* Moved the glossary to a new page and removed the advanced warnings from all internals docs. * Update website/source/layouts/docs.erb Co-Authored-By: Judith Malnick <judith@hashicorp.com> * Updates based on PR feedback * Update website/source/docs/internals/index.html.md * Update website/source/docs/internals/index.html.md * Update website/source/docs/internals/index.html.md * Update website/source/docs/internals/index.html.md * Update website/source/docs/internals/index.html.md
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docs | Consul Architecture | docs-internals-architecture | Consul is a complex system that has many different moving parts. To help users and developers of Consul form a mental model of how it works, this page documents the system architecture. |
Consul Architecture
Consul is a complex system that has many different moving parts. To help users and developers of Consul form a mental model of how it works, this page documents the system architecture.
-> Before describing the architecture, we recommend reading the glossary of terms to help clarify what is being discussed.
10,000 foot view
From a 10,000 foot altitude the architecture of Consul looks like this:
Let's break down this image and describe each piece. First of all, we can see that there are two datacenters, labeled "one" and "two". Consul has first class support for multiple datacenters and expects this to be the common case.
Within each datacenter, we have a mixture of clients and servers. It is expected that there be between three to five servers. This strikes a balance between availability in the case of failure and performance, as consensus gets progressively slower as more machines are added. However, there is no limit to the number of clients, and they can easily scale into the thousands or tens of thousands.
All the agents that are in a datacenter participate in a gossip protocol. This means there is a gossip pool that contains all the agents for a given datacenter. This serves a few purposes: first, there is no need to configure clients with the addresses of servers; discovery is done automatically. Second, the work of detecting agent failures is not placed on the servers but is distributed. This makes failure detection much more scalable than naive heartbeating schemes. It also provides failure detection for the nodes; if the agent is not reachable, than the node may have experienced a failure. Thirdly, it is used as a messaging layer to notify when important events such as leader election take place.
The servers in each datacenter are all part of a single Raft peer set. This means that they work together to elect a single leader, a selected server which has extra duties. The leader is responsible for processing all queries and transactions. Transactions must also be replicated to all peers as part of the consensus protocol. Because of this requirement, when a non-leader server receives an RPC request, it forwards it to the cluster leader.
The server agents also operate as part of a WAN gossip pool. This pool is different from the LAN pool as it is optimized for the higher latency of the internet and is expected to contain only other Consul server agents. The purpose of this pool is to allow datacenters to discover each other in a low-touch manner. Bringing a new datacenter online is as easy as joining the existing WAN gossip pool. Because the servers are all operating in this pool, it also enables cross-datacenter requests. When a server receives a request for a different datacenter, it forwards it to a random server in the correct datacenter. That server may then forward to the local leader.
This results in a very low coupling between datacenters, but because of failure detection, connection caching and multiplexing, cross-datacenter requests are relatively fast and reliable.
In general, data is not replicated between different Consul datacenters. When a request is made for a resource in another datacenter, the local Consul servers forward an RPC request to the remote Consul servers for that resource and return the results. If the remote datacenter is not available, then those resources will also not be available, but that won't otherwise affect the local datacenter. There are some special situations where a limited subset of data can be replicated, such as with Consul's built-in ACL replication capability, or external tools like consul-replicate.
In some places, client agents may cache data from the servers to make it available locally for performance and reliability. Examples include Connect certificates and intentions which allow the client agent to make local decisions about inbound connection requests without a round trip to the servers. Some API endpoints also support optional result caching. This helps reliability because the local agent can continue to respond to some queries like service-discovery or Connect authorization from cache even if the connection to the servers is disrupted or the servers are temporarily unavailable.
Getting in depth
At this point we've covered the high level architecture of Consul, but there are many more details for each of the subsystems. The consensus protocol is documented in detail as is the gossip protocol. The documentation for the security model and protocols used are also available.
For other details, either consult the code, ask in IRC, or reach out to the mailing list.