aivika: A multi-method simulation library

Aivika is a multi-method simulation library focused on discrete event simulation (DES) with partial support of system dynamics and agent-based modeling.

The library has the following features:

• allows defining recursive stochastic differential equations of system dynamics (unordered as in maths via the recursive do-notation);

• supports the event-driven paradigm of DES as a basic core for implementing other paradigms;

• supports extensively the process-oriented paradigm of DES with an ability to resume, suspend and cancel the discontinuous processes;

• allows working with the resources based on specified queue strategies (FCFS/FIFO, LCFS/LIFO, SIRO, static priorities and so on);

• allows customizing the infinite and finite queues based on strategies too;

• supports the resource preemption;

• allows defining a queue network based on streams of data (transacts) and their processors;

• allows simulating circuits with recursive links and delays;

• supports the activity-oriented paradigm of DES;

• supports basic constructs for the agent-based modeling such as agents, states, timeout and timer handlers;

• allows creating combined discrete-continuous models as all parts of the library are well integrated and this is reflected directly in the type system;

• the arrays of simulation variables are inherently supported;

• supports the Monte-Carlo simulation;

• the simulation model can depend on external parameters;

• uses extensively signals for notification;

• allows gathering statistics in time points;

• hides technical details in high-level simulation computations (monads, streams and arrows).

Aivika itself is a light-weight engine with minimal dependencies. However, it has additional packages [1, 2] that offer the following features:

• automating simulation experiments;

• saving the results in CSV files;

• plotting the deviation chart by rule 3-sigma, histogram, time series, XY chart;

• collecting the summary of statistical data;

• parallel execution of the Monte-Carlo simulation;

• has an extensible architecture.

The charting package has two interchangeable back-ends [3, 4], where one of them uses Cairo and it is more preferable.

The PDF documentation and installation instructions are available on the Aivika Wiki website [5].

Moreover, the method was generalized [6] and applied to nested simulation [7] and parallel distributed simulation [8].

The libraries were tested on Linux, Windows and OS X.

A more full information about Aivika is available on the project website [9].

[1] http://hackage.haskell.org/package/aivika-experiment

[2] http://hackage.haskell.org/package/aivika-experiment-chart

[3] http://hackage.haskell.org/package/aivika-experiment-cairo

[4] http://hackage.haskell.org/package/aivika-experiment-diagrams

[5] https://github.com/dsorokin/aivika/wiki

[6] http://hackage.haskell.org/package/aivika-transformers

[7] http://hackage.haskell.org/package/aivika-branches

[8] http://hackage.haskell.org/package/aivika-distributed

[9] http://www.aivikasoft.com/en/products/aivika.html

P.S. Aivika is actually a genuine female Mari name which is pronounced with stress on the last syllable.

• Simulation
  • Simulation.Aivika
    • Simulation.Aivika.Activity
      • Simulation.Aivika.Activity.Random
    • Simulation.Aivika.Agent
    • Simulation.Aivika.Arrival
    • Simulation.Aivika.Circuit
    • Simulation.Aivika.Cont
    • Simulation.Aivika.DoubleLinkedList
    • Simulation.Aivika.Dynamics
      • Simulation.Aivika.Dynamics.Extra
      • Simulation.Aivika.Dynamics.Memo
        • Simulation.Aivika.Dynamics.Memo.Unboxed
      • Simulation.Aivika.Dynamics.Random
    • Simulation.Aivika.Event
    • Simulation.Aivika.Gate
    • Simulation.Aivika.Generator
    • Simulation.Aivika.Net
      • Simulation.Aivika.Net.Random
    • Simulation.Aivika.Operation
      • Simulation.Aivika.Operation.Random
    • Simulation.Aivika.Parameter
      • Simulation.Aivika.Parameter.Random
    • Simulation.Aivika.PriorityQueue
      • Simulation.Aivika.PriorityQueue.Pure
    • Simulation.Aivika.Process
      • Simulation.Aivika.Process.Random
    • Simulation.Aivika.Processor
      • Simulation.Aivika.Processor.Random
      • Simulation.Aivika.Processor.RoundRobbin
    • Simulation.Aivika.Queue
      • Simulation.Aivika.Queue.Base
      • Simulation.Aivika.Queue.Infinite
        • Simulation.Aivika.Queue.Infinite.Base
    • Simulation.Aivika.QueueStrategy
    • Simulation.Aivika.Ref
      • Simulation.Aivika.Ref.Base
    • Simulation.Aivika.Resource
      • Simulation.Aivika.Resource.Base
      • Simulation.Aivika.Resource.Preemption
        • Simulation.Aivika.Resource.Preemption.Base
    • Simulation.Aivika.Results
      • Simulation.Aivika.Results.IO
      • Simulation.Aivika.Results.Locale
      • Simulation.Aivika.Results.Transform
    • Simulation.Aivika.Server
      • Simulation.Aivika.Server.Random
    • Simulation.Aivika.Signal
    • Simulation.Aivika.Simulation
    • Simulation.Aivika.Specs
    • Simulation.Aivika.Statistics
      • Simulation.Aivika.Statistics.Accumulator
    • Simulation.Aivika.Stream
      • Simulation.Aivika.Stream.Random
    • Simulation.Aivika.SystemDynamics
    • Simulation.Aivika.Table
    • Simulation.Aivika.Task
    • Simulation.Aivika.Transform
      • Simulation.Aivika.Transform.Extra
      • Simulation.Aivika.Transform.Memo
        • Simulation.Aivika.Transform.Memo.Unboxed
    • Simulation.Aivika.Unboxed
    • Simulation.Aivika.Var
      • Simulation.Aivika.Var.Unboxed
    • Simulation.Aivika.Vector
      • Simulation.Aivika.Vector.Unboxed