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

It Stands at 10 trillion digits of Pi...
World Record for both Desktop and Supercomputer!!!

 

(Last updated: April 21, 2012)

 

 

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 0.5.5 Build 9180 (fix 2) (Released: April 6, 2011)

Linux      : Version 0.5.5 Build 9187 (fix 2) (Released: February 20, 2011)

 

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

y-cruncher has been tested up to the current limit 10 trillion digits. (Credit: Shigeru Kondo)

 

Due to algorithmic limitations, v0.5.x is not capable of going above 10 trillion digits. (The exact limit is unknown, but is somewhere between 10 - 40 trillion...)

This will be solved in v0.6.1 with the addition of a new multiplication algorithm.

 

 

Update on v0.6.1: (April 21, 2012)

 

No, y-cruncher isn't dead. Sure, it's been almost a year since the last release. See my blog for more details.

 

 

Records Set by y-cruncher:

World Record Size Computations

Date Announced	Date Completed:	Source:	Who:	Constant:	Decimal Digits:	Time:	Computer:
February 9, 2012	February 9, 2012		Alexander Yee	Square Root of 2	2,000,000,000,050	Compute:  110 hours Verify:  119 hours	2 x Xeon X5482 @ 3.2 GHz - 64 GB 8 x 2 TB Core i7 2600K @ 4.4 GHz - 16 GB 5 x 1 TB + 5 x 2 TB
October 17, 2011	October 16, 2011	Source	Shigeru Kondo & Alexander Yee	Pi	10,000,000,000,050	Compute:  371 days Verify:  45 hours	2 x Intel Xeon X5680 @ 3.33 GHz 96 GB DDR3 @ 1066 MHz 24 x 2 TB
May 24, 2011	May 20, 2011		Shigeru Kondo	Log(10)	100,000,000,000	Compute and Verify: 142 hours	Intel Core i7 2500K @ 4.8 GHz 16 GB DDR3 + 6 x 1 TB
	May 14, 2011		Shigeru Kondo	Log(2)	100,000,000,000	Compute and Verify: 142 hours	Intel Core i7 2500K @ 4.8 GHz 16 GB DDR3 + 6 x 1 TB
December 13, 2010	December 12, 2010		Alex Roberts	Catalan's Constant	50,000,000,000	Compute:  35.5 days Not Verified	AMD Phenom II X4 945 @ 3.0 GHz 8 GB
December 4, 2010	November 26, 2010		Alex Roberts	Log(2)	50,000,000,000	Compute:  13.1 days Independently Verified	Intel Core i7 720Q @ 1.60 GHz 4 GB DDR3
September 17, 2010	September 17, 2010	Source	Alexander Yee	Zeta(3) - Apery's Constant	100,000,001,000	Compute:  148 hours Verify:  366 hours	"Nagisa" + "Ushio"
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 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 Verify: 219 hours	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 Verify:  98 hours	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	"Ushio"
April 16, 2009	April 16, 2009	Source	Alexander Yee & Raymond Chan	Catalan's Constant	31,026,000,000	Compute:  178 hours Verify:  221 hours	"Nagisa"
March 13, 2009	March 13, 2009	Source	Alexander Yee & Raymond Chan	Euler-Mascheroni Constant	29,844,489,545	Compute:  205 hours Verify:  269 hours	"Nagisa"
	February 28, 2009	Source	Alexander Yee & Raymond Chan	Log(10)	31,026,000,000	Compute and Verify: 40 hours	"Nagisa"
	February 15, 2009	Source	Alexander Yee & Raymond Chan	Zeta(3) - Apery's Constant	31,026,000,000	Compute:  45 hours Verify:  44 hours	"Nagisa"
	February 4, 2009	Source	Alexander Yee & Raymond Chan	Log(2)	31,026,000,000	Compute:  24 hours Verify:  16 hours	"Nagisa"
Janurary 31, 2009	January 31, 2009	Source	Alexander Yee & Raymond Chan	Catalan's Constant	15,510,000,000	Compute:  88 hours Verify:  100 hours	"Nagisa"
Janurary 21, 2009	January 21, 2009	Source	Alexander Yee & Raymond Chan	Zeta(3) - Apery's Constant	15,510,000,000	Compute:  20 hours Verify:  21 hours	"Nagisa"
Janurary 18, 2009	January 18, 2009	Source	Alexander Yee & Raymond Chan	Euler-Mascheroni Constant	14,922,244,771	Compute:  96 hours Verify:  134 hours	"Nagisa"
	January 7, 2009	Source	Alexander Yee & Raymond Chan	Log(2)	15,500,000,000	Compute:  12.5 hours Verify:  8.3 hours	"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.

 

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 v0.5.5.9180 (fix 2).zip (5.83 MB)
Linux      : y-cruncher v0.5.5.9187 (fix 2).tar.gz (5.34 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++ 2010 Redistributable Package (x86)
  Microsoft C++ 2010 Redistributable Package (x64)
  
  
• In order to properly run any computation in Swap Mode, y-cruncher needs full adminstrative privileges.
  This is a problem in Vista and Win7 because of User Account Control. The solution is to either disable User Account Control or run y-cruncher by: Right Click -> Run as Adminstrator
  
  Failure to provide y-cruncher with sufficient privilages will result in the following warning message when starting any computation in Swap Mode.
  
  "Unable to set permissions for file allocation. Expect performance degradation."
  
  The program will still work correctly, but it will be much slower. (especially in Advanced Swap Mode)

  
  
  

• 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: February 5, 2011)

 

All times in seconds. All times include the time needed to convert the digits to decimal representation.

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. v0.5.5 is faster on processors with AVX instructions.

Processor(s):	Core 2 Q6600 2.4 GHz	Phenom II X4 940 3.5 GHz1	Core i7 920 2.80 GHz2	Core i7 920 4.2 GHz3	Core i7 980X 4.48 GHz4	Core i7 2600K 4.8 GHz5	4 x Opteron (Barcelona) 2.31 GHz6	2 x Xeon X5482 (Harpertown) 3.2 GHz	2 x Xeon X5680 (Westmere-EP) 3.46 GHz7
Cores/Threads:	4/4	4/4	4/8	4/8	6/12	4/8	16/16	8/8	12/24
Number of Digits	v0.5.3	v0.5.3	v0.5.4	v0.5.4	v0.5.4	v0.5.5	v0.5.3	v0.5.5	v0.5.3
1,000,000	0.566		0.390	0.259		0.216		0.354
10,000,000	5.286		3.667	2.466		1.916		3.147
100,000,000	68.95	48.55	43.60	29.53	22.51	21.54	35.09	29.43	16.29
1,000,000,000	990.0	698.8	619.4	424.3	302.8	311.8	468.1	392.5	202.5
10,000,000,000								5,365	2,721

¹Overclocked from 3.0 GHz. Credit to CRFX from XtremeSystems.

²Base frequency is 2.67 GHz. Intel Turbo Boost Technology increases actual operating frequency to 2.8 GHz.

³Overclocked from 2.67 GHz to 4.0 GHz. Actual operating frequency after Turbo Boost is 4.2 GHz.

⁴Overclocked from 3.33 GHz. Credit to tet5uo from XtremeSystems.

⁵Base frequency is 3.4 GHz with 3.5 GHz 4-core Turbo Boost. Actual operating frequency is 4.8 GHz by overclocking. Credit to Shigeru Kondo for the 100m and 1b runs. (I haven't had the time to play with my overclock enough to get 4.8 GHz benchable for longer runs.)

⁶Credit to skycrane from XtremeSystems.

⁷Base frequency is 3.33 GHz. Intel Turbo Boost Technology increases actual operating frequency to 3.46 GHz. Credit to Shigeru Kondo.

 

 

 

Random Screenshots: (from my test machines)

Pi - 1 billion digits (7 minutes)	Pi - 1 billion digits (5 minutes, 33 seconds)	Pi - 100 billion digits (28 hours)
Windows 7 - y-cruncher v0.5.4 x64 SSE4.1	Ubuntu Linux 10 - y-cruncher v0.5.5 x64 AVX	Windows 7 - y-cruncher v0.5.4 x64 SSE4.1
Core i7 920 @ 4.2 GHz (overclock)	Core i7 2600K @ 4.4 GHz (overclock)	2 x Xeon X5482 Harpertown @ 3.2 GHz
12 GB DDR3 @ 1200 MHz	16 GB DDR3 @ 1333 MHz	64 GB DDR2 FB-DIMM @ 800 MHz
		8 x 2 TB Hitachi Deskstar

 

Fastest Times:

(Last updated: September 22, 2011)

 

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.

 

A 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

Desktop (Limit One Processor)
Digits	Time	Version		Computer		Credit
25,000,000	3.606	v0.5.5	x64 AVX	Intel Core i7 3930K @ 4.95 GHz	16 GB DDR3	CARDB0ARDfoxx @ XtremeSystems
50,000,000	6.888	v0.5.5	x64 AVX	Intel Core i7 3930K @ 4.95 GHz	16 GB DDR3	CARDB0ARDfoxx @ XtremeSystems
100,000,000	14.895	v0.5.5	x64 AVX	Intel Core i7 3930K @ 4.95 GHz	16 GB DDR3	CARDB0ARDfoxx @ XtremeSystems
250,000,000	42.435	v0.5.5	x64 AVX	Intel Core i7 3930K @ 4.95 GHz	16 GB DDR3	CARDB0ARDfoxx @ XtremeSystems
500,000,000	105.520	v0.5.5	x64 AVX	Intel Core i7 3930K @ 4.20 GHz	32 GB DDR3	Rod Laird
1,000,000,000	233.251	v0.5.5	x64 AVX	Intel Core i7 3930K @ 4.20 GHz	32 GB DDR3	Rod Laird
2,500,000,000	628.925	v0.5.5	x64 AVX	Intel Core i7 3930K @ 4.20 GHz	32 GB DDR3	Rod Laird
5,000,000,000	1,369.20	v0.5.5	x64 AVX	Intel Core i7 3930K @ 4.20 GHz	32 GB DDR3	Rod Laird
10,000,000,000	2,802.06	v0.5.5	x64 AVX	Intel Core i7 3930K @ 4.60 GHz	64 GB DDR3	Duane Lyons
25,000,000,000	6.874 hours	v0.5.4	x64 SSE4.1	Intel Core i7 2600K @ 4.50 GHz - on Water Hard Drives: 1.5 TB + 4 x 1 TB	16 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	30.984 hours	v0.5.5	x64 AVX	Intel Core i7 2600K @ 4.40 GHz - on Water Hard Drives: 1.5 TB + 5 x 1 TB + 5 x 2 TB	16 GB DDR3	Alexander Yee
250,000,000,000	123.982 hours	v0.5.5	x64 AVX	Intel Core i7 2600K @ 4.40 GHz - on Water Hard Drives: 1.5 TB + 4 x 1 TB	16 GB DDR3	Alexander Yee
500,000,000,000	-	-	-	-	-	-

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	2,121.99	v0.5.5	x64 SSE3	4 x AMD Opteron 6168	64 GB DDR3	Sheik @ XtremeSystems
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
2,500,000,000,000
5,000,000,000,000	90 days	v0.5.4	x64 SSE4.1	2 x Intel Xeon X5680 @ 3.33 GHz Hard Drives: 16 x 2 TB	96 GB DDR3	Shigeru Kondo
10,000,000,000,000	371 days	v0.5.5	x64 SSE4.1	2 x Intel Xeon X5680 @ 3.33 GHz Hard Drives: 24 x 2 TB	96 GB DDR3	Shigeru Kondo

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

FAQ:

Q:  Why does AVX (v0.5.5) only give about 10% speedup over SSE4.1 (v0.5.4)? Shouldn't it be double the speed?
A:  Unlike the majority of compute-intensive applications, y-cruncher does not exclusively use floating-point. As of v0.5.4, only about 30% of a Pi computation is floating-point bound. The remainder of the time is spent on integer operations and stalling on memory access. So cutting that 30% in half yields little overall speedup. Speeding up the code in this manner exposes more memory bottlenecks - which ends up reducing the speedup to only 10%...

Integer operations can be largely be emulated using floating-point (albeit with overhead). But most of the integer work involves carry-propagation, so it is not very vectorizable. For now, integer operations are still faster using the normal integer instructions.

Even without AVX, floating-point is not the dominant factor in performance.
Plans for v0.6.x include improving the integer operations to better utilize x64 capabilities. Memory optimizations are also slated for the future.

Mathematical improvements will be added whenever convenient. These will improve the computational speed of y-cruncher, but will probably have no effect on the resource consumption ratios in y-cruncher. (By "resource consumption ratios" I mean the relative portions of the program with are bound by integer/floating-point/memory.)

 

 

 

Q:  Why is the performance so poor for small computations? The program only gets xx% CPU utilization on my xx core machine for small sizes!!!
A:  The reason is simple. For small computations, there isn't much that can be parallelized. In fact, spawning N threads for an N core machine may actually take longer than the computation itself!!! In these cases, the program will decide not to use all available cores. Therefore, parallelism is really only helpful when there is a lot of work to be done. As of 2010, I am not aware of any Pi-program that achieves perfect parallelism for small computations and is at least half the speed of y-cruncher. (It's easy to get perfect parallelism if you artificially make the task really slow.)

Now here's a layman explanation:

Suppose you had a 1000 page novel that needs to be proof-read. Now suppose you had 10 staff members. To speed up the process, you can assign 100 pages to each staff member. This basically makes the task 10x faster. This is an example of a "large computation" done using a "small" number of cores.

Now suppose you need to proof-read a 1 page paper. And you have a staff of 100 people. Are you going to tear the page into 100 small parts and give one to each person to proof-read? Furthermore, organizing your group of 100 staff members is probably going to take longer than proof reading the entire page yourself!!! This is an example of a "small computation" using a "large" number of cores.

Of course, this is a highly simplified explanation of what is really going on. But the overall idea is the same.
It should be noted that some tasks are easier to parallelize than others. Most of the multi-threaded benchmarks that are used in the overclocking community tend to be highly "synthetic" tasks that are extremely easy to parallelize. These "synthetic" tasks typically achieve perfect parallelism regardless of the size of the task. But most other applications that do any sort of "meaningful" task tend to be less ideal. (And no, I'm not trying to imply that computing Pi is in anyway meaningful.)

 

 

Q:  Who else helped you develop this program?
A:  Although all the development and testing (including all the coding) was done by myself, I have to give a lot of credit to my parents for providing me the resources to acquire the hardware that I've needed.

The total cost of all the hardware that were directly involved in the development of y-cruncher adds up to more than $10,000. Most of this came from my parents. So yes, y-cruncher was developed entirely using my own hardware. (With small amounts of testing on some of my friends' hardware.)

Since then, I've gained back much more than 10-grand in the form of scholarships and job opportunities. (So it can't really be quantified...)
But that's not the point. The y-cruncher project started out as just a really expensive hobby from which we were expecting no return.

It just happened to turn out a little better than expected...

 

Q:  Is there a publicly available library for the multi-threaded arithmetic that y-cruncher uses?
A:  Yes there is, but it's still in a very alpha stage and is far from ready for release.

 

 

Q:  Is there a distributed version that performs better on NUMA and HPC clusters?
A:  Not yet. Pretty much the entire program needs to be redesigned for NUMA and MPI.

For now, a speedup can be gained in Linux by running y-cruncher with interleaved memory: numactl --interleave=all "./x64 SSE3.out"

 

 

Q:  Can you make a CUDA version?
A:  Definitely not for CUDA 1.x. Things are better for CUDA 2.0, but probably still not good enough.

Here are the major reasons:

GPUs are highly vectorized. y-cruncher isn't ready for massive scalable vectorization. The widening of the SIMD vector from 128-bit SSE to 256-bit AVX only produced 10% speedup. Therefore, going to larger vectors with the current set of algorithms will be well into the region of diminishing return. New algorithms and programming techniques will need to be developed to make such a task efficient on GPUs.   The memory bandwidth between the GPU and main memory will almost certainly be a bottleneck. This isn't a problem for small computations that will fit entirely into GPU memory, but small computations isn't the point of y-cruncher.   There is currently no set-in-stone standard for GP-GPU programming. CUDA is NVidia only. Most other GPU programming standards are, for the most part, too graphics oriented for such a non-graphics task as computing Pi.

 

Q:  How does y-cruncher compare to other programs?
A:  Here's a graph comparing y-cruncher to the two fastest publicly-available Pi programs that I know of. (click to enlarge)

(Huge thanks to Fredrik Kjølstad for compiling GMP for me on my machines!)

• The programs that we benchmarked here can be found at the following links:
  • TachusPi
  • GMP-Chudnovsky
  • Parallel GMP-Chudnovsky
    
    
• For both GMP benchmarks, we modified the output function within the GMP library to do only the conversion. That way we could benchmark GMP for the time it takes to compute decimal digits without including the time needed to output the digits to disk.
  
  
• The lines for GMP and Parallel GMP stop short because both of them ran out of memory before we could reach our maximum benchmark size.
  • Both GMP and Parallel GMP needed about 11 GB of memory to compute 1 billion digits. That's the most we could do on the Core i7 system.
  • GMP needed 31 GB of memory for 2.5 billion digits and more than 60 GB for 5 billion digits on the Xeon system.
  • Parallel GMP ran out of memory when we tried to run 5 billion digits on the Xeon system.
    
    
• The Linux benchmarks were done on Ubuntu 10.04 and the Windows benchmarks were done on Windows 7 Ultimate. Although both GMP and TachusPi perform better in Linux than Windows, y-cruncher performs slightly better in Windows.
  
  
• Lastly, GMP performs much better on AMD systems than Intel systems. But since we don't have access to an up-to-date AMD system we're unable to provide benchmarks on AMD. Also, the performance of Parallel GMP-Chudnovsky suffers greatly because the GMP library itself is not paralleled.

 

For those who are interested more at the internals than Pi, here are graphs comparing y-cruncher's multiplication to GMP and TachusPi. The data for these graphs were taken from the "Final Multiply" step of the Pi computations that were done above.

• Note that there is no difference in performance between GMP and Parallel GMP due to the fact that the GMP library has no support for multi-threading.
  The fact that y-cruncher can beat GMP by more than a factor of 10 in the paralleled environment shows how important it is to support multi-threading within the arithmetic itself.
  
  
• It is slightly unfortunate that our Core i7 system only has 12 GB of ram. It would be interesting to see the extent of the slowdown that TachusPi encounters as we push the size above 1 billion digits. On the Xeon system (which has 64 GB of ram), we can see this clearly, but the Xeon system has a very different memory architecture than the Core i7 system.

 

 

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:  Who are you?
A:  About me.

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.
    
    
• My Parents
  • Lastly I want to give the biggest thanks to my parents. They provided me with a lot of support (both financially and morally) to develop this program.

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.