README
¶
Chapter II: creating an empty experiment
In this chapter we will create an empty experiment and replace
the code calling the real torsf experiment in main.go to
call our empty experiment instead.
(This file is auto-generated from the corresponding source file, so make sure you don't edit it manually.)
Changes in main.go
In main.go we will simply replace the call to the
torsf.NewExperimentMeasurer function with a call to
a NewExperimentMeasurer function that we are going
to implement as part of this chapter.
After you do this, you also need to remove the now-unneded
import of the torsf package.
There are no additional changes to main.go.
m := NewExperimentMeasurer(Config{})
The torsf.go file
This file will contain the implementation of the
NewExperimentMeasurer function.
As usual we start with the package declaration and
with the few imports we need to add.
package main
import (
"context"
"time"
"github.com/ooni/probe-cli/v3/internal/model"
)
Data structures
Next, we define data structures.
Config contains config for the torsf experiment. As for the real
torsf experiment, we don't have any specific config, so we keep
the structure empty. We still need to define a Config struct
here, because, by convention, all OONI experiments have a Config.
type Config struct{}
Measurer is the torsf measurer. This structure implements the
model.ExperimentMeasurer interface, as we will see below.
Most OONI experiments have a measurer that contains as its unique field the specific configuration. Here we do the same.
type Measurer struct {
config Config
}
NewExperimentMeasurer creates a new model.ExperimentMeasurer
instance for performing torsf measurements. This function
will just assemble a new instance of Measurer with the config
that was passed as an argument.
func NewExperimentMeasurer(config Config) model.ExperimentMeasurer {
return &Measurer{config: config}
}
Implementing the model.ExperimentMeasurer.
Now it's time to implement the methods required by the model's
ExperimentMeasurer interface.
ExperimentName implements ExperimentMeasurer.ExperimentName. This function returns the name of the experiment. This code is used by generic code manipulating the experiment to print the experiment name.
func (m *Measurer) ExperimentName() string {
return "torsf"
}
ExperimentVersion implements ExperimentMeasurer.ExperimentVersion. This function returns the version of the experiment. This code is also used by generic code manipulating the experiment to print the experiment version.
func (m *Measurer) ExperimentVersion() string {
return "0.1.0"
}
Run implements ExperimentMeasurer.Run. This is the most interesting
function, where we run the experiment proper. In the previous chapter
we learned how to call this function from a main.go file. Here,
instead, we're going to create a minimal stub. In the subsequent
chapters, finally, we will modify this function until it is a
minimal implementation of the torsf experiment.
func (m *Measurer) Run(ctx context.Context, args *model.ExperimentArgs) error {
_ = args.Callbacks
_ = args.Measurement
sess := args.Session
As you can see, this is just a stub implementation that sleeps for one second and prints a logging message.
time.Sleep(time.Second)
sess.Logger().Info("hello from the torsf experiment!")
return nil
}
Summary keys
Before concluding this chapter, we also need to create the SummaryKeys
for this experiment. For historical reasons, the TestKeys of each
experiment is an interface{}. Every experiment also defines a SummaryKeys
data structure and a GetSummaryKeys method to convert the opaque
result of a measurement to the summary for such an experiment.
The experiment summary is only used by the OONI Probe CLI.
SummaryKeys contains summary keys for this experiment. Because this is
just an illustrative tutorial, we will just include a single key, named
IsAnomaly. This key is not exported as JSON and is used by the OONI
Probe CLI to inform the user of whether this measurement is ordinary or
anomalous. All OONI experiments' SummaryKeys contain such a field.
type SummaryKeys struct {
IsAnomaly bool `json:"-"`
}
GetSummaryKeys implements model.ExperimentMeasurer.GetSummaryKeys. This
method just converts the TestKeys inside measurement to an instance of
the SummaryKeys structure. For now, we'll just implement a stub returning
fake SummaryKeys declaring there was no anomaly.
func (m *Measurer) GetSummaryKeys(measurement *model.Measurement) (interface{}, error) {
return &SummaryKeys{IsAnomaly: false}, nil
}
Running the code
We can run the code written in this chapter as follows:
$ go run ./experiment/torsf/chapter02
2021/06/21 20:48:32 info hello from the torsf experiment!
{
"data_format_version": "",
"input": null,
"measurement_start_time": "",
"probe_asn": "",
"probe_cc": "",
"probe_network_name": "",
"report_id": "",
"resolver_asn": "",
"resolver_ip": "",
"resolver_network_name": "",
"software_name": "",
"software_version": "",
"test_keys": null,
"test_name": "",
"test_runtime": 0,
"test_start_time": "",
"test_version": ""
}
Here you see that we're printing the log message and
that the test_keys are null.
The OONI data processing popeline will not be so happy
if we pass it a null settings, because there is not
much interesting data in there. We will thus start filling
it in the next chapter.
Documentation
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