cloud failover extension
1 TopicInstalling and running iControl extensions in isolated GCP VPCs
BIG-IP instances launched on Google Cloud Platform usually need access to the internet to retrieve extensions, install DO and AS3 declarations, and get to any other run-time assets pulled from public URLs during boot. This allows decoupling of BIG-IP releases from the library and extensions that enhance GCP deployments, and is generally a good thing. What if the BIG-IP doesn't have access to the Internet? Best practices for Google Cloud recommend that VMs are deployed with the minimal set of access requirements. For some that means that egress to the internet is restricted too: BIG-IP VMs do not have public IP addresses. A NAT Gateway or NATing VM is not present in the VPC. Default VPC network routes to the internet have been removed. If you have a private artifact repository available in the VPC, supporting libraries and onboarding resources could be added to there and retrieved during initialization as needed, or you could also create customized BIG-IP images that have the supporting libraries pre-installed (see BIG-IP image generator for details). Both those methods solve the problem of installing run-time components without internet access, but Cloud Failover Extension, AS3 Service Discovery, and Telemetry Streaming must be able to make calls to GCP APIs, but GCP APIs are presented as endpoints on the public internet. For example, Cloud Failover Extension will not function correctly out of the box when the BIG-IP instances are not able to reach the internet directly or via a NAT because the extension must have access to Storage APIs for shared-state persistence, and to Compute APIs to updates to network resources. If the BIG-IP is deployed without functioning routes to the internet, CFE cannot function as expected. Figure 1: BIG-IP VMs 1 cannot reach public API endpoints 2 because routes to internet 3 are removed Given that constraint, how can we make CFE work in truly isolated VPCs where internet access is prohibited? Private Google Access Enabling Private Google Access on each VPC subnet that may need to access Google Cloud APIs changes the underlying SDN so that the CIDRs for restricted.googleapis.com (or private.googleapis.com † ) will be routed without going through the internet. When combined with a private DNS zone which shadows all googleapis.com lookups to use the chosen protected endpoint range, the VPC networks effectively have access for all GCP APIs. The steps to do so are simple: Enable Private Google Access on each VPC subnet where a GCP API call may be sourced. Create a Cloud DNS private zone for googleapis.com that contains two records: CNAME for *.googleapis.com that responds with restricted.googleapis.com. A record for restricted.googleapis.com that resolves to each host in 199.36.153.4/30. Create a custom route on each VPC network for 199.36.153.4/30 with next-hop set for internet gateway. With this configuration in place, any VMs that are attached to the VPC networks that are associated with this private DNS zone will automatically try to use 199.36.153.4/30 endpoints for all GCP API calls without code changes, and the custom route will allow Private Google Access to function correctly. Automating with Terraform and Google Cloud Foundation Toolkit ‡ While you can perform the steps to enable private API access manually, it is always better to have a repeatable and reusable approach that can be automated as part of your infrastructure provisioning. My tool of choice for infrastructure automation is Hashicorp's Terraform, and Google's Cloud Foundation Toolkit, a set of Terraform modules that can create and configure GCP resources. By combining Google's modules with my own BIG-IP modules, we can build a repeatable solution for isolated VPC deployments; just change the variable definitions to deploy to development, testing/QA, and production. Cloud Failover Example Figure 2: Private Google Access 1 , custom DNS 2 , and custom routes 3 combine to enable API access 4 without public internet access A fully-functional example that builds out the infrastructure shown in figure 2 can be found in my GitHub repo f5-google-bigip-isolated-vpcs. When executed, Terraform will create three network VPCs that lack the default-internet egress route, but have a custom route defined to allow traffic to restricted.googleapis.com CIDR. A Cloud DNS private zone will be created to override wildcard googleapis.com lookups with restricted.googleapis.com, and the private zone will be enabled on all three VPC networks. A pair of BIG-IPs are instantiated with CFE enabled and configured to use a dedicated CFE bucket for state management. An IAP-enabled bastion host with tinyproxy allows for SSH and GUI access to the BIG-IPs (See the repo's README for full details on how to connect). Once logged in to the active BIG-IP, you can verify that the instances do not have access to the internet, and you can verify that CFE is functioning correctly by forcing the active instance to standby. Almost immediately you can see that the other BIG-IP instance has become the active instance. Notes † Private vs Restricted access GCP supports two protected endpoint options; private and restricted. Both allow access to GCP API endpoints without traversing the public internet, but restricted is integrated with VPC Service Controls. If you need access to a GCP API that is unsupported by VPC Service Controls, you can choose private access and change steps 2 and 3 above to use private.googleapis.com and 199.36.153.8/30 instead. ‡ Prefer Google Deployment Manager? My colleague Gert Wolfis has written a similar article that focuses on using GDM templates for BIG-IP deployment. You can find his article at https://devcentral.f5.com/s/articles/Deploy-BIG-IP-on-GCP-with-GDM-without-Internet-access.339Views1like0Comments