I have python code that takes a bunch of tasks and distributes them to either different threads or different nodes on a cluster. I always end up writing a main script
driver.py, that takes two command line arguments:
--run-task. The first is just a wrapper that iterates through all tasks and then calls
driver.py --run-task with each task passed as argument. Example:
== driver.py == # Determine the current script DRIVER = os.path.abspath(__file__) (opts, args) = parser.parse_args() if opts.run_all is not None: # Run all tasks for task in opts.run_all.split(","): # Call driver.py again with a specific task cmd = "python %s --run-task %s" %(DRIVER, task) # Execute on system distribute_cmd(cmd) elif opts.run_task is not None: # Run on an individual task # code here for processing a task...
The user would then call:
$ driver.py --run-all task1,task2,task3,task4
And each task would get distributed.
distribute_cmd takes a shell executable command and sends in a system-specific way to either a node or a thread. The reason
driver.py has to find its own name and call itself is because
distribute_cmd needs an executable shell command; it cannot take a function name for example.
This consideration led me to this design, of a driver script having two modes and having to call itself. This has two complications: (1) the script has to find out its own path via
__file__ and (2) when making this into a Python package, it's unclear where
driver.py should go. It's meant to be an executable scripts, but if I put it in
scripts=, then I will have to find out where the scripts live (see correct way to find scripts directory from setup.py in Python distutils?). This does not seem to be a good solution.
What's an alternative design to this? Keep in mind that the distribution of tasks has to result in an executable command that can be passed as a string to