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135 lines
4.7 KiB
135 lines
4.7 KiB
****************************
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Getting Started
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****************************
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Before starting with this guide, one should follow the instructions for :doc:`installation`.
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A Quick Tour through Stormpy
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================================
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This guide is intended for people which have a basic understanding of probabilistic models and their verification. More details and further pointers to literature can be found on the
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`storm website <https://moves-rwth.github.io/storm>`_.
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While we assume some very basic programming concepts, we refrain from using more advanced concepts of python throughout the guide.
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We start with a selection of high-level constructs in stormpy, and go into more details afterwards.
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.. seealso:: The code examples are also given in the examples/ folder. These boxes throughout the text will tell you which example contains the code discussed.
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In order to do this, we import stormpy::
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import stormpy
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import stormpy.core
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Building models
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------------------------------------------------
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.. seealso:: ``01-getting-started.py``
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There are several ways to create a Markov chain.
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One of the easiest is to parse a description of such a Markov chain and to let storm build the chain.
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Here, we build a Markov chain from a prism program.
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Stormpy comes with a small set of examples, which we use here::
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import stormpy.examples
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import stormpy.examples.files
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With this, we can now import the path of our prism file::
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path = stormpy.examples.files.prism_dtmc_die
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prism_program = stormpy.parse_prism_program(path)
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The `prism_program` can be translated into Markov chains::
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model = stormpy.build_model(prism_program)
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print("Number of states: {}".format(model.nr_states)) # out: 13
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print("Number of states: {}".format(model.nr_states)) # out: 20
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This tells us that the model has 13 states and 20 transitions.
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Moreover, initial states and deadlocks are indicated with a labelling function. We can see the labels present in the model by::
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print("Labels: {}".format(model.labels) # out: {"init", "deadlock"}
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We will investigate ways to examine the model in more detail in :ref:`getting-started-investigating-the-model`
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Building properties
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--------------------------
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.. seealso:: ``02-getting-started.py``
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Storm takes properties in the prism-property format.
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To express that one is interested in the reachability of any state where the prism program variable s is 2, one would formulate::
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P=? [F s=2]
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Stormpy can be used to parse this. As the variables in the property refer to a program, the program has to be passed as an additional parameter::
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formula_str = "P=? [F s=2]"
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properties = parse_properties_for_prism_program(formula_str, prism_program)
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Notice that properties is now a list of properties containing a single element.
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However, if we build the model as before, then the appropriate information that the variable s=2 in some states is not present.
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In order to label the states accordingly, we should notify storm upon building the model that we would like to preserve given properties.
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Storm will then add the labels accordingly::
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model = stormpy.build_model(prism_program, properties)
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print("Labels: {}".format(model.labels) # {"init", "deadlock", "s=2"})
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Model building however now behaves slightly different: Only the properties passed are preserved, which means that model building might skip parts of the model.
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In particular, to check the probability of eventually reaching a state x where s=2, successor states of x are not relevant::
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print("Number of states: {}".format(model.nr_states)) # out: 8
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If we consider another property, however, such as::
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P=? [F s=7 & d=2]
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then storm is only skipping exploration of successors of the particular state y where s=7 and d=2. In this model, state y has a self-loop, so effectively, the whole model is explored.
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Checking properties
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------------------------------------
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.. seealso:: ``03-getting-started.py``
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The last lesson taught us to construct properties and models with matching state labels.
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Now default checking routines are just a simple command away::
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properties = parse_properties_for_prism_program(formula_str, prism_program)
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model = stormpy.build_model(prism_program, properties)
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result = stormpy.model_checking(model, properties[0])
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The result may contain information about all states. Merely printing does not give all information in there::
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print(result) # out: [0,1] range
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Instead, we can iterate over the results:
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Instantiating parametric models
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------------------------------------
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.. seealso:: ``04-getting-started.py``
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Checking parametric models
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------------------------------------
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.. seealso:: ``05-getting-started.py``
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.. _getting-started-investigating-the-model:
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Investigating the model
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-------------------------------------
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