In 1597, English philosopher Francis Bacon said 'knowledge is power'. Folding@home is proof that 'power (both electrical + computer) produces
knowledge'.
I suppose this is evermore true with the rise of Artificial Intelligence and LLM (large language models)
This Wikipedia article is more informative than the following personal effort.
Misfolded proteins have been implicated in numerous diseases. Folding@home
is biological research based upon the science of Molecular
Dynamics where molecular chemistry
and mathematics are combined in computer-based models to predict how protein molecules might fold (or misfold) in space over
time. This information is then used to guide scientific and medical research.
When I first heard about this, I recalled the science-fiction magnum opus by Isaac Asimov colloquially known as The Foundation Trilogy which introduced the fictional science of psychohistory (where statistics, history and sociology were combined in computer-based models) to guide
humanity's future, in order to minimize a potential dark age. How did Asimov
conceive of such a thing? (Answer: "Asimov is to sci-fi" as "Bach is to Baroque
classical music")
Years ago I became infected with an Asimov
inspired optimism about humanity's future and have since felt the need to promote Asimov's vision. While Folding@home
will not cure my "infection of optimism", I am convinced Dr.
Isaac Asimov (PhD in Biochemistry from Columbia in 1948, then was employed as a Professor of Biochemistry at the Boston University School of Medicine for 10-years until his publishing workload became too large) would
have been fascinated by something like this.
I was considering a financial charitable donation to Folding@home when it occurred to me that
my money would be better spent by making a knowledgeable charitable donation to all of humanity
by:
Increasing my Folding@home computations (which will advance medical discoveries to increase both the length and quality of
human life). I was already folding on a half-dozen computers so all I needed to do was purchase video graphics cards which
would increase my computational throughput by a thousand-fold (three orders of magnitude).
Convincing others (like you) to follow my example. My solitary folding efforts will have little
effect on humanity's future but together we can make a real difference.
Dr.
Asimov: I am dedicating this website to you and your work. You have greatly influenced my life.
Misfolded proteins have been associated with numerous diseases and age-related
illnesses. However, proteins are much larger and so much more complicated than smaller molecules that it is not possible to
begin a chemical experiment without first providing hints to researchers about where to look and what
to look for. Since the behavior of atoms-in-molecules (computational chemistry) as well as atoms-between-molecules (molecular dynamics) can be modeled, it makes more sense to begin with a computer analysis. Once that has
been completed, permitted configurations can then be passed on to experimental researchers.
Real-world observation
From a kitchen point of view, chicken eggs are a mix of water, fat (yolk), and protein (albumen). Cooking an egg causes the
semi-clear protein to unfold into long strings which now can intertwine into a tangled network which will stiffen then scatter
light (now appears white). No chemical change has occurred, but taste, volume and color have been altered.
Click here to read a short "protein article" by Isaac Asimov published in 1993
shortly after his death.
Using the most powerful single core processor (Pentium-4), simulating the folding possibilities of one large protein molecule for one millisecond of chemical time might require one million days (2737 years) of
computational time. However, if the problem is sliced up then assigned to 100,000 personal computers over the internet, the
computational time drops to ten days. Convincing friends, relatives, and employers to do the same could
reduce the computational time requirement to one day or less.
chemical
time
in
nature
required simulation time
one
computer
100,000
computers
1 million
computers
1 Second
1 billion days
(2.7 million years)
27 years
2.7 years
1 mS
1 million days
(2,737 years)
10 days
1 day
1 uS
1 thousand days
(2.73 years)
14.4
minutes
1.44
minutes
Additional information for science + technology nerds
Special-purpose research computers like IBM's BlueGene
employ 10 to 20 thousand processors (CPUs) joined by many kilometers of optical
fiber to solve problems. IBM's Roadrunner is
a similar technology employing both "CPUs" and "special non-graphic GPUs that IBM refers to as cell processors"
The basic terms:
Early CPUs were built around integer processing with floating point operations being simulated in software.
Later CPUs offered builtin support for floating point operations
The combined throughput (fetch floating point data from memory, manipulate it, then write it back) is known as a FLOP
(FLoating point OPeration) with the total spec being published as FLOPS (FLoating point OPerations per Second)
As of June 2023, the Folding@home project consists of ~ 40,000 active platforms (some hosting 14,000 GPUs) which yield 26,135 TeraFLOPS (26
PetaFLOPS).
Equivalents:
A Pentium-4 was rated at 12 GigaFLOPS
(26 x 10^15) / (12 x 10^9) = 2,167,000 Pentium-4 processors
A Core i7 was rated at 100 GigaFLOPS which is 8-times higher than the Pentium-4).
(26 x 10^15) / (100 x 10^9) = 260,000 Core i7 processors
This means that the original million-day protein simulation problem could theoretically be
completed in (1,000,000 / 2,167,000) 0.46 days (or 11 hours). But since there are many more protein
molecules than DNA molecules, humanity could be at this for decades. Adding your computers to Folding@home will permanently advance humanity's progress in protein
research and medicine.
When the Human Genome Project (to study
human DNA) was being planned, it was thought that the task may require 100 years. However, technological change in the areas of
computers, robotic sequencers, and the internet after the world-wide-web appeared in 1991 (to coordinate the activities of a
large number of universities where each one was assigned a small piece of the problem), allowed the human genome project to
publish results after only 15 years (a 660% increase).
Distributed computing projects like Folding@home and BOINC have only been possible since 1995:
the world-wide-web (proposed in 1989 to solve
a document sharing problem among scientists at CERN in Geneva; then
implemented in 1991) began to make the internet both popular and ubiquitous.
CISC was replaced with RISC which further evolved to superscalar RISC then multicore.
Vector processing became ubiquitous (primarily) in the form of video
cards.
Processor technology was traditionally defined like this:
Superscalar (1-6 non-blocking scalar
instructions simultaneously in a pipeline. e.g. RISC CPU)
See: Flynn's Taxonomy for
definitions like SISD (single instruction single
data) and SIMD (single instruction multiple data)
but remember that Data represents "Data stream"
See: Duncan's taxonomy for a
more modern twist Caveat: these lists purposely omit things like SMP (symmetric multiprocessing) and VAX Clusters
Then CISC and RISC vendors began adding vector processing instructions to their CPU chips which
blurred everything:
Terminology from math, science and computer science:
scalar: any measurement described by one data point (e.g. 30 km/hour)
vector: any measurement described by two data points (e.g. 30 km/hour, North)
A collection of vectors is usually referred to as a matrix (although a 2-dimensional data structure
created in a computer is also known as a matrix; this includes a single spreadsheet as well as a set of
database records where the columns represent field names; note that these examples can contain, scalars,
vectors, and tensors)
tensor: any item involving three, or more, data points.
Vector processing is a generic name for any kind of multi data point math (vector or tensor) performed on a
computer.
Google released a neat math library in 2015 called TensorFlow
Technological speed up:
While it is possible to do floating point (FP) math on integer-only CPUs, adding specialized logic to
support FP and transcendental math can decrease FP processing time by one order of magnitude (x10) or more.
Similarly, while it is possible to do vector processing (VP) on a scalar machine, adding specialized logic
can decrease VP processing time by 2 to 3 orders of magnitude (x100 to x1000).
2015: AVX-512 (512-bit extensions) first
proposed in 2013 but not seen until 2015
many components extended to 512-bits.
Technology
Width
Year
MMX
64 bit
1997
SSE
128 bit
1999
AVX
256 bit
2008
AVX-512
512 bit
2015
Add-on graphics cards
GPU (graphics programming unit) take vector processing to a whole new level. Why? A $200.00
graphics card now can equip your system with 1500-2000 streaming processors and 2-4 GB of additional high-speed
memory. According to the 2013 book "CUDA Programming", the author provides evidence why any modern
high-powered PC equipped with one, or more (if your motherboard supports it), graphics cards can outperform any
supercomputer listed 12 years ago on www.top500.org
Many companies manufactured graphics cards (I recall seeing them available as purchase options in the IBM-PC
back in 1981) but I will only mention two companies here:
introduces the Tesla line in 2007; these pure-math video cards have no video connector so cannot be
connected to a monitor.
CUDA is released in 2007.
The circle of life?
specialized mainframe computers from companies like IBM and Cray are built to host many thousands of "non-video
video cards" (originally targeted for PCs and workstations). IBM's
Roadrunner is one example.
Both the PlayStation 4 as well as the XBOX One employ an 8-core APU (Accelerated
Processing Unit) made by AMD code-named
Jaguar. What is an APU? It is a multi-core CPU with an embedded Graphics Chip Engine. Placing both systems
on the same silicon die eliminates the signal delay associated with sending signals over an external bus.
I've been in the computer industry for decades but noticed that computers only began to get really
interesting again with the releases of CUDA (2007) and OpenCL (2009)
Distributed computing projects like Folding@home and BOINC
have only been practical since 2005 when the CPUs in personal computers began to out-perform mini-computers and enterprise
servers. Partly because...
AMD added 64-bit support to their x86 processor technology calling it x86-64.
(Linux distros still refer to this a 686)
Intel followed suit calling their 64-bit extension technology EM64T
DDR2 memory became popular (this dynamic memory is capable of
double-data-rate transfers)
Intel added DDR2 support to their Pentium 4 processor line
(2002)
AMD added DDR2 support to their Athlon 64 processor line (2006)
DDR3 memory became popular (this dynamic memory is capable of
quadruple-data-rate transfers)
Since then, the following list of technological improvements has made computers both faster while less expensive:
Intel's abandonment of NetBurst which meant a return to shorter
instruction pipelines starting with Core2 comment: AMD never went to longer pipelines; a long pipeline is only efficient when running a static
CPU benchmark for marketing purposes - not running code in real-world where i/o events interrupt the primary foreground task
(science in our case)
multi-core (each core is a fully functional CPU) chips from all
manufacturers.
continued development of optional graphic cards where CPUs would off-load much work to a graphics co-processor system
(each card appeared as many hundreds to thousands of streaming processors)
ATI Radeon graphics cards (ATI was acquired by AMD in 2009)
NVIDIA GeForce graphics cards
development of high performance "graphics" memory technology (e.g. GDDR3
, GDDR4 , GDDR5)
to bypass processing stalls caused when streaming processors are too fast.
Note that GDDR5 is used a main memory in the PlayStation 4
(PS4). While standalone PCs were built to host an optional graphics card, it seems that Sony has flipped things so that
their graphics system is hosting an 8-core CPU. These hybrids go by the name APU.
shifting analysis from host CPU cores (usually 2-4) to thousands of streaming processors
Intel replacing 20-year old FSB technology
with a proprietary new approach called QuickPath
Interconnect (QPI) which is now found in Core-i3, Core-i5, Core
i7 and Xeon Historical note:
DEC created the 64-bit Alpha processor which
was first announced in 1992 (21064 was first, 21164, 21264, 21364, came later)
Compaq bought DEC in 1998.
The DEC division of Compaq created CSI (Common
System Interface) for use in their EV8 Alpha
processor which was never released.
HP merged with Compaq in 2002.
HP preferred Itanium2 (jointly developed by HP
and Intel) so announced their intention to gracefully shut down Alpha.
Alpha technology (which included CSI) was immediately sold to Intel.
approximately 300 Alpha engineers were transferred to Intel between 2002 and 2004.
CSI morphed into QPI (some industry watchers say that Intel ignored CSI until the announcement by AMD to go with a new
industry-supported technology known as HyperTransport.
The remainder of the industry went with a non-proprietary technology called HyperTransport which has been described as a multi-point Ethernet for use within a computer system.
As is true in any "demand vs. supply" scenario, most consumers didn't need the additional computing power which meant that
chip manufacturers had to drop their prices just to keep the computing marketplace moving. This was good news for people setting
up "folding farms". Something similar is happening today with computer systems since John-q-public is shifting from
"towers and desktops" to "laptops and pads". This is causing the price of towers and graphics cards to plummet ever lower. You
just can't beat the price-performance ratio of a Core-i7 motherboard hosting an NVIDIA graphics card.
Shifting from brute-force "Chemical Equilibrium" algorithms to techniques involving Bayesian statistics and Markov
Models will enable some exponential speedups.
Computational Chemistry Student Questions:
Using information from the periodic
table of the elements you can see that the molecular
mass of water (H2O) is ~18 which is lighter than many gases so why is water in a liquid state at room
temperature while other slightly heavier molecules take the form of a gas?
Ethanol (a liquid) has one more atom of Oxygen than Ethane (a gas). How can this small difference change the state?
Liquid Water
This diagram depicts an
H2O molecule loosely
bound to four others by
Van der Walls forces.
Substance
Molecule
Atomic
Masses
Molecular
Mass
State at Room
Temperature
Water
H2O
(1x2) + 16
18
liquid
Carbon Monoxide
CO
12 + 16
28
gas
Molecular Oxygen
O2
(16x2)
32
gas
Carbon Dioxide
CO2
12 + (16x2)
44
gas
Ozone
O3
(16x3)
48
gas
Methane
CH4
12 + (1x4)
16
gas
Ethane
C2H6
(12x2) + (1x6)
30
gas
Ethanol
C2H6O
(12x2) + (1x6) + 16
46
liquid
Propane
C3H8
(12x3) + (1x8)
44
gas
Butane
C4H10
(12x4) + (1x10)
58
gas
Pentane
C5H12
(12x5) + (1x12)
72
gas
Hexane
C6H14
(12x6) + (1x14)
86
liquid
Heptane
C7H16
(12x7) + (1x16)
100
liquid
Octane
C8H18
(12x8) + (1x18)
114
liquid
Short answers:
In the case of an H20 (water) molecule, even though two hydrogen atoms are covalently bound to one oxygen atom, those same hydrogen atoms are also attracted to each other which
causes the water molecule to bend into a Y shape (according to
VSEPR Theory). At the mid-point of the bend, a positive electrical charge from the oxygen atom is exposed to the world
which allows a weak connection to the hydrogen atom of a neighboring H20 molecule (water molecules weakly
sticking to each other form a liquid). These weak connections are called Van der Waals forces
Here are the molecular schematic diagrams of Ethane (symmetrical) and Ethanol (asymmetrical). Notice that Oxygen-Hydrogen
kink dangling to the right of Ethanol? That kink is not much different than a similar one associated with water. That is the
location where a Van der Waal force weakly connects with an adjacent ethanol molecule (not shown). So it should be no
surprise that ethane at STP (Standard
Temperature and Pressure) is a gas while Ethanol is a liquid.
Ethane Ethanol
(symmetrical) (asymmetrical)
H H H H H
| | | | /
H-C-C-H H-C-C-O
| | | |
H H H H
Van der Waals did all his computations using pencil and paper long before the first computer was
invented; and this was only possible because the molecules in question were small and few.
Chemistry Caveat: The Molecular Table above was only meant to get you thinking. Now inspect this LARGER periodic table of the elements where the color of
the atomic number indicates whether the natural state is solid or gaseous:
all elements in column 1 (except hydrogen) are naturally solid.
all elements in column 8 (helium to radon) are naturally gaseous.
half the elements in row 2 starting with Lithium (atomic number 3) and ending with Carbon (atomic number 6), as well as
two thirds of row 3 starting with Sodium (atomic number 11) and ending with Sulfur (atomic number 16), are naturally solid.
I will leave it to you to determine why.
Molecular Dynamics
Proteins come in many shapes and sizes. Here is a very short list:
technology problems, discussions, news, science, etc.
FAH Targeted Diseases
This "folding knowledge" will be used to develop new drugs for treating diseases such as:
ALS ("Amyotrophic Lateral Sclerosis" a.k.a. "Lou Gehrig's Disease")
Alzheimer's Disease
Plaques, which contain misfolded peptides called amyloid beta, are formed in the brain many years before the signs of this
disease are observed. Together, these plaques and neurofibrillary tangles form the pathological hallmarks of the disease.
Cancer & P53
P53 is the suicide gene involved in apoptosis (programmed cell death - something
necessary in order your immune system to kill cancer cells)
CJD (Creutzfeldt-Jakob Disease)
the human variation of mad cow disease
Huntington's Disease
Huntington's disease is caused by a trinucleotide repeat expansion in the Huntingtin (Htt) gene and is one of
several polyglutamine (or PolyQ) diseases. This expansion produces an altered form of the Htt protein, mutant Huntingtin (mHtt),
which results in neuronal cell death in select areas of the brain. Huntington's disease is a terminal illness.
Osteogenesis Imperfecta
Normal bone growth is a yin-yang balance between osteoclasts and oseteoblasts.
Osteogenesis Imperfecta occurs when bone grows without sufficient or healthy collagen
(protein)
Parkinson's Disease
The mechanism by which the brain cells in Parkinson's are lost may consist of an abnormal accumulation of the protein
alpha-synuclein bound to ubiquitin in the damaged cells.
Ribosome & antibiotics
A ribosome is a protein producing organelle found inside each cell.
6,250,000,000 points: 2024-11-23 (yes, over 6 billion)
141,200 work units: 2024-11-23
FAH third-party stats:
Many like-minded people in China are helping with protein folding (this is great news). Some of
their client processes WHERE folding under my account name at a very respectable 8 million points
per day. Whoever you are, many thanks for helping humanity advance biological knowledge. Isaac Asimov would approve.
from
to
user
team
third party statics
rank
2007-12-22
2022-01-28
neil_rieck
Default
FINAL Tally ( Points: 418,381,428 WU: 110,984 )
https://folding.extremeoverclocking.com/user_summary.php?s=&u=306663
Note: no more new stats here because I changed teams
A single core Pentium-class CPU provides one scalar processor. It also provides one streaming (vector)
processor under marketing names like MMX
(64-bit) , SSE (128-bit), AVX (256-bit) and AVX-512 (512-bit)
Most Core i5 and Core i7 CPU's provide four scalar cores so offer at least four streaming (vector) processors.
A single add-on graphics card can provide hundreds to thousands vector processors (the
Nvidia RTX-3090 provides 10,496)
caveat: GPU folding on CentOS-7 failed December-2021 and is no longer possible so: jump
to 2022
I found two junk PCs in my basement with 64-bit CPUs that were running 32-bit operating systems (Windows-XP and Windows-Vista).
Unfortunately for me, neither were eligible for Microsoft's free upgrade to Windows-10, and I had no intention of buying a new
64-bit OS just for this hobby. So I swapped out Windows with CentOS-7 and was able to get each one folding with very little effort.
What follows are some tips for people who are not Linux gurus:
CentOS-7.7 and CentOS-8.0 were released days apart in September 2019 (perhaps due to the invisible
hand of IBM?)
Software from the top of download page preferentially offers CentOS-8 which is too large (> 4.7 GB) to write to a
single-layer writable DVD, but I have has some success with Dual Layer optical media. Linux distros assume you will copy
these images to a USB stick, but the BIOS in many older machines does not support booting from a thumb drive.
Transfer to bootable media (choose one of the following)
copy the ISO image to a DVD-writer
-OR-
use rufus to format an USB stick then copy the ISO image to the USB caveat: newer PCs have transitioned from BIOS to UEFI. Older BIOS-based systems do not support
booting from a USB stick (strange because you can connect a USB-based DVD then boot from that)
Boot-install CentOS-7 on the 64-bit CPU
Using a larger downloaded image:
1) burn, boot, install Linux using recipe: "GUI with Server" 2) reboot; now update via the internet like so: yum update 3) reboot;
4) add development tools: yum group "Development Tools" install
Using smaller downloads (then adding GUI after the fact):
1) burn, boot, install Linux using recipe: "Server" 2) reboot; now update via the internet like so: yum update 3) reboot; optionally enable GUI: yum group "Server with GUI" install may also need to type: systemctl isolate graphical.target systemctl set-default graphical.target
4) add development tools: yum group "Development Tools" install
My machines hosted NVIDIA graphics cards (GTX-560 and GTX-960
respectively) so these systems required the correct NVIDIA drivers in order to do GPU-based folding. Why? The generic drivers
only support video but folding science requires OpenCL and CUDA
HARD WAY: If you are a Linux guru and know how to first disable the Nouveau driver, then install the
64-bit Linux driver provided by NVIDIA here: http://www.nvidia.com/Download/index.aspx
EASY WAY: First install the nvidia-detect module found at elrepo (Enterprise
Linux REPOsitory) here ( http://elrepo.org/tiki/tiki-index.php
) and documented here ( https://elrepo.org/tiki/nvidia-detect ) then
use the utility to install another elrepo package. The steps look similar to this if you are logged in as root:
step-1 (install one/two repos via yum)
activity
Linux command
Notes
Description
view available repos
yum list \*-release\*
backslash escapes the asterisk
install elrepo
yum install elrepo-release
required
Enterprise Linux REPO
install epel
yum install epel-release
optional
Extra Packages for Enterprise Linux
step-2 (install nvidia-detect from elrepo)
activity
Linux command
install nvidia-detect
yum install nvidia-detect
test nvidia-detect
nvidia-detect -v
install nvidia driver
yum install $(nvidia-detect)
reboot
reboot
If you are not logged in as root then you must prefix every command with sudo (Super
User DO).
Now jump to Linux common
Folding with EL8 (2022)
Both of my CentOS-7 machines stopped folding in Dec-2021. Apparently this is due to several changes by the FAH
research team.
First off, new FAH downloadable cores require an updated version of Linux library glibc which is not available on
CentOS-7, so you need to upgrade to CentOS-8, or any other EL8 (see caveat ~ 6 lines below)
Secondly, changes to the FAH GPU cores now require a minimum of OpenCL-1.2. This means that my GTX-560 is no longer
useful as a streaming processor. I noticed another blurb about double-precision FP math which definitely rules out my GTX-560
so I replaced it with a GTX-1650
On both systems I replaced CentOS-7 with CentOS-8 (via a fresh install) then followed the CentOS-7 instructions just above.
However, the Nvidia driver from elrepo-release (EL8) did not contain any OpenCL support so I was forced to install the Linux
driver provided by Nvidia (you first need to disable the Nouveau driver which requires some Linux guru voodoo). If doing a
fresh reinstall is not possible then you should consider using the ELevate -
leapp migration tool published by AlamaLinux
For some reason, these CentOS-8 machines seem sluggish, so I jumped to Rocky Linux 8.5 which solved all my problems.
Caveat:IBM purchased Red Hat in 2019 for the sum of US$34 billion. In 2020 the
transformed Blue Hat announced their intent CentOS-8 minor point updates after 2021-12-31 because too many
companies (like Facebook) were using this free software (gotta speed up the ROI on that $34 billion investment). Even though
Red Hat begins each OS iteration using open-source
software, they announced on 2023-06-21 that they were going to restrict access (close source) their modifications. This
will affect all EL (Enterprise Linux) flavors including: AlmaLinux, EuroLinux, Oracle Linux, Rocky Linux, etc. so you might
consider moving to any target supported by this migration tool (ELevate -
leapp). Note that academics working at Fermilab just outside of Chicago, or CERN (home of the LHC) in Geneva, recommend
moving to AlmaLinux. My advice is to always employ a
Linux that can be downloaded from a university mirror. Here is one example of 10,000: https://mirror.csclub.uwaterloo.ca/
Mirror observations:
active offerings for AlmaLinux
no CentOS updates after CentOS-8.5
no offerings for CentOS-stream, Oracle Linux, EuroLinux, Rocky Linux
Real world concern: you never know when problems (political, commercial, technological) will block you from getting to
a single site. But you can always modify "/etc/yum.conf" to point directly to a nearby university mirror.
Updating to a NVIDIA published driver
after the initial Linux install, type "sudo yum update" to bring the platform up to the latest level. If a new
kernel was installed then you must reboot before you continue.
DO NOT use elrepo to update the Nvidia driver (on 2022-01-16 it was missing support for OpenCL and CUDA)
Only download the desired driver file from NVIDIA into the root account
for GTX960 I used: NVIDIA-Linux-x86_64-470.86.run (will probably be renamed before you read this)
for GTX1650 I used: NVIDIA-Linux-x86_64-525.89.run (will probably be renamed before you read this)
Now disable the Nouveau driver
create file /etc/modprobe.d/blacklist-nouveau.conf containing these two lines:
blacklist nouveau
options nouveau modeset=0
create a new ramdisk for use during system boot: dracut --force
reboot
caveat: at this point your monitor is no longer capable of displaying small text in character-cell mode but
you don't care because you've already downloaded the necessary files from Nvidia corporation. Right?
Install the NVIDIA driver
yum group "Development Tools" install
chmod 777 NVIDIA-Linux-x86_64-470.86.run
./NVIDIA-Linux-x86_64-470.86.run
caveat: the previous command might fail for the following reasons:
not an executable file (did you use chmod ?)
no build tools (gcc compiler, etc. Did you install "Development Tools"?)
nouveau driver is running
reboot
caveats:
kernel updates via "yum update" (CentOS-7) or "dnf update" (CentOS-8) always require a reboot. Ninety
percent of the time you will need to reinstall the Nvidia driver after a kernel update (just repeat step 3 above).
If your console is blank then type this three-key-combo CTL-ALT-F3 (control alternate F3) then log in as root
on the third virtual console.
some of the GUI-based software may not work properly (on CentOS-7 or earlier) because Python3 is a prerequisite
Python3 can be easily added to EL7 systems like CentOS-7 but do not remove or disable Python2 because that action will
break certain system utilities like yum or firewall-cmd to name two of
many.
starting the client with the --configure switch will generate an XML configuration file
starting the client with the --config switch will let you test an XML configuration file
starting the client with the --help switch will display more help than you ever dreamed possible
Caveat: just installing the FAH-Client will cause it to be installed as a service then start CPU folding
(which is probably what you do not want). If you want to enable GPU-based folding (and/or
disable CPU folding) then you will need to stop the client, modify the config file, test the config file, then restart the
client. Here are some commands to help out.
task
command
stop service
sudo systemctl stop fahclient
or
sudo /etc/init.d/FAHClient stop
notes:
1) type can be one of: 'cpu', 'smp', 'gpu'
2) never enable 'smp' unless to have >= 4 cores
3) with 'gpu' enabled I see no point in folding with 'cpu' or 'smp'
note: GPU folding requires OpenCL-1.2 so if you see errors like
'cannot find OpenCL' then you might need to rebuild your NVIDIA
driver (almost always required after any Linux update that
replaces the kernel
end interactive test
hit: <ctrl-c>
start the service
systemctl start fahclient
or
sudo /etc/init.d/FAHClient start &
monitor step #1
monitor step #2
monitor step #3
top -d 0.5
cat /var/lib/fahclient/logs.txt
tail -40 /var/lib/fahclient/logs.txt
Stopped services may only be deleted from DOS like so:
sc query neil369
sc delete neil369
BOINC (Berkeley Open Infrastructure for Network Computing)
BOINC (Berkeley Open Infrastructure for Network Computing) is a science framework
in which you can support one, or more, projects of choice.
If you are unable to pick a single cause then pick several because the BOINC manager will switch between science clients
every hour (this interval is adjustable). In my case I actively support POEM, Rosetta, and Docking.
The current BOINC client can be programmed to use one, some, or all cores of a multi-core machine. The BOINC client can also
utilize (or not) the streaming processors on your Graphics Card.
http://boinc.bakerlab.org/rosetta/ is the home of Rosetta@home
which operates through the BOINC framework. Their graphics screen-saver is one very effective way to help visualize "what
molecular dynamics is all about". All science teachers must show this to their students.
I'm sure everyone already knows that a computer "rendering beautiful graphical displays" is doing less science. That said,
humans are visual creatures and graphical displays have their place in our society. Except for some public locations, all
clients should be running in non-graphical mode so that more system resources are diverted to protein analysis.
Five questions for Rosetta@home: How Rosetta@home helps cure cancer, AIDS, Alzheimer's, and more
some people may prefer to use the generic BOINC client from Berkley then install the WCG plugin from that application; you
will still need to create your WCG account at the WCG site
You only need to do this if you want to cycle your BOINC client between multiple projects of which WCG is just one
If you only want to run the WCG project (which also switches between IBM sponsored science projects) then it probably
makes more sense to use the WCG-specific client
https://en.wikipedia.org/wiki/World_community_grid (WCG) is
an effort to create the world's largest public computing grid to tackle scientific research projects that benefit humanity.
Launched 2004-11-16, it is funded and operated by IBM with client software currently available for Windows, Linux,
Mac-OS-X and FreeBSD operating systems. They encourage their employees and customers to do the same.
Personal Comment: I wonder why HP (Hewlett-Packard) has not followed IBM's lead. Up until now I
always thought of IBM as the template of uber-capitalism but it seems that the title of "king of profit by the elimination of
seemingly superfluous expenses" goes to HP. Don't they realize that IBM's effort in this area is done under IBM's advertising
budgets? Just like IBM's 1990s foray into chess playing systems (e.g. Deep Blue) led to increased sales as well as share prices,
one day IBM will be able to say "IBM contributed to a treatments for human diseases including cancer". IBM actions in this area
reinforce the public's association with IBM and information processing.
The Encyclopedia of DNA Elements (ENCODE) Consortium is an
international collaboration of research groups funded by the National Human Genome Research Institute (NHGRI). The goal of ENCODE is to build a comprehensive parts list of functional elements in the human genome,
including elements that act at the protein and RNA levels, and regulatory elements that control cells and circumstances in which a
gene is active.
The Encyclopedia of DNA Elements (ENCODE) is a public research consortium launched by the US National Human Genome Research Institute (NHGRI) in September 2003. The
goal is to find all functional elements in the human genome, one of the most critical projects by NHGRI after it completed the
successful Human Genome Project.
All data generated in the course of the project will be released rapidly into public databases.
On 5 September 2012, initial results of the project were released in a coordinated set of 30 papers published in the journals
Nature (6 publications), Genome Biology (18 papers) and Genome Research (6
papers). These publications combine to show that approximately 20% of
noncoding DNA in the human genome is functional while an additional 60% is transcribed with no known function. Much of
this functional non-coding DNA is involved in the
regulation of the expression of
coding genes. Furthermore, the expression of each coding gene is controlled by multiple regulatory sites located both near and
distant from the gene. These results demonstrate that gene regulation is far more complex than previously believed.
http://www.technologyreview.com/view/510571/the-million-core-problem/ The Million-Core Problem - Stanford researchers
break a supercomputing barrier.
quote: A team of Stanford researchers have broken a record in supercomputing, using a million cores to model a complex fluid
dynamics problem. The computer is a newly installed Sequioa IBM Bluegene/Q system at the Lawrence Livermore National
Laboratories. Sequoia has 1,572,864 processors, reports Andrew Myers of Stanford Engineering, and 1.6 petabytes of memory.