Production architecture guide¶
This guide will help with configuring Kolla to suit production needs. It is meant to answer some questions regarding basic configuration options that Kolla requires. This document also contains other useful pointers.
Node types and services running on them¶
A basic Kolla inventory consists of several types of nodes, known in Ansible as
Control - Cloud controller nodes which host control services like APIs and databases. This group should have odd number of nodes for quorum.
Network - Network nodes host Neutron agents along with haproxy / keepalived. These nodes will have a floating ip defined in
Compute - Compute nodes for compute services. This is where guest VMs live.
Storage - Storage nodes for cinder-volume, LVM or Swift.
Monitoring - Monitor nodes which host monitoring services.
In Kolla operators should configure following network interfaces:
network_interface- While it is not used on its own, this provides the required default for other interfaces below.
api_interface- This interface is used for the management network. The management network is the network OpenStack services uses to communicate to each other and the databases. There are known security risks here, so it’s recommended to make this network internal, not accessible from outside. Defaults to
kolla_external_vip_interface- This interface is public-facing one. It’s used when you want HAProxy public endpoints to be exposed in different network than internal ones. It is mandatory to set this option when
kolla_enable_tls_externalis set to yes. Defaults to
storage_interface- This is the interface that is used by Swift. This can be heavily utilized so it’s recommended to use a high speed network fabric. Defaults to
swift_storage_interface- This interface is used by Swift for storage access traffic. This can be heavily utilized so it’s recommended to use a high speed network fabric. Defaults to
swift_replication_interface- This interface is used by Swift for storage replication traffic. This can be heavily utilized so it’s recommended to use a high speed network fabric. Defaults to
tunnel_interface- This interface is used by Neutron for vm-to-vm traffic over tunneled networks (like VxLan). Defaults to
neutron_external_interface- This interface is required by Neutron. Neutron will put br-ex on it. It will be used for flat networking as well as tagged vlan networks. Has to be set separately.
dns_interface- This interface is required by Designate and Bind9. Is used by public facing DNS requests and queries to bind9 and designate mDNS services. Defaults to
bifrost_network_interface- This interface is required by Bifrost. Is used to provision bare metal cloud hosts, require L2 connectivity with the bare metal cloud hosts in order to provide DHCP leases with PXE boot options. Defaults to
Ansible facts does not recognize interface names containing dashes,
bond-0 cannot be used because ansible will read
Address family configuration (IPv4/IPv6)¶
Starting with the Train release, Kolla Ansible allows operators to deploy the control plane using IPv6 instead of IPv4. Each Kolla Ansible network (as represented by interfaces) provides a choice of two address families. Both internal and external VIP addresses can be configured using an IPv6 address as well. IPv6 is tested on all supported platforms.
While Kolla Ansible Train requires Ansible 2.6 or later, IPv6 support requires Ansible 2.8 or later due to a bug: https://github.com/ansible/ansible/issues/63227
Currently there is no dual stack support. IPv4 can be mixed with IPv6 only when on different networks. This constraint arises from services requiring common single address family addressing.
network_address_family accepts either
as its value and defines the default address family for all networks just
network_interface defines the default interface.
api_address_family changes the address family for the API
network. Current listing of networks is available in
While IPv6 support introduced in Train is broad, some services are known not to work yet with IPv6 or have some known quirks:
Bifrost does not support IPv6: https://storyboard.openstack.org/#!/story/2006689
Docker does not allow IPv6 registry address: https://github.com/moby/moby/issues/39033 - the workaround is to use the hostname
Ironic DHCP server, dnsmasq, is not currently automatically configured to offer DHCPv6: https://bugs.launchpad.net/kolla-ansible/+bug/1848454
Because Docker is core dependency of Kolla, proper configuration of Docker can change the experience of Kolla significantly. Following section will highlight several Docker configuration details relevant to Kolla operators.
While the default storage driver should be fine for most users, Docker offers more options to consider. For details please refer to Docker documentation.
Kolla puts nearly all of persistent data in Docker volumes. These volumes are
created in Docker working directory, which defaults to
We recommend to ensure that this directory has enough space and is placed on fast disk as it will affect performance of builds, deploys as well as database commits and rabbitmq.
This becomes especially relevant when
openstack_logging_debug are both set to true, as fully loaded 130 node
cluster produced 30-50GB of logs daily.
High Availability (HA) and scalability¶
HA is an important topic in production systems. HA concerns itself with redundant instances of services so that the overall service can be provided with close-to-zero interruption in case of failure. Scalability often works hand-in-hand with HA to provide load sharing by the use of load balancers.
Multinode Kolla Ansible deployments provide HA and scalability for services.
OpenStack API endpoints are a prime example here: redundant
instances provide HA with
keepalived while the backends are also
deployed redundantly to enable both HA and load balancing.
Other core services¶
The core non-OpenStack components required by most deployments: the SQL
database provided by
mariadb and message queue provided by
rabbitmq are also deployed in a HA way. Care has to be taken, however,
as unlike previously described services, these have more complex HA
mechanisms. The reason for that is that they provide the central, persistent
storage of information about the cloud that each other service assumes to
have a consistent state (aka integrity).
This assumption leads to the requirement of quorum establishment
(look up the CAP theorem for greater insight).
Quorum needs a majority vote and hence deploying 2 instances of these
do not provide (by default) any HA as a failure of one causes a failure
of the other one. Hence the recommended number of instances is
where 1 node failure is acceptable. For scaling purposes and better
resilience it is possible to use
5 nodes and have 2 failures
Note, however, that higher numbers usually provide no benefits due to amount
of communication between quorum members themselves and the non-zero
probability of the communication medium failure happening instead.