The process can be started using `./lotus-bench import` with `--car` flag set to the location of
CAR chain export. `--start-epoch` and `--end-epoch` can be used to to limit the range of epochs to run
the benchmark. Note that state tree of `start-epoch` needs to be in the CAR file or has to be previously computed
to work.
The output will be a `bench.json` file containing information about every syscall invoked
and the time taken by these invocations. This file can grow to be quite big in size so make sure you have
spare space.
After the bench run is complete the `bench.json` file can be analyzed with `./lotus-bench import analyze bench.json`.
It will compute means, standard deviations and co-variances (when applicable) of syscall runtimes.
The output is in nanoseconds, so the gas values for syscalls should be 10x that. In cases where co-variance of
execution time to some parameter is evaluated, the strength of the correlation should be taken into account.
#### Special cases
OnImplPut compute gas is based on the flush time to disk of objects created,
during block execution (when gas traces are formed) objects are only written to memory. Use `vm/flush_copy_ms` and `vm/flush_copy_count` to estimate OnIpldPut compute cost.
### Targeted gas balancing
In some cases complete gas balancing is infeasible, either new syscall gets introduced or
complete balancing is too time consuming.
In these cases the recommended way to estimate gas for given syscall is to perform an `in-vivo` benchmark.
In the past `in-vitro` as in standalone benchmarks were found to be highly inaccurate when compared to results
of real execution.
A in-vivo benchmark can be performed by running an example of such syscall during block execution.
The best place to hook-in such benchmark is message execution loop in
`chain/stmgr/stmgr.go` in `ApplyBlocks()`. Depending of time required to complete the syscall it might be
advisable to run the execution only once every few messages.
