DevStack is written in POSIX shell script. This choice was made because it best illustrates the configuration steps that this implementation takes on setting up and interacting with OpenStack components. DevStack specifically uses Bash and is compatible with Bash 3.
DevStack's official repository is located on GitHub at https://github.com/openstack-dev/devstack.git. Besides the master branch that tracks the OpenStack trunk branches a separate branch is maintained for all OpenStack releases starting with Diablo (stable/diablo).
Contributing code to DevStack follows the usual OpenStack process as described in How To Contribute in the OpenStack wiki. DevStack's LaunchPad project contains the usual links for blueprints, bugs, tec.
The primary script in DevStack is stack.sh
, which performs the bulk of the
work for DevStack's use cases. There is a subscript functions
that contains
generally useful shell functions and is used by a number of the scripts in
DevStack.
The lib
directory contains sub-scripts for projects or packages that stack.sh
sources to perform much of the work related to those projects. These sub-scripts
contain configuration defaults and functions to configure, start and stop the project
or package. These variables and functions are also used by related projects,
such as Grenade, to manage a DevStack installation.
A number of additional scripts can be found in the tools
directory that may
be useful in supporting DevStack installations. Of particular note are info.sh
to collect and report information about the installed system, and instal_prereqs.sh
that handles installation of the prerequisite packages for DevStack. It is
suitable, for example, to pre-load a system for making a snapshot.
DevStack scripts should generally begin by calling env(1)
in the shebang line:
#!/usr/bin/env bash
Sometimes the script needs to know the location of the DevStack install directory.
TOP_DIR
should always point there, even if the script itself is located in
a subdirectory:
# Keep track of the current devstack directory. TOP_DIR=$(cd $(dirname "$0") && pwd)
Many scripts will utilize shared functions from the functions
file. There are
also rc files (stackrc
and openrc
) that are often included to set the primary
configuration of the user environment:
# Keep track of the current devstack directory. TOP_DIR=$(cd $(dirname "$0") && pwd) # Import common functions source $TOP_DIR/functions # Import configuration source $TOP_DIR/openrc
stack.sh
is a rather large monolithic script that flows through from beginning
to end. It has been broken down into project-specific subscripts (as noted above)
located in lib
to make stack.sh
more manageable and to promote code reuse.
These library sub-scripts have a number of fixed entry points, some of which may
just be stubs. These entry points will be called by stack.sh
in the
following order:
install_XXXX configure_XXXX init_XXXX start_XXXX stop_XXXX cleanup_XXXX
There is a sub-script template in lib/templates
to be used in creating new
service sub-scripts. The comments in <>
are meta comments describing
how to use the template and should be removed.
In order to show the dependencies and conditions under which project functions
are executed the top-level conditional testing for things like is_service_enabled
should be done in stack.sh
. There may be nested conditionals that need
to be in the sub-script, such as testing for keystone being enabled in
configure_swift()
.
stackrc
is the global configuration file for DevStack. It is responsible for
calling localrc
if it exists so configuration can be overridden by the user.
The criteria for what belongs in stackrc
can be vaguely summarized as
follows:
- All project respositories and branches (for historical reasons)
- Global configuration that may be referenced in
localrc
, i.e.DEST
,DATA_DIR
- Global service configuration like
ENABLED_SERVICES
- Variables used by multiple services that do not have a clear owner, i.e.
VOLUME_BACKING_FILE_SIZE
(nova-volumes and cinder) orPUBLIC_NETWORK_NAME
(nova-network and quantum) - Variables that can not be cleanly declared in a project file due to dependency ordering, i.e. the order of sourcing the project files can not be changed for other reasons but the earlier file needs to dereference a variable set in the later file. This should be rare.
Also, variable declarations in stackrc
do NOT allow overriding (the form
FOO=${FOO:-baz}
); if they did then they can already be changed in localrc
and can stay in the project file.
The official DevStack repo on GitHub does not include a gh-pages branch that GitHub uses to create static web sites. That branch is maintained in the CloudBuilders DevStack repo mirror that supports the http://devstack.org site. This is the primary DevStack documentation along with the DevStack scripts themselves.
All of the scripts are processed with shocco to render them with the comments
as text describing the script below. For this reason we tend to be a little
verbose in the comments _ABOVE_ the code they pertain to. Shocco also supports
Markdown formatting in the comments; use it sparingly. Specifically, stack.sh
uses Markdown headers to divide the script into logical sections.
The scripts in the exercises directory are meant to 1) perform basic operational checks on certain aspects of OpenStack; and b) document the use of the OpenStack command-line clients.
In addition to the guidelines above, exercise scripts MUST follow the structure
outlined here. swift.sh
is perhaps the clearest example of these guidelines.
These scripts are executed serially by exercise.sh
in testing situations.
Begin and end with a banner that stands out in a sea of script logs to aid in debugging failures, particularly in automated testing situations. If the end banner is not displayed, the script ended prematurely and can be assumed to have failed.
echo "**************************************************" echo "Begin DevStack Exercise: $0" echo "**************************************************" ... set +o xtrace echo "**************************************************" echo "End DevStack Exercise: $0" echo "**************************************************"
The scripts will generally have the shell
xtrace
attribute set to display the actual commands being executed, and theerrexit
attribute set to exit the script on non-zero exit codes:# This script exits on an error so that errors don't compound and you see # only the first error that occured. set -o errexit # Print the commands being run so that we can see the command that triggers # an error. It is also useful for following allowing as the install occurs. set -o xtrace
Settings and configuration are stored in
exerciserc
, which must be sourced afteropenrc
orstackrc
:# Import exercise configuration source $TOP_DIR/exerciserc
There are a couple of helper functions in the common
functions
sub-script that will check for non-zero exit codes and unset environment variables and print a message and exit the script. These should be called after most client commands that are not otherwise checked to short-circuit long timeouts (instance boot failure, for example):swift post $CONTAINER die_if_error "Failure creating container $CONTAINER" FLOATING_IP=`euca-allocate-address | cut -f2` die_if_not_set FLOATING_IP "Failure allocating floating IP"
If you want an exercise to be skipped when for example a service wasn't enabled for the exercise to be run, you can exit your exercise with the special exitcode 55 and it will be detected as skipped.
The exercise scripts should only use the various OpenStack client binaries to interact with OpenStack. This specifically excludes any
*-manage
tools as those assume direct access to configuration and databases, as well as direct database access from the exercise itself.If specific configuration needs to be present for the exercise to complete, it should be staged in
stack.sh
, or called fromstack.sh
(seefiles/keystone_data.sh
for an example of this).The
OS_*
environment variables should be the only ones used for all authentication to OpenStack clients as documented in the CLIAuth wiki page.
- The exercise MUST clean up after itself if successful. If it is not successful, it is assumed that state will be left behind; this allows a chance for developers to look around and attempt to debug the problem. The exercise SHOULD clean up or graciously handle possible artifacts left over from previous runs if executed again. It is acceptable to require a reboot or even a re-install of DevStack to restore a clean test environment.