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347 lines
16 KiB
347 lines
16 KiB
# xDS REST and gRPC protocol |
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Envoy discovers its various dynamic resources via the filesystem or by querying |
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one or more management servers. Collectively, these discovery services and their |
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corresponding APIs are referred to as _xDS_. Resources are requested via |
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_subscriptions_, by specifying a filesystem path to watch, initiating gRPC |
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streams or polling a REST-JSON URL. The latter two methods involve sending |
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requests with a |
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[`DiscoveryRequest`](https://www.envoyproxy.io/docs/envoy/latest/api-v2/api/v2/discovery.proto#discoveryrequest) |
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proto payload. Resources are delivered in a |
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[`DiscoveryResponse`](https://www.envoyproxy.io/docs/envoy/latest/api-v2/api/v2/discovery.proto#discoveryresponse) |
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proto payload in all methods. We discuss each type of subscription below. |
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## Filesystem subscriptions |
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The simplest approach to delivering dynamic configuration is to place it at a |
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well known path specified in the |
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[`ConfigSource`](https://www.envoyproxy.io/docs/envoy/latest/api-v2/api/v2/core/config_source.proto#core-configsource). |
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Envoy will use `inotify` (`kqueue` on Mac OS X) to monitor the file for changes |
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and parse the `DiscoveryResponse` proto in the file on update. Binary |
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protobufs, JSON, YAML and proto text are supported formats for the |
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`DiscoveryResponse`. |
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There is no mechanism available for filesystem subscriptions to ACK/NACK updates |
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beyond stats counters and logs. The last valid configuration for an xDS API will |
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continue to apply if an configuration update rejection occurs. |
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## Streaming gRPC subscriptions |
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### Singleton resource type discovery |
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A gRPC |
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[`ApiConfigSource`](https://www.envoyproxy.io/docs/envoy/latest/api-v2/api/v2/core/config_source.proto#core-apiconfigsource) |
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can be specified independently for each xDS API, pointing at an upstream |
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cluster corresponding to a management server. This will initiate an independent |
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bidirectional gRPC stream for each xDS resource type, potentially to distinct |
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management servers. API delivery is eventually consistent. See |
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[ADS](#aggregated-discovery-service) below for situations in which explicit |
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control of sequencing is required. |
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#### Type URLs |
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Each xDS API is concerned with resources of a given type. There is a 1:1 |
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correspondence between an xDS API and a resource type. That is: |
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* [LDS: `envoy.api.v2.Listener`](envoy/api/v2/lds.proto) |
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* [RDS: `envoy.api.v2.RouteConfiguration`](envoy/api/v2/rds.proto) |
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* [CDS: `envoy.api.v2.Cluster`](envoy/api/v2/cds.proto) |
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* [EDS: `envoy.api.v2.ClusterLoadAssignment`](envoy/api/v2/eds.proto) |
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The concept of [_type |
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URLs_](https://developers.google.com/protocol-buffers/docs/proto3#any) appears |
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below, and takes the form `type.googleapis.com/<resource type>`, e.g. |
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`type.googleapis.com/envoy.api.v2.Cluster` for CDS. In various requests from |
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Envoy and responses by the management server, the resource type URL is stated. |
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#### ACK/NACK and versioning |
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Each stream begins with a `DiscoveryRequest` from Envoy, specifying the list of |
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resources to subscribe to, the type URL corresponding to the subscribed |
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resources, the node identifier and an empty `version_info`. An example EDS request |
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might be: |
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```yaml |
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version_info: |
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node: { id: envoy } |
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resource_names: |
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- foo |
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- bar |
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type_url: type.googleapis.com/envoy.api.v2.ClusterLoadAssignment |
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response_nonce: |
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``` |
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The management server may reply either immediately or when the requested |
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resources are available with a `DiscoveryResponse`, e.g.: |
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```yaml |
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version_info: X |
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resources: |
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- foo ClusterLoadAssignment proto encoding |
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- bar ClusterLoadAssignment proto encoding |
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type_url: type.googleapis.com/envoy.api.v2.ClusterLoadAssignment |
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nonce: A |
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``` |
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After processing the `DiscoveryResponse`, Envoy will send a new request on the |
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stream, specifying the last version successfully applied and the nonce provided |
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by the management server. If the update was successfully applied, the |
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`version_info` will be __X__, as indicated in the sequence diagram: |
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![Version update after ACK](diagrams/simple-ack.svg) |
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In this sequence diagram, and below, the following format is used to abbreviate |
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messages: |
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* `DiscoveryRequest`: (V=`version_info`,R=`resource_names`,N=`response_nonce`,T=`type_url`) |
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* `DiscoveryResponse`: (V=`version_info`,R=`resources`,N=`nonce`,T=`type_url`) |
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The version provides Envoy and the management server a shared notion of the |
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currently applied configuration, as well as a mechanism to ACK/NACK |
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configuration updates. If Envoy had instead rejected configuration update __X__, |
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it would reply with |
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[`error_detail`](https://www.envoyproxy.io/docs/envoy/latest/api-v2/api/v2/discovery.proto#envoy-api-field-discoveryrequest-error-detail) |
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populated and its previous version, which in this case was the empty |
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initial version. The error_detail has more details around the exact error message |
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populated in the message field: |
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![No version update after NACK](diagrams/simple-nack.svg) |
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Later, an API update may succeed at a new version __Y__: |
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![ACK after NACK](diagrams/later-ack.svg) |
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Each stream has its own notion of versioning, there is no shared versioning |
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across resource types. When ADS is not used, even each resource of a given |
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resource type may have a |
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distinct version, since the Envoy API allows distinct EDS/RDS resources to point |
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at different `ConfigSource`s. |
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#### When to send an update |
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The management server should only send updates to the Envoy client when the |
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resources in the `DiscoveryResponse` have changed. Envoy replies to any |
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`DiscoveryResponse` with a `DiscoveryRequest` containing the ACK/NACK |
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immediately after it has been either accepted or rejected. If the management |
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server provides the same set of resources rather than waiting for a change to |
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occur, it will cause Envoy and the management server to spin and have a severe |
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performance impact. |
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Within a stream, new `DiscoveryRequest`s supersede any prior `DiscoveryRequest`s |
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having the same resource type. This means that the management server only needs |
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to respond to the latest `DiscoveryRequest` on each stream for any given resource |
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type. |
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#### Resource hints |
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The `resource_names` specified in the `DiscoveryRequest` are a hint. Some |
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resource types, e.g. `Cluster`s and `Listener`s will specify an empty |
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`resource_names` list, since Envoy is interested in learning about all the |
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`Cluster`s (CDS) and `Listener`s (LDS) that the management server(s) know about |
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corresponding to its node identification. Other resource types, e.g. |
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`RouteConfiguration`s (RDS) and `ClusterLoadAssignment`s (EDS), follow from |
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earlier CDS/LDS updates and Envoy is able to explicitly enumerate these |
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resources. |
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LDS/CDS resource hints will always be empty and it is expected that the |
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management server will provide the complete state of the LDS/CDS resources in |
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each response. An absent `Listener` or `Cluster` will be deleted. |
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For EDS/RDS, the management server does not need to supply every requested |
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resource and may also supply additional, unrequested resources. `resource_names` |
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is only a hint. Envoy will silently ignore any superfluous resources. When a |
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requested resource is missing in a RDS or EDS update, Envoy will retain the last |
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known value for this resource. The management server may be able to infer all |
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the required EDS/RDS resources from the `node` identification in the |
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`DiscoveryRequest`, in which case this hint may be discarded. An empty EDS/RDS |
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`DiscoveryResponse` is effectively a nop from the perspective of the respective |
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resources in the Envoy. |
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When a `Listener` or `Cluster` is deleted, its corresponding EDS and RDS |
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resources are also deleted inside the Envoy instance. In order for EDS resources |
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to be known or tracked by Envoy, there must exist an applied `Cluster` |
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definition (e.g. sourced via CDS). A similar relationship exists between RDS and |
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`Listeners` (e.g. sourced via LDS). |
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For EDS/RDS, Envoy may either generate a distinct stream for each resource of a |
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given type (e.g. if each `ConfigSource` has its own distinct upstream cluster |
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for a management server), or may combine together multiple resource requests for |
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a given resource type when they are destined for the same management server. |
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While this is left to implementation specifics, management servers should be capable |
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of handling one or more `resource_names` for a given resource type in each |
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request. Both sequence diagrams below are valid for fetching two EDS resources |
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`{foo, bar}`: |
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![Multiple EDS requests on the same stream](diagrams/eds-same-stream.svg) |
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![Multiple EDS requests on distinct streams](diagrams/eds-distinct-stream.svg) |
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#### Resource updates |
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As discussed above, Envoy may update the list of `resource_names` it presents to |
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the management server in each `DiscoveryRequest` that ACK/NACKs a specific |
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`DiscoveryResponse`. In addition, Envoy may later issue additional |
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`DiscoveryRequest`s at a given `version_info` to update the management server |
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with new resource hints. For example, if Envoy is at EDS version __X__ and knows |
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only about cluster `foo`, but then receives a CDS update and learns about `bar` |
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in addition, it may issue an additional `DiscoveryRequest` for __X__ with |
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`{foo,bar}` as `resource_names`. |
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![CDS response leads to EDS resource hint update](diagrams/cds-eds-resources.svg) |
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There is a race condition that may arise here; if after a resource hint update |
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is issued by Envoy at __X__, but before the management server processes the |
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update it replies with a new version __Y__, the resource hint update may be |
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interpreted as a rejection of __Y__ by presenting an __X__ `version_info`. To |
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avoid this, the management server provides a `nonce` that Envoy uses to indicate |
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the specific `DiscoveryResponse` each `DiscoveryRequest` corresponds to: |
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![EDS update race motivates nonces](diagrams/update-race.svg) |
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The management server should not send a `DiscoveryResponse` for any |
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`DiscoveryRequest` that has a stale nonce. A nonce becomes stale following a |
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newer nonce being presented to Envoy in a `DiscoveryResponse`. A management |
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server does not need to send an update until it determines a new version is |
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available. Earlier requests at a version then also become stale. It may process |
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multiple `DiscoveryRequests` at a version until a new version is ready. |
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![Requests become stale](diagrams/stale-requests.svg) |
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An implication of the above resource update sequencing is that Envoy does not |
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expect a `DiscoveryResponse` for every `DiscoveryRequest` it issues. |
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#### Eventual consistency considerations |
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Since Envoy's xDS APIs are eventually consistent, traffic may drop briefly |
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during updates. For example, if only cluster __X__ is known via CDS/EDS, |
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a `RouteConfiguration` references cluster __X__ |
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and is then adjusted to cluster __Y__ just before the CDS/EDS update |
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providing __Y__, traffic will be blackholed until __Y__ is known about by the |
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Envoy instance. |
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For some applications, a temporary drop of traffic is acceptable, retries at the |
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client or by other Envoy sidecars will hide this drop. For other scenarios where |
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drop can't be tolerated, traffic drop could have been avoided by providing a |
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CDS/EDS update with both __X__ and __Y__, then the RDS update repointing from |
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__X__ to __Y__ and then a CDS/EDS update dropping __X__. |
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In general, to avoid traffic drop, sequencing of updates should follow a |
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`make before break` model, wherein |
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* CDS updates (if any) must always be pushed first. |
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* EDS updates (if any) must arrive after CDS updates for the respective clusters. |
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* LDS updates must arrive after corresponding CDS/EDS updates. |
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* RDS updates related to the newly added listeners must arrive in the end. |
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* Stale CDS clusters and related EDS endpoints (ones no longer being |
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referenced) can then be removed. |
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xDS updates can be pushed independently if no new clusters/routes/listeners |
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are added or if it's acceptable to temporarily drop traffic during |
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updates. Note that in case of LDS updates, the listeners will be warmed |
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before they receive traffic, i.e. the dependent routes are fetched through |
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RDS if configured. Clusters are warmed when adding/removing/updating |
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clusters. On the other hand, routes are not warmed, i.e., the management |
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plane must ensure that clusters referenced by a route are in place, before |
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pushing the updates for a route. |
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### Aggregated Discovery Services (ADS) |
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It's challenging to provide the above guarantees on sequencing to avoid traffic |
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drop when management servers are distributed. ADS allow a single management |
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server, via a single gRPC stream, to deliver all API updates. This provides the |
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ability to carefully sequence updates to avoid traffic drop. With ADS, a single |
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stream is used with multiple independent `DiscoveryRequest`/`DiscoveryResponse` |
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sequences multiplexed via the type URL. For any given type URL, the above |
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sequencing of `DiscoveryRequest` and `DiscoveryResponse` messages applies. An |
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example update sequence might look like: |
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![EDS/CDS multiplexed on an ADS stream](diagrams/ads.svg) |
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A single ADS stream is available per Envoy instance. |
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An example minimal `bootstrap.yaml` fragment for ADS configuration is: |
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```yaml |
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node: |
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id: <node identifier> |
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dynamic_resources: |
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cds_config: {ads: {}} |
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lds_config: {ads: {}} |
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ads_config: |
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api_type: GRPC |
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grpc_services: |
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envoy_grpc: |
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cluster_name: ads_cluster |
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static_resources: |
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clusters: |
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- name: ads_cluster |
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connect_timeout: { seconds: 5 } |
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type: STATIC |
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hosts: |
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- socket_address: |
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address: <ADS management server IP address> |
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port_value: <ADS management server port> |
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lb_policy: ROUND_ROBIN |
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http2_protocol_options: {} |
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admin: |
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... |
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``` |
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### Incremental xDS |
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Incremental xDS is a separate xDS endpoint available for ADS, CDS and RDS that |
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allows: |
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* Incremental updates of the list of tracked resources by the xDS client. |
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This supports Envoy on-demand / lazily requesting additional resources. For |
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example, this may occur when a request corresponding to an unknown cluster |
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arrives. |
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* The xDS server can incremetally update the resources on the client. |
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This supports the goal of scalability of xDS resources. Rather than deliver |
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all 100k clusters when a single cluster is modified, the management server |
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only needs to deliver the single cluster that changed. |
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An xDS incremental session is always in the context of a gRPC bidirectional |
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stream. This allows the xDS server to keep track of the state of xDS clients |
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connected to it. There is no REST version of Incremental xDS. |
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In incremental xDS the nonce field is required and used to pair a |
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[`IncrementalDiscoveryResponse`](https://www.envoyproxy.io/docs/envoy/latest/api-v2/api/v2/discovery.proto#discoveryrequest) |
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to a [`IncrementalDiscoveryRequest`](https://www.envoyproxy.io/docs/envoy/latest/api-v2/api/v2/discovery.proto#discoveryrequest) |
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ACK or NACK. |
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Optionally, a response message level system_version_info is present for |
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debugging purposes only. |
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`IncrementalDiscoveryRequest` can be sent in 3 situations: |
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1. Initial message in a xDS bidirectional gRPC stream. |
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2. As an ACK or NACK response to a previous `IncrementalDiscoveryResponse`. |
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In this case the `response_nonce` is set to the nonce value in the Response. |
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ACK or NACK is determined by the absence or presence of `error_detail`. |
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3. Spontaneous `IncrementalDiscoveryRequest` from the client. |
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This can be done to dynamically add or remove elements from the tracked |
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`resource_names` set. In this case `response_nonce` must be omitted. |
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In this first example the client connects and receives a first update that it |
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ACKs. The second update fails and the client NACKs the update. Later the xDS |
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client spontaneously requests the "wc" resource. |
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![Incremental session example](diagrams/incremental.svg) |
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On reconnect the xDS Incremental client may tell the server of its known resources |
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to avoid resending them over the network. |
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![Incremental reconnect example](diagrams/incremental-reconnect.svg) |
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## REST-JSON polling subscriptions |
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Synchronous (long) polling via REST endpoints is also available for the xDS |
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singleton APIs. The above sequencing of messages is similar, except no |
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persistent stream is maintained to the management server. It is expected that |
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there is only a single outstanding request at any point in time, and as a result |
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the response nonce is optional in REST-JSON. The [JSON canonical transform of |
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proto3](https://developers.google.com/protocol-buffers/docs/proto3#json) is used |
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to encode `DiscoveryRequest` and `DiscoveryResponse` messages. ADS is not |
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available for REST-JSON polling. |
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When the poll period is set to a small value, with the intention of long |
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polling, then there is also a requirement to avoid sending a `DiscoveryResponse` |
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[unless a change to the underlying resources has |
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occurred](#when-to-send-an-update).
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