Bent automates downloading, compiling, and running Go tests and benchmarks from various Github repositories. The benchmarks and tests retrieved are pinned at a particular version, which avoids that source of variation and also avoids the problem of running unknown code.
Older versions of bent defaulted to running benchmarks in a container, however that is not the default now and it is no longer well tested.
Installation:
go install golang.org/x/benchmarks/cmd/bent@latest
Depends on burntsushi/toml.
Install rsync
for slightly improved copy performance.
Initial usage :
go install golang.org/x/benchmarks/cmd/bent@latest mkdir scratch cd scratch bent -I cp configurations-sample.toml configurations.toml nano configurations.toml # or use your favorite editor bent -v -N 10 # will run default set of ~50 benchmarks 10 times using supplied configuration(s)
The output binaries are placed in subdirectory testbin
, various benchmark results (from building, run, and others requested) are placed in subdirectory bench
, and the binaries are also incorporated into Docker containers if Docker is used. Each benchmark and configuration has a shortname, and the generated binaries combine these shortnames, for example gonum_mat_Tip
and gonum_mat_Go1.9
. Benchmark files are prefixed with a run timestamp, and grouped by configuration, with various suffixes for the various benchmarks. Run benchmarks appears in files with suffix .stdout
. Others are more obviously named, with suffixes .build
, .benchsize
, and .benchdwarf
.
Flags for your use:
Flag | meaning | example |
---|---|---|
-v | print commands as they are run | |
-I | initialize a directory for running tests | |
-N x | benchmark/test repeat count | -N 25 |
-a N | repeat builds for build benchmarking | -a 10 |
-R N | for randomized builds, build a new binary for each run (incompatible with -a, -N) | -R 3 |
-B file | benchmarks file | -B benchmarks-trial.toml |
-C file | configurations file | -C conf_1.9_and_tip.toml |
-T | run tests instead of benchmarks | |
-b list | run benchmarks in comma-separated list (even if normally “disabled” ) | -b uuid,gonum_topo |
-c list | use configurations from comma-separated list (even if normally “disabled”) | -c Tip,Go1.9 |
-l | list available benchmarks and configurations, then exit | |
Less useful flags | ||
-r string | skip get and build, just run. string names Docker image if needed, if not using Docker any non-empty will do. | -r f10cecc3eaac |
-s k | (build) shuffle flag, k = 0,1,2,3. Randomize build order to reduce sensitivity to other machine load | -s 2 |
-G t/f | group runs by benchmark to reduce time-of-day background noise (default true) | |
-X | do not reset go.mod for experiments involving modifications to build/*/go.mod | |
-g | get benchmarks, but do not build or run | |
-W | print benchmark information as a markdown table | |
-sandbox | require Docker sandbox to run tests/benchmarks (and exclude those that do not sandbox) |
Suites, benchmarks and configurations appear in toml format, since that is somewhat more human-friendly than JSON and in particular allows comments. Values in these files can refer to environment variables; PATH
, USER
, HOME
, SHELL
, BENT*
, and GO*
. Unless it is explicitly supplied, ROOT
is defined to be $PWD
. For iterated builds and benchmarks BENT_I
is set to the iteration count, and for runs BENT_BINARY
is the file name (excluding path).
The Suite file defines the shortnames for benchmarks, where they are obtained, and what version, plus any always-necessary flags:
[[Suites]] Name = "gonum_mat" Repo = "gonum.org/v1/gonum/mat" BuildFlags = ["-tags", "safe"] Version = "@v0.9.3" [[Suites]] Name = "toml" Repo = "github.com/BurntSushi/toml" Version = "@v1.3.2" ExtraFiles = ["_example"]
Here, gonum_mat
is checked out at version 0.9.3
and is always build with -tags safe
. And to run the toml benchmarks, the contents of the _example
directory are also required.
A sample benchmark entry:
[[Benchmarks]] Name = "gonum_topo" Tests = "Test" Benchmarks = "Benchmark(TarjanSCCGnp_1000_half|TarjanSCCGnp_10_tenth)" # NotSandboxed = true # uncomment if cannot be run in a Docker container # Disabled = true # uncomment to disable benchmark
Here, Name
is a short name, and Tests
and Benchmarks
are the regular expressions for go test
specifying which tests or benchmarks to run.
A sample configuration entry with all the options supplied:
[[Configurations]] Name = "Go-preempt" Root = "$HOME/work/go/" # Optional flags below BuildFlags = ["-gccgoflags=all=-O3 -static-libgo","-tags=noasm"] # for Gollvm AfterBuild = ["benchsize", "benchdwarf"] GcFlags = "-d=ssa/insert_resched_checks/on" LdFlags = "-randlayout=$BENT_I" GcEnv = ["GOMAXPROCS=1","GOGC=200"] RunFlags = ["-test.short"] RunEnv = ["GOGC=1000"] RunWrapper = ["cpuprofile"] Disabled = false
The Gc...
attributes apply to the test or benchmark compilation, the Run...
attributes apply to the test or benchmark run. A RunWrapper
command receives the entire command line as arguments, plus the environment variable BENT_BINARY
set to the filename (excluding path) of the binary being run (for example, “uuid_Tip”) and BENT_I
set to the run number for this binary. One useful example is cpuprofile
:
#!/bin/bash # Run args as command, but run cpuprofile and then pprof to capture test cpuprofile output if [ -n ${BENT_PGO} ] ; then pf="${BENT_PGO}/${BENT_BENCH}.prof" mkdir -p ${BENT_PGO} else pf="${BENT_PROFILES}/${BENT_BINARY}_${BENT_I}.prof" mkdir -p ${BENT_PROFILES} fi "$@" -test.cpuprofile="$pf" echo cpuprofile in "$pf" if [[ x`which pprof` == x"" ]] ; then go tool pprof -text -flat -nodecount=20 "$pf" else pprof -text -flat -nodecount=20 "$pf" fi
When both configuration and benchmark wrappers are used the configuration wrapper runs the benchmark wrapper runs the actual benchmark, i.e.
ConfigWrapper ConfigArg BenchWrapper BenchArg ActualBenchmark
The Disabled
attribute for both benchmarks and configurations removes them from normal use, but leaves them accessible to explicit request with -b
or -c
.
Bent includes sample configurations to support PGO-optimized benchmarks and randomized link order to normalize away branch alignment artifacts. These may need editing to reference local paths before use.
For PGO optimization:
# First generate profiles bent -C configurations-pgo.toml -c pgo-generate # Use profiles for 10 benchmark runs bent -C configurations-pgo.toml -N 10
For randomized link order:
# Randomized benchmarking -R is incompatible with -a or -N bent -C configurations-random.toml -R 10
Bent now comes with several shell scripts to automate common uses. These all run using perflock
if it is available, and default to different numbers of builds (usually 1) and benchmark runs (usually 15) which can be overridden at invocation.
cmpcl.sh refs/changes/<nn>/<cl>/<patch> [options]
This checks out a particular version of a CL, and its immediate predecessor, and benchmarks the change. The refs/changes/<nn>/<cl>/<patch>
parameter is the same one that appears as a Gerrit download option for the CL. The default is to build once, benchmark 15 times. The results are also uploaded with benchsave
to perf.golang.org.
cmpjob.sh <branch-or-tag> <branch-or-tag> [options]
This checks out two particular tag or branches, and benchmarks the difference. This can be helpful when binary-searching a performance regression. The default is to build once, benchmark 15 times. The results are also uploaded with benchsave
to perf.golang.org.
cronjob.sh [options]
This checks out the current development tip and the most recent release (e.g. 1.14) and benchmarks their difference. This can be helpful for nightly performance monitoring. The default is to build 25 times and benchmark 25 times. The results are also uploaded with benchsave
to perf.golang.org. The script also contains glue to tweet the results, but by default this will silently do nothing.
cmpcl-phase.sh refs/changes/<nn>/<cl>/<patch> [options]
This checks out a particular version of a CL, and its immediate predecessor, compiles each once with the ssa phase timing flag turned on, does not run benchmarks, and feeds the log (with all the embedded phase timings) to phase-times to help spot any bad performance trends in the new CL. The resulting CSVs can be imported into a spreadsheet and graphed (select the “Test” sheet and scroll down below the vast table of numbers, there is a pretty chart).