DFID (Dept-First Iterative Deeping) vs. IDA* (Iterative-Deeping A*)

I wonder what are the advantages and disadvantages of these two algorithms. I want to write AddEmUp C++ solved, but I'm not sure which (IDA or DFID) algorithm should I use.

The best article I found is this one, but it seems too old - '93. Any newer?

I think IDA* would be better, but.. ? Any other ideas?

Any ideas and info would be helpful.

Thanks ! (:

EDIT: Some good article about IDA* and good explanation of the algorithm?

EDIT2: Or some good heuristic function for that game? I have no idea how to think of some :/

-
Isn't DFID just a special case of IDA* where the heuristic function is constantly 0? So essentially you're asking whether you should use a heuristic function. –  huaiyuan Dec 6 '10 at 17:46
@huaiyuan: It's a special case, but not in any useful sense. –  larsmans Dec 6 '10 at 18:26

The Russel & Norvig book is an excellent reference on these algorithms, and I'll give larsmans a virtual high-five for suggesting it; however I disagree that IDA* is in any appreciable way harder to program than A*. I've done it for a project where I had to write an AI to solve a sliding-block puzzle - the familiar problem of having a N x N grid of numbered tiles, and using the single free space to slide tiles around until they are in ascending order.

Recall:

``````F(n) = g(n) + h(n).

TotalCost = PathCost + Heuristic.
``````

g(n) = Path cost, the distance from the initial to the current state

h(n) = Heuristic, the estimation of cost from current state to end state. To be an admissible heuristic (and thus ensure A*'s optimality), you cannot in any case overestimate the cost. See this question for more info on the effects of overestimating/underestimating heuristics on A*.

Remember that Iterative Deepening A* is just A* with a limit on the F value of nodes you are allowed to traverse. This `FLimit` increases with each outer iteration; with each iteration you are deepening the search.

Here's my C++ code implementing both A* and IDA* to solve the aforementioned sliding block puzzle. You can see that I use a `std::priority_queue` with a custom Comparator to store Puzzle states in the queue prioritized by their F value. You will also note that the only difference between A* and IDA* is the addition of an `FLimit` check and an outer loop that increments this `FLimit`. I hope this helps shed some light on this subject.

-
Thanks a lot, this really helped me (: Accepted. –  Kiril Kirov Dec 7 '10 at 13:31
@Aphex In your implementation, A* and the final iteration of IDA* uses the same space. The original proposed implementation (See citeseerx.ist.psu.edu/viewdoc/summary?doi=10.1.1.91.288 ), the author uses Depth-first search in each iteration of IDA* with the advantage that there is no need to store open and closed lists of A* (there is a visited list during DFS which needs to be stored if the graph is not a tree). –  phaedrus Sep 17 '11 at 18:31
That is the idea of IDA*; the chance that you might find the solution within a certain (hopefully shallow) depth without having to traverse deeper nodes. What you and that article are describing appears to be IDDFS - Iterative Deepening Depth-First Search (also known as DFID) - not Iterative Deepening A*. –  Aphex Sep 19 '11 at 14:40

Check out Russell & Norvig, chapters 3 and 4, and realize that IDA* is hard to program correctly. You might want to try recursive best first search (RBFS), also described by R&N, or plain old A*. The latter can be implemented using an `std::priority_queue`.

IIRC, R&N described IDA* in the first edition, then replaced it with RBFS in the second. I haven't seen the third edition yet.

As regards your second edit, I haven't looked into the game, but a good procedure for deriving heuristics is that of relaxed problems. You take away the rules of the game until you derive a version for which the heuristic is easily expressed and implemented (and cheap to compute). Or, following a bottom-up approach, you check the main rules to see which one admits an easy heuristic, then try that and add in other rules as you need them.

-
Thanks (: But it seems that IDA* is more appropriate for this game, if I'm not wrong. Due to my research, I keep believing that this is the correct algorithm for this problem. As you say it's very hard, I hope someone will convince me in the opposite.. :/ :) –  Kiril Kirov Dec 6 '10 at 17:09
@Kiril: Have you tried implementing any search algorithm? Picking the right algorithm for this kind of task is not an exact science: you'll have to try several until you find one that works well. It may be that a simple algorithm is all you need. –  larsmans Dec 6 '10 at 18:17
Argh, you're right. I haven't tried. But I don't have much time for testing, I just wondered if there's a recommended algorithm for that kind of games. AddEmUp seems (a littel) like 8-puzzle problem, which is most efficiently solved using IDA*. But you're right, I agree. –  Kiril Kirov Dec 6 '10 at 18:27
"Most efficiently solved by IDA*" still doesn't mean much without specifying the heuristic. I recommend trying IDS (or DFID as your source calls it) on progressively harder instances until it breaks, then implement A* or RBFS if and when it does. There are very many choices to make when implementing search, which is why nobody wrote the library for it yet. –  larsmans Dec 6 '10 at 18:31
thanks a lot for the information and for you help (: Appreciated. +1 for the attention, the explanations and suggesting R&N. 10q –  Kiril Kirov Dec 7 '10 at 8:03