I'm doing some research for a new project, for which the constraints and specifications have yet to be set. One thing that is wanted is a large number of paths, directly under the root domain. This could ramp up to millions of paths. The paths don't have a common structure or unique parts, so I have to look for exact matches.
Now I know it's more efficient to break up those paths, which would also help in the path lookup. However I'm researching the possibility here, so bear with me.
I'm evaluating methods to accomplish this, while maintaining excellent performance. I thought of the following methods:
- Storing the paths in an SQL database and doing a lookup on every request. This seems like the worst option and will definitely not be used.
- Storing the paths in a key-value store like Redis. This would be a lot better, and perform quite well I think (have to benchmark it though).
- Doing string/regex matching - like many frameworks do out of the box - for this amount of possible matches is nuts and thus not really an option. But I could see how doing some sort of algorithm where you compare letter-by-letter, in combination with some smart optimizations, could work.
But maybe there are tools/methods I don't know about that are far more suited for this type of problem. I could use any tips on how to accomplish this though.
Oh and in case anyone is wondering, no this isn't homework.
I've tested the Redis approach. Based on two sets of keywords, I got 150 million paths. I've added each of them using the
set command, with the value being a serialized string of id's I can use to identify the actual keywords in the request. (
SET 'keyword1-keyword2' '<serialized_string>')
A quick test in a local VM with a data set of one million records returned promising results: benchmarking 1000 requests took 2ms on average. And this was on my laptop, which runs tons of other stuff.
Next I did a complete test on a VPS with 4 cores and 8GB of RAM, with the complete set of 150 million records. This yielded a database of 3.1G in file size, and around 9GB in memory. Since the database could not be loaded in memory entirely, Redis started swapping, which caused terrible results: around 100ms on average.
Obviously this will not work and scale nice. Either each web server needs to have a enormous amount of RAM for this, or we'll have to use a dedicated Redis-routing server. I've read an article from the engineers at Instagram, who came up with a trick to decrease the database size dramatically, but I haven't tried this yet. Either way, this does not seem the right way to do this. Back to the drawing board.