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/ docs / admin / system_admin / tuning / tuning-scale-horizontally-cluster.rst

Scale Horizontally / RhodeCode Cluster

|RCE| is built in a way it support horizontal scaling across multiple machines. There are three main pre-requisites for that:

  • Shared storage that each machine can access. Using NFS or other shared storage system.
  • Shared DB connection across machines. Using MySQL/PostgreSQL that each node can access.
  • |RCE| user sessions and caches need to use a shared storage (e.g Redis/Memcached)

Horizontal scaling means adding more machines or workers into your pool of resources. Horizontally scaling |RCE| gives a huge performance increase, especially under large traffic scenarios with a high number of requests. This is very beneficial when |RCE| is serving many users simultaneously, or if continuous integration servers are automatically pulling and pushing code. It also adds High-Availability to your running system.

Cluster Overview

Below we'll present a configuration example that will use two separate nodes to serve |RCE| in a load-balanced environment. The 3rd node will act as a shared storage/cache and handle load-balancing. In addition 3rd node will be used as shared database instance.

This setup can be used both in Docker based configuration or with individual physical/virtual machines. Using the 3rd node for Storage/Redis/PostgreSQL/Nginx is optional. All those components can be installed on one of the two nodes used for |RCE|. We'll use following naming for our nodes:

  • rc-node-1 (NFS, DB, Cache node)
  • rc-node-2 (Worker node1)
  • rc-node-3 (Worker node2)

Our shares NFS storage in the example is located on /home/rcdev/storage and it's RW accessible on each node.

In this example we used certain recommended components, however many of those can be replaced by other, in case your organization already uses them, for example:

  • MySQL/PostgreSQL: Aren't replaceable and are the two only supported databases.
  • Nginx on rc-node-1 can be replaced by: Hardware Load Balancer (F5), Apache, HA-Proxy etc.
  • Nginx on rc-node-2/3 acts as a reverse proxy and can be replaced by other HTTP server acting as reverse proxy such as Apache.
  • Redis on rc-node-1 can be replaced by: Memcached

Here's an overview what components should be installed/setup on each server in our example:

  • rc-node-1:
  • main storage acting as NFS host.
  • nginx acting as a load-balancer.
  • postgresql-server used for database and sessions.
  • redis-server used for storing shared caches.
  • optionally rabbitmq-server or redis for Celery if used.
  • optionally if Celery is used Enterprise/Community instance + VCSServer.
  • optionally mailserver that can be shared by other instances.
  • optionally channelstream server to handle live communication for all instances.
  • rc-node-2/3:
  • nginx acting as a reverse proxy to handle requests to |RCE|.
  • 1x RhodeCode Enterprise/Community instance.
  • 1x VCSServer instance.
  • optionally for testing connection: postgresql-client, redis-client (redis-tools).

Before we start here are few assumptions that should be fulfilled:

  • make sure each node can access each other.
  • make sure Redis/MySQL/PostgreSQL/RabbitMQ are running on rc-node-1
  • make sure both rc-node-2/3 can access NFS storage with RW access
  • make sure rc-node-2/3 can access Redis/PostgreSQL, MySQL database on rc-node-1.
  • make sure Redis/Database/RabbitMQ are password protected and accessible only from rc-node-2/3.

Setup rc-node-2/3

Initially before rc-node-1 we'll configure both nodes 2 and 3 to operate as standalone nodes with their own hostnames. Use a default installation settings, and use the default local addresses (127.0.0.1) to configure VCSServer and Community/Enterprise instances. All external connectivity will be handled by the reverse proxy (Nginx in our example).

This way we can ensure each individual host works, accepts connections, or do some operations explicitly on chosen node.

In addition this would allow use to explicitly direct certain traffic to a node, e.g CI server will only call directly rc-node-3. This should be done similar to normal installation so check out Nginx/Apache configuration example to configure each host. Each one should already connect to shared database during installation.

  1. Assuming our final url will be http://rc-node-1, Configure instances_id, app.base_url
  1. On rc-node-2 find the following settings and edit :file:`/home/{user}/.rccontrol/{instance-id}/rhodecode.ini`
## required format is: *NAME-
instance_id = *rc-node-2-
app.base_url = http://rc-node-1
  1. On rc-node-3 find the following settings and edit :file:`/home/{user}/.rccontrol/{instance-id}/rhodecode.ini`
## required format is: *NAME-
instance_id = *rc-node-3-
app.base_url = http://rc-node-1
  1. Configure User Session to use a shared database. Example config that should be changed on both rc-node-2 and rc-node-3 . Edit :file:`/home/{user}/.rccontrol/{instance-id}/rhodecode.ini`
####################################
###       BEAKER SESSION        ####
####################################

## Disable the default `file` sessions
#beaker.session.type = file
#beaker.session.data_dir = %(here)s/data/sessions

## use shared db based session, fast, and allows easy management over logged in users
beaker.session.type = ext:database
beaker.session.table_name = db_session
# use our rc-node-1 here
beaker.session.sa.url = postgresql://postgres:qweqwe@rc-node-1/rhodecode
beaker.session.sa.pool_recycle = 3600
beaker.session.sa.echo = false

In addition make sure both instances use the same session.secret so users have persistent sessions across nodes. Please generate other one then in this example.

# use a unique generated long string
beaker.session.secret = 70e116cae2274656ba7265fd860aebbd
  1. Configure stored cached/archive cache to our shared NFS rc-node-1
# note the `_` prefix that allows using a directory without
# remap and rescan checking for vcs inside it.
cache_dir = /home/rcdev/storage/_cache_dir/data
# note archive cache dir is disabled by default, however if you enable
# it also needs to be shared
#archive_cache_dir = /home/rcdev/storage/_tarball_cache_dir
  1. Use shared exception store. Example config that should be changed on both rc-node-2 and rc-node-3, and also for VCSServer. Edit :file:`/home/{user}/.rccontrol/{instance-id}/rhodecode.ini` and :file:`/home/{user}/.rccontrol/{vcsserver-instance-id}/vcsserver.ini` and add/change following setting.
exception_tracker.store_path = /home/rcdev/storage/_exception_store_data
  1. Change cache backends to use Redis based caches. Below full example config that replaces default file-based cache to shared Redis with Distributed Lock.
#####################################
###         DOGPILE CACHE        ####
#####################################

## `cache_perms` cache settings for permission tree, auth TTL.
#rc_cache.cache_perms.backend = dogpile.cache.rc.file_namespace
#rc_cache.cache_perms.expiration_time = 300

## alternative `cache_perms` redis backend with distributed lock
rc_cache.cache_perms.backend = dogpile.cache.rc.redis
rc_cache.cache_perms.expiration_time = 300
## redis_expiration_time needs to be greater then expiration_time
rc_cache.cache_perms.arguments.redis_expiration_time = 7200
rc_cache.cache_perms.arguments.socket_timeout = 30
rc_cache.cache_perms.arguments.host = rc-node-1
rc_cache.cache_perms.arguments.password = qweqwe
rc_cache.cache_perms.arguments.port = 6379
rc_cache.cache_perms.arguments.db = 0
rc_cache.cache_perms.arguments.distributed_lock = true

## `cache_repo` cache settings for FileTree, Readme, RSS FEEDS
#rc_cache.cache_repo.backend = dogpile.cache.rc.file_namespace
#rc_cache.cache_repo.expiration_time = 2592000

## alternative `cache_repo` redis backend with distributed lock
rc_cache.cache_repo.backend = dogpile.cache.rc.redis
rc_cache.cache_repo.expiration_time = 2592000
## redis_expiration_time needs to be greater then expiration_time
rc_cache.cache_repo.arguments.redis_expiration_time = 2678400
rc_cache.cache_repo.arguments.socket_timeout = 30
rc_cache.cache_repo.arguments.host = rc-node-1
rc_cache.cache_repo.arguments.password = qweqwe
rc_cache.cache_repo.arguments.port = 6379
rc_cache.cache_repo.arguments.db = 1
rc_cache.cache_repo.arguments.distributed_lock = true

## cache settings for SQL queries, this needs to use memory type backend
rc_cache.sql_cache_short.backend = dogpile.cache.rc.memory_lru
rc_cache.sql_cache_short.expiration_time = 30

## `cache_repo_longterm` cache for repo object instances, this needs to use memory
## type backend as the objects kept are not pickle serializable
rc_cache.cache_repo_longterm.backend = dogpile.cache.rc.memory_lru
## by default we use 96H, this is using invalidation on push anyway
rc_cache.cache_repo_longterm.expiration_time = 345600
## max items in LRU cache, reduce this number to save memory, and expire last used
## cached objects
rc_cache.cache_repo_longterm.max_size = 10000
  1. Configure Nginx as reverse proxy on rc-node-2/3: Minimal Nginx config used:
## rate limiter for certain pages to prevent brute force attacks
limit_req_zone  $binary_remote_addr  zone=req_limit:10m   rate=1r/s;

## custom log format
log_format log_custom '$remote_addr - $remote_user [$time_local] '
                      '"$request" $status $body_bytes_sent '
                      '"$http_referer" "$http_user_agent" '
                      '$request_time $upstream_response_time $pipe';

server {
    listen          80;
    server_name     rc-node-2;
    #server_name     rc-node-3;

    access_log   /var/log/nginx/rhodecode.access.log log_custom;
    error_log    /var/log/nginx/rhodecode.error.log;

    # example of proxy.conf can be found in our docs.
    include     /etc/nginx/proxy.conf;

    ## serve static files by Nginx, recommended for performance
    location /_static/rhodecode {
        gzip on;
        gzip_min_length  500;
        gzip_proxied     any;
        gzip_comp_level 4;
        gzip_types  text/css text/javascript text/xml text/plain text/x-component application/javascript application/json application/xml application/rss+xml font/truetype font/opentype application/vnd.ms-fontobject image/svg+xml;
        gzip_vary on;
        gzip_disable     "msie6";
        expires 60d;
        #alias /home/rcdev/.rccontrol/community-1/static;
        alias /home/rcdev/.rccontrol/enterprise-1/static;
    }


    location /_admin/login {
        limit_req  zone=req_limit  burst=10  nodelay;
        try_files $uri @rhode;
    }

    location / {
        try_files $uri @rhode;
    }

    location @rhode {
        # Url to running RhodeCode instance.
        # This is shown as `- URL: <host>` in output from rccontrol status.
        proxy_pass      http://127.0.0.1:10020;
    }

    ## custom 502 error page. Will be displayed while RhodeCode server
    ## is turned off
    error_page 502 /502.html;
    location = /502.html {
       #root  /home/rcdev/.rccontrol/community-1/static;
       root  /home/rcdev/.rccontrol/enterprise-1/static;
    }
}
  1. Optional: Full text search, in case you use Whoosh full text search we also need a shared storage for the index. In our example our NFS is mounted at /home/rcdev/storage which represents out storage so we can use the following:
# note the `_` prefix that allows using a directory without
# remap and rescan checking for vcs inside it.
search.location = /home/rcdev/storage/_index_data/index

Note

If you use ElasticSearch it's by default shared, and simply running ES node is by default cluster compatible.

  1. Optional: If you intend to use mailing all instances need to use either a shared mailing node, or each will use individual local mail agent. Simply put node-1/2/3 needs to use same mailing configuration.

Setup rc-node-1

Configure Nginx as Load Balancer to rc-node-2/3. Minimal Nginx example below:

## define rc-cluster which contains a pool of our instances to connect to
upstream rc-cluster {
    # rc-node-2/3 are stored in /etc/hosts with correct IP addresses
    server rc-node-2:80;
    server rc-node-3:80;
}

server {
    listen          80;
    server_name     rc-node-1;

    location / {
        proxy_pass http://rc-cluster;
    }
}

Note

You should configure your load balancing accordingly. We recommend writing load balancing rules that will separate regular user traffic from automated process traffic like continuous servers or build bots. Sticky sessions are not required.

Show which instance handles a request

You can easily check if load-balancing is working as expected. Visit our main node rc-node-1 URL which at that point should already handle incoming requests and balance it across node-2/3.

Add a special GET param ?showrcid=1 to show current instance handling your request.

For example: visiting url http://rc-node-1/?showrcid=1 will show, in the bottom of the screen` cluster instance info. e.g: RhodeCode instance id: rc-node-3-rc-node-3-3246 which is generated from:

<NODE_HOSTNAME>-<INSTANCE_ID>-<WORKER_PID>

Using Celery with cluster

If Celery is used we recommend setting also an instance of Enterprise/Community+VCSserver on the node that is running RabbitMQ or Redis. Those instances will be used to executed async tasks on the rc-node-1. This is the most efficient setup. Celery usually handles tasks such as sending emails, forking repositories, importing repositories from external location etc. Using workers on instance that has the direct access to disks used by NFS as well as email server gives noticeable performance boost. Running local workers to the NFS storage results in faster execution of forking large repositories or sending lots of emails.

Those instances need to be configured in the same way as for other nodes. The instance in rc-node-1 can be added to the cluster, but we don't recommend doing it. For best results let it be isolated to only executing Celery tasks in the cluster setup.