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Problem: Given a userID (integer) quickly find which group the user belongs to. Groups will contain no more than 15 users. Additionally, I am using libev which gives me no control over the parameters passed into the read I/O event, so the userID (file descriptor/integer) is really the only thing I can use.

My solution: hash once on the userID into a hash table containing groupID and userID pairs. Hash a second time on the groupID to a hash table containing groupID and array of 15 userID pairs.

The solution works, but this is server code that will be executed an ungodly amount of times. I wonder if the double hashing will be inefficient and if there may be a better solution.

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Posting the actual code you're using on might be a better idea. – Cody Gray Feb 21 '12 at 7:34
Not sure why someone changed the title of the post to a different question than what I am asking. – Josh Brittain Feb 21 '12 at 11:15

I would sort the userID in the group array and use a binary search algorithm.

Do the same thing with the groupid, make a class or a struc that contain a groupID and an array of user ids.

Than make an array of your group and sort them as you add them, then, use a binary search algorithm again to find the group.


The Binary search could be good for a small amount of data while the "Hash map" will always take the same time as your amount of data increases.

So here's a link to another question with the comparisons of the two solutions: Which is faster, Hash lookup or Binary search?

I must admit that you were right!

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a well constructed hash table has constant lookup time. A binary search algorithm has O(log n) search time. Not to mention the overhead involved in constantly updating the array to keep it sorted. I'm confused as to what is better about this method? – Josh Brittain Feb 21 '12 at 8:08
I'm not an expert, but I have just take a look at the complexity of the two solutions and the hash map tend to be O(n) in the worst case and the binary search is always O(logn). And for the sorting time, if you do not add a lot of group and user, this may not be a problem. – Emileb Feb 21 '12 at 8:29
While it is true that a hash table is O(n) in the worst case, only a poorly designed hash table should perform like that. Since I'm only hashing on ints it should be easy to design a hash with few collisions. Also, I will have thousands of users and hundreds of groups to manage. – Josh Brittain Feb 21 '12 at 8:46
For the title update, you can change it back (I think) to what you really want to ask, but since it's a Q&A website, it's best to write a question as the title. – Emileb Feb 23 '12 at 9:11

You say that libev only gives you a limited amount of data—the ev_io handle itself—and conclude that all there is useful in there is the file descriptor. Well, normally, you're probably right, but there's a neat trick you can do.

Since with libev, you allocate the structures yourself and then have libev initialize them, there's nothing stopping you from allocating too much space. Since libev won't be touching that extra space, you can put your own stuff in there. Success!

So how does this work in practice? You create a new structure containing an ev_io as the first member, and then put all the rest of your data after it, say like this:

struct my_mutant_io {
    ev_io handle;
    int group_id;

Now, wherever you allocate a uv_io, allocate a my_mutant_io instead. Put your data in there however you'd like and once you need to pass it to a libuv function, just take the address of handle instead:

struct my_mutant_io *mutant = malloc(sizeof(struct my_mutant_io));
if(!mutant) {
mutant->group_id = /* ... */;
ev_io_init(&mutant, some_callback, fd, EV_READ);

You've given libev a ev_io, and it's none-the-wiser that it's actually just a part of a larger struct. Now let's move on to the callback. You'll get your ev_io back, but wait! Since the ev_io is the first member of the struct, its address is the same as the address of our mutant. We can cast the ev_io * right back to a struct my_mutant_io * and use it. (Just don't tell the strict-aliasing gods.)

A struct like this is most commonly called a baton.

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