Hipache: a distributed HTTP and websocket proxy
What is it?
Hipache (pronounce hɪ'pætʃɪ) is a distributed proxy designed to route high volumes of http and
websocket traffic to unusually large numbers of virtual hosts, in a highly
dynamic topology where backends are added and removed several times per second.
It is particularly well-suited for PaaS (platform-as-a-service) and other
environments that are both business-critical and multi-tenant.
Hipache was originally developed at dotCloud, a popular platform-as-a-service, to replace its first-generation routing layer based on a heavily instrumented nginx deployment. It currently serves production traffic for tens of thousands of applications hosted on dotCloud. Hipache is based on the node-http-proxy library.
Run it!
1. Installation
From the shell:
$ npm install hipache -g
The '-g' option will make the 'hipache' bin-script available system-wide (usually linked from '/usr/local/bin')
2. Configuration (config.json)
Basic Hipache configuration is described in a json file. For example:
{
"server": {
"accessLog": "/var/log/hipache_access.log",
"port": 80,
"workers": 5,
"maxSockets": 100,
"deadBackendTTL": 30,
"address": ["127.0.0.1", "::1"],
"https": {
"port": 443,
"key": "/etc/ssl/ssl.key",
"cert": "/etc/ssl/ssl.crt"
}
},
"driver": "redis://:password@127.0.0.1:6379/0"
}
- server.accessLog: location of the Access logs, the format is the same as nginx
- server.port: Port to listen to (HTTP)
- server.workers: Number of workers to be spawned (specify at least 1, the master process does not serve any request)
- server.maxSockets: The maximum number of sockets which can be opened on each backend (per worker)
- server.deadBackendTTL: The number of seconds a backend is flagged as `dead' before retrying to proxy another request to it (doesn't apply if you are using a third-party health checker)
- server.address: IPv4 and IPv6 Addresses listening (HTTP and HTTPS)
- server.https: SSL configuration (omit this section to disable HTTPS)
- driver: Redis url (you can omit this entirely to use the local redis on the default port). If you want a master/slave Redis, specify a second url for the master, eg:
driver: ["redis://slave:port", "redis://master:port"]. More generally, the driver syntax is:redis://:password@host:port/database#prefix- all parameter are optional, hence justredis:is a valid driver uri. More infos about drivers in lib/drivers.
3. Spawning
From the shell (defaults to using the config/config.json file):
$ hipache
If you use a privileged port (eg: 80):
$ sudo hipache
If you want to use a specific configuration file:
$ hipache --config path/to/someConfig.json
Managing multiple configuration files:
The default configuration file is config/config.json. It's possible to have
different configuration files named config_<suffix>.json, where the suffix
is the value of an environment variable named SETTINGS_FLAVOR.
For instance, here is how to spawn the server with the config_test.json
configuration file in order to run the tests.
$ SETTINGS_FLAVOR=test hipache
4. Configuring a vhost (redis)
All vhost configuration is managed through Redis. This makes it possible to update the configuration dynamically and gracefully while the server is running, and have that state shared accross workers and even accross Hipache instances.
It also makes it simple to write configuration adapters. It would be trivial to load a plain text configuration file into Redis (and update it at runtime).
Different configuration adapters will follow, but for the moment you have to provision the Redis manually.
Let's take an example, I want to proxify requests to 2 backends for the hostname www.dotcloud.com. The 2 backends IP are 192.168.0.42 and 192.168.0.43 and they serve the HTTP traffic on the port 80.
redis-cli is the standard client tool to talk to Redis from the terminal.
Here are the steps I will follow:
-
Create the frontend and associate an identifier
$ redis-cli rpush frontend:www.dotcloud.com mywebsite (integer) 1
The frontend identifer is mywebsite, it could be anything.
-
Associate the 2 backends
$ redis-cli rpush frontend:www.dotcloud.com http://192.168.0.42:80 (integer) 2 $ redis-cli rpush frontend:www.dotcloud.com http://192.168.0.43:80 (integer) 3 -
Review the configuration
$ redis-cli lrange frontend:www.dotcloud.com 0 -1 1) "mywebsite" 2) "http://192.168.0.42:80" 3) "http://192.168.0.43:80"
While the server is running, any of these steps can be re-run without messing up with the traffic.
5. OS integration
Upstart
Copy upstart.conf to /etc/init/hipache.conf.
Then you can use:
start hipache
stop hipache
restart hipache
The configuration file used is /etc/hipache.json.
Features
Load-balancing across multiple backends
As seen in the example above, multiple backends can be attached to a frontend.
All requests coming to the frontend are load-balanced across all healthy backends.
The backend to use for a specific request is determined randomly. Subsequent requests coming from the same client won't necessarily be routed to the same backend (since backend selection is purely random).
Dead backend detection
If a backend stops responding, it will be flagged as dead for a configurable amount of time. The dead backend will be temporarily removed from the load-balancing rotation.
Multi-process architecture
To optimize response times and make use of all your available cores, Hipache uses the cluster module (included in NodeJS), and spreads the load across multiple NodeJS processes. A master process is in charge of spawning workers and monitoring them. When a worker dies, the master spawns a new one.
Memory monitoring
The memory footprint of Hipache tends to grow slowly over time, indicating a probable memory leak. A close examination did not turn up any memory leak in Hipache's code itself; but it doesn't prove that there is none. Also, we did not investigate (yet) thoroughly the code of Hipache's external dependencies, so the leaks could be creeping there.
While we profile Hipache's memory to further reduce its footprint, we implemented a memory monitoring system to make sure that memory use doesn't go out of bounds. Each worker monitors its memory usage. If it crosses a given threshold, the worker stops accepting new connections, it lets the current requests complete cleanly, and it stops itself; it is then replaced by a new copy by the master process.
Dynamic configuration
You can alter the configuration stored in Redis at any time. There is no need to restart Hipache, or to signal it that the configuration has changed: Hipache will re-query Redis at each request. Worried about performance? We were, too! And we found out that accessing a local Redis is helluva fast. So fast, that it didn't increase measurably the HTTP request latency!
WebSocket
Hipache supports the WebSocket protocol. It doesn't do any fancy handling on its own and relies entirely on NodeJS and node-http-proxy.
SSL
If provided with a SSL private key and certificate, Hipache will support SSL connections, for "regular" requests as well as WebSocket upgrades.
Custom HTML error pages
When something wrong happens (e.g., a backend times out), or when a request for an undefined virtual host comes in, Hipache will display an error page. Those error pages can be customized.
Wildcard domains support
When adding virtual hosts in Hipache configuration, you can specify wildcards. E.g., instead (or in addition to) www.example.tld, you can insert *.example.tld. Hipache will look for an exact match first, and then for a wildcard one up to 5 subdomains deep, e.g. foo.bar.baz.qux.quux will attempt to match itself first, then *.bar.baz.qux.quux, then *.baz.qux.quux, etc.
Active Health-Check
Even though Hipache support passive health checks, it's also possible to run active health checks. This mechanism requires to run an external program (see third-party softwares below).
Third party softwares of interest
Health-checkers:
A web interface to manage vhosts: