# Devstack2 local configuration

# When a value looks like a bash variable + default then it is parsed like a bash 
# variable and will perform similar lookups. Ie ${SQL_HOST:-localhost} will
# look in environment variable SQL_HOST and if that does not exist then
# localhost will be used instead.
#
# We also allow for simple referencing of other variables, similar to bash 
# variables to occur when a keys value like the following format are found:
#
# web_host = ${RUNNING_HOST:-http://$(X:Y)}
#
# For this example, the RUNNING_HOST enviroment variable will be referenced.
# If it is not found (no value exists), then "http://$(X:Y)" will be 
# examined and found to be contain a expression (denoted by "$(X:Y)"). 
#
# Then in that expression there are components of the format "X:Y" which the 
# configuration class will attempt to resolve those values by looking up in the 
# configuration file for a value in section "X" with option "Y" and replacing the 
# retrieved value for what was previously "$(X:Y)". Multiple of these "expressions"
# are allowed and each will have its expression "text" replaced with the resolved
# value before the final value for the original variable is determined. 
#
# For this example if the section X with option Y contained  value "1.2.3.4" then
# the final string would be "http://1.2.3.4" which would then be cached as the value
# for option web_host.


[default]

# Where is rabbit located?
rabbit_host = ${RABBIT_HOST:-$(host:ip)}

# Sys log enabled or not
syslog = 0

# Which run type to use [fork (the default), upstart, screen]
run_type = fork

[upstart]

# These flags are used for starting components under upstart (if default/run_type is upstart)
respawn = 1

# Note that we support component start/stop and "all"
# Start and stop, this is the "all" event name
start_event = all_os_start
stop_event = all_os_stop

[host]

# Set api host endpoint
# If this is empty in code we will try to determine your network ip.
ip = ${HOST_IP:-}

[db]

# Where you db is located at and how to access it.
sql_host = ${SQL_HOST:-localhost}
sql_user = ${SQL_USER:-root}
port = ${SQL_PORT:-3306}

# What type of database is this?
type = ${SQL_TYPE:-mysql}

[keystone]

# Where is the keystone auth host at?
keystone_auth_host = ${KEYSTONE_AUTH_HOST:-$(host:ip)}
keystone_auth_port = ${KEYSTONE_AUTH_PORT:-35357}
keystone_auth_protocol = ${KEYSTONE_AUTH_PROTOCOL:-http}

# Where is the keystone service host at?
keystone_service_host = ${KEYSTONE_SERVICE_HOST:-$(host:ip)}
keystone_service_port = ${KEYSTONE_SERVICE_PORT:-5000}
keystone_service_protocol = ${KEYSTONE_SERVICE_PROTOCOL:-http}

[nova]

# Should nova be in verbose mode?
verbose = ${NOVA_VERBOSE:-1}
logdir = ${NOVA_LOGDIR:-/var/log/nova}

# Allow the admin api to be accessible?
allow_admin_api = 1

# Currently novaclient needs you to specify the *compute api* version.
nova_version = ${NOVA_VERSION:-1.1}

# Which scheduler will nova be running with?
scheduler = ${NOVA_SCHEDULER:-nova.scheduler.filter_scheduler.FilterScheduler}

# Network settings
# Very useful to read over:
# http://docs.openstack.org/cactus/openstack-compute/admin/content/configuring-networking-on-the-compute-node.html
fixed_range = ${NOVA_FIXED_RANGE:-10.0.0.0/24}
fixed_network_size = ${NOVA_FIXED_NETWORK_SIZE:-256}
network_manager = ${NET_MAN:-FlatDHCPManager}
public_interface = ${PUBLIC_INTERFACE:-eth0}

# DHCP Warning: If your flat interface device uses DHCP, there will be a hiccup while the network 
# is moved from the flat interface to the flat network bridge. This will happen when you launch 
# your first instance. Upon launch you will lose all connectivity to the node, and the vm launch will probably fail.
#
# If you are running on a single node and don't need to access the VMs from devices other than 
# that node, you can set the flat interface to the same value as FLAT_NETWORK_BRIDGE. This will stop the network hiccup from occurring.
flat_interface = ${FLAT_INTERFACE:-eth0}
vlan_interface = ${VLAN_INTERFACE:-$(nova:public_interface)}
flat_network_bridge = ${FLAT_NETWORK_BRIDGE:-br100}

# Test floating pool and range are used for testing. 
# They are defined here until the admin APIs can replace nova-manage
floating_range = ${FLOATING_RANGE:-172.24.4.224/28}
test_floating_pool = ${TEST_FLOATING_POOL:-test}
test_floating_range = ${TEST_FLOATING_RANGE:-192.168.253.0/29}

# TODO document these
vncproxy_url = ${VNCPROXY_URL:-http://$(host:ip):6080/vnc_auto.html}
xvpvncproxy_url = ${XVPVNCPROXY_URL:-http://$(host:ip):6081/console}
vncserver_listen = ${VNCSERVER_LISTEN:-127.0.0.1}
vncserver_proxyclient_address = ${VNCSERVER_PROXYCLIENT_ADDRESS:-}
ec2_dmz_host = ${EC2_DMZ_HOST:-$(host:ip)}
libvirt_firewall_driver = nova.virt.libvirt.firewall.IptablesFirewallDriver 

# Volume settings
volume_group = ${VOLUME_GROUP:-nova-volumes}
volume_backing_file = ${VOLUME_BACKING_FILE:-}
volume_backing_file_size =${VOLUME_BACKING_FILE_SIZE:-2052M}
volume_name_prefix = ${VOLUME_NAME_PREFIX:-volume-}
volume_name_postfix = ${VOLUME_NAME_POSTFIX:-%08x}

# How instances will be named
instance_name_prefix = ${INSTANCE_NAME_PREFIX:-instance-}
instance_name_postfix = ${INSTANCE_NAME_POSTFIX:-%08x}

# Where instances will be stored
instances_path = ${INSTANCES_PATH:-}

# Are we setup in multihost mode?
# Multi-host is a mode where each compute node runs its own network node. 
# This allows network operations and routing for a VM to occur on the server that is running the VM - removing a SPOF and bandwidth bottleneck.
multi_host = ${MULTI_HOST:-0}

# Virtualization settings
# Drivers known (libvirt, xensever, vmware, baremetal)
# Defaults to libvirt (the most compatible) if unknown.
virt_driver = ${VIRT_DRIVER:-libvirt}

# Only useful if above libvirt_type is "libvirt"
# Types known (qemu, kvm, xen, uml, lxc)
# Defaults to qemu (the most compatible) if unknown (or blank).
libvirt_type = ${LIBVIRT_TYPE:-}

# What type of image service will be used? 
img_service = ${IMG_SERVICE:-nova.image.glance.GlanceImageService}
glance_server = ${GLANCE_SERVER:-$(host:ip):9292}

# Used however you want - ensure you know nova's conf file format if you use this!
extra_flags = ${NOVA_EXTRA_FLAGS:-}

# Xen server/api settings
xa_connection_url = http://169.254.0.1:80/
xa_connection_username = root
xs_firewall_driver = nova.virt.firewall.IptablesFirewallDriver
xs_flat_interface = eth1
xs_flat_network_bridge = xapi1

[extern]

# Set the ec2 url so euca2ools works
# Typically like http://localhost:8773/services/Cloud
# If blank we will generate this.
ec2_url = ${EC2_URL:-http://$(host:ip):8773/services/Cloud}

# Set the s3 url so euca2ools works
# Typically like http://localhost:3333/services/Cloud
# If blank we will generate this.
s3_url = ${S3_URL:-http://$(host:ip):3333/services/Cloud}

# Not used (currently)??
ec2_user_id = 42
ec2_cert_fn = ~/cert.pm

# Not used (currently)??
nova_cert_fn = ~/cert.pm

[git]

# Compute service git repo
nova_repo = git://github.com/openstack/nova.git
nova_branch = master

# Storage service git repo
swift_repo = git://github.com/openstack/swift.git
swift_branch = master

# Image catalog service git repo
glance_repo = git://github.com/openstack/glance.git
glance_branch = master

# Unified auth system (manages accounts/tokens) git repo
keystone_repo = git://github.com/openstack/keystone.git
keystone_branch = master

# A websockets/html5 or flash powered VNC console for vm instances 
novnc_repo = git://github.com/cloudbuilders/noVNC.git
novnc_branch = master

# Django powered web control panel for openstack
horizon_repo = git://github.com/openstack/horizon.git
horizon_branch = master

# Python keystone client library to nova that horizon uses
keystoneclient_repo = git://github.com/openstack/python-keystoneclient.git
keystoneclient_branch = master

# Python client library to nova that horizon (and others) use
novaclient_repo = git://github.com/openstack/python-novaclient.git
novaclient_branch = master

# Quantum service git repo
quantum_repo = git://github.com/openstack/quantum.git
quantum_branch = master

# Quantum client git repo
quantum_client_repo = git://github.com/openstack/python-quantumclient.git
quantum_client_branch = master

# Melange service
melange_repo = git://github.com/openstack/melange.git
melange_branch = master

# Python melange client library
melangeclient_repo = git://github.com/openstack/python-melangeclient.git
melangeclient_branch = master

[melange]

# Default Melange Port
m_port = ${M_PORT:-9898}

# Default Melange Host
m_host = ${M_HOST:-$(host:ip)}

# Melange MAC Address Range
m_mac_range = ${M_MAC_RANGE:-404040/24}

[quantum]

# Where your quantum host is at
q_host = ${Q_HOST:-$(host:ip)}

# Which port your quantum host is at
q_port  = ${Q_PORT:-9696}

# Which type of quantum plugin you will be using
q_plugin = ${Q_PLUGIN:-openvswitch}

# Default OVS bridge name
ovs_bridge = br-int

# OVS bridge external name
ovs_bridge_external_name = br-int

[horizon]

# What user will apache be serving from.
#
# Root will typically not work (for apache on most distros)
# sudo adduser <username> then sudo adduser <username> admin will be what you want to set this up (in ubuntu)
# I typically use user "horizon" for ubuntu and the runtime user (who will have sudo access) for RHEL.
# If blank the currently executing user will be used.
apache_user = ${APACHE_USER:-}

# This is the group of the previous user (adjust as needed)
apache_group = ${APACHE_GROUP:-$(horizon:apache_user)}

# Port horizon should run on
port = ${HORIZON_PORT:-80}

[swift]

# By default the location of swift drives and objects is located inside the swift source directory.
# SWIFT_DATA_LOCATION variable allow you to redefine this.
data_location = ${SWIFT_DATA_LOCATION:-data}

# TBD
swift_user = ${SWIFT_USER:-root}

# TBD
swift_group = ${SWIFT_GROUP:-$(swift:swift_user)}

# We will create a loop-back disk formatted as XFS to store the swift data. 
# By default the disk size is 1 gigabyte. The variable SWIFT_LOOPBACK_DISK_SIZE 
# specified in bytes allow you to change that.
loopback_disk_size = ${SWIFT_LOOPBACK_DISK_SIZE:-1G}

# The ring uses a configurable number of bits from a path’s MD5 hash as a
# partition index that designates a device. The number of bits kept from the
# hash is known as the partition power, and 2 to the partition power indicates 
# the partition count. Partitioning the full MD5 hash ring allows other parts 
# of the cluster to work in batches of items at once which ends up either more 
# efficient or at least less complex than working with each item separately or 
# the entire cluster all at once. By default we define 9 for the partition count (which mean 512).
partition_power_size = ${SWIFT_PARTITION_POWER_SIZE:-9}

[img]

# Specify a comma-separated list of uec images to download and install into glance.
# supported urls here are:
#
#  * "uec-style" images:
#     If the file ends in .tar.gz, uncompress the tarball and and select the first
#     .img file inside it as the image.  If present, use "*-vmlinuz*" as the kernel
#     and "*-initrd*" as the ramdisk
#     example: http://cloud-images.ubuntu.com/releases/oneiric/release/ubuntu-11.10-server-cloudimg-amd64.tar.gz
#  * disk image (*.img,*.img.gz)
#    if file ends in .img, then it will be uploaded and registered as a to
#    glance as a disk image.  If it ends in .gz, it is uncompressed first.
#    example:
#      http://cloud-images.ubuntu.com/releases/oneiric/release/ubuntu-11.10-server-cloudimg-armel-disk1.img
#      http://launchpad.net/cirros/trunk/0.3.0/+download/cirros-0.3.0-x86_64-rootfs.img.gz

# old ttylinux-uec image
#image_urls="http://smoser.brickies.net/ubuntu/ttylinux-uec/ttylinux-uec-amd64-11.2_2.6.35-15_1.tar.gz" 
# cirros full disk image
#image_urls="http://launchpad.net/cirros/trunk/0.3.0/+download/cirros-0.3.0-x86_64-disk.img" 

# uec style cirros image
image_urls = http://launchpad.net/cirros/trunk/0.3.0/+download/cirros-0.3.0-x86_64-uec.tar.gz, http://uec-images.ubuntu.com/oneiric/current/oneiric-server-cloudimg-amd64.tar.gz

[passwords]

# This section is where passwords could be stored. This section also has special meaning
# in code in that the configuration class we use will look in this section for passwords
# and if no password is found (ie an empty string) then the user will be prompted to enter
# a password, if they do not enter one (or its blank) then one will be generated for the user.

# You will need to send the same MYSQL_PASSWORD to every host if you are doing a multi-node devstack installation.
sql = ${MYSQL_PASSWORD:-}

# Change the rabbit password since the default is "guest"
rabbit = ${RABBIT_PASSWORD:-}

# This password will be used by horizon and keystone as the admin password
horizon_keystone_admin = ${ADMIN_PASSWORD:-}

# Openstack components need to have an admin token to validate user tokens.
service_token = ${SERVICE_TOKEN:-}
service_password = ${SERVICE_PASSWORD:-}

# The xen api connection password
xenapi_connection = ${XENAPI_CONNECTION:-}

# swift_hash is a random unique string for a swift cluster that can never change.
swift_hash = ${SWIFT_HASH:-}