Secure Control of Egress Traffic in Istio, part 2
Use Istio Egress Traffic Control to prevent attacks involving egress traffic.
Welcome to part 2 in our new series about secure control of egress traffic in Istio. In the first part in the series, I presented the attacks involving egress traffic and the requirements we collected for a secure control system for egress traffic. In this installment, I describe the Istio way to securely control the egress traffic, and show how Istio can help you prevent the attacks.
Secure control of egress traffic in Istio
To implement secure control of egress traffic in Istio, you must direct TLS traffic to external services through an egress gateway. Alternatively, you can direct HTTP traffic through an egress gateway and let the egress gateway perform TLS origination.
Both alternatives have their pros and cons, you should choose between them according to your circumstances. The choice mainly depends on whether your application can send unencrypted HTTP requests and whether your organization’s security policies allow sending unencrypted HTTP requests. For example, if your application uses some client library that encrypts the traffic without a possibility to cancel the encryption, you cannot use the option of sending unencrypted HTTP traffic. The same in the case your organization’s security policies do not allow sending unencrypted HTTP requests inside the pod (outside the pod the traffic is encrypted by Istio).
If the application sends HTTP requests and the egress gateway performs TLS origination, you can monitor HTTP information like HTTP methods, headers, and URL paths. You can also define policies based on said HTTP information. If the application performs TLS origination, you can monitor SNI and the service account of the source pod’s TLS traffic, and define policies based on SNI and service accounts.
You must ensure that traffic from your cluster to the outside cannot bypass the egress gateway. Istio cannot enforce it for you, so you must apply some additional security mechanisms, for example, the Kubernetes network policies or an L3 firewall. See an example of the Kubernetes network policies configuration. According to the Defense in depth concept, the more security mechanisms you apply for the same goal, the better.
You must also ensure that Istio control plane and the egress gateway cannot be compromised. While you may have hundreds or thousands of application pods in your cluster, there are only a dozen of Istio control plane pods and the gateways. You can and should focus on protecting the control plane pods and the gateways, since it is easy (there is a small number of pods to protect) and it is most crucial for the security of your cluster. If attackers compromise the control plane or the egress gateway, they could violate any policy.
You might have multiple tools to protect the control plane pods, depending on your environment. The reasonable security measures are:
- Run the control plane pods on nodes separate from the application nodes.
- Run the control plane pods in their own separate namespace.
- Apply the Kubernetes RBAC and network policies to protect the control plane pods.
- Monitor the control plane pods more closely than you do the application pods.
Once you direct egress traffic through an egress gateway and apply the additional security mechanisms, you can securely monitor and enforce security policies for the traffic.
The following diagram shows Istio’s security architecture, augmented with an L3 firewall which is part of the additional security mechanisms that should be provided outside of Istio.
You can configure the L3 firewall trivially to only allow incoming traffic through the Istio ingress gateway and only allow outgoing traffic through the Istio egress gateway. The Istio proxies of the gateways enforce policies and report telemetry just as all other proxies in the mesh do.
Now let’s examine possible attacks and let me show you how the secure control of egress traffic in Istio prevents them.
Preventing possible attacks
Consider the following security policies for egress traffic:
- Application A is allowed to access
*.ibm.com, which includes all the external services with URLs matching
- Application B is allowed to access
- All egress traffic is monitored.
Suppose the attackers have the following goals:
*.ibm.comfrom your cluster.
*.ibm.comfrom your cluster, unmonitored. The attackers want their traffic to be unmonitored to prevent a possibility that you will detect the forbidden access.
mongo1.composedb.comfrom your cluster.
Now suppose that the attackers manage to break into one of the pods of application A, and try to use the compromised pod to perform the forbidden access. The attackers may try their luck and access the external services in a straightforward way. You will react to the straightforward attempts as follows:
- Initially, there is no way to prevent a compromised application A to access
*.ibm.com, because the compromised pod is indistinguishable from the original pod.
- Fortunately, you can monitor all access to external services, detect suspicious traffic, and thwart attackers from
gaining unmonitored access to
*.ibm.com. For example, you could apply anomaly detection tools on the egress traffic logs.
- To stop attackers from accessing
mongo1.composedb.comfrom your cluster, Istio will correctly detect the source of the traffic, application A in this case, and verify that it is not allowed to access
mongo1.composedb.comaccording to the security policies mentioned above.
Having failed to achieve their goals in a straightforward way, the malicious actors may resort to advanced attacks:
- Bypass the container’s sidecar proxy to be able to access any external service directly, without the sidecar’s policy enforcement and reporting. This attack is prevented by a Kubernetes Network Policy or by an L3 firewall that allow egress traffic to exit the mesh only from the egress gateway.
- Compromise the egress gateway to be able to force it to send fake information to the monitoring system or to disable enforcement of the security policies. This attack is prevented by applying the special security measures to the egress gateway pods.
- Impersonate as application B since application B is allowed to access
mongo1.composedb.com. This attack, fortunately, is prevented by Istio’s strong identity support.
As far as we can see, all the forbidden access is prevented, or at least is monitored and can be prevented later. If you see other attacks that involve egress traffic or security holes in the current design, we would be happy to hear about it.
Hopefully, I managed to convince you that Istio is an effective tool to prevent attacks involving egress traffic. In the next part of this series, I compare secure control of egress traffic in Istio with alternative solutions such as Kubernetes Network Policies and legacy egress proxies/firewalls.