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---
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title: "Few performance facts about bgpgrep"
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mobile_menu_title: "bgpgrep performance facts"
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date: 2021-10-19
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description: "After a complete codebase rewrite, some tweaks, and a lot of new
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features, it is time to look back and enjoy some benchmarking between bgpgrep and bgpscanner.
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Let's see how much things have improved and why."
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series: [ "ubgpsuite - The Micro BGP Suite" ]
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categories: [ "benchmarks", "development" ]
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tags: [ "ubgpsuite", "bgpscanner", "bgpgrep", "Networking", "BGP", "benchmarks" ]
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news_keywords: [ "ubgpsuite", "bgpscanner", "bgpgrep", "benchmarks" ]
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---
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## Few performance facts about bgpgrep
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If you are a performance junkie like me, the first question
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that probably pops in your mind after a major code rewrite is something like:
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*Is it faster than before?*
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Let's now satisfy this curiosity (of mine) with some benchmarking.
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## Benchmark environment
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* Processor: Intel© Core™ i7-8565U at 1.80GHz (4 cores physical, 8 cores with hyperthreading)
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* Cache layout:
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- L1 data cache: 128 KiB (4 instances)
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- L1 instructions cache: 128 KiB (4 instances)
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- L2 cache: 1 MiB (4 instances)
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- L3 cache: 8 MiB (1 instance)
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* Memory: 16 GB RAM DDR4, in two 8GB banks
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* Hard disk: SAMSUNG MZALQ512HALU-000L1
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* Kernel: Linux 5.10.62-1-lts SMP x86_64 GNU/Linux
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To avoid adultering results we also:
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- disable `cron` and any other background file indexing service;
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- force performance CPU profile, disabling powersave mode;
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- disable [Linux address space layout randomization](https://en.wikipedia.org/wiki/Address_space_layout_randomization) for the duration of our tests;
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- increase kernel performance events sample rate;
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- drop filesystem caches and clean any temporary file;
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- run benchmarks in console mode, outside any desktop environment.
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Both `bgpscanner` and `bgpgrep` have been compiled in release mode with full optimizations,
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as documented in their official build instructions, using `clang` version 12.0.1.
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For reference, we also do a benchmark run with `bgpdump`, version 1.6.2, as available from
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[Arch Linux User Repositories (AUR)](https://aur.archlinux.org/packages/bgpdump/).
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Results are calculated by averaging five runs of each command, immediately
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after one warmup round. MRT data is decompressed upfront, to avoid accounting for
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decompression overhead, the output is sent directly to `/dev/null`,
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to avoid any disk write overhead.
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## Let the fun begin!
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We take the data for the first benchmark from
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RouteViews' [Sydney Route Collector](http://archive.routeviews.org/route-views.sydney/bgpdata),
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and pull the very first RIB of December 2020, along with any subsequent updates from the same month.
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This gives us 47.1GB uncompressed MRT data to work with.
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We then run our benchmarks with the following commands:
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```sh
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bgpgrep sydney/2020-12/uncompressed.mrt >/dev/null
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bgpscanner sydney/2020-12/uncompressed.mrt >/dev/null
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bgpdump -mv sydney/2020-12/uncompressed.mrt >/dev/null
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```
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| | Average (sec) | Best (sec) | Worst (sec) | Memory (KiB) |
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|------------|---------------|------------|-------------|--------------|
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| bgpgrep | 404.45 | 401.62 | 411.38 | 2076 |
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| bgpscanner | 453.59 | 451.93 | 455.13 | 2448 |
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| bgpdump | 2053.73 | 2037.19 | 2082.22 | 2316 |
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`bgpgrep` is 11% faster than `bgpscanner`, which is good.
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Since this benchmark operates mostly on MRT update dumps, let's try the same
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on a different dataset, mostly made of RIBs.
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We pull nine RIBs from RIPE RIS NCC [RRC00 Route Collector](https://data.ris.ripe.net/rrc00/2019.12/),
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and obtain 25.7GB worth of uncompressed MRT data.
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This time the benchmark is limited to `bgpgrep` and `bgpscanner`.
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Executed commands and results:
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```sh
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bgpgrep rrc00/2019-12/rib-uncompressed.mrt >/dev/null
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bgpscanner rrc00/2019-12/rib-uncompressed.mrt >/dev/null
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```
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| | Average (sec) | Best (sec) | Worst (sec) | Memory (KiB) |
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|------------|---------------|------------|-------------|--------------|
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| bgpgrep | 295.84 | 292.20 | 298.14 | 2112 |
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| bgpscanner | 333.35 | 321.73 | 339.56 | 3016 |
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The same trend is confirmed, `bgpgrep` is about 12% faster, indicating that
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the advantage was not data dependent.
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Though, running our benchmarks under average system load might lead to an
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interesting surprise:
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```sh
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bgpgrep isolario/2021-07/rib-uncompressed.mrt >/dev/null
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bgpscanner isolario/2021-07/rib-uncompressed.mrt >/dev/null
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```
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| | Average (sec) | Best (sec) | Worst (sec) | Memory (KiB) |
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|------------|---------------|------------|-------------|--------------|
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| bgpgrep | 344.90 | 342.88 | 347.03 | 2260 |
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| bgpscanner | 411.39 | 405.13 | 412.70 | 2436 |
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These runs have been performed under a regular GNOME desktop session,
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with other applications running. We used 60.8GB worth of MRT data from
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the Isolario project [Dagobah Collector](https://isolario.it/Isolario_MRT_data/Dagobah/),
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from the month of July, 2021 (mostly RIBs).
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It might strike us that the performance gain now approaches 20%.
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The reason might be a smarter use of memory, and the reduced chance of page faults.
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You might have noticed by our results that `bgpgrep` memory requirements are
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moderate compared to `bgpscanner`, what's less evident is that `bgpgrep` also keeps
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its data structures compact and doesn't like moving them around much.
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This lessens the page pressure on the system (and makes the CPU cache happier).
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The net effects of this aren't evident in the benchmarking environment,
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since `bgpgrep` and `bgpscanner`, in turns, are the only resource intensive
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tasks on the system.
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The initial warmup round contributes to their ideal performance.
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When more tasks are concurrently fighting over memory, and processes might get
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swapped to different cores for various reasons, invalidating their cache,
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the value of `bgpgrep` approach becomes more prominent.
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## Conclusion
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`bgpgrep` seems to be a nice improvement over `bgpscanner`, and I am
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quite satisfied with the performance improvements. Especially when they come with
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a more solid codebase.
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In the next few weeks I intend to improve the filtering engine.
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In general I'd like to stop for a bit to polish the codebase to make it more mature,
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before moving on to implement more features.
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If you haven't already, be sure to check out the Micro BGP Suite at our official
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[Git Repository](https://git.doublefourteen.io/bgp/ubgpsuite).
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Like always, happy hacking to you all!
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Lorenzo Cogotti
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