how to use Graph Theory for scheduling execution order?

Question

I am designing an application, which executes a series of plugins. A plugin's execution might/might not be dependent on another/other plugins execution. i.e some (not all) of the plugins expect other plugin(s) to be executed before it begins its execution.

I need to derive the correct order of execution such that no plugin gets executed before the plugin it's depending on.

I believe graph theory can be used to solve this (plugins as vertex, dependency as edge, and derive execution order using some sort of traversal).

I am planning to use JGraphT since the application is being developed in Java.

Any help or pointers to solve the case ??? i am not expecting whole java code, any pointers about graph theory (algorithms to use) will be equally helpfull ....

Thanks !!!

[solution:] @Artium lead to the solution, this link shows a very similar implementation.

Answer 1

I would suggest a topological sort.

And after a quick check, it is easy to do with JGraphT. Also notice:

For this iterator to work correctly the graph must be acyclic, and must not be modified during iteration. Currently there are no means to ensure that, nor to fail-fast; the results with cyclic input (including self-loops) or concurrent modifications are undefined. To precheck a graph for cycles, consider using CycleDetector or StrongConnectivityInspector.

Answer 2

I would suggest a simple load-on-demand approach, load all plugins a plugin depends on if not already loaded.

A few observations:

1. If the dependency tree is very deep (> 1,000 plugins), this could result in a StackOverflowException
2. This solution is thread-safe assuming all plugins are loaded one by one and synchronously
3. Finding illegal cycles in the "graph" is handled by using a starting flag that is set to true before loading all dependencies and set back to false only after the plugin is initialized
4. This case handles the situation when a plugin explicitly starts another plugin (not as part of its dependencies -- but it does not account for asynchronous initialization)

Here is an untested sample to give an idea:

class Plugin {
    Set<Plugin> dependencies;
    boolean started, starting;

    Plugin(Set<Plugin> deps) { dependencies = deps; }

    void start() {
        if (started) { /* already initialized */ }
        else if (starting) { throw new IllegalArgumentException("Cyclic plugin dependency"); }
        else {
            starting = true;
            for (Plugin p : dependencies) { p.start(); }
            /* initialize this plugin here */
            starting = false;
            started = true;
        }
    }
}