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The suite definition describes the static structure, its not until the definition is loaded in the server, that we see its dynamic behaviour.

With ecflow python api, the dynamic behaviour of the suite can be simulated, ( i.e. in the same manner as the server).

Simulation has the following benefits:

• Exercise the suite definition. There is no need for '.ecf' files
• Allows for very easy experimentation.
• Can be done on the client side, no need for server
• Can help in detecting deadlock's
• Will simulate with both 'real' and 'hybrid' clocks
• A year's simulation can be done in a few seconds
• Can be added as a unit test, to prevent regressions

The simulation relies on you adding simple verification attributes. (This is similar to c/c++/python asserts). These can be added on a task, family and suite nodes.(see below for an example)

There are however restrictions. If the definition has large loops due to, crons or  Repeat attributes, which run indefinitely, then in this case the simulation will never complete, and will timeout after a years worth of run time.

This can be compensated for by adding start and end clock. If no start/end clock is specified, the simulator makes the following assumption about the simulation period.

• No time dependencies - simulate for 24 hours.
• day attributes              - simulate for 1 week
• date attributes             - simulate for 1 month
• cron attributes             - simulate for 1 year
• repeat attributes          - simulate for 1 year

Additionally if time base attributes like, time,today,cron have no minutes, then the simulator will use 1 hour resolution.

Here is an example of a text based suite definition that use a verify attribute, for which we want check our assumption about the dynamic behaviour.

suite year            # use real clock otherwise the date wont change
 clock real 1.1.2017  # define a start date for deterministic simulation
 endclock   1.1.2018  # When to finish. A endclock is *ONLY* for use with the simulator.
 family cronFamily
  task t
   cron -d 1,2,3,4,5,6,7,8,9,10,11,12,13,14,15,16,17,18,19,20,21,22,23,24,25,26,27,28,29,30,31 -m 1,2,3,4,5,6,7,8,9,10,11,12 10:00 # run every day at 10am for a year
   verify complete:365 # verify that this task completes 365 times
 endfamily
endsuite

suite leap_year       # use real clock otherwise the date wont change
 clock real 1.1.2016  # define a start date for deterministic simulation 
 endclock   1.1.2017  # When to finish. A endclock is *ONLY* for use with the simulator.
 family cronFamily
  task t
   cron -d 1,2,3,4,5,6,7,8,9,10,11,12,13,14,15,16,17,18,19,20,21,22,23,24,25,26,27,28,29,30,31 -m 1,2,3,4,5,6,7,8,9,10,11,12 10:00  #  run every day at 10am for a year
   verify complete:366 # verify that this task completes 366 times in a leap year
 endfamily
endsuite

This python segment shows how to load a text based suite definition(cron.def) and simulate it in python.

import ecflow
defs = Defs("cron.def")
result = defs.simulate()    
assert len(result) == 0,  "Expected simulation to return without any errors, but found:\n" + result

If the simulation does not complete it will produce two files, which will help in the analysis:

• defs.depth: This file shows a depth first view, of why simulation did not complete.
• defs.flat: This shows a simple flat view, of why simulation did not complete

Both files will show which nodes are holding, and include the state of the holding trigger expressions.

Deadlock

This simulation is expected to fail, since we have a deadlock/ race condition

suite dead_lock
  family family
    task t1
      trigger t2 == complete
    task t2
      trigger t1 == complete
  endfamily
endsuite

import ecflow
defs = ecflow.Defs().add(
	     Suite("dead_lock").add(
            Family("family").add(
               Task("t1").add( Trigger("t2 == complete")),
               Task("t2").add( Trigger("t1 == complete")))))

theResult = defs.simulate(); # simulate the definition
assert len(theResult) != 0, "Expected simulation to return errors" 
print theResult