y-cruncher - A Multi-Threaded Pi-Program

From a high-school project that went a little too far...

By Alexander J. Yee

(Last updated: June 14, 2023)

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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.

Current Release:

Windows: Version 0.7.10 Build 9513 (Released: August 31, 2022)

Linux : Version 0.7.10 Build 9513 (Released: August 31, 2022)

Official Mersenneforum Subforum (new).

Official HWBOT forum thread.

News:

Upcoming Changes for v0.8.x: (June 7, 2023) - permalink

In an effort to clean up and modernize the project, most of the large multiply algorithms are getting either refreshed or removed. Algorithms that are useful on modern processors are getting redesigned and rewritten from scratch while the rest will be completely removed from the codebase.

The implication of this will be performance gains on newer processors and regressions on older processors.

If this sounds big, it is. More than 400,000 lines of code will be touched. Work actually began more than 3 years ago, but very little progress was made until this year where I'm on garden leave and therefore not working.

As of today, enough has been done to get some preliminary in-memory benchmarks:

Processor	Architecture		Clock Speeds	Binary	ISA	Pi computation Speedup vs. v0.7.10
Core i7 920	Intel Nehalem	2008	3.5 GHz + 3 x 1333 MT/s	08-NHM ~ Ushio	x64 SSE4.1	-27%
Core i7 3630QM	Intel Ivy Bridge	2012	stock + 2 x 1600 MT/s	11-SNB ~ Hina	x64 AVX	-10%
FX-8350	AMD Piledriver	2012	stock + 2 x 1600 MT/s	11-BD1 ~ Miyu	x64 FMA4	-1%
Core i7 5960X	Intel Haswell	2013	4.0 GHz + 4 x 2400 MT/s	13-HSW ~ Airi	x64 AVX2	3 - 4%
Core i7 6820HK	Intel Skylake	2015	stock + 2 x 2133 MT/s	14-BDW ~ Kurumi	x64 AVX2 + ADX	4 - 7%
Ryzen 7 1800X	AMD Zen 1	2017	stock + 2 x 2866 MT/s	17-ZN1 ~ Yukina	x64 AVX2 + ADX	~1%
Core i9 7900X	Intel Skylake X	2017	3.6 GHz (AVX512) + 4 x 3000 MT/s	17-SKX ~ Kotori	x64 AVX512-DQ	6 - 9%
Core i9 7940X	Intel Skylake X	2017	3.6 GHz (AVX512) + 4 x 3466 MT/s	17-SKX ~ Kotori	x64 AVX512-DQ	10 - 13%
Ryzen 9 3950X	AMD Zen 2	2019	stock + 2 x 3000 MT/s	19-ZN2 ~ Kagari	x64 AVX2 + ADX	13 - 14%
Core i3 8121U	Intel Cannon Lake	2018	stock + 2 x 2400 MT/s	18-CNL ~ Shinoa	x64 AVX512-VBMI	16 - 17%
Core i7 1165G7	Intel Tiger Lake	2020	stock + 2 x 2666 MT/s			12 - 22%
Core i7 11800H	Intel Tiger Lake	2020	stock + 2 x 3200 MT/s			23 - 27%
Ryzen 9 7950X	AMD Zen 4	2022	stock + 2 x 4400 MT/s	22-ZN4 ~ Kizuna	x64 AVX512-GFNI	23 - 31%

The loss of performance for the oldest processors is primarily due to the removal of the Hybrid NTT. Yes, the Hybrid NTT that started the entire y-cruncher project is now gone. While it was the fastest thing in 2008, it unfortunately did not age very well. Stay tuned for a future blog about the algorithm. It will no longer be a secret.

Overall, there is still a lot of work to do. For example, swap-mode is still using the old implementations and will need to be revamped as well. But since the new code has reached or exceeded performance parity for the chips I care about, this is a good stopping point for v0.8.1 pending testing and validation.

Nevertheless, the benchmarks above are not final and are subject to change. Specifically, there are unresolved toolchain issues where Intel is removing their old compiler while its replacement is still significantly worse. And it's unclear whether it can be fixed before it is no longer possible to keep using their old compiler.

A big unknown is how stress-testing will be affected. Despite not being designed for this purpose, y-cruncher's stress-test is notorious for its ability to expose memory instabilities that other (even dedicated) memory testing applications cannot. In other words, it is one of the best memory testers out there. But with so much stuff being rewritten, there's no telling how this will change. Nevertheless, it doesn't make a whole lot of sense to keep around hundreds of thousands of lines of old code if turns out to be the better stress test.

So yeah... Out with the old and in with the new. Expect to see Zen 4 gaining up to 20% speedup with AVX512 vs. just AVX2 - no wider execution units needed.

The Need for Speed!: (April 19, 2023) - permalink

Jordan Ranous from StorageReview has just flexed a system that matched Google's 100 trillion digit world record in just 59 days. You can read more about it here:

I'm not sure if Google's record used SSDs or hard drives, but if the latter, this would be the first large computation done entirely on SSDs.

It's probably safe to say that since StorageReview is able to match the world record in a fraction of the time, they are more than capable of beating it. So everyone else better watch out!

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:
May 13, 2023	May 13, 2023		Jordan Ranous & Kevin O'Brien	Euler-Mascheroni Constant	700,000,000,000	Compute: 8.80 days Verify: 6.95 days	2 x AMD Epyc 9654 @ 2.4 GHz 1.5 TB
July 17, 2022	July 15, 2022		Seungmin Kim	Lemniscate	1,200,000,000,100	Compute: 32.2 days Verify: 46.5 days	2 x Intel Xeon Gold 6140 @ 2.30 GHz 377 GB
June 8, 2022	March 21, 2022		Emma Haruka Iwao	Pi	100,000,000,000,000	Compute: 158 days Verify: 12.6 hours Validation File	128 vCPU Intel Ice Lake (GCP) 864 GB 663 TB storage
March 14, 2022	March 9, 2022		Seungmin Kim	Catalan's Constant	1,200,000,000,100	Compute: 48.6 days Verify: 47.3 days	2 x Intel Xeon Gold 6140 @ 2.30 GHz 2 x Intel Xeon E5-2680 v3 @ 2.50 GHz
January 5, 2022	November 12, 2021		Tizian Hanselmann	Square Root of 2	10,000,000,001,000	Compute: 18.4 days Verify: 18.5 days	Intel Xeon E7-4870 @ 2.4 GHz 896 GB
October 4, 2021	September 30, 2021		Chris Danneil	Zeta(5)	200,000,000,000	Compute: 28.2 days Verify: 33.0 days	Intel Xeon E5-268v4 @ 2.1 GHz 256 GB
October 4, 2021	September 9, 2021		William Echols	Log(2)	1,500,000,000,000	Compute: 98.9 days Verify: 61.7 days	2 x Intel Xeon E5-2690 v3 @ 2.6 GHz 256 GB
August 17, 2021	August 14, 2021	Source	UAS Grisons	Pi	62,831,853,071,796	Compute: 108 days Verify: 34.4 hours	AMD Epyc 7542 @ 2.9 GHz 1 TB 34 + 4 Hard Drives
February 14, 2021	February 12, 2021		Clifford Spielman	Golden Ratio	10,000,000,000,000	Compute: 14.3 days Verify: 7.40 days	AMD Threadripper 3995WX @ 2.7 GHz 512 GB
December 5, 2020	November 22, 2020		David Christle	e	31,415,926,535,897	Compute: 53.8 days Verify: 46.0 days	2 x Intel Xeon E5-2680 v2 @ 2.8 GHz 252 GB
September 13, 2020	September 6, 2020		Seungmin Kim	Log(10)	1,200,000,000,100	Compute: 14.5 days Verify: 22.5 days	2 x Intel Xeon E5-2699 v3 @ 2.3 GHz 756 GB 2 x Intel Xeon Gold 5220 @ 2.2 GHz 754 GB
August 9, 2020	July 26, 2020		Seungmin Kim	Zeta(3) - Apery's Constant	1,200,000,000,100	Compute: 31.7 days Verify: 32.6 days	2 x Intel Xeon E5-2670 v3 @ 2.3 GHz 503 GB 2 x Intel Xeon Gold 5220 @ 2.2 GHz 754 GB
August 9, 2020	July 23, 2020		Andrew Sun	Gamma(1/3)	500,000,001,337	Compute: 17.3 days Verify: 4.07 days	2 x Intel Xeon E5-2690 v4 @ 2.6 GHz 315 GB
June 28, 2020	June 22, 2020		Seungmin Kim	Zeta(3) - Apery's Constant	1,200,000,000,000	Compute: 31.7 days *Not Verified*	2 x Xeon E5-2670 v3 @ 2.3 GHz 503 GB
June 28, 2020	May 27, 2020		Andrew Sun	Gamma(1/4)	500,000,000,000	Compute: 20.0 days Verify: 14.9 days	2 x Intel Xeon E5-2690 v4 @ 2.6 GHz 315 GB
January 29, 2020	January 29, 2020	Blog	Timothy Mullican	Pi	50,000,000,000,000	Compute: 303 days Verify: 17.2 hours Validation File	4 x Intel Xeon E7-4880 v2 @ 2.5 GHz 315 GB 48 Hard Drives
December 4, 2019	November 13, 2019		Christophe Patris de Broe & Alexandre Gouy & Cyril Hsu	Golden Ratio	20,000,000,000,000	Compute: 6.94 days *Not Verified*	2 x Intel Xeon Platinum 8268 @ 2.9 GHz 768 GB
October 21, 2019	October 17, 2019		Marco Julian Hummel	Gamma(1/3)	274,877,906,944	Compute: 11.2 days Verify: 30.7 days	2 x Intel Xeon E5-2651 v2 @ 1.8 GHz 192 GB
March 14, 2019	January 21, 2019	Blogs 1 + 2	Emma Haruka Iwao	Pi	31,415,926,535,897	Compute: 121 days Verify: 20.0 hours Validation File	2 x Undisclosed Intel Xeon @ 2.00 GHz > 1.40 TB DDR4 > 240 TB SSD
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
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
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 want to set a record yourself, the rules are in that link.

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:

Sample Screenshot: 1 trillion digits of Pi

Core i7 5960X @ 4.0 GHz - 64 DDR4 @ 2400 MHz - 16 HDs

Latest Releases: (August 31, 2022)

Downloading any of these files constitutes as acceptance of the license agreement.

OS Download Link Size

Windows

y-cruncher v0.7.10.9513.zip
45.1 MB

Linux (Static)

y-cruncher v0.7.10.9513-static.tar.xz
34.1 MB

Linux (Dynamic)

y-cruncher v0.7.10.9513-dynamic.tar.xz
28.0 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 7 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 22.04.

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:

Other Downloads (for C++ programmers):

Advanced Documentation:

Benchmarks:

Comparison Chart: (Last updated: May 13, 2023)

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.

Purple: Benchmarks are from unreleased internal builds that are not speed comparable with the current release.

Laptops + Low-Power:

Processor(s):	Core i7 8565U	Core i7 9750H	Core i7 1065G7		Core i7 1065G7	Core i7 1165G7	Core i9 11900KB
Generation:	Intel Kaby Lake R	Intel Coffee Lake	Intel Ice Lake		Intel Ice Lake	Intel Tiger Lake	Intel Tiger Lake
Cores/Threads:	4/8	6/12	4/8		4/8	4/8	8/16
Processor Speed:	2.3 - 4.6 GHz	3.1 - 3.9 GHz	2.1 - 3.0 GHz (25W)		???	3.6 - 4.0 GHz (45W)	3.3 - 4.5 GHz
Memory:	8 GB	16 GB - 2666 MT/s	16 GB @ 3200 MT/s		16 GB @ 3733 MT/s	32 GB @ 3200 MT/s	32 GB @ 3200 MT/s
Version:	v0.7.8 (14-BDW)	v0.7.8 (14-BDW)	v0.7.7 (18-CNL)		v0.7.8 (18-CNL)	v0.7.8 (18-CNL)	v0.7.8 (18-CNL)
Instruction Set:	x64 AVX2 + ADX	x64 AVX2 + ADX	x64 AVX512-DQ	x64 AVX512-VBMI	x64 AVX512-VBMI	x64 AVX512-VBMI	x64 AVX512-VBMI
25,000,000	1.584	1.463	1.596	1.243	1.046	0.868	0.575
50,000,000	3.523	3.123	3.552	2.718	2.318	1.825	1.301
100,000,000	7.837	6.585	7.903	5.870	5.150	3.888	2.866
250,000,000	23.336	18.378	22.520	16.531	14.745	10.813	7.997
500,000,000	54.403	40.028	50.683	37.778	32.856	23.769	17.560
1,000,000,000	127.177	87.298	114.539	85.426	73.918	52.930	38.525
2,500,000,000		251.637	332.819	249.579	222.515	156.696	111.600
5,000,000,000						348.512	247.368
10,000,000,000
Credit:		ji lcpd	ji lcpd		Gnyueh	ji lcpd	ji lcpd

Processor(s):	Core i7 3630QM	Core i7 4610M	*Core i3 8121U (Windows)**			Core i7 6560U	Core i7 6700HQ
Generation:	Intel Ivy Bridge	Intel Haswell	Intel Cannon Lake			Intel Skylake	Intel Skylake
Cores/Threads:	4/8	2/4	2/4			4/8	4/8
Processor Speed:	3.2 GHz	3.0 GHz	2.6 - 3.0 GHz	2.6 - 3.0 GHz	2.4 - 2.9 GHz	2.21 GHz	2.6 GHz ?
Memory:	16 GB - 1600 MT/s	8 GB	8 GB			8 GB	16 GB
Version:	v0.7.8 (11-SNB)	v0.7.8 (13-HSW)	v0.7.8 (14-BDW)	v0.7.8 (17-SKX)	v0.7.8 (18-CNL)	v0.7.8 (14-BDW)	v0.7.8 (14-BDW)
Instruction Set:	x64 AVX	x64 AVX2	x64 AVX2 + ADX	x64 AVX512-DQ	x64 AVX512-VBMI	x64 AVX2 + ADX	x64 AVX2 + ADX
25,000,000	3.688	3.372	2.984	2.685	2.189	3.165	2.140
50,000,000	8.460	7.634	6.795	6.079	4.879	7.212	4.634
100,000,000	18.817	17.037	15.173	13.654	10.725	16.008	10.168
250,000,000	56.097	48.912	45.801	41.775	31.268	46.491	29.298
500,000,000	129.173	109.82	106.192	97.429	75.072	105.889	65.509
1,000,000,000	302.003	244.751	241.978	222.909	170.715	233.860	144.395
2,500,000,000	848.475						429.748
5,000,000,000
10,000,000,000
Credit:	Oliver Kruse	Marco Julian Hummel				Sebastien Davies	Marco Julian Hummel

Mainstream Desktops:

Processor(s):	Core i9 11900K	Ryzen 9 3950X	Ryzen 9 5950X	Core i9 12900K	Core i9 13900K	Ryzen 9 7950X
Generation:	Intel Rocket Lake	AMD Zen 2	AMD Zen 3	Intel Alder Lake	Intel Raptor Lake	AMD Zen 4
Cores/Threads:	8/16	16/32	16/32	8/16 + 8/8	8/16 + 8/8	16/32
Processor Speed:	5.3 GHz			5.1 GHz	5.6 GHz / 4.4 GHz
Memory:	64 GB - 3733 MT/s	64 GB - 3200 MT/s	64 GB	64 GB - 6400 MT/s	64 GB - 7200 MT/s	128 GB - 4400 MT/s
Program Version:	v0.7.8 (18-CNL)	v0.7.8 (17-ZN1)	v0.7.8 (19-ZN2)	v0.7.9 (14-BDW)	v0.7.9 (14-BDW)	v0.7.10 (22-ZN4)
Instruction Set:	x64 AVX512-VBMI	x64 AVX2 + ADX	x64 AVX2 + ADX	x64 AVX2 + ADX	x64 AVX2 + ADX	x64 AVX512-GFNI
25,000,000	0.461	0.701	0.559	0.399	0.282	0.434
50,000,000	1.027	1.422	1.171	0.744	0.581	0.901
100,000,000	2.223	2.870	2.403	1.622	1.260	1.875
250,000,000	6.350	7.279	6.162	4.529	3.543	4.953
500,000,000	14.133	15.037	12.725	9.930	7.908	10.620
1,000,000,000	31.235	32.306	27.277	21.550	17.482	23.431
2,500,000,000	91.316	91.836	77.652	61.097	49.712	65.561
5,000,000,000	202.208	204.570	171.633	134.698	110.268	144.664
10,000,000,000	447.487	460.548	382.39		242.129	317.490
25,000,000,000						914.088
Credit:	O-EtaIXVII	Marc Beste	Sebastien Davies	曾铮	曾铮

Processor(s):	FX-8350	Core i7 4770K	Core i7 7700K	Ryzen 7 1800X	Ryzen 7 3700X	Ryzen 7 5800X3D
Generation:	AMD Piledriver	Intel Haswell	Intel Kaby Lake	AMD Zen	AMD Zen 2	AMD Zen 3
Cores/Threads:	8/8	4/8	4/8	8/16	8/16	8/16
Processor Speed:	4.0 GHz	4.0 GHz (OC)	4.9 GHz (OC)	3.7 GHz	4.3 GHz
Memory:	32 GB - 1600 MT/s	32 GB - 2133 MT/s	64 GB - 3200 MT/s	64 GB - 2866 MT/s	64 GB - 3600 MT/s	32 GB
Program Version:	v0.7.8 (11-BD1)	v0.7.8 (13-HSW)	v0.7.8 (14-BDW)	v0.7.8 (17-ZN1)	v0.7.8 (17-ZN1)	v0.7.9 (20-ZN3)
Instruction Set:	x64 AVX + XOP	x64 AVX2	x64 AVX2 + ADX	x64 AVX2 + ADX	x64 AVX2 + ADX	x64 AVX2 + ADX
25,000,000	3.070	1.482	1.149	1.247	0.681	0.580
50,000,000	6.845	3.396	2.489	2.623	1.427	1.220
100,000,000	15.130	7.385	5.482	5.655	2.975	2.693
250,000,000	43.077	20.610	15.419	16.053	8.135	7.435
500,000,000	96.327	45.964	33.986	35.607	17.666	16.713
1,000,000,000	214.870	101.692	74.021	78.961	39.007	36.338
2,500,000,000	623.521	292.899	209.412	226.557	112.849	104.964
5,000,000,000	1,384.689	643.534	451.414	498.824	250.157	232.368
10,000,000,000			966.710	1,084.855	549.067
25,000,000,000
Credit:			Oliver Kruse		Sebastien Davies	Marc Beste

High-End Desktops:

Processor(s):	Core i9 9980XE	Core i9 10980XE	Threadripper 3955WX	Threadripper 3970X		Threadripper 3990X
Generation:	Intel Skylake X	Intel Cascade Lake X	AMD Zen 2	AMD Zen 2		AMD Zen 2
Cores/Threads:	18/18	18/36	16/32	32/64		64/128
Processor Speed:		2.8 GHz	3.9 GHz	3.7 GHz		4.0 GHz (OC)
Memory:	128 GB - 3600 MT/s	128 GB - 3600 MT/s	512 GB - 3200 MT/s	64 GB		256 GB - 3200 MT/s
Program Version:	v0.7.8 (17-SKX)	v0.7.8 (17-SKX)	v0.7.8 (19-ZN2)	v0.7.8 (17-ZN1)	v0.7.8 (19-ZN2)	v0.7.8 (19-ZN2)
Instruction Set:	x64 AVX512-DQ	x64 AVX512-DQ	x64 AVX2 + ADX	x64 AVX2 + ADX	x64 AVX2 + ADX	x64 AVX2 + ADX
25,000,000	0.262	0.394	0.531	0.458	0.431	0.694
50,000,000	0.556	0.837	1.070	0.910	0.890	1.011
100,000,000	1.203	1.814	2.015	1.763	1.734	2.203
250,000,000	3.492	4.885	5.072	4.258	4.070	5.618
500,000,000	7.703	10.198	10.423	8.699	7.896	10.474
1,000,000,000	16.923	21.633	22.386	18.427	15.939	21.872
2,500,000,000	48.896	59.536	63.115	50.338	44.058	54.171
5,000,000,000	108.179	129.954	138.574	109.537	95.645	116.739
10,000,000,000	236.789	282.091	304.391	237.537	208.484	245.579
25,000,000,000	675.992	799.543	846.597			682.885
50,000,000,000			1,960.563			1672.776
100,000,000,000			4,450.366
Credit:	Shigeru Kondo	ji lcpd	Michael Makovi	Tainus		Bennet Huch

Processor(s):	Core i7 5960X	Threadripper 1950X	Core i9 7940X
Generation:	Intel Haswell	AMD Threadripper	Intel Skylake X
Cores/Threads:	8/16	16/32	14/28
Processor Speed:	4.0 GHz (OC)	3.5 - 3.7 GHz	3.8 GHz	3.6 GHz
Processor Speed:	4.0 GHz (OC)	3.5 - 3.7 GHz	2.8 GHz cache
Memory:	64 GB - 2133 MT/s	128 GB - 2933 MT/s	128 GB - 3466 MT/s
Program Version:	v0.7.8 (13-HSW)	v0.7.8 (17-ZN1)	v0.7.8 (14-BDW)	v0.7.8 (17-SKX)
Instruction Set:	x64 AVX2	x64 AVX2 + ADX	x64 AVX2 + ADX	x64 AVX512-DQ
25,000,000	0.853	0.721	0.503	0.482
50,000,000	1.769	1.500	1.090	0.994
100,000,000	3.828	3.173	2.407	1.974
250,000,000	10.807	8.666	6.575	5.145
500,000,000	23.523	18.926	14.026	10.791
1,000,000,000	51.930	41.762	29.989	22.974
2,500,000,000	149.081	119.06	84.231	64.586
5,000,000,000	326.022	264.191	189.510	143.051
10,000,000,000	713.146	572.900	410.372	316.622
25,000,000,000		1642.184	1,185.891	903.586
50,000,000,000
Credit:		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 Platinum 8124M	Xeon Gold 6148	Xeon Platinum 8175M	Xeon Platinum 8275CL	Epyc 7742	Epyc 7B12	Epyc 7742
Generation:	Intel Skylake Purley	Intel Skylake Purley	Intel Skylake Purley	Intel Cascade Lake	AMD Rome	AMD Rome	AMD Rome
Sockets/Cores/Threads:	2/36/72	2/40/40	2/48/96	2/48/96	2/128/256	2/112/224	2/128/256
Processor Speed:	3.0 GHz	2.4 GHz	2.5 GHz	3.0 GHz		2.25 GHz	2.25 GHz
Memory:	137 GB - ??	188 GB - ??	~756 GB - ??	192 GB	~504 GB	~882 GB	2 TB
Program Version:	v0.7.5 (17-SKX)	v0.7.6 (17-SKX)	v0.7.6 (17-SKX)	v0.7.8 (17-SKX)	v0.7.7 (17-ZN1)	v0.7.8 (19-ZN2)	v0.7.8 (19-ZN2)
Instruction Set:	x64 AVX512-DQ	x64 AVX512-DQ	x64 AVX512-DQ	x64 AVX512-DQ	x64 AVX2 + ADX	x64 AVX2 + ADX	x64 AVX2 + ADX
25,000,000	0.540	0.329	0.294	0.283	0.534	0.439	0.513
50,000,000	0.981	0.683	0.617	0.544	1.027	0.838	0.920
100,000,000	1.905	1.456	1.305	1.169	2.298	1.796	1.887
250,000,000	5.085	3.737	3.591	3.125	5.854	4.509	4.650
500,000,000	10.372	7.750	7.293	6.309	10.502	8.196	8.066
1,000,000,000	21.217	16.550	15.041	13.042	17.836	14.252	13.246
2,500,000,000	55.701	45.693	39.329	34.028	35.485	30.592	27.011
5,000,000,000	118.151	99.078	83.601	71.777	62.432	58.405	49.940
10,000,000,000	247.928	212.984	176.695	153.169	115.543	116.900	98.156
25,000,000,000		599.653	491.988	425.442	307.995	314.907	258.081
50,000,000,000			1,081.181		690.662	741.633	598.716
100,000,000,000						1715.123	1,370.714
250,000,000,000							3,872.397
Credit:	Jacob Coleman	Oliver Kruse	newalex	Xinyu Miao	Carsten Spille	Greg Hogan	Song Pengei

Processor(s):	Xeon E5-2683 v3	Xeon E7-8880 v3	Xeon E5-2687W v4	Xeon E5-2686 v4	Xeon E5-2696 v4	Epyc 7601	Xeon Gold 6130F
Generation:	Intel Haswell	Intel Haswell	Intel Broadwell	Intel Broadwell	Intel Broadwell	AMD Naples	Intel Skylake Purley
Sockets/Cores/Threads:	2/28/56	4/64/128	2/24/48	2/36/72	2/44/88	2/64/128	2/32/64
Processor Speed:	2.03 GHz	2.3 GHz	3.0 GHz	2.3 GHz	2.2 GHz	2.2 GHz	2.1 GHz
Memory:	128 GB - ???	2 TB - ???	64 GB	504 GB - ???	768 GB - ???	256 GB - ??	256 GB - ??
Program Version:	v0.6.9 (13-HSW)	v0.7.1 (13-HSW)	v0.7.6 (14-BDW)	v0.7.7 (14-BDW)	v0.7.1 (14-BDW)	v0.7.3 (17-ZN1)	v0.7.3 (17-SKX)
Instruction Set:	x64 AVX2	x64 AVX2	x64 AVX2 + ADX	x64 AVX2 + ADX	x64 AVX2 + ADX	x64 AVX2 + ADX	x64 AVX512-DQ
25,000,000	0.907	1.176	0.490	0.494	0.715	2.459	1.150
50,000,000	1.745	2.321	1.072	0.982	1.344	4.347	1.883
100,000,000	3.317	4.217	2.303	2.193	2.673	6.996	3.341
250,000,000	8.339	8.781	6.196	6.044	6.853	14.258	7.731
500,000,000	17.708	15.879	13.046	12.582	14.538	24.930	15.346
1,000,000,000	37.311	32.078	27.763	26.852	31.260	47.837	31.301
2,500,000,000	102.131	78.251	76.202	73.596	84.271	111.139	82.871
5,000,000,000	218.917	164.157	165.046	160.094	192.889	228.252	179.488
10,000,000,000	471.802	346.307	356.487	346.305	417.322	482.777	387.530
25,000,000,000	1,511.852	957.966	1,006.131	980.784	1,186.881	1,184.144	1,063.850
50,000,000,000		2,096.169	2,202.558	2,156.854	2,601.476
100,000,000,000		4,442.742			6,037.704
250,000,000,000		17,428.450
Credit:	Shigeru Kondo	Jacob Coleman	Cameron Giesbrecht	newalex	"yoyo"	Dave Graham

Fastest Times:

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

These fastest times may include unreleased betas.

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

Note that I usually do not respond to these emails. I simply put them into the charts which I update periodically (typically within 2 weeks).

Performance Tips:

Decimal Digits of Pi - Times in Seconds Core i9 7940X @ 3.7 GHz AVX512
Memory Frequency:	2666 MT/s	3466 MT/s
25,000,000	0.839	0.758
50,000,000	1.424	1.338
100,000,000	2.701	2.425
250,000,000	6.489	5.877
500,000,000	13.307	11.917
1,000,000,000	27.913	24.915
2,500,000,000	76.837	68.322
5,000,000,000	168.058	148.737
10,000,000,000	365.047	322.115
25,000,000,000	1,037.527	916.039

High core count Skylake X processors are known to be heavily bottlenecked by memory bandwidth.

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:

The number of logical cores is not a power-of-two.
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.
CPU-intensive background processes are interfering with y-cruncher's ability to use all the hardware. This applies to all forms of system jitter.

Large Pages:

Large pages used to not matter in the past, but they do now in the post-Spectre/Meltdown world. Mitigations for the Meltdown vulnerability can have a noticeable performance drop for y-cruncher (up to 5% has been observed). It turns out that turning on large pages can mitigate the penalty for this mitigation. (pun intended)

Refer to the memory allocation guide on how to turn on large pages.

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:

FAQ:

Pi and other Constants:

Program Usage:

Hardware and Overclocking:

Academia:

Programming:

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:

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.

You can also find me on Twitter as @Mysticial.

OS	Download Link	Size
Windows	y-cruncher v0.7.10.9513.zip	45.1 MB
Linux (Static)	y-cruncher v0.7.10.9513-static.tar.xz	34.1 MB
Linux (Dynamic)	y-cruncher v0.7.10.9513-dynamic.tar.xz	28.0 MB

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

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Sample Screenshot: 1 trillion digits of Pi

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