Skip to content

Latest commit

 

History

History
executable file
·
179 lines (136 loc) · 7.91 KB

apiserver-watch.md

File metadata and controls

executable file
·
179 lines (136 loc) · 7.91 KB

WARNING WARNING WARNING WARNING WARNING

PLEASE NOTE: This document applies to the HEAD of the source tree

If you are using a released version of Kubernetes, you should refer to the docs that go with that version.

The latest release of this document can be found [here](http://releases.k8s.io/release-1.3/docs/proposals/apiserver-watch.md).

Documentation for other releases can be found at releases.k8s.io.

Abstract

In the current system, most watch requests sent to apiserver are redirected to etcd. This means that for every watch request the apiserver opens a watch on etcd.

The purpose of the proposal is to improve the overall performance of the system by solving the following problems:

  • having too many open watches on etcd
  • avoiding deserializing/converting the same objects multiple times in different watch results

In the future, we would also like to add an indexing mechanism to the watch. Although Indexer is not part of this proposal, it is supposed to be compatible with it - in the future Indexer should be incorporated into the proposed new watch solution in apiserver without requiring any redesign.

High level design

We are going to solve those problems by allowing many clients to watch the same storage in the apiserver, without being redirected to etcd.

At the high level, apiserver will have a single watch open to etcd, watching all the objects (of a given type) without any filtering. The changes delivered from etcd will then be stored in a cache in apiserver. This cache is in fact a "rolling history window" that will support clients having some amount of latency between their list and watch calls. Thus it will have a limited capacity and whenever a new change comes from etcd when a cache is full, the oldest change will be remove to make place for the new one.

When a client sends a watch request to apiserver, instead of redirecting it to etcd, it will cause:

  • registering a handler to receive all new changes coming from etcd
  • iterating though a watch window, starting at the requested resourceVersion to the head and sending filtered changes directory to the client, blocking the above until this iteration has caught up

This will be done be creating a go-routine per watcher that will be responsible for performing the above.

The following section describes the proposal in more details, analyzes some corner cases and divides the whole design in more fine-grained steps.

Proposal details

We would like the cache to be per-resource-type and optional. Thanks to it we will be able to:

  • have different cache sizes for different resources (e.g. bigger cache [= longer history] for pods, which can significantly affect performance)
  • avoid any overhead for objects that are watched very rarely (e.g. events are almost not watched at all, but there are a lot of them)
  • filter the cache for each watcher more effectively

If we decide to support watches spanning different resources in the future and we have an efficient indexing mechanisms, it should be relatively simple to unify the cache to be common for all the resources.

The rest of this section describes the concrete steps that need to be done to implement the proposal.

  1. Since we want the watch in apiserver to be optional for different resource types, this needs to be self-contained and hidden behind a well defined API. This should be a layer very close to etcd - in particular all registries: "pkg/registry/generic/etcd" should be built on top of it. We will solve it by turning tools.EtcdHelper by extracting its interface and treating this interface as this API - the whole watch mechanisms in apiserver will be hidden behind that interface. Thanks to it we will get an initial implementation for free and we will just need to reimplement few relevant functions (probably just Watch and List). Moreover, this will not require any changes in other parts of the code. This step is about extracting the interface of tools.EtcdHelper.

  2. Create a FIFO cache with a given capacity. In its "rolling history window" we will store two things:

  • the resourceVersion of the object (being an etcdIndex)
  • the object watched from etcd itself (in a deserialized form)

This should be as simple as having an array an treating it as a cyclic buffer. Obviously resourceVersion of objects watched from etcd will be increasing, but they are necessary for registering a new watcher that is interested in all the changes since a given etcdIndex.

Additionally, we should support LIST operation, otherwise clients can never start watching at now. We may consider passing lists through etcd, however this will not work once we have Indexer, so we will need that information in memory anyway. Thus, we should support LIST operation from the "end of the history" - i.e. from the moment just after the newest cached watched event. It should be pretty simple to do, because we can incrementally update this list whenever the new watch event is watched from etcd. We may consider reusing existing structures cache.Store or cache.Indexer ("pkg/client/cache") but this is not a hard requirement.

  1. Create the new implementation of the API, that will internally have a single watch open to etcd and will store the data received from etcd in the FIFO cache - this includes implementing registration of a new watcher which will start a new go-routine responsible for iterating over the cache and sending all the objects watcher is interested in (by applying filtering function) to the watcher.

  2. Add a support for processing "error too old" from etcd, which will require:

  • disconnect all the watchers
  • clear the internal cache and relist all objects from etcd
  • start accepting watchers again
  1. Enable watch in apiserver for some of the existing resource types - this should require only changes at the initialization level.

  2. The next step will be to incorporate some indexing mechanism, but details of it are TBD.

Future optimizations:

  1. The implementation of watch in apiserver internally will open a single watch to etcd, responsible for watching all the changes of objects of a given resource type. However, this watch can potentially expire at any time and reconnecting can return "too old resource version". In that case relisting is necessary. In such case, to avoid LIST requests coming from all watchers at the same time, we can introduce an additional etcd event type: EtcdResync

Whenever relisting will be done to refresh the internal watch to etcd, EtcdResync event will be send to all the watchers. It will contain the full list of all the objects the watcher is interested in (appropriately filtered) as the parameter of this watch event. Thus, we need to create the EtcdResync event, extend watch.Interface and its implementations to support it and handle those events appropriately in places like Reflector

However, this might turn out to be unnecessary optimization if apiserver will always keep up (which is possible in the new design). We will work out all necessary details at that point.

Analytics