When Trove receives a command to create a guest instance, it does so by launching a Nova instance based on the appropriate guest image that is stored in Glance.
To operate Trove it is vital to have a properly constructed guest image, and while tools are provided that help you build them, the Trove project itself does not distribute guest images. This document shows you how to build guest images for use with Trove.
It is assumed that you have a working OpenStack deployment with the key services like Keystone, Glance, Swift, Cinder, Nova and networking through either Nova Networks or Neutron where you will deploy the guest images. It is also assumed that you have Trove functioning and all the Trove services operating normally. If you don’t have these prerequisites, this document won’t help you get them. Consult the appropriate documentation for installing and configuring OpenStack for that.
At the most basic level, a Trove Guest Instance is a Nova instance launched by Trove in response to a create command. For most of this document, we will confine ourselves to single instance databases; in other words, without the additional complexity of replication or mirroring. Guest instances and Guest images for replicated and mirrored database instances will be addressed specifically in later sections of this document.
This section describes the various components of a Trove Guest Instance.
A Trove Guest Instance contains at least a functioning Operating System and the database software that the instance wishes to provide (as a Service). For example, if your chosen operating system is Ubuntu and you wish to deliver MySQL version 5.5, then your guest instance is a Nova instance running the Ubuntu operating system and will have MySQL version 5.5 installed on it.
Trove supports multiple databases, some of them are relational (RDBMS) and some are non-relational (NoSQL). In order to provide a common management interface to all of these, the Trove Guest Instance has on it a ‘Guest Agent’. The Trove Guest Agent is a component of the Trove system that is specific to the database running on that Guest Instance.
The purpose of the Trove Guest Agent is to implement the Trove Guest Agent API for the specific database. This includes such things as the implementation of the database ‘start’ and ‘stop’ commands. The Trove Guest Agent API is the common API used by Trove to communicate with any guest database, and the Guest Agent is the implementation of that API for the specific database.
The Trove Guest Agent runs on the Trove Guest Instance.
When TaskManager launches the guest VM it injects the specific settings for the guest into the VM, into the file /etc/trove/conf.d/guest_info.conf. The file is injected one of three ways. If use_heat=True, it is injected during the heat launch process. If use_nova_server_config_drive=True it is injected via ConfigDrive. Otherwise it is passed to the nova create call as the ‘files’ parameter and will be injected based on the configuration of Nova; the Nova default is to discard the files. If the settings in guest_info.conf are not present on the guest Guest Agent will fail to start up.
The database stores data on persistent storage on Cinder (if configured, see trove.conf and the volume_support parameter) or ephemeral storage on the Nova instance. The database is accessible over the network and the Guest Instance is configured for network access by client applications.
A Trove Guest Image can be built with any tool that produces an image accepted by Nova. In this document we describe how to build guest images using the ‘Disk Image Builder’ (DIB) tool, and we focus on building qemu images [1]. DIB is an OpenStack tool and is available for download at https://git.openstack.org/cgit/openstack/diskimage-builder/tree/ or https://pypi.python.org/pypi/diskimage-builder/0.1.38.
DIB uses a chroot’ed environment to construct the image. The goal is to build a bare machine that has all the components required for launch by Nova.
You can download the DIB tool from OpenStack’s public git repository. Note that DIB works with Ubuntu and Fedora (RedHat). Other operating systems are not yet fully supported.
user@machine:/opt/stack$ git clone https://git.openstack.org/openstack/diskimage-builder
Cloning into 'diskimage-builder'...
remote: Counting objects: 8881, done.
remote: Total 8881 (delta 0), reused 0 (delta 0)
Receiving objects: 100% (8881/8881), 1.92 MiB | 0 bytes/s, done.
Resolving deltas: 100% (4668/4668), done.
Checking connectivity... done.
user@machine:/opt/stack$ cd diskimage-builder
user@machine:/opt/stack/diskimage-builder$ sudo pip install -r requirements.txt
user@machine:/opt/stack/diskimage-builder$ sudo python setup.py install
Ensure that you have qemu-img [2] and kpartx installed.
The disk-image-create command is the main command in the DIB tool that is used to build guest images for Trove. The disk-image-create command takes the following options:
user@machine:/opt/stack/diskimage-builder$ disk-image-create -h
Usage: disk-image-create [OPTION]... [ELEMENT]...
Options:
-a i386|amd64|armhf -- set the architecture of the image(default amd64)
-o imagename -- set the imagename of the output image file(default image)
-t qcow2,tar -- set the image types of the output image files (default qcow2)
File types should be comma separated
-x -- turn on tracing
-u -- uncompressed; do not compress the image - larger but faster
-c -- clear environment before starting work
--image-size size -- image size in GB for the created image
--image-cache directory -- location for cached images(default ~/.cache/image-create)
--max-online-resize size -- max number of filesystem blocks to support when resizing.
Useful if you want a really large root partition when the image is deployed.
Using a very large value may run into a known bug in resize2fs.
Setting the value to 274877906944 will get you a 1PB root file system.
Making this value unnecessarily large will consume extra disk space
on the root partition with extra file system inodes.
--min-tmpfs size -- minimum size in GB needed in tmpfs to build the image
--no-tmpfs -- do not use tmpfs to speed image build
--offline -- do not update cached resources
--qemu-img-options -- option flags to be passed directly to qemu-img.
Options need to be comma separated, and follow the key=value pattern.
--root-label label -- label for the root filesystem. Defaults to 'cloudimg-rootfs'.
--ramdisk-element -- specify the main element to be used for building ramdisks.
Defaults to 'ramdisk'. Should be set to 'dracut-ramdisk' for platforms such
as RHEL and CentOS that do not package busybox.
--install-type -- specify the default installation type. Defaults to 'source'. Set
to 'package' to use package based installations by default.
-n skip the default inclusion of the 'base' element
-p package[,package,package] -- list of packages to install in the image
-h|--help -- display this help and exit
ELEMENTS_PATH will allow you to specify multiple locations for the elements.
NOTE: At least one distribution root element must be specified.
Examples:
disk-image-create -a amd64 -o ubuntu-amd64 vm ubuntu
export ELEMENTS_PATH=~/source/tripleo-image-elements/elements
disk-image-create -a amd64 -o fedora-amd64-heat-cfntools vm fedora heat-cfntools
user@machine:/opt/stack/diskimage-builder$
The example command provided above would build a perfectly functional Nova image with the 64 bit Fedora operating system.
In addition to the -a argument which specifies to build an amd64 (64 bit) image, and the -o which specifies the output file, the command line lists the various elements that should be used in building the image. The next section of this document talks about image elements.
Building a Trove guest image is a little more involved and the standard elements (more about this later) are highly configurable through the use of environment variables.
This command will create a guest image usable by Trove:
# assign a suitable value for each of these environment
# variables that change the way the elements behave.
export HOST_USERNAME
export HOST_SCP_USERNAME
export GUEST_USERNAME
export CONTROLLER_IP
export TROVESTACK_SCRIPTS
export SERVICE_TYPE
export PATH_TROVE
export ESCAPED_PATH_TROVE
export SSH_DIR
export GUEST_LOGDIR
export ESCAPED_GUEST_LOGDIR
export DIB_CLOUD_INIT_DATASOURCES="ConfigDrive"
export DATASTORE_PKG_LOCATION
export BRANCH_OVERRIDE
# you typically do not have to change these variables
export ELEMENTS_PATH=$TROVESTACK_SCRIPTS/files/elements
export ELEMENTS_PATH+=:$PATH_DISKIMAGEBUILDER/elements
export ELEMENTS_PATH+=:$PATH_TRIPLEO_ELEMENTS/elements
export DIB_APT_CONF_DIR=/etc/apt/apt.conf.d
export DIB_CLOUD_INIT_ETC_HOSTS=true
local QEMU_IMG_OPTIONS="--qemu-img-options compat=1.1"
# run disk-image-create that actually causes the image to be built
$disk-image-create -a amd64 -o "${VM}" \
-x ${QEMU_IMG_OPTIONS} ${DISTRO} ${EXTRA_ELEMENTS} vm \
cloud-init-datasources ${DISTRO}-guest ${DISTRO}-${SERVICE_TYPE}
DIB Elements are ‘executed’ by the disk-image-create command to produce the guest image. An element consists of a number of bash scripts that are executed by DIB in a specific order to generate the image. You provide the names of the elements that you would like executed, in order, on the command line to disk-image-create.
Elements are executed within the chroot’ed environment while DIB is run. Elements are executed in phases and the various phases are (in order) root.d, extra-data.d, pre-install.d, install.d, post-install.d, block-device.d, finalise.d [3], and cleanup.d [4]. The latter reference provides a very good outline on writing elements and is a ‘must read’.
Some elements use environment.d to setup environment variables. Element dependencies can be established using the element-deps and element-provides files which are plain text files.
DIB comes with some tools that are located in the elements directory.
user@machine:/opt/stack/diskimage-builder/elements$ ls
apt-conf dpkg ramdisk
apt-preferences dracut-network ramdisk-base
apt-sources dracut-ramdisk rax-nova-agent
architecture-emulation-binaries element-manifest redhat-common
baremetal enable-serial-console rhel
base epel rhel7
cache-url fedora rhel-common
centos7 hwburnin rpm-distro
cleanup-kernel-initrd hwdiscovery select-boot-kernel-initrd
cloud-init-datasources ilo selinux-permissive
cloud-init-nocloud ironic-agent serial-console
debian ironic-discoverd-ramdisk source-repositories
debian-systemd iso stable-interface-names
debian-upstart local-config svc-map
deploy manifests uboot
deploy-baremetal mellanox ubuntu
deploy-ironic modprobe-blacklist ubuntu-core
deploy-kexec opensuse vm
dhcp-all-interfaces package-installs yum
dib-run-parts pip-cache zypper
disable-selinux pkg-map
dkms pypi
In addition, projects like TripleO [5] provide elements as well.
Trove provides a set of elements as part of the trove [6] project which will be described in the next section.
Reference elements provided by Trove are part of the trove project.
In keeping with the philosophy of making elements ‘layered’, Trove provides two sets of elements. The first implements the guest agent for various operating systems and the second implements the database for these operating systems.
The Trove reference elements are located in the trove/integration/scripts/files/elements directory. The elements [operating-system]-guest provide the Trove Guest capabilities and the [operating-system]-[database] elements provide support for each database on the specified database.
user@machine:/opt/stack/trove/integration/scripts/files/elements$ ls -l
total 56
drwxrwxr-x 5 user group 4096 Jan 7 12:47 fedora-guest
drwxrwxr-x 3 user group 4096 Jan 7 12:47 fedora-mongodb
drwxrwxr-x 3 user group 4096 Jan 7 12:47 fedora-mysql
drwxrwxr-x 3 user group 4096 Jan 7 12:47 fedora-percona
drwxrwxr-x 3 user group 4096 Jan 7 12:47 fedora-postgresql
drwxrwxr-x 3 user group 4096 Jan 7 12:47 fedora-redis
drwxrwxr-x 3 user group 4096 Jan 7 12:47 ubuntu-cassandra
drwxrwxr-x 3 user group 4096 Jan 7 12:47 ubuntu-couchbase
drwxrwxr-x 6 user group 4096 Jan 7 12:47 ubuntu-guest
drwxrwxr-x 3 user group 4096 Jan 7 12:47 ubuntu-mongodb
drwxrwxr-x 4 user group 4096 Jan 7 12:47 ubuntu-mysql
drwxrwxr-x 4 user group 4096 Jan 7 12:47 ubuntu-percona
drwxrwxr-x 3 user group 4096 Jan 7 12:47 ubuntu-postgresql
drwxrwxr-x 3 user group 4096 Jan 7 12:47 ubuntu-redis
user@machine:/opt/stack/trove/integration/scripts/files/elements$
With this infrastructure in place, and the elements from DIB and TripleO accessible to the DIB command, one can generate the (for example) Ubuntu guest image for Percona Server with the command line:
${DIB} -a amd64 -o ${output-file} Ubuntu vm \
cloud-init-datasources ubuntu-guest ubuntu-percona
Where ${DIB} is the fully qualified path to the disk-image-create command and ${output-file} is the name of the output file to be created.
When contributing a new datastore, you should contribute elements that will allow any user of Trove to be able to build a guest image for that datastore.
This is typically accomplished by submitting files into the trove project, as above.
The guest agent code typically runs on the guest instance alongside the database. There are two ways in which the guest agent code can be placed on the guest instance and we describe both of these here.
In this option, the guest agent code is built into the guest image, thereby ensuring that all database instances that are launched with the image will have the exact same version of the guest image.
This can be accomplished by placing suitable code in the elements for the image and these elements will ensure that the guest agent code is installed on the image.
In this option, the guest agent code is not part of the guest image and instead the guest agent code is obtained at runtime, potentially from some well known location.
In devstack, this is implemented in trove-guest.upstart.conf and trove-guest.systemd.conf. Shown below is the code from trove-guest.upstart.conf (this code may change in the future and is shown here as an example only). See the code highlighted below:
description "Trove Guest"
author "Auto-Gen"
start on (filesystem and net-device-up IFACE!=lo)
stop on runlevel [016]
chdir /var/run
pre-start script
mkdir -p /var/run/trove
chown GUEST_USERNAME:root /var/run/trove/
mkdir -p /var/lock/trove
chown GUEST_USERNAME:root /var/lock/trove/
mkdir -p GUEST_LOGDIR
chown GUEST_USERNAME:root GUEST_LOGDIR
chmod +r /etc/guest_info
# If /etc/trove does not exist, copy the trove source and the
# guest agent config from the user's development environment
if [ ! -d /etc/trove ]; then
-> sudo -u GUEST_USERNAME rsync -e 'ssh -o UserKnownHostsFile=/dev/null -o StrictHostKeyChecking=no' -avz --exclude='.*' HOST_SCP_USERNAME@NETWORK_GATEWAY:PATH_TROVE/ /home/GUEST_USERNAME/trove
mkdir -p /etc/trove
-> sudo -u GUEST_USERNAME rsync -e 'ssh -o UserKnownHostsFile=/dev/null -o StrictHostKeyChecking=no' -avz --exclude='.*' HOST_SCP_USERNAME@NETWORK_GATEWAY:/etc/trove/trove-guestagent.conf ~GUEST_USERNAME/
mv ~GUEST_USERNAME/trove-guestagent.conf /etc/trove/trove-guestagent.conf
fi
end script
exec su -c "/home/GUEST_USERNAME/trove/contrib/trove-guestagent -config-file=/etc/guest_info --config-file=/etc/trove/trove-guestagent.conf" GUEST_USERNAME
In building an image for a production Trove deployment, it is a very bad idea to use this mechanism. It makes sense in a development environment where the thing that you are developing is in Trove and part of the Guest Agent! This is because you get to merely boot a new Trove instance and the freshly modified code gets run on the Guest. But, in any other circumstance, it is much better to have the guest image include the guest agent code.
In building a guest image, there are several considerations that one must take into account. Some of the ones that we have encountered are described below.
The actions performed on first boot can be very expensive and may impact the time taken to launch a new guest instance. So, for example, guest images that don’t have the database software pre-installed and instead download and install during launch could take longer to launch.
In building a guest image, therefore care should be taken to ensure that activities performed on first boot are traded off against the demands for start-time.
Some database software downloads are licensed and manual steps are required in order to obtain the installable software. In other instances, no repositories may be setup to serve images of a particular database. In these cases, it is suggested that an extra step be used to build the guest image.
The user manually downloads the database software in a suitable format and places it in a specified location on the machine that will be used to build the guest image.
An environment variable ‘DATASTORE_PKG_LOCATION’ is set to point to this location. It can be a single file (for example new_db.deb) or a folder (for example new_db_files) depending on what the elements expect. In the latter case, the folder would need to contain all the files that the elements need in order to install the database software (a folder would typically be used only if more than one file was required).
Use an extra-data.d folder for the element and copy the file into the image
Steps in extra-data.d are run first, and outside the DIB chroot’ed environment. The step here can copy the installable from DATASTORE_PKG_LOCATION into the image (typically into TMP_HOOKS_PATH).
For example, if DATASTORE_PKG_LOCATION contains the full path to an installation package, an element in this folder could contain the following line:
dd if=${DATASTORE_PKG_LOCATION} of=${TMP_HOOKS_PATH}/new_db.deb
A standard install.d step can now install the software from TMP_HOOKS_DIR.
For example, an element in this folder could contain:
dpkg -i ${TMP_HOOKS_PATH}/new_db.deb
Once elements have been set up that expect a package to be available, the guest image can be created by executing the following:
DATASTORE_PKG_LOCATION=/path/to/new_db.deb ./script_to_call_dib.sh
Assuming the elements for new_db are available in the trove repository, this would equate to:
DATASTORE_PKG_LOCATION=/path/to/new_db.deb ./trovestack kick-start new_db
A very good reference for how one builds guest images can be found by reviewing the trovestack script (trove/integration/scripts). Lower level routines that actually invoke Disk Image Builder can be found in trove/integration/scripts/functions_qemu.
The following block of code illustrates the most basic invocation of DIB to create a guest image. This code is in trove/integration/scripts/functions_qemu as part of the function build_vm(). We look at this section of code in detail below.
# assign a suitable value for each of these environment
# variables that change the way the elements behave.
export HOST_USERNAME
export HOST_SCP_USERNAME
export GUEST_USERNAME
export CONTROLLER_IP
export TROVESTACK_SCRIPTS
export SERVICE_TYPE
export PATH_TROVE
export ESCAPED_PATH_TROVE
export SSH_DIR
export GUEST_LOGDIR
export ESCAPED_GUEST_LOGDIR
export DIB_CLOUD_INIT_DATASOURCES="ConfigDrive"
export DATASTORE_PKG_LOCATION
export BRANCH_OVERRIDE
# you typically do not have to change these variables
export ELEMENTS_PATH=$TROVESTACK_SCRIPTS/files/elements
export ELEMENTS_PATH+=:$PATH_DISKIMAGEBUILDER/elements
export ELEMENTS_PATH+=:$PATH_TRIPLEO_ELEMENTS/elements
export DIB_APT_CONF_DIR=/etc/apt/apt.conf.d
export DIB_CLOUD_INIT_ETC_HOSTS=true
local QEMU_IMG_OPTIONS="--qemu-img-options compat=1.1"
# run disk-image-create that actually causes the image to be built
$disk-image-create -a amd64 -o "${VM}" \
-x ${QEMU_IMG_OPTIONS} ${DISTRO} ${EXTRA_ELEMENTS} vm \
cloud-init-datasources ${DISTRO}-guest ${DISTRO}-${SERVICE_TYPE}
Several of the environment variables referenced above are referenced in the course of the Disk Image Building process.
For example, let’s look at GUEST_LOGDIR. Looking at the element elements/fedora-guest/extra-data.d/20-guest-systemd, we find:
#!/bin/bash
set -e
set -o xtrace
# CONTEXT: HOST prior to IMAGE BUILD as SCRIPT USER
# PURPOSE: stages the bootstrap file and upstart conf file while replacing variables so that guest image is properly
# configured
source $_LIB/die
[ -n "$TMP_HOOKS_PATH" ] || die "Temp hook path not set"
[ -n "${GUEST_USERNAME}" ] || die "GUEST_USERNAME needs to be set to the user for the guest image"
[ -n "${HOST_SCP_USERNAME}" ] || die "HOST_SCP_USERNAME needs to be set to the user for the host instance"
[ -n "${CONTROLLER_IP}" ] || die "CONTROLLER_IP needs to be set to the ip address that guests will use to contact the controller"
[ -n "${ESCAPED_PATH_TROVE}" ] || die "ESCAPED_PATH_TROVE needs to be set to the path to the trove directory on the trovestack host"
[ -n "${TROVESTACK_SCRIPTS}" ] || die "TROVESTACK_SCRIPTS needs to be set to the trove/integration/scripts dir"
[ -n "${ESCAPED_GUEST_LOGDIR}" ] || die "ESCAPED_GUEST_LOGDIR must be set to the escaped guest log dir"
sed "s/GUEST_USERNAME/${GUEST_USERNAME}/g;s/GUEST_LOGDIR/${ESCAPED_GUEST_LOGDIR}/g;s/HOST_SCP_USERNAME/${HOST_SCP_USERNAME}/g;s/CONTROLLER_IP/${CONTROLLER_IP}/g;s/PATH_TROVE/${ESCAPED_PATH_TROVE}/g" \
${TROVESTACK_SCRIPTS}/files/trove-guest.systemd.conf >
${TMP_HOOKS_PATH}/trove-guest.service
As you can see, the value of GUEST_LOGDIR is used in the extra-data.d script to appropriately configure the trove-guest.systemd.conf file.
This pattern is one that you can expect in your own building of guest images. The invocation of disk-image-create provides a list of elements that are to be invoked ‘in order’.
That list of elements is:
${DISTRO}
${EXTRA_ELEMENTS}
vm
cloud-init-datasources
${DISTRO}-guest
${DISTRO}-${SERVICE_TYPE}
When invoked to (for example) create a MySQL guest image on Ubuntu, we can expect that DISTRO would be ‘Ubuntu’ and SERVICE_TYPE would be MySQL. And therefore these would end up being the elements:
ubuntu From diskimage-builder/elements/ubuntu
vm From diskimage-builder/elements/vm
cloud-init-datasources From diskimage-builder/elements/cloud-init-datasources
ubuntu-guest From trove/integration/scripts/files/elements/ubuntu-guest
ubuntu-mysql From trove/integration/scripts/files/elements/ubuntu-mysql
[1] | For more information about QEMU, refer to http://wiki.qemu.org/Main_Page |
[2] | On Ubuntu, qemu-img is part of the package qemu-utils, on Fedora and RedHat it is part of the qemu package. |
[3] | User (especially in the USA) are cautioned about this spelling which once resulted in several sleepless nights. |
[4] | https://git.openstack.org/cgit/openstack/diskimage-builder/tree/README.rst#writing-an-element |
[5] | https://git.openstack.org/cgit/openstack/tripleo-image-elements/tree/elements |
[6] | https://git.openstack.org/cgit/openstack/trove/tree/integration/scripts/files/elements |
Except where otherwise noted, this document is licensed under Creative Commons Attribution 3.0 License. See all OpenStack Legal Documents.