This is our v2 benchmark suite, which gets run in CI. It makes use of [graphql-bench](https://github.com/hasura/graphql-bench) internally (which in turn uses the [K6 load testing tool](https://k6.io/)) Here is an overview of this directory: ### benchmark_sets/* Each sub-directory here contains a different schema and accompanying latency benchmarks (see below for adding your own). Each benchmark set runs in parallel on CI. See `benchmark_sets/chinook/` for reference. In a benchmark set directory, the existence of an empty file named one of the following have the following effects: - `SKIP_CI`: don't run the benchmark in CI at all - `SKIP_PR_REPORT`: don't post the regression results directly in the PR comment body (useful if the results are noisy for now) ### bench.sh This script runs a particular benchmark set against a particular hasura docker image or, if omitted, the hasura running on port 8181. e.g. to run the `chinook` benchmarks: $ ./bench.sh chinook hasura/graphql-engine:v2.0.1 Only fairly recent (as of this writing) builds of hasura are supported. Be aware benchmarks are tuned for our beefy CI machines, and some may perform poorly and give useless output on a laptop with few cores. ### fabfile.py This is the core of the CI functionality. It's possibile to run this locally but you'll need credentials (see `.circleci/config.yaml`). In general this can be ignored. --- ## Interpreting benchmark results - **bytes_alloc_per_req should be very stable** but of course doesn't measure, e.g. whether we're generating efficient SQL - **min latency is often stable**, especially when we have many (>5,000) samples; a regression here may mean a change to the code is influencing performance ...or it might **indicate the test run was unstable** and should be taken with a grain of salt, or retried - ...but **[long tail latencies](https://engineering.linkedin.com/performance/who-moved-my-99th-percentile-latency)** are very important; the 90th percentile may be a better target to optimize for than the median (50th percentile) - ...but keep in mind that **longtail latencies are by definition noisey**: the 99.9th percentile may represent only a handful of samples. Therefore be cautious when drawing inferences from a _comparison_ of tail latencies between versions. ## Adding a new benchmark You'll create a new directory under `benchmark_sets/`, and in general can follow the pattern from `chinook`. The process looks like: - `export_metadata` to create your `replace_metadata.json` using _stable hasura_ if possible, so that you can compare performance against older versions of hasura (e.g. `chinook` and `huge_schema` use v2 of metadata) - check `major_gcs` from `/dev/rts_stats` before and after a test run, ensuring the benchmark ran for long enough to perform at least a few major GCs. - play with benchmark duration, so that results are repeatable but take no longer than necessary (see also above) - if you're interested in latency, be sure you haven't requested a rate too close to the throughput limit; experiment locally to find an appropriate upper bounds for load. - set `preAllocatedVUs` juar high enough so that K6 doesn't have to allocate VUs during test, and you see no `dropped_iterations` reported - look for `✓ no error in body` in K6 output to make sure your query is correct (assuming you're not benchmarking error handling) - document the purpose of the benchmark. e.g. "large response bodies at high throughput", or "complex joins with conditions on a table with a lot of data, ensuring we're generating an efficient query"; give context so your fellow developers have a sense of what a regression means Make sure the benchmark set takes **less than 20 minutes**, otherwise it will be killed. You can always split benchmarks up into two different sets to be run in parallel. If a benchmark set is not fairly stable, or you're not sure if it is, add an empty file named `SKIP_PR_REPORT` in the benchmark set's directory; this will prevent display of regression numbers in the PR comment body, but will still run and record the benchmarks.