1 multicore salsa parallel programming 2.0 peking university october 31 2007 geoffrey fox, huapeng...
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Multicore SalsaParallel Programming 2.0
Peking UniversityOctober 31 2007
Geoffrey Fox, Huapeng Yuan, Seung-Hee BaeCommunity Grids Laboratory, Indiana University Bloomington IN 47404
Xiaohong QiuResearch Computing UITS, Indiana University Bloomington IN
George Chrysanthakopoulos, Henrik Frystyk Nielsen
Microsoft Research, Redmond WA
[email protected], http://www.infomall.org
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Abstract of Multicore SalsaParallel Programming 2.0
Multicore or manycore systems are probably not architecturally that different from parallel machines with which we are familiar. However in next 5-8 years the basic commodity (PC) chips will have 64-256 cores and currently there is little understanding of how to use them. It is clearly essential (at least for major US technology companies) that we effectively use such cores on broadly deployed machines.
This constraint makes multicore chips an exciting and different problem.We describe general issues in context of the SALSA project at http://www.infomall.org/multicore. This is using Service Aggregated Linked Sequential Activities where we are looking at a suite of parallel datamining applications as one important broadly useful capability for future multicore-based systems that will offer users navigation and advice based on the ever increasing data from sensors and the Internet. A key idea is using services not libraries as the basic building block so that we can offer productive user interfaces (Parallel Programming 2.0) by adapting workflow and mashups for composing parallel services. We still imagine that services will be constructed by experts using extensions of current threading and MPI models. Automatic compilers do not seem practical in the key 5-8 year time frame although PGAS((Partitioned Global Address Space) could be valuable. We present results on 8 cores (two quadcore chips) using the Microsoft CCR/DSS runtime that combines MPI, threading and service capabilities.
Too much Computing? Historically both grids and parallel computing have tried to increase
computing capabilities by• Optimizing performance of codes at cost of re-usability• Exploiting all possible CPU’s such as Graphics co-processors and
“idle cycles” (across administrative domains)• Linking central computers together such as NSF/DoE/DoD
supercomputer networks without clear user requirements Next Crisis in technology area will be the opposite problem –
commodity chips will be 32-128way parallel in 5 years time and we currently have no idea how to use them – especially on clients• Only 2 releases of standard software (e.g. Office) in this time span
so need solutions that can be implemented in next 3-5 years Note that even cell phones will be multicore There is “Too much data” as well as “Too much computing” and
maybe processing the data deluge will “solve” the “Too much computing” problem• Quite plausible on servers where we naturally will have lots of data• Less clear on clients but short of other ideas• Intel RMS analysis: Gaming and Generalized decision support
(data mining) are two ways of using these cycles
Intel’s Projection
Tomorrow
What is …? What if …?Is it …?
Recognition Mining Synthesis
Create a model instance
RMS: Recognition Mining SynthesisRMS: Recognition Mining Synthesis
Model-basedmultimodalrecognition
Find a modelinstance
Model
Real-time analytics ondynamic, unstructured,
multimodal datasets
Photo-realism andphysics-based
animation
TodayModel-less Real-time streaming and
transactions on static – structured datasets
Very limited realism
What is a tumor? Is there a tumor here? What if the tumor progresses?
It is all about dealing efficiently with complex multimodal datasetsIt is all about dealing efficiently with complex multimodal datasets
Recognition Mining Synthesis
Images courtesy: http://splweb.bwh.harvard.edu:8000/pages/images_movies.html
Intel’s Application Stack
Too much Data to the Rescue? Multicore servers have clear “universal parallelism” as many
users can access and use machines simultaneously Maybe also need application parallelism (e.g. datamining) as
needed on client machines Over next years, we will be submerged of course in data
deluge• Scientific observations for e-Science• Local (video, environmental) sensors• Data fetched from Internet defining users interests
Maybe data-mining of this “too much data” will use up the “too much computing” both for science and commodity PC’s• PC will use this data(-mining) to be intelligent user
assistant?• Must have highly parallel algorithms
Broad Parallelism Issues and Data-mining Algorithms
Looking at Intel list of algorithms (and all previous experience), we find there are two styles of “micro” parallelism• Dynamic search as in integer programming, Hidden Markov Methods
(and computer chess); irregular synchronization with dynamic threads
• “MPI Style” i.e. several threads running typically in SPMD (Single Program Multiple Data); collective synchronization of all threads together
Most Intel RMS are “MPI Style” and very close to scientific algorithms even if applications are not science
Note MPI historically runs with processes not threads but likely that threads will be implementation of choice for commodity applications
Most “commodity experience” is for few way concurrency to support Windows/Linux O/S in “dynamic thread” paradigm
Little experience in MPI style synchronization with threads
“Space-Time” Picture• Data-parallel applications map spatial structure
of problem on parallel structure of both CPU’s and memory
• However “left over” parallelism has to map into time on computer
• Data-parallel languages support this
Application Time
Application Spacet0
t1
t2
t3
t4
Computer Time
4-wayParallelComputer(CPU’s)
T0
T1
T2
T3
T4
“Internal” (to data chunk) application spatial dependence (n degrees of freedom) maps into time on the computer
Data Parallel Time Dependence• A simple form of data parallel applications are synchronous with all elements
of the application space being evolved with essentially the same instructions• Such applications are suitable for SIMD computers and run well on vector
supercomputers (and GPUs but these are more general than just synchronous)
• However synchronous applications also run fine on MIMD machines• SIMD CM-2 evolved to MIMD CM-5 with same data parallel language
CMFortran• The iterative solutions to Laplace’s equation are synchronous as are many full
matrix algorithms
Synchronization on MIMD machines is accomplished by messaging
It is automatic on SIMD machines!
Application Time
Application Spacet0
t1
t2
t3
t4
Synchronous
Identical evolution algorithms
Local Messaging for Synchronization• MPI_SENDRECV is typical primitive• Processors do a send followed by a receive or a receive followed by a send• In two stages (needed to avoid race conditions), one has a complete left shift• Often follow by equivalent right shift, do get a complete exchange• This logic guarantees correctly updated data is sent to processors that have their data at same
simulation time
……
…8 Processors
Application and Processor Time
Application Space
ComputePhase
CommunicationPhase
ComputePhase
CommunicationPhase
ComputePhase
CommunicationPhase
CommunicationPhase
Loosely Synchronous Applications• This is most common large scale science and engineering and
one has the traditional data parallelism but now each data point has in general a different update– Comes from heterogeneity in problems that would be synchronous if
homogeneous• Time steps typically uniform but sometimes need to support variable time steps across
application space – however ensure small time steps are t = (t1-t0)/Integer so subspaces with finer time steps do synchronize with full domain
• The time synchronization via messaging is still valid
• However one no longer load balances (ensure each processor does equal work in each time step) by putting equal number of points in each processor
• Load balancing although NP complete is in practice surprisingly easy
Application Time
Application Spacet0
t1
t2
t3
t4
Distinct evolution algorithms for each data point in each processor
Dynamic (search/Thread) Applications
Application Time
Application Space
Application Space
Application Time
• Here there is no natural universal ‘time’ in the application as there is in science algorithms where an iteration number or Mother Nature’s time gives global synchronization
• Loose (zero) coupling or special features of application needed for successful parallelization
• In computer chess, the minimax scores at parent nodes provide multiple dynamic synchronization points
Some links See http://www.connotea.org/user/crmc for references --
select tag oldies for venerable links; tags like MPI Applications Compiler have obvious significance
http://www.infomall.org/salsa for recent work including publications
My tutorialhttp://grids.ucs.indiana.edu/ptliupages/presentations/PC2007/index.html If you have forgotten about parallel computing (or never learnt)
Multicore SALSA at CGL Service Aggregated Linked Sequential Activities Aims to link parallel and distributed (Grid) computing by
developing parallel applications as services and not as programs or libraries• Improve traditionally poor parallel programming
development environments Can use messaging to link parallel and Grid services but
performance – functionality tradeoffs different• Parallelism needs few µs latency for message latency and
thread spawning• Network overheads in Grid 10-100’s µs
Use low latency where performance needed; use high latency where productivity needed
Developing set of services (library) of multicore parallel data mining algorithms
Parallel Programming Model If multicore technology is to succeed, mere mortals must be able to build
effective parallel programs There are interesting new developments – especially the new Darpa
HPCS Languages X10, Chapel and Fortress However if mortals are to program the 64-256 core chips expected in 5-7
years, then we must use today’s technology and we must make it easy• This rules out radical new approaches such as new languages
Remember that the important applications are not scientific computing but most of the algorithms needed are similar to those explored in scientific parallel computing
We can divide problem into two parts:• Micro-parallelism: High Performance scalable (in number of cores)
parallel kernels or libraries • Macro-parallelism: Composition of kernels into complete
applications We currently assume that the kernels of the scalable parallel
algorithms/applications/libraries will be built by experts with a Broader group of programmers (mere mortals) composing library
members into complete applications.
Scalable Parallel Components There are no agreed high-level programming environments for
building library members that are broadly applicable. However lower level approaches where experts define
parallelism explicitly are available and have clear performance models.
These include MPI for messaging or just locks within a single shared memory.
There are several patterns to support here including the collective synchronization of MPI, dynamic irregular thread parallelism needed in search algorithms, and more specialized cases like discrete event simulation.
We use Microsoft CCR http://msdn.microsoft.com/robotics/ as it supports both MPI and dynamic threading style of parallelism
Good and Bad about MPI MPI (or equivalent locks on shared memory machine)
has a bad reputation as the “machine-code” approach to parallel computing• User must break problem into parts
• User must program each part
• User must generate synchronization/messaging between parts However these defects imply a very clear performance
model as user needs to make explicit both application and machine structure
Thus if you can do this, one expects reliable understandable results that port well between different architectures
Other Parallel Programming Models OpenMP annotation or Automatic Parallelism of existing
software is practical way to use those pesky cores with existing code• As parallelism is typically not expressed precisely, one needs luck to get
good performance• Remember writing in Fortran, C, C#, Java … throws away information
about parallelism HPCS Languages should be able to properly express parallelism
but we do not know how efficient and reliable compilers will be• High Performance Fortran failed as language expressed a subset of
parallelism and compilers did not give predictable performance PGAS (Partitioned Global Address Space) like UPC, Co-array
Fortran, Titanium, HPJava• One decomposes application into parts and writes the code for each
component but use some form of global index • Compiler generates synchronization and messaging• PGAS approach should work but has never been widely used – presumably
because compilers not mature
Summary of micro-parallelism On new applications, use MPI/locks with explicit
user decomposition A subset of applications can use “data parallel”
compilers which follow in HPF footsteps• Graphics Chips and Cell processor motivate such
special compilers but not clear how many applications can be done this way
OpenMP and/or Compiler-based Automatic Parallelism for existing codes in conventional languages
Composition of Parallel Components The composition (macro-parallelism) step has many excellent solutions
as this does not have the same drastic synchronization and correctness constraints as one has for scalable kernels• Unlike micro-parallelism step which has no very good solutions
Task parallelism in languages such as C++, C#, Java and Fortran90; General scripting languages like PHP Perl Python Domain specific environments like Matlab and Mathematica Functional Languages like MapReduce, F# HeNCE, AVS and Khoros from the past and CCA from DoE Web Service/Grid Workflow like Taverna, Kepler, InforSense KDE,
Pipeline Pilot (from SciTegic) and the LEAD environment built at Indiana University.
Web solutions like Mash-ups and DSS Many scientific applications use MPI for the coarse grain composition
as well as fine grain parallelism but this doesn’t seem elegant The new languages from Darpa’s HPCS program support task
parallelism (composition of parallel components) decoupling composition and scalable parallelism will remain popular and must be supported.
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Mashups v Workflow? Mashup Tools are reviewed at
http://blogs.zdnet.com/Hinchcliffe/?p=63 Workflow Tools are reviewed by Gannon and Fox
http://grids.ucs.indiana.edu/ptliupages/publications/Workflow-overview.pdf Both include scripting
in PHP, Python, sh etc. as both implement distributed programming at level of services
Mashups use all types of service interfaces and perhaps do not have the potential robustness (security) of Grid service approach
Mashups typically “pure” HTTP (REST)
Grid Workflow Data Assimilation in Earth Science Grid services triggered by abnormal events and controlled by workflow process real
time data from radar and high resolution simulations for tornado forecasts
Typical graphical interface to service composition
Taverna another well known Grid/Web Service workflow tool
Recent Web 2.0 visual Mashup tools include Yahoo Pipes and Microsoft Popfly
“Service Aggregation” in SALSA Kernels and Composition must be supported both inside
chips (the multicore problem) and between machines in clusters (the traditional parallel computing problem) or Grids.
The scalable parallelism (kernel) problem is typically only interesting on true parallel computers as the algorithms require low communication latency.
However composition is similar in both parallel and distributed scenarios and it seems useful to allow the use of Grid and Web composition tools for the parallel problem. • This should allow parallel computing to exploit large
investment in service programming environments Thus in SALSA we express parallel kernels not as traditional
libraries but as (some variant of) services so they can be used by non expert programmers
For parallelism expressed in CCR, DSS represents the natural service (composition) model.
Parallel Programming 2.0 Web 2.0 Mashups will (by definition the largest market)
drive composition tools for Grid, web and parallel programming
Parallel Programming 2.0 will build on Mashup tools like Yahoo Pipes and Microsoft Popfly
Yahoo Pipes
Inter-Service Communication Note that we are not assuming a uniform implementation of
service composition even if user sees same interface for multicore and a Grid• Good service composition inside a multicore chip can require
highly optimized communication mechanisms between the services that minimize memory bandwidth use.
• Between systems interoperability could motivate very different mechanisms to integrate services.
• Need both MPI/CCR level and Service/DSS level communication optimization
Note bandwidth and latency requirements reduce as one increases the grain size of services • Suggests the smaller services inside closely coupled cores and
machines will have stringent communication requirements.
Inside the SALSA Services We generalize the well known CSP (Communicating Sequential
Processes) of Hoare to describe the low level approaches to fine grain parallelism as “Linked Sequential Activities” in SALSA.
We use term “activities” in SALSA to allow one to build services from either threads, processes (usual MPI choice) or even just other services.
We choose term “linkage” in SALSA to denote the different ways of synchronizing the parallel activities that may involve shared memory rather than some form of messaging or communication.
There are several engineering and research issues for SALSA• There is the critical communication optimization problem area for
communication inside chips, clusters and Grids. • We need to discuss what we mean by services• The requirements of multi-language support
Further it seems useful to re-examine MPI and define a simpler model that naturally supports threads or processes and the full set of communication patterns needed in SALSA (including dynamic threads).• Should start a new standards effort in OGF perhaps?
CICC Chemical Informatics and Cyberinfrastructure Collaboratory Web Service Infrastructure
Portal ServicesRSS FeedsUser ProfilesCollaboration as in Sakai
Core Grid ServicesService RegistryJob Submission and Management
Local ClustersIU Big Red, TeraGrid, Open Science Grid
Varuna.netQuantum Chemistry
Statistics Services Database Services
Core functionality Computation functionality 3D structures byFingerprints Regression CIDSimilarity Classification SMARTSDescriptors Clustering 3D Similarity2D diagrams Sampling distributionsFile format conversion
Docking scores/poses byApplications Applications CID
Docking Predictive models SMARTSFiltering Feature selection Protein
2D plots Docking scoresToxicity predictions
Anti-cancer activity predictionsCID, SMARTS
Cheminformatics Services
DruglikenessArbitrary R code (PkCell)
Mutagenecity predictionsPubChem related data by
Pharmacokinetic parametersOSCAR Document AnalysisInChI Generation/SearchComputational Chemistry (Gamess, Jaguar etc.)
Need to make all this parallel
Deterministic Annealing for Data Mining We are looking at deterministic annealing algorithms because
although heuristic• They have clear scalable parallelism (e.g. use parallel BLAS)• They avoid (some) local minima and regularize ill defined
problems in an intuitively clear fashion• They are fast (no Monte Carlo)• I understand them and Google Scholar likes them
Developed first by Durbin as Elastic Net for TSP Extended by Rose (my student then; now at UCSB)) and Gurewitz
(visitor to C3P) at Caltech for signal processing and applied later to many optimization and supervised and unsupervised learning methods.
See K. Rose, "Deterministic Annealing for Clustering, Compression, Classification, Regression, and Related Optimization Problems," Proceedings of the IEEE, vol. 80, pp. 2210-2239, November 1998
High Level Theory Deterministic Annealing can be looked at from a Physics,
Statistics and/or Information theoretic point of view Consider a function (e.g. a likelihood) L({y}) that we
want to operate on (e.g. maximize)
Set L ({y},T) = L({y}) exp(- ({y} - {y})2 /T ) d{y}• Incorporating entropy term ensuring that one looks for most
likely states at temperature T• If {y} is a distance, replacing L by L corresponds to smearing
or smoothing it over resolution T Minimize Free Energy F = -Ln L ({y},T) rather than
energy E = -Ln L ({y}) • Use mean field approximation to avoid Monte Carlo
(simulated annealing)
Deterministic Annealing for Clustering I
Illustrating similarity between clustering and Gaussian mixtures Deterministic annealing for mixtures replaces by
and anneals down to mixture size
))2/(),(exp()(
with centers)(K MixtureGaussian Simple Compare
))(lnEnergy Free
)(),(
)/),(exp()(
where)(/)/),(exp()Pr(
CentersCluster and Points
1
2
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K
k kkiki
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kiki
K
k kii
ikiki
ki
yxEPxZ
xZTF
yxyxE
TyxExZ
xZTyxECx
yKxN
22 k Tk 22
Deterministic Annealing for Clustering II
This is an extended K-means algorithm Start with a single cluster giving as solution y1 as centroid For some annealing schedule for T, iterate above algorithm testing
correlation matrix in xi about each cluster center to see if “elongated” Split cluster if elongation “long enough”; splitting is a phase
transition in physics view You do not need to assume number of clusters but rather a final
resolution T or equivalent At T=0, uninteresting solution is N clusters; one at each point xi
N
i ki
N
i kiinew
k
old
kiold
kiki
Cx
Cxxy
yxZTyxECx
1
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)Pr(
)Pr( Calculate
),(/)/),(exp()Pr(with
Minimum evolving as temperature decreases Movement at fixed temperature going to local
minima if not initialized “correctly
Solve Linear Equations for each temperature
Nonlinearity removed by approximating with solution at previous higher temperature
DeterministicAnnealing
F({y}, T)
Configuration {y}
Clustering Data Cheminformatics was tested successfully with small datasets and
compared to commercial tools Cluster on properties of chemicals from high throughput
screening results to chemical properties (structure, molecular weight etc.)
Applying to PubChem (and commercial databases) that have 6-20 million compounds• Comparing traditional fingerprint (binary properties) with real-valued
properties GIS uses publicly available Census data; in particular the 2000
Census aggregated in 200,000 Census Blocks covering Indiana• 100MB of data
Initial clustering done on simple attributes given in this data• Total population and number of Asian, Hispanic and Renters
Working with POLIS Center at Indianapolis on clustering of SAVI (Social Assets and Vulnerabilities Indicators) attributes at http://www.savi.org) for community and decision makers• Economy, Loans, Crime, Religion etc.
Where are we? We have deterministically annealed clustering running well on 8-
core (2-processor quad core) Intel systems using C# and Microsoft Robotics Studio CCR/DSS
Could also run on multicore-based parallel machines but didn’t do this (is there a large Windows quad core cluster on TeraGrid?)• This would also be efficient on large problems
Applied to Geographical Information Systems (GIS) and census data• Could be an interesting application on future broadly deployed PC’s• Visualize nicely on Google Maps (and presumably Microsoft Virtual Earth)
Applied to several Cheminformatics problems and have parallel efficiency but visualization harder as in 150-1024 (or more) dimensions
Will develop a family of such parallel annealing data-mining tools where basic approach known for• Clustering• Gaussian Mixtures (Expectation Maximization)• and possibly Hidden Markov Methods
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Microsoft CCR• Supports exchange of messages between threads using named
ports• FromHandler: Spawn threads without reading ports• Receive: Each handler reads one item from a single port• MultipleItemReceive: Each handler reads a prescribed number of
items of a given type from a given port. Note items in a port can be general structures but all must have same type.
• MultiplePortReceive: Each handler reads a one item of a given type from multiple ports.
• JoinedReceive: Each handler reads one item from each of two ports. The items can be of different type.
• Choice: Execute a choice of two or more port-handler pairings• Interleave: Consists of a set of arbiters (port -- handler pairs) of 3
types that are Concurrent, Exclusive or Teardown (called at end for clean up). Concurrent arbiters are run concurrently but exclusive handlers are
• http://msdn.microsoft.com/robotics/
Preliminary Results• Parallel Deterministic Annealing Clustering in
C# with speed-up of 7 on Intel 2 quadcore systems
• Analysis of performance of Java, C, C# in MPI and dynamic threading with XP, Vista, Windows Server, Fedora, Redhat on Intel/AMD systems
• Study of cache effects coming with MPI thread-based parallelism
• Study of execution time fluctuations in Windows (limiting speed-up to 7 not 8!)
Machines UsedAMD4: HPxw9300 workstation, 2 AMD Opteron CPUs Processor 275 at 2.19GHz, 4 coresL2 Cache 4x1MB (summing both chips), Memory 4GB, XP Pro 64bit , Windows Server, Red HatC# Benchmark Computational unit: 1.388 µs
Intel4: Dell Precision PWS670, 2 Intel Xeon Paxville CPUs at 2.80GHz, 4 coresL2 Cache 4x2MB, Memory 4GB, XP Pro 64bitC# Benchmark Computational unit: 1.475 µs
Intel8a: Dell Precision PWS690, 2 Intel Xeon CPUs E5320 at 1.86GHz, 8 coresL2 Cache 4x4M, Memory 8GB, XP Pro 64bit C# Benchmark Computational unit: 1.696 µs
Intel8b: Dell Precision PWS690, 2 Intel Xeon CPUs E5355 at 2.66GHz, 8 coresL2 Cache 4x4M, Memory 4GB, Vista Ultimate 64bit, Fedora 7C# Benchmark Computational unit: 1.188 µs
Intel8c: Dell Precision PWS690, 2 Intel Xeon CPUs E5345 at 2.33GHz, 8 coresL2 Cache 4x4M, Memory 8GB, Red Hat 5.0, Fedora 7
Clustering algorithm annealing by decreasing distance scale and gradually finds more clusters as resolution improvedHere we see 10 clusters increasing to 30 as algorithm progresses
Renters
Total
Asian
Hispanic
Renters
IUB
Purdue
10 Clusters
Total
Asian
Hispanic
Renters
30 Clusters
In detail, different groups have different cluster centers
DSS Section
• We view system as a collection of services – in this case– One to supply data– One to run parallel clustering– One to visualize results – in this by spawning
a Google maps browser– Note we are clustering Indiana census data
• DSS is convenient as built on CCR
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1 10 100 1000 10000
Round trips
Av
era
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ime
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icro
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Timing of HP Opteron Multicore as a function of number of simultaneous two-way service messages processed (November 2006 DSS Release)
Measurements of Axis 2 shows about 500 microseconds – DSS is 10 times better
DSS Service Measurements
Clustering Problem
Deterministic Annealing • See K. Rose, "Deterministic Annealing for Clustering,
Compression, Classification, Regression, and Related Optimization Problems," Proceedings of the IEEE, vol. 80, pp. 2210-2239, November 1998
• Parallelization is similar to ordinary K-Means as we are calculating global sums which are decomposed into local averages and then summed over components calculated in each processor
• Many similar data mining algorithms (such as annealing for E-M expectation maximization) which have high parallel efficiency and avoid local minima
• For more details see – http://grids.ucs.indiana.edu/ptliupages/presentations/
Grid2007PosterSept19-07.ppt and– http://grids.ucs.indiana.edu/ptliupages/presentations/
PC2007/PC07BYOPA.ppt
Parallel MulticoreDeterministic Annealing Clustering
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Parallel Overheadon 8 Threads Intel 8b
Speedup = 8/(1+Overhead)
10000/(Grain Size n = points per core)
Overhead = Constant1 + Constant2/n
Constant1 = 0.05 to 0.1 (Client Windows) due to threadruntime fluctuations
10 Clusters
20 Clusters
Parallel Multicore Deterministic Annealing Clustering
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Increasing number of clusters decreases communication/memory bandwidth overheads
Parallel Overhead for large (2M points) Indiana Census clustering on 8 Threads Intel 8bThis fluctuating overhead due to 5-10% runtime fluctuations between threads
Parallel Multicore Deterministic Annealing Clustering
“Constant1”
Increasing number of clusters decreases communication/memory bandwidth overheads
Parallel Overhead for subset of PubChem clustering on 8 Threads (Intel 8b)
The fluctuating overhead is reduced to 2% (under investigation!)40,000 points with 1052 binary properties (Census is 2 real valued properties)
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Number of processors
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MPI Parallel Divkmeans clustering of PubChem
AVIDD Linux cluster, 5,273,852 structures (Pubchem compound collection, Nov 2005)
min_size ncpus wall_mins walltime1 20 676 11:16:061 40 444 7:24:241 60 379 6:18:411 80 353 5:53:00
100 20 462 7:41:58100 40 356 5:56:01100 40 356 5:55:47100 60 339 5:38:44100 80 337 5:36:53
1000 20 513 8:32:391000 40 376 6:16:251000 60 346 5:46:221000 80 346 5:45:40
Scaled Speed up Tests• The full clustering algorithm involves different values of the
number of clusters NC as computation progresses• The amount of computation per data point is proportional to NC
and so overhead due to memory bandwidth (cache misses) declines as NC increases
• We did a set of tests on the clustering kernel with fixed NC
• Further we adopted the scaled speed-up approach looking at the performance as a function of number of parallel threads with constant number of data points assigned to each thread– This contrasts with fixed problem size scenario where the number of
data points per thread is inversely proportional to number of threads• We plot Run time for same workload per thread divided by
number of data points multiplied by number of clusters multiped by time at smallest data set (10,000 data points per thread)
• Expect this normalized run time to be independent of number of threads if not for parallel and memory bandwidth overheads– It will decrease as NC increases as number of computations per points
fetched from memory increases proportional to NC
Intel 8-core C# with 80 Clusters: Vista Run Time Fluctuations for Clustering Kernel
• 2 Quadcore Processors
• This is average of standard deviation of run time of the 8 threads between messaging synchronization points
Number of Threads
Standard Deviation/Run Time
Intel 8 core with 80 Clusters: Redhat Run Time Fluctuations for Clustering Kernel
• This is average of standard deviation of run time of the 8 threads between messaging synchronization points
Number of Threads
Standard Deviation/Run Time
Basic Performance of CCR
MPI Exchange Latency in µs (20-30 µs computation between messaging)
Machine OS Runtime Grains Parallelism MPI Exchange Latency
Intel8c:gf12
(8 core 2.33 Ghz)
(in 2 chips)
Redhat MPJE (Java) Process 8 181
MPICH2 (C) Process 8 40.0
MPICH2: Fast Process 8 39.3
Nemesis Process 8 4.21
Intel8c:gf20
(8 core 2.33 Ghz)
Fedora MPJE Process 8 157
mpiJava Process 8 111
MPICH2 Process 8 64.2
Intel8b
(8 core 2.66 Ghz)
Vista MPJE Process 8 170
Fedora MPJE Process 8 142
Fedora mpiJava Process 8 100
Vista CCR (C#) Thread 8 20.2
AMD4
(4 core 2.19 Ghz)
XP MPJE Process 4 185
Redhat MPJE Process 4 152
mpiJava Process 4 99.4
MPICH2 Process 4 39.3
XP CCR Thread 4 16.3
Intel4 (4 core 2.8 Ghz) XP CCR Thread 4 25.8
SALSA Performance
The macroscopic inter-service DSS Overhead is about 35µs
DSS is composed from CCR threads that have4µs overhead for spawning threads in dynamic search applications20µs overhead for MPI Exchange
CCR Overhead for a computation of 23.76 µs between messaging
Rendezvous
Intel8b: 8 Core Number of Parallel Computations
(μs) 1 2 3 4 7 8
Spawned
Pipeline 1.58 2.44 3 2.94 4.5 5.06
Shift 2.42 3.2 3.38 5.26 5.14
Two Shifts 4.94 5.9 6.84 14.32 19.44
MPI
Pipeline 2.48 3.96 4.52 5.78 6.82 7.18
Shift 4.46 6.42 5.86 10.86 11.74
Exchange As Two Shifts
7.4 11.64 14.16 31.86 35.62
Exchange 6.94 11.22 13.3 18.78 20.16
Overhead (latency) of AMD4 PC with 4 execution threads on MPI style Rendezvous Messaging for Shift and Exchange implemented either as two shifts or as custom CCR pattern
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0 2 4 6 8 10
AMD Exch
AMD Exch as 2 Shifts
AMD Shift
Stages (millions)
Time Microseconds
Overhead (latency) of Intel8b PC with 8 execution threads on MPI style Rendezvous Messaging for Shift and Exchange implemented either as two shifts or as custom CCR pattern
0
10
20
30
40
50
60
70
0 2 4 6 8 10
Intel Exch
Intel Exch as 2 Shifts
Intel Shift
Stages (millions)
Time Microseconds
Basic Performance of MPI for C and Java
MPI Exchange Latency in µs (20-30 µs computation between messaging)
Machine OS Runtime Grains Parallelism MPI Exchange Latency
Intel8c:gf12
(8 core 2.33 Ghz)
(in 2 chips)
Redhat MPJE (Java) Process 8 181
MPICH2 (C) Process 8 40.0
MPICH2: Fast Process 8 39.3
Nemesis Process 8 4.21
Intel8c:gf20
(8 core 2.33 Ghz)
Fedora MPJE Process 8 157
mpiJava Process 8 111
MPICH2 Process 8 64.2
Intel8b
(8 core 2.66 Ghz)
Vista MPJE Process 8 170
Fedora MPJE Process 8 142
Fedora mpiJava Process 8 100
Vista CCR (C#) Thread 8 20.2
AMD4
(4 core 2.19 Ghz)
XP MPJE Process 4 185
Redhat MPJE Process 4 152
mpiJava Process 4 99.4
MPICH2 Process 4 39.3
XP CCR Thread 4 16.3
Intel4 (4 core 2.8 Ghz) XP CCR Thread 4 25.8
Cache Line Interference
Cache Line Interference• Early implementations of our clustering algorithm
showed large fluctuations due to the cache line interference effect discussed here and on next slide in a simple case
• We have one thread on each core each calculating a sum of same complexity storing result in a common array A with different cores using different array locations
• Thread i stores sum in A(i) is separation 1 – no variable access interference but cache line interference
• Thread i stores sum in A(X*i) is separation X
• Serious degradation if X < 8 (64 bytes) with Windows– Note A is a double (8 bytes)– Less interference effect with Linux – especially Red Hat
Time µs versus Thread Array Separation (unit is 8 bytes)
1 4 8 1024 Machine
OS
Run Time Mean Std/
Mean Mean Std/
Mean Mean Std/
Mean Mean Std/
Mean Intel8b Vista C# CCR 8.03 .029 3.04 .059 0.884 .0051 0.884 .0069 Intel8b Vista C# Locks 13.0 .0095 3.08 .0028 0.883 .0043 0.883 .0036 Intel8b Vista C 13.4 .0047 1.69 .0026 0.66 .029 0.659 .0057 Intel8b Fedora C 1.50 .01 0.69 .21 0.307 .0045 0.307 .016 Intel8a XP CCR C# 10.6 .033 4.16 .041 1.27 .051 1.43 .049 Intel8a XP Locks C# 16.6 .016 4.31 .0067 1.27 .066 1.27 .054 Intel8a XP C 16.9 .0016 2.27 .0042 0.946 .056 0.946 .058 Intel8c Red Hat C 0.441 .0035 0.423 .0031 0.423 .0030 0.423 .032 AMD4 WinSrvr C# CCR 8.58 .0080 2.62 .081 0.839 .0031 0.838 .0031 AMD4 WinSrvr C# Locks 8.72 .0036 2.42 0.01 0.836 .0016 0.836 .0013 AMD4 WinSrvr C 5.65 .020 2.69 .0060 1.05 .0013 1.05 .0014 AMD4 XP C# CCR 8.05 0.010 2.84 0.077 0.84 0.040 0.840 0.022 AMD4 XP C# Locks 8.21 0.006 2.57 0.016 0.84 0.007 0.84 0.007 AMD4 XP C 6.10 0.026 2.95 0.017 1.05 0.019 1.05 0.017
Cache Line Interference
• Note measurements at a separation X of 8 (and values between 8 and 1024 not shown) are essentially identical
• Measurements at 7 (not shown) are higher than that at 8 (except for Red Hat which shows essentially no enhancement at X<8)
• If effects due to co-location of thread variables in a 64 byte cache line, the array must be aligned with cache boundaries
– In early implementations we found poor X=8 performance expected in words of A split across cache lines
Inter-Service Communication Note that we are not assuming a uniform implementation of
service composition even if user sees same interface for multicore and a Grid• Good service composition inside a multicore chip can require
highly optimized communication mechanisms between the services that minimize memory bandwidth use.
• Between systems interoperability could motivate very different mechanisms to integrate services.
• Need both MPI/CCR level and Service/DSS level communication optimization
Note bandwidth and latency requirements reduce as one increases the grain size of services • Suggests the smaller services inside closely coupled cores and
machines will have stringent communication requirements.
Inside the SALSA Services We generalize the well known CSP (Communicating Sequential
Processes) of Hoare to describe the low level approaches to fine grain parallelism as “Linked Sequential Activities” in SALSA.
We use term “activities” in SALSA to allow one to build services from either threads, processes (usual MPI choice) or even just other services.
We choose term “linkage” in SALSA to denote the different ways of synchronizing the parallel activities that may involve shared memory rather than some form of messaging or communication.
There are several engineering and research issues for SALSA• There is the critical communication optimization problem area for
communication inside chips, clusters and Grids. • We need to discuss what we mean by services• The requirements of multi-language support
Further it seems useful to re-examine MPI and define a simpler model that naturally supports threads or processes and the full set of communication patterns needed in SALSA (including dynamic threads).• Should start a new standards effort in OGF perhaps?