neutron/doc/source/admin/config-lbaas.rst
Michael Johnson 1e075f01ee Mark neutron-lbaas as deprecated
This patch marks neutron-lbaas as deprecated in the neutron documentation.

It also removes some legacy LBaaS v1 documentation and neutron-lbaas bug
handling links.

Change-Id: I9824191ec671ba29fe545cc112fb2129405b3b60
2018-01-31 16:13:45 -08:00

502 lines
18 KiB
ReStructuredText

.. _config-lbaas:
==================================
Load Balancer as a Service (LBaaS)
==================================
.. warning::
Neutron-lbaas is deprecated as of Queens. Load-Balancer-as-a-Service
(LBaaS v2) is now provided by the `Octavia project
<https://docs.openstack.org/octavia/latest/>`_. Please see the FAQ:
https://wiki.openstack.org/wiki/Neutron/LBaaS/Deprecation
The Networking service offers a load balancer feature called "LBaaS v2"
through the ``neutron-lbaas`` service plug-in.
LBaaS v2 adds the concept of listeners to the LBaaS v1 load balancers.
LBaaS v2 allows you to configure multiple listener ports on a single load
balancer IP address.
There are two reference implementations of LBaaS v2.
The one is an agent based implementation with HAProxy.
The agents handle the HAProxy configuration and manage the HAProxy daemon.
Another LBaaS v2 implementation, `Octavia
<https://docs.openstack.org/octavia/latest/>`_, has a separate API and
separate worker processes that build load balancers within virtual machines on
hypervisors that are managed by the Compute service. You do not need an agent
for Octavia.
.. warning::
Currently, no migration path exists between v1 and v2 load balancers. If you
choose to switch from v1 to v2, you must recreate all load balancers, pools,
and health monitors.
.. TODO(amotoki): Data mirgation from v1 to v2 is provided in Newton release,
but its usage is not documented enough. It should be added here.
LBaaS v2 Concepts
~~~~~~~~~~~~~~~~~
LBaaS v2 has several new concepts to understand:
.. image:: figures/lbaasv2-diagram.png
:alt: LBaaS v2 layout
Load balancer
The load balancer occupies a neutron network port and has an IP address
assigned from a subnet.
Listener
Load balancers can listen for requests on multiple ports. Each one of those
ports is specified by a listener.
Pool
A pool holds a list of members that serve content through the load balancer.
Member
Members are servers that serve traffic behind a load balancer. Each member
is specified by the IP address and port that it uses to serve traffic.
Health monitor
Members may go offline from time to time and health monitors divert traffic
away from members that are not responding properly. Health monitors are
associated with pools.
LBaaS v2 has multiple implementations via different service plug-ins. The two
most common implementations use either an agent or the Octavia services. Both
implementations use the `LBaaS v2 API <https://developer.openstack.org/api-ref/networking/v2/#lbaas-2-0-stable>`_.
Configurations
~~~~~~~~~~~~~~
Configuring LBaaS v2 with an agent
----------------------------------
#. Add the LBaaS v2 service plug-in to the ``service_plugins`` configuration
directive in ``/etc/neutron/neutron.conf``. The plug-in list is
comma-separated:
.. code-block:: console
service_plugins = [existing service plugins],neutron_lbaas.services.loadbalancer.plugin.LoadBalancerPluginv2
#. Add the LBaaS v2 service provider to the ``service_provider`` configuration
directive within the ``[service_providers]`` section in
``/etc/neutron/neutron_lbaas.conf``:
.. code-block:: console
service_provider = LOADBALANCERV2:Haproxy:neutron_lbaas.drivers.haproxy.plugin_driver.HaproxyOnHostPluginDriver:default
If you have existing service providers for other networking service
plug-ins, such as VPNaaS or FWaaS, add the ``service_provider`` line shown
above in the ``[service_providers]`` section as a separate line. These
configuration directives are repeatable and are not comma-separated.
#. Select the driver that manages virtual interfaces in
``/etc/neutron/lbaas_agent.ini``:
.. code-block:: console
[DEFAULT]
device_driver = neutron_lbaas.drivers.haproxy.namespace_driver.HaproxyNSDriver
interface_driver = INTERFACE_DRIVER
[haproxy]
user_group = haproxy
Replace ``INTERFACE_DRIVER`` with the interface driver that the layer-2
agent in your environment uses. For example, ``openvswitch`` for Open
vSwitch or ``linuxbridge`` for Linux bridge.
#. Run the ``neutron-lbaas`` database migration:
.. code-block:: console
neutron-db-manage --subproject neutron-lbaas upgrade head
#. If you have deployed LBaaS v1, **stop the LBaaS v1 agent now**. The v1 and
v2 agents **cannot** run simultaneously.
#. Start the LBaaS v2 agent:
.. code-block:: console
neutron-lbaasv2-agent \
--config-file /etc/neutron/neutron.conf \
--config-file /etc/neutron/lbaas_agent.ini
#. Restart the Network service to activate the new configuration. You are now
ready to create load balancers with the LBaaS v2 agent.
Configuring LBaaS v2 with Octavia
---------------------------------
Octavia provides additional capabilities for load balancers, including using a
compute driver to build instances that operate as load balancers.
The `Hands on Lab - Install and Configure OpenStack Octavia
<https://www.openstack.org/summit/tokyo-2015/videos/presentation/rsvp-required-hands-on-lab-install-and-configure-openstack-octavia>`_
session at the OpenStack Summit in Tokyo provides an overview of Octavia.
The DevStack documentation offers a `simple method to deploy Octavia
<https://docs.openstack.org/devstack/latest/guides/devstack-with-lbaas-v2.html>`_
and test the service with redundant load balancer instances. If you already
have Octavia installed and configured within your environment, you can
configure the Network service to use Octavia:
#. Add the LBaaS v2 service plug-in to the ``service_plugins`` configuration
directive in ``/etc/neutron/neutron.conf``. The plug-in list is
comma-separated:
.. code-block:: console
service_plugins = [existing service plugins],neutron_lbaas.services.loadbalancer.plugin.LoadBalancerPluginv2
#. Add the Octavia service provider to the ``service_provider`` configuration
directive within the ``[service_providers]`` section in
``/etc/neutron/neutron_lbaas.conf``:
.. code-block:: console
service_provider = LOADBALANCERV2:Octavia:neutron_lbaas.drivers.octavia.driver.OctaviaDriver:default
Ensure that the LBaaS v1 and v2 service providers are removed from the
``[service_providers]`` section. They are not used with Octavia. **Verify
that all LBaaS agents are stopped.**
#. Restart the Network service to activate the new configuration. You are now
ready to create and manage load balancers with Octavia.
Add LBaaS panels to Dashboard
-----------------------------
The Dashboard panels for managing LBaaS v2 are available starting with the
Mitaka release.
#. Clone the `neutron-lbaas-dashboard repository
<https://git.openstack.org/cgit/openstack/neutron-lbaas-dashboard/>`__
and check out the release
branch that matches the installed version of Dashboard:
.. code-block:: console
$ git clone https://git.openstack.org/openstack/neutron-lbaas-dashboard
$ cd neutron-lbaas-dashboard
$ git checkout OPENSTACK_RELEASE
#. Install the Dashboard panel plug-in:
.. code-block:: console
$ python setup.py install
#. Copy the ``_1481_project_ng_loadbalancersv2_panel.py`` file from the
``neutron-lbaas-dashboard/enabled`` directory into the Dashboard
``openstack_dashboard/local/enabled`` directory.
This step ensures that Dashboard can find the plug-in when it enumerates
all of its available panels.
#. Enable the plug-in in Dashboard by editing the ``local_settings.py`` file
and setting ``enable_lb`` to ``True`` in the ``OPENSTACK_NEUTRON_NETWORK``
dictionary.
#. If Dashboard is configured to compress static files for better performance
(usually set through ``COMPRESS_OFFLINE`` in ``local_settings.py``),
optimize the static files again:
.. code-block:: console
$ ./manage.py collectstatic
$ ./manage.py compress
#. Restart Apache to activate the new panel:
.. code-block:: console
$ sudo service apache2 restart
To find the panel, click on :guilabel:`Project` in Dashboard, then click the
:guilabel:`Network` drop-down menu and select :guilabel:`Load Balancers`.
LBaaS v2 operations
~~~~~~~~~~~~~~~~~~~
The same neutron commands are used for LBaaS v2 with an agent or with Octavia.
Building an LBaaS v2 load balancer
----------------------------------
#. Start by creating a load balancer on a network. In this example, the
``private`` network is an isolated network with two web server instances:
.. code-block:: console
$ neutron lbaas-loadbalancer-create --name test-lb private-subnet
#. You can view the load balancer status and IP address with the
:command:`neutron lbaas-loadbalancer-show` command:
.. code-block:: console
$ neutron lbaas-loadbalancer-show test-lb
+---------------------+------------------------------------------------+
| Field | Value |
+---------------------+------------------------------------------------+
| admin_state_up | True |
| description | |
| id | 7780f9dd-e5dd-43a9-af81-0d2d1bd9c386 |
| listeners | {"id": "23442d6a-4d82-40ee-8d08-243750dbc191"} |
| | {"id": "7e0d084d-6d67-47e6-9f77-0115e6cf9ba8"} |
| name | test-lb |
| operating_status | ONLINE |
| provider | octavia |
| provisioning_status | ACTIVE |
| tenant_id | fbfce4cb346c4f9097a977c54904cafd |
| vip_address | 192.0.2.22 |
| vip_port_id | 9f8f8a75-a731-4a34-b622-864907e1d556 |
| vip_subnet_id | f1e7827d-1bfe-40b6-b8f0-2d9fd946f59b |
+---------------------+------------------------------------------------+
#. Update the security group to allow traffic to reach the new load balancer.
Create a new security group along with ingress rules to allow traffic into
the new load balancer. The neutron port for the load balancer is shown as
``vip_port_id`` above.
Create a security group and rules to allow TCP port 80, TCP port 443, and
all ICMP traffic:
.. code-block:: console
$ neutron security-group-create lbaas
$ neutron security-group-rule-create \
--direction ingress \
--protocol tcp \
--port-range-min 80 \
--port-range-max 80 \
--remote-ip-prefix 0.0.0.0/0 \
lbaas
$ neutron security-group-rule-create \
--direction ingress \
--protocol tcp \
--port-range-min 443 \
--port-range-max 443 \
--remote-ip-prefix 0.0.0.0/0 \
lbaas
$ neutron security-group-rule-create \
--direction ingress \
--protocol icmp \
lbaas
Apply the security group to the load balancer's network port using
``vip_port_id`` from the :command:`neutron lbaas-loadbalancer-show`
command:
.. code-block:: console
$ neutron port-update \
--security-group lbaas \
9f8f8a75-a731-4a34-b622-864907e1d556
Adding an HTTP listener
-----------------------
#. With the load balancer online, you can add a listener for plaintext
HTTP traffic on port 80:
.. code-block:: console
$ neutron lbaas-listener-create \
--name test-lb-http \
--loadbalancer test-lb \
--protocol HTTP \
--protocol-port 80
This load balancer is active and ready to serve traffic on ``192.0.2.22``.
#. Verify that the load balancer is responding to pings before moving further:
.. code-block:: console
$ ping -c 4 192.0.2.22
PING 192.0.2.22 (192.0.2.22) 56(84) bytes of data.
64 bytes from 192.0.2.22: icmp_seq=1 ttl=62 time=0.410 ms
64 bytes from 192.0.2.22: icmp_seq=2 ttl=62 time=0.407 ms
64 bytes from 192.0.2.22: icmp_seq=3 ttl=62 time=0.396 ms
64 bytes from 192.0.2.22: icmp_seq=4 ttl=62 time=0.397 ms
--- 192.0.2.22 ping statistics ---
4 packets transmitted, 4 received, 0% packet loss, time 2997ms
rtt min/avg/max/mdev = 0.396/0.402/0.410/0.020 ms
#. You can begin building a pool and adding members to the pool to serve HTTP
content on port 80. For this example, the web servers are ``192.0.2.16``
and ``192.0.2.17``:
.. code-block:: console
$ neutron lbaas-pool-create \
--name test-lb-pool-http \
--lb-algorithm ROUND_ROBIN \
--listener test-lb-http \
--protocol HTTP
$ neutron lbaas-member-create \
--name test-lb-http-member-1 \
--subnet private-subnet \
--address 192.0.2.16 \
--protocol-port 80 \
test-lb-pool-http
$ neutron lbaas-member-create \
--name test-lb-http-member-2 \
--subnet private-subnet \
--address 192.0.2.17 \
--protocol-port 80 \
test-lb-pool-http
#. You can use ``curl`` to verify connectivity through the load balancers to
your web servers:
.. code-block:: console
$ curl 192.0.2.22
web2
$ curl 192.0.2.22
web1
$ curl 192.0.2.22
web2
$ curl 192.0.2.22
web1
In this example, the load balancer uses the round robin algorithm and the
traffic alternates between the web servers on the backend.
#. You can add a health monitor so that unresponsive servers are removed
from the pool:
.. code-block:: console
$ neutron lbaas-healthmonitor-create \
--name test-lb-http-monitor \
--delay 5 \
--max-retries 2 \
--timeout 10 \
--type HTTP \
--pool test-lb-pool-http
In this example, the health monitor removes the server from the pool if
it fails a health check at two five-second intervals. When the server
recovers and begins responding to health checks again, it is added to
the pool once again.
Adding an HTTPS listener
------------------------
You can add another listener on port 443 for HTTPS traffic. LBaaS v2 offers
SSL/TLS termination at the load balancer, but this example takes a simpler
approach and allows encrypted connections to terminate at each member server.
#. Start by creating a listener, attaching a pool, and then adding members:
.. code-block:: console
$ neutron lbaas-listener-create \
--name test-lb-https \
--loadbalancer test-lb \
--protocol HTTPS \
--protocol-port 443
$ neutron lbaas-pool-create \
--name test-lb-pool-https \
--lb-algorithm LEAST_CONNECTIONS \
--listener test-lb-https \
--protocol HTTPS
$ neutron lbaas-member-create \
--name test-lb-https-member-1 \
--subnet private-subnet \
--address 192.0.2.16 \
--protocol-port 443 \
test-lb-pool-https
$ neutron lbaas-member-create \
--name test-lb-https-member-2 \
--subnet private-subnet \
--address 192.0.2.17 \
--protocol-port 443 \
test-lb-pool-https
#. You can also add a health monitor for the HTTPS pool:
.. code-block:: console
$ neutron lbaas-healthmonitor-create \
--name test-lb-https-monitor \
--delay 5 \
--max-retries 2 \
--timeout 10 \
--type HTTPS \
--pool test-lb-pool-https
The load balancer now handles traffic on ports 80 and 443.
Associating a floating IP address
---------------------------------
Load balancers that are deployed on a public or provider network that are
accessible to external clients do not need a floating IP address assigned.
External clients can directly access the virtual IP address (VIP) of those
load balancers.
However, load balancers deployed onto private or isolated networks need a
floating IP address assigned if they must be accessible to external clients. To
complete this step, you must have a router between the private and public
networks and an available floating IP address.
You can use the :command:`neutron lbaas-loadbalancer-show` command from the
beginning of this section to locate the ``vip_port_id``. The ``vip_port_id``
is the ID of the network port that is assigned to the load balancer. You can
associate a free floating IP address to the load balancer using
:command:`neutron floatingip-associate`:
.. code-block:: console
$ neutron floatingip-associate FLOATINGIP_ID LOAD_BALANCER_PORT_ID
Setting quotas for LBaaS v2
---------------------------
Quotas are available for limiting the number of load balancers and load
balancer pools. By default, both quotas are set to 10.
You can adjust quotas using the :command:`neutron quota-update` command:
.. code-block:: console
$ neutron quota-update --tenant-id TENANT_UUID --loadbalancer 25
$ neutron quota-update --tenant-id TENANT_UUID --pool 50
A setting of ``-1`` disables the quota for a tenant.
Retrieving load balancer statistics
-----------------------------------
The LBaaS v2 agent collects four types of statistics for each load balancer
every six seconds. Users can query these statistics with the
:command:`neutron lbaas-loadbalancer-stats` command:
.. code-block:: console
$ neutron lbaas-loadbalancer-stats test-lb
+--------------------+----------+
| Field | Value |
+--------------------+----------+
| active_connections | 0 |
| bytes_in | 40264557 |
| bytes_out | 71701666 |
| total_connections | 384601 |
+--------------------+----------+
The ``active_connections`` count is the total number of connections that were
active at the time the agent polled the load balancer. The other three
statistics are cumulative since the load balancer was last started. For
example, if the load balancer restarts due to a system error or a configuration
change, these statistics will be reset.