I have a weighted, directed graph which is dense with around 20,000 nodes.

- Given an node in the graph, I choose an adjacent node randomly with a probability related to the relative weights.
- After each choice, I receive feedback about whether the choice was good or bad, and update the network. For example, after a bad choice I decrease the weight of
*all edges*pointing to the chosen node.

I learned yesterday about the alias method for simulating rolling a weighted die, which is the same as making one choice (each node is one weighted die, and the sides correspond to other nodes). One roll is highly efficient, but updating the weights is not; the alias method may not be appropriate because I will be updating more dice than I will be rolling!

**What data structure should I use, which allows for frequent updates, and what corresponding algorithm is best for making the choices?**

Some ideas/notes:

- I can decrease updates by recording each weight adjustment, and then only actually updating a node/die when necessary (i.e. directly before a roll). But I'd still be precomputing the alias data once for
*each*roll. - Instead, I could simply store the graph as is (so that updates are cheap) and forgo the alias method. I would calculate relative weights on the fly before each roll (binary search works here).
- An additional benefit of calculating relative weights on the fly is that I could factor out out the "global weight" for each node to further reduce updates. Then, a bad choice would result in only 2 updates: the incoming edge weight and the node's global weight.
*added*: Maybe there is something in between: a way to maintain local relative weights in a data structure (e.g. tree or alias method) and then during each roll merge them with "global weights" on the fly.

The truth is that in practice I don't need to make choices very often (no more than once a minute), so I don't *need* the most efficient solution. But this is a fun side project and I'm interested in finding a theoretically optimal solution.