I'm learning about fractal tree indices such as that found in TokuDB. I am fascinated with the strategy it uses to make writes fast by writing to CPU cache most of the time and only rarely writing out to slower RAM memory. However, a fractal tree index does eventually have to do big writes out to RAM and then giant writes out to disk and then utterly huge writes completely on disk. It is here where I get confused. Can the fractal tree index do this efficiently? More efficiently, say, than a B-tree can update the disk in a worst-case-scenario update? Also, what effect does a giant, on-disk rewrite have upon lookup-time of that data? And, vise versa, what effect does doing several look-ups on that data have on the process of the giant rewrite?

As context for answering this, you should know:

  • Everything I learned about fractal tree indices I learned in this slide presentation
  • I don't have a good mental model for how a spinning medium hard drive works.
  • When I say "giant rewrite", basically what happens is that you have two sorted arrays of the same length (of size 2^largeNumber) and you write them to a single array (of size 2^(largeNumber+1)) which is sorted.
  • I guess in-disk writes could always be done efficiently with 3 disks. You would just keep two of the sorted list on disks A and B, and play them into a buffer that writes out to C. If you're really sneaky about it, you would probably be able to write copies out to disk so that at all times the disk working on adding documents will not be the disks servicing query requests. Interesting. – JnBrymn Sep 8 '12 at 14:34
up vote 3 down vote accepted

I suggest you watch my video at http://www.youtube.com/watch?v=88NaRUdoWZM which may give you a better understanding of how Fractal Tree Indexes work. When the indexes do not fit in main memory, a fractal tree index is able to buffer large groups of messages which slowly push down the tree as the buffers overflow. When they eventually make it to a leaf node there is a single IO to retrieve the leaf and apply all the messages. Fractal Tree Indexes do significantly less write IO as they aggregate many operations across a single IO and writes are highly compressed. Read IO is also significantly lessened as it is reading highly compressed data.

I'm not sure if this fully answers your questions, but hopefully it helps.

  • Wow thanks. I look forward to watching to your video. – JnBrymn Sep 15 '12 at 1:12
  • @tmcallaghan but in this tokutek's presentation bnl.gov/csc/seminars/abstracts/Bender_Presentation.pdf somthing different is shown as b-tree. Your presentation is about message infrastructure connected with something like B-Tree, where buffers gets flushed towards leafs, but in that .PDF presentation we have "sorted arrays of exponentially increasing size". There no messages infrastructure mentioned in that .PDF presentation. Can you comment that? Sorry for poor language. – pavelkolodin May 29 '15 at 20:24
  • Sure thing. That PDF is from a long time ago, much changed along the way. You can trust that my YouTube video is the actual implementation. – tmcallaghan May 30 '15 at 21:55
  • @tmcallaghan can you comment this video youtube.com/watch?v=dLFgJvVrzJ0 ? Something like "sorted arrays stack" is shown there. How it is related to real life? Thanks. – pavelkolodin Jun 3 '15 at 19:08

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