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Geoffrey Fox, Marlon Pierce Community Grids Lab Indiana University gcf@indiana

http://www.grid2002.org. Complexity Computational Environment, integrating data and simulation on the Grid: Multiscale computing JPL June 18 2003. Geoffrey Fox, Marlon Pierce Community Grids Lab Indiana University gcf@indiana.edu. http://academia.web.cern.ch/academia/lectures/grid/.

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Geoffrey Fox, Marlon Pierce Community Grids Lab Indiana University gcf@indiana

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  1. http://www.grid2002.org Complexity Computational Environment,integrating data and simulation on the Grid: Multiscale computingJPLJune 18 2003 Geoffrey Fox, Marlon Pierce Community Grids Lab Indiana University gcf@indiana.edu http://academia.web.cern.ch/academia/lectures/grid/

  2. Grid Backdrop from CT Project • Grid Computational Environment (GCE) for SERVOGrid based on Web services (WS) • Job submission Job management, simple security (to be addressed), File processing • Support as WS key simulation and Pattern recognition codes (DISLOC*, SIMPLEX*, VC, PARK, GEOFEST*, DAHMM, PDPC) • *Current • Support databases and visualization • Simple workflow, notification, metadata services • Initial Schema for GEM specific (meta-)data • Portlet based Interfaces • Extend to ACES (Japan, Australia) for distributed computers, software, databases, clients • Collaboration and other useful portlets • Can inherit Globus support from Alliance Portal, NMI efforts

  3. AIST Additions • Compatibility with Grid Services • Use of OGSA-DAI XML and SQL database standards • Including extensions for streaming (sensor) data • Including extensions for integration with simulations • Optimization for parallel simulations (e.g. parallel IO) (?) • Better workflow, notification, metadata services • openGIS/GML compatibility (fault etc. Schema) • Semantic Grid • Autonomic (Robust Reliable Resilient) services (?) • Support multi-scale simulations and data assimilation • ServoPSE Problem Solving Environments (?) • GeoLanguage (ServoML specializing CCEML) integrating workflow and multi-scale support • Interactive portlet based front end with Matlab and/or Mathemetica style interface

  4. SERVOGrid Caricature RepositoriesFederated Databases Sensor Nets Streaming Data Database Database Analysis and Visualization Loosely Coupled Filters Closely Coupled Compute Nodes

  5. Sources of Grid Technology? • Grids support distributed collaboratories or virtual organizations that support People, Computers, Observational Data and results of thought and data processing • The Web and Web Services • Most important for Information Grids as these are naturally service-based • Distributed Objects (CORBA Java/Jini COM) • Distributed Object same as a Service • Globus Legion Condor NetSolve Ninf and other High Performance Computing activities • Compute/File Grids that need to be made into services (Globus GT3) and integrated with Information Grids for Geocomplexity • Peer-to-peer Networks

  6. Taxonomy of Grid Functionalities

  7. Application WS Approach WS linking to user and Other WS (data sources) Typicalcodes • Build on e-Science methodology and Grid technology • Geocomplexity (and Biocomplexity) applications with multi-scale models, scalable parallelism, data assimilation as key issues • Data-driven models for earthquakes • Use existing code/database technology (SQL/Fortran/C++) linked to “Application Web/OGSA services” • XML specification of models, computational steering, scale supported at “Web Service” level as don’t need “high performance” here • Allows use of Semantic Grid technology • AIST builds on CT

  8. Data Data Filter Filter Filter Data Filter Data OGSA-DAIGrid Services AnalysisControl Visualize Grid Data Filter This Type of Grid integrates with Parallel computing Multiple HPC facilities but only use one at a time Many simultaneous data sources and sinks HPC Simulation Grid Data Assimilation Other Gridand Web Services Distributed Filters massage data For simulation SERVOGrid (Complexity)Computing Model

  9. Data Assimilation • Data assimilation implies one is solving some optimization problem which might have Kalman Filter like structure • As discussed by DAO at Earth Science meeting, one will become more and more dominated by the data (Nobs much larger than number of simulation points). • Natural approach is to form for each local (position, time) patch the “important” data combinations so that optimization doesn’t waste time on large error or insensitive data. • Data reduction done in natural distributed fashion NOT on HPC machine as distributed computing most cost effective if calculations essentially independent • Filter functions must be transmitted from HPC machine

  10. Distributed Filtering Nobslocal patch >> Nfilteredlocalpatch≈ Number_of_Unknownslocalpatch In simplest approach, filtered data gotten by linear transformations on original data based on Singular Value Decomposition of Least squares matrix Send needed Filter Receive filtered data Nobslocal patch 1 Filter Data Nfilteredlocal patch 1 Geographically DistributedSensor patches Nobslocal patch 2 Filter Data Nfilteredlocal patch 2 HPC Machine Factorize Matrixto product of local patches Distributed Machine

  11. Grid Politics • There is a Global Grid Forum meeting 3 times per year with about 700 attendees per meeting • Exchange information and define standards for “everything” not done in W3C and OASIS • e.g. Grid Service, Security, What is a Job, Database, Computer, How to build portals …. • There is a large project called Globus developing software largely for “compute/file” Grids • There are some 50 Grid projects (mainly in Europe and USA) developing software and applications as well as installing infrastructure • Some are “deployment”: EDG NMI VDT ….. • There are related initiatives called CyberInfrastructure (NSF USA) and e-Science (UK) • There is a proposed OMII (Open Middleware Infrastructure Institute) – an international Alliance of separately funded projects with common coordination

  12. OGSA OGSI & Hosting Environments Not OGSA specific services Domain - Other models More specialized services: data Possibly OGSA replication, workflow, etc., etc. Broadly applicable services: registry, authorization, monitoring, data & other entities OGSA Environment Models for resources access, etc., etc. OGSI on Web Services Hosting Environment for WS Given to us from on high Network • Start with Web Services in a hosting environment • Add OGSI to get a Grid service and a component model • Add OGSA to get Interoperable Grid “correcting” differences in base platform and adding key functionalities

  13. OGSI Open Grid Service Interface • http://www.gridforum.org/ogsi-wg • It is a “component model” for web services. • It defines a set of behavior patterns that each OGSI service must exhibit. • Every “Grid Service” portType extends a common base type. • Defines an introspection model for the service • You can query it (in a standard way) to discover • What methods/messages a port understands • What other port types does the service provide? • If the service is “stateful” what is the current state? • Factory Model • A set of standard portTypes for • Message subscription and notification • Service collections • Each service is identified by a URI called the “Grid Service Handle” • GSHs are bound dynamically to Grid Services References (typically wsdl docs) • A GSR may be transient. GSHs are fixed. • Handle map services translate GSHs into GSRs.

  14. OGSA-DAI(Malcolm Atkinson Edinburgh) UK e-Science Grid Core Programme Development of Data Access and Integration Services for OGSA http://umbriel.dcs.gla.ac.uk/NeSC/general/projects/OGSA_DAI - Access to XML Databases - - Access to Relational Databases - - Distributed Query Processing (DB Federation) - - XML Schema Support for e-Science -

  15. DAI Key Services GridDataService GDS Access to data & DB operations GridDataServiceFactory GDSF Makes GDS & GDSF GridDataServiceRegistry GDSR Discovery of GDS(F) & Data GridDataTranslationService GDTS Translates or Transforms Data GridDataTransportDepot GDTD Data transport with persistence Integrated Structured Data Transport Relational & XML models supported Role-based Authorisation Binary structured files (later)

  16. Client Client Client Directory / File system XML database Grid Data Service Interface transparency: one GDS supports multiple database types Relational database

  17. Integration of Data and Filters WSDL Of Filter OGSA-DAI Interface Filter DB • One has the OGSA-DAI Data repository interface combined with WSDL of the (Perl, Fortran, Python …) filter • User only sees WSDL not data syntax • Some non-trivial issues as to where the filtering compute power is • Microsoft says filter next to data

  18. MultiScale Load Balancing Algorithms InfoGrid Grid Portals Parallel Computing Extended/Integrated VA+PARK+GEOFEST Integrated CCE Computer Science Large System Simulations Visualization e-ScienceCollaborationGrid Infrastructure Modeling Grid Clusters General Complex Systems Simulations Databases Geology GeoInformatics Other Fields X-Complexity Experiments Field Sensors/Satellites ComplexFluids BioComplexity Stock Market

  19. SERVOGrid Complexity Computing Environment Database Parallel SimulationService DatabaseService ComputeService Sensor Service Middle Tier with XML Interfaces ApplicationService-1 XML Meta-dataService ApplicationService-2 CCE Control Portal Aggregation ComplexitySimulationService ApplicationService-3 Users VisualizationService

  20. SERVOGrid Requirements • Seamless Access to Data repositories and large scale computers • Integration of multiple data sources including sensors, databases, file systems with analysis system • Including filtered OGSA-DAI • Rich meta-data generation and access with SERVOGrid specific Schema extending openGIS standards and using Semantic Grid • Portals with component model for user interfaces and web control of all capabilities • Collaboration to support world-wide work • Basic Grid tools: workflow and notification

  21. AWS AWS AWS AWS Database Portal such as “Jetspeed” Hosting Environment Hosting Environment GridComputing or ProgrammingEnvironments Application/User Framework supporting development and deployment of OGSI compliant AWS (Application Web Services) Generic Application Services Web Services OGSA Interoperability Layer “Core”Grid “Sophisticated” System Services OGSA Interoperability Layer Resource Grid Services e.g. DAI compliantdatabase Resources

  22. Taxonomy of Grid Operational Style

  23. Paradigms Protocols Platforms and Hosting • We can start from the Web view where the basic Grid paradigm is • Meta-data rich Web Services communicating via messages • These have some basic support from some runtime such as .NET, Jini (pure Java), Apache Tomcat+Axis (Web Service toolkit), Enterprise JavaBeans, WebSphere (IBM) or GT3 (Globus Toolkit 3) • These are the distributed equivalent of operating system functions as in UNIX Shell • Called Hosting Environment or platform

  24. Permeating Principles and Policies • Meta-data rich Message-linked Web Services as the permeating paradigm • “User” Component Model such as “Enterprise JavaBean (EJB)” or .NET. • Service Management framework including a possible Factory mechanism • High level Invocation Framework describing how you interact with system components. • This could for example be used to allow the system to built from either W3C or GGF style (OGSI) Web Services and to protect the user from changes in their specifications. • Security is a service but the need for fine grain selective authorization encourages • Policy context that sets the rules for each particular Grid. • Currently OGSA supports policies for routing, security and resource use. • The Grid Fabric or set of resources needs mechanisms to manage them. This includes automatic recording of meta-data and configuration of software. • Quality of service (QoS) for the Network and this implies performance monitoring and bandwidth reservation services. • Challenging as end-to-end and not just backbone QoS is needed. • Messaging systems like MQSeries from IBM provide robustness from asynchronous delivery and can abstract destination and allow customization of content such as converting between different interface specifications. • Messaging is built on transport mechanisms which can be used to support mechanisms to implement QoS and to virtualize ports

  25. Virtualization • The Grid could and sometimes does virtualize various concepts • Location: URI (Universal Resource Identifier) virtualizes URL • Replica management (caching) virtualizes file location generalized by GriPhyn virtual data concept • Protocol: message transport and WSDL bindings virtualize transport protocol as a QoS request • P2P or Publish-subscribe messaging virtualizes matching of source and destination services • Semantic Grid virtualizes Knowledge as a meta-data query • Brokering virtualizes resource allocation • Virtualization implies references can be indirect

  26. Interfaces and Functionality and Semantics I • The Grid platform tries to minimize detail in protocols and maximize detail in interfaces to enhance scaling • However rich meta-data and semantics are critical for correct and interesting operation • Put as much semantic interpretation as you can into specific services • Lack of Semantic interoperation is in fact main weakness of today’s Grids and Web services • Everything becomes a service whether system or application level • There are some very important “Global Services” • Discovery (look up) and Registration of service metadata • Workflow • MetaSchedulers

  27. Interfaces and Functionality and Semantics II • There are many other generally important services • OGSA-DAI The Database Service • Portal Service linked to by WSRP (Web services for Remote Portals) • Notification of events • Job submission • Provenance – interpret meta-data about history of data • File Interfaces • Sensor service – satellites … • Visualization • Basic brokering/scheduling

  28. Categories of Worldwide Grid Servicesto be exploited by SERVOGrid 1) Types of Grid R3 Lightweight P2P Federation and Interoperability 2) Core Infrastructure and Hosting Environment Service Management Component Model Service wrapper/Invocation Messaging 3) Security Services Certificate Authority Authentication Authorization Policy 4) Workflow Services and Programming Model Enactment Engines (Runtime) Languages and Programming Compiler Composition/Development 5) Notification Services 6) Metadata and Information Services Basic including Registry Semantically rich Services and meta-data Information Aggregation (events) Provenance 7) Information Grid Services OGSA-DAI/DAIT Integration with compute resources P2P and database models 8) Compute/File Grid Services Job Submission Job Planning Scheduling Management Access to Remote Files, Storage and Computers Replica (cache) Management Virtual Data Parallel Computing 9) Other services including Grid Shell Accounting Fabric Management Visualization Data-mining and Computational Steering Collaboration 10) Portals and Problem Solving Environments 11) Network Services Performance Reservation Operations

  29. Two-level Programming I Nugget Data • The paradigm implicitly assumes a two-level Programming Model • We make a Service (same as a “distributed object” or “computer program” running on a remote computer) using conventional technologies • C++ Java or Fortran Monte Carlo module • Data streaming from a sensor or Satellite • Specialized (JDBC) database access • Such nuggets accept and produce data from users files and databases • The Grid is built by coordinating such nuggets assuming we have solved problem of programming the nugget

  30. Two-level Programming II Nugget1 Nugget3 Nugget2 Nugget4 • The Grid is discussing the linkage and distribution of the nuggets with the onlyaddition runtime interfaces to Grid as opposed to UNIX data streams • Familiar from use of UNIX Shell, PERL or Python scripts to produce real applications from core programs • Such interpretative environments are the single processor analog of Grid Programming and this tends to be called workflow • Workflow is the composition of multiple services (programs) together to make a new service • Includes “Software Bus”, “Application Integration”, “Co-ordination Languages” etc.

  31. Workflow • Workflow has at least 4 parts • “Programming Environment” – typically GUI to drag and drop services and their linkages (familiar from AVS etc. which was workflow for visualization) • Language – from XML to extended Python • Compiler – converting Language into executable • Runtime controlling flow of information and notification events • Can use Python, Mathematica, Matlab, JavaSpaces, IBM BPEL4WS, DoE CCA etc. • Don’t think current systems are very near “what we will want” but expect much progress over next 3 years and plenty of systems to work with • Metadata critical to tell you how to combine services in a sensible way – so workflow engines must interface with metadata service

  32. Workflow GCEs and Problem Solving Environments (PSEs) • There is some confusion between fields of workflow (Grid Computing Environments GCE) and PSEs • To extent PSEs “just” allow manipulation of “nuggets”, they are indistinguishable from a domain specific GCE • They are distinct if they support intra nugget operations such as • Integration of mesh and simulation • Closely coupled code linkage • Generation of code from high level interface like Mathematica • Even in latter case, a new generation of PSEs should be built with Grid architecture – e.g. message based – and using Grid services like metadata and notification

  33. Jobs Tools Database Selected GeoInformatics Data Tool MetaData XML Meta-dataService MultiScale Ontologies Job MetaData Complexity Scripts Workflow SERVOPSE Programs using CCEML(SERVOML) SERVOGrid ComplexitySimulation Service Importance of Metadata Service; how should this be implemented?

  34. Metadata Approaches • Specialized services like UDDI and MDS (Globus) • Nobody likes UDDI • MDS uses LDAP • RGMA is MDS with a relational database backend • “By hand” as in current GEM Portal which is roughly same as using service stored SDE’s (Service Data Elements) as in OGSI • Some new MDS coming from Globus GT3? • Current MDS has both a Schema (insufficient for us) and a “database technology” • Semantic Grid technologies • Some basic XML database (Oracle, Xindice …) • If “OGSA compliant” (not defined yet), then doesn’t matter that much

  35. Workflow and SERVOGrid CCE • SERVOGrid should workflow technology to support both • “code and data coupling” (DISLOC with SIMPLEX etc.) • Multiscale features • Implementing multiscale model requires • building Web services for each model, • describing each model with metadata and • Describing linkage of models (linkage of ports on web services) • And describing when to use which scale model • So workflow and multiscale depend on web services described by rich metadata • This analysis isn’t correct if scales must be “tightly coupled” as current workflow won’t support this (CCA from DoE claims to address this but not clear if general) • We should focus on multiscale models with loose “nugget” coupling • Hopefully we will learn how to take same architecture, compile away inefficiencies and get high performance on tighter coupling than conventional distributed workflow

  36. Technologies under development at Indiana • Portal Infrastructure and Portlets integrating with rest of Globus/OGSA-DAI Community • Including job submission, management of modest meta-data and linkage to databases • Should package as “application web service toolkit” and test on ACES world wide iSERVOGrid • “Some” core portal Metadata (Semantic Grid) services • Messaging system between Web services that is useful for • “Service Management”/Autonomic Grids • Security • Notification service • Collaboration infrastructure and portlets

  37. WSDL W S Application orContent source R P Web Service Web Services as a Portlet Application as a WSGeneral Application PortsInterface with other WebServices • EachWeb Service naturally has a user interface specified as “just another port” • Customizable for universal access • This gives each Web Service a Portlet view specified (in XML as always) by WSRP (Web services for Remote Portals) • So component model for resources “automatically” gives a component model for user interfaces • When you build your application, you define portletat same time User Face ofWeb ServiceWSRP Ports define WS as a Portlet Web Services have other ports (Grid Service) to be OGSI compliant

  38. Online Knowledge Center built from Portlets A set of UIComponents • Web Services provide a component model for the middleware (see large “common component architecture” effort in Dept. of Energy) • Should match each WSDL component with a corresponding user interface component • Thus one “must use” a component model for the portal with again an XML specification (portalML) of portal component

  39. Sample page with several portlets: proxy credential manager, submission, monitoring

  40. Administer Grid Portal Provide information about application and host parameters Select application to edit

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