the lhc computing project common solutions for the lhc
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The LHC Computing Project Common Solutions for the LHC. ACAT 2002 Presented by Matthias Kasemann FNAL and CERN. Outline. The LCG Project: goal and organization Common solutions: Why common solutions How to … The Run2 common projects The LCG Project: status of planning - PowerPoint PPT PresentationTRANSCRIPT
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The LHC Computing ProjectCommon Solutions for the LHC
ACAT 2002
Presented by
Matthias KasemannFNAL and CERN
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Outline The LCG Project: goal and organization Common solutions:
Why common solutions How to … The Run2 common projects
The LCG Project: status of planning Results of the LCG workshop in March 02 Planning in the Applications Area
For the LCG Grid see: Les Robertson (Thursday)“The LHC Computing Grid Project - Creating a Global Virtual Computing Center for Particle Physics”
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From Raw Data to Physics:what happens during analysis
Fragmentation,DecayPhysics analysis
Interaction withdetector materialPattern,recognition,Particleidentification
Detectorresponseapplycalibration,alignment,
2037 2446 1733 16994003 3611 952 13282132 1870 2093 32714732 1102 2491 32162421 1211 2319 21333451 1942 1121 34293742 1288 2343 7142
Raw data
Convert tophysics quantities
ReconstructionSimulation (Monte-Carlo)
Analysis
e+
e-
f
fZ0
Basic physics
Results
250Kb – 1 Mb 100 Kb 25 Kb 5 Kb 500 b
_
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HEP analysis chain: common to LHC experiments
GenerateEvents
SimulateEvents
Simulationgeometry
BuildSimulationGeometry
Reconstuctiongeometry
BuildReconstructionGeometry
Detectordescription
Detectoralignment Detector
calibrationReconstruction
parameters
ReconstructEvents
ESDAOD
AnalyzeEvents
Physics
RawData
ATLASDetector
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Developing Software for LHC experiments
Challenges in big collaborations Long and careful planning process More formal procedure required to commit resources Long lifetime, need flexible solutions which allow for
change Any state of experiment longer than typical Ph.D. or
postdoc time Need for professional IT participation and support
New development, maintenance and support model required
Challenges in smaller collaborations Limited in resources Adapt and implement available solutions (“b-b-s”)
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CMS - CCS schedule (V33): the bottom line
Milestones of ~ next year: delays of ~9 months
Milestones a few yrs away: delays of ~15 months
LHC starts
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CMS - CCS Software Baseline: L2 milestonesDDD ready for OSCAR, ORCA, IGUANA•Data model defined•Persistent and transient representations•Demonstrably as correct as existing CMS description
Switch from Geant3 to Geant4: •Date not decided (just my estimate)•E.g. it needs the new persistency
Software Infrastructuredeployed and working
User analysis components•Framework with coherent user interface•Event display / interactive visualisation•Tools for browsing / manipulating data sets •Data presentation, histograms, numerical,…
Framework for processing CMS data•Working for simulation, reconstruction, analysis•Supporting persistency and data management•Strongly dependent on LCG success
CCS Baseline Software for TDR’s
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Work AreasApplications Support & CoordinationComputing SystemsGrid TechnologyGrid Deployment
Project Overview Board
Software andComputingCommittee
(SC2)
WP
RTAG
WP WP WP WP
ProjectExecution
BoardWork Plan Definition
The LHC Computing Grid Project (LCG)
Work AreasApplications Support & CoordinationComputing SystemsGrid TechnologyGrid Deployment
Common SolutinsExperiments and Regional Centres agree on requirements for common projects
LCG was approved in fall 2001
-resources contributed from
some member states
-1. Workshop in March 02
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LCG - Fundamental goal:The experiments have to get the best, most
reliable and accurate physics results from the data provided by their detectors
Their computing projects are fundamental to the achievement of this goal
The LCG project at CERN was set up to help them all in this task
CorollarySuccess of LCG is fundamental to success
of LHC Computing
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Fulfilling LCG Project Goals Prepare and deploy the LHC Computing Environment
Applications - provide the common components, tools and infrastructure for the physics application software
Computing system – fabric, grid, global analysis system Deployment – foster collaboration and coherence Not just another grid technology project
Validate the software by participating in Data Challenges using the progressively more complex Grid Prototype Phase 1 - 50% model production grid in 2004
Produce a TDR for full system to be built in Phase 2 Software performance impacts on size and cost of
production facility Analysis models impact on exploitation of production grid
Maintain opportunities for reuse of deliverables outside LHC experimental programme
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Applications Activity Areas
Application software infrastructure physics software development environment, standard
libraries, development tools
Common frameworks for simulation and analysis Development and integration of toolkits & components
Support for physics applications Development, support of common software tools &
frameworks
Adaptation of Physics Applications to Grid environment
Object persistency and data management tools Event data, metadata, conditions data, analysis objects,
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Goals for Applications Area
Many Software Production Teams LHC experiments CERN IT groups, ROOT team, .. HEP software collaborations – CLHEP, Geant4 , .. External Software – python, Qt, XML, …
Strive to work together to develop and use software in common
Will involve identifying and packaging existing HEP software for reuse as well as developing new components
Each unit has its own approach to design and to supporting the development Sharing in the development and deployment of software
will be greatly facilitated if units follow a common approach
Recognise that there will be start-up costs associated with adapting to use new common products and development tools
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Why common and when? Why not:
Experiments have independent detectors and analysis tools verify physics results
Competition for best physics results Coordination of common software development is
significant overhead Why common solutions:
Need mature engineered software Resources are scarce, in particular manpower Effort: Common projects are a good way to become
more efficient ( , , , ?) Lessons need to be learnt from past experience
For LHC experiments: Everything non experiment–specific is a
potential candidate for a common project
2 n 2nn1
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R2JOPSteering Committee
DirectorateD0 Collaboration CDF Collaboration
Task Coordinators
Run IICommittee
Run II ComputingProject Office
External Review Committee
Basic Infrastructure Mass Storage &Data Access
Reconstruction Systems
Physics AnalysisSupport
FermilabClass
LibraryConfigurationManagement
SupportDatabases
SimulationStorage
ManagementSerial Media
WorkingGroup
MSSHardware
Reconstructionfarm hardware
Networkinghardware
ProductionManagement
Reconstructioninput pipeline
Physics analysishardware
Physics Anal-ysis Software
VisualizationData Access
FNAL: CDF/D0/CD - Run 2 Joint Project Organization
15 joint projects defined,4 years before start of data taking
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Perceptions of Common Projects Experiments
Whilst may be very enthusiastic about long-term advantages ….
…have to deliver on short term milestones Devoting resources to both will be difficult Already experience an out-flux of effort into common
projects Hosting projects in experiments excellent way of
integrating effort For initial phase and prototyping
Technology groups Great motivation to use expertise to produce useful
solutions Need the involvement of the experiments
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Common solutions - How to do?
Requirements are set by experiments in the SC2 + Requirements Technical Assessment Groups (RTAGs)
Planning and implementation is done by LCG together with experiments
Monitoring of progress and adherence by the SC2
Frequent releases and testing Guaranteed life-time maintenance and supportIssues: ‘How will applications area cooperate with other
areas?’ ‘Not feasible to have a single LCG architect to cover
all areas.’ Need mechanisms to bring coherence to the project
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Workflow around the organisation chart
WPn PEB SC2 RTAGm
requirements
mandate
Prioritisedrequirements
Updated workplanWorkplan feedback
~2 mths
Project plan
Release 1
Release 2
~4 mths
Status report
Review feedbacktime
SC2 Sets the requirements
SC2 approves the workplan
SC2 reviews the status
PEB develops workplan
PEB manages LCG resources
PEB tracks progress
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Issues related to partitioning the work
‘How do you go from present to future without dismantling existing projects?’
‘Have to be careful that we don’t partition into too small chunks and lose coherence of overall software’
We are not starting afresh, we have a good knowledge of what the broad categories are going to be
Experiment architectures help to ensure coherency.
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Coherent Architecture Applications common projects must follow a
coherent overall architecture The software needs to be broken down into
manageable pieces i.e. down to the component level Component-based, but not a bag of disjoint
components components designed for interoperability through
clean interfaces Does not preclude a common implementation
foundation, such as ROOT, for different components The ‘contract’ in the architecture is to respect the
interfaces No hidden communication among components
Starting point is existing products, not a clean slate
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Approach to making workplan
“Develop a global workplan from which the RTAGs can be derived”
Considerations for the workplan: Experiment need and priority Is it suitable for a common project Is it a key component of the architecture e.g. object
dictionary Timing: when will the conditions be right to initiate a
common project Do established solutions exist in the experiments Are they open to review or are they entrenched
Availability of resources and allocation of effort Is there existing effort which would be better spent doing
something else Availability, maturity of associated third party software
E.g. grid software Pragmatism and seizing opportunity. A workplan derived from
a grand design does not fit the reality of this project
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RTAG: ‘blueprint’ of LCG application architecture
Mandate: define the architectural ‘blueprint’ for LCG applications: Define the main architectural domains (‘collaborating
frameworks’) of LHC experiments and identify their principal components. (For example: Simulation is such an architectural domain; Detector Description is a component which figures in several domains.)
Define the architectural relationships between these ‘frameworks’ and components, including Grid aspects, identify the main requirements for their inter-communication, and suggest possible first implementations. (The focus here is on the architecture of how major ‘domains’ fit together, and not detailed architecture within a domain.)
Identify the high-level milestones for each domain and provide a first estimate of the effort needed. (Here the architecture within a domain could be considered.)
Derive a set of requirements for the LCG Time-scale: started in June 02, draft report in July, final report in
August 02
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RTAG status Identified and started eight
Requirement Technical Assessments (RTAGs) in application software area
Data persistency finished Software support process and tools finished Mathematical libraries finished Detector Geometry & Materials descriptions started ‘blueprint’ architecture of applications started Monte Carlo event generators started
in compute fabric area mass storage requirements finished
in Grid technology and deployment area Grid technology use cases finished regional center category and services definition finished
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Software Process RTAG Mandate:
Define a process for managing LCG software. Specific tasks to include: Establish a structure for organizing software, for managing versions and coherent subsets for distribution
Identify external software packages to be supported Identify recommended tools for use within the project – to
include configuration and release management Estimate resources (person power) needed to run an LCG
support activity Guidance:
Procedures and tools will be specified Will be used within project Can be packaged and supported for general use Will evolve with time The RTAG does not make any recommendations on how
experiment internal software should be developed and managed. However, if an experiment specific program becomes an LCG product it should adhere to the development practices proposed by this RTAG
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All LCG projects must adopt the same set of tools, standards and procedures. The tools must be centrally installed, maintained and supported.
Adopt commonly used open-source or commercial software where available. Try to avoid “do it yourself” solutions in this area where we don’t have core competency.
Concerning commercial software, avoid commercial software that has to be installed on individual’s machines as this will cause well known problems of license agreements and management in our widely distributed environment. Commercial solutions for web-portals or other centrally managed solutions would be fine.
Process RTAG –Recommendations(1)
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Process RTAG –Recommendations(2)
‘Release early, release often’ implies major release 2-3 times per year Development release every 2-3 weeks Automated nightly builds, regression tests, benchmarks
Test and quality assurance Support of external software
installation and build up of local expertise Effort needed for filling support roles
Librarian Release manager Toolsmith Quality assurance Technical writer
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Persistency RTAG Mandate:
Write the product specification for the Persistency Framework for Physics Applications at LHC
Construct a component breakdown for the management of all types of LHC data
Identify the responsibilities of Experiment Frameworks, existing products (such as ROOT) and as yet to be developed products
Develop requirements/use cases to specify (at least) the metadata /navigation component(s)
Estimate resources (manpower) needed to prototype missing components
Guidance: The RTAG may decide to address all types of data, or may decide
to postpone some topics for other RTAGS, once the components have been identified.
The RTAG should develop a detailed description at least for the event data management.
Issues of schema evolution, dictionary construction and storage, object and data models should be addressed.
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Persistency – Near term recommendations
to develop a common object streaming layer and associated persistence infrastructure. a common object streaming layer based on ROOT-IO
and several related components to support it, including a (currently lightweight) relational
database layer. Dictionary services are included in the near-term
project specification. dictionary services may have additional clients
This is first step towards a complete data management environment, one with enormous potential for commonality among the experiments.
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RTAG: math library review
Mandate: Review the current situation with math libraries and make recommendations Review the current situation of the usage of the
various math libraries in the experiments (including but not limited to NagC++, GSL, CLHEP, ROOT)
Identify and recommend which ones should be adopted, which ones could be discontinued
Suggest possible improvements to the existing ones Estimate resources needed for this activity
Guidance – The result of the RTAG should allow to establish a clear program of work to streamline the status of math libraries and find the maximum commonality between experiments, taking into account cost, maintenance and projected evolution of the experiment needs
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Math Library: Recommendations
To design a support group to provide advice and information about the use of
existing libraries, to assure their continued availability, to identify where new functionality is needed, and to develop that functionality themselves or by
coordinating with other HEP-specific library developers. The goal would be to have close contact with the
experiments and provide expertise on mathematical methods, aiming at common solutions,
The experiments should maintain a data base of mathematical libraries used in their software, and within each library, the individual modules used.
A detailed study should be undertaken to determine whether there is any functionality needed by the experiments and available in the NAG library which is not covered as well by a free library such as GSL.
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RTAG: Detector Geometry & Materials Description
Write the product specification for detector geometry and materials description services. Specify scope: e.g. Services to define, provide transient
access to, and store the geometry and materials descriptions required by simulation, reconstruction, analysis, online and event display applications, with the various descriptions using the same information source
Identify requirements including end-user needs such as ease and naturalness of use of the description tools, readability and robustness against errors e.g. provision for named constants and derived quantities
Explore commonality of persistence requirements with conditions data management
Interaction of the DD with a conditions DB. In that context versioning and ‘configuration management’ of the detector description, coherence issues…
Identify where experiments have differing requirements and examine how to address them within common tools
Address migration from current tools
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RTAG:Monte Carlo Event Generators
Mandate: To best explore the common solutions needed and how to engage the HEP community external to the LCG it is proposed to study: How to maintain a common code repository for
the generator code and related tools such as PDFLIB. The development or adaptation of generator-related
tools (e.g.HepMC) for LHC needs. How to provide support for the tuning, evaluation
and maintenance of the generators. The integration of the Monte Carlo generators into
the experimental software frameworks. The structure of possible forums to facilitate
interaction with the distributed external groups who provide the Monte Carlo generators.
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Possible Organisation of activities
Project
WP WP WP
Project
WP
Project
WP WP
Project
WP WPWP
Overall management, coordination, architecture, integration, support
Activity area: Physics data managementPossible projects: Hybrid event store, Conditions DB, …Work Packages: Component breakdown and work plan lead to Work Package definitions. ~1-3 FTEs per WP
Activity areaActivity areaActivity area
Example:
Architect
Projectleader
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Global Workplan – 1st priority level
1. Establish process and infrastructure Nicely covered by software process RTAG
2. Address core areas essential to building a coherent architecture
Object dictionary – essential piece Persistency - strategic Interactive frameworks - also driven by assigning
personnel optimally3. Address priority common project opportunities
Driven by a combination of experiment need, appropriateness to common project, and ‘the right moment’ (existing but not entrenched solutions in some experiments)
Detector description and geometry model Driven by need and available manpower
Simulation tools
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Global Workplan – 2nd priority level
Build outward from the core top-priority components Conditions database Statistical analysis Framework services, class libraries
Address common project areas of less immediate priority Math libraries Physics packages (scope?)
Extend and elaborate the support infrastructure Software testing and distribution
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Global Workplan – 3rd priority level
The core components have been addressed, architecture and component breakdown laid out, work begun. Grid products have had another year to develop and mature. Now explicitly address physics applications integration into the grid applications layer. Distributed production systems. End-to-end grid
application/framework for production. Distributed analysis interfaces. Grid-aware analysis
environment and grid-enabled tools. Some common software components are now
available. Build on them. Lightweight persistency, based on persistency
framework Release LCG benchmarking suite
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Global Workplan – 4th priority level
Longer term items waiting for their moment ‘Hard’ ones, perhaps made easier by a growing
common software architecture Event processing framework
Address evolution of how we write software OO language usage
Longer term needs; capabilities emerging from R&D (more speculative)
Advanced grid tools, online notebooks, …
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Candidate RTAGs (1)Simulation tools Non-physics activityDetector description, model
Description tools, geometry model
Conditions database If necessary after existing RTAG
Data dictionary Key need for common serviceInteractive frameworks
What do we want, have, need
Statistical analysis Tools, interfaces, integrationVisualization Tools, interfaces, integrationPhysics packages Important area but scope
unclearFramework services If common framework is too
optimistic…C++ class libraries Standard foundation libraries
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Candidate RTAGs (2)Event processing framework
Hard, long term
Distributed analysis
Application layer over grid
Distributed production
Application layer over grid
Small scale persistency
Simple persistency tools
Software testing May be covered by process RTAG
Software distribution
From central ‘Program Library’ to convenient broad distribution
OO language usage C++, Java (..?) roles in the future
Benchmarking suite
Comprehensive suite for LCG software
Online notebooks Long term; low priority
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Common Solutions: Conclusions
Common Solutions for LHC software are required for success Common solutions are agreed upon by experiments The requirements are set by the experiments The development is done jointly by the LCG project and
the LHC experiments All LCG software is centrally supported and maintained.
What makes us believe that we succeed? What is key to success? The process in the LCG organization The collaboration between players Common technology Central resources, jointly steer-able by experiments and
management Participants have prototyping experience !!
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Backup & Additional slides
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Post-RTAG Participation of Architects – Draft Proposal (1)
Monthly open meeting (expanded weekly meeting) Accumulated issues to be taken up with architects Architects in attendance; coordinators invited
Information has gone out beforehand, so architects are ‘primed’
Meeting is informational, and decision-making (for the easier decisions) An issue is either
Resolved (the easy ones) Flagged for addressing in the ‘architects committee’
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Post-RTAG Participation of Architects – Draft Proposal (2)
Architects committee: Members: experiment architects + applications manager (chair) Invited: computing coordinators, LCG project manager and CTO Others invited at discretion of members
e.g. project leader of project at issue Meets shortly after the open meeting (also bi-weekly?) Decides the difficult issues
Most of the time, committee will converge on a decision If not, try harder If still not, applications manager takes decision
Such decisions can be accepted or challenged Challenged decisions go to full PEB, then if necessary to SC2
PEB role of raising issues to be taken up by SC2 We all abide happily by an SC2 decision
Committee meetings also cover general current issues and exchange of views Committee decisions, actions documented in public minutes
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Distributed Character of Components (1)
Persistency framework Naming based on logical filenames Replica catalog and management Cost estimators; policy modules
Conditions database Inherently distributed (but configurable for local
use) Interactive frameworks
Grid-aware environment; ‘transparent’ access to grid-enabled tools and services
Statistical analysis, visualization Integral parts of distributed analysis environment
Framework services Grid-aware message and error reporting, error
handling, grid-related framework services
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Distributed Character of Components (2)
Event processing framework Cf. framework services, persistency framework,
interactive frameworks Distributed analysis Distributed production Software distribution
Should use the grid OO language usage
Distributed computing considerations Online notebook
Grid-aware tool
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RTAG?: Simulation tools Geant4 is establishing a HEP physics requirements
body within the collaboration, accepted by SC2 as a mechanism for addressing G4 physics performance issues
However, there are important simulation needs to which LCG resources could be applied in the near term.
By the design of LCG, this requires SC2 delivering requirements to PEB
John Apostolakis has recently assembled G4 requests and requirements from the LHC collaborations
Proposal: Use these requirements as the groundwork for a quick 1-month RTAG to guide near term simulation activity in the project, leaving the addressing of physics performance requirements to the separate process within Geant4
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RTAG?: Simulation tools (2)
Some possible activity areas in simulation, from the Geant4 requests/requirements received from the experiments, which would be input to the RTAG: Error propagation tool for reconstruction (‘GEANE’) Assembly and documentation of standard physics lists Python interface Documentation, tutorials, communication Geant4 CVS server access issues
The RTAG could also address FLUKA support Requested by ALICE as an immediate priority Strong interest expressed by other experiments as well
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RTAG?: Detector geometry & materials description and modeling services
Write the product specification for detector geometry and materials description and modeling services Specify scope: eg. Services to define, provide transient
access to, and store the geometry and materials descriptions required by simulation, reconstruction, analysis, online and event display applications, with the various descriptions using the same information source
Identify requirements including end-user needs such as ease and naturalness of use of the description tools, readibility and robustness against errors e.g. provision for named constants and derived quantities
Explore commonality of persistence requirements with conditions data management
Identify where experiments have differing requirements and examine how to address them within common tools
Address migration from current tools
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RTAG?: Conditions database
Will depend on persistency RTAG outcome Refine the requirements and product specification
of a conditions database serving the needs of the LHC experiments, using the existing requirements and products as a reference point. Give due consideration to effective distributed/remote usage.
Identify the extent to which the persistency framework (hybrid store) can be directly used at the lower levels of a conditions database implementation.
Identify the component(s) and interfaces atop a common persistency foundation that complete the conditions database
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RTAG?: Data dictionary service
Can the experiments converge on common data definition and dictionary tools in the near term?
Even if the answer is no, it should be possible to establish a standard dictionary service (generic API) by which common tools can interact, while leaving free to the experiments how their class models are defined and implemented
Develop a product specification for a generic high-level data dictionary service able to accommodate distinct data definition and dictionary tools and present a common, generic interface to the dictionary
Review the current data definition and dictionary approaches and seek to expand commonality among the experiments. Write the product specifications for common (even if N<4) components.
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CERN
, Jun
e 25
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50/39
RTAG?: Interactive frameworks
Frameworks providing interactivity for various environments including physics analysis and event processing control (simulation and reconstruction) are critical. They serve end users directly and must match end user requirements extremely well. They can be a powerful and flexible ‘glue’ in a modular environment, providing interconnectivity between widely distinct components and making the ‘whole’ offered by such an environment much greater than the sum of its parts.
Develop the requirements for an interactive framework common across the various application environments
Relate the requirements to existing tools and approaches (e.g. ROOT/CINT, Python-based tools)
Write a product specification, with specific recommendations on tools and technologies to employ
Address both command line and GUI interactivity
Mat
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and
CERN
, Jun
e 25
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51/39
RTAG?: Statistical analysis interfaces & tools
Address requirements on analysis tools What data analysis services and tools are required What is and is not provided by existing tools
Address what existing tools should be supported and what further development is needed
Including long term maintenance issues Address role of abstract interfaces to statistical
analysis services Are they to be used? If so, what tools should be interfaced to a common
abstract interface to meet LHC needs (and how, when, etc.)
Address requirements and approaches to persistency and data interchange
Mat
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CERN
, Jun
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52/39
RTAG?: Detector and event visualization
Examine the range of tools available and identify those which should be developed as common components within the LCG Applications architecture
Address requirements, recommendations and needed/desired implementations in such areas as existing and planned standard interfaces and their
applicability GUI integration Interactivity requirements (picking) Interface to visualizing objects (eg. Draw() method) Use of standard 3D graphics libraries
Very dependent on other RTAG outcomes
Mat
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CERN
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53/39
RTAG?: Physics packages Needs and requirements in event generators and
their interfaces & persistency, particle property services, …
Scope of the LCG in this area needs to be made clearer before a well defined candidate RTAG can be developed
Mat
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CERN
, Jun
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54/39
RTAG?: Framework services
While converging on a common event processing framework among the LHC experiments may be impractical at least on the near term, this does not preclude adopting common approaches and tools for Framework services
Examples: message handling and error reporting; execution monitoring and state management; exception handling and recovery; job state persistence and recording of history information; dynamic component loading; interface definition, versioning, etc.
Seek to identify framework services and tools which can be developed in common, possibly starting from existing products.
Develop requirements on their functionality and interfaces.
Mat
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and
CERN
, Jun
e 25
, 200
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55/39
RTAG?: C++ class libraries
Address needs and requirements in standard C++ class libraries, with recommendations on specific tools
Provide recommendations on the application and evolution of community libraries such as ROOT, CLHEP, HepUtilities, …
Survey third party libraries and provide recommendations on which should be adopted and what should be used from them
Merge with Framework Services candidate RTAG?
Mat
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n, F
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and
CERN
, Jun
e 25
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56/39
RTAG?: Event processing framework
There is no consensus to pursue a common event processing framework in the near term. There is perhaps more agreement that this should be pursued in the long term (but there’s no consensus on a likely candidate for a common framework in the long term)
This looks at best to be a long term RTAG Two experiments do use a common event
processing framework kernel (Gaudi) Many difficult issues in growing N past 2, whether
with Gaudi, AliRoot, COBRA or something else!
Mat
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CERN
, Jun
e 25
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57/39
RTAG?: Interfaces to distributed analysis
Develop requirements on end-user interfaces to distributed analysis, layered over grid middleware services, and write a product specification Grid portals, but not only; e.g. PROOF and Jas fall
into this category A grid portal for analysis is presumably an evolution
of tools like these Focus on analysis interface; address the distinct
requirements of production separately Production interface should probably be addressed
first, as it is simpler and will probably have components usable as parts of the analysis interface
Mat
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CERN
, Jun
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58/39
RTAG?: Distributed production systems
Distributed production systems will have much common ground at the grid middleware level. How much can be done in common at the higher level of end-to-end distributed production applications layered over the grid middleware?
Recognizing that the grid projects are active at this level too, and coordination is needed
Survey existing and planned production components and end-to-end systems at the application level (AliEn, MOP, etc.) and identify tools and approaches to develop in common
Write product specifications for common components, and/or explicitly identify specific tools to be adapted and developed as common components
Include end user (production operations) interface Grid portal for production
Mat
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CERN
, Jun
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59/39
RTAG?: Small-scale persistency & databases
If not covered by the existing persistency RTAG, and if there is agreement this is needed…
Write the product specification for a simple, self-contained, low-overhead object persistency service for small-scale persistency in C++ applications
Marshal objects to a byte stream which may be stored on a file, in an RDBMS record, etc.
In implementation, very likely a simplified derivative of the object streamer of the hybrid store
For small scale persistence applications, e.g. saving state, saving configuration information
Examine the utility of and requirements on a simple, standard, easily installed and managed database service complementing the persistency service for small scale applications
MySQL, PostgreSQL etc are casually adopted for simple applications with increasing frequency. Is it possible and worthwhile to converge on a common database service
Mat
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CERN
, Jun
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60/39
RTAG?: Software testing tools & services
How much commonality can be achieved in the infrastructure and tools used Memory checking, unit tests, regression tests,
validation tests, performance tests A large part of this has been covered by the
process RTAG
Mat
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CERN
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61/39
RTAG?: Software distribution
May or may not be adequately addressed in the process RTAG
Requirements for a central distribution point at CERN A ‘CERN LHC Program Library Office’
Requirements on software distribution taking into account all tiers
Survey and recommend on the various approaches, their utility, complementarity Tarballs (DAR) RPMs and other standard open software tools Role of AFS, asis Higher level automated distribution tools (pacman)
Mat
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CERN
, Jun
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62/39
RTAG?: Evolution of OO language usage
Long-term evolution of C++ Role for other language(s), e.g. Java?
Near, medium and (to the extent possible) long term application of other languages among LHC experiments
Implications for tools and support requirements Identify any requirements arising
Applications, services to be developed in common Third party tools to be integrated and supported Compilers and other infrastructure to be supported Libraries required
Mat
thia
s Kas
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n, F
NAL
and
CERN
, Jun
e 25
, 200
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63/39
RTAG?: LCG Benchmarking suite
Below threshold for an RTAG? Every LCG application should come with a
benchmarking suite, and should be made available and readily usable as part of a comprehensive benchmarking suite
Develop requirements for a comprehensive benchmarking suite of LCG applications for use in performance evaluation, testing, platform validation and performance measurement, etc. Tools which should be represented Tests which should be included Packaging and distribution requirements
Mat
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CERN
, Jun
e 25
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64/39
RTAG?: Online notebooks and other remote control / collaborative tools
Identify near term and long term needs and requirements common across the experiments
Survey existing, planned tools and approaches Develop recommendations for common
development/adaptation and support of tools for LHC