From 26a238f5b75683ff59d4d2e361ef68c2c242deac Mon Sep 17 00:00:00 2001 From: Peter Dillinger Date: Tue, 28 Dec 2021 21:53:26 -0800 Subject: [PATCH] New blog post for Ribbon filter (#8992) Summary: new blog post for Ribbon filter Pull Request resolved: https://github.com/facebook/rocksdb/pull/8992 Test Plan: markdown render in GitHub, Pages on my fork Reviewed By: jay-zhuang Differential Revision: D33342496 Pulled By: pdillinger fbshipit-source-id: a0a7c19100abdf8755f8a618eb4dead755dfddae --- docs/_posts/2021-12-29-ribbon-filter.markdown | 281 ++++++++++++++++++ 1 file changed, 281 insertions(+) create mode 100644 docs/_posts/2021-12-29-ribbon-filter.markdown diff --git a/docs/_posts/2021-12-29-ribbon-filter.markdown b/docs/_posts/2021-12-29-ribbon-filter.markdown new file mode 100644 index 000000000..c6a52ce84 --- /dev/null +++ b/docs/_posts/2021-12-29-ribbon-filter.markdown @@ -0,0 +1,281 @@ +--- +title: Ribbon Filter +layout: post +author: pdillinger +category: blog +--- + +## Summary +Since version 6.15 last year, RocksDB supports Ribbon filters, a new +alternative to Bloom filters that save space, especially memory, at +the cost of more CPU usage, mostly in constructing the filters in the +background. Most applications with long-lived data (many hours or +longer) will likely benefit from adopting a Ribbon+Bloom hybrid filter +policy. Here we explain why and how. + +[Ribbon filter on RocksDB wiki](https://github.com/facebook/rocksdb/wiki/RocksDB-Bloom-Filter#ribbon-filter) + +[Ribbon filter paper](https://arxiv.org/abs/2103.02515) + +## Problem & background +Bloom filters play a critical role in optimizing point queries and +some range queries in LSM-tree storage systems like RocksDB. Very +large DBs can use 10% or more of their RAM memory for (Bloom) filters, +so that (average case) read performance can be very good despite high +(worst case) read amplification, [which is useful for lowering write +and/or space +amplification](http://smalldatum.blogspot.com/2015/11/read-write-space-amplification-pick-2_23.html). +Although the `format_version=5` Bloom filter in RocksDB is extremely +fast, all Bloom filters use around 50% more space than is +theoretically possible for a hashed structure configured for the same +false positive (FP) rate and number of keys added. What would it take +to save that significant share of “wasted” filter memory, and when +does it make sense to use such a Bloom alternative? + +A number of alternatives to Bloom filters were known, especially for +static filters (not modified after construction), but all the +previously known structures were unsatisfying for SSTs because of some +combination of +* Not enough space savings for CPU increase. For example, [Xor + filters](https://arxiv.org/abs/1912.08258) use 3-4x more CPU than + Bloom but only save 15-20% of + space. [GOV](https://arxiv.org/pdf/1603.04330.pdf) can save around + 30% space but requires around 10x more CPU than Bloom. +* Inconsistent space savings. [Cuckoo + filters](https://www.cs.cmu.edu/~dga/papers/cuckoo-conext2014.pdf) + and Xor+ filters offer significant space savings for very low FP + rates (high bits per key) but little or no savings for higher FP + rates (low bits per key). ([Higher FP rates are considered best for + largest levels of + LSM.](https://stratos.seas.harvard.edu/files/stratos/files/monkeykeyvaluestore.pdf)) + [Spatially-coupled Xor + filters](https://arxiv.org/pdf/2001.10500.pdf) require very large + number of keys per filter for large space savings. +* Inflexible configuration. No published alternatives offered the same + continuous configurability of Bloom filters, where any FP rate and + any fractional bits per key could be chosen. This flexibility + improves memory efficiency with the `optimize_filters_for_memory` + option that minimizes internal fragmentation on filters. + +## Ribbon filter development and implementation +The Ribbon filter came about when I developed a faster, simpler, and +more adaptable algorithm for constructing a little-known [Xor-based +structure from Dietzfelbinger and +Walzer](https://arxiv.org/pdf/1907.04750.pdf). It has very good space +usage for required CPU time (~30% space savings for 3-4x CPU) and, +with some engineering, Bloom-like configurability. The complications +were managable for use in RocksDB: +* Ribbon space efficiency does not naturally scale to very large + number of keys in a single filter (whole SST file or partition), but + with the current 128-bit Ribbon implementation in RocksDB, even 100 + million keys in one filter saves 27% space vs. Bloom rather than 30% + for 100,000 keys in a filter. +* More temporary memory is required during construction, ~230 bits per + key for 128-bit Ribbon vs. ~75 bits per key for Bloom filter. A + quick calculation shows that if you are saving 3 bits per key on the + generated filter, you only need about 50 generated filters in memory + to offset this temporary memory usage. (Thousands of filters in + memory is typical.) Starting in RocksDB version 6.27, this temporary + memory can be accounted for under block cache using + `BlockBasedTableOptions::reserve_table_builder_memory`. +* Ribbon filter queries use relatively more CPU for lower FP rates + (but still O(1) relative to number of keys added to filter). This + should be OK because lower FP rates are only appropriate when then + cost of a false positive is very high (worth extra query time) or + memory is not so constrained (can use Bloom instead). + +Future: data in [the paper](https://arxiv.org/abs/2103.02515) suggests +that 32-bit Balanced Ribbon (new name: [Bump-Once +Ribbon](https://arxiv.org/pdf/2109.01892.pdf)) would improve all of +these issues and be better all around (except for code complexity). + +## Ribbon vs. Bloom in RocksDB configuration +Different applications and hardware configurations have different +constraints, but we can use hardware costs to examine and better +understand the trade-off between Bloom and Ribbon. + +### Same FP rate, RAM vs. CPU hardware cost +Under ideal conditions where we can adjust our hardware to suit the +application, in terms of dollars, how much does it cost to construct, +query, and keep in memory a Bloom filter vs. a Ribbon filter? The +Ribbon filter costs more for CPU but less for RAM. Importantly, the +RAM cost directly depends on how long the filter is kept in memory, +which in RocksDB is essentially the lifetime of the filter. +(Temporary RAM during construction is so short-lived that it is +ignored.) Using some consumer hardware and electricity prices and a +predicted balance between construction and queries, we can compute a +“break even” duration in memory. To minimize cost, filters with a +lifetime shorter than this should be Bloom and filters with a lifetime +longer than this should be Ribbon. (Python code) + +``` +# Commodity prices based roughly on consumer prices and rough guesses +# Upfront cost of a CPU per hardware thread +upfront_dollars_per_cpu_thread = 30.0 + +# CPU average power usage per hardware thread +watts_per_cpu_thread = 3.5 + +# Upfront cost of a GB of RAM +upfront_dollars_per_gb_ram = 8.0 + +# RAM average power usage per GB +# https://www.crucial.com/support/articles-faq-memory/how-much-power-does-memory-use +watts_per_gb_ram = 0.375 + +# Estimated price of power per kilowatt-hour, including overheads like conversion losses and cooling +dollars_per_kwh = 0.35 + +# Assume 3 year hardware lifetime +hours_per_lifetime = 3 * 365 * 24 +seconds_per_lifetime = hours_per_lifetime * 60 * 60 + +# Number of filter queries per key added in filter construction is heavily dependent on workload. +# When replication is in layer above RocksDB, it will be low, likely < 1. When replication is in +# storage layer below RocksDB, it will likely be > 1. Using a rough and general guesstimate. +key_query_per_construct = 1.0 + +#================================== +# Bloom & Ribbon filter performance +typical_bloom_bits_per_key = 10.0 +typical_ribbon_bits_per_key = 7.0 + +# Speeds here are sensitive to many variables, especially query speed because it +# is so dependent on memory latency. Using this benchmark here: +# for IMPL in 2 3; do +# ./filter_bench -impl=$IMPL -quick -m_keys_total_max=200 -use_full_block_reader +# done +# and "Random filter" queries. +nanoseconds_per_construct_bloom_key = 32.0 +nanoseconds_per_construct_ribbon_key = 140.0 + +nanoseconds_per_query_bloom_key = 500.0 +nanoseconds_per_query_ribbon_key = 600.0 + +#================================== +# Some constants +kwh_per_watt_lifetime = hours_per_lifetime / 1000.0 +bits_per_gb = 8 * 1024 * 1024 * 1024 + +#================================== +# Crunching the numbers +# on CPU for constructing filters +dollars_per_cpu_thread_lifetime = upfront_dollars_per_cpu_thread + watts_per_cpu_thread * kwh_per_watt_lifetime * dollars_per_kwh +dollars_per_cpu_thread_second = dollars_per_cpu_thread_lifetime / seconds_per_lifetime + +dollars_per_construct_bloom_key = dollars_per_cpu_thread_second * nanoseconds_per_construct_bloom_key / 10**9 +dollars_per_construct_ribbon_key = dollars_per_cpu_thread_second * nanoseconds_per_construct_ribbon_key / 10**9 + +dollars_per_query_bloom_key = dollars_per_cpu_thread_second * nanoseconds_per_query_bloom_key / 10**9 +dollars_per_query_ribbon_key = dollars_per_cpu_thread_second * nanoseconds_per_query_ribbon_key / 10**9 + +dollars_per_bloom_key_cpu = dollars_per_construct_bloom_key + key_query_per_construct * dollars_per_query_bloom_key +dollars_per_ribbon_key_cpu = dollars_per_construct_ribbon_key + key_query_per_construct * dollars_per_query_ribbon_key + +# on holding filters in RAM +dollars_per_gb_ram_lifetime = upfront_dollars_per_gb_ram + watts_per_gb_ram * kwh_per_watt_lifetime * dollars_per_kwh +dollars_per_gb_ram_second = dollars_per_gb_ram_lifetime / seconds_per_lifetime + +dollars_per_bloom_key_in_ram_second = dollars_per_gb_ram_second / bits_per_gb * typical_bloom_bits_per_key +dollars_per_ribbon_key_in_ram_second = dollars_per_gb_ram_second / bits_per_gb * typical_ribbon_bits_per_key + +#================================== +# How many seconds does it take for the added cost of constructing a ribbon filter instead +# of bloom to be offset by the added cost of holding the bloom filter in memory? +break_even_seconds = (dollars_per_ribbon_key_cpu - dollars_per_bloom_key_cpu) / (dollars_per_bloom_key_in_ram_second - dollars_per_ribbon_key_in_ram_second) +print(break_even_seconds) +# -> 3235.1647730256936 +``` + +So roughly speaking, filters that live in memory for more than an hour +should be Ribbon, and filters that live less than an hour should be +Bloom. This is very interesting, but how long do filters live in +RocksDB? + +First let's consider the average case. Write-heavy RocksDB loads are +often backed by flash storage, which has some specified write +endurance for its intended lifetime. This can be expressed as *device +writes per day* (DWPD), and supported DWPD is typically < 10.0 even +for high end devices (excluding NVRAM). Roughly speaking, the DB would +need to be writing at a rate of 20+ DWPD for data to have an average +lifetime of less than one hour. Thus, unless you are prematurely +burning out your flash or massively under-utilizing available storage, +using the Ribbon filter has the better cost profile *on average*. + +### Predictable lifetime +But we can do even better than optimizing for the average case. LSM +levels give us very strong data lifetime hints. Data in L0 might live +for minutes or a small number of hours. Data in Lmax might live for +days or weeks. So even if Ribbon filters weren't the best choice on +average for a workload, they almost certainly make sense for the +larger, longer-lived levels of the LSM. As of RocksDB 6.24, you can +specify a minimum LSM level for Ribbon filters with +`NewRibbonFilterPolicy`, and earlier levels will use Bloom filters. + +### Resident filter memory +The above analysis assumes that nearly all filters for all live SST +files are resident in memory. This is true if using +`cache_index_and_filter_blocks=0` and `max_open_files=-1` (defaults), +but `cache_index_and_filter_blocks=1` is popular. In that case, +if you use `optimize_filters_for_hits=1` and non-partitioned filters +(a popular MyRocks configuration), it is also likely that nearly all +live filters are in memory. However, if you don't use +`optimize_filters_for_hits` and use partitioned filters, then +cold data (by age or by key range) can lead to only a portion of +filters being resident in memory. In that case, benefit from Ribbon +filter is not as clear, though because Ribbon filters are smaller, +they are more efficient to read into memory. + +RocksDB version 6.21 and later include a rough feature to determine +block cache usage for data blocks, filter blocks, index blocks, etc. +Data like this is periodically dumped to LOG file +(`stats_dump_period_sec`): + +``` +Block cache entry stats(count,size,portion): DataBlock(441761,6.82 GB,75.765%) FilterBlock(3002,1.27 GB,14.1387%) IndexBlock(17777,887.75 MB,9.63267%) Misc(1,0.00 KB,0%) +Block cache LRUCache@0x7fdd08104290#7004432 capacity: 9.00 GB collections: 2573 last_copies: 10 last_secs: 0.143248 secs_since: 0 +``` + +This indicates that at this moment in time, the block cache object +identified by `LRUCache@0x7fdd08104290#7004432` (potentially used +by multiple DBs) uses roughly 14% of its 9GB, about 1.27 GB, on filter +blocks. This same data is available through `DB::GetMapProperty` with +`DB::Properties::kBlockCacheEntryStats`, and (with some effort) can +be compared to total size of all filters (not necessarily in memory) +using `rocksdb.filter.size` from +`DB::Properties::kAggregatedTableProperties`. + +### Sanity checking lifetime +Can we be sure that using filters even makes sense for such long-lived +data? We can apply [the current 5 minute rule for caching SSD data in +RAM](http://renata.borovica-gajic.com/data/adms2017_5minuterule.pdf). A +4KB filter page holds data for roughly 4K keys. If we assume at least +one negative (useful) filter query in its lifetime per added key, it +can satisfy the 5 minute rule with a lifetime of up to about two +weeks. Thus, the lifetime threshold for “no filter” is about 300x +higher than the lifetime threshold for Ribbon filter. + +### What to do with saved memory +The default way to improve overall RocksDB performance with more +available memory is to use more space for caching, which improves +latency, CPU load, read IOs, etc. With +`cache_index_and_filter_blocks=1`, savings in filters will +automatically make room for caching more data blocks in block +cache. With `cache_index_and_filter_blocks=0`, consider increasing +block cache size. + +Using the space savings to lower filter FP rates is also an option, +but there is less evidence for this commonly improving existing +*optimized* configurations. + +## Generic recommendation +If using `NewBloomFilterPolicy(bpk)` for a large persistent DB using +compression, try using `NewRibbonFilterPolicy(bpk)` instead, which +will generate Ribbon filters during compaction and Bloom filters +for flush, both with the same FP rate as the old setting. Once new SST +files are generated under the new policy, this should free up some +memory for more caching without much effect on burst or sustained +write speed. Both kinds of filters can be read under either policy, so +there's always an option to adjust settings or gracefully roll back to +using Bloom filter only (keeping in mind that SST files must be +replaced to see effect of that change).