Re: Proposal: Adding compression of temporary files - Mailing list pgsql-hackers
| From | Tomas Vondra |
|---|---|
| Subject | Re: Proposal: Adding compression of temporary files |
| Date | |
| Msg-id | 29c87c10-fdbc-4d0f-b0f4-15e14dd36bce@vondra.me Whole thread Raw |
| List | pgsql-hackers |
Hi, On 11/18/24 22:58, Filip Janus wrote: > ... > Hi all, > Postgresql supports data compression nowadays, but the compression of > temporary files has not been implemented yet. The huge queries can > produce a significant amount of temporary data that needs to > be stored on disk > and cause many expensive I/O operations. > I am attaching a proposal of the patch to enable temporary files > compression for > hashjoins for now. Initially, I've chosen the LZ4 compression > algorithm. It would > probably make better sense to start with pglz, but I realized it late. > Thanks for the idea & patch. I agree this might be quite useful for workloads generating a lot of temporary files for stuff like sorts etc. I think it will be interesting to think about the trade offs, i.e. how to pick the compression level - at some point the compression ratio stops improving while paying more and more CPU time. Not sure what the right choice is, so using default seems fine. I agree it'd be better to start with pglz, and only then add lz4 etc. Firstly, pglz is simply the built-in compression, supported everywhere. And it's also simpler to implement, I think. > # Future possible improvements > Reducing the number of memory allocations within the dumping and > loading of > the buffer. I have two ideas for solving this problem. I would > either add a buffer into > struct BufFile or provide the buffer as an argument from the caller. > For the sequential > execution, I would prefer the second option. > Yes, this would be good. Doing a palloc+pfree for each compression is going to be expensive, especially because these buffers are going to be large - likely larger than 8kB. Which means it's not cached in the memory context, etc. Adding it to the BufFile is not going to fly, because that doubles the amount of memory per file. And we already have major issues with hash joins consuming massive amounts of memory. But at the same time the buffer is only needed during compression, and there's only one at a time. So I agree with passing a single buffer as an argument. > # Future plan/open questions > In the future, I would like to add support for pglz and zstd. > Further, I plan to > extend the support of the temporary file compression also for > sorting, gist index creation, etc. > > Experimenting with the stream mode of compression algorithms. The > compression > ratio of LZ4 in block mode seems to be satisfying, but the stream > mode could > produce a better ratio, but it would consume more memory due to the > requirement to store > context for LZ4 stream compression. > One thing I realized is that this only enables temp file compression for a single place - hash join spill files. AFAIK this is because compressed files don't support random access, and the other places might need that. Is that correct? The patch does not explain this anywhere. If that's correct, the patch probably should mention this in a comment for the 'compress' argument added to BufFileCreateTemp(), so that it's clear when it's legal to set compress=true. Which other places might compress temp files? Surely hash joins are not the only place that could benefit from this, right? Another thing is testing. If I run regression tests, it won't use compression at all, because the GUC has "none" by default, right? But we need some testing, so how would we do that? One option would be to add a regression test that explicitly sets the GUC and does a hash join, but that won't work with lz4 (because that may not be enabled). Another option might be to add a PG_TEST_xxx environment variable that determines compression to use. Something like PG_TEST_USE_UNIX_SOCKETS. But perhaps there's a simpler way. > # Benchmark > I prepared three different databases to check expectations. Each > dataset is described below. My testing demonstrates that my patch > improves the execution time of huge hash joins. > Also, my implementation should not > negatively affect performance within smaller queries. > The usage of memory needed for temporary files was reduced in every > execution without a significant impact on execution time. > > *## Dataset A:* > Tables* > * > table_a(bigint id,text data_text,integer data_number) - 10000000 rows > table_b(bigint id, integer ref_id, numeric data_value, bytea > data_blob) - 10000000 rows > Query: SELECT * FROM table_a a JOIN table_b b ON a.id <http:// > a.id> = b.id <http://b.id>; > > The tables contain highly compressible data. > The query demonstrated a reduction in the usage of the temporary > files ~20GB -> 3GB, based on this reduction also caused the execution > time of the query to be reduced by about ~10s. > > > *## Dataset B:* > Tables:* > * > table_a(integer id, text data_blob) - 1110000 rows > table_b(integer id, text data_blob) - 10000000 rows > Query: SELECT * FROM table_a a JOIN table_b b ON a.id <http:// > a.id> = b.id <http://b.id>; > > The tables contain less compressible data. data_blob was generated > by a pseudo-random generator. > In this case, the data reduction was only ~50%. Also, the execution > time was reduced > only slightly with the enabled compression. > > The second scenario demonstrates no overhead in the case of enabled > compression and extended work_mem to avoid temp file usage. > > *## Dataset C:* > Tables > customers (integer,text,text,text,text) > order_items(integer,integer,integer,integer,numeric(10,2)) > orders(integer,integer,timestamp,numeric(10,2)) > products(integer,text,text,numeric(10,2),integer) > > Query: SELECT p.product_id, p.name <http://p.name>, p.price, > SUM(oi.quantity) AS total_quantity, AVG(oi.price) AS avg_item_price > FROM eshop.products p JOIN eshop.order_items oi ON p.product_id = > oi.product_id JOIN > eshop.orders o ON oi.order_id = o.order_id WHERE o.order_date > > '2020-01-01' AND p.price > 50 > GROUP BY p.product_id, p.name <http://p.name>, p.price HAVING > SUM(oi.quantity) > 1000 > ORDER BY total_quantity DESC LIMIT 100; > > This scenario should demonstrate a more realistic usage of the database. > Enabled compression slightly reduced the temporary memory usage, but > the execution > time wasn't affected by compression. > > > +------------+-------------------------+----------------------- > +------------------------------+ > | Dataset | Compression. | temp_bytes | Execution > Time (ms) | > +------------+-------------------------+----------------------- > +----------------------------- + > | A | Yes | 3.09 GiB > | 22s586ms | work_mem = 4MB > | | No | 21.89 GiB > | 35s | work_mem = 4MB > +------------+-------------------------+----------------------- > +---------------------------------------- > | B | Yes | 333 MB > | 1815.545 ms | work_mem = 4MB > | | No | 146 MB > | 1500.460 ms | work_mem = 4MB > | | Yes | 0 MB > | 3262.305 ms | work_mem = 80MB > | | No | 0 MB > | 3174.725 ms | work_mem = 80MB > +-------------+------------------------+------------------------ > +------------------------------------- > | C | Yes | 40 MB > | 1011.020 ms | work_mem = 1MB > | | No | 53 > MB | 1034.142 ms | work_mem = 1MB > +------------+------------------------+------------------------ > +-------------------------------------- > > Thanks. I'll try to do some benchmarks on my own. Are these results fro ma single run, or an average of multiple runs? Do you maybe have a script to reproduce this, including the data generation? Also, can you share some information about the machine used for this? I expect the impact to strongly depends on memory pressure - if the temp file fits into page cache (and stays there), it may not benefit from the compression, right? regards -- Tomas Vondra
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