- Traffic Management Best Practices
- Set default routes for services
- Control configuration sharing across namespaces
- Split large virtual services and destination rules into multiple resources
- Avoid 503 errors while reconfiguring service routes
Traffic Management Best Practices
This section provides specific deployment or configuration guidelines to avoid networking or traffic management issues.
Set default routes for services
Although the default Istio behavior conveniently sends traffic from anysource to all versions of a destination service without any rules being set,creating a VirtualService
with a default route for every service,right from the start, is generally considered a best practice in Istio.
Even if you initially have only one version of a service, as soon as you decideto deploy a second version, you need to have a routing rule in place beforethe new version is started, to prevent it from immediately receiving trafficin an uncontrolled way.
Another potential issue when relying on Istio’s default round-robin routing isdue to a subtlety in Istio’s destination rule evaluation algorithm.When routing a request, Envoy first evaluates route rules in virtual servicesto determine if a particular subset is being routed to.If so, only then will it activate any destination rule policies corresponding to the subset.Consequently, Istio only applies the policies you define for specific subsets ifyou explicitly routed traffic to the corresponding subset.
For example, consider the following destination rule as the one and only configuration defined for thereviews service, that is, there are no route rules in a corresponding VirtualService
definition:
apiVersion: networking.istio.io/v1alpha3
kind: DestinationRule
metadata:
name: reviews
spec:
host: reviews
subsets:
- name: v1
labels:
version: v1
trafficPolicy:
connectionPool:
tcp:
maxConnections: 100
Even if Istio’s default round-robin routing calls “v1” instances on occasion,maybe even always if “v1” is the only running version, the above traffic policywill never be invoked.
You can fix the above example in one of two ways. You can either move thetraffic policy up a level in the DestinationRule
to make it apply to any version:
apiVersion: networking.istio.io/v1alpha3
kind: DestinationRule
metadata:
name: reviews
spec:
host: reviews
trafficPolicy:
connectionPool:
tcp:
maxConnections: 100
subsets:
- name: v1
labels:
version: v1
Or, better yet, define a proper route rule for the service in the VirtualService
definition.For example, add a simple route rule for “reviews:v1”:
apiVersion: networking.istio.io/v1alpha3
kind: VirtualService
metadata:
name: reviews
spec:
hosts:
- reviews
http:
- route:
- destination:
host: reviews
subset: v1
Control configuration sharing across namespaces
You can define virtual services, destination rules, or service entriesin one namespace and then reuse them in other namespaces, if they are exportedto those namespaces.Istio exports all traffic management resources to all namespaces by default,but you can override the visibility with the exportTo
field.For example, only clients in the same namespace can use the following virtual service:
apiVersion: networking.istio.io/v1alpha3
kind: VirtualService
metadata:
name: myservice
spec:
hosts:
- myservice.com
exportTo:
- "."
http:
- route:
- destination:
host: myservice
You can similarly control the visibility of a Kubernetes Service
using the networking.istio.io/exportTo
annotation.
Setting the visibility of destination rules in a particular namespace doesn’tguarantee the rule is used. Exporting a destination rule to other namespaces enables you to use itin those namespaces, but to actually be applied during a request the namespace also needs to beon the destination rule lookup path:
- client namespace
- service namespace
- Istio configuration root (
istio-system
by default)For example, consider the following destination rule:
apiVersion: networking.istio.io/v1alpha3
kind: DestinationRule
metadata:
name: myservice
spec:
host: myservice.default.svc.cluster.local
trafficPolicy:
connectionPool:
tcp:
maxConnections: 100
Let’s assume you create this destination rule in namespace ns1
.
If you send a request to the myservice
service from a client in ns1
, the destinationrule would be applied, because it is in the first namespace on the lookup path, that is,in the client namespace.
If you now send the request from a different namespace, for example ns2
,the client is no longer in the same namespace as the destination rule, ns1
.Because the corresponding service, myservice.default.svc.cluster.local
, is also not in ns1
,but rather in the default
namespace, the destination rule will also not be found inthe second namespace of the lookup path, the service namespace.
Even if the myservice
service is exported to all namespaces and therefore visiblein ns2
and the destination rule is also exported to all namespaces, including ns2
,it will not be applied during the request from ns2
because it’s not in anyof the namespaces on the lookup path.
You can avoid this problem by creating the destination rule in the same namespace asthe corresponding service, default
in this example. It would then get applied to requestsfrom clients in any namespace.You can also move the destination rule to the istio-system
namespace, the third namespace onthe lookup path, although this isn’t recommended unless the destination rule is really a globalconfiguration that is applicable in all namespaces, and it would require administrator authority.
Istio uses this restricted destination rule lookup path for two reasons:
- Prevent destination rules from being defined that can override the behavior of servicesin completely unrelated namespaces.
- Have a clear lookup order in case there is more than one destination rule forthe same host.
Split large virtual services and destination rules into multiple resources
In situations where it is inconvenient to define the complete set of route rules or policies for a particularhost in a single VirtualService
or DestinationRule
resource, it may be preferable to incrementally specifythe configuration for the host in multiple resources.Pilot will merge such destination rulesand merge such virtual services if they are bound to a gateway.
Consider the case of a VirtualService
bound to an ingress gateway exposing an application host which usespath-based delegation to several implementation services, something like this:
apiVersion: networking.istio.io/v1alpha3
kind: VirtualService
metadata:
name: myapp
spec:
hosts:
- myapp.com
gateways:
- myapp-gateway
http:
- match:
- uri:
prefix: /service1
route:
- destination:
host: service1.default.svc.cluster.local
- match:
- uri:
prefix: /service2
route:
- destination:
host: service2.default.svc.cluster.local
- match:
...
The downside of this kind of configuration is that other configuration (e.g., route rules) for any of theunderlying microservices, will need to also be included in this single configuration file, instead ofin separate resources associated with, and potentially owned by, the individual service teams.See Route rules have no effect on ingress gateway requestsfor details.
To avoid this problem, it may be preferable to break up the configuration of myapp.com
into severalVirtualService
fragments, one per backend service. For example:
apiVersion: networking.istio.io/v1alpha3
kind: VirtualService
metadata:
name: myapp-service1
spec:
hosts:
- myapp.com
gateways:
- myapp-gateway
http:
- match:
- uri:
prefix: /service1
route:
- destination:
host: service1.default.svc.cluster.local
---
apiVersion: networking.istio.io/v1alpha3
kind: VirtualService
metadata:
name: myapp-service2
spec:
hosts:
- myapp.com
gateways:
- myapp-gateway
http:
- match:
- uri:
prefix: /service2
route:
- destination:
host: service2.default.svc.cluster.local
---
apiVersion: networking.istio.io/v1alpha3
kind: VirtualService
metadata:
name: myapp-...
When a second and subsequent VirtualService
for an existing host is applied, istio-pilot
will mergethe additional route rules into the existing configuration of the host. There are, however, severalcaveats with this feature that must be considered carefully when using it.
- Although the order of evaluation for rules in any given source
VirtualService
will be retained,the cross-resource order is UNDEFINED. In other words, there is no guaranteed order of evaluationfor rules across the fragment configurations, so it will only have predictable behavior if thereare no conflicting rules or order dependency between rules across fragments. - There should only be one “catch-all” rule (i.e., a rule that matches any request path or header) in the fragments.All such “catch-all” rules will be moved to the end of the list in the merged configuration, butsince they catch all requests, whichever is applied first will essentially override and disable any others.
A
VirtualService
can only be fragmented this way if it is bound to a gateway.Host merging is not supported in sidecars.ADestinationRule
can also be fragmented with similar merge semantic and restrictions.There should only be one definition of any given subset across multiple destination rules for the same host.If there is more than one with the same name, the first definition is used and any following duplicates are discarded.No merging of subset content is supported.
- There should only be one top-level
trafficPolicy
for the same host.When top-level traffic policies are defined in multiple destination rules, the first one will be used.Any following top-leveltrafficPolicy
configuration is discarded. - Unlike virtual service merging, destination rule merging works in both sidecars and gateways.
Avoid 503 errors while reconfiguring service routes
When setting route rules to direct traffic to specific versions (subsets) of a service, care must be taken to ensurethat the subsets are available before they are used in the routes. Otherwise, calls to the service may return503 errors during a reconfiguration period.
Creating both the VirtualServices
and DestinationRules
that define the corresponding subsets using a single kubectl
call (e.g., kubectl apply -f myVirtualServiceAndDestinationRule.yaml
is not sufficient because theresources propagate (from the configuration server, i.e., Kubernetes API server) to the Pilot instances in an eventually consistent manner. If theVirtualService
using the subsets arrives before the DestinationRule
where the subsets are defined, the Envoy configuration generated by Pilot would refer to non-existent upstream pools. This results in HTTP 503 errors until all configuration objects are available to Pilot.
To make sure services will have zero down-time when configuring routes with subsets, follow a “make-before-break” process as described below:
When adding new subsets:
Update
DestinationRules
to add a new subset first, before updating anyVirtualServices
that use it. Apply the rule usingkubectl
or any platform-specific tooling.Wait a few seconds for the
DestinationRule
configuration to propagate to the Envoy sidecarsUpdate the
VirtualService
to refer to the newly added subsets.
When removing subsets:
Update
VirtualServices
to remove any references to a subset, before removing the subset from aDestinationRule
.Wait a few seconds for the
VirtualService
configuration to propagate to the Envoy sidecars.Update the
DestinationRule
to remove the unused subsets.