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Diapositiva 1

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2nd General Meeting CINA Bologna Maurice H. ter Beek, Fabio Gadducci and Francesco Santini ISTI-CNR, Pisa Universit di Pisa IIT-CNR, Pisa Dynamic reconfigurations ... – PowerPoint PPT presentation

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Title: Diapositiva 1


1
Validating Reconfigurations of Reo Circuits
2nd General Meeting CINA Bologna
Maurice H. ter Beek, Fabio Gadducci and Francesco
Santini
ISTI-CNR, Pisa Università di Pisa IIT-CNR,
Pisa
2
Intro and Motivations
  • Dynamic reconfigurations of Reo circuits
  • Reo circuits formally model the coordination
    among components
  • Graph transformation techniques formally model
    reconfigurations
  • Reconfiguration is triggered by events
  • In our scenario, when system buffers become
    congested
  • Applied to a critical scenario in Finance (Credit
    Suisse)
  • The e-banking infrastructure can start loosing
    orders (i.e. money)
  • Different infrastructures can be considered to
    save money
  • A first simulation was presented at ESM12 (Risk
    Analysis)
  • This research was presented at ISARCS13
    (Architecting Critical Systems)

3
Simulation
  • Beside a formal definition of coordination (Reo)
    and graph rewriting (DPO), we performed a
    simulation, to check how reconfiguring works in
    practice
  • Modelica (for complex physical systems) and
    Dymola tool

4
Outline
  • Introduction
  • Reo
  • Graph Transformation
  • Modelica Simulation Language
  • Simulation
  • Conclusion
  • Future Work

5
In a Nutshell
Reo
Modelica
Graph Rewriting
Simulation
6
Reo Arbab04
  • A graphical language it implements the
    composition of channels into circuits
  • A circuit describes exogenous coordination
  • Components (software) are not aware of how
    interaction works
  • Circuits made of nodes and (open-ended set of)
    channels
  • Nodes are where different channels are
    synchronized
  • Components write/take data to/from circuits
    boundary nodes
  • Every circuit defines an interface through its
    boundary nodes
  • Semantics (also) based on constraint automata
    Baier et al.06

7
Reo channels
8
Example with Writer/Reader
Writer
Reader
A
B

s
9
Examples
1) a XOR
2)
10
Algebraic Graph Transformation
  • Rewrite (parts of) circuits by manipulating
    graphical structures
  • Already proposed for Reo in Krause11 and
    Krause et al.13
  • Set of rewrite rules that state the objects to be
    modified
  • L ? R (pattern graph ? replacement graph), K
    invariant/gluing graph
  • Search occurrence of pattern graph L in G, then
    replace it to obtain H
  • DPO approach a rule is a pair of morphisms l L
    ? K, r K ? R in the graphs category denoting how
    graph L is rewritten into graph R while
    intermediate graphs store connection between
    items of LHS and RHS

11
Case1
12
Case 2
13
Rewriting Rule 1
14
Rewriting Rule 2
15
Rewriting Rule 3
16
Modelica
  • Modelica is an object-oriented, declarative,
    modeling language for component-oriented modeling
    of complex systems, e.g. systems containing
    mechanical, electrical, electronic, hydraulic,
    thermal, control, electric power or
    process-oriented subcomponents

17
Modelica (2)
  • An object oriented, modeling language
  • Modelica classes are not compiled in the usual
    sense, but they are translated into objects which
    are then exercised by a simulation engine
  • The primary content of classes are equations x
    y 3 z
  • They express equalities (not assignments)
  • The simulation engine discovers the order of
    execution and which components in the equation
    are inputs and which are outputs
  • Algorithmic parts can be present as well
  • Open (OpenModelica) and commercial front-ends
  • Dymola Dynasim AB (now part of Dassault Systèmes)

18
Case 1 (Modelica)
19
Case 2 (Modelica)
20
Aggregating Values
21
Rewriting (Modelica)
fifoCongestion gt a
1) open 2) case1or2
1) fifoCongestion
22
Simulation
fifoCapacity 100
When (fifoCongestion 10) then (switch from
case1 to case2)
10K orders, 1h
23
Conclusion and Future Work
  • Formal design of coordination among components
  • Easy to verify (e.g. model check) behaviour of
    coordination
  • Formal design of event-triggered rewriting of
    coordination
  • Simulation through an equation-based simulation
    language
  • Application to a critical e-banking system
  • To stress the infrastructure and have feedback on
    e.g. risk analysis
  • Test other coordination schemes
  • A link to Control Theory and Hybrid Simulation

24
Thank you for your time!
Contact/questions maurice.terbeek_at_isti.cnr.it
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