Skip to main content
Version: 1.9

Validate by doing JSON queries

In the previous section, we have shown how to write a validation policy policy by using Go types that describe Kubernetes objects.

There is however another way to write validation logic: by extracting the relevant data from the JSON document using ad-hoc queries.

This "jq-like" approach can be pretty handy when the policy has to look deep inside a Kubernetes object. This is especially helpful when dealing with inner objects that are optional.

This section of the document reimplements the previous code by doing JSON queries instead of unmarshaling the JSON payload into native Go types.

The validate function

We will use the policy we just created and change its validate function to not use the Go types that define Kubernetes objects.

We will instead use the gjson library to extract data from the raw JSON object.

First of all, we have to change the requirement section. This is how the code has to look like:

import (

mapset ""
kubewarden ""
kubewarden_protocol ""

The validation function has to be changed to look like that:

func validate(payload []byte) ([]byte, error) {
// Create a ValidationRequest instance from the incoming payload
validationRequest := kubewarden_protocol.ValidationRequest{}
err := json.Unmarshal(payload, &validationRequest)
if err != nil {
return kubewarden.RejectRequest(

// Create a Settings instance from the ValidationRequest object
settings, err := NewSettingsFromValidationReq(&validationRequest)
if err != nil {
return kubewarden.RejectRequest(

// Access the **raw** JSON that describes the object
podJSON := validationRequest.Request.Object

// NOTE 1
data := gjson.GetBytes(

var validationErr error
labels := mapset.NewThreadUnsafeSet[string]()
data.ForEach(func(key, value gjson.Result) bool {
// NOTE 2
label := key.String()

// NOTE 3
validationErr = validateLabel(label, value.String(), &settings)

// keep iterating if there are no errors
return validationErr == nil

// NOTE 4
if validationErr != nil {
return kubewarden.RejectRequest(

// NOTE 5
for requiredLabel := range settings.ConstrainedLabels {
if !labels.Contains(requiredLabel) {
return kubewarden.RejectRequest(
kubewarden.Message(fmt.Sprintf("Constrained label %s not found inside of Pod", requiredLabel)),

return kubewarden.AcceptRequest()

The initial part of the validate function is similar to the previous one. Things start to change only as soon as we reach the NOTE sections. Let's get through them:

  1. We use a gjson selector to get the label map provided by the object embedded into the request
  2. We use a gjson helper to iterate over the results of the query. If the query has no results the loop will never take place.
  3. We use the validateLabel function to validate the label and its value, like we did before. We're also adding the labels found inside of the Pod to a mapset.Set that we previously defined.
  4. If the validation produced an error, we immediately return with a validation rejection reply.
  5. Like before, we iterate over the constrainedLabels to make sure all of them have been specified inside of the Pod. The code has been slightly changed to make use of the mapset.Set object we previously populated.

Testing the validation code

The unit tests do not need any change, we can run them like before:

make test

All of them are working as expected:

go test -v
=== RUN TestParseValidSettings
--- PASS: TestParseValidSettings (0.00s)
=== RUN TestParseSettingsWithInvalidRegexp
--- PASS: TestParseSettingsWithInvalidRegexp (0.00s)
=== RUN TestDetectValidSettings
--- PASS: TestDetectValidSettings (0.00s)
=== RUN TestDetectNotValidSettingsDueToBrokenRegexp
--- PASS: TestDetectNotValidSettingsDueToBrokenRegexp (0.00s)
=== RUN TestDetectNotValidSettingsDueToConflictingLabels
--- PASS: TestDetectNotValidSettingsDueToConflictingLabels (0.00s)
=== RUN TestValidateLabel
--- PASS: TestValidateLabel (0.00s)
ok 0.002s

End to end tests

End to end test need no changes at all. Let's run them to ensure they are still green:

make e2e-tests

This is the output we will get:

bats e2e.bats
✓ accept when no settings are provided
✓ accept because label is satisfying a constraint
✓ accept labels are not on deny list
✓ reject because label is on deny list
✓ reject because label is not satisfying a constraint
✓ reject because constrained label is missing
✓ fail settings validation because of conflicting labels
✓ fail settings validation because of invalid constraint

8 tests, 0 failures

Again, all the tests are working as expected.