I care I love
00:45:24 all the
00:45:25 chips and that includes things that are
00:45:29 way over my planning horizon like
00:45:30 quantum and analog and like I'm just
00:45:32 such a nerd right um
00:45:34 uh FPGAs like there's so many things out
00:45:36 there um the way to think about Mojo is
00:45:39 it's useful for anything that has a
00:45:40 program counter and so it's not going to
00:45:42 help you with an FPGA
00:45:44 could I mean you could do uh high level
00:45:47 synthesis type stuff theoretically I'm
00:45:49 not a fan of that and if you want I can
00:45:51 talk about it over beer um but uh so you
00:45:53 could theoretically do that but it's
00:45:54 really good for something with the
00:45:56 program counter and so if you have a
00:45:58 weird ASIC you have something that has
00:46:00 like a gigantic systolic array or you
00:46:02 have a a risk 5 core that's controlling
00:46:04 a video encoder like it's very useful
00:46:07 for that kind of stuff um we haven't
00:46:09 opened up the ability to add new
00:46:10 backends yet that's something we're
00:46:12 interested in doing but it's not like in
00:46:13 the next three months time horizon so
00:46:25 um you mentioned DeepSeek um I I've only
00:46:25 found one article that basically sort of
00:46:27 said they decoded the binaries and found
00:46:30 out you know there's a bunch of special
00:46:31 op codes that Nvidia sort of quasi
00:46:34 documents in the documentation so you
00:46:36 have to sort of give the the question is
00:46:38 that the Chinese programmers obviously
00:46:39 had some serious brains to take PDX and
00:46:41 say this stuff is crap we're going to
00:46:43 generate the real lower level machine
00:46:45 code so my question is anybody decode
00:46:47 all of the kernel binaries to find out
00:46:49 what what the translation that Nvidia
00:46:51 did that was sort of less than less than
00:46:53 optimal because effectively what you're
00:46:55 doing is you're saying these guys are
00:46:56 smarter than we were and they've sort of
00:46:58 done a better transformation with the
00:47:00 PDX into the raw hardware so we ought to
00:47:02 be able to I mean Nvidia ought to be
00:47:04 able to figure that out themselves and
00:47:05 say "Hey we they set the bar that we're
00:47:08 we're missing you know." Yeah so So the
00:47:10 lesson I take from Deepseek is slightly
00:47:12 different than what you're saying i
00:47:14 think what I what I hear you say is that
00:47:15 you're saying uh that the Deepseek
00:47:19 programmers figured out how to use
00:47:20 Nvidia's hardware better than Nvidia did
00:47:23 right but that's I don't think that's
00:47:24 actually what happened what actually
00:47:26 happened is they invented new algorithms
00:47:29 that Nvidia hadn't hardcoded into CUDA
00:47:31 yet right and so because they invented
00:47:33 new algorithms they had to go to the
00:47:34 same primitives that Nvidia and many
00:47:36 other Cutless programmers and other
00:47:38 things like this had to use and so the
00:47:40 problem with the the CUDA thing is that
00:47:43 again the Nvidia approach is saying like
00:47:45 find the important use case and then
00:47:46 hardcode it into the libraries and so
00:47:48 that only works if you're chasing
00:47:50 research that's not helping if you're
00:47:52 doing research and so this is where if
00:47:54 you go again just a week or so you can
00:47:56 go pour over more mojo code than you
00:47:59 ever wanted to know by the way please
00:48:00 train your LLMs on it um the uh you can
00:48:04 go look and we go directly PTX also
00:48:06 because you have to to get the highest
00:48:07 performance and so it's not I don't
00:48:09 think that that was a novel thing it was
00:48:10 more about
00:48:22 did say oh there's these special op
00:48:22 codes that won't
00:48:25 slow somebody said the paper also did
00:48:27 combination algorithm but
00:48:41 also you're beyond my knowledge uh so I
00:48:41 I'm I'm going to earn many things i
00:48:43 don't know the full details of what the
00:48:44 DeepSeek team did um but again there
00:48:47 there's no magic my my my fundamental
00:48:49 philosophy is there's no magic right and
00:48:51 so there is an optimal set of
00:48:53 instructions that will make any
00:48:54 individual chip go fast and so you know
00:48:57 you can write theoretically everything
00:48:59 in assembly and if you care about
00:49:00 exactly one point solution you can do
00:49:03 that but that's not what AI is what AI
00:49:06 is is an ever evolving set of use cases
00:49:08 there's an evolving set of algorithms
00:49:10 there's like research innovations
00:49:12 happening like every day there's a new
00:49:14 paper and so I think the the challenge
00:49:16 to me the way I define success is making
00:49:18 it so you can get the full power of what
00:49:20 for example a deepseek engineer did but
00:49:23 that you can then get the software
00:49:25 engineering benefit and the scalability
00:49:26 and the leverage of compilers and of
00:49:29 abstraction and of software engineering
00:49:32 so that you're not having to literally
00:49:34 write everything in assembly language um
00:49:36 if you go back to me making fun of
00:49:38 compiler engineers for making fun of
00:49:40 kernel engineers like my whole
00:49:43 philosophy and the philosophy with Mojo
00:49:44 is to say look kernel engineers are
00:49:47 amazing they should be empowered with
00:49:50 compiler algorithms and so what Mojo
00:49:52 does is says let's take much of the
00:49:54 algorithmic smarts and put it back in
00:49:56 the kernels and then allow the kernel
00:49:59 engineers to have superpowers so they
00:50:00 get the power of generalization they get
00:50:02 power of meta programming they get the
00:50:03 power of what compilers will get at and
00:50:06 it's in air quote user space it's in the
00:50:07 Mojo source code instead of being hacked
00:50:10 and hardcoded into the compiler and so I
00:50:12 love compilers i love compiler engineers
00:50:14 obviously right but the the the way to
00:50:16 factor this world is to make it so that
00:50:18 you have more people that can
00:50:19 participate in the space and make it so
00:50:21 that their work can scale i think that's
00:50:23 fundamentally the contribution of what
00:50:25 we're building
00:50:31 did you
00:50:31 ever uh can you elaborate on the
00:50:34 self-hosted K8s in your commercial
00:50:38 license self-hosted which uh you had a
00:50:41 clause about self-hosted uh K8s
00:50:45 I'm assuming Kubernetes uh yeah so I
00:50:47 mean our general approach is that we
00:50:49 like you can use for free the kind of
00:50:51 VLM or TRTLM subset of the stack and so
00:50:54 you can deploy it yourself on your own
00:50:56 Kubernetes thing and scale and do do
00:50:57 whatever we can make that much easier
00:50:59 for you if you want to use our
00:51:01 management layer and our cluster
00:51:02 solution
00:51:04 y um I have a question about the
00:51:07 abstraction levels So in your slides you
00:51:10 mentioned um OpenAI Triton library um in
00:51:14 that case you were saying it's not as
00:51:16 fast as CUDA but um Triton is actually
00:51:19 I'm sure you know maybe better than me
00:51:21 but um sort of at least the Triton I
00:51:24 wrote is quite low level much more much
00:51:26 more lowle um it's actually more low
00:51:28 level than CUDA in a way and um first of
00:51:31 all I was surprised there's a gap uh so
00:51:33 this is something I need to learn more
00:51:35 but um second um u and excuse me if you
00:51:39 explain that but sure do you think
00:51:41 um module is higher level abstraction
00:51:44 level or lower than um an open eye
00:51:48 triton and if it's higher how could it
00:51:51 be faster great question so this and
00:51:54 this this is this is the secret okay so
00:51:58 so I'll try to explain this in a
00:51:59 slightly different way yeah I will write
00:52:01 more blog posts time permitting but uh I
00:52:05 did not I mean it's turning to an epic
00:52:06 book at this point but the uh um so the
00:52:10 the problem with Triton if I the problem
00:52:12 with the Triton approach because it's
00:52:14 it's not just Triton there's many of
00:52:15 these systems and there's many DSLs
00:52:18 there's like tons of them but the
00:52:20 problem is they're saying let me give
00:52:22 you a programming model so the tabbased
00:52:24 programming model that Triton has let me
00:52:27 provide a very fancy compiler that does
00:52:29 loop pipelining or whatever set of
00:52:31 transformations that it does and then
00:52:33 let me expose that to you as a
00:52:35 programmer to make a common case simpler
00:52:38 and so Triton's really nice if you're
00:52:39 writing attention blocks like the vast
00:52:42 majority of what Triton gets used for is
00:52:43 writing attention blocks um but there's
00:52:46 a problem because the compiler goes and
00:52:48 does stuff and sometimes does the right
00:52:50 stuff sometimes it doesn't sometimes
00:52:52 performance is good sometimes it's not
00:52:53 maybe you're an expert i don't know the
00:52:55 20% number came from Phil Tole who's the
00:52:57 author of Triton and so I was not trying
00:52:59 to make an innovative claim I was just
00:53:02 trying to repeat what he has said
00:53:04 publicly um but Mojo has a fundamentally
00:53:07 different approach and so Mojo the
00:53:10 language is lower level and so you can
00:53:13 write thread index.x X you can write all
00:53:15 the way down to if you're building an
00:53:17 ASIC you can write assembly go into the
00:53:19 whatever your tensor core is or like you
00:53:21 get full power of the hardware so it's a
00:53:24 low-level
00:53:25 language but then it has a very powerful
00:53:27 metaroming system and so the
00:53:29 metarogramming system allows you to
00:53:31 build for example tile-based algorithms
00:53:35 in Mojo code and so it's not hardcoded
00:53:38 into the compiler and so the thing that
00:53:40 we open source not only does it include
00:53:42 all the kernels but it has all of our
00:53:44 abstractions for building kernels and so
00:53:46 we have a thing called layout tensor
00:53:47 layout tensor is roughly the API used to
00:53:49 talk to tensor cores and it talks to
00:53:51 multiple tensor cores that have
00:53:52 different layouts and it has an index
00:53:53 algebra and it has a whole very fancy
00:53:56 set of abstractions they're all built in
00:53:59 Mojo so they're libraries which means
00:54:02 that if you want to you can totally use
00:54:04 those abstractions they're very nice i
00:54:06 think they should be better but you know
00:54:08 we'd love help uh but the uh but they're
00:54:10 getting there they're they're they're
00:54:12 not done they're not perfect they're but
00:54:14 they're they're getting close enough for
00:54:15 us to publish um but if you don't like
00:54:17 them ignore them throw them away it's a
00:54:20 library and so this means that you can
00:54:22 write you know array tracer you could
00:54:24 write bioinformatics you can write
00:54:26 whatever not just transformer blocks you
00:54:28 can write anything you want and you have
00:54:29 the full power of a GPU but if you like
00:54:32 the abstractions for tilebased
00:54:33 programming you can totally use them you
00:54:35 get high expressivity and a lot of power
00:54:37 and portability coarser grain and things
00:54:40 like this and that that's the secret
00:54:42 right is is about taking it out of the
00:54:44 compiler tiles are not in our compiler
00:54:46 at all putting it in the library
00:54:55 um you can cross compile yes the the
00:54:55 again it's not obvious usually you need
00:54:57 to like for survey you need to actually
00:55:00 get
00:55:06 p and compile them so it's actually kind
00:55:06 of cool just the only thing you have you
00:55:09 can compile say on a normal non GPU that
00:55:12 run this slow well seriously like have
00:55:16 you ever heard of have you ever heard of
00:55:17 one binary that runs on both an H100 and
00:55:20 A100 and an MI300
00:55:30 what what what what
00:55:30 what I what I what I love right now is
00:55:32 that I see virtual brains splatter
00:55:34 against the wall because your head just
00:55:36 exploded so but but again this is and by
00:55:39 the way
00:55:40 all all you try it yourself so this is
00:55:45 like great claims can be justified with
00:55:47 actual proof but um uh but for example
00:55:51 all of our kernels are jitted because
00:55:54 they're all jitted this means that yes
00:55:56 you get cross compilation and the way
00:55:58 mojo works was designed again this is
00:55:59 the mad science that it took to build
00:56:01 this stuff what's
00:56:04 that question no warm up is fast i think
00:56:07 again it depends on the model but if you
00:56:09 build like a llama 8B model which is I
00:56:12 don't know a thousand plus ops in the
00:56:15 graph something like this and you're
00:56:16 jitting it it jits and fuses down to 80
00:56:19 odd CUDA launches or kernel launches
00:56:22 something like this the whole thing end
00:56:24 to end jitting takes about a minute
00:56:27 decodegen makes hundreds of thousands of
00:56:29 PTX completely novel kernels
00:56:33 like seriously built entirely new
00:56:36 language the whole thing is paralyzed
00:56:38 like work around all the problems with
00:56:40 LVM this is not easy took a lot of work
00:56:42 from a lot of very smart people so but I
00:56:44 love the brains the brains splattered is
00:56:47 that's what we're going for so
00:56:50 take uh two more questions and then
00:56:51 we're gonna let Chris enjoy the rest of
00:56:53 his Diet Coke um All right all right I'm
00:56:56 going to try to pass this back here
00:57:00 you mentioned dependent types uh did
00:57:02 that grow out of something specific is
00:57:04 that just helping to keep the meta
00:57:05 programming sort of structured somehow
00:57:07 what what's going on there yeah so
00:57:09 dependent types for those that don't
00:57:11 know is that it allows you to build uh
00:57:14 type computation computation in the type
00:57:17 domain basically um so Mojo has a very
00:57:21 powerful metaroming system it's not
00:57:23 completely novel it's directly inspired
00:57:26 by Zigg and so Zigg has they call it
00:57:29 comp time and so it allows you to use
00:57:31 arbitrary runtime code or nearly
00:57:33 arbitrary runtime code at compile time
00:57:35 and it unifies the language in the meta
00:57:37 language and so Mojo does literally that
00:57:39 unifies the language of the meta
00:57:40 language making the whole thing simpler
00:57:42 make it way faster etc etc etc the
00:57:45 consequence is now you can use arbitrary
00:57:47 uh what we call parameters in type type
00:57:49 domain and so um it may blow your mind
00:57:52 but go look at the nightlys um integer
00:57:56 literals for example do like all of
00:58:00 their work in type algebra and so they
00:58:03 can be infinite precision those infinite
00:58:06 precision literals that even for
00:58:08 floating point which is really cool uh
00:58:10 again very mad science stuff that most
00:58:12 people don't know anything about which
00:58:14 is fine but um but that then gets
00:58:16 materialized into different integer
00:58:18 widths and SIMD types and stuff like
00:58:20 this and it's all made possible by by
00:58:22 this kind of stuff and so again like
00:58:24 this is stuff that uh innovation in PL
00:58:27 is programming languages is not
00:58:28 something that lots of people talk about
00:58:30 but it's actually um you know it's not
00:58:33 about syntax it's about being able to
00:58:34 express powerful libraries and this this
00:58:37 to me is the the key
00:58:39 So and not having to wait for C++
00:58:41 templates to compile
00:58:50 both it takes an hour to compile just
00:58:50 the flash attention
00:58:52 repository it's Hey Chris uh thanks for
00:58:55 the talk and answering all our questions
00:58:57 um so I work at a hardware vendor and
00:58:59 you know we're 5 CPU so we're not ARM or
00:59:01 Intel uh and then you know we have our
00:59:03 own accelerator so we're not AMD or
00:59:04 Nvidia y so when is like a good time for
00:59:06 us to meet with you know you guys to
00:59:08 build our own back end uh you know for
00:59:11 Mojo because you know I was at the talk
00:59:13 I think a year ago now in San Francisco
00:59:15 and you know obviously that was way too
00:59:16 early you know GPU was so early then uh
00:59:19 but you know I'd love to get this in our
00:59:20 hands internally because I feel like it
00:59:22 would accelerate a lot of our kernel
00:59:23 engineers um and a lot of the work we do
00:59:26 yeah amazing uh so the answer is
00:59:28 probably this fall is my best guess so
00:59:32 um I I'll share my problem with you
00:59:35 which is we really want to get this it's
00:59:38 like I was talking about earlier we
00:59:39 really want to get this in everybody's
00:59:40 hands but we also want to do things in
00:59:41 the right steps and so I'm really
00:59:44 worried about open sourcing kernels by
00:59:46 the way i'll share my anxiety uh we have
00:59:48 a small team i think that the stuff
00:59:50 we're doing is really interesting i
00:59:51 don't want them to get completely
00:59:53 annihilated
00:59:55 what we're doing is we're putting
00:59:58 the um I
01:00:01 think can't guarantee that we'll have
01:00:04 the right answer there but it
01:00:05 feels ballpark to where we could do some
01:00:08 interesting things together potentially
01:00:10 so thank you so much how about this
01:00:13 definitely not until fall so so maybe
01:00:16 fall but definitely not until then all
01:00:18 right let's give another round of
01:00:20 applause for Chris
01:00:28 so if you have any other burning
01:00:28 questions for Chris he will be around
01:00:29 during the networking portion of
01:00:31 tonight's event or you can always feel
01:00:33 free to drop your questions in our
01:00:35 community forum at
01:00:37 forum.mmodular.com the team is
01:00:39 constantly monitoring chris himself
01:00:41 responds to a lot of the stuff there so
01:00:43 definitely a great place to share your
01:00:44 questions uh up next we have Jack
01:00:47 Clayton Mojo standard library engineer
01:00:49 who is going to do a live demo for us of
01:00:51 GPU programming with
01:01:03 Mojo testing all right cool um so yeah
01:01:03 we've gone over time a little bit so I'm
01:01:05 going to rush through it a little can I
01:01:07 can I just get a round of hands um who
01:01:09 has
01:01:11 done how many people have done GPU
01:01:13 programming with CUDA like written a
01:01:15 CUDA kernel
01:01:16 before okay sweet and has anyone written
01:01:19 Mojo
01:01:21 here cool all right so I'll just give
01:01:25 brief give a brief explanation of GPU
01:01:29 programming as I go but this is this is
01:01:31 all Mojo code so it's just a mandler
01:01:34 kernel you can see there's some
01:01:34 parameters up the top here um so alias
01:01:37 means it's a
01:01:39 parameter uh yeah
01:01:41 sure how's
01:01:49 that um yeah so the this device context
01:01:49 this is getting a device context for the
01:01:51 GPU so I'm on an Nvidia machine at the
01:01:53 moment you can see when I do this I got
01:01:56 a uh A100 that I'm running on here um
01:01:59 and then this device buffer it's
01:02:00 creating it's in queuing creating a
01:02:02 device buffer um using the size of this
01:02:04 layout so you can see as Chris was
01:02:06 talking about before we have this
01:02:08 parameter system so um it dynamically uh
01:02:11 sorry like at compile time it's actually
01:02:13 getting these figures so you can see
01:02:14 that the mount brought grid size is 25
01:02:16 by 60 um so it's it's creating a buffer
01:02:20 of that size and then wrapping it in a
01:02:21 layout tensor um the layout tensor is a
01:02:23 really powerful abstraction uh based on
01:02:26 the cute library which Nvidia has so it
01:02:28 allows you to do a lot of powerful
01:02:29 things um and then this uh is in queuing
01:02:32 the function mandle brought to run so if
01:02:35 you look down here this is a mandelro
01:02:36 kernel so this is like what you would do
01:02:38 if you were programming a CUDA kernel um
01:02:41 I won't go over like how how mandelro
01:02:43 works but basically you can see this is
01:02:45 like a getting the thread index um so
01:02:48 it's getting the index on the y index
01:02:49 and the x index um and then it's doing
01:02:51 the mandelro uh uh algorithm and just
01:02:55 putting it back into the tensor um and
01:02:57 then at the end it just draws the
01:02:58 moundro so if I run this
01:03:15 Uh you can see the mount bro come back
01:03:15 so uh yeah that's running on GPU um and
01:03:20 then something really cool that you can
01:03:21 do you can actually see the PTX that's
01:03:24 being generated so if I go in here and
01:03:26 dump the uh assembly
01:03:34 And this is running on a remote instance
01:03:34 with a with an Nvidia
01:03:41 GPU that dumps the assembly here so if I
01:03:41 open it
01:03:42 up uh you can see what the PTX looks
01:03:45 like so you can see the actual
01:03:46 instructions that it's generating um and
01:03:48 it's because it's just a mandelro kernel
01:03:50 it's like it's quite simple um so yeah
01:03:53 this is running directly from Mojo so
01:03:54 you can create like a binary and just
01:03:55 run things eagerly but then we can also
01:03:57 do things with Python so if you want to
01:03:59 create uh custom ops that you can run
01:04:02 with the max inference engine uh then
01:04:05 you can create your own custom ops so an
01:04:08 example is this uh grayscale uh I'll
01:04:10 bring this
01:04:17 up so you can see this is the Mojo
01:04:17 grayscale
01:04:23 uh where it's doing the same thing where
01:04:23 it's in queuing the the function to run
01:04:25 so it's incuing the GPU kernel to run um
01:04:27 the block dims is setting out by 16 grid
01:04:30 there and then the grid dims is
01:04:33 uh using the ceiling to create like a
01:04:36 grid across the entire dimension of the
01:04:38 image um so what we're going to be doing
01:04:40 here we got this image of two dogs um so
01:04:44 that's been loaded in by uh by IMRI and
01:04:48 that's just a numpy tensor um and then
01:04:51 we're defining the tensor shape so we
01:04:52 have a color tensor and a gray tensor uh
01:04:55 the input is the color tensor um which
01:04:57 is the image this image here of the two
01:04:59 dogs and then the ops we have a
01:05:01 grayscale a brightness and a blur um so
01:05:04 these are just wrapper functions to make
01:05:06 building the graph a bit simpler um so
01:05:08 the data goes to the GPU it sits on the
01:05:10 GPU runs through one op at a time and
01:05:12 then it gets copied back to the CPU and
01:05:14 written to the device um and you can see
01:05:17 that code down here and it'll write out
01:05:18 to uh that one there
01:05:21 so if we go into that folder um and then
01:05:24 magic run image pipeline so magic is the
01:05:26 CLI tool that allows you to use Mojo and
01:05:28 get all the access to GPU programming um
01:05:31 from Python as well
01:05:50 um just on the first run it's just
01:05:50 compiling the the kernels so the three
01:05:53 different uh kernels for the custom ops
01:05:56 and then we can bring up the image so we
01:05:59 got dogs
01:06:01 out and you can see that's just
01:06:04 uh it's just blurred them turn them into
01:06:07 grayscale and brightened up the image a
01:06:08 bit um so you could like you want to
01:06:10 inject this into a into an AI pipeline
01:06:12 where lots of people will eagerly
01:06:20 um you can actually put this into the
01:06:20 pipeline so that you know you get a lot
01:06:22 of better performance across different
01:06:24 batch sizes and things like that um and
01:06:27 I'll just quickly show you through the
01:06:28 the kernels how they work
01:06:31 uh so bring this
01:06:44 yeah the grayscale one here so you can
01:06:44 see that it's just looping like it's got
01:06:48 Um and it's just getting
01:07:17 what's that sorry oh the comma oh yeah i
01:07:17 deleted it thank
01:07:23 you uh yeah so that that takes an input
01:07:23 image with color and then outputs a
01:07:25 grayscale image um and then the next two
01:07:27 kernels so this brightness one is using
01:07:29 like a sort of higher level abstraction
01:07:31 using this for each um so for each runs
01:07:34 across its CPU and GPU so uh like this
01:07:37 this one up the top here is just running
01:07:38 on GPU using Q function but the the CPU
01:07:42 version can run on CPU or GPU um so I
01:07:45 put a challenge in here if anyone like
01:07:46 wants to go into the repo um I'll show a
01:07:49 link at the end if you can convert this
01:07:51 into using a for each loop so it runs on
01:07:53 CPU and GPU you get some special Mojo
01:07:55 swag which we'll we'll send out to
01:07:57 you and then the blur kernel down the
01:08:00 bottom here so this is like a little bit
01:08:01 more complicated you can't really use a
01:08:03 4 each for this um because it's taking
01:08:05 the eight surrounding pixels and then
01:08:06 doing a doing a getting the average of
01:08:08 them so it can blur across the entire
01:08:10 image um but yeah this is just an
01:08:12 example of a slightly more complicated
01:08:14 kernel um and like Chris said like we'll
01:08:16 be open sourcing all the all the very
01:08:18 complicated kernels um soon so you can
01:08:20 see like how to do like you know super
01:08:22 lowle performance type things um and
01:08:25 there is an example here of uh of top
01:08:28 kum and this is using like a low-level
01:08:30 operation using uh warps so shuffling
01:08:33 down sharing data between threads in on
01:08:35 a GPU within the same warp um so for any
01:08:38 uh CUDA um engineers you'll you'll be
01:08:41 familiar with that and uh yeah Mojo's
01:08:43 fully capable of doing all the low-level
01:08:45 um things that you expect um but the the
01:08:48 very special thing about Mojo is that um
01:08:50 this hasn't been like announced publicly
01:08:52 yet but all of this that I've shown you
01:08:55 actually works on AMD GPUs as well so
01:08:57 this is an AMD instance here um and it
01:09:00 does the same same thing so I can run
01:09:04 the Mandelro
01:09:13 Um yeah and you see it running the metal
01:09:13 brought there and then you can actually
01:09:14 see the the PTX as well uh not the PTX
01:09:17 sorry but the the
01:09:20 assembly um so yeah you can see the
01:09:22 machine instructions for the AMD side uh
01:09:25 so you can get a comparison about like
01:09:26 you know what what the difference is
01:09:27 between Nvidia and AMD um and yeah it's
01:09:31 been quite amazing really because uh
01:09:32 like low-level stuff like warp shuffles
01:09:35 um I didn't expect it to work but when I
01:09:36 just tried to run it on AMD DG GPUs it
01:09:39 just just worked out of the box um and
01:09:41 same with all that image pipeline stuff
01:09:43 just worked um after the first
01:09:45 try so if you're interested in doing
01:09:47 this kind of stuff um I have these three
01:09:49 links here so I'll zoom in on that um
01:09:52 you have this GPU basics guide which is
01:09:54 just like introducing GPU programming uh
01:09:57 it gives you like a kind of rundown of
01:09:59 what GPU programming is um but it's
01:10:01 still in the early stages there's only
01:10:02 chapter one there so far uh I'll just
01:10:05 show you it and if you any problems we
01:10:08 have this um forum thread so if you have
01:10:11 any problems with the with the tutorial
01:10:12 you just post your questions or feedback
01:10:15 there that would be great and this is
01:10:18 the repo with the eager GPU functions
01:10:21 that you can just run from Mojo um so
01:10:23 yeah you can make contributions there
01:10:27 and this custom ops one um so tomorrow
01:10:30 the image pipeline will be there with
01:10:31 the two challenges if you can get
01:10:33 everything running on CPU as well as GPU
01:10:35 uh you get some special Mojo swag um and
01:10:38 that image pipeline will be there
01:10:44 tomorrow um so that's essentially it uh
01:10:44 we we have lots of good stuff coming out
01:10:46 like we realize how teach the world how
01:10:48 to program GPUs with Mojo um so there's
01:10:51 lots of stuff coming down um things
01:10:54 similar to like you know uh uh GPU
01:10:56 puzzles and extending the manual and
01:10:59 releasing all the open source co code so
01:11:01 that everyone can get up to speed uh
01:11:02 with programming GPUs with
01:11:05 Mojo and that's it is any questions
01:11:28 Oh thank you Jack um so I'm Todd
01:11:28 um we mentioned Nvidia and AMD today and
01:11:35 there was kind of a side mention of
01:11:37 Apple but I have an Apple NPU in this
01:11:42 and so have you had any experience
01:11:47 we we haven't started work on on Apple
01:11:49 Metal yet uh but Chris was saying like
01:11:52 towards the end of the year in the
01:11:53 summer um that we'll be opening it up so
01:11:56 people can start working on that
01:11:57 themselves uh and then they'll be able
01:11:59 to contribute and get get things running
01:12:01 on Apple Metal just like it runs on AMD
01:12:03 and Nvidia so yeah that'll be coming at
01:12:06 a later date
01:12:09 thank you any other questions for Jack
01:12:13 what was the AMD model or the CPU sorry
01:12:16 GPU oh yeah MI3 MI3 30 300 300X yeah so
01:12:21 I got it here rocking
01:12:25 SMI uh it doesn't show the model number
01:12:27 here um but yeah it's an
01:12:30 MI300X no worries yeah I keep these red
01:12:33 bars and green bars so that I know what
01:12:35 instance I'm on uh otherwise I get
01:12:36 confused
01:12:38 um
01:12:46 uh at the moment no collab is something
01:12:46 that people are looking at but um so
01:12:55 yeah you need access to to GPUs at the
01:12:56 moment yeah but we we want to fix that
01:12:57 um so people are looking at Google
01:12:59 collab integration
01:13:02 or something similar yeah so quick
01:13:04 question when you showed the pipeline it
01:13:05 reminded me of two things one was a
01:13:07 Gstreamer pipeline kind of situation
01:13:10 where you build like end to end and
01:13:11 Nvidia does support that thing um and
01:13:14 the other was basically a graphics
01:13:15 pipeline right so do you think it's easy
01:13:19 enough with where it stands in the Mojo
01:13:21 GPU library you can do some basic
01:13:23 graphical stuff as well as something
01:13:25 like build an application for like maybe
01:13:27 video realtime video streaming have you
01:13:29 guys played around with that uh no like
01:13:32 so I haven't seen anyone play around
01:13:33 with uh video yet but um it's you know
01:13:36 definitely like all the tools are there
01:13:38 like you have the access to all the
01:13:39 low-level stuff you do um through CUDA
01:13:42 so it's just a matter of someone that's
01:13:44 like motivated and wants to get that
01:13:45 working they they could do that um so
01:13:47 hopefully as we start releasing more
01:13:49 train like learning materials people
01:13:51 will go out and build that kind of stuff
01:13:52 because you know we're really excited to
01:13:53 see
01:13:54 that any other questions for
01:14:02 Jack no all right let's give another
01:14:02 hand thank you thank you Jack
01:14:11 that was awesome
01:14:11 so before we kick off the networking
01:14:13 portion of the night I just want to give
01:14:15 a chance for anyone who's hiring in the
01:14:16 audience if you want a moment with the
01:14:18 mic to share what you're hiring for so
01:14:21 folks can find you uh when we kick off
01:14:24 the the mingling portion no one's hiring
01:14:28 we're hiring there are a few QR codes
01:14:31 scattered around here uh there are also
01:14:34 printouts of four different roles that
01:14:36 we're hiring for up at the front desk so
01:14:39 definitely check those out um and if you
01:14:41 had a good time with us tonight we also
01:14:44 have a an upcoming uh modular GPU kernel
01:14:47 hackathon at AGI House in Hillsboro so
01:14:51 you can scan this QR code right here to
01:14:55 attend uh you can
01:14:58 also you can also scan that QR code to
01:15:01 join our community forum drop any
01:15:04 questions for the team there that's the

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