1449 lines
59 KiB
Plaintext
1449 lines
59 KiB
Plaintext
-------------------
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HAProxy
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Architecture Guide
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-------------------
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version 1.1.34
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willy tarreau
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2006/01/29
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This document provides real world examples with working configurations.
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Please note that except stated otherwise, global configuration parameters
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such as logging, chrooting, limits and time-outs are not described here.
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===================================================
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1. Simple HTTP load-balancing with cookie insertion
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===================================================
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A web application often saturates the front-end server with high CPU loads,
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due to the scripting language involved. It also relies on a back-end database
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which is not much loaded. User contexts are stored on the server itself, and
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not in the database, so that simply adding another server with simple IP/TCP
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load-balancing would not work.
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+-------+
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|clients| clients and/or reverse-proxy
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+---+---+
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-+-----+--------+----
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| _|_db
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+--+--+ (___)
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| web | (___)
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+-----+ (___)
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192.168.1.1 192.168.1.2
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Replacing the web server with a bigger SMP system would cost much more than
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adding low-cost pizza boxes. The solution is to buy N cheap boxes and install
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the application on them. Install haproxy on the old one which will spread the
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load across the new boxes.
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192.168.1.1 192.168.1.11-192.168.1.14 192.168.1.2
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-------+-----------+-----+-----+-----+--------+----
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| | | | | _|_db
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+--+--+ +-+-+ +-+-+ +-+-+ +-+-+ (___)
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| LB1 | | A | | B | | C | | D | (___)
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+-----+ +---+ +---+ +---+ +---+ (___)
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haproxy 4 cheap web servers
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Config on haproxy (LB1) :
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-------------------------
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listen webfarm 192.168.1.1:80
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mode http
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balance roundrobin
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cookie SERVERID insert indirect
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option httpchk HEAD /index.html HTTP/1.0
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server webA 192.168.1.11:80 cookie A check
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server webB 192.168.1.12:80 cookie B check
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server webC 192.168.1.13:80 cookie C check
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server webD 192.168.1.14:80 cookie D check
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Description :
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-------------
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- LB1 will receive clients requests.
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- if a request does not contain a cookie, it will be forwarded to a valid
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server
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- in return, a cookie "SERVERID" will be inserted in the response holding the
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server name (eg: "A").
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- when the client comes again with the cookie "SERVERID=A", LB1 will know that
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it must be forwarded to server A. The cookie will be removed so that the
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server does not see it.
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- if server "webA" dies, the requests will be sent to another valid server
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and a cookie will be reassigned.
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Flows :
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-------
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(client) (haproxy) (server A)
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>-- GET /URI1 HTTP/1.0 ------------> |
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( no cookie, haproxy forwards in load-balancing mode. )
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| >-- GET /URI1 HTTP/1.0 ---------->
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| <-- HTTP/1.0 200 OK -------------<
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( the proxy now adds the server cookie in return )
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<-- HTTP/1.0 200 OK ---------------< |
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Set-Cookie: SERVERID=A |
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>-- GET /URI2 HTTP/1.0 ------------> |
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Cookie: SERVERID=A |
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( the proxy sees the cookie. it forwards to server A and deletes it )
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| >-- GET /URI2 HTTP/1.0 ---------->
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| <-- HTTP/1.0 200 OK -------------<
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( the proxy does not add the cookie in return because the client knows it )
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<-- HTTP/1.0 200 OK ---------------< |
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>-- GET /URI3 HTTP/1.0 ------------> |
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Cookie: SERVERID=A |
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( ... )
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Limits :
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--------
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- if clients use keep-alive (HTTP/1.1), only the first response will have
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a cookie inserted, and only the first request of each session will be
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analyzed. This does not cause trouble in insertion mode because the cookie
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is put immediately in the first response, and the session is maintained to
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the same server for all subsequent requests in the same session. However,
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the cookie will not be removed from the requests forwarded to the servers,
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so the server must not be sensitive to unknown cookies. If this causes
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trouble, you can disable keep-alive by adding the following option :
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option httpclose
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- if for some reason the clients cannot learn more than one cookie (eg: the
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clients are indeed some home-made applications or gateways), and the
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application already produces a cookie, you can use the "prefix" mode (see
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below).
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- LB1 becomes a very sensible server. If LB1 dies, nothing works anymore.
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=> you can back it up using keepalived (see below)
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- if the application needs to log the original client's IP, use the
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"forwardfor" option which will add an "X-Forwarded-For" header with the
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original client's IP address. You must also use "httpclose" to ensure
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that you will rewrite every requests and not only the first one of each
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session :
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option httpclose
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option forwardfor
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- if the application needs to log the original destination IP, use the
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"originalto" option which will add an "X-Original-To" header with the
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original destination IP address. You must also use "httpclose" to ensure
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that you will rewrite every requests and not only the first one of each
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session :
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option httpclose
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option originalto
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The web server will have to be configured to use this header instead.
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For example, on apache, you can use LogFormat for this :
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LogFormat "%{X-Forwarded-For}i %l %u %t \"%r\" %>s %b " combined
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CustomLog /var/log/httpd/access_log combined
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Hints :
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-------
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Sometimes on the internet, you will find a few percent of the clients which
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disable cookies on their browser. Obviously they have troubles everywhere on
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the web, but you can still help them access your site by using the "source"
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balancing algorithm instead of the "roundrobin". It ensures that a given IP
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address always reaches the same server as long as the number of servers remains
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unchanged. Never use this behind a proxy or in a small network, because the
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distribution will be unfair. However, in large internal networks, and on the
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internet, it works quite well. Clients which have a dynamic address will not
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be affected as long as they accept the cookie, because the cookie always has
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precedence over load balancing :
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listen webfarm 192.168.1.1:80
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mode http
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balance source
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cookie SERVERID insert indirect
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option httpchk HEAD /index.html HTTP/1.0
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server webA 192.168.1.11:80 cookie A check
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server webB 192.168.1.12:80 cookie B check
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server webC 192.168.1.13:80 cookie C check
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server webD 192.168.1.14:80 cookie D check
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==================================================================
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2. HTTP load-balancing with cookie prefixing and high availability
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==================================================================
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Now you don't want to add more cookies, but rather use existing ones. The
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application already generates a "JSESSIONID" cookie which is enough to track
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sessions, so we'll prefix this cookie with the server name when we see it.
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Since the load-balancer becomes critical, it will be backed up with a second
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one in VRRP mode using keepalived under Linux.
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Download the latest version of keepalived from this site and install it
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on each load-balancer LB1 and LB2 :
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http://www.keepalived.org/
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You then have a shared IP between the two load-balancers (we will still use the
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original IP). It is active only on one of them at any moment. To allow the
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proxy to bind to the shared IP on Linux 2.4, you must enable it in /proc :
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# echo 1 >/proc/sys/net/ipv4/ip_nonlocal_bind
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shared IP=192.168.1.1
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192.168.1.3 192.168.1.4 192.168.1.11-192.168.1.14 192.168.1.2
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-------+------------+-----------+-----+-----+-----+--------+----
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| | | | | | _|_db
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+--+--+ +--+--+ +-+-+ +-+-+ +-+-+ +-+-+ (___)
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| LB1 | | LB2 | | A | | B | | C | | D | (___)
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+-----+ +-----+ +---+ +---+ +---+ +---+ (___)
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haproxy haproxy 4 cheap web servers
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keepalived keepalived
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Config on both proxies (LB1 and LB2) :
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--------------------------------------
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listen webfarm 192.168.1.1:80
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mode http
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balance roundrobin
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cookie JSESSIONID prefix
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option httpclose
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option forwardfor
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option httpchk HEAD /index.html HTTP/1.0
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server webA 192.168.1.11:80 cookie A check
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server webB 192.168.1.12:80 cookie B check
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server webC 192.168.1.13:80 cookie C check
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server webD 192.168.1.14:80 cookie D check
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Notes: the proxy will modify EVERY cookie sent by the client and the server,
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so it is important that it can access to ALL cookies in ALL requests for
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each session. This implies that there is no keep-alive (HTTP/1.1), thus the
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"httpclose" option. Only if you know for sure that the client(s) will never
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use keep-alive (eg: Apache 1.3 in reverse-proxy mode), you can remove this
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option.
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Configuration for keepalived on LB1/LB2 :
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-----------------------------------------
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vrrp_script chk_haproxy { # Requires keepalived-1.1.13
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script "killall -0 haproxy" # cheaper than pidof
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interval 2 # check every 2 seconds
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weight 2 # add 2 points of prio if OK
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}
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vrrp_instance VI_1 {
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interface eth0
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state MASTER
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virtual_router_id 51
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priority 101 # 101 on master, 100 on backup
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virtual_ipaddress {
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192.168.1.1
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}
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track_script {
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chk_haproxy
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}
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}
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Description :
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-------------
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- LB1 is VRRP master (keepalived), LB2 is backup. Both monitor the haproxy
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process, and lower their prio if it fails, leading to a failover to the
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other node.
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- LB1 will receive clients requests on IP 192.168.1.1.
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- both load-balancers send their checks from their native IP.
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- if a request does not contain a cookie, it will be forwarded to a valid
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server
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- in return, if a JESSIONID cookie is seen, the server name will be prefixed
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into it, followed by a delimiter ('~')
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- when the client comes again with the cookie "JSESSIONID=A~xxx", LB1 will
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know that it must be forwarded to server A. The server name will then be
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extracted from cookie before it is sent to the server.
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- if server "webA" dies, the requests will be sent to another valid server
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and a cookie will be reassigned.
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Flows :
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-------
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(client) (haproxy) (server A)
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>-- GET /URI1 HTTP/1.0 ------------> |
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( no cookie, haproxy forwards in load-balancing mode. )
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| >-- GET /URI1 HTTP/1.0 ---------->
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| X-Forwarded-For: 10.1.2.3
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| <-- HTTP/1.0 200 OK -------------<
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( no cookie, nothing changed )
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<-- HTTP/1.0 200 OK ---------------< |
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>-- GET /URI2 HTTP/1.0 ------------> |
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( no cookie, haproxy forwards in lb mode, possibly to another server. )
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| >-- GET /URI2 HTTP/1.0 ---------->
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| X-Forwarded-For: 10.1.2.3
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| <-- HTTP/1.0 200 OK -------------<
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| Set-Cookie: JSESSIONID=123
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( the cookie is identified, it will be prefixed with the server name )
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<-- HTTP/1.0 200 OK ---------------< |
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Set-Cookie: JSESSIONID=A~123 |
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>-- GET /URI3 HTTP/1.0 ------------> |
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Cookie: JSESSIONID=A~123 |
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( the proxy sees the cookie, removes the server name and forwards
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to server A which sees the same cookie as it previously sent )
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| >-- GET /URI3 HTTP/1.0 ---------->
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| Cookie: JSESSIONID=123
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| X-Forwarded-For: 10.1.2.3
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| <-- HTTP/1.0 200 OK -------------<
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( no cookie, nothing changed )
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<-- HTTP/1.0 200 OK ---------------< |
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( ... )
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Hints :
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-------
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Sometimes, there will be some powerful servers in the farm, and some smaller
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ones. In this situation, it may be desirable to tell haproxy to respect the
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difference in performance. Let's consider that WebA and WebB are two old
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P3-1.2 GHz while WebC and WebD are shiny new Opteron-2.6 GHz. If your
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application scales with CPU, you may assume a very rough 2.6/1.2 performance
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ratio between the servers. You can inform haproxy about this using the "weight"
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keyword, with values between 1 and 256. It will then spread the load the most
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smoothly possible respecting those ratios :
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server webA 192.168.1.11:80 cookie A weight 12 check
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server webB 192.168.1.12:80 cookie B weight 12 check
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server webC 192.168.1.13:80 cookie C weight 26 check
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server webD 192.168.1.14:80 cookie D weight 26 check
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========================================================
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2.1 Variations involving external layer 4 load-balancers
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========================================================
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Instead of using a VRRP-based active/backup solution for the proxies,
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they can also be load-balanced by a layer4 load-balancer (eg: Alteon)
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which will also check that the services run fine on both proxies :
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| VIP=192.168.1.1
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+----+----+
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| Alteon |
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+----+----+
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192.168.1.3 | 192.168.1.4 192.168.1.11-192.168.1.14 192.168.1.2
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-------+-----+------+-----------+-----+-----+-----+--------+----
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| | | | | | _|_db
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+--+--+ +--+--+ +-+-+ +-+-+ +-+-+ +-+-+ (___)
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| LB1 | | LB2 | | A | | B | | C | | D | (___)
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+-----+ +-----+ +---+ +---+ +---+ +---+ (___)
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haproxy haproxy 4 cheap web servers
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Config on both proxies (LB1 and LB2) :
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--------------------------------------
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listen webfarm 0.0.0.0:80
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mode http
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balance roundrobin
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cookie JSESSIONID prefix
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option httpclose
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option forwardfor
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option httplog
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option dontlognull
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option httpchk HEAD /index.html HTTP/1.0
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server webA 192.168.1.11:80 cookie A check
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server webB 192.168.1.12:80 cookie B check
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server webC 192.168.1.13:80 cookie C check
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server webD 192.168.1.14:80 cookie D check
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The "dontlognull" option is used to prevent the proxy from logging the health
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checks from the Alteon. If a session exchanges no data, then it will not be
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logged.
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Config on the Alteon :
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----------------------
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/c/slb/real 11
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ena
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name "LB1"
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rip 192.168.1.3
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/c/slb/real 12
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ena
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name "LB2"
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rip 192.168.1.4
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/c/slb/group 10
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name "LB1-2"
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metric roundrobin
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health tcp
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add 11
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add 12
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/c/slb/virt 10
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ena
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vip 192.168.1.1
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/c/slb/virt 10/service http
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group 10
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Note: the health-check on the Alteon is set to "tcp" to prevent the proxy from
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forwarding the connections. It can also be set to "http", but for this the
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proxy must specify a "monitor-net" with the Alteons' addresses, so that the
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Alteon can really check that the proxies can talk HTTP but without forwarding
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the connections to the end servers. Check next section for an example on how to
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use monitor-net.
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============================================================
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2.2 Generic TCP relaying and external layer 4 load-balancers
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============================================================
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Sometimes it's useful to be able to relay generic TCP protocols (SMTP, TSE,
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VNC, etc...), for example to interconnect private networks. The problem comes
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when you use external load-balancers which need to send periodic health-checks
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to the proxies, because these health-checks get forwarded to the end servers.
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The solution is to specify a network which will be dedicated to monitoring
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systems and must not lead to a forwarding connection nor to any log, using the
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"monitor-net" keyword. Note: this feature expects a version of haproxy greater
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than or equal to 1.1.32 or 1.2.6.
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| VIP=172.16.1.1 |
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+----+----+ +----+----+
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| Alteon1 | | Alteon2 |
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+----+----+ +----+----+
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192.168.1.252 | GW=192.168.1.254 | 192.168.1.253
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------+---+------------+--+-----------------> TSE farm : 192.168.1.10
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192.168.1.1 | | 192.168.1.2
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+--+--+ +--+--+
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| LB1 | | LB2 |
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+-----+ +-----+
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haproxy haproxy
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Config on both proxies (LB1 and LB2) :
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--------------------------------------
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listen tse-proxy
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bind :3389,:1494,:5900 # TSE, ICA and VNC at once.
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mode tcp
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balance roundrobin
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server tse-farm 192.168.1.10
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monitor-net 192.168.1.252/31
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The "monitor-net" option instructs the proxies that any connection coming from
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192.168.1.252 or 192.168.1.253 will not be logged nor forwarded and will be
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closed immediately. The Alteon load-balancers will then see the proxies alive
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without perturbating the service.
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Config on the Alteon :
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----------------------
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/c/l3/if 1
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ena
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addr 192.168.1.252
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mask 255.255.255.0
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/c/slb/real 11
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ena
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name "LB1"
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rip 192.168.1.1
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/c/slb/real 12
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ena
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name "LB2"
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rip 192.168.1.2
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/c/slb/group 10
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name "LB1-2"
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metric roundrobin
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health tcp
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add 11
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add 12
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/c/slb/virt 10
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ena
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vip 172.16.1.1
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/c/slb/virt 10/service 1494
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group 10
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/c/slb/virt 10/service 3389
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group 10
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/c/slb/virt 10/service 5900
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group 10
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Special handling of SSL :
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-------------------------
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Sometimes, you want to send health-checks to remote systems, even in TCP mode,
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in order to be able to failover to a backup server in case the first one is
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dead. Of course, you can simply enable TCP health-checks, but it sometimes
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happens that intermediate firewalls between the proxies and the remote servers
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acknowledge the TCP connection themselves, showing an always-up server. Since
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this is generally encountered on long-distance communications, which often
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involve SSL, an SSL health-check has been implemented to work around this issue.
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It sends SSL Hello messages to the remote server, which in turns replies with
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SSL Hello messages. Setting it up is very easy :
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listen tcp-syslog-proxy
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bind :1514 # listen to TCP syslog traffic on this port (SSL)
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mode tcp
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balance roundrobin
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option ssl-hello-chk
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server syslog-prod-site 192.168.1.10 check
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server syslog-back-site 192.168.2.10 check backup
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=========================================================
|
|
3. Simple HTTP/HTTPS load-balancing with cookie insertion
|
|
=========================================================
|
|
|
|
This is the same context as in example 1 above, but the web
|
|
server uses HTTPS.
|
|
|
|
+-------+
|
|
|clients| clients
|
|
+---+---+
|
|
|
|
|
-+-----+--------+----
|
|
| _|_db
|
|
+--+--+ (___)
|
|
| SSL | (___)
|
|
| web | (___)
|
|
+-----+
|
|
192.168.1.1 192.168.1.2
|
|
|
|
|
|
Since haproxy does not handle SSL, this part will have to be extracted from the
|
|
servers (freeing even more resources) and installed on the load-balancer
|
|
itself. Install haproxy and apache+mod_ssl on the old box which will spread the
|
|
load between the new boxes. Apache will work in SSL reverse-proxy-cache. If the
|
|
application is correctly developed, it might even lower its load. However,
|
|
since there now is a cache between the clients and haproxy, some security
|
|
measures must be taken to ensure that inserted cookies will not be cached.
|
|
|
|
|
|
192.168.1.1 192.168.1.11-192.168.1.14 192.168.1.2
|
|
-------+-----------+-----+-----+-----+--------+----
|
|
| | | | | _|_db
|
|
+--+--+ +-+-+ +-+-+ +-+-+ +-+-+ (___)
|
|
| LB1 | | A | | B | | C | | D | (___)
|
|
+-----+ +---+ +---+ +---+ +---+ (___)
|
|
apache 4 cheap web servers
|
|
mod_ssl
|
|
haproxy
|
|
|
|
|
|
Config on haproxy (LB1) :
|
|
-------------------------
|
|
|
|
listen 127.0.0.1:8000
|
|
mode http
|
|
balance roundrobin
|
|
cookie SERVERID insert indirect nocache
|
|
option httpchk HEAD /index.html HTTP/1.0
|
|
server webA 192.168.1.11:80 cookie A check
|
|
server webB 192.168.1.12:80 cookie B check
|
|
server webC 192.168.1.13:80 cookie C check
|
|
server webD 192.168.1.14:80 cookie D check
|
|
|
|
|
|
Description :
|
|
-------------
|
|
- apache on LB1 will receive clients requests on port 443
|
|
- it forwards it to haproxy bound to 127.0.0.1:8000
|
|
- if a request does not contain a cookie, it will be forwarded to a valid
|
|
server
|
|
- in return, a cookie "SERVERID" will be inserted in the response holding the
|
|
server name (eg: "A"), and a "Cache-control: private" header will be added
|
|
so that the apache does not cache any page containing such cookie.
|
|
- when the client comes again with the cookie "SERVERID=A", LB1 will know that
|
|
it must be forwarded to server A. The cookie will be removed so that the
|
|
server does not see it.
|
|
- if server "webA" dies, the requests will be sent to another valid server
|
|
and a cookie will be reassigned.
|
|
|
|
Notes :
|
|
-------
|
|
- if the cookie works in "prefix" mode, there is no need to add the "nocache"
|
|
option because it is an application cookie which will be modified, and the
|
|
application flags will be preserved.
|
|
- if apache 1.3 is used as a front-end before haproxy, it always disables
|
|
HTTP keep-alive on the back-end, so there is no need for the "httpclose"
|
|
option on haproxy.
|
|
- configure apache to set the X-Forwarded-For header itself, and do not do
|
|
it on haproxy if you need the application to know about the client's IP.
|
|
|
|
|
|
Flows :
|
|
-------
|
|
|
|
(apache) (haproxy) (server A)
|
|
>-- GET /URI1 HTTP/1.0 ------------> |
|
|
( no cookie, haproxy forwards in load-balancing mode. )
|
|
| >-- GET /URI1 HTTP/1.0 ---------->
|
|
| <-- HTTP/1.0 200 OK -------------<
|
|
( the proxy now adds the server cookie in return )
|
|
<-- HTTP/1.0 200 OK ---------------< |
|
|
Set-Cookie: SERVERID=A |
|
|
Cache-Control: private |
|
|
>-- GET /URI2 HTTP/1.0 ------------> |
|
|
Cookie: SERVERID=A |
|
|
( the proxy sees the cookie. it forwards to server A and deletes it )
|
|
| >-- GET /URI2 HTTP/1.0 ---------->
|
|
| <-- HTTP/1.0 200 OK -------------<
|
|
( the proxy does not add the cookie in return because the client knows it )
|
|
<-- HTTP/1.0 200 OK ---------------< |
|
|
>-- GET /URI3 HTTP/1.0 ------------> |
|
|
Cookie: SERVERID=A |
|
|
( ... )
|
|
|
|
|
|
|
|
========================================
|
|
3.1. Alternate solution using Stunnel
|
|
========================================
|
|
|
|
When only SSL is required and cache is not needed, stunnel is a cheaper
|
|
solution than Apache+mod_ssl. By default, stunnel does not process HTTP and
|
|
does not add any X-Forwarded-For header, but there is a patch on the official
|
|
haproxy site to provide this feature to recent stunnel versions.
|
|
|
|
This time, stunnel will only process HTTPS and not HTTP. This means that
|
|
haproxy will get all HTTP traffic, so haproxy will have to add the
|
|
X-Forwarded-For header for HTTP traffic, but not for HTTPS traffic since
|
|
stunnel will already have done it. We will use the "except" keyword to tell
|
|
haproxy that connections from local host already have a valid header.
|
|
|
|
|
|
192.168.1.1 192.168.1.11-192.168.1.14 192.168.1.2
|
|
-------+-----------+-----+-----+-----+--------+----
|
|
| | | | | _|_db
|
|
+--+--+ +-+-+ +-+-+ +-+-+ +-+-+ (___)
|
|
| LB1 | | A | | B | | C | | D | (___)
|
|
+-----+ +---+ +---+ +---+ +---+ (___)
|
|
stunnel 4 cheap web servers
|
|
haproxy
|
|
|
|
|
|
Config on stunnel (LB1) :
|
|
-------------------------
|
|
|
|
cert=/etc/stunnel/stunnel.pem
|
|
setuid=stunnel
|
|
setgid=proxy
|
|
|
|
socket=l:TCP_NODELAY=1
|
|
socket=r:TCP_NODELAY=1
|
|
|
|
[https]
|
|
accept=192.168.1.1:443
|
|
connect=192.168.1.1:80
|
|
xforwardedfor=yes
|
|
|
|
|
|
Config on haproxy (LB1) :
|
|
-------------------------
|
|
|
|
listen 192.168.1.1:80
|
|
mode http
|
|
balance roundrobin
|
|
option forwardfor except 192.168.1.1
|
|
cookie SERVERID insert indirect nocache
|
|
option httpchk HEAD /index.html HTTP/1.0
|
|
server webA 192.168.1.11:80 cookie A check
|
|
server webB 192.168.1.12:80 cookie B check
|
|
server webC 192.168.1.13:80 cookie C check
|
|
server webD 192.168.1.14:80 cookie D check
|
|
|
|
Description :
|
|
-------------
|
|
- stunnel on LB1 will receive clients requests on port 443
|
|
- it forwards them to haproxy bound to port 80
|
|
- haproxy will receive HTTP client requests on port 80 and decrypted SSL
|
|
requests from Stunnel on the same port.
|
|
- stunnel will add the X-Forwarded-For header
|
|
- haproxy will add the X-Forwarded-For header for everyone except the local
|
|
address (stunnel).
|
|
|
|
|
|
========================================
|
|
4. Soft-stop for application maintenance
|
|
========================================
|
|
|
|
When an application is spread across several servers, the time to update all
|
|
instances increases, so the application seems jerky for a longer period.
|
|
|
|
HAproxy offers several solutions for this. Although it cannot be reconfigured
|
|
without being stopped, nor does it offer any external command, there are other
|
|
working solutions.
|
|
|
|
|
|
=========================================
|
|
4.1 Soft-stop using a file on the servers
|
|
=========================================
|
|
|
|
This trick is quite common and very simple: put a file on the server which will
|
|
be checked by the proxy. When you want to stop the server, first remove this
|
|
file. The proxy will see the server as failed, and will not send it any new
|
|
session, only the old ones if the "persist" option is used. Wait a bit then
|
|
stop the server when it does not receive anymore connections.
|
|
|
|
|
|
listen 192.168.1.1:80
|
|
mode http
|
|
balance roundrobin
|
|
cookie SERVERID insert indirect
|
|
option httpchk HEAD /running HTTP/1.0
|
|
server webA 192.168.1.11:80 cookie A check inter 2000 rise 2 fall 2
|
|
server webB 192.168.1.12:80 cookie B check inter 2000 rise 2 fall 2
|
|
server webC 192.168.1.13:80 cookie C check inter 2000 rise 2 fall 2
|
|
server webD 192.168.1.14:80 cookie D check inter 2000 rise 2 fall 2
|
|
option persist
|
|
redispatch
|
|
contimeout 5000
|
|
|
|
|
|
Description :
|
|
-------------
|
|
- every 2 seconds, haproxy will try to access the file "/running" on the
|
|
servers, and declare the server as down after 2 attempts (4 seconds).
|
|
- only the servers which respond with a 200 or 3XX response will be used.
|
|
- if a request does not contain a cookie, it will be forwarded to a valid
|
|
server
|
|
- if a request contains a cookie for a failed server, haproxy will insist
|
|
on trying to reach the server anyway, to let the user finish what they were
|
|
doing. ("persist" option)
|
|
- if the server is totally stopped, the connection will fail and the proxy
|
|
will rebalance the client to another server ("redispatch")
|
|
|
|
Usage on the web servers :
|
|
--------------------------
|
|
- to start the server :
|
|
# /etc/init.d/httpd start
|
|
# touch /home/httpd/www/running
|
|
|
|
- to soft-stop the server
|
|
# rm -f /home/httpd/www/running
|
|
|
|
- to completely stop the server :
|
|
# /etc/init.d/httpd stop
|
|
|
|
Limits
|
|
------
|
|
If the server is totally powered down, the proxy will still try to reach it
|
|
for those clients who still have a cookie referencing it, and the connection
|
|
attempt will expire after 5 seconds ("contimeout"), and only after that, the
|
|
client will be redispatched to another server. So this mode is only useful
|
|
for software updates where the server will suddenly refuse the connection
|
|
because the process is stopped. The problem is the same if the server suddenly
|
|
crashes. All of its users will be fairly perturbated.
|
|
|
|
|
|
==================================
|
|
4.2 Soft-stop using backup servers
|
|
==================================
|
|
|
|
A better solution which covers every situation is to use backup servers.
|
|
Version 1.1.30 fixed a bug which prevented a backup server from sharing
|
|
the same cookie as a standard server.
|
|
|
|
|
|
listen 192.168.1.1:80
|
|
mode http
|
|
balance roundrobin
|
|
redispatch
|
|
cookie SERVERID insert indirect
|
|
option httpchk HEAD / HTTP/1.0
|
|
server webA 192.168.1.11:80 cookie A check port 81 inter 2000
|
|
server webB 192.168.1.12:80 cookie B check port 81 inter 2000
|
|
server webC 192.168.1.13:80 cookie C check port 81 inter 2000
|
|
server webD 192.168.1.14:80 cookie D check port 81 inter 2000
|
|
|
|
server bkpA 192.168.1.11:80 cookie A check port 80 inter 2000 backup
|
|
server bkpB 192.168.1.12:80 cookie B check port 80 inter 2000 backup
|
|
server bkpC 192.168.1.13:80 cookie C check port 80 inter 2000 backup
|
|
server bkpD 192.168.1.14:80 cookie D check port 80 inter 2000 backup
|
|
|
|
Description
|
|
-----------
|
|
Four servers webA..D are checked on their port 81 every 2 seconds. The same
|
|
servers named bkpA..D are checked on the port 80, and share the exact same
|
|
cookies. Those servers will only be used when no other server is available
|
|
for the same cookie.
|
|
|
|
When the web servers are started, only the backup servers are seen as
|
|
available. On the web servers, you need to redirect port 81 to local
|
|
port 80, either with a local proxy (eg: a simple haproxy tcp instance),
|
|
or with iptables (linux) or pf (openbsd). This is because we want the
|
|
real web server to reply on this port, and not a fake one. Eg, with
|
|
iptables :
|
|
|
|
# /etc/init.d/httpd start
|
|
# iptables -t nat -A PREROUTING -p tcp --dport 81 -j REDIRECT --to-port 80
|
|
|
|
A few seconds later, the standard server is seen up and haproxy starts to send
|
|
it new requests on its real port 80 (only new users with no cookie, of course).
|
|
|
|
If a server completely crashes (even if it does not respond at the IP level),
|
|
both the standard and backup servers will fail, so clients associated to this
|
|
server will be redispatched to other live servers and will lose their sessions.
|
|
|
|
Now if you want to enter a server into maintenance, simply stop it from
|
|
responding on port 81 so that its standard instance will be seen as failed,
|
|
but the backup will still work. Users will not notice anything since the
|
|
service is still operational :
|
|
|
|
# iptables -t nat -D PREROUTING -p tcp --dport 81 -j REDIRECT --to-port 80
|
|
|
|
The health checks on port 81 for this server will quickly fail, and the
|
|
standard server will be seen as failed. No new session will be sent to this
|
|
server, and existing clients with a valid cookie will still reach it because
|
|
the backup server will still be up.
|
|
|
|
Now wait as long as you want for the old users to stop using the service, and
|
|
once you see that the server does not receive any traffic, simply stop it :
|
|
|
|
# /etc/init.d/httpd stop
|
|
|
|
The associated backup server will in turn fail, and if any client still tries
|
|
to access this particular server, they will be redispatched to any other valid
|
|
server because of the "redispatch" option.
|
|
|
|
This method has an advantage : you never touch the proxy when doing server
|
|
maintenance. The people managing the servers can make them disappear smoothly.
|
|
|
|
|
|
4.2.1 Variations for operating systems without any firewall software
|
|
--------------------------------------------------------------------
|
|
|
|
The downside is that you need a redirection solution on the server just for
|
|
the health-checks. If the server OS does not support any firewall software,
|
|
this redirection can also be handled by a simple haproxy in tcp mode :
|
|
|
|
global
|
|
daemon
|
|
quiet
|
|
pidfile /var/run/haproxy-checks.pid
|
|
listen 0.0.0.0:81
|
|
mode tcp
|
|
dispatch 127.0.0.1:80
|
|
contimeout 1000
|
|
clitimeout 10000
|
|
srvtimeout 10000
|
|
|
|
To start the web service :
|
|
|
|
# /etc/init.d/httpd start
|
|
# haproxy -f /etc/haproxy/haproxy-checks.cfg
|
|
|
|
To soft-stop the service :
|
|
|
|
# kill $(</var/run/haproxy-checks.pid)
|
|
|
|
The port 81 will stop responding and the load-balancer will notice the failure.
|
|
|
|
|
|
4.2.2 Centralizing the server management
|
|
----------------------------------------
|
|
|
|
If one finds it preferable to manage the servers from the load-balancer itself,
|
|
the port redirector can be installed on the load-balancer itself. See the
|
|
example with iptables below.
|
|
|
|
Make the servers appear as operational :
|
|
# iptables -t nat -A OUTPUT -d 192.168.1.11 -p tcp --dport 81 -j DNAT --to-dest :80
|
|
# iptables -t nat -A OUTPUT -d 192.168.1.12 -p tcp --dport 81 -j DNAT --to-dest :80
|
|
# iptables -t nat -A OUTPUT -d 192.168.1.13 -p tcp --dport 81 -j DNAT --to-dest :80
|
|
# iptables -t nat -A OUTPUT -d 192.168.1.14 -p tcp --dport 81 -j DNAT --to-dest :80
|
|
|
|
Soft stop one server :
|
|
# iptables -t nat -D OUTPUT -d 192.168.1.12 -p tcp --dport 81 -j DNAT --to-dest :80
|
|
|
|
Another solution is to use the "COMAFILE" patch provided by Alexander Lazic,
|
|
which is available for download here :
|
|
|
|
http://w.ods.org/tools/haproxy/contrib/
|
|
|
|
|
|
4.2.3 Notes :
|
|
-------------
|
|
- Never, ever, start a fake service on port 81 for the health-checks, because
|
|
a real web service failure will not be detected as long as the fake service
|
|
runs. You must really forward the check port to the real application.
|
|
|
|
- health-checks will be sent twice as often, once for each standard server,
|
|
and once for each backup server. All this will be multiplicated by the
|
|
number of processes if you use multi-process mode. You will have to ensure
|
|
that all the checks sent to the server do not overload it.
|
|
|
|
=======================
|
|
4.3 Hot reconfiguration
|
|
=======================
|
|
|
|
There are two types of haproxy users :
|
|
- those who can never do anything in production out of maintenance periods ;
|
|
- those who can do anything at any time provided that the consequences are
|
|
limited.
|
|
|
|
The first ones have no problem stopping the server to change configuration
|
|
because they got some maintenance periods during which they can break anything.
|
|
So they will even prefer doing a clean stop/start sequence to ensure everything
|
|
will work fine upon next reload. Since those have represented the majority of
|
|
haproxy uses, there has been little effort trying to improve this.
|
|
|
|
However, the second category is a bit different. They like to be able to fix an
|
|
error in a configuration file without anyone noticing. This can sometimes also
|
|
be the case for the first category because humans are not failsafe.
|
|
|
|
For this reason, a new hot reconfiguration mechanism has been introduced in
|
|
version 1.1.34. Its usage is very simple and works even in chrooted
|
|
environments with lowered privileges. The principle is very simple : upon
|
|
reception of a SIGTTOU signal, the proxy will stop listening to all the ports.
|
|
This will release the ports so that a new instance can be started. Existing
|
|
connections will not be broken at all. If the new instance fails to start,
|
|
then sending a SIGTTIN signal back to the original processes will restore
|
|
the listening ports. This is possible without any special privileges because
|
|
the sockets will not have been closed, so the bind() is still valid. Otherwise,
|
|
if the new process starts successfully, then sending a SIGUSR1 signal to the
|
|
old one ensures that it will exit as soon as its last session ends.
|
|
|
|
A hot reconfiguration script would look like this :
|
|
|
|
# save previous state
|
|
mv /etc/haproxy/config /etc/haproxy/config.old
|
|
mv /var/run/haproxy.pid /var/run/haproxy.pid.old
|
|
|
|
mv /etc/haproxy/config.new /etc/haproxy/config
|
|
kill -TTOU $(cat /var/run/haproxy.pid.old)
|
|
if haproxy -p /var/run/haproxy.pid -f /etc/haproxy/config; then
|
|
echo "New instance successfully loaded, stopping previous one."
|
|
kill -USR1 $(cat /var/run/haproxy.pid.old)
|
|
rm -f /var/run/haproxy.pid.old
|
|
exit 1
|
|
else
|
|
echo "New instance failed to start, resuming previous one."
|
|
kill -TTIN $(cat /var/run/haproxy.pid.old)
|
|
rm -f /var/run/haproxy.pid
|
|
mv /var/run/haproxy.pid.old /var/run/haproxy.pid
|
|
mv /etc/haproxy/config /etc/haproxy/config.new
|
|
mv /etc/haproxy/config.old /etc/haproxy/config
|
|
exit 0
|
|
fi
|
|
|
|
After this, you can still force old connections to end by sending
|
|
a SIGTERM to the old process if it still exists :
|
|
|
|
kill $(cat /var/run/haproxy.pid.old)
|
|
rm -f /var/run/haproxy.pid.old
|
|
|
|
Be careful with this as in multi-process mode, some pids might already
|
|
have been reallocated to completely different processes.
|
|
|
|
|
|
==================================================
|
|
5. Multi-site load-balancing with local preference
|
|
==================================================
|
|
|
|
5.1 Description of the problem
|
|
==============================
|
|
|
|
Consider a world-wide company with sites on several continents. There are two
|
|
production sites SITE1 and SITE2 which host identical applications. There are
|
|
many offices around the world. For speed and communication cost reasons, each
|
|
office uses the nearest site by default, but can switch to the backup site in
|
|
the event of a site or application failure. There also are users on the
|
|
production sites, which use their local sites by default, but can switch to the
|
|
other site in case of a local application failure.
|
|
|
|
The main constraints are :
|
|
|
|
- application persistence : although the application is the same on both
|
|
sites, there is no session synchronisation between the sites. A failure
|
|
of one server or one site can cause a user to switch to another server
|
|
or site, but when the server or site comes back, the user must not switch
|
|
again.
|
|
|
|
- communication costs : inter-site communication should be reduced to the
|
|
minimum. Specifically, in case of a local application failure, every
|
|
office should be able to switch to the other site without continuing to
|
|
use the default site.
|
|
|
|
5.2 Solution
|
|
============
|
|
- Each production site will have two haproxy load-balancers in front of its
|
|
application servers to balance the load across them and provide local HA.
|
|
We will call them "S1L1" and "S1L2" on site 1, and "S2L1" and "S2L2" on
|
|
site 2. These proxies will extend the application's JSESSIONID cookie to
|
|
put the server name as a prefix.
|
|
|
|
- Each production site will have one front-end haproxy director to provide
|
|
the service to local users and to remote offices. It will load-balance
|
|
across the two local load-balancers, and will use the other site's
|
|
load-balancers as backup servers. It will insert the local site identifier
|
|
in a SITE cookie for the local load-balancers, and the remote site
|
|
identifier for the remote load-balancers. These front-end directors will
|
|
be called "SD1" and "SD2" for "Site Director".
|
|
|
|
- Each office will have one haproxy near the border gateway which will direct
|
|
local users to their preference site by default, or to the backup site in
|
|
the event of a previous failure. It will also analyze the SITE cookie, and
|
|
direct the users to the site referenced in the cookie. Thus, the preferred
|
|
site will be declared as a normal server, and the backup site will be
|
|
declared as a backup server only, which will only be used when the primary
|
|
site is unreachable, or when the primary site's director has forwarded
|
|
traffic to the second site. These proxies will be called "OP1".."OPXX"
|
|
for "Office Proxy #XX".
|
|
|
|
|
|
5.3 Network diagram
|
|
===================
|
|
|
|
Note : offices 1 and 2 are on the same continent as site 1, while
|
|
office 3 is on the same continent as site 3. Each production
|
|
site can reach the second one either through the WAN or through
|
|
a dedicated link.
|
|
|
|
|
|
Office1 Office2 Office3
|
|
users users users
|
|
192.168 # # # 192.168 # # # # # #
|
|
.1.0/24 | | | .2.0/24 | | | 192.168.3.0/24 | | |
|
|
--+----+-+-+- --+----+-+-+- ---+----+-+-+-
|
|
| | .1 | | .1 | | .1
|
|
| +-+-+ | +-+-+ | +-+-+
|
|
| |OP1| | |OP2| | |OP3| ...
|
|
,-:-. +---+ ,-:-. +---+ ,-:-. +---+
|
|
( X ) ( X ) ( X )
|
|
`-:-' `-:-' ,---. `-:-'
|
|
--+---------------+------+----~~~( X )~~~~-------+---------+-
|
|
| `---' |
|
|
| |
|
|
+---+ ,-:-. +---+ ,-:-.
|
|
|SD1| ( X ) |SD2| ( X )
|
|
( SITE 1 ) +-+-+ `-:-' ( SITE 2 ) +-+-+ `-:-'
|
|
|.1 | |.1 |
|
|
10.1.1.0/24 | | ,---. 10.2.1.0/24 | |
|
|
-+-+-+-+-+-+-+-----+-+--( X )------+-+-+-+-+-+-+-----+-+--
|
|
| | | | | | | `---' | | | | | | |
|
|
...# # # # # |.11 |.12 ...# # # # # |.11 |.12
|
|
Site 1 +-+--+ +-+--+ Site 2 +-+--+ +-+--+
|
|
Local |S1L1| |S1L2| Local |S2L1| |S2L2|
|
|
users +-+--+ +--+-+ users +-+--+ +--+-+
|
|
| | | |
|
|
10.1.2.0/24 -+-+-+--+--++-- 10.2.2.0/24 -+-+-+--+--++--
|
|
|.1 |.4 |.1 |.4
|
|
+-+-+ +-+-+ +-+-+ +-+-+
|
|
|W11| ~~~ |W14| |W21| ~~~ |W24|
|
|
+---+ +---+ +---+ +---+
|
|
4 application servers 4 application servers
|
|
on site 1 on site 2
|
|
|
|
|
|
|
|
5.4 Description
|
|
===============
|
|
|
|
5.4.1 Local users
|
|
-----------------
|
|
- Office 1 users connect to OP1 = 192.168.1.1
|
|
- Office 2 users connect to OP2 = 192.168.2.1
|
|
- Office 3 users connect to OP3 = 192.168.3.1
|
|
- Site 1 users connect to SD1 = 10.1.1.1
|
|
- Site 2 users connect to SD2 = 10.2.1.1
|
|
|
|
5.4.2 Office proxies
|
|
--------------------
|
|
- Office 1 connects to site 1 by default and uses site 2 as a backup.
|
|
- Office 2 connects to site 1 by default and uses site 2 as a backup.
|
|
- Office 3 connects to site 2 by default and uses site 1 as a backup.
|
|
|
|
The offices check the local site's SD proxy every 30 seconds, and the
|
|
remote one every 60 seconds.
|
|
|
|
|
|
Configuration for Office Proxy OP1
|
|
----------------------------------
|
|
|
|
listen 192.168.1.1:80
|
|
mode http
|
|
balance roundrobin
|
|
redispatch
|
|
cookie SITE
|
|
option httpchk HEAD / HTTP/1.0
|
|
server SD1 10.1.1.1:80 cookie SITE1 check inter 30000
|
|
server SD2 10.2.1.1:80 cookie SITE2 check inter 60000 backup
|
|
|
|
|
|
Configuration for Office Proxy OP2
|
|
----------------------------------
|
|
|
|
listen 192.168.2.1:80
|
|
mode http
|
|
balance roundrobin
|
|
redispatch
|
|
cookie SITE
|
|
option httpchk HEAD / HTTP/1.0
|
|
server SD1 10.1.1.1:80 cookie SITE1 check inter 30000
|
|
server SD2 10.2.1.1:80 cookie SITE2 check inter 60000 backup
|
|
|
|
|
|
Configuration for Office Proxy OP3
|
|
----------------------------------
|
|
|
|
listen 192.168.3.1:80
|
|
mode http
|
|
balance roundrobin
|
|
redispatch
|
|
cookie SITE
|
|
option httpchk HEAD / HTTP/1.0
|
|
server SD2 10.2.1.1:80 cookie SITE2 check inter 30000
|
|
server SD1 10.1.1.1:80 cookie SITE1 check inter 60000 backup
|
|
|
|
|
|
5.4.3 Site directors ( SD1 and SD2 )
|
|
------------------------------------
|
|
The site directors forward traffic to the local load-balancers, and set a
|
|
cookie to identify the site. If no local load-balancer is available, or if
|
|
the local application servers are all down, it will redirect traffic to the
|
|
remote site, and report this in the SITE cookie. In order not to uselessly
|
|
load each site's WAN link, each SD will check the other site at a lower
|
|
rate. The site directors will also insert their client's address so that
|
|
the application server knows which local user or remote site accesses it.
|
|
|
|
The SITE cookie which is set by these directors will also be understood
|
|
by the office proxies. This is important because if SD1 decides to forward
|
|
traffic to site 2, it will write "SITE2" in the "SITE" cookie, and on next
|
|
request, the office proxy will automatically and directly talk to SITE2 if
|
|
it can reach it. If it cannot, it will still send the traffic to SITE1
|
|
where SD1 will in turn try to reach SITE2.
|
|
|
|
The load-balancers checks are performed on port 81. As we'll see further,
|
|
the load-balancers provide a health monitoring port 81 which reroutes to
|
|
port 80 but which allows them to tell the SD that they are going down soon
|
|
and that the SD must not use them anymore.
|
|
|
|
|
|
Configuration for SD1
|
|
---------------------
|
|
|
|
listen 10.1.1.1:80
|
|
mode http
|
|
balance roundrobin
|
|
redispatch
|
|
cookie SITE insert indirect
|
|
option httpchk HEAD / HTTP/1.0
|
|
option forwardfor
|
|
server S1L1 10.1.1.11:80 cookie SITE1 check port 81 inter 4000
|
|
server S1L2 10.1.1.12:80 cookie SITE1 check port 81 inter 4000
|
|
server S2L1 10.2.1.11:80 cookie SITE2 check port 81 inter 8000 backup
|
|
server S2L2 10.2.1.12:80 cookie SITE2 check port 81 inter 8000 backup
|
|
|
|
Configuration for SD2
|
|
---------------------
|
|
|
|
listen 10.2.1.1:80
|
|
mode http
|
|
balance roundrobin
|
|
redispatch
|
|
cookie SITE insert indirect
|
|
option httpchk HEAD / HTTP/1.0
|
|
option forwardfor
|
|
server S2L1 10.2.1.11:80 cookie SITE2 check port 81 inter 4000
|
|
server S2L2 10.2.1.12:80 cookie SITE2 check port 81 inter 4000
|
|
server S1L1 10.1.1.11:80 cookie SITE1 check port 81 inter 8000 backup
|
|
server S1L2 10.1.1.12:80 cookie SITE1 check port 81 inter 8000 backup
|
|
|
|
|
|
5.4.4 Local load-balancers S1L1, S1L2, S2L1, S2L2
|
|
-------------------------------------------------
|
|
Please first note that because SD1 and SD2 use the same cookie for both
|
|
servers on a same site, the second load-balancer of each site will only
|
|
receive load-balanced requests, but as soon as the SITE cookie will be
|
|
set, only the first LB will receive the requests because it will be the
|
|
first one to match the cookie.
|
|
|
|
The load-balancers will spread the load across 4 local web servers, and
|
|
use the JSESSIONID provided by the application to provide server persistence
|
|
using the new 'prefix' method. Soft-stop will also be implemented as described
|
|
in section 4 above. Moreover, these proxies will provide their own maintenance
|
|
soft-stop. Port 80 will be used for application traffic, while port 81 will
|
|
only be used for health-checks and locally rerouted to port 80. A grace time
|
|
will be specified to service on port 80, but not on port 81. This way, a soft
|
|
kill (kill -USR1) on the proxy will only kill the health-check forwarder so
|
|
that the site director knows it must not use this load-balancer anymore. But
|
|
the service will still work for 20 seconds and as long as there are established
|
|
sessions.
|
|
|
|
These proxies will also be the only ones to disable HTTP keep-alive in the
|
|
chain, because it is enough to do it at one place, and it's necessary to do
|
|
it with 'prefix' cookies.
|
|
|
|
Configuration for S1L1/S1L2
|
|
---------------------------
|
|
|
|
listen 10.1.1.11:80 # 10.1.1.12:80 for S1L2
|
|
grace 20000 # don't kill us until 20 seconds have elapsed
|
|
mode http
|
|
balance roundrobin
|
|
cookie JSESSIONID prefix
|
|
option httpclose
|
|
option forwardfor
|
|
option httpchk HEAD / HTTP/1.0
|
|
server W11 10.1.2.1:80 cookie W11 check port 81 inter 2000
|
|
server W12 10.1.2.2:80 cookie W12 check port 81 inter 2000
|
|
server W13 10.1.2.3:80 cookie W13 check port 81 inter 2000
|
|
server W14 10.1.2.4:80 cookie W14 check port 81 inter 2000
|
|
|
|
server B11 10.1.2.1:80 cookie W11 check port 80 inter 4000 backup
|
|
server B12 10.1.2.2:80 cookie W12 check port 80 inter 4000 backup
|
|
server B13 10.1.2.3:80 cookie W13 check port 80 inter 4000 backup
|
|
server B14 10.1.2.4:80 cookie W14 check port 80 inter 4000 backup
|
|
|
|
listen 10.1.1.11:81 # 10.1.1.12:81 for S1L2
|
|
mode tcp
|
|
dispatch 10.1.1.11:80 # 10.1.1.12:80 for S1L2
|
|
|
|
|
|
Configuration for S2L1/S2L2
|
|
---------------------------
|
|
|
|
listen 10.2.1.11:80 # 10.2.1.12:80 for S2L2
|
|
grace 20000 # don't kill us until 20 seconds have elapsed
|
|
mode http
|
|
balance roundrobin
|
|
cookie JSESSIONID prefix
|
|
option httpclose
|
|
option forwardfor
|
|
option httpchk HEAD / HTTP/1.0
|
|
server W21 10.2.2.1:80 cookie W21 check port 81 inter 2000
|
|
server W22 10.2.2.2:80 cookie W22 check port 81 inter 2000
|
|
server W23 10.2.2.3:80 cookie W23 check port 81 inter 2000
|
|
server W24 10.2.2.4:80 cookie W24 check port 81 inter 2000
|
|
|
|
server B21 10.2.2.1:80 cookie W21 check port 80 inter 4000 backup
|
|
server B22 10.2.2.2:80 cookie W22 check port 80 inter 4000 backup
|
|
server B23 10.2.2.3:80 cookie W23 check port 80 inter 4000 backup
|
|
server B24 10.2.2.4:80 cookie W24 check port 80 inter 4000 backup
|
|
|
|
listen 10.2.1.11:81 # 10.2.1.12:81 for S2L2
|
|
mode tcp
|
|
dispatch 10.2.1.11:80 # 10.2.1.12:80 for S2L2
|
|
|
|
|
|
5.5 Comments
|
|
------------
|
|
Since each site director sets a cookie identifying the site, remote office
|
|
users will have their office proxies direct them to the right site and stick
|
|
to this site as long as the user still uses the application and the site is
|
|
available. Users on production sites will be directed to the right site by the
|
|
site directors depending on the SITE cookie.
|
|
|
|
If the WAN link dies on a production site, the remote office users will not
|
|
see their site anymore, so they will redirect the traffic to the second site.
|
|
If there are dedicated inter-site links as on the diagram above, the second
|
|
SD will see the cookie and still be able to reach the original site. For
|
|
example :
|
|
|
|
Office 1 user sends the following to OP1 :
|
|
GET / HTTP/1.0
|
|
Cookie: SITE=SITE1; JSESSIONID=W14~123;
|
|
|
|
OP1 cannot reach site 1 because its external router is dead. So the SD1 server
|
|
is seen as dead, and OP1 will then forward the request to SD2 on site 2,
|
|
regardless of the SITE cookie.
|
|
|
|
SD2 on site 2 receives a SITE cookie containing "SITE1". Fortunately, it
|
|
can reach Site 1's load balancers S1L1 and S1L2. So it forwards the request
|
|
so S1L1 (the first one with the same cookie).
|
|
|
|
S1L1 (on site 1) finds "W14" in the JSESSIONID cookie, so it can forward the
|
|
request to the right server, and the user session will continue to work. Once
|
|
the Site 1's WAN link comes back, OP1 will see SD1 again, and will not route
|
|
through SITE 2 anymore.
|
|
|
|
However, when a new user on Office 1 connects to the application during a
|
|
site 1 failure, it does not contain any cookie. Since OP1 does not see SD1
|
|
because of the network failure, it will direct the request to SD2 on site 2,
|
|
which will by default direct the traffic to the local load-balancers, S2L1 and
|
|
S2L2. So only initial users will load the inter-site link, not the new ones.
|
|
|
|
|
|
===================
|
|
6. Source balancing
|
|
===================
|
|
|
|
Sometimes it may reveal useful to access servers from a pool of IP addresses
|
|
instead of only one or two. Some equipment (NAT firewalls, load-balancers)
|
|
are sensible to source address, and often need many sources to distribute the
|
|
load evenly amongst their internal hash buckets.
|
|
|
|
To do this, you simply have to use several times the same server with a
|
|
different source. Example :
|
|
|
|
listen 0.0.0.0:80
|
|
mode tcp
|
|
balance roundrobin
|
|
server from1to1 10.1.1.1:80 source 10.1.2.1
|
|
server from2to1 10.1.1.1:80 source 10.1.2.2
|
|
server from3to1 10.1.1.1:80 source 10.1.2.3
|
|
server from4to1 10.1.1.1:80 source 10.1.2.4
|
|
server from5to1 10.1.1.1:80 source 10.1.2.5
|
|
server from6to1 10.1.1.1:80 source 10.1.2.6
|
|
server from7to1 10.1.1.1:80 source 10.1.2.7
|
|
server from8to1 10.1.1.1:80 source 10.1.2.8
|
|
|
|
|
|
=============================================
|
|
7. Managing high loads on application servers
|
|
=============================================
|
|
|
|
One of the roles often expected from a load balancer is to mitigate the load on
|
|
the servers during traffic peaks. More and more often, we see heavy frameworks
|
|
used to deliver flexible and evolutive web designs, at the cost of high loads
|
|
on the servers, or very low concurrency. Sometimes, response times are also
|
|
rather high. People developing web sites relying on such frameworks very often
|
|
look for a load balancer which is able to distribute the load in the most
|
|
evenly fashion and which will be nice with the servers.
|
|
|
|
There is a powerful feature in haproxy which achieves exactly this : request
|
|
queueing associated with concurrent connections limit.
|
|
|
|
Let's say you have an application server which supports at most 20 concurrent
|
|
requests. You have 3 servers, so you can accept up to 60 concurrent HTTP
|
|
connections, which often means 30 concurrent users in case of keep-alive (2
|
|
persistent connections per user).
|
|
|
|
Even if you disable keep-alive, if the server takes a long time to respond,
|
|
you still have a high risk of multiple users clicking at the same time and
|
|
having their requests unserved because of server saturation. To work around
|
|
the problem, you increase the concurrent connection limit on the servers,
|
|
but their performance stalls under higher loads.
|
|
|
|
The solution is to limit the number of connections between the clients and the
|
|
servers. You set haproxy to limit the number of connections on a per-server
|
|
basis, and you let all the users you want connect to it. It will then fill all
|
|
the servers up to the configured connection limit, and will put the remaining
|
|
connections in a queue, waiting for a connection to be released on a server.
|
|
|
|
This ensures five essential principles :
|
|
|
|
- all clients can be served whatever their number without crashing the
|
|
servers, the only impact it that the response time can be delayed.
|
|
|
|
- the servers can be used at full throttle without the risk of stalling,
|
|
and fine tuning can lead to optimal performance.
|
|
|
|
- response times can be reduced by making the servers work below the
|
|
congestion point, effectively leading to shorter response times even
|
|
under moderate loads.
|
|
|
|
- no domino effect when a server goes down or starts up. Requests will be
|
|
queued more or less, always respecting servers limits.
|
|
|
|
- it's easy to achieve high performance even on memory-limited hardware.
|
|
Indeed, heavy frameworks often consume huge amounts of RAM and not always
|
|
all the CPU available. In case of wrong sizing, reducing the number of
|
|
concurrent connections will protect against memory shortages while still
|
|
ensuring optimal CPU usage.
|
|
|
|
|
|
Example :
|
|
---------
|
|
|
|
Haproxy is installed in front of an application servers farm. It will limit
|
|
the concurrent connections to 4 per server (one thread per CPU), thus ensuring
|
|
very fast response times.
|
|
|
|
|
|
192.168.1.1 192.168.1.11-192.168.1.13 192.168.1.2
|
|
-------+-------------+-----+-----+------------+----
|
|
| | | | _|_db
|
|
+--+--+ +-+-+ +-+-+ +-+-+ (___)
|
|
| LB1 | | A | | B | | C | (___)
|
|
+-----+ +---+ +---+ +---+ (___)
|
|
haproxy 3 application servers
|
|
with heavy frameworks
|
|
|
|
|
|
Config on haproxy (LB1) :
|
|
-------------------------
|
|
|
|
listen appfarm 192.168.1.1:80
|
|
mode http
|
|
maxconn 10000
|
|
option httpclose
|
|
option forwardfor
|
|
balance roundrobin
|
|
cookie SERVERID insert indirect
|
|
option httpchk HEAD /index.html HTTP/1.0
|
|
server railsA 192.168.1.11:80 cookie A maxconn 4 check
|
|
server railsB 192.168.1.12:80 cookie B maxconn 4 check
|
|
server railsC 192.168.1.13:80 cookie C maxconn 4 check
|
|
contimeout 60000
|
|
|
|
|
|
Description :
|
|
-------------
|
|
The proxy listens on IP 192.168.1.1, port 80, and expects HTTP requests. It
|
|
can accept up to 10000 concurrent connections on this socket. It follows the
|
|
roundrobin algorithm to assign servers to connections as long as servers are
|
|
not saturated.
|
|
|
|
It allows up to 4 concurrent connections per server, and will queue the
|
|
requests above this value. The "contimeout" parameter is used to set the
|
|
maximum time a connection may take to establish on a server, but here it
|
|
is also used to set the maximum time a connection may stay unserved in the
|
|
queue (1 minute here).
|
|
|
|
If the servers can each process 4 requests in 10 ms on average, then at 3000
|
|
connections, response times will be delayed by at most :
|
|
|
|
3000 / 3 servers / 4 conns * 10 ms = 2.5 seconds
|
|
|
|
Which is not that dramatic considering the huge number of users for such a low
|
|
number of servers.
|
|
|
|
When connection queues fill up and application servers are starving, response
|
|
times will grow and users might abort by clicking on the "Stop" button. It is
|
|
very undesirable to send aborted requests to servers, because they will eat
|
|
CPU cycles for nothing.
|
|
|
|
An option has been added to handle this specific case : "option abortonclose".
|
|
By specifying it, you tell haproxy that if an input channel is closed on the
|
|
client side AND the request is still waiting in the queue, then it is highly
|
|
likely that the user has stopped, so we remove the request from the queue
|
|
before it will get served.
|
|
|
|
|
|
Managing unfair response times
|
|
------------------------------
|
|
|
|
Sometimes, the application server will be very slow for some requests (eg:
|
|
login page) and faster for other requests. This may cause excessive queueing
|
|
of expectedly fast requests when all threads on the server are blocked on a
|
|
request to the database. Then the only solution is to increase the number of
|
|
concurrent connections, so that the server can handle a large average number
|
|
of slow connections with threads left to handle faster connections.
|
|
|
|
But as we have seen, increasing the number of connections on the servers can
|
|
be detrimental to performance (eg: Apache processes fighting for the accept()
|
|
lock). To improve this situation, the "minconn" parameter has been introduced.
|
|
When it is set, the maximum connection concurrency on the server will be bound
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|
by this value, and the limit will increase with the number of clients waiting
|
|
in queue, till the clients connected to haproxy reach the proxy's maxconn, in
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which case the connections per server will reach the server's maxconn. It means
|
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that during low-to-medium loads, the minconn will be applied, and during surges
|
|
the maxconn will be applied. It ensures both optimal response times under
|
|
normal loads, and availability under very high loads.
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Example :
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---------
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listen appfarm 192.168.1.1:80
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mode http
|
|
maxconn 10000
|
|
option httpclose
|
|
option abortonclose
|
|
option forwardfor
|
|
balance roundrobin
|
|
# The servers will get 4 concurrent connections under low
|
|
# loads, and 12 when there will be 10000 clients.
|
|
server railsA 192.168.1.11:80 minconn 4 maxconn 12 check
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|
server railsB 192.168.1.12:80 minconn 4 maxconn 12 check
|
|
server railsC 192.168.1.13:80 minconn 4 maxconn 12 check
|
|
contimeout 60000
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|
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