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

Announcing 5 trillion digits of Pi!
New World Record for both Desktop and Supercomputer!!!

 

(Last updated: September 4, 2010)

 

 

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

 

Against the Big Guns...

Faster than SuperPi on single-core...

Faster than PiFast 4.3 on dual-core...

Faster than QuickPi 4.5 on quad-core...

 

1 billion digits of Pi in 5 minutes on 6-core Core i7 @ 4.26 GHz

 

See the official XtremeSystems thread for more benchmarks.

 

Latest Version:

Windows: Version 0.5.4 Build 9148 (fix 1) (Released: August 5, 2010)

Linux      : Version 0.5.4 Build 9157 (fix 1) (Released: August 28, 2010)

 

 

Changes to v0.5.4.9157 for Linux

• Added most of the features that were in the Windows version, but missing from the Linux version.
  • Colored console output.
  • CPU Type Detection
  • CPU Frequency Detection
  • Memory Detection
  • Automatic Memory Selection for Advanced Swap Mode

 

Starting from v0.5.2, y-cruncher allows Pi computations of up to 10 trillion digits.

However, y-cruncher has only been tested up to 5 trillion digits. (Credit: Shigeru Kondo)

 

Records Set by y-cruncher:

World Record Size Computations

Date Announced	Date Completed:	Source:	Who:	Constant:	Decimal Digits:	Time:	Computer:
August 2, 2010	August 2, 2010	Source	Shigeru Kondo & Alexander Yee	Pi	5,000,000,000,000	Compute:  90 days Verify:  64 hours	2 x Intel Xeon X5680 @ 3.33 GHz 96 GB DDR3 @ 1066 MHz 16 x 2 TB
July 8, 2010	July 8, 2010	Source	Alexander Yee	Golden Ratio	1,000,000,000,000	Compute:  114 hours (4.7 days) Verify:  ~7 days* *Not a continuous run.	"Nagisa" 2 x Intel Xeon X5482 @ 3.2 GHz 64 GB DDR2 FB-DIMM 1.5 TB (Boot + Output) 4 x 1 TB (2 x 2 RAID0) + 6 x 2 TB
July 5, 2010	July 5, 2010	Source	Shigeru Kondo	e	1,000,000,000,000	Compute: 224 hours (9.3 days) Verify: 219 hours (9.1 days)	Intel Core i7 980X @ 3.33 GHz 12 GB DDR3 2 TB (Boot + Output) 8 x 1 TB (Computation)
March 22, 2010	March 22, 2010	Source	Shigeru Kondo	Square Root of 2	1,000,000,000,000	Compute:  193 hours (8.0 days) Verify:  98 hours (4.1 days)	Core i7 975 @ 4 GHz - 12GB 8 x 1 TB HDs 2 x Xeon W5590 - 144GB 16 x 2 TB HDs
February 21, 2010	February 20, 2010	Source	Alexander Yee	e	500,000,000,000	Compute and Verify: 307 hours (12.8 days)	"Ushio"
April 16, 2009	April 16, 2009	Source	Alexander Yee & Raymond Chan	Catalan's Constant	31,026,000,000	Compute:  178 hours (7.4 days) Verify:  221 hours (9.2 days)	"Nagisa"
March 13, 2009	March 13, 2009	Source	Alexander Yee & Raymond Chan	Euler-Mascheroni Constant	29,844,489,545	Compute:  205 hours (8.5 days) Verify:  269 hours (11.2 days)	"Nagisa"
	February 28, 2009	Source	Alexander Yee & Raymond Chan	Log(10)	31,026,000,000	Compute and Verify: 40 hours (1.7 days)	"Nagisa"
	February 15, 2009	Source	Alexander Yee & Raymond Chan	Zeta(3) - Apery's Constant	31,026,000,000	Compute:  45 hours (1.9 days) Verify:  44 hours (1.8 days)	"Nagisa"
	February 4, 2009	Source	Alexander Yee & Raymond Chan	Log(2)	31,026,000,000	Compute:  24 hours, 10 minutes Verify:  15 hours, 58 minutes	"Nagisa"
Janurary 31, 2009	January 31, 2009	Source	Alexander Yee & Raymond Chan	Catalan's Constant	15,510,000,000	Compute:  88 hours (3.7 days) Verify:  100 hours (4.2 days)	"Nagisa"
Janurary 21, 2009	January 21, 2009	Source	Alexander Yee & Raymond Chan	Zeta(3) - Apery's Constant	15,510,000,000	Compute:  20 hours, 18 minutes Verify:  21 hours, 1 minute	"Nagisa"
Janurary 18, 2009	January 18, 2009	Source	Alexander Yee & Raymond Chan	Euler-Mascheroni Constant	14,922,244,771	Compute:  96 hours (4 days) Verify:  134 hours (5.5 days)	"Nagisa"
	January 7, 2009	Source	Alexander Yee & Raymond Chan	Log(2)	15,500,000,000	Compute:  12 hours, 34 minutes Verify:  8 hours, 20 minutes	"Nagisa"

Note that starting from v0.5.2, the computation limits of the program are no longer locked below the current world records. So barring any bugs, anyone with sufficient resources will be able to break these records.

The Storyline:

2005 - 2006:

The roots of y-cruncher date all the way back to my senior year in high school in my AP Computer Science class.

It started from a class project which was to write a multi-precision arithmetic library in Java that would support addition, subtraction, multiplication, and division.
After the assignment was due, I continued working on the library and named it "BigNumber". Some of the new features that were added were square roots, trig-functions, constants, etc...

 

June - October 2006:

After graduation, I began to take speed seriously. Multiplication was completely rewritten in C and linked back to BigNumber using JNI. This was around the time that I began to realize that parts of "BigNumber" were fairly fast - comparable to Mathematica. In particular, the function for computing the Euler-Mascheroni Constant was faster than that of Mathematica 5. By October, it came to realization that the world record of 108 million digits for the Euler-Mascheroni Constant was in reach.

 

November 2006:

With the goal of breaking the world record of 108 million digits for Euler's Constant in mind, November was spent entirely on implementing and optimizing the algorithms needed for extremely high precision arithmetic. I also upgraded my laptop from 512MB to 1.5GB of ram as that would be the computer that I would use for such a computation.

 

December 2006:

Finals week and with winter break approching, BigNumber was used to compute 116 million digits of Euler's Constant on my laptop for what appeared to be a new world record. The computation ran for 38.5 hours and the verification ran for 48 hours. It required 1.8 GB of memory.

 

Early 2007:

Lots of media attention... As well as a lot of hate mail saying that it was not a world record. (S. Kondo and S. Pagliarulo already had 2 billion digits, but they hadn't announced it.)

During this time I also made a number of minor improvements to BigNumber. Though all work was pretty much halted by April because of the release of a number of new video games.

 

Sometime between November - December 2007:

In the middle of one of my boring lecture classes - Lightbulb!!! The Hybrid NTT algorithm for multiplication was born. This effectively renewed my interest in this area.

 

2008:

BigNumber was rewritten from scratch in C++ and renamed y-cruncher.

("y" is gamma, the symbol for the Euler-Mascheroni Constant - but I still pronounce it as "y")

 

Click to expand this section. (Warning: technical terminology)

 

January 2009 (back from winter break):

With Nagisa back up and running, Raymond and I managed to break the world records for Log(2) and the Euler-Mascheroni Constant. (Main Article)

And with that, we released the first public version of y-cruncher.

 

By the end of the month, we had also taken the world records for Apery's Constant and Catalan's Constant.

No celebration though, since neither of us could legally drink yet...

 

 

Current:

Currently, y-cruncher is just a mere side-hobby. I no longer work on it as much as I did in 2008 - not even close by a long-shot.

Gaming and school-work now take priority.

 

The build numbers were started when the rewrite began back in January 2008. During the 9 months of active development before the first public release, there were 6000 builds. But during the 6 active months of development from January to October 2009, there were fewer than 1700 builds. (Again no work was done over the summer because of internship.)

 

Features:

• Computes Pi and other constants.
• Capable of computing trillions of digits of Pi (among other constants).
• Faster than PiFast 4.3 and QuickPi 4.5 when two or more cores are present.
• Two algorithms are available for each major constant. One for computation and one for verification. (great for stress-testing)
• Extremely efficient even for large computations (> 1 billion digits).
• Swap Space management for large computations that require more memory than there is available.
• Multi-Threaded - Multi-threading can be used to fully utilize modern multi-core processors without significantly increasing memory usage.
  For large computations, it scales almost linearly with the # of cores.
• Multi-Hard Drive - Multiple hard drives can be used for faster disk swapping. (scales linearly - as fast as hardware Raid 0, with no limit to the # of drives)
• Semi-Fault Tolerant - Able to detect and correct for minor errors that may be caused by hardware instability or software bugs.

Aside from computing π and other constants, y-cruncher is great for stress testing 64-bit systems with lots of ram.

Download:

Windows: y-cruncher v0.5.4.9148 (fix 1).zip (7.15 MB)
Linux      : y-cruncher v0.5.4.9157 (fix 1) (x64 SSE3 - Linux).out (1.91 MB)

 

System Requirements:

• Windows XP or Windows Server 2000 or later.
• Users running Windows Vista or earlier may need to install one of the following updates:
  
  Microsoft C++ 2008 Redistributable Package (x86)
  Microsoft C++ 2008 Redistributable Package (x64)

   

• For Linux, x64 and SSE3 are required to run y-cruncher.

Click here for older versions.

Please do not link directly to the file downloads as there may be newer versions.
Just link to http://www.numberworld.org/y-cruncher/#Download instead. Thanks!

 

 

 

 

 

 

 

 

Performance:

y-cruncher is the first efficient and publicly available Pi-calculator that can sustain a near 100% cpu load on multi-core computers.
There are other multi-threaded Pi-programs that can achieve high cpu usage, but few of them can sustain it through an entire Pi computation.

 

Below is a typical CPU utilization graph of y-cruncher when computing 1 billion digits of Pi across 8 cores.

 

y-cruncher uses less memory than most other Pi-programs. It is also able to multi-thread WITHOUT significantly increasing memory usage.

 

Benchmarks:

Comparison Chart: (Last updated: June 9, 2010)

 

All times in seconds.

All benchmarks were done using the fastest binary with the fastest achieved settings for the system they were run on.

v0.5.3 and v0.5.4 are exactly the same speed. So results are directly comparable.

Number of Digits	Core 2 Quad (8 MB cache) 2.4 GHz	Phenom II X4 3.2 GHz1	Core i7 2.67 GHz2	Core i7 4.0 GHz3	4 x Opteron (Barcelona) 2.31 GHz4	2 x Xeon (Harpertown) 3.2 GHz	2 x Xeon (Westmere-EP) 3.33 GHz5
	v0.5.3	v0.5.4	v0.5.4	v0.5.4	v0.5.3	v0.5.4	v0.5.3
1,000,000	0.566		0.390	0.259		0.353
10,000,000	5.286		3.667	2.466		3.371
100,000,000	68.95		43.60	29.53	35.09	30.81	16.29
1,000,000,000	990.0		619.4	424.3	468.1	395.9	202.5
10,000,000,000						5,339	2,721

¹This was actually a 2.8 GHz Phenom II X3. It was unlocked to 4 cores and then overclocked to 3.2 GHz. Credit to Raymond Chan.

²Intel Turbo Boost Technology increases actual operating frequency to 2.8 GHz.

³Overclocked from 2.67 GHz. Actual operating frequency after Turbo Boost is 4.2 GHz.

⁴Credit to skycrane from XtremeSystems.

⁵Intel Turbo Boost Technology increases actual operating frequency to 3.46 GHz. Credit to Shigeru Kondo.

 

Click to see benchmarks of older versions.

 

 

Multi-core Scaling: How much faster is multi-threading?

• v0.5.3 - v0.5.4:

Processor(s):	CPU Frequency*:	Memory:	Memory Frequency:	Multi-Threading Benefit:	View Benchmark Data:
Intel Core 2 Quad Q6600 @ 2.4 GHz	2.4 GHz	6 GB DDR2	800 MHz	3.570 x	View Benchmarks
Intel Core i7 920 @ 2.67 GHz	3.34 GHz (3.5 GHz Turbo Boost)	12 GB DDR3	1336 MHz	4.104 x	View Benchmarks
2 x Intel Xeon X5482 Harpertown @ 3.2 GHz	3.2 GHz	64 GB DDR2	800 MHz	6.458 x	View Benchmarks

 

*Note that CPU frequencies higher than the stock frequency imply overclocking.

 

Click to see results from older versions.

 

 

Random Screenshots: (from my test machines)

Pi - 500 million digits (6 minutes, 40 seconds)	Pi - 1 billion digits (7 minutes)	Pi - 100 billion digits (28 hours)
2.8 GHz Phenom II X3 (Unlock to 4 Cores + Overclock to 3.2 GHz) 720 Deneb	2.67 GHz Core i7 (Overclock to 4.2 GHz) 920 Bloomsfield	Dual 3.2 GHz Quad-Core Xeon X5482 Harpertown
4 GB DDR3 1333 MHz (dual channel)	12 GB DDR3 1200 MHz (triple channel)	64 GB DDR2 FB-DIMM 800 MHz (quad channel)
		8 x 2 TB Hitachi Deskstar

 

Fastest Times:

(Last updated: May 17, 2010)

 

All times in seconds.

 

Green indicates that the benchmark has been validated.

Red indicates that the benchmark was either not validated, or no validation was provided.

 

In the future, I may decide to allow only validated benchmarks on this list.

As of the current release, only Ram-Only Pi computations done using the Benchmark feature will be validated. However, starting from version 0.5.2, all computations have validation. This includes both swap modes as well as all the other constants.

Desktop (Limit One Processor)
Digits	Time	Version		Computer		Credit
25,000,000	4.654	v0.5.3	x64 SSE4.1	Intel Core i7 980X @ 4.66 GHz - on Air	6 GB DDR3	Shigeru Kondo
50,000,000	9.740	v0.5.3	x64 SSE4.1	Intel Core i7 980X @ 4.53 GHz - on Air	6 GB DDR3	Shigeru Kondo
100,000,000	21.945	v0.5.3	x64 SSE4.1	Intel Core i7 980X @ 4.40 GHz - on Air	6 GB DDR3	Shigeru Kondo
250,000,000	61.246	v0.5.3	x64 SSE4.1	Intel Core i7 980X @ 4.40 GHz - on Air	6 GB DDR3	Shigeru Kondo
500,000,000	135.432	v0.5.3	x64 SSE4.1	Intel Core i7 980X @ 4.26 GHz - on Air	6 GB DDR3	Shigeru Kondo
1,000,000,000	312.441	v0.5.3	x64 SSE4.1	Intel Core i7 980X @ 4.26 GHz - on Air	6 GB DDR3	Shigeru Kondo
2,500,000,000	956.499	v0.4.4	x64 SSE4.1	Intel Xeon X5650 @ 3.82 GHz (4.2 GHz Turbo Boost)	? GB DDR3	jcool @ XtremeSystems
5,000,000,000	3,922.15	v0.5.2	x64 SSE4.1	Intel Core i7 920 @ 3.34 GHz (3.5 GHz Turbo Boost) - on Air Hard Drives: 4 x 2 TB	12 GB DDR3	Alexander Yee
10,000,000,000	2.953 hours	v0.5.2	x64 SSE4.1	Intel Core i7 920 @ 3.34 GHz (3.5 GHz Turbo Boost) - on Air Hard Drives: 4 x 2 TB	12 GB DDR3	Alexander Yee
25,000,000,000	9.591 hours	v0.5.2	x64 SSE4.1	Intel Core i7 920 @ 3.34 GHz (3.5 GHz Turbo Boost) - on Air Hard Drives: 4 x 2 TB	12 GB DDR3	Alexander Yee
50,000,000,000	22.343 hours	v0.5.2	x64 SSE4.1	Intel Core i7 920 @ 3.34 GHz (3.5 GHz Turbo Boost) - on Air Hard Drives: 4 x 2 TB	12 GB DDR3	Alexander Yee
100,000,000,000	40.025 hours	v0.5.2	x64 SSE4.1	Intel Core i7 975 @ 4.00 GHz Hard Drives: 8 x 1 TB	12 GB DDR3	Shigeru Kondo
250,000,000,000	-	-	-	-	-	-

Desktop (Limit One Processor)
Digits		Time	Version		Computer		Credit
1M	1,048,576	0.221	v0.5.3	x64 SSE4.1	Intel Core i7 980X @ 5.21 GHz - on Dry Ice	6 GB DDR3	Shigeru Kondo
2M	2,097,152	0.411	v0.5.3	x64 SSE4.1	Intel Core i7 980X @ 5.21 GHz - on Dry Ice	6 GB DDR3	Shigeru Kondo
4M	4,194,304	0.776	v0.5.3	x64 SSE4.1	Intel Core i7 980X @ 5.21 GHz - on Dry Ice	6 GB DDR3	Shigeru Kondo
8M	8,388,608	1.583	v0.5.3	x64 SSE4.1	Intel Core i7 980X @ 4.66 GHz - on Air	6 GB DDR3	Shigeru Kondo
16M	16,777,216	3.129	v0.5.3	x64 SSE4.1	Intel Core i7 980X @ 4.66 GHz - on Air	6 GB DDR3	Shigeru Kondo
32M	33,554,432	6.273	v0.5.3	x64 SSE4.1	Intel Core i7 980X @ 4.53 GHz - on Air	6 GB DDR3	Shigeru Kondo
64M	67,108,864	13.362	v0.5.3	x64 SSE4.1	Intel Core i7 980X @ 4.40 GHz - on Air	6 GB DDR3	Shigeru Kondo
128M	134,217,728	30.452	v0.5.3	x64 SSE4.1	Intel Core i7 980X @ 4.40 GHz - on Air	6 GB DDR3	Shigeru Kondo
256M	268,435,456	66.652	v0.5.3	x64 SSE4.1	Intel Core i7 980X @ 4.26 GHz - on Air	6 GB DDR3	Shigeru Kondo
512M	536,870,912	145.808	v0.5.3	x64 SSE4.1	Intel Core i7 980X @ 4.26 GHz - on Air	6 GB DDR3	Shigeru Kondo
1G	1,073,741,824	334.578	v0.5.3	x64 SSE4.1	Intel Core i7 980X @ 4.26 GHz - on Air	6 GB DDR3	Shigeru Kondo
2G	2,147,483,648	749.534	v0.5.3	x64 SSE4.1	Intel Core i7 980X @ 4.13 GHz - on Air	12 GB DDR3	Shigeru Kondo
4G	4,294,967,296	-	-		-	-	-

 

Any Computer (No Processor Limit)
Digits	Time	Version		Computer		Credit
25,000,000	3.849	v0.5.3	x64 SSE4.1	2 x Intel Xeon X5680 @ 4.3 GHz	12 GB DDR3	sRHunt3r @ XtremeSystems
50,000,000	7.585	v0.5.3	x64 SSE4.1	2 x Intel Xeon X5680 @ 4.3 GHz	12 GB DDR3	sRHunt3r @ XtremeSystems
100,000,000	14.512	v0.5.3	x64 SSE4.1	2 x Intel Xeon X5680 @ 4.3 GHz	12 GB DDR3	sRHunt3r @ XtremeSystems
250,000,000	38.582	v0.5.3	x64 SSE4.1	2 x Intel Xeon X5680 @ 4.3 GHz	12 GB DDR3	sRHunt3r @ XtremeSystems
500,000,000	79.311	v0.4.4	x64 SSE4.1	2 x Intel Xeon X5680 @ 4.3 GHz	12 GB DDR3	sRHunt3r @ XtremeSystems
1,000,000,000	174.470	v0.4.4	x64 SSE4.1	2 x Intel Xeon X5680 @ 4.3 GHz	12 GB DDR3	sRHunt3r @ XtremeSystems
2,500,000,000	552.673	v0.5.2	x64 SSE4.1	4 x Intel Xeon X7560 @ 2.27 GHz (HT Off)	128 GB DDR3	Daniel Ghidali
5,000,000,000	1,143.750	v0.5.2	x64 SSE4.1	4 x Intel Xeon X7560 @ 2.27 GHz (HT Off)	128 GB DDR3	Daniel Ghidali
10,000,000,000	2,276.566	v0.5.2	x64 SSE4.1	4 x Intel Xeon X7560 @ 2.27 GHz (HT Off)	128 GB DDR3	Daniel Ghidali
25,000,000,000	1.720 hours	v0.5.3	x64 SSE4.1	4 x Intel Xeon X7560 @ 2.27 GHz (HT Off)	128 GB DDR3	Daniel Ghidali
50,000,000,000	14.807 hours	v0.5.3	x64 SSE4.1	2 x Intel Xeon X5482 @ 3.2 GHz Hard Drives: 1.5 TB + 4 x 1 TB	64 GB DDR2	Alexander Yee
100,000,000,000	17.283 hours	v0.5.3	x64 SSE4.1	2 x Intel Xeon X5650 @ 2.66 GHz Hard Drives: 16 x 2 TB	144 GB DDR3	Shigeru Kondo
250,000,000,000	83.586 hours	v0.5.2	x64 SSE4.1	2 x Intel Xeon W5590 @ 3.33 GHz Hard Drives: 8 x 2 TB	144 GB DDR3	Shigeru Kondo
500,000,000,000	172.396 hours	v0.5.2	x64 SSE4.1	2 x Intel Xeon W5590 @ 3.33 GHz Hard Drives: 16 x 2 TB	144 GB DDR3	Shigeru Kondo
1,000,000,000,000	12.260 days	v0.5.3	x64 SSE4.1	2 x Intel Xeon X5650 @ 2.66 GHz Hard Drives: 16 x 2 TB	96 GB DDR3	Shigeru Kondo

Any Computer (No Processor Limit)
Digits		Time	Version		Computer		Credit
1M	1,048,576	0.221	v0.5.3	x64 SSE4.1	Intel Core i7 980X @ 5.21 GHz - on Dry Ice	6 GB DDR3	Shigeru Kondo
2M	2,097,152	0.411	v0.5.3	x64 SSE4.1	Intel Core i7 980X @ 5.21 GHz - on Dry Ice	6 GB DDR3	Shigeru Kondo
4M	4,194,304	0.776	v0.5.3	x64 SSE4.1	Intel Core i7 980X @ 5.21 GHz - on Dry Ice	6 GB DDR3	Shigeru Kondo
8M	8,388,608	1.583	v0.5.3	x64 SSE4.1	Intel Core i7 980X @ 4.66 GHz - on Air	6 GB DDR3	Shigeru Kondo
16M	16,777,216	3.129	v0.5.3	x64 SSE4.1	Intel Core i7 980X @ 4.66 GHz - on Air	6 GB DDR3	Shigeru Kondo
32M	33,554,432	6.273	v0.5.3	x64 SSE4.1	Intel Core i7 980X @ 4.53 GHz - on Air	6 GB DDR3	Shigeru Kondo
64M	67,108,864	13.362	v0.5.3	x64 SSE4.1	Intel Core i7 980X @ 4.40 GHz - on Air	6 GB DDR3	Shigeru Kondo
128M	134,217,728	30.452	v0.5.3	x64 SSE4.1	Intel Core i7 980X @ 4.40 GHz - on Air	6 GB DDR3	Shigeru Kondo
256M	268,435,456	66.652	v0.5.3	x64 SSE4.1	Intel Core i7 980X @ 4.26 GHz - on Air	6 GB DDR3	Shigeru Kondo
512M	536,870,912	145.808	v0.5.3	x64 SSE4.1	Intel Core i7 980X @ 4.26 GHz - on Air	6 GB DDR3	Shigeru Kondo
1G	1,073,741,824	328.764	v0.4.3	x64 SSE4.1	2 x Intel Xeon W5590 @ 3.33 GHz	6 GB DDR3	Dave Hunt Movieman @ XtremeSystems
2G	2,147,483,648	731.146	v0.4.3	x64 SSE4.1	2 x Intel Xeon W5590 @ 3.33 GHz	72 GB DDR3	Shigeru Kondo
4G	4,294,967,296	1,595.959	v0.4.3	x64 SSE4.1	2 x Intel Xeon W5590 @ 3.33 GHz	72 GB DDR3	Shigeru Kondo
8G	8,589,934,592	3,689.989	v0.4.3	x64 SSE4.1	2 x Intel Xeon W5590 @ 3.33 GHz	72 GB DDR3	Shigeru Kondo
16G	17,179,869,184	8,184.953	v0.4.3	x64 SSE4.1	2 x Intel Xeon W5590 @ 3.33 GHz	72 GB DDR3	Shigeru Kondo
32G	34,359,738,368	24,047.321	v0.4.3	x64 SSE4.1	2 x Intel Xeon W5590 @ 3.33 GHz	72 GB DDR3	Shigeru Kondo
64G	68,719,476,736	-	-		-	-	-

*These fastest times may include unreleased betas.
Got a faster time? Let me know: a-yee@northwestern.edu

FAQ:

Q:  Is there a Linux version?
A:  Yes, it's about time. y-cruncher has been successfully ported to linux. However, it is slower than the Windows versions due to the lack of Linux-specifc tuning. Furthermore, some of the features had to be disabled in the Linux versino... But it's better than nothing.

Whenever I get the time, I'll slowly bring it up to the level of the Windows versions.

 

 

Q:  Is there a distributed version that performs better on NUMA and HPC clusters?
A:  As much as I'd like to optimize the program for NUMA and HPC clusters, I do not have the resources needed to do it.

To make a distributed/NUMA-friendly version, I need to have (or have an extended period of time of exclusive/physical access to) a highly Non-Uniform Memory machine (such as a high-end quad or 8-socket Opteron server), or an HPC cluster of 4 or more identical high-end desktops with high-speed connectivity.
Both of these are well beyond my student-sized budget.

If you are wondering about my Nagisa Workstation, it is also well beyond my budget... But long story short, I basically got it for free. Don't ask...

 

 

Q:  Can you make a CUDA version?
A:  Not yet...

Here are the major reasons:

GPUs currently have very poor double-precision floating-point (DP-FP) performance. y-cruncher relies heavily on DP-FP for its speed.   GPUs are highly vectorized. y-cruncher isn't ready for massive scalable vectorization.   CUDA currently does not support recursion. (There's a lot of multi-way recursion in y-cruncher. I'm not inclined to try rewriting them using loops.)   y-cruncher's purpose is efficiency on large computations. GPUs simply don't have enough ram to do large computations locally. The bandwidth between GPU and main memory will probably be a huge bottleneck. y-cruncher is already somewhat bottlenecked by bandwidth on a CPU. On a GPU, it will be much more bottlenecked because the GPU has much more computational power and the (GPU <--> main memory) bandwidth is usually less than (CPU <--> main memory) bandwidth. This holds even for benchmarking. If y-cruncher were able to fully utilize a GPU, benchmarks would be extremely fast - so fast that the largest computation that could be done in ram (either GPU ram, or CPU ram - it doesn't matter) would likely be too short to be a worthwhile benchmark.   There is currently no set-in-stone standard for GP-GPU programming.

Note that Nvidia's upcoming Fermi-based video cards will solve a number of these issues. But for now, I'll play by ear.

 

Q:  How does y-cruncher compare to other programs?
A:  Below is a table of the five fastest (publicly available) programs and how y-cruncher compares to them.

Program	Author(s)	Description + Environments where it beats y-cruncher
TachusPI	Fabrice Bellard	Holder of the current world record for the most digits of Pi computed on both supercomputer and desktop. It is faster than y-cruncher for both single-threaded and multi-threaded computations. However, it does not appear to scale as well with multi-threading. Despite being slower than TachusPi, y-cruncher is able to beat TachusPi when scalability becomes important. On dual-core, TachusPi 0.9.2 is faster than y-cruncher v0.5.3. On quad-core systems, TachusPi and y-cruncher are virtually tied. (TachusPi is faster for small computations, y-cruncher is faster for larger ones.) On 8-core systems, y-cruncher pulls ahead.
Parallel GMP-Chudnovsky	David Carver + Hanhong Xue + GMP team	This is a paralleled version of GMP-Chudnovsky using OpenMP. It appeared back in October 2008 and was improved a month later. It runs much faster on AMD processors than Intel processors. But because of its use of GMP, the true speed of this program cannot be achieved in Windows due to the lack of assembly support. On AMD K10 (in linux), the x64 version appears to beat y-cruncher (in Windows) for: All computations below a million digits. All single-threaded computations. Dual-thread computations below a few million digits. For larger computations with 4 or more cores, y-cruncher is still faster. Although Parallel GMP-Chudnovsky is multi-threaded, it does not scale as well as y-cruncher. So even though it beats y-cruncher in clock-for-clock linear speed, it is slower when there are more than 2 cores.
QuickPi 4.5	Steve Pagliarulo	QuickPi is multi-threaded and supports x64 and SSE3. Clock-for-clock, QuickPi 4.5 is faster than y-cruncher. Therefore it beats y-cruncher for single-threaded computations of less than a billion digits or so. Like Parallel GMP-Chudnovsky, QuickPi 4.5 has trouble scaling up with cores. So for multi-threaded computations with 2 or more cores, y-cruncher is usually faster.
MaxxPi-Multi	M. Bicak	MaxxPi-Multi is a relatively new program that is aimed at benchmarking. Although its purpose is not speed, it is nevertheless one of the fastest in the world. It supports SSE, multi-threading, and is the only "fast" program for computing Pi that has a GUI. Clock-for-clock, MaxxPi-Multi is actually the only program in this table that is slower than y-cruncher. However, it scales decently well for the first few cores - enough to beat out GMP-Chudnovsky and PiFast 4.3 on quad-core. Because MaxxPi-Multi is slower clock-for-clock, y-cruncher seems to beat it for all large computations regardless of the number of cores/threads.
GMP-Chudnovsky	Hanhong Xue + GMP team	This is the original (single-threaded) version of GMP-Chudnovsky. It runs much faster on AMD processors than Intel processors. Clock-for-clock, GMP-Chudnovsky is faster than y-cruncher. Therefore it beats y-cruncher for all single-threaded computations. For multi-threaded computations with 2 or more cores, y-cruncher is still faster.
PiFast 4.3	Xavier Gourdon	PiFast - An old classic. It undisputedly held the title of "Fastest Program to Compute Pi" for quite a while until QuickPi passed it. Using only x86 and x87 FPU instructions, PiFast packs a very impressive speed. It is also one of the most memory efficient programs for computing Pi. Clock-for-clock, PiFast 4.3 is virtually tied with y-cruncher 0.4.3 (x86). However, it is more efficient for larger computations. The cross-over point between PiFast 4.3 and single-threaded y-cruncher 0.4.3 (x86) is about 10 million digits on Core i7. Below that, y-cruncher is slightly faster. And above that, PiFast 4.3 is slightly faster. Because of the virtual tie, any advantage for y-cruncher will tip the balance. Therefore any of (SSE3, x64, multi-threading) will make y-cruncher faster.

Just to clear up a few things: y-cruncher is intended to be fast, but not optimal. It is optimized for memory efficiency on large computations.
Utmost speed is not important as y-cruncher can probably be made 10 - 30% faster by relaxing memory constraints and using decimal arithmetic.

 

 

Q:  Why does y-cruncher run 4 threads on my 3-core system (8 threads on 6-core, etc...)
A:  This is due to practical restrictions in the algorithms that are used by y-cruncher. Because of the nature of the algorithms that y-cruncher uses, they are most efficiently paralleled when the thread count is a power of two. To deal with systems that don't have a power-of-two number of logical cores, y-cruncher simply rounds up to the next power of two.

The overhead of running extra threads is usually very small. Any load balancing issues that result from awkward thread-to-core ratios are usually resolved by further increasing the thread count. (as explained in the next Q/A)

 

Q:  Why does y-cruncher create more threads than I tell it to use? Because of this I can't get dual-core benchmarks on a quad core machine since it will use all 4 cores even in dual-core mode.
A:  This is by design and is NOT a bug. Because of the nature of some of the algorithms, I find it necessary to spam threads in order to maximize multi-core efficiency. The work-around is to go to "Processor Affinity" in Task Manager and uncheck the cores that you do not want y-cruncher to use. y-cruncher does not do this automatically because it "doesn't know which logical cores are the best to use".

I call this method "Thread Spamming". Yes, it sounds ridiculous. But it's a very simple and effective way to deal with load imbalance.

 

Q:  Is y-cruncher open-sourced?
A:  No.

 

Q:  Is there a publicly available static library for the multi-threaded arithmetic that y-cruncher uses?
A:  No. At least not now...

y-cruncher's arithmetic module is indeed isolated from rest of the program in its own library. I call it "YMP" (y-cruncher Multi-Precision Arithmetic Library), but it is also closed-sourced.

Currently, y-cruncher is the only thing that uses YMP in it's entirety. But there is a growing interest to use y-cruncher's FFT in some signal processing and optical-related work since it is significantly faster than FFTW in a number of performance critical applications.

Q:  Who are you? Are you really still in college? What degrees do you have? etc...
A:  Yes I'm still in college. As of spring 2009, I am 21 years old and a Junior undergraduate student at Northwestern University just north of Chicago, Illinois.
Therefore, I don't even have a college diploma yet - let alone a masters or Ph.D... So I apologize if my tone of writing in this entire website is of a restless college student.
I am a computer enthusiast and a semi-die hard gamer. Outside of computers, my hobbies include bowling, piano, and Japanese Anime.
And lastly, no I don't speak Japanese (as much as I'd like to). Aside from English, I speak Cantonese and a tiny bit of Mandarin.

Links:

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

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

Special Thanks

• Raymond Chan - Code Tester, Hardware Mentor, and Webmaster
  • My friend and roommate for Sophomore, Junior, and soon Senior years in college. Raymond helped test a lot of code back in 2006.
    In September 2008, he helped me build "Nagisa" and for that, every record set using Nagisa will have his name attached.
    
    Raymond is the webmaster who redesigned this site. He currently helps me maintain it.
    
    
• Johnny Sun - Code tester and Overclocker
  • My friend, dorm suitemate, computer-enthusiast, and hardware expert.
    He was one of the first people to notice that Raymond and I were building a computer...
    It was also around the same that the Nehalems were released, so he tried a little bragging with his new Core i7...
    
    Long story short... that didn't go too well for him...
    Can't blame him though... Nagisa was probably the last kind of computer you'd expect to find in a dorm room.
    
    With the second best computer in the dorm (Nagisa being the first), he helped me test a lot of 64-bit code. This was crucial because Nagisa was almost always "tied up" by a world-record sized computation that would often last for weeks.
    
    Currently, he helps me beta-test new versions of y-cruncher before they are released.
    
    
• Colleen Lee - Math genius and Number-Theory expert
  • One of my best friends from high-school and a gamer. Her math skills rank internationally...
    She's the one I turn to whenever I have math-related questions.
    
    So far, her contributions have not made their way into y-cruncher yet.

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.