y-cruncher - A Multi-Threaded Pi-Program
	From a high-school project that went a little too far... By Alexander J. Yee

(Last updated: October 14, 2018)

 

 

The first scalable multi-threaded Pi-benchmark for multi-core systems...

 

How fast can your computer compute Pi?

 

y-cruncher is a program that can compute Pi and other constants to trillions of digits.

It is the first of its kind that is multi-threaded and scalable to multi-core systems. Ever since its launch in 2009, it has become a common benchmarking and stress-testing application for overclockers and hardware enthusiasts.

 

y-cruncher has been used to set several world records for the most digits of Pi ever computed.

• 22.4 trillion digits - November 2016 (Peter Trueb)
• 13.3 trillion digits - October 2014 (Sandon Van Ness "houkouonchi")
• 12.1 trillion digits - December 2013 (Shigeru Kondo)
• 10 trillion digits - October 2011 (Shigeru Kondo)
• 5 trillion digits - August 2010 (Shigeru Kondo)

 

Current Release:

Windows: Version 0.7.6 Build 9487 (Released: October 14, 2018)

Linux      : Version 0.7.6 Build 9487 (Released: October 14, 2018)

 

Official HWBOT thread.

Official XtremeSystems Forums thread.

 

News:

 

Catalan's Constant is No Longer a Slow Constant: (August 23, 2018) - permalink

 

In what is probably the first major mathematical improvement since the start of the y-cruncher project, there are 3 new formulas for Catalan's Constant.

 

I was recently made aware of a publication by F. M. S. Lima which directly and indirectly led to 3 new formulas for Catalan's Constant which are faster than the Lupas formula which had been the fastest for more than a decade.

Name	Formula	Speedup vs. Lupas
Guillera		1.7x
Pilehrood (short)		3.8x
Pilehrood (long)		2.5x

All 3 formulas have been implemented for y-cruncher v0.7.7. But the timing of this with respect to y-cruncher's release cycle (having just released v0.7.6), means it will be months before these formulas see the light of day for y-cruncher. But at the very least, we know that they exist and that they work. All 3 implementations have been tested to 1 billion digits. (which didn't take very long)

 

Catalan's Constant has historically been one of the slowest mainstream constants to compute - second only to the Euler-Mascheroni Constant. But thanks to these formulas, Catalan's Constant is now almost as fast as Zeta(3).

 

As only two independent algorithms are needed to establish records, the existing formulas by Lupas and Huvent (as well as Guillera's formula) are now effectively out-of-date. But there are no immediate plans to remove any of the outdated formulas.

 

Mathematics evolves at a much slower pace than computer hardware. So it is easy to forget that math remains one of the most important parts of high precision computations. Without such formulas and algorithms, large computations would be impossible. So we must never stop thanking the generations of mathemeticians, both past and present, that have made such projects possible.

 

While we wait for v0.7.7, two new articles have been added to the algorithms page:

• Binary Splitting
• Binary Splitting Recursion Library

 

 

 

Older News

 

Records Set by y-cruncher:

y-cruncher has been used to set a number of world record sized computations.

 

Blue: Current World Record

Green: Former World Record

Red: Unverified computation. Does not qualify as a world record until verified using an alternate formula.

Date Announced	Date Completed:	Source:	Who:	Constant:	Decimal Digits:	Time:	Computer:
October 6, 2018	October 6, 2018		Alexander Yee	Zeta(5)	20,000,000,000	Compute:  25.3 hours Verify:  17.3 hours	Intel Core i9 7940X @ 3.6 GHz 128 GB DDR4
September 23, 2018	September 28, 2018		Tizian Hanselmann	Golden Ratio	2,600,000,000,000	Compute:  9.25 days Verify:  9.03 days	2 x Intel Xeon E5620 @ 2.4 GHz 128/144 GB DDR4 4 x 4TB
August 28, 2018	August 28, 2018		"yoyo" & Ryan Moore	Golden Ratio	2,500,000,000,000	Compute:  42.2 hours Verify:  169 hours	2 x Intel Xeon E5-2696 v4 @ 2.2 GHz 768 GB Intel Core i7 7700K @ 4.2 GHz 32 GB
August 9, 2018	August 4, 2018		Gerald Hofmann	e	8,000,000,000,000	Compute:  28.5 days Not Verified	2 x AMD Epyc 7551 @ 2.0 GHz 256 GB
August 24, 2017	August 23, 2017		Ron Watkins	Euler-Mascheroni Constant	477,511,832,674	Compute:  34.4 days Verify:  141 days	4 x Xeon E5-4660 v3 @ 2.1 GHz - 1 TB 2 x Xeon X5690 @ 3.47 GHz - 128 GB
August 14, 2017	August 13, 2017		Ron Watkins	Zeta(3) - Apery's Constant	500,000,000,000	Compute:  19.7 days Verify:  29.8 days	8 x Xeon 6550 @ 2.0 GHz - 512 GB 2 x Xeon X5690 @ 3.46 GHz - 142 GB
November 15, 2016	November 11, 2016	Blog Sponsor	Peter Trueb	Pi	22,459,157,718,361	Compute:  105 days Verify:  28 hours Validation File	4 x Xeon E7-8890 v3 @ 2.50 GHz 1.25 TB DDR4 20 x 6 TB 7200 RPM Seagate
September 3, 2016	August 29, 2016		Ron Watkins	e	5,000,000,000,000	Compute:  48.6 days Verify:  48.7 days	2 x Xeon X5690 @ 3.47 GHz 141 GB
July 11, 2016	July 5, 2016		"yoyo"	Golden Ratio	10,000,000,000,000	Compute:  6.2 days Not Verified	2 x Intel Xeon E5-2696 v4 @ 2.2 GHz 768 GB
June 28, 2016	June 19, 2016		Ron Watkins	Square Root of 2	10,000,000,000,000	Compute:  18.8 days Verify:  25.2 days	2 x Xeon X5690 @ 3.47 GHz 141 GB
June 4, 2016	May 29, 2016		Ron Watkins	Lemniscate	250,000,000,000	Compute:  91.7 hours Verify:  270 hours	4 x Xeon E5-4660 v3 @ 2.1 GHz - 1TB 4 x Xeon X6550 @ 2 GHz - 512 GB
April 24, 2016	April 18, 2016		Ron Watkins	Log(2)	500,000,000,000	Compute:  12.8 days Verify:  14.4 days	4 x Xeon X5690 @ 3.47 GHz - 141 GB
April 17, 2016	April 12, 2016		Ron Watkins	Catalan's Constant	250,000,000,000	Compute:  204 hours Verify:  207 hours	4 x Xeon E5-4660 v3 @ 2.1 GHz 1 TB
April 9, 2016	April 3, 2016		Ron Watkins	Log(10)	500,000,000,000	Compute:  14.4 days Verify:  15.2 days	2 x Xeon X5690 @ 3.47 GHz 141 GB
February 8, 2016	February 6, 2016		Mike A	Catalan's Constant	500,000,000,000	Compute:  26.1 days Not Verified	2 x Intel Xeon E5-2697 v3 @ 2.6 GHz 128 GB
July 24, 2015	July 22, 2015 July 23, 2015	Source	Ron Watkins Dustin Kirkland	Golden Ratio	2,000,000,000,000	Compute:  77.3 hours Verify:  76.33 hours Compute:  79.3 hours Verify:  80.8 hours	4 x Xeon X6550 @ 2 GHz - 512 GB Xeon E5-2676 v3 @ 2.4 GHz - 64 GB
October 8, 2014	October 7, 2014		Sandon Van Ness (houkouonchi)	Pi	13,300,000,000,000	Compute:  208 days Verify:  182 hours Validation File	2 x Xeon E5-4650L @ 2.6 GHz 192 GB DDR3 @ 1333 MHz 24 x 4 TB + 30 x 3 TB
December 28, 2013	December 28, 2013	Source	Shigeru Kondo	Pi	12,100,000,000,050	Compute: 94 days Verify: 46 hours	2 x Xeon E5-2690 @ 2.9 GHz 128 GB DDR3 @ 1600 MHz 24 x 3 TB

See the complete list including other notably large computations.

 

If you wish to set a record, you must:

1. Run the computation twice using different algorithms.
2. If using y-cruncher v0.7.5 or later, both computations must be done with "Verify Output" enabled.
3. If using y-cruncher v0.7.6 or later, digit output must be enabled. You can't claim a record if the digits are never saved!
4. The digits from both computations need to match.
5. Then send me the validation files, but do not make any attempt to modify* them. It is recommended to zip or compress the file when sending over email (or any other medium) to protect it from being corrupted by file formatters.

*The validation files are protected with a checksum to prevent tampering/cheating. People have tried to cheat before - which is why we can't have nice things.

 

 

An exception to the "two computations rule" can be made for Pi since it can be verified using BBP formulas.

 

Note that for anyone attempting to set a Pi world record: Should the attempt succeed, I kindly ask that you make yourself sufficiently available for external requests to access or download the digits in its entirety (at least until it is broken again by someone else). Pi is popular enough that people do actually want to see the digits.

 

Features:

 

The main computational features of y-cruncher are:

• Able to compute Pi and other constants to trillions of digits.
• Two algorithms are available for most constants. One for computation and one for verification.
• Multi-Threaded - Multi-threading can be used to fully utilize modern multi-core processors without significantly increasing memory usage.
• Vectorized - Able to fully utilize the SIMD capabilities for most processors. (SSE, AVX, AVX512, etc...)
• Swap Space management for large computations that require more memory than there is available.
• Multi-Hard Drive - Multiple hard drives can be used for faster disk swapping.
• Semi-Fault Tolerant - Able to detect and correct for minor errors that may be caused by hardware instability or software bugs.

 

Download:

 

Latest Releases: (October 14, 2018)

OS	Download Link	Size
Windows	y-cruncher v0.7.6.9487.zip	39.7 MB
Linux (Static)	y-cruncher v0.7.6.9487-static.tar.xz	25.3 MB
Linux (Dynamic)	y-cruncher v0.7.6.9487-dynamic.tar.xz	18.7 MB

 

 

 

 

 

 

 

 

The Linux version comes in both statically and dynamically linked versions. The static version should work on most Linux distributions, but lacks Cilk Plus and NUMA binding. The dynamic version supports all features, but is less portable due to the DLL dependency hell.

 

The Windows download comes bundled with the HWBOT submitter which allows benchmarks to be submitted to HWBOT.

 

System Requirements:

Windows:

• Windows Vista or later.
• The HWBOT submitter requires the Java 8 Runtime.

Linux:

• 64-bit Linux is required. There is no support for 32-bit.
• The dynamic version has been tested on Ubuntu 18.04.

All Systems:

• An x86 or x64 processor.

Very old systems that don't meet these requirements may be able to run older versions of y-cruncher. Support goes all the way back to even before Windows XP.

 

Version History:

• y-cruncher
• HWBOT Submitter

 

Other Downloads (for C++ programmers):

• Source code for the Digit Viewer
• Mini-Pi: A tiny self-contained Pi program

 

Advanced Documentation:

• Multi-Threading
• Memory Allocation
• Swap Mode

 

 

Benchmarks:

Comparison Chart: (Last updated: September 15, 2018)

 

Computations of Pi to various sizes. All times in seconds. All computations done entirely in ram.

The timings include the time needed to convert the digits to decimal representation, but not the time needed to write out the digits to disk.

 

Blue: Benchmarks are up-to-date with the latest version of y-cruncher.

Green: Benchmarks were done with an old version of y-cruncher that is comparable in performance with the current release.

Red: Benchmarks are significantly out-of-date due to being run with an old version of y-cruncher that is no longer comparable with the current release.

 

 

Laptops + Low-Power:

Processor(s):	Core i7 3630QM	VIA C4650	Pentium N42001	Xeon E3-1535M v5	Core i7 6820HK	Core i7 8850H
Generation:	Intel Ivy Bridge	VIA Isaiah	Intel Apollo Lake	Intel Skylake	Intel Skylake	Intel Coffee Lake
Cores/Threads:	4/8	4/4	4/4	4/8	4/8	6/12
Processor Speed:	3.2 GHz	2.0 GHz	1.1 - 2.5 GHz	2.9 GHz	3.2 GHz	?? GHz
Memory:	16 GB - 1600 MT/s	16 GB	4 GB	16 GB	48 GB - 2133 MT/s	16 GB
Version:	v0.7.6 ~ Hina	v0.7.2 ~ Hina	v0.7.2 ~ Ushio	v0.7.1 ~ Kurumi	v0.7.6 ~ Kurumi	v0.7.6 ~ Kurumi
Instruction Set:	x64 AVX	x64 AVX	x64 SSE4.1	x64 AVX2 + ADX	x64 AVX2 + ADX	x64 AVX2 + ADX
25,000,000	3.895	17.207	11.739	1.865	1.656	1.539
50,000,000	8.761	39.049	26.289	4.102	3.591	3.309
100,000,000	19.338	87.626	65.147	9.007	7.916	7.546
250,000,000	57.716	277.711	192.473	25.444	21.959	20.011
500,000,000	132.171	587.516	493.551	56.566	48.781	47.37
1,000,000,000	304.784	1,350.868		130.055	108.108	109.754
2,500,000,000	895.365	3,884.838			308.514	291.586
5,000,000,000					681.761
10,000,000,000					1,535.329
Credit:	Oliver Kruse	Tralalak		Kaupo Karuse		yoyo

 

 

Mainstream Desktops:

Processor(s):	Core i7 7700K	Ryzen 7 1800X	Core i7 8700K	Core i7 9700K	Core i7 9900K
Generation:	Intel Kaby Lake	AMD Zen	Intel Coffee Lake	Intel Coffee Lake	Intel Coffee Lake
Cores/Threads:	4/8	8/16	6/12	8/8	8/16
Processor Speed:	4.9 GHz (OC)	3.7 GHz	4.9 - 5.0 GHz (OC)	*** GHz	*** GHz
Memory:	64 GB - 3200 MT/s	64 GB - 3000 MT/s	16 GB - 3600 MT/s	16 GB - **** MT/s	16 GB - **** MT/s
Program Version:	v0.7.6 ~ Kurumi	v0.7.6 ~ Yukina	v0.7.6 ~ Kurumi	v0.7.6 ~ Kurumi	v0.7.6 ~ Kurumi
Instruction Set:	x64 AVX2 + ADX	x64 AVX2 + ADX	x64 AVX2 + ADX	x64 AVX2 + ADX	x64 AVX2 + ADX
25,000,000	1.049	1.247	0.930	Under embargo until release.
50,000,000	2.314	2.655	2.023
100,000,000	5.077	5.759	4.352
250,000,000	14.277	16.115	11.925
500,000,000	31.878	35.783	25.883
1,000,000,000	70.806	79.345	56.387
2,500,000,000	204.042	228.840	157.515
5,000,000,000	448.258	498.923
10,000,000,000	976.451	1,092.887
Credit:	Oliver Kruse		Nehal Prasad

Processor(s):	Phenom II X3 720	Core i7 920	FX-8350	Core i7 4770K	Core i7 5775C
Generation:	AMD K10	Intel Nehalem	AMD Piledriver	Intel Haswell	Intel Broadwell
Cores/Threads:	4/4 (unlock from 3/3)	4/8	8/8	4/8	4/8
Processor Speed:	2.8 GHz	3.5 GHz (OC)	4.0 GHz	4.0 GHz (OC)	3.8 GHz (OC)
Memory:	12 GB - 1333 MT/s	12 GB - 1333 MT/s	32 GB - 1600 MT/s	32 GB - 2133 MT/s	16 GB - 2400 MT/s
Program Version:	v0.7.6 ~ Kasumi	v0.7.5 ~ Ushio	v0.7.6 ~ Miyu	v0.7.6 ~ Airi	v0.7.1 ~ Kurumi
Instruction Set:	x64 SSE3	x64 SSE4.1	x64 AVX + XOP	x64 AVX2	x64 AVX2 + ADX
25,000,000	9.357	5.046	3.239	1.524	1.730
50,000,000	19.678	11.117	7.167	3.365	3.940
100,000,000	43.794	24.855	15.700	7.527	8.739
250,000,000	127.530	73.794	43.787	20.766	25.073
500,000,000	283.572	164.814	97.843	46.358	56.343
1,000,000,000	648.422	375.974	219.344	102.451	125.967
2,500,000,000	1,832.422	1,066.704	633.021	291.632	369.738
5,000,000,000			1,408.939	645.998
10,000,000,000
Credit:					André Bachmann

 

 

High-End Desktops:

Processor(s):	Core i7 5820K	Core i7 5960X	Threadripper 1950X	Core i9 7900X	Core i9 7940X
Generation:	Intel Haswell	Intel Haswell	AMD Threadripper	Intel Skylake X	Intel Skylake X
Cores/Threads:	6/12	8/16	16/32	10/20	14/28
Processor Speed:	4.5 GHz (OC)	4.0 GHz (OC)	3.5 - 3.7 GHz	4.3/4.0/3.6 GHz*	4.6/4.0/3.6 GHz*
				3.0 GHz cache	2.8 GHz cache
Memory:	32 GB - 2400 MT/s	64 GB - 2133 MT/s	128 GB - 3000 MT/s	128 GB - 3600 MT/s	128 GB - 3466 MT/s
Program Version:	v0.7.3 ~ Airi	v0.7.6 ~ Airi	v0.7.6 ~ Yukina	v0.7.6 ~ Kotori	v0.7.6 ~ Kotori
Instruction Set:	x64 AVX2	x64 AVX2	x64 AVX2 + ADX	x64 AVX512-DQ	x64 AVX512-DQ
25,000,000	1.287	0.812	0.747	0.522	0.520
50,000,000	2.499	1.942	1.516	1.117	1.052
100,000,000	5.401	4.072	3.203	2.362	2.177
250,000,000	14.732	10.991	8.733	6.209	5.409
500,000,000	32.294	23.929	19.139	13.204	11.412
1,000,000,000	71.225	52.768	42.345	28.827	24.232
2,500,000,000	200.323	149.365	119.526	79.854	66.592
5,000,000,000	443.543	330.414	266.066	178.786	147.719
10,000,000,000		722.456	579.380	394.887	323.079
25,000,000,000			1629.994	1119.634	911.097
Credit:	Sean Heneghan		Oliver Kruse

*All-core non-AVX/AVX/AVX512 CPU frequency.

 

 

Multi-Processor Workstation/Servers:

 

Due to high core count and the effect of NUMA (Non-Uniform Memory Access), performance on multi-processor systems are extremely sensitive to various settings. Therefore, these benchmarks may not be entirely representative of what the hardware is capable of.

Processor(s):	Xeon E5-2683 v3	Xeon E5-2687W v4	Xeon E5-2696 v4	Xeon E7-8880 v3	Epyc 7601	Xeon Gold 6130F	Xeon Platinum 8124M
Generation:	Intel Haswell	Intel Broadwell	Intel Broadwell	Intel Haswell	AMD Naples	Intel Skylake Purley	Intel Skylake Purley
Sockets/Cores/Threads:	2/28/56	2/24/48	2/44/88	4/64/128	2/64/128	2/32/64	2/36/72
Processor Speed:	2.03 GHz	3.0 GHz	2.2 GHz	2.3 GHz	2.2 GHz	2.1 GHz	3.0 GHz
Memory:	128 GB - ???	64 GB	768 GB - ???	2 TB - ???	256 GB - ??	256 GB - ??	137 GB - ??
Program Version:	v0.6.9 ~ Airi	v0.7.4 ~ Kurumi	v0.7.1 ~ Kurumi	v0.7.1 ~ Airi	v0.7.3 ~ Yukina	v0.7.3 ~ Kotori	v0.7.5 ~ Kotori
Instruction Set:	x64 AVX2	x64 AVX2 + ADX	x64 AVX2 + ADX	x64 AVX2	x64 AVX2 + ADX	x64 AVX512-DQ	x64 AVX512-DQ
25,000,000	0.907	0.705	0.715	1.176	2.459	1.150	0.540
50,000,000	1.745	1.372	1.344	2.321	4.347	1.883	0.981
100,000,000	3.317	2.726	2.673	4.217	6.996	3.341	1.905
250,000,000	8.339	6.947	6.853	8.781	14.258	7.731	5.085
500,000,000	17.708	14.454	14.538	15.879	24.930	15.346	10.372
1,000,000,000	37.311	30.816	31.260	32.078	47.837	31.301	21.217
2,500,000,000	102.131	84.631	84.271	78.251	111.139	82.871	55.701
5,000,000,000	218.917	185.02	192.889	164.157	228.252	179.488	118.151
10,000,000,000	471.802	396.895	417.322	346.307	482.777	387.530	247.928
25,000,000,000	1,511.852	1,126.769	1,186.881	957.966	1,184.144	1,063.850
50,000,000,000		2,478.332	2,601.476	2,096.169
100,000,000,000			6,037.704	4,442.742
250,000,000,000				17,428.450
Credit:	Shigeru Kondo	Cameron Giesbrecht	"yoyo"	Jacob Coleman	Dave Graham		Jacob Coleman

Processor(s):	Xeon X5482		Xeon E5-2690
Generation:	Intel Penryn		Intel Sandy Bridge
Sockets/Cores/Threads:	2/8/8		2/16/32
Processor Speed:	3.2 GHz		3.5 GHz
Memory:	64 GB - 800 MT/s		256 GB - ???
Program Version:	v0.7.2 ~ Ushio	v0.7.5 ~ Nagisa	v0.6.2/3 ~ Hina
Instruction Set:	x64 SSE4.1		x64 AVX
25,000,000	4.548	4.248	2.283
50,000,000	9.779	9.148	4.295
100,000,000	20.834	19.580	8.167
250,000,000	60.049	56.226	20.765
500,000,000	134.978	126.448	42.394
1,000,000,000	308.679	286.903	89.920
2,500,000,000	874.588	824.820	239.154
5,000,000,000	1,946.683	1,836.808	520.977
10,000,000,000	4,317.677	4,000.065	1,131.809
25,000,000,000			3,341.281
50,000,000,000			7,355.076
Credit:			Shigeru Kondo

 

 

Fastest Times:

The full chart of rankings for each size can be found here:

• Rankings: 25m
• Rankings: 50m
• Rankings: 100m
• Rankings: 250m
• Rankings: 500m
• Rankings: 1b
• Rankings: 2.5b
• Rankings: 5b
• Rankings: 10b
• Rankings: 25b
• Rankings: 50b
• Rankings: 100b
• Rankings: 250b
• Rankings: 500b
• Rankings: 1t

These fastest times may include unreleased betas.

Got a faster time? Let me know: a-yee@u.northwestern.edu

Note that I usually don't respond to these emails. I simply put them into the charts which I update periodically.

 

 

Performance Tips:

 

Memory Bandwidth:

 

Because of the memory-intensive nature of computing Pi and other constants, y-cruncher needs a lot of memory bandwidth to perform well. In fact, the program has been noticably memory bound on nearly all high-end desktops since 2012 as well as the majority of multi-socket systems since at least 2006.

 

Recommendations:

• Make sure all memory channels are populated. This is by far the most important since bandwidth scales almost linearly with the # of channels.
• Run your memory at as high a frequency as possible to maximize bandwidth.
• Memory timings are usually less important. Long memory latencies are hidden away fairly well by Hyperthreading.
• On Skylake X processors, L3 cache bandwidth is also a bottleneck. So overclock the cache as much as possible.

Don't be surprised if y-cruncher exposes instabilities that other applications and stress-tests do not. y-cruncher is unusual in that it simultaneously places a heavy load on both the CPU and the entire memory subsystem.

 

 

 

Parallel Performance:

 

y-cruncher has a lot of settings for tuning parallel performance. By default, it makes a best effort to analyze the hardware and pick the best settings. But because of the virtually unlimited combinations of processor topologies, it's difficult for y-cruncher to optimally pick the best settings for everything. So sometimes the best performance can only be achieved with manual settings.

• Try both the Push Pool and Cilk Plus frameworks. While the Push Pool is faster in most cases, Cilk Plus may be better for extremely small computations as well as on machines with many (> 64) cores.*
• Experiment with larger task decomposition sizes. This may alleviate problems with load-imbalance.*
• On Windows, if the system has more than 64 logical cores, make sure node-interleaving is disabled in the BIOS. Otherwise, it would lead to imbalanced processor groups which will lead to load-imbalance.

*These are advanced settings that cannot be changed if you're using the benchmark option in the console UI. To change them, you will need to either run benchmark mode from the command line or use the custom compute menu.

 

Load imbalance is a faily common problem in y-cruncher. The usual causes are:

1. The number of logical cores is not a power-of-two.
2. The cores are not homogenous. Common reasons include:
   • The cores are clocked at different speeds.
   • The cores have access to different amounts of memory bandwidth due an imbalanced NUMA topology.
   • The cores are different generation cores hidden behind a virtual machine.
3. CPU-intensive background processes are interfering with y-cruncher's ability to use all the hardware. This applies to all forms of system jitter.

 

Swap Mode:

 

This is probably one of the most complicated features in y-cruncher.

• Read the guide so you know how to use it.
• Depending on the CPU capability of your system, chances are you will either need multiple NVMe SSDs or many hard drives to avoid bottlenecking on disk I/O.
• Don't use hardware or software RAID. y-cruncher usually does a better job if you let it manage each drive separately.
• Don't use SSDs if you care about their lifespan. y-cruncher can and will destroy SSDs if you sustain it long enough.

 

 

Known Issues:

 

Everything in this section is in the process of being re-verified and moved to: https://github.com/Mysticial/y-cruncher/issues

 

 

Performance Issues:

• Swap computations on the latest Ubuntu (15.10) and possibly everything else with the same kernel version have very poor performance in swap mode. This is because the OS does excessive and unnecessary disk swapping to the pagefile. The solution is to disable the swap file so that no paging is possible. It may also suffice to set the "swappiness" value to zero. y-cruncher will also attempt to lock pages in memory to prevent the OS from shooting itself with paging.

Algorithms and Developments:

• Algorithms and Internals
• Current and Future Developments

 

FAQ:

 

Pi and other Constants:

• Where can I download the digits for Pi and other constants that are featured in the various record computations?
• Can you search for XXX in the digits of Pi for me?
• Can you add support for more constants? I want to compute e^Pi, Khinchin, Glaisher, etc...

 

Hardware and Overclocking:

• My computer is completely stable. But I keep getting errors such as, "Redundancy Check Failed: Coefficient is too large".
• Why is y-cruncher so much slower on AMD processors than Intel processors?

 

Academia:

• Is there a version that can use the GPU?
• Why can't you use distributed computing to set records?
• Is there a distributed version that performs better on NUMA and HPC clusters?
• Why have recent Pi records used desktops instead of supercomputers?

 

Programming:

• What is the technical explanation for the notorious, "Coefficient is too large" error?
• Is there a publicly available library for the multi-threaded arithmetic that y-cruncher uses?
• Is y-cruncher open-sourced?

 

Program Usage:

• What's the difference between "Total Computation Time" and "Total Time"? Which is relevant for benchmarks?
• Why does y-cruncher need administrator privileges in Windows to run Swap Mode computations?
• Why is the performance so poor for small computations? The program only gets xx% CPU utilization on my xx core machine for small sizes!!!

 

Other:

• What about support for other platforms? Mac, ARM, etc...

 

Links:

Here's some interesting sites dedicated to the computation of Pi and other constants:

• Mathematical Constants and Computation
• Shigeru Kondo's Pi pages (dead)
• Stu's Pi page (dead)

 

Questions or Comments

Contact me via e-mail. I'm pretty good with responding unless it gets caught in my school's junk mail filter.