- Our algorithm needs to receive a query in a DAG structure and outputs list of hits that satisfies the graph.
- Each edge in the graph points to a unique list of objects to be filtered.
- Each object has two values, say HEAD and TAIL.
- Connected nodes by the directed edges in the graph resemble HEADs and TAILs of these objects.
- For example, a query DAG of three connected nodes requires two objects (one from each edge's list) where one's HEAD equals the other's TAIL.
- And so on with more complex DAG queries.
- Hence, the role of the algorithm is to return all possible object permutations that fulfill the HEAD/TAIL sharing (being equal) criteria.
- A single hit is simply a possible permutation list of such objects.
Our current solution works as follows:
- Sort by HEAD/TAIL then order lists ascendingly by length (shortest first).
- Iterate over objects from the shortest list.
- Binary search for objects in the next list that share the HEAD/TAIL value with the object from the last searched list directly connected to it.
- If no such object exists in the list, go back to the previous list and try with its next object as sorted.
- If this next object matches its edge/list criteria, we move forward again, otherwise we go back and so on.
- If we reach the longest list then we have a hit consisting of all the objects from each list that match the overall DAG criteria.
- Go back to the previous list and try again until we reach the bottom of the first shortest list.
As you can see, we simply can divide the first list evenly between threads. However, this can result in unbalanced load on different threads. Therefore, the order of the searched lists can impact the performance. We choose to go with shortest to longest hopping that a miss hit would be detected early on before we reach longer lists where we try linearly not binarily. If we choose to go longest to shortest, we could achieve perfect balance though will always have to fully iterate over the longest list impacting performance.
What is you thought on that balance ? Is this a standard algorithmic problem that has a name I can google for ? Any other ways to concurrently traverse the DAGs that can achieve better performance ?
Many thanks !