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154 lines
7.7 KiB
Markdown
154 lines
7.7 KiB
Markdown
# BIRD Journey to Threads. Chapter 3½: Route server performance
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All the work on multithreading shall be justified by performance improvements.
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This chapter tries to compare times reached by version 3.0-alpha0 and 2.0.8,
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showing some data and thinking about them.
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BIRD is a fast, robust and memory-efficient routing daemon designed and
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implemented at the end of 20th century. We're doing a significant amount of
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BIRD's internal structure changes to make it run in multiple threads in parallel.
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## Testing setup
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There are two machines in one rack. One of these simulates the peers of
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a route server, the other runs BIRD in a route server configuration. First, the
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peers are launched, then the route server is started and one of the peers
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measures the convergence time until routes are fully propagated. Other peers
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drop all incoming routes.
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There are four configurations. *Single* where all BGPs are directly
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connected to the main table, *Multi* where every BGP has its own table and
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filters are done on pipes between them, and finally *Imex* and *Mulimex* which are
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effectively *Single* and *Multi* where all BGPs have also their auxiliary
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import and export tables enabled.
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All of these use the same short dummy filter for route import to provide a
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consistent load. This filter includes no meaningful logic, it's just some dummy
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data to run the CPU with no memory contention. Real filters also do not suffer from
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memory contention, with an exception of ROA checks. Optimization of ROA is a
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task for another day.
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There is also other stuff in BIRD waiting for performance assessment. As the
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(by far) most demanding setup of BIRD is route server in IXP, we chose to
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optimize and measure BGP and filters first.
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Hardware used for testing is Intel(R) Xeon(R) CPU E5-2630 v3 @ 2.40GHz with 8
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physical cores, two hyperthreads on each. Memory is 32 GB RAM.
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## Test parameters and statistics
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BIRD setup may scale on two major axes. Number of peers and number of routes /
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destinations. *(There are more axes, e.g.: complexity of filters, routes /
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destinations ratio, topology size in IGP)*
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Scaling the test on route count is easy, just by adding more routes to the
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testing peers. Currently, the largest test data I feed BIRD with is about 2M
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routes for around 800K destinations, due to memory limitations. The routes /
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destinations ratio is around 2.5 in this testing setup, trying to get close to
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real-world routing servers.[^1]
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[^1]: BIRD can handle much more in real life, the actual software limit is currently
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a 32-bit unsigned route counter in the table structure. Hardware capabilities
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are already there and checking how BIRD handles more than 4G routes is
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certainly going to be a real thing soon.
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Scaling the test on peer count is easy, until you get to higher numbers. When I
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was setting up the test, I configured one Linux network namespace for each peer,
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connecting them by virtual links to a bridge and by a GRE tunnel to the other
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machine. This works well for 10 peers but setting up and removing 1000 network
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namespaces takes more than 15 minutes in total. (Note to myself: try this with
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a newer Linux kernel than 4.9.)
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Another problem of test scaling is bandwidth. With 10 peers, everything is OK.
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With 1000 peers, version 3.0-alpha0 does more than 600 Mbps traffic in peak
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which is just about the bandwidth of the whole setup. I'm planning to design a
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better test setup with less chokepoints in future.
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## Hypothesis
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There are two versions subjected to the test. One of these is `2.0.8` as an
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initial testpoint. The other is version 3.0-alpha0, named `bgp` as parallel BGP
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is implemented there.
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The major problem of large-scale BIRD setups is convergence time on startup. We
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assume that a multithreaded version should reduce the overall convergence time,
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at most by a factor equal to number of cores involved. Here we have 16
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hyperthreads, in theory we should reduce the times up to 16-fold, yet this is
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almost impossible as a non-negligible amount of time is spent in bottleneck
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code like best route selection or some cleanup routines. This has become a
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bottleneck by making other parts parallel.
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## Data
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Four charts are included here, one for each setup. All axes have a
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logarithmic scale. The route count on X scale is the total route count in
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tested BIRD, different color shades belong to different versions and peer
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counts. Time is plotted on Y scale.
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Raw data is available in Git, as well as the chart generator. Strange results
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caused by testbed bugs are already omitted.
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There is also a line drawn on a 2-second mark. Convergence is checked by
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periodically requesting `birdc show route count` on one of the peers and BGP
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peers have also a 1-second connect delay time (default is 5 seconds). All
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measured times shorter than 2 seconds are highly unreliable.
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![Plotted data for Single](03b_stats_2d_single.png)
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[Plotted data for Single in PDF](03b_stats_2d_single.pdf)
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Single-table setup has times reduced to about 1/8 when comparing 3.0-alpha0 to
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2.0.8. Speedup for 10-peer setup is slightly worse than expected and there is
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still some room for improvement, yet 8-fold speedup on 8 physical cores and 16
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hyperthreads is good for me now.
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The most demanding case with 2M routes and 1k peers failed. On 2.0.8, my
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configuration converges after almost two hours on 2.0.8, with the speed of
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route processing steadily decreasing until only several routes per second are
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done. Version 3.0-alpha0 is memory-bloating for some non-obvious reason and
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couldn't fit into 32G RAM. There is definitely some work ahead to stabilize
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BIRD behavior with extreme setups.
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![Plotted data for Multi](03b_stats_2d_multi.png)
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[Plotted data for Multi in PDF](03b_stats_2d_multi.pdf)
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Multi-table setup got the same speedup as single-table setup, no big
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surprise. Largest cases were not tested at all as they don't fit well into 32G
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RAM even with 2.0.8.
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![Plotted data for Imex](03b_stats_2d_imex.png)
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[Plotted data for Imex in PDF](03b_stats_2d_imex.pdf)
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![Plotted data for Mulimex](03b_stats_2d_mulimex.png)
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[Plotted data for Mulimex in PDF](03b_stats_2d_mulimex.pdf)
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Setups with import / export tables are also sped up by a factor
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about 6-8. Data on largest setups (2M routes) are showing some strangely
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ineffective behaviour. Considering that both single-table and multi-table
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setups yield similar performance data, there is probably some unwanted
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inefficiency in the auxiliary table code.
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## Conclusion
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BIRD 3.0-alpha0 is a good version for preliminary testing in IXPs. There is
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some speedup in every testcase and code stability is enough to handle typical
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use cases. Some test scenarios went out of available memory and there is
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definitely a lot of work to stabilize this, yet for now it makes no sense to
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postpone this alpha version any more.
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We don't recommend upgrading a production machine to this version
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yet, anyway if you have a test setup, getting version 3.0-alpha0 there and
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reporting bugs is much welcome.
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Notice: Multithreaded BIRD, at least in version 3.0-alpha0, doesn't limit its number of
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threads. It will spawn at least one thread per every BGP, RPKI and Pipe
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protocol, one thread per every routing table (including auxiliary tables) and
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possibly several more. It's up to the machine administrator to setup a limit on
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CPU core usage by BIRD. When running with many threads and protocols, you may
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need also to raise the filedescriptor limit: BIRD uses 2 filedescriptors per
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every thread for internal messaging.
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*It's a long road to the version 3. By releasing this alpha version, we'd like
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to encourage every user to try this preview. If you want to know more about
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what is being done and why, you may also check the full
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[blogpost series about multithreaded BIRD](https://en.blog.nic.cz/2021/03/15/bird-journey-to-threads-chapter-0-the-reason-why/). Thank you for your ongoing support!*
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