This is the Buildbot documentation for Buildbot version 3.9.1.

If you are evaluating Buildbot and would like to get started quickly, start with the Tutorial. Regular users of Buildbot should consult the Manual, and those wishing to modify Buildbot directly will want to be familiar with the Developer’s Documentation.

Table Of Contents

1. Buildbot Tutorial

Contents:

1.1. First Run

1.1.1. Goal

This tutorial will take you from zero to running your first buildbot master and worker as quickly as possible, without changing the default configuration.

This tutorial is all about instant gratification and the five minute experience: in five minutes we want to convince you that this project works, and that you should seriously consider spending time learning the system. In this tutorial no configuration or code changes are done.

This tutorial assumes that you are running Unix, but might be adaptable to Windows.

Thanks to virtualenv, installing buildbot in a standalone environment is very easy. For those more familiar with Docker, there also exists a docker version of these instructions.

You should be able to cut and paste each shell block from this tutorial directly into a terminal.

1.1.2. Simple introduction to BuildBot

Before trying to run BuildBot it’s helpful to know what BuildBot is.

BuildBot is a continuous integration framework written in Python. It consists of a master daemon and potentially many worker daemons that usually run on other machines. The master daemon runs a web server that allows the end user to start new builds and to control the behaviour of the BuildBot instance. The master also distributes builds to the workers. The worker daemons connect to the master daemon and execute builds whenever master tells them to do so.

In this tutorial we will run a single master and a single worker on the same machine.

A more thorough explanation can be found in the manual section of the Buildbot documentation.

1.1.3. Getting ready

There are many ways to get the code on your machine. We will use the easiest one: via pip in a virtualenv. It has the advantage of not polluting your operating system, as everything will be contained in the virtualenv.

To make this work, you will need the following installed:

Preferably, use your distribution package manager to install these.

You will also need a working Internet connection, as virtualenv and pip will need to download other projects from the Internet. The master and builder daemons will need to be able to connect to github.com via HTTPS to fetch the repo we’re testing.

If you need to use a proxy for this ensure that either the HTTPS_PROXY or ALL_PROXY environment variable is set to your proxy, e.g., by executing export HTTPS_PROXY=http://localhost:9080 in the shell before starting each daemon.

Note

Buildbot does not require root access. Run the commands in this tutorial as a normal, unprivileged user.

1.1.4. Creating a master

The first necessary step is to create a virtualenv for our master. We first create a separate directory to demonstrate the distinction between a master and worker:

mkdir -p ~/buildbot-test/master_root
cd ~/buildbot-test/master_root

Then we create the virtual environment. On Python 3:

python3 -m venv sandbox
source sandbox/bin/activate

Next, we need to install several build dependencies to make sure we can install buildbot and its supporting packages. These build dependencies are:

  • GCC build tools (gcc for RHEL/CentOS/Fedora based distributions, or build-essential for Ubuntu/Debian based distributions).

  • Python development library (python3-devel for RHEL/CentOS/Fedora based distributions, or python3-dev for Ubuntu/Debian based distributions).

  • OpenSSL development library (openssl-devel for RHEL/CentOS/Fedora based distributions, or libssl-dev for Ubuntu/Debian based distributions).

  • libffi development library (libffi-devel for RHEL/CentOS/Fedora based distributions, or libffi-dev for Ubuntu/Debian based distributions).

Install these build dependencies:

# if in Ubuntu/Debian based distributions:
sudo apt-get install build-essential python3-dev libssl-dev libffi-dev

# if in RHEL/CentOS/Fedora based distributions:
sudo yum install gcc python3-devel openssl-devel libffi-devel

or refer to your distribution’s documentation on how to install these packages.

Now that we are ready, we need to install buildbot:

pip install --upgrade pip
pip install 'buildbot[bundle]'

Now that buildbot is installed, it’s time to create the master. my_master represents a path to a directory, where future master will be created:

buildbot create-master my_master

Buildbot’s activity is controlled by a configuration file. Buildbot by default uses configuration from file at master.cfg, but its installation comes with a sample configuration file named master.cfg.sample. We will use the sample configuration file unchanged, but we have to rename it to master.cfg:

mv my_master/master.cfg.sample my_master/master.cfg

Finally, start the master:

buildbot start my_master

You will now see some log information from the master in this terminal. It should end with lines like these:

2014-11-01 15:52:55+0100 [-] BuildMaster is running
The buildmaster appears to have (re)started correctly.

From now on, feel free to visit the web status page running on the port 8010: http://localhost:8010/

Our master now needs (at least) one worker to execute its commands. For that, head on to the next section!

1.1.5. Creating a worker

The worker will be executing the commands sent by the master. In this tutorial, we are using the buildbot/hello-world project as an example. As a consequence of this, your worker will need access to the git command in order to checkout some code. Be sure that it is installed, or the builds will fail.

Same as we did for our master, we will create a virtualenv for our worker next to the master’s one. It would however be completely ok to do this on another computer - as long as the worker computer is able to connect to the master’s . We first create a new directory for the worker:

mkdir -p ~/buildbot-test/worker_root
cd ~/buildbot-test/worker_root

Again, we create a virtual environment. On Python 3:

python3 -m venv sandbox
source sandbox/bin/activate

Install the buildbot-worker command:

pip install --upgrade pip
pip install buildbot-worker
# required for `runtests` build
pip install setuptools-trial

Now, create the worker:

buildbot-worker create-worker my_worker localhost example-worker pass

Note

If you decided to create this from another computer, you should replace localhost with the name of the computer where your master is running.

The username (example-worker), and password (pass) should be the same as those in my_master/master.cfg; verify this is the case by looking at the section for c['workers']:

cat ../master_root/my_master/master.cfg

And finally, start the worker:

buildbot-worker start my_worker

Check the worker’s output. It should end with lines like these:

2014-11-01 15:56:51+0100 [-] Connecting to localhost:9989
2014-11-01 15:56:51+0100 [Broker,client] message from master: attached
The worker appears to have (re)started correctly.

Meanwhile, from the other terminal, in the master log (twisted.log in the master directory), you should see lines like these:

2014-11-01 15:56:51+0100 [Broker,1,127.0.0.1] worker 'example-worker' attaching from
IPv4Address(TCP, '127.0.0.1', 54015)
2014-11-01 15:56:51+0100 [Broker,1,127.0.0.1] Got workerinfo from 'example-worker'
2014-11-01 15:56:51+0100 [-] bot attached

1.1.6. Wrapping up

Your directory tree now should look like this:

~/buildbot-test/master_root/my_master  # master base directory
~/buildbot-test/master_root/sandbox    # virtualenv for master

~/buildbot-test/worker_root/my_worker  # worker base directory
~/buildbot-test/worker_root/sandbox    # virtualenv for worker

You should now be able to go to http://localhost:8010, where you will see a web page similar to:

index page

Click on “Builds” at the left to open the submenu and then Builders to see that the worker you just started (identified by the green bubble) has connected to the master:

builder runtests is active.

Your master is now quietly waiting for new commits to hello-world. This doesn’t happen very often though. In the next section, we’ll see how to manually start a build.

We just wanted to get you to dip your toes in the water. It’s easy to take your first steps, but this is about as far as we can go without touching the configuration.

You’ve got a taste now, but you’re probably curious for more. Let’s step it up a little in the second tutorial by changing the configuration and doing an actual build. Continue on to A Quick Tour.

1.2. A Quick Tour

1.2.1. Goal

This tutorial will expand on the First Run tutorial by taking a quick tour around some of the features of buildbot that are hinted at in the comments in the sample configuration. We will simply change parts of the default configuration and explain the activated features.

As a part of this tutorial, we will make buildbot do a few actual builds.

This section will teach you how to:

  • make simple configuration changes and activate them

  • deal with configuration errors

  • force builds

  • enable and control the IRC bot

  • add a ‘try’ scheduler

1.2.2. The First Build

On the Builders page, click on the runtests link. You’ll see a builder page, and a blue “force” button that will bring up the following dialog box:

force a build.

Click Start Build - there’s no need to fill in any of the fields in this case. Next, click on view in waterfall.

You will now see that a successful test run has happened:

an successful test run happened.

This simple process is essentially the whole purpose of the Buildbot project.

The information about what actions are executed for a certain build are defined in things called builders.

The information about when a certain builder should launch a build are defined in things called schedulers. In fact, the blue “force” button that was pushed in this example activated a scheduler too.

1.2.3. Setting Project Name and URL

Let’s start simple by looking at where you would customize the buildbot’s project name and URL.

We continue where we left off in the First Run tutorial.

Open a new terminal, go to the directory you created master in, activate the same virtualenv instance you created before, and open the master configuration file with an editor (here $EDITOR is your editor of choice like vim, gedit, or emacs):

cd ~/buildbot-test/master
source sandbox/bin/activate
$EDITOR master/master.cfg

Now, look for the section marked PROJECT IDENTITY which reads:

####### PROJECT IDENTITY

# the 'title' string will appear at the top of this buildbot installation's
# home pages (linked to the 'titleURL').

c['title'] = "Hello World CI"
c['titleURL'] = "https://buildbot.github.io/hello-world/"

If you want, you can change either of these links to anything you want so that you can see what happens when you change them.

After making a change, go to the terminal and type:

buildbot reconfig master

You will see a handful of lines of output from the master log, much like this:

2011-12-04 10:11:09-0600 [-] loading configuration from /path/to/buildbot/master.cfg
2011-12-04 10:11:09-0600 [-] configuration update started
2011-12-04 10:11:09-0600 [-] builder runtests is unchanged
2011-12-04 10:11:09-0600 [-] removing IStatusReceiver <...>
2011-12-04 10:11:09-0600 [-] (TCP Port 8010 Closed)
2011-12-04 10:11:09-0600 [-] Stopping factory <...>
2011-12-04 10:11:09-0600 [-] adding IStatusReceiver <...>
2011-12-04 10:11:09-0600 [-] RotateLogSite starting on 8010
2011-12-04 10:11:09-0600 [-] Starting factory <...>
2011-12-04 10:11:09-0600 [-] Setting up http.log rotating 10 files of 10000000 bytes each
2011-12-04 10:11:09-0600 [-] WebStatus using (/path/to/buildbot/public_html)
2011-12-04 10:11:09-0600 [-] removing 0 old schedulers, updating 0, and adding 0
2011-12-04 10:11:09-0600 [-] adding 1 new changesources, removing 1
2011-12-04 10:11:09-0600 [-] gitpoller: using workdir '/path/to/buildbot/gitpoller-workdir'
2011-12-04 10:11:09-0600 [-] GitPoller repository already exists
2011-12-04 10:11:09-0600 [-] configuration update complete

Reconfiguration appears to have completed successfully.

The important lines are the ones telling you that the new configuration is being loaded (at the top) and that the update is complete (at the bottom).

Now, if you go back to the waterfall page, you will see that the project’s name is whatever you may have changed it to, and when you click on the URL of the project name at the bottom of the page, it should take you to the link you put in the configuration.

1.2.4. Configuration Errors

It is very common to make a mistake when configuring buildbot, so you might as well see now what happens in that case and what you can do to fix the error.

Open up the config again and introduce a syntax error by removing the first single quote in the two lines you changed before, so they read:

c[title'] = "Hello World CI"
c[titleURL'] = "https://buildbot.github.io/hello-world/"

This creates a Python SyntaxError. Now go ahead and reconfig the master:

buildbot reconfig master

This time, the output looks like:

2015-08-14 18:40:46+0000 [-] beginning configuration update
2015-08-14 18:40:46+0000 [-] Loading configuration from '/data/buildbot/master/master.cfg'
2015-08-14 18:40:46+0000 [-] error while parsing config file:
        Traceback (most recent call last):
          File "/usr/local/lib/python2.7/dist-packages/buildbot/master.py", line 265, in reconfig
            d = self.doReconfig()
          File "/usr/local/lib/python2.7/dist-packages/twisted/internet/defer.py", line 1274, in unwindGenerator
            return _inlineCallbacks(None, gen, Deferred())
          File "/usr/local/lib/python2.7/dist-packages/twisted/internet/defer.py", line 1128, in _inlineCallbacks
            result = g.send(result)
          File "/usr/local/lib/python2.7/dist-packages/buildbot/master.py", line 289, in doReconfig
            self.configFileName)
        --- <exception caught here> ---
          File "/usr/local/lib/python2.7/dist-packages/buildbot/config.py", line 156, in loadConfig
            exec f in localDict
        exceptions.SyntaxError: EOL while scanning string literal (master.cfg, line 103)

2015-08-14 18:40:46+0000 [-] error while parsing config file: EOL while scanning string literal (master.cfg, line 103) (traceback in logfile)
2015-08-14 18:40:46+0000 [-] reconfig aborted without making any changes

Reconfiguration failed. Please inspect the master.cfg file for errors,
correct them, then try 'buildbot reconfig' again.

This time, it’s clear that there was a mistake in the configuration. Luckily, the Buildbot master will ignore the wrong configuration and keep running with the previous configuration.

The message is clear enough, so open the configuration again, fix the error, and reconfig the master.

1.2.5. Enabling the IRC Bot

Buildbot includes an IRC bot that you can tell to join a channel to control and report on the status of buildbot.

Note

Security Note

Please note that any user having access to your IRC channel, or can send a private message to the bot, will be able to create or stop builds bug #3377.

First, start an IRC client of your choice, connect to irc.freenode.net and join an empty channel. In this example we will use #buildbot-test, so go join that channel. (Note: please do not join the main buildbot channel!)

Edit master.cfg and look for the BUILDBOT SERVICES section. At the end of that section add the lines:

c['services'].append(reporters.IRC(host="irc.freenode.net", nick="bbtest",
                                   channels=["#buildbot-test"]))

The reconfigure the master and type:

grep -i irc master/twistd.log

The log output should contain a line like this:

2016-11-13 15:53:06+0100 [-] Starting factory <...>
2016-11-13 15:53:19+0100 [IrcStatusBot,client] <...>: I have joined #buildbot-test

You should see the bot now joining in your IRC client. In your IRC channel, type:

bbtest: commands

to get a list of the commands the bot supports.

Let’s tell the bot to notify on certain events. To learn on which EVENTS we can notify, type:

bbtest: help notify

Now, let’s set some event notifications:

<@lsblakk> bbtest: notify on started finished failure
< bbtest> The following events are being notified: ['started', 'failure', 'finished']

Now, go back to the web interface and force another build. Alternatively, ask the bot to force a build:

<@lsblakk> bbtest: force build --codebase= runtests
< bbtest> build #1 of runtests started
< bbtest> Hey! build runtests #1 is complete: Success [finished]

You can also see the new builds in the web interface.

a successful test run from IRC happened.

The full documentation is available at IRC.

1.2.6. Setting Authorized Web Users

The default configuration allows everyone to perform any task, like creating or stopping builds via the web interface. To restrict this to a user, look for:

c['www'] = dict(port=8010,
                 plugins=dict(waterfall_view={}, console_view={}))

and append:

c['www']['authz'] = util.Authz(
        allowRules = [
            util.AnyEndpointMatcher(role="admins")
        ],
        roleMatchers = [
            util.RolesFromUsername(roles=['admins'], usernames=['Alice'])
        ]
)
c['www']['auth'] = util.UserPasswordAuth([('Alice','Password1')])

For more details, see Authentication plugins.

1.2.7. Adding a ‘try’ scheduler

Buildbot includes a way for developers to submit patches for testing without committing them to the source code control system. (This is really handy for projects that support several operating systems or architectures.)

To set this up, add the following lines to master.cfg:

from buildbot.scheduler import Try_Userpass
c['schedulers'] = []
c['schedulers'].append(Try_Userpass(
                                    name='try',
                                    builderNames=['runtests'],
                                    port=5555,
                                    userpass=[('sampleuser','samplepass')]))

Then you can submit changes using the try command.

Let’s try this out by making a one-line change to hello-world, say, to make it trace the tree by default:

git clone https://github.com/buildbot/hello-world.git hello-world-git
cd hello-world-git/hello
$EDITOR __init__.py
# change 'return "hello " + who' on line 6 to 'return "greets " + who'

Then run buildbot’s try command as follows:

cd ~/buildbot-test/master
source sandbox/bin/activate
buildbot try --connect=pb --master=127.0.0.1:5555 \
    --username=sampleuser --passwd=samplepass --vc=git

This will do git diff for you and send the resulting patch to the server for build and test against the latest sources from Git.

Now go back to the waterfall page, click on the runtests link, and scroll down. You should see that another build has been started with your change (and stdout for the tests should be chock-full of parse trees as a result). The “Reason” for the job will be listed as “‘try’ job”, and the blamelist will be empty.

To make yourself show up as the author of the change, use the --who=emailaddr option on buildbot try to pass your email address.

To make a description of the change show up, use the --properties=comment="this is a comment" option on buildbot try.

To use ssh instead of a private username/password database, see Try_Jobdir.

1.3. First Buildbot run with Docker

Note

Docker can be tricky to get working correctly if you haven’t used it before. If you’re having trouble, first determine whether it is a Buildbot issue or a Docker issue by running:

docker run ubuntu:20.04 apt-get update

If that fails, look for help with your Docker install. On the other hand, if that succeeds, then you may have better luck getting help from members of the Buildbot community.

Docker is a tool that makes building and deploying custom environments a breeze. It uses lightweight linux containers (LXC) and performs quickly, making it a great instrument for the testing community. The next section includes a Docker pre-flight check. If it takes more that 3 minutes to get the ‘Success’ message for you, try the Buildbot pip-based first run instead.

1.3.1. Current Docker dependencies

  • Linux system, with at least kernel 3.8 and AUFS support. For example, Standard Ubuntu, Debian and Arch systems.

  • Packages: lxc, iptables, ca-certificates, and bzip2 packages.

  • Local clock on time or slightly in the future for proper SSL communication.

  • This tutorial uses docker-compose to run a master, a worker, and a postgresql database server

1.3.2. Installation

  • Use the Docker installation instructions for your operating system.

  • Make sure you install docker-compose. As root or inside a virtualenv, run:

    pip install docker-compose
    
  • Test docker is happy in your environment:

    sudo docker run -i busybox /bin/echo Success
    

1.3.3. Building and running Buildbot

# clone the example repository
git clone --depth 1 https://github.com/buildbot/buildbot-docker-example-config

# Build the Buildbot container (it will take a few minutes to download packages)
cd buildbot-docker-example-config/simple
docker-compose up

You should now be able to go to http://localhost:8010 and see a web page similar to:

index page

Click on “Builds” at the left to open the submenu and then Builders to see that the worker you just started has connected to the master:

builder runtests is active.

1.3.4. Overview of the docker-compose configuration

This docker-compose configuration is made as a basis for what you would put in production

  • Separated containers for each component

  • A solid database backend with postgresql

  • A buildbot master that exposes its configuration to the docker host

  • A buildbot worker that can be cloned in order to add additional power

  • Containers are linked together so that the only port exposed to external is the web server

  • The default master container is based on Alpine linux for minimal footprint

  • The default worker container is based on more widely known Ubuntu distribution, as this is the container you want to customize.

  • Download the config from a tarball accessible via a web server

1.3.5. Playing with your Buildbot containers

If you’ve come this far, you have a Buildbot environment that you can freely experiment with.

In order to modify the configuration, you need to fork the project on github https://github.com/buildbot/buildbot-docker-example-config Then you can clone your own fork, and start the docker-compose again.

To modify your config, edit the master.cfg file, commit your changes, and push to your fork. You can use the command buildbot check-config in order to make sure the config is valid before the push. You will need to change docker-compose.yml the variable BUILDBOT_CONFIG_URL in order to point to your github fork.

The BUILDBOT_CONFIG_URL may point to a .tar.gz file accessible from HTTP. Several git servers like github can generate that tarball automatically from the master branch of a git repository If the BUILDBOT_CONFIG_URL does not end with .tar.gz, it is considered to be the URL to a master.cfg file accessible from HTTP.

1.3.6. Customize your Worker container

It is advised to customize you worker container in order to suit your project’s build dependencies and need. An example DockerFile is available which the buildbot community uses for its own CI purposes:

https://github.com/buildbot/metabbotcfg/blob/nine/docker/metaworker/Dockerfile

1.3.7. Multi-master

A multi-master environment can be setup using the multimaster/docker-compose.yml file in the example repository

# Build the Buildbot container (it will take a few minutes to download packages)
cd buildbot-docker-example-config/simple
docker-compose up -d
docker-compose scale buildbot=4

1.3.8. Going forward

You’ve got a taste now, but you’re probably curious for more. Let’s step it up a little in the second tutorial by changing the configuration and doing an actual build. Continue on to A Quick Tour.

1.4. Further Reading

See the following user-contributed tutorials for other highlights and ideas:

1.4.1. Buildbot in 5 minutes - a user-contributed tutorial

(Ok, maybe 10.)

Buildbot is really an excellent piece of software, however it can be a bit confusing for a newcomer (like me when I first started looking at it). Typically, at first sight, it looks like a bunch of complicated concepts that make no sense and whose relationships with each other are unclear. After some time and some reread, it all slowly starts to be more and more meaningful, until you finally say “oh!” and things start to make sense. Once you get there, you realize that the documentation is great, but only if you already know what it’s about.

This is what happened to me, at least. Here, I’m going to (try to) explain things in a way that would have helped me more as a newcomer. The approach I’m taking is more or less the reverse of that used by the documentation. That is, I’m going to start from the components that do the actual work (the builders) and go up the chain to the change sources. I hope purists will forgive this unorthodoxy. Here I’m trying to only clarify the concepts and not go into the details of each object or property; the documentation explains those quite well.

1.4.1.1. Installation

I won’t cover the installation; both Buildbot master and worker are available as packages for the major distributions, and in any case the instructions in the official documentation are fine. This document will refer to Buildbot 0.8.5 which was current at the time of writing, but hopefully the concepts are not too different in future versions. All the code shown is of course python code, and has to be included in the master.cfg configuration file.

We won’t cover basic things such as how to define the workers, project names, or other administrative information that is contained in that file; for that, again the official documentation is fine.

1.4.1.2. Builders: the workhorses

Since Buildbot is a tool whose goal is the automation of software builds, it makes sense to me to start from where we tell Buildbot how to build our software: the builder (or builders, since there can be more than one).

Simply put, a builder is an element that is in charge of performing some action or sequence of actions, normally something related to building software (for example, checking out the source, or make all), but it can also run arbitrary commands.

A builder is configured with a list of workers that it can use to carry out its task. The other fundamental piece of information that a builder needs is, of course, the list of things it has to do (which will normally run on the chosen worker). In Buildbot, this list of things is represented as a BuildFactory object, which is essentially a sequence of steps, each one defining a certain operation or command.

Enough talk, let’s see an example. For this example, we are going to assume that our super software project can be built using a simple make all, and there is another target make packages that creates rpm, deb and tgz packages of the binaries. In the real world things are usually more complex (for example there may be a configure step, or multiple targets), but the concepts are the same; it will just be a matter of adding more steps to a builder, or creating multiple builders, although sometimes the resulting builders can be quite complex.

So to perform a manual build of our project, we would type the following on the command line (assuming we are at the root of the local copy of the repository):

$ make clean    # clean remnants of previous builds
...
$ svn update
...
$ make all
...
$ make packages
...
# optional but included in the example: copy packages to some central machine
$ scp packages/*.rpm packages/*.deb packages/*.tgz someuser@somehost:/repository
...

Here we’re assuming the repository is SVN, but again the concepts are the same with git, mercurial or any other VCS.

Now, to automate this, we create a builder where each step is one of the commands we typed above. A step can be a shell command object, or a dedicated object that checks out the source code (there are various types for different repositories, see the docs for more info), or yet something else:

from buildbot.plugins import steps, util

# first, let's create the individual step objects

# step 1: make clean; this fails if the worker has no local copy, but
# is harmless and will only happen the first time
makeclean = steps.ShellCommand(name="make clean",
                               command=["make", "clean"],
                               description="make clean")

# step 2: svn update (here updates trunk, see the docs for more
# on how to update a branch, or make it more generic).
checkout = steps.SVN(baseURL='svn://myrepo/projects/coolproject/trunk',
                     mode="update",
                     username="foo",
                     password="bar",
                     haltOnFailure=True)

# step 3: make all
makeall = steps.ShellCommand(name="make all",
                             command=["make", "all"],
                             haltOnFailure=True,
                             description="make all")

# step 4: make packages
makepackages = steps.ShellCommand(name="make packages",
                                  command=["make", "packages"],
                                  haltOnFailure=True,
                                  description="make packages")

# step 5: upload packages to central server. This needs passwordless ssh
# from the worker to the server (set it up in advance as part of the worker setup)
uploadpackages = steps.ShellCommand(
    name="upload packages",
    description="upload packages",
    command="scp packages/*.rpm packages/*.deb packages/*.tgz someuser@somehost:/repository",
    haltOnFailure=True)

# create the build factory and add the steps to it
f_simplebuild = util.BuildFactory()
f_simplebuild.addStep(makeclean)
f_simplebuild.addStep(checkout)
f_simplebuild.addStep(makeall)
f_simplebuild.addStep(makepackages)
f_simplebuild.addStep(uploadpackages)

# finally, declare the list of builders. In this case, we only have one builder
c['builders'] = [
    util.BuilderConfig(name="simplebuild", workernames=['worker1', 'worker2', 'worker3'],
                       factory=f_simplebuild)
]

So our builder is called simplebuild and can run on either of worker1, worker2 or worker3. If our repository has other branches besides trunk, we could create another one or more builders to build them; in this example, only the checkout step would be different, in that it would need to check out the specific branch. Depending on how exactly those branches have to be built, the shell commands may be recycled, or new ones would have to be created if they are different in the branch. You get the idea. The important thing is that all the builders be named differently and all be added to the c['builders'] value (as can be seen above, it is a list of BuilderConfig objects).

Of course the type and number of steps will vary depending on the goal; for example, to just check that a commit doesn’t break the build, we could include just up to the make all step. Or we could have a builder that performs a more thorough test by also doing make test or other targets. You get the idea. Note that at each step except the very first we use haltOnFailure=True because it would not make sense to execute a step if the previous one failed (ok, it wouldn’t be needed for the last step, but it’s harmless and protects us if one day we add another step after it).

1.4.1.3. Schedulers

Now this is all nice and dandy, but who tells the builder (or builders) to run, and when? This is the job of the scheduler which is a fancy name for an element that waits for some event to happen, and when it does, based on that information, decides whether and when to run a builder (and which one or ones). There can be more than one scheduler. I’m being purposely vague here because the possibilities are almost endless and highly dependent on the actual setup, build purposes, source repository layout and other elements.

So a scheduler needs to be configured with two main pieces of information: on one hand, which events to react to, and on the other hand, which builder or builders to trigger when those events are detected. (It’s more complex than that, but if you understand this, you can get the rest of the details from the docs).

A simple type of scheduler may be a periodic scheduler that runs a certain builder (or builders) when a configurable amount of time has passed. In our example, that’s how we would trigger a build every hour:

from buildbot.plugins import schedulers

# define the periodic scheduler
hourlyscheduler = schedulers.Periodic(name="hourly",
                                      builderNames=["simplebuild"],
                                      periodicBuildTimer=3600)

# define the available schedulers
c['schedulers'] = [hourlyscheduler]

That’s it. Every hour this hourly scheduler will run the simplebuild builder. If we have more than one builder that we want to run every hour, we can just add them to the builderNames list when defining the scheduler. Or since multiple schedulers are allowed, other schedulers can be defined and added to c['schedulers'] in the same way.

Other types of schedulers exist; in particular, there are schedulers that can be more dynamic than the periodic one. The typical dynamic scheduler is one that learns about changes in a source repository (generally because some developer checks in some change) and triggers one or more builders in response to those changes. Let’s assume for now that the scheduler “magically” learns about changes in the repository (more about this later); here’s how we would define it:

from buildbot.plugins import schedulers

# define the dynamic scheduler
trunkchanged = schedulers.SingleBranchScheduler(name="trunkchanged",
                                                change_filter=util.ChangeFilter(branch=None),
                                                treeStableTimer=300,
                                                builderNames=["simplebuild"])

# define the available schedulers
c['schedulers'] = [trunkchanged]

This scheduler receives changes happening to the repository, and among all of them, pays attention to those happening in “trunk” (that’s what branch=None means). In other words, it filters the changes to react only to those it’s interested in. When such changes are detected, and the tree has been quiet for 5 minutes (300 seconds), it runs the simplebuild builder. The treeStableTimer helps in those situations where commits tend to happen in bursts, which would otherwise result in multiple build requests queuing up.

What if we want to act on two branches (say, trunk and 7.2)? First, we create two builders, one for each branch, and then we create two dynamic schedulers:

from buildbot.plugins import schedulers

# define the dynamic scheduler for trunk
trunkchanged = schedulers.SingleBranchScheduler(name="trunkchanged",
                                                change_filter=util.ChangeFilter(branch=None),
                                                treeStableTimer=300,
                                                builderNames=["simplebuild-trunk"])

# define the dynamic scheduler for the 7.2 branch
branch72changed = schedulers.SingleBranchScheduler(
    name="branch72changed",
    change_filter=util.ChangeFilter(branch='branches/7.2'),
    treeStableTimer=300,
    builderNames=["simplebuild-72"])

# define the available schedulers
c['schedulers'] = [trunkchanged, branch72changed]

The syntax of the change filter is VCS-dependent (above is for SVN), but again, once the idea is clear, the documentation has all the details. Another feature of the scheduler is that it can be told which changes, within those it’s paying attention to, are important and which are not. For example, there may be a documentation directory in the branch the scheduler is watching, but changes under that directory should not trigger a build of the binary. This finer filtering is implemented by means of the fileIsImportant argument to the scheduler (full details in the docs and - alas - in the sources).

1.4.1.4. Change sources

Earlier, we said that a dynamic scheduler “magically” learns about changes; the final piece of the puzzle is change sources, which are precisely the elements in Buildbot whose task is to detect changes in a repository and communicate them to the schedulers. Note that periodic schedulers don’t need a change source since they only depend on elapsed time; dynamic schedulers, on the other hand, do need a change source.

A change source is generally configured with information about a source repository (which is where changes happen). A change source can watch changes at different levels in the hierarchy of the repository, so for example, it is possible to watch the whole repository or a subset of it, or just a single branch. This determines the extent of the information that is passed down to the schedulers.

There are many ways a change source can learn about changes; it can periodically poll the repository for changes, or the VCS can be configured (for example through hook scripts triggered by commits) to push changes into the change source. While these two methods are probably the most common, they are not the only possibilities. It is possible, for example, to have a change source detect changes by parsing an email sent to a mailing list when a commit happens. Yet other methods exist and the manual again has the details.

To complete our example, here’s a change source that polls a SVN repository every 2 minutes:

from buildbot.plugins import changes, util

svnpoller = changes.SVNPoller(repourl="svn://myrepo/projects/coolproject",
                              svnuser="foo",
                              svnpasswd="bar",
                              pollinterval=120,
                              split_file=util.svn.split_file_branches)

c['change_source'] = svnpoller

This poller watches the whole “coolproject” section of the repository, so it will detect changes in all the branches. We could have said:

repourl = "svn://myrepo/projects/coolproject/trunk"

or:

repourl = "svn://myrepo/projects/coolproject/branches/7.2"

to watch only a specific branch.

To watch another project, you need to create another change source, and you need to filter changes by project. For instance, when you add a change source watching project ‘superproject’ to the above example, you need to change the original scheduler from:

trunkchanged = schedulers.SingleBranchScheduler(
    name="trunkchanged",
    change_filter=filter.ChangeFilter(branch=None),
    # ...
    )

to e.g.:

trunkchanged = schedulers.SingleBranchScheduler(
    name="trunkchanged",
    change_filter=filter.ChangeFilter(project="coolproject", branch=None),
    # ...
    )

otherwise, coolproject will be built when there’s a change in superproject.

Since we’re watching more than one branch, we need a method to tell in which branch the change occurred when we detect one. This is what the split_file argument does, it takes a callable that Buildbot will call to do the job. The split_file_branches function, which comes with Buildbot, is designed for exactly this purpose so that’s what the example above uses.

And of course this is all SVN-specific, but there are pollers for all the popular VCSs.

Note that if you have many projects, branches, and builders, it probably pays not to hardcode all the schedulers and builders in the configuration, but generate them dynamically starting from the list of all projects, branches, targets, etc, and using loops to generate all possible combinations (or only the needed ones, depending on the specific setup), as explained in the documentation chapter about Customization.

1.4.1.5. Reporters

Now that the basics are in place, let’s go back to the builders, which is where the real work happens. Reporters are simply the means Buildbot uses to inform the world about what’s happening, that is, how builders are doing. There are many reporters: a mail notifier, an IRC notifier, and others. They are described fairly well in the manual.

One thing I’ve found useful is the ability to pass a domain name as the lookup argument to a mailNotifier, which allows you to take an unqualified username as it appears in the SVN change and create a valid email address by appending the given domain name to it:

from buildbot.plugins import reporter

# if jsmith commits a change, an email for the build is sent to jsmith@example.org
notifier = reporter.MailNotifier(fromaddr="buildbot@example.org",
                               sendToInterestedUsers=True,
                               lookup="example.org")
c['reporters'].append(notifier)

The mail notifier can be customized at will by means of the messageFormatter argument, which is a class that Buildbot calls to format the body of the email, and to which it makes available lots of information about the build. For more details, look into the Reporters section of the Buildbot manual.

1.4.1.6. Conclusion

Please note that this article has just scratched the surface; given the complexity of the task of build automation, the possibilities are almost endless. So there’s much much more to say about Buildbot. Hopefully this has been a gentle introduction before reading the official manual. Had I found an explanation as the one above when I was approaching Buildbot, I’d have had to read the manual just once, rather than multiple times. I hope this can help someone else.

(Thanks to Davide Brini for permission to include this tutorial, derived from one he originally posted at http://backreference.org .)

This is the Buildbot manual for Buildbot version 3.9.1.

2. Buildbot Manual

2.1. Introduction

Buildbot is a framework to automate the compile and test cycle that is used to validate code changes in most software projects.

Features:

  • run builds on a variety of worker platforms

  • arbitrary build process: handles projects using C, Python, whatever

  • minimal host requirements: Python and Twisted

  • workers can be behind a firewall if they can still do checkout

  • status delivery through web page, email, IRC, other protocols

  • flexible configuration by subclassing generic build process classes

  • debug tools to force a new build, submit fake Changes, query worker status

  • released under the GPL

2.1.1. System Architecture

Buildbot consists of a single buildmaster and one or more workers that connect to the master. The buildmaster makes all decisions about what, when, and how to build. The workers only connect to master and execute whatever commands they are instructed to execute.

The usual flow of information is as follows:

  • the buildmaster fetches new code changes from version control systems

  • the buildmaster decides what builds (if any) to start

  • the builds are performed by executing commands on the workers (e.g. git clone, make, make check).

  • the workers send the results of the commands back to the buildmaster

  • buildmaster interprets the results of the commands and marks the builds as successful or failing

  • buildmaster sends success or failure reports to external services to e.g. inform the developers.

Overview Diagram
2.1.1.1. Worker Connections

The workers connect to the buildmaster over a TCP connection to a publicly-visible port. This allows workers to live behind a NAT or similar firewalls as long as they can get to buildmaster. After the connection is established, the connection is bidirectional: commands flow from the buildmaster to the worker and results flow from the worker to the buildmaster.

The buildmaster does not provide the workers with the source code itself, only with commands necessary to perform the source code checkout. As a result, the workers need to be able to reach the source code repositories that they are supposed to build.

Worker Connections
2.1.1.2. Buildmaster Architecture

The following is rough overview of the data flow within the buildmaster.

Buildmaster Architecture

The following provides a short overview of the core components of Buildbot master. For a more detailed description see the Concepts page.

The core components of Buildbot master are as follows:

Builders

A builder is a user-configurable description of how to perform a build. It defines what steps a new build will have, what workers it may run on and a couple of other properties. A builder takes a build request which specifies the intention to create a build for specific versions of code and produces a build which is a concrete description of a build including a list of steps to perform, the worker this needs to be performed on and so on.

Schedulers:

A scheduler is a user-configurable component that decides when to start a build. The decision could be based on time, on new code being committed or on similar events.

Change Sources:

Change sources are user-configurable components that interact with external version control systems and retrieve new code. Internally new code is represented as Changes which roughly correspond to single commit or changeset. The design of Buildbot requires the workers to have their own copies of the source code, thus change sources is an optional component as long as there are no schedulers that create new builds based on new code commit events.

Reporters

Reporters are user-configurable components that send information about started or completed builds to external sources. Buildbot provides its own web application to observe this data, so reporters are optional. However they can be used to provide up to date build status on platforms such as GitHub or sending emails.

2.2. Installation

2.2.1. Buildbot Components

Buildbot is shipped in two components: the buildmaster (called buildbot for legacy reasons) and the worker. The worker component has far fewer requirements, and is more broadly compatible than the buildmaster. You will need to carefully pick the environment in which to run your buildmaster, but the worker should be able to run just about anywhere.

It is possible to install the buildmaster and worker on the same system, although for anything but the smallest installation this arrangement will not be very efficient.

2.2.2. Requirements

2.2.2.1. Common Requirements

At a bare minimum, you’ll need the following for both the buildmaster and a worker:

Python: https://www.python.org

Buildbot master works with Python-3.6+. Buildbot worker works with Python 2.7, or Python 3.5+.

Note

This should be a “normal” build of Python. Builds of Python with debugging enabled or other unusual build parameters are likely to cause incorrect behavior.

Twisted: http://twistedmatrix.com

Buildbot requires Twisted-17.9.0 or later on the master and the worker. In upcoming versions of Buildbot, a newer Twisted will also be required on the worker. As always, the most recent version is recommended.

Certifi: https://github.com/certifi/python-certifi

Certifi provides collection of Root Certificates for validating the trustworthiness of SSL certificates. Unfortunately it does not support any addition of own company certificates. At the moment you need to add your own .PEM content to cacert.pem manually.

Of course, your project’s build process will impose additional requirements on the workers. These hosts must have all the tools necessary to compile and test your project’s source code.

Note

If your internet connection is secured by a proxy server, please check your http_proxy and https_proxy environment variables. Otherwise pip and other tools will fail to work.

Windows Support

Buildbot - both master and worker - runs well natively on Windows. The worker runs well on Cygwin, but because of problems with SQLite on Cygwin, the master does not.

Buildbot’s windows testing is limited to the most recent Twisted and Python versions. For best results, use the most recent available versions of these libraries on Windows.

Pywin32: http://sourceforge.net/projects/pywin32/

Twisted requires PyWin32 in order to spawn processes on Windows.

Build Tools for Visual Studio 2019 - Microsoft Visual C++ compiler

Twisted requires MSVC to compile some parts like tls during the installation, see https://twistedmatrix.com/trac/wiki/WindowsBuilds and https://wiki.python.org/moin/WindowsCompilers.

2.2.2.2. Buildmaster Requirements

Note that all of these requirements aside from SQLite can easily be installed from the Python package repository, PyPI.

sqlite3: http://www.sqlite.org

Buildbot requires a database to store its state, and by default uses SQLite. Version 3.7.0 or higher is recommended, although Buildbot will run down to 3.6.16 – at the risk of “Database is locked” errors. The minimum version is 3.4.0, below which parallel database queries and schema introspection fail.

Please note that Python ships with sqlite3 by default since Python 2.6.

If you configure a different database engine, then SQLite is not required. however note that Buildbot’s own unit tests require SQLite.

Jinja2: http://jinja.pocoo.org/

Buildbot requires Jinja version 2.1 or higher.

Jinja2 is a general purpose templating language and is used by Buildbot to generate the HTML output.

SQLAlchemy: http://www.sqlalchemy.org/

Buildbot requires SQLAlchemy version 1.3.0 or higher. SQLAlchemy allows Buildbot to build database schemas and queries for a wide variety of database systems.

Alembic: https://alembic.sqlalchemy.org/en/latest/

Buildbot requires Alembic version 1.6.0 or higher. Buildbot uses Alembic to manage schema upgrades from version to version.

Python-Dateutil: http://labix.org/python-dateutil

Buildbot requires Python-Dateutil in version 1.5 or higher (the last version to support Python-2.x). This is a small, pure-Python library.

Autobahn:

The master requires Autobahn version 0.16.0 or higher with Python 2.7.

txrequests: https://github.com/tardyp/txrequests or treq: https://github.com/twisted/treq

Both libraries are optional, but a lot of Buildbot plugins assume that one of it is installed. Otherwise plugins will complain in the twisted log file if it is not installed. Here is a little comparison table:

txrequests

treq

International Domains and URLs

yes

yes

Keep-Alive & Connection Pooling

yes

yes

Sessions with Cookie Persistence

yes

yes

Browser-style SSL Verification

yes

yes

Basic Authentication

yes

yes

Digest Authentication

yes

no

Elegant Key/Value Cookies

yes

yes

Automatic Decompression

yes

yes

Unicode Response Bodies

yes

yes

Multi-part File Uploads

yes

yes

Connection Timeouts

yes

yes

HTTP(S) Proxy Support

yes

no

.netrc support

yes

no

Python 2.7

yes

yes

Python 3.x

yes

yes

Speed

slower

fast

2.2.3. Installing the code

2.2.3.1. The Buildbot Packages

Buildbot comes in several parts: buildbot (the buildmaster), buildbot-worker (the worker), buildbot-www, and several web plugins such as buildbot-waterfall-view.

The worker and buildmaster can be installed individually or together. The base web (buildbot.www) and web plugins are required to run a master with a web interface (the common configuration).

2.2.3.2. Installation From PyPI

The preferred way to install Buildbot is using pip. For the master:

pip install buildbot

and for the worker:

pip install buildbot-worker

When using pip to install, instead of distribution specific package managers, e.g. via apt or ports, it is simpler to choose exactly which version one wants to use. It may however be easier to install via distribution specific package managers, but note that they may provide an earlier version than what is available via pip.

If you plan to use TLS or SSL in master configuration (e.g. to fetch resources over HTTPS using twisted.web.client), you need to install Buildbot with tls extras:

pip install buildbot[tls]
2.2.3.3. Installation From Tarballs

Buildbot master and buildbot-worker are installed using the standard Python distutils process. For either component, after unpacking the tarball, the process is:

python setup.py build
python setup.py install

where the install step may need to be done as root. This will put the bulk of the code in somewhere like /usr/lib/pythonx.y/site-packages/buildbot. It will also install the buildbot command-line tool in /usr/bin/buildbot.

If the environment variable $NO_INSTALL_REQS is set to 1, then setup.py will not try to install Buildbot’s requirements. This is usually only useful when building a Buildbot package.

To test this, shift to a different directory (like /tmp), and run:

buildbot --version
# or
buildbot-worker --version

If it shows you the versions of Buildbot and Twisted, the install went ok. If it says “no such command” or gets an ImportError when it tries to load the libraries, then something went wrong. pydoc buildbot is another useful diagnostic tool.

Windows users will find these files in other places. You will need to make sure that Python can find the libraries, and will probably find it convenient to have buildbot in your PATH.

2.2.3.4. Installation in a Virtualenv

If you cannot or do not wish to install buildbot into a site-wide location like /usr or /usr/local, you can also install it into the account’s home directory or any other location using a tool like virtualenv.

2.2.3.5. Running Buildbot’s Tests (optional)

If you wish, you can run the buildbot unit test suite. First, ensure that you have the mock Python module installed from PyPI. You must not be using a Python wheels packaged version of Buildbot or have specified the bdist_wheel command when building. The test suite is not included with the PyPi packaged version. This module is not required for ordinary Buildbot operation - only to run the tests. Note that this is not the same as the Fedora mock package!

You can check if you have mock with:

python -mmock

Then, run the tests:

PYTHONPATH=. trial buildbot.test
# or
PYTHONPATH=. trial buildbot_worker.test

Nothing should fail, although a few might be skipped.

If any of the tests fail for reasons other than a missing mock, you should stop and investigate the cause before continuing the installation process, as it will probably be easier to track down the bug early. In most cases, the problem is incorrectly installed Python modules or a badly configured PYTHONPATH. This may be a good time to contact the Buildbot developers for help.

2.2.4. Buildmaster Setup

2.2.4.1. Creating a buildmaster

As you learned earlier (System Architecture), the buildmaster runs on a central host (usually one that is publicly visible, so everybody can check on the status of the project), and controls all aspects of the buildbot system

You will probably wish to create a separate user account for the buildmaster, perhaps named buildmaster. Do not run the buildmaster as root!

You need to choose a directory for the buildmaster, called the basedir. This directory will be owned by the buildmaster. It will contain the configuration, database, and status information - including logfiles. On a large buildmaster this directory will see a lot of activity, so it should be on a disk with adequate space and speed.

Once you’ve picked a directory, use the buildbot create-master command to create the directory and populate it with startup files:

buildbot create-master -r basedir

You will need to create a configuration file before starting the buildmaster. Most of the rest of this manual is dedicated to explaining how to do this. A sample configuration file is placed in the working directory, named master.cfg.sample, which can be copied to master.cfg and edited to suit your purposes.

(Internal details: This command creates a file named buildbot.tac that contains all the state necessary to create the buildmaster. Twisted has a tool called twistd which can use this .tac file to create and launch a buildmaster instance. Twistd takes care of logging and daemonization (running the program in the background). /usr/bin/buildbot is a front end which runs twistd for you.)

Your master will need a database to store the various information about your builds, and its configuration. By default, the sqlite3 backend will be used. This needs no configuration, neither extra software. All information will be stored in the file state.sqlite. Buildbot however supports multiple backends. See Using A Database Server for more options.

Buildmaster Options

This section lists options to the create-master command. You can also type buildbot create-master --help for an up-to-the-moment summary.

--force

This option will allow to re-use an existing directory.

--no-logrotate

This disables internal worker log management mechanism. With this option worker does not override the default logfile name and its behaviour giving a possibility to control those with command-line options of twistd daemon.

--relocatable

This creates a “relocatable” buildbot.tac, which uses relative paths instead of absolute paths, so that the buildmaster directory can be moved about.

--config

The name of the configuration file to use. This configuration file need not reside in the buildmaster directory.

--log-size

This is the size in bytes when exceeded to rotate the Twisted log files. The default is 10MiB.

--log-count

This is the number of log rotations to keep around. You can either specify a number or None to keep all twistd.log files around. The default is 10.

--db

The database that the Buildmaster should use. Note that the same value must be added to the configuration file.

2.2.5. Worker Setup

2.2.5.1. Creating a worker

Typically, you will be adding a worker to an existing buildmaster, to provide additional architecture coverage. The Buildbot administrator will give you several pieces of information necessary to connect to the buildmaster. You should also be somewhat familiar with the project being tested so that you can troubleshoot build problems locally.

Buildbot exists to make sure that the project’s stated how to build it process actually works. To this end, the worker should run in an environment just like that of your regular developers. Typically the project’s build process is documented somewhere (README, INSTALL, etc), in a document that should mention all library dependencies and contain a basic set of build instructions. This document will be useful as you configure the host and account in which worker runs.

Here’s a good checklist for setting up a worker:

  1. Set up the account

It is recommended (although not mandatory) to set up a separate user account for the worker. This account is frequently named buildbot or worker. This serves to isolate your personal working environment from that of the worker’s, and helps to minimize the security threat posed by letting possibly-unknown contributors run arbitrary code on your system. The account should have a minimum of fancy init scripts.

  1. Install the Buildbot code

Follow the instructions given earlier (Installing the code). If you use a separate worker account, and you didn’t install the Buildbot code to a shared location, then you will need to install it with --home=~ for each account that needs it.

  1. Set up the host

Make sure the host can actually reach the buildmaster. Usually the buildmaster is running a status webserver on the same machine, so simply point your web browser at it and see if you can get there. Install whatever additional packages or libraries the project’s INSTALL document advises. (or not: if your worker is supposed to make sure that building without optional libraries still works, then don’t install those libraries.)

Again, these libraries don’t necessarily have to be installed to a site-wide shared location, but they must be available to your build process. Accomplishing this is usually very specific to the build process, so installing them to /usr or /usr/local is usually the best approach.

  1. Test the build process

Follow the instructions in the INSTALL document, in the worker’s account. Perform a full CVS (or whatever) checkout, configure, make, run tests, etc. Confirm that the build works without manual fussing. If it doesn’t work when you do it manually, it will be unlikely to work when Buildbot attempts to do it in an automated fashion.

  1. Choose a base directory

This should be somewhere in the worker’s account, typically named after the project which is being tested. The worker will not touch any file outside of this directory. Something like ~/Buildbot or ~/Workers/fooproject is appropriate.

  1. Get the buildmaster host/port, workername, and password

When the Buildbot admin configures the buildmaster to accept and use your worker, they will provide you with the following pieces of information:

  • your worker’s name

  • the password assigned to your worker

  • the hostname and port number of the buildmaster

  1. Create the worker

Now run the ‘worker’ command as follows:

buildbot-worker create-worker BASEDIR MASTERHOST:PORT WORKERNAME PASSWORD

This will create the base directory and a collection of files inside, including the buildbot.tac file that contains all the information you passed to the buildbot-worker command.

  1. Fill in the hostinfo files

When it first connects, the worker will send a few files up to the buildmaster which describe the host that it is running on. These files are presented on the web status display so that developers have more information to reproduce any test failures that are witnessed by the Buildbot. There are sample files in the info subdirectory of the Buildbot’s base directory. You should edit these to correctly describe you and your host.

BASEDIR/info/admin should contain your name and email address. This is the worker admin address, and will be visible from the build status page (so you may wish to munge it a bit if address-harvesting spambots are a concern).

BASEDIR/info/host should be filled with a brief description of the host: OS, version, memory size, CPU speed, versions of relevant libraries installed, and finally the version of the Buildbot code which is running the worker.

The optional BASEDIR/info/access_uri can specify a URI which will connect a user to the machine. Many systems accept ssh://hostname URIs for this purpose.

If you run many workers, you may want to create a single ~worker/info file and share it among all the workers with symlinks.

Worker Options

There are a handful of options you might want to use when creating the worker with the buildbot-worker create-worker <options> DIR <params> command. You can type buildbot-worker create-worker --help for a summary. To use these, just include them on the buildbot-worker create-worker command line, like this

buildbot-worker create-worker --umask=0o22 ~/worker buildmaster.example.org:42012 \
    {myworkername} {mypasswd}
--protocol

This is a string representing a protocol to be used when creating master-worker connection. The default option is Perspective Broker (pb).

--no-logrotate

This disables internal worker log management mechanism. With this option worker does not override the default logfile name and its behaviour giving a possibility to control those with command-line options of twistd daemon.

--umask

This is a string (generally an octal representation of an integer) which will cause the worker process’ umask value to be set shortly after initialization. The twistd daemonization utility forces the umask to 077 at startup (which means that all files created by the worker or its child processes will be unreadable by any user other than the worker account). If you want build products to be readable by other accounts, you can add --umask=0o22 to tell the worker to fix the umask after twistd clobbers it. If you want build products to be writable by other accounts too, use --umask=0o000, but this is likely to be a security problem.

--keepalive

This is a number that indicates how frequently keepalive messages should be sent from the worker to the buildmaster, expressed in seconds. The default (600) causes a message to be sent to the buildmaster at least once every 10 minutes. To set this to a lower value, use e.g. --keepalive=120.

If the worker is behind a NAT box or stateful firewall, these messages may help to keep the connection alive: some NAT boxes tend to forget about a connection if it has not been used in a while. When this happens, the buildmaster will think that the worker has disappeared, and builds will time out. Meanwhile the worker will not realize that anything is wrong.

--maxdelay

This is a number that indicates the maximum amount of time the worker will wait between connection attempts, expressed in seconds. The default (300) causes the worker to wait at most 5 minutes before trying to connect to the buildmaster again.

--maxretries

This is a number that indicates the maximum number of times the worker will make connection attempts. After that amount, the worker process will stop. This option is useful for Latent Workers to avoid consuming resources in case of misconfiguration or master failure.

For VM based latent workers, the user is responsible for halting the system when the Buildbot worker has exited. This feature is heavily OS dependent, and cannot be managed by the Buildbot worker. For example, with systemd, one can add ExecStopPost=shutdown now to the Buildbot worker service unit configuration.

--log-size

This is the size in bytes when exceeded to rotate the Twisted log files.

--log-count

This is the number of log rotations to keep around. You can either specify a number or None to keep all twistd.log files around. The default is 10.

--allow-shutdown

Can also be passed directly to the worker constructor in buildbot.tac. If set, it allows the worker to initiate a graceful shutdown, meaning that it will ask the master to shut down the worker when the current build, if any, is complete.

Setting allow_shutdown to file will cause the worker to watch shutdown.stamp in basedir for updates to its mtime. When the mtime changes, the worker will request a graceful shutdown from the master. The file does not need to exist prior to starting the worker.

Setting allow_shutdown to signal will set up a SIGHUP handler to start a graceful shutdown. When the signal is received, the worker will request a graceful shutdown from the master.

The default value is None, in which case this feature will be disabled.

Both master and worker must be at least version 0.8.3 for this feature to work.

--use-tls

Can also be passed directly to the Worker constructor in buildbot.tac. If set, the generated connection string starts with tls instead of with tcp, allowing encrypted connection to the buildmaster. Make sure the worker trusts the buildmasters certificate. If you have an non-authoritative certificate (CA is self-signed) see connection_string below.

--delete-leftover-dirs

Can also be passed directly to the Worker constructor in buildbot.tac. If set, unexpected directories in worker base directory will be removed. Otherwise, a warning will be displayed in twistd.log so that you can manually remove them.

--proxy-connection-string

Can also be passed directly to the Worker constructor in buildbot.tac. If set, the worker connection will be tunneled through a HTTP proxy specified by the option value.

Other Worker Configuration
unicode_encoding

This represents the encoding that Buildbot should use when converting unicode commandline arguments into byte strings in order to pass to the operating system when spawning new processes.

The default value is what Python’s sys.getfilesystemencoding returns, which on Windows is ‘mbcs’, on Mac OSX is ‘utf-8’, and on Unix depends on your locale settings.

If you need a different encoding, this can be changed in your worker’s buildbot.tac file by adding a unicode_encoding argument to the Worker constructor.

s = Worker(buildmaster_host, port, workername, passwd, basedir,
           keepalive, usepty, umask=umask, maxdelay=maxdelay,
           unicode_encoding='utf-8', allow_shutdown='signal')
Worker TLS Configuration
tls

See --useTls option above as an alternative to setting the conneciton_string manually.

connection_string

For TLS connections to the master, the connection_string-argument must be passed to the worker constructor. buildmaster_host and port must then be None.

connection_string will be used to create a client endpoint with clientFromString. An example of connection_string is "TLS:buildbot-master.com:9989".

See more about how to formulate the connection string in ConnectionStrings.

Example TLS connection string:

s = Worker(None, None, workername, passwd, basedir, keepalive,
           connection_string='TLS:buildbot-master.com:9989')

Make sure the worker trusts the certificate of the master. If you have a non-authoritative certificate (CA is self-signed), the trustRoots parameter can be used.

s = Worker(None, None, workername, passwd, basedir, keepalive,
           connection_string=
           'TLS:buildbot-master.com:9989:trustRoots=/dir-with-ca-certs')

It must point to a directory with PEM-encoded certificates. For example:

$ cat /dir-with-ca-certs/ca.pem
-----BEGIN CERTIFICATE-----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-----END CERTIFICATE-----

Using TCP in connection_string is the equivalent to using the buildmaster_host and port arguments.

s = Worker(None, None, workername, passwd, basedir, keepalive
           connection_string='TCP:buildbot-master.com:9989')

is equivalent to

s = Worker('buildbot-master.com', 9989, workername, passwd, basedir,
           keepalive)

2.2.6. Next Steps

2.2.6.1. Launching the daemons

Both the buildmaster and the worker run as daemon programs. To launch them, pass the working directory to the buildbot and buildbot-worker commands, as appropriate:

# start a master
buildbot start [ BASEDIR ]
# start a worker
buildbot-worker start [ WORKER_BASEDIR ]

The BASEDIR is optional and can be omitted if the current directory contains the buildbot configuration (the buildbot.tac file).

buildbot start

This command will start the daemon and then return, so normally it will not produce any output. To verify that the programs are indeed running, look for a pair of files named twistd.log and twistd.pid that should be created in the working directory. twistd.pid contains the process ID of the newly-spawned daemon.

When the worker connects to the buildmaster, new directories will start appearing in its base directory. The buildmaster tells the worker to create a directory for each Builder which will be using that worker. All build operations are performed within these directories: CVS checkouts, compiles, and tests.

Once you get everything running, you will want to arrange for the buildbot daemons to be started at boot time. One way is to use cron, by putting them in a @reboot crontab entry [1]

@reboot buildbot start [ BASEDIR ]

When you run crontab to set this up, remember to do it as the buildmaster or worker account! If you add this to your crontab when running as your regular account (or worse yet, root), then the daemon will run as the wrong user, quite possibly as one with more authority than you intended to provide.

It is important to remember that the environment provided to cron jobs and init scripts can be quite different than your normal runtime. There may be fewer environment variables specified, and the PATH may be shorter than usual. It is a good idea to test out this method of launching the worker by using a cron job with a time in the near future, with the same command, and then check twistd.log to make sure the worker actually started correctly. Common problems here are for /usr/local or ~/bin to not be on your PATH, or for PYTHONPATH to not be set correctly. Sometimes HOME is messed up too. If using systemd to launch buildbot-worker, it may be a good idea to specify a fixed PATH using the Environment directive (see systemd unit file example).

Some distributions may include conveniences to make starting buildbot at boot time easy. For instance, with the default buildbot package in Debian-based distributions, you may only need to modify /etc/default/buildbot (see also /etc/init.d/buildbot, which reads the configuration in /etc/default/buildbot).

Buildbot also comes with its own init scripts that provide support for controlling multi-worker and multi-master setups (mostly because they are based on the init script from the Debian package). With a little modification, these scripts can be used on both Debian and RHEL-based distributions. Thus, they may prove helpful to package maintainers who are working on buildbot (or to those who haven’t yet split buildbot into master and worker packages).

# install as /etc/default/buildbot-worker
#         or /etc/sysconfig/buildbot-worker
worker/contrib/init-scripts/buildbot-worker.default

# install as /etc/default/buildmaster
#         or /etc/sysconfig/buildmaster
master/contrib/init-scripts/buildmaster.default

# install as /etc/init.d/buildbot-worker
worker/contrib/init-scripts/buildbot-worker.init.sh

# install as /etc/init.d/buildmaster
master/contrib/init-scripts/buildmaster.init.sh

# ... and tell sysvinit about them
chkconfig buildmaster reset
# ... or
update-rc.d buildmaster defaults
2.2.6.2. Launching worker as Windows service

Security consideration

Setting up the buildbot worker as a Windows service requires Windows administrator rights. It is important to distinguish installation stage from service execution. It is strongly recommended run Buildbot worker with lowest required access rights. It is recommended run a service under machine local non-privileged account.

If you decide run Buildbot worker under domain account it is recommended to create dedicated strongly limited user account that will run Buildbot worker service.

Windows service setup

In this description, we assume that the buildbot worker account is the local domain account worker.

In case worker should run under domain user account please replace .\worker with <domain>\worker. Please replace <worker.passwd> with given user password. Please replace <worker.basedir> with the full/absolute directory specification to the created worker (what is called BASEDIR in Creating a worker).

buildbot_worker_windows_service --user .\worker --password <worker.passwd> --startup auto install
powershell -command "& {&'New-Item' -path Registry::HKEY_LOCAL_MACHINE\SYSTEM\CurrentControlSet\services\BuildBot\Parameters}"
powershell -command "& {&'set-ItemProperty' -path Registry::HKEY_LOCAL_MACHINE\SYSTEM\CurrentControlSet\services\BuildBot\Parameters -Name directories -Value '<worker.basedir>'}"

The first command automatically adds user rights to run Buildbot as service.

Modify environment variables

This step is optional and may depend on your needs. At least we have found useful to have dedicated temp folder worker steps. It is much easier discover what temporary files your builds leaks/misbehaves.

  1. As Administrator run regedit

  2. Open the key Computer\HKEY_LOCAL_MACHINE\SYSTEM\CurrentControlSet\Services\Buildbot.

  3. Create a new value of type REG_MULTI_SZ called Environment.

  4. Add entries like

TMP=c:\bbw\tmp
TEMP=c:\bbw\tmp
Check if Buildbot can start correctly configured as Windows service

As admin user run the command net start buildbot. In case everything goes well, you should see following output

The BuildBot service is starting.
The BuildBot service was started successfully.
Troubleshooting

If anything goes wrong check

  • Twisted log on C:\bbw\worker\twistd.log

  • Windows system event log (eventvwr.msc in command line, Show-EventLog in PowerShell).

2.2.6.3. Logfiles

While a buildbot daemon runs, it emits text to a logfile, named twistd.log. A command like tail -f twistd.log is useful to watch the command output as it runs.

The buildmaster will announce any errors with its configuration file in the logfile, so it is a good idea to look at the log at startup time to check for any problems. Most buildmaster activities will cause lines to be added to the log.

2.2.6.4. Shutdown

To stop a buildmaster or worker manually, use:

buildbot stop [ BASEDIR ]
# or
buildbot-worker stop [ WORKER_BASEDIR ]

This simply looks for the twistd.pid file and kills whatever process is identified within.

At system shutdown, all processes are sent a SIGKILL. The buildmaster and worker will respond to this by shutting down normally.

The buildmaster will respond to a SIGHUP by re-reading its config file. Of course, this only works on Unix-like systems with signal support and not on Windows. The following shortcut is available:

buildbot reconfig [ BASEDIR ]

When you update the Buildbot code to a new release, you will need to restart the buildmaster and/or worker before they can take advantage of the new code. You can do a buildbot stop BASEDIR and buildbot start BASEDIR in succession, or you can use the restart shortcut, which does both steps for you:

buildbot restart [ BASEDIR ]

Workers can similarly be restarted with:

buildbot-worker restart [ BASEDIR ]

There are certain configuration changes that are not handled cleanly by buildbot reconfig. If this occurs, buildbot restart is a more robust way to fully switch over to the new configuration.

buildbot restart may also be used to start a stopped Buildbot instance. This behavior is useful when writing scripts that stop, start, and restart Buildbot.

A worker may also be gracefully shutdown from the web UI. This is useful to shutdown a worker without interrupting any current builds. The buildmaster will wait until the worker has finished all its current builds, and will then tell the worker to shutdown.

2.3. Concepts

This chapter defines some of the basic concepts that Buildbot uses. You’ll need to understand how Buildbot sees the world to configure it properly.

2.3.1. Source identification

The following concepts are used within Buildbot to describe source code that is being built:

Repository

A repository is a location where files tracked by a version control system reside. Usually, it is identified by a URL or a location on a disk. It contains a subset of the history of a codebase.

Codebase

A codebase is a collection of related files and their history tracked as a unit by version control systems. The files and their history are stored in one or more repositories. For example, the primary repository for the Buildbot codebase is at https://github.com/buildbot/buildbot/. There are also more than a thousand forks of Buildbot. These repositories, while storing potentially very old versions of Buildbot code, still contain the same codebase.

Project

A project is a set of one or more codebases that together may be built and produce some end artifact. For example, an application may be comprised of two codebases - one for the code and one for the test data, the latter of which occupies a lot of space. Building and testing such an application requires acquiring code from both codebases.

Revision:

A revision is an textual identifier used by most version control systems to uniquely specify a particular version of the source code in a particular codebase.

Source stamp:

A source stamp is a collection of information needed to identify a particular version of code on a certain codebase. In most version control systems, source stamps only store a revision. On other version control systems, a branch is also required.

Source stamp set:

A source stamp set is a set of source stamps to identify a particular version of code on a certain project. Like a project is a collection of codebases, a source stamp set is a collection of source stamps, one for each codebase within a project.

In order to build a project, Buildbot only needs to know a source stamp set corresponding to that project. This source stamp set has a source stamp for each codebase comprising the project. In turn, each source stamp has enough information to identify a particular version of the code within the codebase.

Source Stamp Sets

2.3.2. Change sources

Change sources are user-configurable components that interact with external version control systems and retrieve new code. Internally, new code is represented as Changes which roughly correspond to a single commit or changeset. The changes are sent to the schedulers which then decide whether new builds should be created for these new code changes.

The design of Buildbot requires the workers to have their own copies of the source code, thus change sources is an optional component as long as there are no schedulers that create new builds based on new code commit events.

2.3.3. Changes

A Change is an abstract way Buildbot uses to represent a single change to the source files, performed by a developer. In version control systems that support the notion of atomic check-ins, a change represents a changeset or commit.

Changes are used for the Change sources to communicate with Schedulers.

A Change comprises the following information:

  • the developer who is responsible for the change

  • the list of files that the change added, removed or modified

  • the message of the commit

  • the repository, the codebase and the project that the change corresponds to

  • the revision and the branch of the commit

2.3.4. Schedulers

A scheduler is a component that decides when to start a build. The decision could be based on time, on new code being committed or on similar events.

Schedulers are responsible for creating Build Requests which identify a request to start a build on a specific version of the source code.

Each Buildmaster has a set of scheduler objects, each of which gets a copy of every incoming Change. The Schedulers are responsible for deciding when Builds should be run. Some Buildbot installations might have a single scheduler, while others may have several, each for a different purpose.

2.3.5. BuildRequests

A BuildRequest is a request to start a specific build. A BuildRequest consists of the following information:

  • the name of the Builder (see below) that will perform the build.

  • the set of SourceStamps (see above) that specify the version of the source tree to build and/or test.

Two build requests representing the same version of the source code and the same builder may be merged. The user may configure additional restrictions for determining mergeability of build requests.

2.3.6. Builders and Build Factories

A Builder is responsible for creating new builds from BuildRequests. Creating a new build is essentially determining the following properties of the subsequent build:

  • the exact steps a build will execute

  • the workers that the build may run on

The sequence of steps to run is performed by user-configurable BuildFactory that is attached to each Builder by the user.

A Builder will attempt to create a Build from a BuildRequest as soon as it is possible, that is, as soon as the associated worker becomes free. When a worker becomes free, the build master will select the oldest BuildRequest that can run on that worker and notify the corresponding Builder to maybe start a build out of it.

Each Builder by default runs completely independently. This means, that a worker that has N builders attached to it, may potentially attempt to run N builds concurrently. This level of concurrency may be controlled by various kinds of Interlocks.

At a low level, each builder has its own exclusive directory on the build master and one exclusive directory on each of the workers it is attached to. The directory on the master is used for keeping status information. The directories on the workers are used as a location where the actual checkout, compilation and testing steps happen.

For easier management in the Web UI related builders may be grouped into projects.

2.3.7. Builds

A Build represents a single compile or test run of a particular version of a source code. A build is comprised of a series of steps. The steps may be arbitrary. For example, for compiled software a build generally consists of the checkout, configure, make, and make check sequence. For interpreted projects like Python modules, a build is generally a checkout followed by an invocation of the bundled test suite.

Builds are created by instances of Builder (see above).

2.3.8. BuildSets

A BuildSet represents a set of potentially not yet created Builds that all compile and/or test the same version of the source tree. It tracks whether this set of builds as a whole succeeded or not. The information that is stored in a BuildSet is a set of SourceStamps which define the version of the code to test and a set of Builders which define what builds to create.

2.3.9. Workers

A Worker corresponds to an environment where builds are executed. A single physical machine must run at least one Worker in order for Buildbot to be able to utilize it for running builds. Multiple Workers may run on a single machine to provide different environments that can reuse the same hardware by means of containers or virtual machines.

Each builder is associated with one or more Workers. For example, a builder which is used to perform macOS builds (as opposed to Linux or Windows builds) should naturally be associated with a Mac worker.

If multiple workers are available for any given builder, you will have some measure of redundancy: in case one worker goes offline, the others can still keep the Builder working. In addition, multiple workers will allow multiple simultaneous builds for the same Builder, which might be useful if you have a lot of forced or try builds taking place.

Ideally, each Worker that is configured for a builder should be identical. Otherwise build or test failures will be dependent on which worker the build is run and this will complicate investigations of failures.

2.3.10. Users

Buildbot has a somewhat limited awareness of users. It assumes the world consists of a set of developers, each of whom can be described by a couple of simple attributes. These developers make changes to the source code, causing builds which may succeed or fail.

Users also may have different levels of authorization when issuing Buildbot commands, such as forcing a build from the web interface or from an IRC channel.

Each developer is primarily known through the source control system. Each Change object that arrives is tagged with a who field that typically gives the account name (on the repository machine) of the user responsible for that change. This string is displayed on the HTML status pages and in each Build's blamelist.

To do more with the User than just refer to them, this username needs to be mapped into an address of some sort. The responsibility for this mapping is left up to the status module which needs the address. In the future, the responsibility for managing users will be transferred to User Objects.

The who fields in git Changes are used to create User Objects, which allows for more control and flexibility in how Buildbot manages users.

2.3.10.1. User Objects

User Objects allow Buildbot to better manage users throughout its various interactions with users (see Change Sources and Changes and Reporters). The User Objects are stored in the Buildbot database and correlate the various attributes that a user might have: irc, Git, etc.

Changes

Incoming Changes all have a who attribute attached to them that specifies which developer is responsible for that Change. When a Change is first rendered, the who attribute is parsed and added to the database, if it doesn’t exist, or checked against an existing user. The who attribute is formatted in different ways depending on the version control system that the Change came from.

git

who attributes take the form Full Name <Email>.

svn

who attributes are of the form Username.

hg

who attributes are free-form strings, but usually adhere to similar conventions as git attributes (Full Name <Email>).

cvs

who attributes are of the form Username.

darcs

who attributes contain an Email and may also include a Full Name like git attributes.

bzr

who attributes are free-form strings like hg, and can include a Username, Email, and/or Full Name.

Tools

For managing users manually, use the buildbot user command, which allows you to add, remove, update, and show various attributes of users in the Buildbot database (see Command-line Tool).

Uses

Correlating the various bits and pieces that Buildbot views as users also means that one attribute of a user can be translated into another. This provides a more complete view of users throughout Buildbot.

One such use is being able to find email addresses based on a set of Builds to notify users through the MailNotifier. This process is explained more clearly in Email Addresses.

Another way to utilize User Objects is through UsersAuth for web authentication. To use UsersAuth, you need to set a bb_username and bb_password via the buildbot user command line tool to check against. The password will be encrypted before it gets stored in the database along with other user attributes.

2.3.10.2. Doing Things With Users

Each change has a single user who is responsible for it. Most builds have a set of changes: the build generally represents the first time these changes have been built and tested by the Buildbot. The build has a blamelist that is the union of the users responsible for all of the build’s changes. If the build was created by a Try Schedulers this list will include the submitter of the try job if known.

The build provides a list of users who are interested in the build – the interested users. Usually this is equal to the blamelist, but may also be expanded, e.g., to include the current build sherrif or a module’s maintainer.

If desired, buildbot can notify the interested users until the problem is resolved.

2.3.10.3. Email Addresses

The MailNotifier is a status target which can send emails about the results of each build. It accepts a static list of email addresses to which each message should be delivered, but it can also be configured to send emails to a Build's Interested Users. To do this, it needs a way to convert User names into email addresses.

For many VCSs, the User name is actually an account name on the system which hosts the repository. As such, turning the name into an email address is simply a matter of appending @repositoryhost.com. Some projects use other kinds of mappings (for example the preferred email address may be at project.org, despite the repository host being named cvs.project.org), and some VCSs have full separation between the concept of a user and that of an account on the repository host (like Perforce). Some systems (like Git) put a full contact email address in every change.

To convert these names to addresses, the MailNotifier uses an EmailLookup object. This provides a getAddress method which accepts a name and (eventually) returns an address. The default MailNotifier module provides an EmailLookup which simply appends a static string, configurable when the notifier is created. To create more complex behaviors (perhaps using an LDAP lookup, or using finger on a central host to determine a preferred address for the developer), provide a different object as the lookup argument.

If an EmailLookup object isn’t given to the MailNotifier, the MailNotifier will try to find emails through User Objects. If every user in the Build’s Interested Users list has an email in the database for them, this will work the same as if an EmailLookup object was used. If a user whose change led to a Build doesn’t have an email attribute, that user will not receive an email. If extraRecipients is given, those users still get an email when the EmailLookup object is not specified.

In the future, when the Problem mechanism has been set up, Buildbot will need to send emails to arbitrary Users. It will do this by locating a MailNotifier-like object among all the buildmaster’s status targets, and asking it to send messages to various Users. This means the User-to-address mapping only has to be set up once, in your MailNotifier, and every email message buildbot emits will take advantage of it.

2.3.10.4. IRC Nicknames

Like MailNotifier, the buildbot.reporters.irc.IRC class provides a status target which can announce the results of each build. It also provides an interactive interface by responding to online queries posted in the channel or sent as private messages.

In the future, buildbot can be configured to map User names to IRC nicknames, to watch for the recent presence of these nicknames, and to deliver build status messages to the interested parties. Like MailNotifier does for email addresses, the IRC object will have an IRCLookup which is responsible for nicknames. The mapping can be set up statically, or it can be updated by online users themselves (by claiming a username with some kind of buildbot: i am user warner commands).

Once the mapping is established, buildbot can then ask the IRC object to send messages to various users. It can report on the likelihood that the user saw the given message (based upon how long the user has been inactive on the channel), which might prompt the Problem Hassler logic to send them an email message instead.

These operations and authentication of commands issued by particular nicknames will be implemented in User Objects.

2.3.11. Build Properties

Each build has a set of Build Properties, which can be used by its build steps to modify their actions.

The properties are represented as a set of key-value pairs. Effectively, a single property is a variable that, once set, can be used by subsequent steps in a build to modify their behaviour. The value of a property can be a number, a string, a list or a dictionary. Lists and dictionaries can contain other lists or dictionaries. Thus, the value of a property could be any arbitrarily complex structure.

Properties work pretty much like variables, so they can be used to implement all manner of functionality.

The following are a couple of examples:

  • By default, the name of the worker that runs the build is set to the workername property. If there are multiple different workers and the actions of the build depend on the exact worker, some users may decide that it’s more convenient to vary the actions depending on the workername property instead of creating separate builders for each worker.

  • In most cases, the build does not know the exact code revision that will be tested until it checks out the code. This information is only known after a source step runs. To give this information to the subsequent steps, the source step records the checked out revision into the got_revision property.

2.4. Secret Management

2.4.1. Requirements

Buildbot steps might need secrets to execute their actions. Secrets are used to execute commands or to create authenticated network connections. Secrets may be a SSH key, a password, or a file content like a wgetrc file or a public SSH key. To preserve confidentiality, the secret values must not be printed or logged in the twisted or step logs. Secrets must not be stored in the Buildbot configuration (master.cfg), as the source code is usually shared in SCM like git.

2.4.2. How to use Buildbot Secret Management

2.4.2.1. Secrets and providers

Buildbot implements several providers for secrets retrieval:

  • File system based: secrets are written in a file. This is a simple solution for example when secrets are managed by a config management system like Ansible Vault.

  • Third party backend based: secrets are stored by a specialized software. These solutions are usually more secure.

Secrets providers are configured if needed in the master configuration. Multiple providers can be configured at once. The secret manager is a Buildbot service. The secret manager returns the specific provider results related to the providers registered in the configuration.

2.4.2.2. How to use secrets in Buildbot

Secret can be used in Buildbot via the IRenderable mechanism. Two IRenderable actually implement secrets. Interpolate can be used if you need to mix secrets and other interpolation in the same argument. Secret can be used if your secret is directly used as a component argument.

Secret

Secret is a simple renderable which directly renders a secret.

Secret("secretName")
As argument to steps

The following example shows a basic usage of secrets in Buildbot.

from buildbot.plugins import secrets, util
# First we declare that the secrets are stored in a directory of the filesystem
# each file contains one secret identified by the filename
c['secretsProviders'] = [secrets.SecretInAFile(dirname="/path/toSecretsFiles")]

# then in a buildfactory:

# use a secret on a shell command via Interpolate
f1.addStep(ShellCommand(
    util.Interpolate("wget -u user -p '%(secret:userpassword)s' '%(prop:urltofetch)s'")))
# .. or non shell form:
f1.addStep(ShellCommand(["wget", "-u", "user", "-p",
                         util.Secret("userpassword"),
                         util.Interpolate("%(prop:urltofetch)s")]))

Secrets are also interpolated in the build like properties are. Their values will be used in a command line for example.

As argument to services

You can use secrets to configure services. All services arguments are not compatible with secrets. See their individual documentation for details.

# First we declare that the secrets are stored in a directory of the filesystem
# each file contains one secret identified by the filename
c['secretsProviders'] = [secrets.SecretInAFile(dirname="/path/toSecretsFiles")]

# then for a reporter:
c['services'] = [GitHubStatusPush(token=util.Secret("githubToken"))]
2.4.2.3. Secrets storages
SecretInAFile
c['secretsProviders'] = [secrets.SecretInAFile(dirname="/path/toSecretsFiles")]

In the passed directory, every file contains a secret identified by the filename.

e.g: a file user contains the text pa$$w0rd.

Arguments:

dirname

(required) Absolute path to directory containing the files with a secret.

strip

(optional) if True (the default), trailing newlines are removed from the file contents.

HashiCorpVaultKvSecretProvider
c['secretsProviders'] = [
    secrets.HashiCorpVaultKvSecretProvider(
        authenticator=secrets.VaultAuthenticatorApprole(roleId="<role-guid>",
                                                        secretId="<secret-guid>"),
        vault_server="http://localhost:8200",
        secrets_mount="kv")
]

HashiCorpVaultKvSecretProvider allows to use HashiCorp Vault KV secret engine as secret provider. Other secret engines are not supported by this particular provider. For more information about Vault please visit: Vault: https://www.vaultproject.io/

In order to use this secret provider, optional dependency hvac needs to be installed (pip install hvac).

It supports different authentication methods with ability to re-authenticate when authentication token expires (not possible using HvacAuthenticatorToken).

Parameters accepted by HashiCorpVaultKvSecretProvider:

  • authenticator: required parameter, specifies Vault authentication method. Possible authenticators are:

    • VaultAuthenticatorToken(token): simplest authentication by directly providing the authentication token. This method cannot benefit from re-authentication mechanism and when token expires, secret provider will just stop working.

    • VaultAuthenticatorApprole(roleId, secretId): approle authentication using roleId and secretId. This is common method for automation tools fetching secrets from vault.

  • vault_server: required parameter, specifies URL of vault server.

  • secrets_mount: specifies mount point of KV secret engine in vault, default value is “secret”.

  • api_version: version of vault KV secret engine. Supported versions are 1 and 2, default value is 2.

  • path_delimiter: character used to separate path and key name in secret identifiers. Default value is “|”.

  • path_escape: escape character used in secret identifiers to allow escaping of path_delimiter character in path or key values. Default value is “".

The secret identifiers that need to be passed to, e.g. Interpolate, have format: "path/to/secret:key". In case path or key name does contain colon character, it is possible to escape it using “" or specify different separator character using path_delimiter parameter when initializing secret provider.

Example use:

passwd = util.Secret('path/to/secret:password')
HashiCorpVaultSecretProvider

Note

Use of HashiCorpVaultSecretProvider is deprecated in favor of newer HashiCorpVaultKvSecretProvider and will be removed in future releases.

c['secretsProviders'] = [secrets.HashiCorpVaultSecretProvider(
                        vaultToken=open('VAULT_TOKEN').read().strip(),
                        vaultServer="http://localhost:8200",
                        secretsmount="secret",
                        apiVersion=2
)]

Vault secures, stores, and tightly controls access to secrets. Vault presents a unified API to access multiple backends. At the moment, Buildbot supports KV v1 and v2 backends via the apiVersion argument.

Buildbot’s Vault authentication/authorisation is via a token. The “Initial Root Token”, generated on Vault initialization, can be used but has ‘root’ authorization. Vault policies, and subsequent tokens assigned to them, provide for a more restrictive approach.

In the master configuration, the Vault provider is instantiated through the Buildbot service manager as a secret provider with the Vault server address and the Vault token. The provider SecretInVault allows Buildbot to read secrets in Vault.

The secret identifiers that need to be passed to, e.g. Interpolate, accept one of the following formats:

  • key: The provider will fetch the secret with name key and return the value of value attribute stored therein.

  • key/attr: The provider will fetch the secret with name key and return the value of attr attribute stored therein.

Vault stores secrets in form of key-value pairs.

  • Simple keys

_images/vault_simple_key.png

The key value with key name keyname can be read like:

text = Interpolate("your key equals %(secret:folder1/folder2/secretname/keyname)s")
  • Multipart keys

_images/vault_multipart_key.png

Each part of a multipart value can be read like

url = Interpolate("site url is %(secret:folder1/folde2/folde3/secretname/url)s")
pass = Interpolate("your password is %(secret:folder1/folde2/folde3/secretname/pass)s")
cert = Interpolate("your cert is %(secret:folder1/folde2/folde3/secretname/ssh-cert)s")
SecretInPass
c['secretsProviders'] = [secrets.SecretInPass(
                        gpgPassphrase="passphrase",
                        dirname="/path/to/password/store"
)]

Passwords can be stored in a unix password store, encrypted using GPG keys. Buildbot can query secrets via the pass binary found in the PATH of each worker. While pass allows for multiline entries, the secret must be on the first line of each entry. The only caveat is that all passwords Buildbot needs to access have to be encrypted using the same GPG key.

For more information about pass, please visit pass: https://www.passwordstore.org/

Arguments:

gpgPassphrase

(optional) Pass phrase to the GPG decryption key, if any

dirname

(optional) Absolute path to the password store directory, defaults to ~/.password-store

2.4.2.4. How to populate secrets in a build

To populate secrets in files during a build, 2 steps are used to create and delete the files on the worker. The files will be automatically deleted at the end of the build.

       f = BuildFactory()
       with f.withSecrets(secrets_list):
           f.addStep(step_definition)

or
f = BuildFactory()
f.addSteps([list_of_step_definitions], withSecrets=secrets_list)

In both cases the secrets_list is a list of (secret path, secret value) tuples.

secrets_list = [('/first/path', Interpolate('write something and %(secret:somethingmore)s')),
                ('/second/path', Interpolate('%(secret:othersecret)s'))]

The Interpolate class is used to render the value during the build execution.

2.4.2.5. How to configure a Vault instance

Vault being a very generic system, it can be complex to install for the first time. Here is a simple tutorial to install the minimal Vault to use with Buildbot.

Use Docker to install Vault

A Docker image is available to help users installing Vault. Without any arguments, the command launches a Docker Vault developer instance, easy to use and test the functions. The developer version is already initialized and unsealed. To launch a Vault server please refer to the VaultDocker documentation:

In a shell:

docker run vault
Starting the vault instance

Once the Docker image is created, launch a shell terminal on the Docker image:

docker exec -i -t ``docker_vault_image_name`` /bin/sh

Then, export the environment variable VAULT_ADDR needed to init Vault.

export VAULT_ADDR='vault.server.adress'
Writing secrets

By default the official docker instance of Vault is initialized with a mount path of ‘secret’, a KV v1 secret engine, and a second KV engine (v2) at ‘secret/data’. Currently, Buildbot is “hard wired” to expect KV v2 engines to reside within this “data” sub path. Provision is made to set a top level path via the “secretsmount” argument: defaults to “secret”. To add a new secret:

vault kv put secret/new_secret_key value=new_secret_value

2.5. Configuration

The following sections describe the configuration of the various Buildbot components. The information available here is sufficient to create basic build and test configurations, and does not assume great familiarity with Python.

In more advanced Buildbot configurations, Buildbot acts as a framework for a continuous-integration application. The next section, Customization, describes this approach, with frequent references into the development documentation.

2.5.1. Configuring Buildbot

Buildbot’s behavior is defined by the config file, which normally lives in the master.cfg file in the buildmaster’s base directory (but this can be changed with an option to the buildbot create-master command). This file completely specifies which Builders are to be run, which workers they should use, how Changes should be tracked, and where the status information is to be sent. The buildmaster’s buildbot.tac file names the base directory; everything else comes from the config file.

A sample config file was installed for you when you created the buildmaster, but you will need to edit it before your Buildbot will do anything useful.

This chapter gives an overview of the format of this file and the various sections in it. You will need to read the later chapters to understand how to fill in each section properly.

2.5.1.1. Config File Format

The config file is, fundamentally, just a piece of Python code which defines a dictionary named BuildmasterConfig, with a number of keys that are treated specially. You don’t need to know Python to do the basic configuration, though; you can just copy the sample file’s syntax. If you are comfortable writing Python code, however, you can use all the power of a full programming language to build more complicated configurations.

The BuildmasterConfig name is the only one which matters: all other names defined during the execution of the file are discarded. When parsing the config file, the Buildmaster generally compares the old configuration with the new one and performs the minimum set of actions necessary to bring Buildbot up to date: Builders which are not changed are left untouched, and Builders which are modified get to keep their old event history.

The beginning of the master.cfg file typically starts with something like:

BuildmasterConfig = c = {}

Therefore a config key like change_source will usually appear in master.cfg as c['change_source'].

See Buildmaster Configuration Index for a full list of BuildMasterConfig keys.

Basic Python Syntax

The master configuration file is interpreted as Python, allowing the full flexibility of the language. For the configurations described in this section, a detailed knowledge of Python is not required, but the basic syntax is easily described.

Python comments start with a hash character #, tuples are defined with (parenthesis, pairs), and lists (arrays) are defined with [square, brackets]. Tuples and lists are mostly interchangeable. Dictionaries (data structures which map keys to values) are defined with curly braces: {'key1': value1, 'key2': value2}. Function calls (and object instantiations) can use named parameters, like steps.ShellCommand(command=["trial", "hello"]).

The config file starts with a series of import statements, which make various kinds of Steps and Status targets available for later use. The main BuildmasterConfig dictionary is created, and then it is populated with a variety of keys, described section-by-section in the subsequent chapters.

2.5.1.2. Predefined Config File Symbols

The following symbols are automatically available for use in the configuration file.

basedir

the base directory for the buildmaster. This string has not been expanded, so it may start with a tilde. It needs to be expanded before use. The config file is located in:

os.path.expanduser(os.path.join(basedir, 'master.cfg'))
__file__

the absolute path of the config file. The config file’s directory is located in os.path.dirname(__file__).

2.5.1.3. Testing the Config File

To verify that the config file is well-formed and contains no deprecated or invalid elements, use the checkconfig command, passing it either a master directory or a config file.

% buildbot checkconfig master.cfg
Config file is good!
# or
% buildbot checkconfig /tmp/masterdir
Config file is good!

If the config file has deprecated features (perhaps because you’ve upgraded the buildmaster and need to update the config file to match), they will be announced by checkconfig. In this case, the config file will work, but you should really remove the deprecated items and use the recommended replacements instead:

% buildbot checkconfig master.cfg
/usr/lib/python2.4/site-packages/buildbot/master.py:559: DeprecationWarning: c['sources'] is
deprecated as of 0.7.6 and will be removed by 0.8.0 . Please use c['change_source'] instead.
Config file is good!

If you have errors in your configuration file, checkconfig will let you know:

% buildbot checkconfig master.cfg
Configuration Errors:
c['workers'] must be a list of Worker instances
no workers are configured
builder 'smoketest' uses unknown workers 'linux-002'

If the config file is simply broken, that will be caught too:

% buildbot checkconfig master.cfg
error while parsing config file:
Traceback (most recent call last):
File "/home/buildbot/master/bin/buildbot", line 4, in <module>
    runner.run()
File "/home/buildbot/master/buildbot/scripts/runner.py", line 1358, in run
    if not doCheckConfig(so):
File "/home/buildbot/master/buildbot/scripts/runner.py", line 1079, in doCheckConfig
    return cl.load(quiet=quiet)
File "/home/buildbot/master/buildbot/scripts/checkconfig.py", line 29, in load
    self.basedir, self.configFileName)
--- <exception caught here> ---
File "/home/buildbot/master/buildbot/config.py", line 147, in loadConfig
    exec f in localDict
exceptions.SyntaxError: invalid syntax (master.cfg, line 52)
Configuration Errors:
error while parsing config file: invalid syntax (master.cfg, line 52) (traceback in logfile)
2.5.1.4. Loading the Config File

The config file is only read at specific points in time. It is first read when the buildmaster is launched.

Note

If the configuration is invalid, the master will display the errors in the console output, but will not exit.

Reloading the Config File (reconfig)

If you are on the system hosting the buildmaster, you can send a SIGHUP signal to it: the buildbot tool has a shortcut for this:

buildbot reconfig BASEDIR

This command will show you all of the lines from twistd.log that relate to the reconfiguration. If there are any problems during the config-file reload, they will be displayed in the output.

When reloading the config file, the buildmaster will endeavor to change as little as possible about the running system. For example, although old status targets may be shut down and new ones started up, any status targets that were not changed since the last time the config file was read will be left running and untouched. Likewise any Builders which have not been changed will be left running. If a Builder is modified (say, the build command is changed), this change will apply only for new Builds. Any existing build that is currently running or was already queued will be allowed to finish using the old configuration.

Note that if any lock is renamed, old and new instances of the lock will be completely unrelated in the eyes of the buildmaster. This means that buildmaster will be able to start new builds that would otherwise have waited for the old lock to be released.

Warning

Buildbot’s reconfiguration system is fragile for a few difficult-to-fix reasons:

  • Any modules imported by the configuration file are not automatically reloaded. Python modules such as https://docs.python.org/3/library/importlib.html and importlib.reload() may help here, but reloading modules is fraught with subtleties and difficult-to-decipher failure cases.

  • During the reconfiguration, active internal objects are divorced from the service hierarchy, leading to tracebacks in the web interface and other components. These are ordinarily transient, but with HTTP connection caching (either by the browser or an intervening proxy) they can last for a long time.

  • If the new configuration file is invalid, it is possible for Buildbot’s internal state to be corrupted, leading to undefined results. When this occurs, it is best to restart the master.

  • For more advanced configurations, it is impossible for Buildbot to tell if the configuration for a Builder or Scheduler has changed, and thus the Builder or Scheduler will always be reloaded. This occurs most commonly when a callable is passed as a configuration parameter.

The bbproto project (at https://github.com/dabrahams/bbproto) may help to construct large (multi-file) configurations which can be effectively reloaded and reconfigured.

2.5.2. Global Configuration

The keys in this section affect the operations of the buildmaster globally.

2.5.2.1. Database Specification

Buildbot requires a connection to a database to maintain certain state information, such as tracking pending build requests. In the default configuration Buildbot uses a file-based SQLite database, stored in the state.sqlite file of the master’s base directory.

Important

SQLite3 is perfectly suitable for small setups with a few users. However, it does not scale well with large numbers of builders, workers and users. If you expect your Buildbot to grow over time, it is strongly advised to use a real database server (e.g., MySQL or Postgres).

A SQLite3 database may be migrated to a real database server using buildbot copy-db script.

See the Using A Database Server section for more details.

Override this configuration with the db_url parameter.

Buildbot accepts a database configuration in a dictionary named db. All keys are optional:

c['db'] = {
    'db_url' : 'sqlite:///state.sqlite',
}

The db_url key indicates the database engine to use. The format of this parameter is completely documented at http://www.sqlalchemy.org/docs/dialects/, but is generally of the form:

"driver://[username:password@]host:port/database[?args]"

This parameter can be specified directly in the configuration dictionary, as c['db_url'], although this method is deprecated.

The following sections give additional information for particular database backends:

SQLite

For sqlite databases, since there is no host and port, relative paths are specified with sqlite:/// and absolute paths with sqlite:////. For example:

c['db_url'] = "sqlite:///state.sqlite"

SQLite requires no special configuration.

MySQL
c['db_url'] = "mysql://username:password@example.com/database_name?max_idle=300"

The max_idle argument for MySQL connections is unique to Buildbot and should be set to something less than the wait_timeout configured for your server. This controls the SQLAlchemy pool_recycle parameter, which defaults to no timeout. Setting this parameter ensures that connections are closed and re-opened after the configured amount of idle time. If you see errors such as _mysql_exceptions.OperationalError: (2006, 'MySQL server has gone away'), this means your max_idle setting is probably too high. show global variables like 'wait_timeout'; will show what the currently configured wait_timeout is on your MySQL server.

Buildbot requires use_unique=True and charset=utf8, and will add them automatically, so they do not need to be specified in db_url.

MySQL defaults to the MyISAM storage engine, but this can be overridden with the storage_engine URL argument.

Postgres
c['db_url'] = "postgresql://username:password@hostname/dbname"

PosgreSQL requires no special configuration.

2.5.2.2. MQ Specification

Buildbot uses a message-queueing system to handle communication within the master. Messages are used to indicate events within the master, and components that are interested in those events arrange to receive them.

The message queueing implementation is configured as a dictionary in the mq option. The type key describes the type of MQ implementation to be used. Note that the implementation type cannot be changed in a reconfig.

The available implementation types are described in the following sections.

Simple
c['mq'] = {
    'type' : 'simple',
    'debug' : False,
}

This is the default MQ implementation. Similar to SQLite, it has no additional software dependencies, but does not support multi-master mode.

Note that this implementation also does not support message persistence across a restart of the master. For example, if a change is received, but the master shuts down before the schedulers can create build requests for it, then those schedulers will not be notified of the change when the master starts again.

The debug key, which defaults to False, can be used to enable logging of every message produced on this master.

Wamp

Note

At the moment, wamp is the only message queue implementation for multimaster. It has been privileged as this is the only message queue that has very solid support for Twisted. Other more common message queue systems like RabbitMQ (using the AMQP protocol) do not have a convincing driver for twisted, and this would require to run on threads, which will add an important performance overhead.

c['mq'] = {
    'type' : 'wamp',
    'router_url': 'ws://localhost:8080/ws',
    'realm': 'realm1',
    # valid are: none, critical, error, warn, info, debug, trace
    'wamp_debug_level' : 'error'
}

This is a MQ implementation using the wamp protocol. This implementation uses Python Autobahn wamp client library, and is fully asynchronous (no use of threads). To use this implementation, you need a wamp router like Crossbar.

Please refer to Crossbar documentation for more details, but the default Crossbar setup will just work with Buildbot, provided you use the example mq configuration above, and start Crossbar with:

# of course, you should work in a virtualenv...
pip install crossbar
crossbar init
crossbar start

The implementation does not yet support wamp authentication. This MQ allows buildbot to run in multi-master mode.

Note that this implementation also does not support message persistence across a restart of the master. For example, if a change is received, but the master shuts down before the schedulers can create build requests for it, then those schedulers will not be notified of the change when the master starts again.

router_url (mandatory): points to your router websocket url.

Buildbot is only supporting wamp over websocket, which is a sub-protocol of http. SSL is supported using wss:// instead of ws://.

realm (optional, defaults to buildbot): defines the wamp realm to use for your buildbot messages.

wamp_debug_level (optional, defaults to error): defines the log level of autobahn.

You must use a router with very reliable connection to the master. If for some reason, the wamp connection is lost, then the master will stop, and should be restarted via a process manager.

2.5.2.3. Multi-master mode

See Multimaster for details on the multi-master mode in Buildbot Nine.

By default, Buildbot makes coherency checks that prevent typos in your master.cfg. It makes sure schedulers are not referencing unknown builders, and enforces there is at least one builder.

In the case of an asymmetric multimaster, those coherency checks can be harmful and prevent you to implement what you want. For example, you might want to have one master dedicated to the UI, so that a big load generated by builds will not impact page load times.

To enable multi-master mode in this configuration, you will need to set the multiMaster option so that buildbot doesn’t warn about missing schedulers or builders.

# Enable multiMaster mode; disables warnings about unknown builders and
# schedulers
c['multiMaster'] = True
c['db'] = {
    'db_url' : 'mysql://...',
}
c['mq'] = {  # Need to enable multimaster aware mq. Wamp is the only option for now.
    'type' : 'wamp',
    'router_url': 'ws://localhost:8080',
    'realm': 'realm1',
    # valid are: none, critical, error, warn, info, debug, trace
    'wamp_debug_level' : 'error'
}
2.5.2.4. Site Definitions

Three basic settings describe the buildmaster in status reports:

c['title'] = "Buildbot"
c['titleURL'] = "http://buildbot.sourceforge.net/"

title is a short string that will appear at the top of this buildbot installation’s home page (linked to the titleURL).

titleURL is a URL string that must end with a slash (/). HTML status displays will show title as a link to titleURL. This URL is often used to provide a link from buildbot HTML pages to your project’s home page.

The buildbotURL string should point to the location where the buildbot’s internal web server is visible. This URL must end with a slash (/).

When status notices are sent to users (e.g., by email or over IRC), buildbotURL will be used to create a URL to the specific build or problem that they are being notified about.

2.5.2.5. Log Handling
c['logCompressionMethod'] = 'gz'
c['logMaxSize'] = 1024*1024 # 1M
c['logMaxTailSize'] = 32768
c['logEncoding'] = 'utf-8'

The logCompressionLimit enables compression of build logs on disk for logs that are bigger than the given size, or disables that completely if set to False. The default value is 4096, which should be a reasonable default on most file systems. This setting has no impact on status plugins, and merely affects the required disk space on the master for build logs.

The logCompressionMethod controls what type of compression is used for build logs. The default is ‘gz’, and the other valid option are ‘raw’ (no compression), ‘gz’ or ‘lz4’ (required lz4 package).

Please find below some stats extracted from 50x “trial Pyflakes” runs (results may differ according to log type).

Space saving details

compression

raw log size

compressed log size

space saving

compression speed

bz2

2.981 MB

0.603 MB

79.77%

3.433 MB/s

gz

2.981 MB

0.568 MB

80.95%

6.604 MB/s

lz4

2.981 MB

0.844 MB

71.68%

77.668 MB/s

The logMaxSize parameter sets an upper limit (in bytes) to how large logs from an individual build step can be. The default value is None, meaning no upper limit to the log size. Any output exceeding logMaxSize will be truncated, and a message to this effect will be added to the log’s HEADER channel.

If logMaxSize is set, and the output from a step exceeds the maximum, the logMaxTailSize parameter controls how much of the end of the build log will be kept. The effect of setting this parameter is that the log will contain the first logMaxSize bytes and the last logMaxTailSize bytes of output. Don’t set this value too high, as the the tail of the log is kept in memory.

The logEncoding parameter specifies the character encoding to use to decode bytestrings provided as logs. It defaults to utf-8, which should work in most cases, but can be overridden if necessary. In extreme cases, a callable can be specified for this parameter. It will be called with byte strings, and should return the corresponding Unicode string.

This setting can be overridden for a single build step with the logEncoding step parameter. It can also be overridden for a single log file by passing the logEncoding parameter to addLog.

2.5.2.6. Data Lifetime
Horizons

Previously Buildbot implemented a global configuration for horizons. Now it is implemented as a utility Builder, and shall be configured via the JanitorConfigurator.

Caches
c['caches'] = {
    'Changes' : 100,     # formerly c['changeCacheSize']
    'Builds' : 500,      # formerly c['buildCacheSize']
    'chdicts' : 100,
    'BuildRequests' : 10,
    'SourceStamps' : 20,
    'ssdicts' : 20,
    'objectids' : 10,
    'usdicts' : 100,
}

The caches configuration key contains the configuration for Buildbot’s in-memory caches. These caches keep frequently-used objects in memory to avoid unnecessary trips to the database. Caches are divided by object type, and each has a configurable maximum size.

The default size for each cache is 1, except where noted below. A value of 1 allows Buildbot to make a number of optimizations without consuming much memory. Larger, busier installations will likely want to increase these values.

The available caches are:

Changes

the number of change objects to cache in memory. This should be larger than the number of changes that typically arrive in the span of a few minutes, otherwise your schedulers will be reloading changes from the database every time they run. For distributed version control systems, like Git or Hg, several thousand changes may arrive at once, so setting this parameter to something like 10000 isn’t unreasonable.

This parameter is the same as the deprecated global parameter changeCacheSize. Its default value is 10.

Builds

The buildCacheSize parameter gives the number of builds for each builder which are cached in memory. This number should be larger than the number of builds required for commonly-used status displays (the waterfall or grid views), so that those displays do not miss the cache on a refresh.

This parameter is the same as the deprecated global parameter buildCacheSize. Its default value is 15.

chdicts

The number of rows from the changes table to cache in memory. This value should be similar to the value for Changes.

BuildRequests

The number of BuildRequest objects kept in memory. This number should be higher than the typical number of outstanding build requests. If the master ordinarily finds jobs for BuildRequests immediately, you may set a lower value.

SourceStamps

the number of SourceStamp objects kept in memory. This number should generally be similar to the number BuildRequesets.

ssdicts

The number of rows from the sourcestamps table to cache in memory. This value should be similar to the value for SourceStamps.

objectids

The number of object IDs - a means to correlate an object in the Buildbot configuration with an identity in the database–to cache. In this version, object IDs are not looked up often during runtime, so a relatively low value such as 10 is fine.

usdicts

The number of rows from the users table to cache in memory. Note that for a given user there will be a row for each attribute that user has.

c[‘buildCacheSize’] = 15

2.5.2.7. Merging Build Requests
c['collapseRequests'] = True

This is a global default value for builders’ collapseRequests parameter, and controls the merging of build requests.

This parameter can be overridden on a per-builder basis. See Collapsing Build Requests for the allowed values for this parameter.

2.5.2.8. Prioritizing Builders
def prioritizeBuilders(buildmaster, builders):
    ...
c['prioritizeBuilders'] = prioritizeBuilders

By default, buildbot will attempt to start builds on builders in order, beginning with the builder with the oldest pending request. Customize this behavior with the prioritizeBuilders configuration key, which takes a callable. See Builder Priority Functions for details on this callable.

This parameter controls the order that the buildmaster can start builds, and is useful in situations where there is resource contention between builders, e.g., for a test database. It does not affect the order in which a builder processes the build requests in its queue. For that purpose, see Prioritizing Builds.

2.5.2.9. Setting the PB Port for Workers
c['protocols'] = {"pb": {"port": 10000}}

The buildmaster will listen on a TCP port of your choosing for connections from workers. It can also use this port for connections from remote Change Sources, status clients, and debug tools. This port should be visible to the outside world, and you’ll need to tell your worker admins about your choice.

It does not matter which port you pick, as long it is externally visible; however, you should probably use something larger than 1024, since most operating systems don’t allow non-root processes to bind to low-numbered ports. If your buildmaster is behind a firewall or a NAT box of some sort, you may have to configure your firewall to permit inbound connections to this port.

c['protocols']['pb']['port'] can also be used as a connection string, as defined in the ConnectionStrings guide.

This means that you can have the buildmaster listen on a localhost-only port by doing:

c['protocols'] = {"pb": {"port": "tcp:10000:interface=127.0.0.1"}}

This might be useful if you only run workers on the same machine, and they are all configured to contact the buildmaster at localhost:10000.

connection strings can also be used to configure workers connecting over TLS. The syntax is then

c['protocols'] = {"pb": {"port":
                         "ssl:9989:privateKey=master.key:certKey=master.crt"}}

Please note that IPv6 addresses with : must be escaped with as well as : in paths and in paths. Read more about the connection strings format in ConnectionStrings documentation.

See also Worker TLS Configuration

2.5.2.10. Defining Global Properties

The properties configuration key defines a dictionary of properties that will be available to all builds started by the buildmaster:

c['properties'] = {
    'Widget-version' : '1.2',
    'release-stage' : 'alpha'
}
2.5.2.11. Manhole

Manhole is an interactive Python shell which allows full access to the Buildbot master instance. It is probably only useful for buildbot developers.

See documentation on Manhole implementations for available authentication and connection methods.

The manhole configuration key accepts a single instance of a Manhole class. For example:

from buildbot import manhole
c['manhole'] = manhole.PasswordManhole("tcp:1234:interface=127.0.0.1",
                                       "admin", "passwd",
                                       ssh_hostkey_dir="data/ssh_host_keys")
2.5.2.12. Metrics Options
c['metrics'] = dict(log_interval=10, periodic_interval=10)

metrics can be a dictionary that configures various aspects of the metrics subsystem. If metrics is None, then metrics collection, logging and reporting will be disabled.

log_interval determines how often metrics should be logged to twistd.log. It defaults to 60s. If set to 0 or None, then logging of metrics will be disabled. This value can be changed via a reconfig.

periodic_interval determines how often various non-event based metrics are collected, such as memory usage, uncollectable garbage, reactor delay. This defaults to 10s. If set to 0 or None, then periodic collection of this data is disabled. This value can also be changed via a reconfig.

Read more about metrics in the Metrics section in the developer documentation.

2.5.2.13. Statistics Service

The Statistics Service (stats service for short) supports the collection of arbitrary data from within a running Buildbot instance and the export to a number of storage backends. Currently, only InfluxDB is supported as a storage backend. Also, InfluxDB (or any other storage backend) is not a mandatory dependency. Buildbot can run without it, although StatsService will be of no use in such a case. At present, StatsService can keep track of build properties, build times (start, end, duration) and arbitrary data produced inside Buildbot (more on this later).

Example usage:

captures = [stats.CaptureProperty('Builder1', 'tree-size-KiB'),
            stats.CaptureBuildDuration('Builder2')]
c['services'] = []
c['services'].append(stats.StatsService(
    storage_backends=[
        stats.InfluxStorageService('localhost', 8086, 'root', 'root', 'test', captures)
    ], name="StatsService"))

The services configuration value should be initialized as a list and a StatsService instance should be appended to it as shown in the example above.

Statistics Service
class buildbot.statistics.stats_service.StatsService

This is the main class for statistics services. It is initialized in the master configuration as shown in the example above. It takes two arguments:

storage_backends

A list of storage backends (see Storage Backends). In the example above, stats.InfluxStorageService is an instance of a storage backend. Each storage backend is an instance of subclasses of statsStorageBase.

name

The name of this service.

yieldMetricsValue: This method can be used to send arbitrary data for storage. (See Using StatsService.yieldMetricsValue for more information.)

Capture Classes
class buildbot.statistics.capture.CaptureProperty

Instance of this class declares which properties must be captured and sent to the Storage Backends. It takes the following arguments:

builder_name

The name of builder in which the property is recorded.

property_name

The name of property needed to be recorded as a statistic.

callback=None

(Optional) A custom callback function for this class. This callback function should take in two arguments - build_properties (dict) and property_name (str) and return a string that will be sent for storage in the storage backends.

regex=False

If this is set to True, then the property name can be a regular expression. All properties matching this regular expression will be sent for storage.

class buildbot.statistics.capture.CapturePropertyAllBuilders

Instance of this class declares which properties must be captured on all builders and sent to the Storage Backends. It takes the following arguments:

property_name

The name of property needed to be recorded as a statistic.

callback=None

(Optional) A custom callback function for this class. This callback function should take in two arguments - build_properties (dict) and property_name (str) and return a string that will be sent for storage in the storage backends.

regex=False

If this is set to True, then the property name can be a regular expression. All properties matching this regular expression will be sent for storage.

class buildbot.statistics.capture.CaptureBuildStartTime

Instance of this class declares which builders’ start times are to be captured and sent to Storage Backends. It takes the following arguments:

builder_name

The name of builder whose times are to be recorded.

callback=None

(Optional) A custom callback function for this class. This callback function should take in a Python datetime object and return a string that will be sent for storage in the storage backends.

class buildbot.statistics.capture.CaptureBuildStartTimeAllBuilders

Instance of this class declares start times of all builders to be captured and sent to Storage Backends. It takes the following arguments:

callback=None

(Optional) A custom callback function for this class. This callback function should take in a Python datetime object and return a string that will be sent for storage in the storage backends.

class buildbot.statistics.capture.CaptureBuildEndTime

Exactly like CaptureBuildStartTime except it declares the builders whose end time is to be recorded. The arguments are same as CaptureBuildStartTime.

class buildbot.statistics.capture.CaptureBuildEndTimeAllBuilders

Exactly like CaptureBuildStartTimeAllBuilders except it declares all builders’ end time to be recorded. The arguments are same as CaptureBuildStartTimeAllBuilders.

class buildbot.statistics.capture.CaptureBuildDuration

Instance of this class declares the builders whose build durations are to be recorded. It takes the following arguments:

builder_name

The name of builder whose times are to be recorded.

report_in='seconds'

Can be one of three: 'seconds', 'minutes', or 'hours'. This is the units in which the build time will be reported.

callback=None

(Optional) A custom callback function for this class. This callback function should take in two Python datetime objects - a start_time and an end_time and return a string that will be sent for storage in the storage backends.

class buildbot.statistics.capture.CaptureBuildDurationAllBuilders

Instance of this class declares build durations to be recorded for all builders. It takes the following arguments:

report_in='seconds'

Can be one of three: 'seconds', 'minutes', or 'hours'. This is the units in which the build time will be reported.

callback=None

(Optional) A custom callback function for this class. This callback function should take in two Python datetime objects - a start_time and an end_time and return a string that will be sent for storage in the storage backends.

class buildbot.statistics.capture.CaptureData

Instance of this capture class is for capturing arbitrary data that is not stored as build-data. Needs to be used in combination with yieldMetricsValue (see Using StatsService.yieldMetricsValue). Takes the following arguments:

data_name

The name of data to be captured. Same as in yieldMetricsValue.

builder_name

The name of builder whose times are to be recorded.

callback=None

The callback function for this class. This callback receives the data sent to yieldMetricsValue as post_data (see Using StatsService.yieldMetricsValue). It must return a string that is to be sent to the storage backends for storage.

class buildbot.statistics.capture.CaptureDataAllBuilders

Instance of this capture class for capturing arbitrary data that is not stored as build-data on all builders. Needs to be used in combination with yieldMetricsValue (see Using StatsService.yieldMetricsValue). Takes the following arguments:

data_name

The name of data to be captured. Same as in yieldMetricsValue.

callback=None

The callback function for this class. This callback receives the data sent to yieldMetricsValue as post_data (see Using StatsService.yieldMetricsValue). It must return a string that is to be sent to the storage backends for storage.

Using StatsService.yieldMetricsValue

Advanced users can modify BuildSteps to use StatsService.yieldMetricsValue which will send arbitrary data for storage to the StatsService. It takes the following arguments:

data_name

The name of the data being sent or storage.

post_data

A dictionary of key value pair that is sent for storage. The keys will act as columns in a database and the value is stored under that column.

buildid

The integer build id of the current build. Obtainable in all BuildSteps.

Along with using yieldMetricsValue, the user will also need to use the CaptureData capture class. As an example, we can add the following to a build step:

yieldMetricsValue('test_data_name', {'some_data': 'some_value'}, buildid)

Then, we can add in the master configuration a capture class like this:

captures = [CaptureBuildData('test_data_name', 'Builder1')]

Pass this captures list to a storage backend (as shown in the example at the top of this section) for capturing this data.

Storage Backends

Storage backends are responsible for storing any statistics data sent to them. A storage backend will generally be some sort of a database-server running on a machine. (Note: This machine may be different from the one running BuildMaster)

Currently, only InfluxDB is supported as a storage backend.

class buildbot.statistics.storage_backends.influxdb_client.InfluxStorageService

This class is a Buildbot client to the InfluxDB storage backend. InfluxDB is a distributed, time series database that employs a key-value pair storage system.

It requires the following arguments:

url

The URL where the service is running.

port

The port on which the service is listening.

user

Username of a InfluxDB user.

password

Password for user.

db

The name of database to be used.

captures

A list of objects of Capture Classes. This tells which statistics are to be stored in this storage backend.

name=None

(Optional) The name of this storage backend.

2.5.2.14. secretsProviders

See Secret Management for details on secret concepts.

Example usage:

c['secretsProviders'] = [ .. ]

secretsProviders is a list of secrets storage. See Secret Management to configure a secret storage provider.

2.5.2.15. BuildbotNetUsageData

Since buildbot 0.9.0, buildbot has a simple feature which sends usage analysis info to buildbot.net. This is very important for buildbot developers to understand how the community is using the tools. This allows to better prioritize issues, and understand what plugins are actually being used. This will also be a tool to decide whether to keep support for very old tools. For example buildbot contains support for the venerable CVS, but we have no information whether it actually works beyond the unit tests. We rely on the community to test and report issues with the old features.

With BuildbotNetUsageData, we can know exactly what combination of plugins are working together, how much people are customizing plugins, what versions of the main dependencies people run.

We take your privacy very seriously.

BuildbotNetUsageData will never send information specific to your Code or Intellectual Property. No repository url, shell command values, host names, ip address or custom class names. If it does, then this is a bug, please report.

We still need to track unique number for installation. This is done via doing a sha1 hash of master’s hostname, installation path and fqdn. Using a secure hash means there is no way of knowing hostname, path and fqdn given the hash, but still there is a different hash for each master.

You can see exactly what is sent in the master’s twisted.log. Usage data is sent every time the master is started.

BuildbotNetUsageData can be configured with 4 values:

  • c['buildbotNetUsageData'] = None disables the feature

  • c['buildbotNetUsageData'] = 'basic' sends the basic information to buildbot including:

    • versions of buildbot, python and twisted

    • platform information (CPU, OS, distribution, python flavor (i.e CPython vs PyPy))

    • mq and database type (mysql or sqlite?)

    • www plugins usage

    • Plugins usages: This counts the number of time each class of buildbot is used in your configuration. This counts workers, builders, steps, schedulers, change sources. If the plugin is subclassed, then it will be prefixed with a >

    example of basic report (for the metabuildbot):

    {
    'versions': {
        'Python': '2.7.6',
        'Twisted': '15.5.0',
        'Buildbot': '0.9.0rc2-176-g5fa9dbf'
    },
    'platform': {
        'machine': 'x86_64',
        'python_implementation': 'CPython',
        'version': '#140-Ubuntu SMP Mon Jul',
        'processor':
        'x86_64',
        'distro:': ('Ubuntu', '14.04', 'trusty')
        },
    'db': 'sqlite',
    'mq': 'simple',
    'plugins': {
        'buildbot.schedulers.forcesched.ForceScheduler': 2,
        'buildbot.schedulers.triggerable.Triggerable': 1,
        'buildbot.config.BuilderConfig': 4,
        'buildbot.schedulers.basic.AnyBranchScheduler': 2,
        'buildbot.steps.source.git.Git': 4,
        '>>buildbot.steps.trigger.Trigger': 2,
        '>>>buildbot.worker.base.Worker': 4,
        'buildbot.reporters.irc.IRC': 1},
    'www_plugins': ['buildbot_travis', 'waterfall_view']
    }
    
  • c['buildbotNetUsageData'] = 'full' sends the basic information plus additional information:

    • configuration of each builders: how the steps are arranged together. for example:

    {
        'builders': [
            ['buildbot.steps.source.git.Git',
             '>>>buildbot.process.buildstep.BuildStep'],
            ['buildbot.steps.source.git.Git',
             '>>buildbot.steps.trigger.Trigger'],
            ['buildbot.steps.source.git.Git',
             '>>>buildbot.process.buildstep.BuildStep'],
            ['buildbot.steps.source.git.Git',
             '>>buildbot.steps.trigger.Trigger']
        ]
    }
    
  • c['buildbotNetUsageData'] = myCustomFunction declares a callback to use to specify exactly what to send.

    This custom function takes the generated data from full report in the form of a dictionary, and returns a customized report as a jsonable dictionary. You can use this to filter any information you don’t want to disclose. You can also use a custom http_proxy environment variable in order to not send any data while developing your callback.

2.5.2.16. Users Options
from buildbot.plugins import util
c['user_managers'] = []
c['user_managers'].append(util.CommandlineUserManager(username="user",
                                                      passwd="userpw",
                                                      port=9990))

user_managers contains a list of ways to manually manage User Objects within Buildbot (see User Objects). Currently implemented is a commandline tool buildbot user, described at length in user. In the future, a web client will also be able to manage User Objects and their attributes.

As shown above, to enable the buildbot user tool, you must initialize a CommandlineUserManager instance in your master.cfg. CommandlineUserManager instances require the following arguments:

username

This is the username that will be registered on the PB connection and need to be used when calling buildbot user.

passwd

This is the passwd that will be registered on the PB connection and need to be used when calling buildbot user.

port

The PB connection port must be different than c[‘protocols’][‘pb’][‘port’] and be specified when calling buildbot user

2.5.2.17. Input Validation
import re
c['validation'] = {
    'branch' : re.compile(r'^[\w.+/~-]*$'),
    'revision' : re.compile(r'^[ \w\.\-\/]*$'),
    'property_name' : re.compile(r'^[\w\.\-\/\~:]*$'),
    'property_value' : re.compile(r'^[\w\.\-\/\~:]*$'),
}

This option configures the validation applied to user inputs of various types. This validation is important since these values are often included in command-line arguments executed on workers. Allowing arbitrary input from untrusted users may raise security concerns.

The keys describe the type of input validated; the values are compiled regular expressions against which the input will be matched. The defaults for each type of input are those given in the example, above.

2.5.2.19. Codebase Generator
all_repositories = {
    r'https://hg/hg/mailsuite/mailclient': 'mailexe',
    r'https://hg/hg/mailsuite/mapilib': 'mapilib',
    r'https://hg/hg/mailsuite/imaplib': 'imaplib',
    r'https://github.com/mailinc/mailsuite/mailclient': 'mailexe',
    r'https://github.com/mailinc/mailsuite/mapilib': 'mapilib',
    r'https://github.com/mailinc/mailsuite/imaplib': 'imaplib',
}

def codebaseGenerator(chdict):
    return all_repositories[chdict['repository']]

c['codebaseGenerator'] = codebaseGenerator

For any incoming change, the codebase is set to ‘’. This codebase value is sufficient if all changes come from the same repository (or clones). If changes come from different repositories, extra processing will be needed to determine the codebase for the incoming change. This codebase will then be a logical name for the combination of repository and or branch etc.

The codebaseGenerator accepts a change dictionary as produced by the buildbot.db.changes.ChangesConnectorComponent, with a changeid equal to None.

2.5.3. Change Sources and Changes

A change source is the mechanism which is used by Buildbot to get information about new changes in a repository maintained by a Version Control System.

These change sources fall broadly into two categories: pollers which periodically check the repository for updates; and hooks, where the repository is configured to notify Buildbot whenever an update occurs.

A Change is an abstract way that Buildbot uses to represent changes in any of the Version Control Systems it supports. It contains just enough information needed to acquire specific version of the tree when needed. This usually happens as one of the first steps in a Build.

This concept does not map perfectly to every version control system. For example, for CVS, Buildbot must guess that version updates made to multiple files within a short time represent a single change.

Changes can be provided by a variety of ChangeSource types, although any given project will typically have only a single ChangeSource active.

2.5.3.1. How Different VC Systems Specify Sources

For CVS, the static specifications are repository and module. In addition to those, each build uses a timestamp (or omits the timestamp to mean the latest) and branch tag (which defaults to HEAD). These parameters collectively specify a set of sources from which a build may be performed.

Subversion combines the repository, module, and branch into a single Subversion URL parameter. Within that scope, source checkouts can be specified by a numeric revision number (a repository-wide monotonically-increasing marker, such that each transaction that changes the repository is indexed by a different revision number), or a revision timestamp. When branches are used, the repository and module form a static baseURL, while each build has a revision number and a branch (which defaults to a statically-specified defaultBranch). The baseURL and branch are simply concatenated together to derive the repourl to use for the checkout.

Perforce is similar. The server is specified through a P4PORT parameter. Module and branch are specified in a single depot path, and revisions are depot-wide. When branches are used, the p4base and defaultBranch are concatenated together to produce the depot path.

Bzr (which is a descendant of Arch/Bazaar, and is frequently referred to as “Bazaar”) has the same sort of repository-vs-workspace model as Arch, but the repository data can either be stored inside the working directory or kept elsewhere (either on the same machine or on an entirely different machine). For the purposes of Buildbot (which never commits changes), the repository is specified with a URL and a revision number.

The most common way to obtain read-only access to a bzr tree is via HTTP, simply by making the repository visible through a web server like Apache. Bzr can also use FTP and SFTP servers, if the worker process has sufficient privileges to access them. Higher performance can be obtained by running a special Bazaar-specific server. None of these matter to the buildbot: the repository URL just has to match the kind of server being used. The repoURL argument provides the location of the repository.

Branches are expressed as subdirectories of the main central repository, which means that if branches are being used, the BZR step is given a baseURL and defaultBranch instead of getting the repoURL argument.

Darcs doesn’t really have the notion of a single master repository. Nor does it really have branches. In Darcs, each working directory is also a repository, and there are operations to push and pull patches from one of these repositories to another. For the Buildbot’s purposes, all you need to do is specify the URL of a repository that you want to build from. The worker will then pull the latest patches from that repository and build them. Multiple branches are implemented by using multiple repositories (possibly living on the same server).

Builders which use Darcs therefore have a static repourl which specifies the location of the repository. If branches are being used, the source Step is instead configured with a baseURL and a defaultBranch, and the two strings are simply concatenated together to obtain the repository’s URL. Each build then has a specific branch which replaces defaultBranch, or just uses the default one. Instead of a revision number, each build can have a context, which is a string that records all the patches that are present in a given tree (this is the output of darcs changes --context, and is considerably less concise than, e.g. Subversion’s revision number, but the patch-reordering flexibility of Darcs makes it impossible to provide a shorter useful specification).

Mercurial follows a decentralized model, and each repository can have several branches and tags. The source Step is configured with a static repourl which specifies the location of the repository. Branches are configured with the defaultBranch argument. The revision is the hash identifier returned by hg identify.

Git also follows a decentralized model, and each repository can have several branches and tags. The source Step is configured with a static repourl which specifies the location of the repository. In addition, an optional branch parameter can be specified to check out code from a specific branch instead of the default master branch. The revision is specified as a SHA1 hash as returned by e.g. git rev-parse. No attempt is made to ensure that the specified revision is actually a subset of the specified branch.

Monotone is another that follows a decentralized model where each repository can have several branches and tags. The source Step is configured with static repourl and branch parameters, which specifies the location of the repository and the branch to use. The revision is specified as a SHA1 hash as returned by e.g. mtn automate select w:. No attempt is made to ensure that the specified revision is actually a subset of the specified branch.

Comparison

Name

Change

Revision

Branches

CVS

patch [1]

timestamp

unnamed

Subversion

revision

integer

directories

Git

commit

sha1 hash

named refs

Mercurial

changeset

sha1 hash

different repos or (permanently) named commits

Darcs

?

none [2]

different repos

Bazaar

?

?

?

Perforce

?

?

?

BitKeeper

changeset

?

different repos

  • [1] note that CVS only tracks patches to individual files. Buildbot tries to recognize coordinated changes to multiple files by correlating change times.

  • [2] Darcs does not have a concise way of representing a particular revision of the source.

Tree Stability

Changes tend to arrive at a buildmaster in bursts. In many cases, these bursts of changes are meant to be taken together. For example, a developer may have pushed multiple commits to a DVCS that comprise the same new feature or bugfix. To avoid trying to build every change, Buildbot supports the notion of tree stability, by waiting for a burst of changes to finish before starting to schedule builds. This is implemented as a timer, with builds not scheduled until no changes have occurred for the duration of the timer.

2.5.3.2. Choosing a Change Source

There are a variety of ChangeSource classes available, some of which are meant to be used in conjunction with other tools to deliver Change events from the VC repository to the buildmaster.

As a quick guide, here is a list of VC systems and the ChangeSources that might be useful with them. Note that some of these modules are in Buildbot’s master/contrib directory, meaning that they have been offered by other users in hopes they may be useful, and might require some additional work to make them functional.

CVS

SVN

Darcs

Mercurial

Bzr (the newer Bazaar)

Git

Repo/Gerrit

Monotone

  • PBChangeSource (listening for connections from monotone-buildbot.lua, which is available with Monotone)

All VC systems can be driven by a PBChangeSource and the buildbot sendchange tool run from some form of commit script. If you write an email parsing function, they can also all be driven by a suitable mail-parsing source. Additionally, handlers for web-based notification (i.e. from GitHub) can be used with WebStatus’ change_hook module. The interface is simple, so adding your own handlers (and sharing!) should be a breeze.

See Change Source Index for a full list of change sources.

2.5.3.3. Configuring Change Sources

The change_source configuration key holds all active change sources for the configuration.

Most configurations have a single ChangeSource, watching only a single tree, e.g.,

from buildbot.plugins import changes

c['change_source'] = changes.PBChangeSource()

For more advanced configurations, the parameter can be a list of change sources:

source1 = ...
source2 = ...
c['change_source'] = [
    source1, source2
]
Repository and Project

ChangeSources will, in general, automatically provide the proper repository attribute for any changes they produce. For systems which operate on URL-like specifiers, this is a repository URL. Other ChangeSources adapt the concept as necessary.

Many ChangeSources allow you to specify a project, as well. This attribute is useful when building from several distinct codebases in the same buildmaster: the project string can serve to differentiate the different codebases. Schedulers can filter on project, so you can configure different builders to run for each project.

2.5.3.4. Mail-parsing ChangeSources

Many projects publish information about changes to their source tree by sending an email message out to a mailing list, frequently named PROJECT-commits or PROJECT-changes. Each message usually contains a description of the change (who made the change, which files were affected) and sometimes a copy of the diff. Humans can subscribe to this list to stay informed about what’s happening to the source tree.

Buildbot can also subscribe to a -commits mailing list, and can trigger builds in response to Changes that it hears about. The buildmaster admin needs to arrange for these email messages to arrive in a place where the buildmaster can find them, and configure the buildmaster to parse the messages correctly. Once that is in place, the email parser will create Change objects and deliver them to the schedulers (see Schedulers) just like any other ChangeSource.

There are two components to setting up an email-based ChangeSource. The first is to route the email messages to the buildmaster, which is done by dropping them into a maildir. The second is to actually parse the messages, which is highly dependent upon the tool that was used to create them. Each VC system has a collection of favorite change-emailing tools with a slightly different format and its own parsing function. Buildbot has a separate ChangeSource variant for each of these parsing functions.

Once you’ve chosen a maildir location and a parsing function, create the change source and put it in change_source:

from buildbot.plugins import changes

c['change_source'] = changes.CVSMaildirSource("~/maildir-buildbot",
                                              prefix="/trunk/")
Subscribing the Buildmaster

The recommended way to install Buildbot is to create a dedicated account for the buildmaster. If you do this, the account will probably have a distinct email address (perhaps buildmaster@example.org). Then just arrange for this account’s email to be delivered to a suitable maildir (described in the next section).

If Buildbot does not have its own account, extension addresses can be used to distinguish between emails intended for the buildmaster and emails intended for the rest of the account. In most modern MTAs, the e.g. foo@example.org account has control over every email address at example.org which begins with “foo”, such that emails addressed to account-foo@example.org can be delivered to a different destination than account-bar@example.org. qmail does this by using separate .qmail files for the two destinations (.qmail-foo and .qmail-bar, with .qmail controlling the base address and .qmail-default controlling all other extensions). Other MTAs have similar mechanisms.

Thus you can assign an extension address like foo-buildmaster@example.org to the buildmaster and retain foo@example.org for your own use.

Using Maildirs

A maildir is a simple directory structure originally developed for qmail that allows safe atomic update without locking. Create a base directory with three subdirectories: new, tmp, and cur. When messages arrive, they are put into a uniquely-named file (using pids, timestamps, and random numbers) in tmp. When the file is complete, it is atomically renamed into new. Eventually the buildmaster notices the file in new, reads and parses the contents, then moves it into cur. A cronjob can be used to delete files in cur at leisure.

Maildirs are frequently created with the maildirmake tool, but a simple mkdir -p ~/MAILDIR/cur,new,tmp is pretty much equivalent.

Many modern MTAs can deliver directly to maildirs. The usual .forward or .procmailrc syntax is to name the base directory with a trailing slash, so something like ~/MAILDIR/. qmail and postfix are maildir-capable MTAs, and procmail is a maildir-capable MDA (Mail Delivery Agent).

Here is an example procmail config, located in ~/.procmailrc:

# .procmailrc
# routes incoming mail to appropriate mailboxes
PATH=/usr/bin:/usr/local/bin
MAILDIR=$HOME/Mail
LOGFILE=.procmail_log
SHELL=/bin/sh

:0
*
new

If procmail is not setup on a system wide basis, then the following one-line .forward file will invoke it.

!/usr/bin/procmail

For MTAs which cannot put files into maildirs directly, the safecat tool can be executed from a .forward file to accomplish the same thing.

The Buildmaster uses the linux DNotify facility to receive immediate notification when the maildir’s new directory has changed. When this facility is not available, it polls the directory for new messages, every 10 seconds by default.

Parsing Email Change Messages

The second component to setting up an email-based ChangeSource is to parse the actual notices. This is highly dependent upon the VC system and commit script in use.

A couple of common tools used to create these change emails, along with the Buildbot tools to parse them, are:

CVS
Buildbot CVS MailNotifier

CVSMaildirSource

SVN
svnmailer

http://opensource.perlig.de/en/svnmailer/

commit-email.pl

SVNCommitEmailMaildirSource

Bzr
Launchpad

BzrLaunchpadEmailMaildirSource

Mercurial
NotifyExtension

https://www.mercurial-scm.org/wiki/NotifyExtension

Git
post-receive-email

http://git.kernel.org/?p=git/git.git;a=blob;f=contrib/hooks/post-receive-email;hb=HEAD

The following sections describe the parsers available for each of these tools.

Most of these parsers accept a prefix= argument, which is used to limit the set of files that the buildmaster pays attention to. This is most useful for systems like CVS and SVN which put multiple projects in a single repository (or use repository names to indicate branches). Each filename that appears in the email is tested against the prefix: if the filename does not start with the prefix, the file is ignored. If the filename does start with the prefix, that prefix is stripped from the filename before any further processing is done. Thus the prefix usually ends with a slash.

CVSMaildirSource
class buildbot.changes.mail.CVSMaildirSource

This parser works with the master/contrib/buildbot_cvs_mail.py script.

The script sends an email containing all the files submitted in one directory. It is invoked by using the CVSROOT/loginfo facility.

The Buildbot’s CVSMaildirSource knows how to parse these messages and turn them into Change objects. It takes the directory name of the maildir root. For example:

from buildbot.plugins import changes

c['change_source'] = changes.CVSMaildirSource("/home/buildbot/Mail")
Configuration of CVS and buildbot_cvs_mail.py

CVS must be configured to invoke the buildbot_cvs_mail.py script when files are checked in. This is done via the CVS loginfo configuration file.

To update this, first do:

cvs checkout CVSROOT

cd to the CVSROOT directory and edit the file loginfo, adding a line like:

SomeModule /cvsroot/CVSROOT/buildbot_cvs_mail.py --cvsroot :ext:example.com:/cvsroot -e buildbot -P SomeModule %@{sVv@}

Note

For cvs version 1.12.x, the --path %p option is required. Version 1.11.x and 1.12.x report the directory path differently.

The above example you put the buildbot_cvs_mail.py script under /cvsroot/CVSROOT. It can be anywhere. Run the script with --help to see all the options. At the very least, the options -e (email) and -P (project) should be specified. The line must end with %{sVv}. This is expanded to the files that were modified.

Additional entries can be added to support more modules.

See buildbot_cvs_mail.py --help for more information on the available options.

SVNCommitEmailMaildirSource
class buildbot.changes.mail.SVNCommitEmailMaildirSource

SVNCommitEmailMaildirSource parses message sent out by the commit-email.pl script, which is included in the Subversion distribution.

It does not currently handle branches: all of the Change objects that it creates will be associated with the default (i.e. trunk) branch.

from buildbot.plugins import changes

c['change_source'] = changes.SVNCommitEmailMaildirSource("~/maildir-buildbot")
BzrLaunchpadEmailMaildirSource
class buildbot.changes.mail.BzrLaunchpadEmailMaildirSource

BzrLaunchpadEmailMaildirSource parses the mails that are sent to addresses that subscribe to branch revision notifications for a bzr branch hosted on Launchpad.

The branch name defaults to lp:Launchpad path. For example lp:~maria-captains/maria/5.1.

If only a single branch is used, the default branch name can be changed by setting defaultBranch.

For multiple branches, pass a dictionary as the value of the branchMap option to map specific repository paths to specific branch names (see example below). The leading lp: prefix of the path is optional.

The prefix option is not supported (it is silently ignored). Use the branchMap and defaultBranch instead to assign changes to branches (and just do not subscribe the Buildbot to branches that are not of interest).

The revision number is obtained from the email text. The bzr revision id is not available in the mails sent by Launchpad. However, it is possible to set the bzr append_revisions_only option for public shared repositories to avoid new pushes of merges changing the meaning of old revision numbers.

from buildbot.plugins import changes

bm = {
    'lp:~maria-captains/maria/5.1': '5.1',
    'lp:~maria-captains/maria/6.0': '6.0'
}
c['change_source'] = changes.BzrLaunchpadEmailMaildirSource("~/maildir-buildbot",
                                                            branchMap=bm)
2.5.3.5. PBChangeSource
class buildbot.changes.pb.PBChangeSource

PBChangeSource actually listens on a TCP port for clients to connect and push change notices into the Buildmaster. This is used by the built-in buildbot sendchange notification tool, as well as several version-control hook scripts. This change is also useful for creating new kinds of change sources that work on a push model instead of some kind of subscription scheme, for example a script which is run out of an email .forward file. This ChangeSource always runs on the same TCP port as the workers. It shares the same protocol, and in fact shares the same space of “usernames”, so you cannot configure a PBChangeSource with the same name as a worker.

If you have a publicly accessible worker port and are using PBChangeSource, you must establish a secure username and password for the change source. If your sendchange credentials are known (e.g., the defaults), then your buildmaster is susceptible to injection of arbitrary changes, which (depending on the build factories) could lead to arbitrary code execution on workers.

The PBChangeSource is created with the following arguments.

port

Which port to listen on. If None (which is the default), it shares the port used for worker connections.

user

The user account that the client program must use to connect. Defaults to change

passwd

The password for the connection - defaults to changepw. Can be a Secret. Do not use this default on a publicly exposed port!

prefix

The prefix to be found and stripped from filenames delivered over the connection, defaulting to None. Any filenames which do not start with this prefix will be removed. If all the filenames in a given Change are removed, then that whole Change will be dropped. This string should probably end with a directory separator.

This is useful for changes coming from version control systems that represent branches as parent directories within the repository (like SVN and Perforce). Use a prefix of trunk/ or project/branches/foobranch/ to only follow one branch and to get correct tree-relative filenames. Without a prefix, the PBChangeSource will probably deliver Changes with filenames like trunk/foo.c instead of just foo.c. Of course this also depends upon the tool sending the Changes in (like buildbot sendchange) and what filenames it is delivering: that tool may be filtering and stripping prefixes at the sending end.

For example:

from buildbot.plugins import changes

c['change_source'] = changes.PBChangeSource(port=9999, user='laura', passwd='fpga')

The following hooks are useful for sending changes to a PBChangeSource:

Bzr Hook

Bzr is also written in Python, and the Bzr hook depends on Twisted to send the changes.

To install, put master/contrib/bzr_buildbot.py in one of your plugins locations a bzr plugins directory (e.g., ~/.bazaar/plugins). Then, in one of your bazaar conf files (e.g., ~/.bazaar/locations.conf), set the location you want to connect with Buildbot with these keys:

  • buildbot_on one of ‘commit’, ‘push, or ‘change’. Turns the plugin on to report changes via commit, changes via push, or any changes to the trunk. ‘change’ is recommended.

  • buildbot_server (required to send to a Buildbot master) the URL of the Buildbot master to which you will connect (as of this writing, the same server and port to which workers connect).

  • buildbot_port (optional, defaults to 9989) the port of the Buildbot master to which you will connect (as of this writing, the same server and port to which workers connect)

  • buildbot_pqm (optional, defaults to not pqm) Normally, the user that commits the revision is the user that is responsible for the change. When run in a pqm (Patch Queue Manager, see https://launchpad.net/pqm) environment, the user that commits is the Patch Queue Manager, and the user that committed the parent revision is responsible for the change. To turn on the pqm mode, set this value to any of (case-insensitive) “Yes”, “Y”, “True”, or “T”.

  • buildbot_dry_run (optional, defaults to not a dry run) Normally, the post-commit hook will attempt to communicate with the configured Buildbot server and port. If this parameter is included and any of (case-insensitive) “Yes”, “Y”, “True”, or “T”, then the hook will simply print what it would have sent, but not attempt to contact the Buildbot master.

  • buildbot_send_branch_name (optional, defaults to not sending the branch name) If your Buildbot’s bzr source build step uses a repourl, do not turn this on. If your buildbot’s bzr build step uses a baseURL, then you may set this value to any of (case-insensitive) “Yes”, “Y”, “True”, or “T” to have the Buildbot master append the branch name to the baseURL.

Note

The bzr smart server (as of version 2.2.2) doesn’t know how to resolve bzr:// urls into absolute paths so any paths in locations.conf won’t match, hence no change notifications will be sent to Buildbot. Setting configuration parameters globally or in-branch might still work. When Buildbot no longer has a hardcoded password, it will be a configuration option here as well.

Here’s a simple example that you might have in your ~/.bazaar/locations.conf.

[chroot-*:///var/local/myrepo/mybranch]
buildbot_on = change
buildbot_server = localhost
2.5.3.6. P4Source

The P4Source periodically polls a Perforce depot for changes. It accepts the following arguments:

p4port

The Perforce server to connect to (as host:port).

p4user

The Perforce user.

p4passwd

The Perforce password.

p4base

The base depot path to watch, without the trailing ‘/…’.

p4bin

An optional string parameter. Specify the location of the perforce command line binary (p4). You only need to do this if the perforce binary is not in the path of the Buildbot user. Defaults to p4.

split_file

A function that maps a pathname, without the leading p4base, to a (branch, filename) tuple. The default just returns (None, branchfile), which effectively disables branch support. You should supply a function which understands your repository structure.

pollInterval

How often to poll, in seconds. Defaults to 600 (10 minutes).

pollRandomDelayMin

Minimum delay in seconds to wait before each poll, default is 0. This is useful in case you have a lot of pollers and you want to spread the polling load over a period of time. Setting it equal to the maximum delay will effectively delay all polls by a fixed amount of time. Must be less than or equal to the maximum delay.

pollRandomDelayMax

Maximum delay in seconds to wait before each poll, default is 0. This is useful in case you have a lot of pollers and you want to spread the polling load over a period of time. Must be less than the poll interval.

project

Set the name of the project to be used for the P4Source. This will then be set in any changes generated by the P4Source, and can be used in a Change Filter for triggering particular builders.

pollAtLaunch

Determines when the first poll occurs. True = immediately on launch, False = wait for one pollInterval (default).

histmax

The maximum number of changes to inspect at a time. If more than this number occur since the last poll, older changes will be silently ignored.

encoding

The character encoding of p4's output. This defaults to “utf8”, but if your commit messages are in another encoding, specify that here. For example, if you’re using Perforce on Windows, you may need to use “cp437” as the encoding if “utf8” generates errors in your master log.

server_tz

The timezone of the Perforce server, using the usual timezone format (e.g: "Europe/Stockholm") in case it’s not in UTC.

use_tickets

Set to True to use ticket-based authentication, instead of passwords (but you still need to specify p4passwd).

ticket_login_interval

How often to get a new ticket, in seconds, when use_tickets is enabled. Defaults to 86400 (24 hours).

revlink

A function that maps branch and revision to a valid url (e.g. p4web), stored along with the change. This function must be a callable which takes two arguments, the branch and the revision. Defaults to lambda branch, revision: (u’’)

resolvewho

A function that resolves the Perforce ‘user@workspace’ into a more verbose form, stored as the author of the change. Useful when usernames do not match email addresses and external, client-side lookup is required. This function must be a callable which takes one argument. Defaults to lambda who: (who)

Example #1

This configuration uses the P4PORT, P4USER, and P4PASSWD specified in the buildmaster’s environment. It watches a project in which the branch name is simply the next path component, and the file is all path components after.

from buildbot.plugins import changes

s = changes.P4Source(p4base='//depot/project/',
                     split_file=lambda branchfile: branchfile.split('/',1))
c['change_source'] = s
Example #2

Similar to the previous example but also resolves the branch and revision into a valid revlink.

from buildbot.plugins import changes

s = changes.P4Source(
    p4base='//depot/project/',
    split_file=lambda branchfile: branchfile.split('/',1))
    revlink=lambda branch, revision: 'http://p4web:8080/@md=d&@/{}?ac=10'.format(revision)
c['change_source'] = s
2.5.3.7. SVNPoller
class buildbot.changes.svnpoller.SVNPoller

The SVNPoller is a ChangeSource which periodically polls a Subversion repository for new revisions, by running the svn log command in a subshell. It can watch a single branch or multiple branches.

SVNPoller accepts the following arguments:

repourl

The base URL path to watch, like svn://svn.twistedmatrix.com/svn/Twisted/trunk, or http://divmod.org/svn/Divmo/, or even file:///home/svn/Repository/ProjectA/branches/1.5/. This must include the access scheme, the location of the repository (both the hostname for remote ones, and any additional directory names necessary to get to the repository), and the sub-path within the repository’s virtual filesystem for the project and branch of interest.

The SVNPoller will only pay attention to files inside the subdirectory specified by the complete repourl.

split_file

A function to convert pathnames into (branch, relative_pathname) tuples. Use this to explain your repository’s branch-naming policy to SVNPoller. This function must accept a single string (the pathname relative to the repository) and return a two-entry tuple. Directory pathnames always end with a right slash to distinguish them from files, like trunk/src/, or src/. There are a few utility functions in buildbot.changes.svnpoller that can be used as a split_file function; see below for details.

For directories, the relative pathname returned by split_file should end with a right slash but an empty string is also accepted for the root, like ("branches/1.5.x", "") being converted from "branches/1.5.x/".

The default value always returns (None, path), which indicates that all files are on the trunk.

Subclasses of SVNPoller can override the split_file method instead of using the split_file= argument.

project

Set the name of the project to be used for the SVNPoller. This will then be set in any changes generated by the SVNPoller, and can be used in a Change Filter for triggering particular builders.

svnuser

An optional string parameter. If set, the option –user argument will be added to all svn commands. Use this if you have to authenticate to the svn server before you can do svn info or svn log commands. Can be a Secret.

svnpasswd

Like svnuser, this will cause a option –password argument to be passed to all svn commands. Can be a Secret.

pollInterval

How often to poll, in seconds. Defaults to 600 (checking once every 10 minutes). Lower this if you want the Buildbot to notice changes faster, raise it if you want to reduce the network and CPU load on your svn server. Please be considerate of public SVN repositories by using a large interval when polling them.

pollRandomDelayMin

Minimum delay in seconds to wait before each poll, default is 0. This is useful in case you have a lot of pollers and you want to spread the polling load over a period of time. Setting it equal to the maximum delay will effectively delay all polls by a fixed amount of time. Must be less than or equal to the maximum delay.

pollRandomDelayMax

Maximum delay in seconds to wait before each poll, default is 0. This is useful in case you have a lot of pollers and you want to spread the polling load over a period of time. Must be less than the poll interval.

pollAtLaunch

Determines when the first poll occurs. True = immediately on launch, False = wait for one pollInterval (default).

histmax

The maximum number of changes to inspect at a time. Every pollInterval seconds, the SVNPoller asks for the last histmax changes and looks through them for any revisions it does not already know about. If more than histmax revisions have been committed since the last poll, older changes will be silently ignored. Larger values of histmax will cause more time and memory to be consumed on each poll attempt. histmax defaults to 100.

svnbin

This controls the svn executable to use. If subversion is installed in a weird place on your system (outside of the buildmaster’s PATH), use this to tell SVNPoller where to find it. The default value of svn will almost always be sufficient.

revlinktmpl

This parameter is deprecated in favour of specifying a global revlink option. This parameter allows a link to be provided for each revision (for example, to websvn or viewvc). These links appear anywhere changes are shown, such as on build or change pages. The proper form for this parameter is an URL with the portion that will substitute for a revision number replaced by ‘’%s’’. For example, 'http://myserver/websvn/revision.php?rev=%s' could be used to cause revision links to be created to a websvn repository viewer.

cachepath

If specified, this is a pathname of a cache file that SVNPoller will use to store its state between restarts of the master.

extra_args

If specified, the extra arguments will be added to the svn command args.

Several split file functions are available for common SVN repository layouts. For a poller that is only monitoring trunk, the default split file function is available explicitly as split_file_alwaystrunk:

from buildbot.plugins import changes, util

c['change_source'] = changes.SVNPoller(
    repourl="svn://svn.twistedmatrix.com/svn/Twisted/trunk",
    split_file=util.svn.split_file_alwaystrunk)

For repositories with the /trunk and /branches/BRANCH layout, split_file_branches will do the job:

from buildbot.plugins import changes, util

c['change_source'] = changes.SVNPoller(
    repourl="https://amanda.svn.sourceforge.net/svnroot/amanda/amanda",
    split_file=util.svn.split_file_branches)

When using this splitter the poller will set the project attribute of any changes to the project attribute of the poller.

For repositories with the PROJECT/trunk and PROJECT/branches/BRANCH layout, split_file_projects_branches will do the job:

from buildbot.plugins import changes, util

c['change_source'] = changes.SVNPoller(
    repourl="https://amanda.svn.sourceforge.net/svnroot/amanda/",
    split_file=util.svn.split_file_projects_branches)

When using this splitter the poller will set the project attribute of any changes to the project determined by the splitter.

The SVNPoller is highly adaptable to various Subversion layouts. See Customizing SVNPoller for details and some common scenarios.

2.5.3.8. Bzr Poller

If you cannot insert a Bzr hook in the server, you can use the BzrPoller. To use it, put master/contrib/bzr_buildbot.py somewhere that your Buildbot configuration can import it. Even putting it in the same directory as the master.cfg should work. Install the poller in the Buildbot configuration as with any other change source. Minimally, provide a URL that you want to poll (bzr://, bzr+ssh://, or lp:), making sure the Buildbot user has necessary privileges.

# put bzr_buildbot.py file to the same directory as master.cfg
from bzr_buildbot import BzrPoller

c['change_source'] = BzrPoller(
    url='bzr://hostname/my_project',
    poll_interval=300)

The BzrPoller parameters are:

url

The URL to poll.

poll_interval

The number of seconds to wait between polls. Defaults to 10 minutes.

branch_name

Any value to be used as the branch name. Defaults to None, or specify a string, or specify the constants from bzr_buildbot.py SHORT or FULL to get the short branch name or full branch address.

blame_merge_author

Normally, the user that commits the revision is the user that is responsible for the change. When run in a pqm (Patch Queue Manager, see https://launchpad.net/pqm) environment, the user that commits is the Patch Queue Manager, and the user that committed the merged, parent revision is responsible for the change. Set this value to True if this is pointed against a PQM-managed branch.

2.5.3.9. GitPoller

If you cannot take advantage of post-receive hooks as provided by master/contrib/git_buildbot.py for example, then you can use the GitPoller.

The GitPoller periodically fetches from a remote Git repository and processes any changes. It requires its own working directory for operation. The default should be adequate, but it can be overridden via the workdir property.

Note

There can only be a single GitPoller pointed at any given repository.

The GitPoller requires Git-1.7 and later. It accepts the following arguments:

repourl

The git-url that describes the remote repository, e.g. git@example.com:foobaz/myrepo.git (see the git fetch help for more info on git-url formats)

branches

One of the following:

  • a list of the branches to fetch. Non-existing branches are ignored.

  • True indicating that all branches should be fetched

  • a callable which takes a single argument. It should take a remote refspec (such as 'refs/heads/master'), and return a boolean indicating whether that branch should be fetched.

branch

Accepts a single branch name to fetch. Exists for backwards compatibility with old configurations.

pollInterval

Interval in seconds between polls, default is 10 minutes

pollRandomDelayMin

Minimum delay in seconds to wait before each poll, default is 0. This is useful in case you have a lot of pollers and you want to spread the polling load over a period of time. Setting it equal to the maximum delay will effectively delay all polls by a fixed amount of time. Must be less than or equal to the maximum delay.

pollRandomDelayMax

Maximum delay in seconds to wait before each poll, default is 0. This is useful in case you have a lot of pollers and you want to spread the polling load over a period of time. Must be less than the poll interval.

pollAtLaunch

Determines when the first poll occurs. True = immediately on launch, False = wait for one pollInterval (default).

buildPushesWithNoCommits

Determines if a push on a new branch or update of an already known branch with already known commits should trigger a build. This is useful in case you have build steps depending on the name of the branch and you use topic branches for development. When you merge your topic branch into “master” (for instance), a new build will be triggered. (defaults to False).

gitbin

Path to the Git binary, defaults to just 'git'

category

Set the category to be used for the changes produced by the GitPoller. This will then be set in any changes generated by the GitPoller, and can be used in a Change Filter for triggering particular builders.

project

Set the name of the project to be used for the GitPoller. This will then be set in any changes generated by the GitPoller, and can be used in a Change Filter for triggering particular builders.

usetimestamps

Parse each revision’s commit timestamp (default is True), or ignore it in favor of the current time, so that recently processed commits appear together in the waterfall page.

encoding

Set encoding will be used to parse author’s name and commit message. Default encoding is 'utf-8'. This will not be applied to file names since Git will translate non-ascii file names to unreadable escape sequences.

workdir

The directory where the poller should keep its local repository. The default is gitpoller_work. If this is a relative path, it will be interpreted relative to the master’s basedir. Multiple Git pollers can share the same directory.

only_tags

Determines if the GitPoller should poll for new tags in the git repository.

sshPrivateKey (optional)

Specifies private SSH key for git to use. This may be either a Secret or just a string. This option requires Git-2.3 or later. The master must either have the host in the known hosts file or the host key must be specified via the sshHostKey option.

sshHostKey (optional)

Specifies public host key to match when authenticating with SSH public key authentication. This may be either a Secret or just a string. sshPrivateKey must be specified in order to use this option. The host key must be in the form of <key type> <base64-encoded string>, e.g. ssh-rsa AAAAB3N<…>FAaQ==.

sshKnownHosts (optional)

Specifies the contents of the SSH known_hosts file to match when authenticating with SSH public key authentication. This may be either a Secret or just a string. sshPrivateKey must be specified in order to use this option. sshHostKey must not be specified in order to use this option.

A configuration for the Git poller might look like this:

from buildbot.plugins import changes

c['change_source'] = changes.GitPoller(repourl='git@example.com:foobaz/myrepo.git',
                                       branches=['master', 'great_new_feature'])
2.5.3.10. HgPoller

The HgPoller periodically pulls a named branch from a remote Mercurial repository and processes any changes. It requires its own working directory for operation, which must be specified via the workdir property.

The HgPoller requires a working hg executable, and at least a read-only access to the repository it polls (possibly through ssh keys or by tweaking the hgrc of the system user Buildbot runs as).

The HgPoller will not transmit any change if there are several heads on the watched named branch. This is similar (although not identical) to the Mercurial executable behaviour. This exceptional condition is usually the result of a developer mistake, and usually does not last for long. It is reported in logs. If fixed by a later merge, the buildmaster administrator does not have anything to do: that merge will be transmitted, together with the intermediate ones.

The HgPoller accepts the following arguments:

name

The name of the poller. This must be unique, and defaults to the repourl.

repourl

The url that describes the remote repository, e.g. http://hg.example.com/projects/myrepo. Any url suitable for hg pull can be specified.

bookmarks

A list of the bookmarks to monitor.

branches

A list of the branches to monitor; defaults to ['default'].

branch

The desired branch to pull. Exists for backwards compatibility with old configurations.

workdir

The directory where the poller should keep its local repository. It is mandatory for now, although later releases may provide a meaningful default.

It also serves to identify the poller in the buildmaster internal database. Changing it may result in re-processing all changes so far.

Several HgPoller instances may share the same workdir for mutualisation of the common history between two different branches, thus easing on local and remote system resources and bandwidth.

If relative, the workdir will be interpreted from the master directory.

pollInterval

Interval in seconds between polls, default is 10 minutes

pollRandomDelayMin

Minimum delay in seconds to wait before each poll, default is 0. This is useful in case you have a lot of pollers and you want to spread the polling load over a period of time. Setting it equal to the maximum delay will effectively delay all polls by a fixed amount of time. Must be less than or equal to the maximum delay.

pollRandomDelayMax

Maximum delay in seconds to wait before each poll, default is 0. This is useful in case you have a lot of pollers and you want to spread the polling load over a period of time. Must be less than the poll interval.

pollAtLaunch

Determines when the first poll occurs. True = immediately on launch, False = wait for one pollInterval (default).

hgbin

Path to the Mercurial binary, defaults to just 'hg'.

category

Set the category to be used for the changes produced by the HgPoller. This will then be set in any changes generated by the HgPoller, and can be used in a Change Filter for triggering particular builders.

project

Set the name of the project to be used for the HgPoller. This will then be set in any changes generated by the HgPoller, and can be used in a Change Filter for triggering particular builders.

usetimestamps

Parse each revision’s commit timestamp (default is True), or ignore it in favor of the current time, so that recently processed commits appear together in the waterfall page.

encoding

Set encoding will be used to parse author’s name and commit message. Default encoding is 'utf-8'.

revlink

A function that maps branch and revision to a valid url (e.g. hgweb), stored along with the change. This function must be a callable which takes two arguments, the branch and the revision. Defaults to lambda branch, revision: (u’’)

A configuration for the Mercurial poller might look like this:

from buildbot.plugins import changes

c['change_source'] = changes.HgPoller(repourl='http://hg.example.org/projects/myrepo',
                                      branch='great_new_feature',
                                      workdir='hg-myrepo')
2.5.3.11. GitHubPullrequestPoller
class buildbot.changes.github.GitHubPullrequestPoller

This GitHubPullrequestPoller periodically polls the GitHub API for new or updated pull requests. The author, revision, revlink, branch and files fields in the recorded changes are populated with information extracted from the pull request. This allows to filter for certain changes in files and create a blamelist based on the authors in the GitHub pull request.

The GitHubPullrequestPoller accepts the following arguments:

owner

The owner of the GitHub repository. This argument is required.

repo

The name of the GitHub repository. This argument is required.

branches

List of branches to accept as base branch (e.g. master). Defaults to None and accepts all branches as base.

pollInterval

Poll interval between polls in seconds. Default is 10 minutes.

pollAtLaunch

Whether to poll on startup of the buildbot master. Default is False and first poll will occur pollInterval seconds after the master start.

category

Set the category to be used for the changes produced by the GitHubPullrequestPoller. This will then be set in any changes generated by the GitHubPullrequestPoller, and can be used in a Change Filter for triggering particular builders.

project

Set the name of the project to be used for the GitHubPullrequestPoller. This will then be set in any changes generated by the GitHubPullrequestPoller, and can be used in a Change Filter for triggering particular builders. If unset, the default is to use the full name of the project as returned by the GitHub API.

baseURL

GitHub API endpoint. Default is https://api.github.com.

pullrequest_filter

A callable which takes a dict which contains the decoded JSON object of the GitHub pull request as argument. All fields specified by the GitHub API are accessible. If the callable returns False the pull request is ignored. Default is True which does not filter any pull requests.

token

A GitHub API token to execute all requests to the API authenticated. It is strongly recommended to use a API token since it increases GitHub API rate limits significantly.

repository_type

Set which type of repository link will be in the repository property. Possible values https, svn, git or svn. This link can then be used in a Source Step to checkout the source.

magic_link

Set to True if the changes should contain refs/pulls/<PR #>/merge in the branch property and a link to the base repository in the repository property. These properties can be used by the GitHub source to pull from the special branch in the base repository. Default is False.

github_property_whitelist

A list of fnmatch expressions which match against the flattened pull request information JSON prefixed with github. For example github.number represents the pull request number. Available entries can be looked up in the GitHub API Documentation or by examining the data returned for a pull request by the API.

2.5.3.12. BitbucketPullrequestPoller
class buildbot.changes.bitbucket.BitbucketPullrequestPoller

This BitbucketPullrequestPoller periodically polls Bitbucket for new or updated pull requests. It uses Bitbuckets powerful Pull Request REST API to gather the information needed.

The BitbucketPullrequestPoller accepts the following arguments:

owner

The owner of the Bitbucket repository. All Bitbucket Urls are of the form https://bitbucket.org/owner/slug/.

slug

The name of the Bitbucket repository.

auth

Authorization data tuple (usename, password) (optional). If set, it will be used as authorization headers at Bitbucket API.

branch

A single branch or a list of branches which should be processed. If it is None (the default) all pull requests are used.

pollInterval

Interval in seconds between polls, default is 10 minutes.

pollAtLaunch

Determines when the first poll occurs. True = immediately on launch, False = wait for one pollInterval (default).

category

Set the category to be used by the BitbucketPullrequestPoller. This will then be set in any changes generated by the BitbucketPullrequestPoller, and can be used in a Change Filter for triggering particular builders.

project

Set the name of the project to be used by the BitbucketPullrequestPoller. This will then be set in any changes generated by the BitbucketPullrequestPoller, and can be used in a Change Filter for triggering particular builders.

pullrequest_filter

A callable which takes one parameter, the decoded Python object of the pull request JSON. If it returns False, the pull request is ignored. It can be used to define custom filters based on the content of the pull request. See the Bitbucket documentation for more information about the format of the response. By default, the filter always returns True.

usetimestamps

Parse each revision’s commit timestamp (default is True), or ignore it in favor of the current time, so that recently processed commits appear together in the waterfall page.

bitbucket_property_whitelist

A list of fnmatch expressions which match against the flattened pull request information JSON prefixed with bitbucket. For example bitbucket.id represents the pull request ID. Available entries can be looked up in the BitBucket API Documentation or by examining the data returned for a pull request by the API.

encoding

This parameter is deprecated and has no effects. Author’s name and commit message are always parsed in 'utf-8'.

A minimal configuration for the Bitbucket pull request poller might look like this:

from buildbot.plugins import changes

c['change_source'] = changes.BitbucketPullrequestPoller(
    owner='myname',
    slug='myrepo',
  )

Here is a more complex configuration using a pullrequest_filter. The pull request is only processed if at least 3 people have already approved it:

def approve_filter(pr, threshold):
    approves = 0
    for participant in pr['participants']:
        if participant['approved']:
            approves = approves + 1

    if approves < threshold:
        return False
    return True

from buildbot.plugins import changes
c['change_source'] = changes.BitbucketPullrequestPoller(
    owner='myname',
    slug='myrepo',
    branch='mybranch',
    project='myproject',
    pullrequest_filter=lambda pr : approve_filter(pr,3),
    pollInterval=600,
)

Warning

Anyone who can create pull requests for the Bitbucket repository can initiate a change, potentially causing the buildmaster to run arbitrary code.

2.5.3.13. GerritChangeSource
class buildbot.changes.gerritchangesource.GerritChangeSource

The GerritChangeSource class connects to a Gerrit server by its SSH interface and uses its event source mechanism, gerrit stream-events.

Note that the Gerrit event stream is stateless and any events that occur while buildbot is not connected to Gerrit will be lost. See GerritEventLogPoller for a stateful change source.

The patchset-created and ref-updated events will be deduplicated, that is, if multiple events related to the same revision are received, only the first will be acted upon. This allows GerritChangeSource to be used together with GerritEventLogPoller.

The GerritChangeSource accepts the following arguments:

gerritserver

The dns or ip that host the Gerrit ssh server

gerritport

The port of the Gerrit ssh server

username

The username to use to connect to Gerrit

identity_file

Ssh identity file to for authentication (optional). Pay attention to the ssh passphrase

handled_events

Event to be handled (optional). By default processes patchset-created and ref-updated

get_files

Populate the files attribute of emitted changes (default False). Buildbot will run an extra query command for each handled event to determine the changed files.

ssh_server_alive_interval_s

Sets the ServerAliveInterval option of the ssh client (default 15). This causes client to emit periodic keepalive messages in case the connection is not otherwise active. If the server does not respond at least ssh_server_alive_count_max times, a reconnection is forced. This helps to avoid stuck connections in case network link is severed without notification in the TCP layer. Specifying None will omit the option from the ssh client command line.

ssh_server_alive_count_max

Sets the ServerAliveCountMax option of the ssh client (default 3). If the server does not respond at least ssh_server_alive_count_max times, a reconnection is forced. This helps to avoid stuck connections in case network link is severed without notification in the TCP layer. Specifying None will omit the option from the ssh client command line.

debug

Print Gerrit event in the log (default False). This allows to debug event content, but will eventually fill your logs with useless Gerrit event logs.

By default this class adds a change to the Buildbot system for each of the following events:

patchset-created

A change is proposed for review. Automatic checks like checkpatch.pl can be automatically triggered. Beware of what kind of automatic task you trigger. At this point, no trusted human has reviewed the code, and a patch could be specially crafted by an attacker to compromise your workers.

ref-updated

A change has been merged into the repository. Typically, this kind of event can lead to a complete rebuild of the project, and upload binaries to an incremental build results server.

But you can specify how to handle events:

  • Any event with change and patchSet will be processed by universal collector by default.

  • In case you’ve specified processing function for the given kind of events, all events of this kind will be processed only by this function, bypassing universal collector.

An example:

from buildbot.plugins import changes

class MyGerritChangeSource(changes.GerritChangeSource):
    """Custom GerritChangeSource
    """
    def eventReceived_patchset_created(self, properties, event):
        """Handler events without properties
        """
        properties = {}
        self.addChangeFromEvent(properties, event)

This class will populate the property list of the triggered build with the info received from Gerrit server in JSON format.

Warning

If you selected GerritChangeSource, you must use Gerrit source step: the branch property of the change will be target_branch/change_id and such a ref cannot be resolved, so the Git source step would fail.

In case of patchset-created event, these properties will be:

event.change.branch

Branch of the Change

event.change.id

Change’s ID in the Gerrit system (the ChangeId: in commit comments)

event.change.number

Change’s number in Gerrit system

event.change.owner.email

Change’s owner email (owner is first uploader)

event.change.owner.name

Change’s owner name

event.change.project

Project of the Change

event.change.subject

Change’s subject

event.change.url

URL of the Change in the Gerrit’s web interface

event.patchSet.number

Patchset’s version number

event.patchSet.ref

Patchset’s Gerrit “virtual branch”

event.patchSet.revision

Patchset’s Git commit ID

event.patchSet.uploader.email

Patchset uploader’s email (owner is first uploader)

event.patchSet.uploader.name

Patchset uploader’s name (owner is first uploader)

event.type

Event type (patchset-created)

event.uploader.email

Patchset uploader’s email

event.uploader.name

Patchset uploader’s name

In case of ref-updated event, these properties will be:

event.refUpdate.newRev

New Git commit ID (after merger)

event.refUpdate.oldRev

Previous Git commit ID (before merger)

event.refUpdate.project

Project that was updated

event.refUpdate.refName

Branch that was updated

event.submitter.email

Submitter’s email (merger responsible)

event.submitter.name

Submitter’s name (merger responsible)

event.type

Event type (ref-updated)

event.submitter.email

Submitter’s email (merger responsible)

event.submitter.name

Submitter’s name (merger responsible)

A configuration for this source might look like:

from buildbot.plugins import changes

c['change_source'] = changes.GerritChangeSource(
    "gerrit.example.com",
    "gerrit_user",
    handled_events=["patchset-created", "change-merged"])

See master/docs/examples/git_gerrit.cfg or master/docs/examples/repo_gerrit.cfg in the Buildbot distribution for a full example setup of Git+Gerrit or Repo+Gerrit of GerritChangeSource.

2.5.3.14. GerritEventLogPoller
class buildbot.changes.gerritchangesource.GerritEventLogPoller

The GerritEventLogPoller class is similar to GerritChangeSource but connects to the Gerrit server by its HTTP interface and uses the events-log plugin.

Note that the decision of whether to use GerritEventLogPoller and GerritChangeSource will depend on your needs. The trade off is:

  1. GerritChangeSource is low-overhead and reacts instantaneously to events, but a broken connection to Gerrit will lead to missed changes

  2. GerritEventLogPoller is subject to polling overhead and reacts only at it’s polling rate, but is robust to a broken connection to Gerrit and missed changes will be discovered when a connection is restored.

You can use both at the same time to get the advantages of each. They will coordinate through the database to avoid duplicate changes generated for buildbot.

Note

The GerritEventLogPoller requires either the txrequest or the treq package.

The GerritEventLogPoller accepts the following arguments:

baseURL

The HTTP url where to find Gerrit. If the URL of the events-log endpoint for your server is https://example.com/a/plugins/events-log/events/ then the baseURL is https://example.com/a. Ensure that /a is included.

auth

A request’s authentication configuration. If Gerrit is configured with BasicAuth, then it shall be ('login', 'password'). If Gerrit is configured with DigestAuth, then it shall be requests.auth.HTTPDigestAuth('login', 'password') from the requests module. However, note that usage of requests.auth.HTTPDigestAuth is incompatible with treq.

handled_events

Event to be handled (optional). By default processes patchset-created and ref-updated.

pollInterval

Interval in seconds between polls (default is 30 sec).

pollAtLaunch

Determines when the first poll occurs. True = immediately on launch (default), False = wait for one pollInterval.

gitBaseURL

The git URL where Gerrit is accessible via git+ssh protocol.

get_files

Populate the files attribute of emitted changes (default False). Buildbot will run an extra query command for each handled event to determine the changed files.

debug

Print Gerrit event in the log (default False). This allows to debug event content, but will eventually fill your logs with useless Gerrit event logs.

The same customization can be done as GerritChangeSource for handling special events.

2.5.3.15. GerritChangeFilter
class buildbot.changes.gerritchangesource.GerritChangeFilter

GerritChangeFilter is a ready to use ChangeFilter you can pass to AnyBranchScheduler in order to filter changes, to create pre-commit builders or post-commit schedulers. It has the same api as Change Filter, except it has additional eventtype set of filter (can as well be specified as value, list, regular expression, or callable).

An example is following:

from buildbot.plugins import schedulers, util

# this scheduler will create builds when a patch is uploaded to gerrit
# but only if it is uploaded to the "main" branch
schedulers.AnyBranchScheduler(
    name="main-precommit",
    change_filter=util.GerritChangeFilter(branch="main", eventtype="patchset-created"),
    treeStableTimer=15*60,
    builderNames=["main-precommit"])

# this scheduler will create builds when a patch is merged in the "main" branch
# for post-commit tests
schedulers.AnyBranchScheduler(name="main-postcommit",
                              change_filter=util.GerritChangeFilter("main", "ref-updated"),
                              treeStableTimer=15*60,
                              builderNames=["main-postcommit"])
2.5.3.16. Change Hooks (HTTP Notifications)

Buildbot already provides a web frontend, and that frontend can easily be used to receive HTTP push notifications of commits from services like GitHub. See Change Hooks for more information.

2.5.4. Changes

class buildbot.changes.changes.Change

A Change is an abstract way Buildbot uses to represent a single change to the source files performed by a developer. In version control systems that support the notion of atomic check-ins, a change represents a changeset or commit. Instances of Change have the following attributes.

2.5.4.1. Who

Each Change has a who attribute, which specifies which developer is responsible for the change. This is a string which comes from a namespace controlled by the VC repository. Frequently this means it is a username on the host which runs the repository, but not all VC systems require this. Each StatusNotifier will map the who attribute into something appropriate for their particular means of communication: an email address, an IRC handle, etc.

This who attribute is also parsed and stored into Buildbot’s database (see User Objects). Currently, only who attributes in Changes from git repositories are translated into user objects, but in the future all incoming Changes will have their who parsed and stored.

2.5.4.2. Files

It also has a list of files, which are just the tree-relative filenames of any files that were added, deleted, or modified for this Change. These filenames are checked by the fileIsImportant function of a scheduler to decide whether it should trigger a new build or not. For example, the scheduler could use the following function to only run a build if a C file was checked in:

def has_C_files(change):
    for name in change.files:
        if name.endswith(".c"):
            return True
    return False

Certain BuildSteps can also use the list of changed files to run a more targeted series of tests, e.g. the python_twisted.Trial step can run just the unit tests that provide coverage for the modified .py files instead of running the full test suite.

2.5.4.3. Comments

The Change also has a comments attribute, which is a string containing any checkin comments.

2.5.4.4. Project

The project attribute of a change or source stamp describes the project to which it corresponds, as a short human-readable string. This is useful in cases where multiple independent projects are built on the same buildmaster. In such cases, it can be used to control which builds are scheduled for a given commit, and to limit status displays to only one project.

2.5.4.5. Repository

This attribute specifies the repository in which this change occurred. In the case of DVCS’s, this information may be required to check out the committed source code. However, using the repository from a change has security risks: if Buildbot is configured to blindly trust this information, then it may easily be tricked into building arbitrary source code, potentially compromising the workers and the integrity of subsequent builds.

2.5.4.6. Codebase

This attribute specifies the codebase to which this change was made. As described in source stamps section, multiple repositories may contain the same codebase. A change’s codebase is usually determined by the codebaseGenerator configuration. By default the codebase is ‘’; this value is used automatically for single-codebase configurations.

2.5.4.7. Revision

Each Change can have a revision attribute, which describes how to get a tree with a specific state: a tree which includes this Change (and all that came before it) but none that come after it. If this information is unavailable, the revision attribute will be None. These revisions are provided by the ChangeSource.

Revisions are always strings.

CVS

revision is the seconds since the epoch as an integer.

SVN

revision is the revision number

Darcs

revision is a large string, the output of darcs changes --context

Mercurial

revision is a short string (a hash ID), the output of hg identify

P4

revision is the transaction number

Git

revision is a short string (a SHA1 hash), the output of e.g. git rev-parse

2.5.4.8. Branches

The Change might also have a branch attribute. This indicates that all of the Change’s files are in the same named branch. The schedulers get to decide whether the branch should be built or not.

For VC systems like CVS, Git, Mercurial and Monotone the branch name is unrelated to the filename. (That is, the branch name and the filename inhabit unrelated namespaces.) For SVN, branches are expressed as subdirectories of the repository, so the file’s repourl is a combination of some base URL, the branch name, and the filename within the branch. (In a sense, the branch name and the filename inhabit the same namespace.) Darcs branches are subdirectories of a base URL just like SVN.

CVS

branch=’warner-newfeature’, files=[‘src/foo.c’]

SVN

branch=’branches/warner-newfeature’, files=[‘src/foo.c’]

Darcs

branch=’warner-newfeature’, files=[‘src/foo.c’]

Mercurial

branch=’warner-newfeature’, files=[‘src/foo.c’]

Git

branch=’warner-newfeature’, files=[‘src/foo.c’]

Monotone

branch=’warner-newfeature’, files=[‘src/foo.c’]

2.5.4.9. Change Properties

A Change may have one or more properties attached to it, usually specified through the Force Build form or sendchange. Properties are discussed in detail in the Build Properties section.

2.5.5. Schedulers

Schedulers are responsible for initiating builds on builders.

Some schedulers listen for changes from ChangeSources and generate build sets in response to these changes. Others generate build sets without changes, based on other events in the buildmaster.

2.5.5.1. Configuring Schedulers

The schedulers configuration parameter gives a list of scheduler instances, each of which causes builds to be started on a particular set of Builders. The two basic scheduler classes you are likely to start with are SingleBranchScheduler and Periodic, but you can write a customized subclass to implement more complicated build scheduling.

Scheduler arguments should always be specified by name (as keyword arguments), to allow for future expansion:

sched = SingleBranchScheduler(name="quick", builderNames=['lin', 'win'])

There are several common arguments for schedulers, although not all are available with all schedulers.

name

Each Scheduler must have a unique name. This is used in status displays, and is also available in the build property scheduler.

builderNames

This is the set of builders which this scheduler should trigger, specified as a list of names (strings). This can also be an IRenderable object which will render to a list of builder names (or a list of IRenderable that will render to builder names).

Note

When builderNames is rendered, these additional Properties attributes are available:

master

A reference to the BuildMaster object that owns this scheduler. This can be used to access the data API.

sourcestamps

The list of sourcestamps that triggered the scheduler.

changes

The list of changes associated with the sourcestamps.

files

The list of modified files associated with the changes.

Any property attached to the change(s) that triggered the scheduler will be combined and available when rendering builderNames.

Here is a simple example:

from buildbot.plugins import util, schedulers

@util.renderer
def builderNames(props):
    builders = set()
    for f in props.files:
        if f.endswith('.rst'):
            builders.add('check_docs')
        if f.endswith('.c'):
            builders.add('check_code')
    return list(builders)

c['schedulers'] = [
    schedulers.AnyBranchScheduler(
        name='all',
        builderNames=builderNames,
    )
]

And a more complex one:

import fnmatch

from twisted.internet import defer

from buildbot.plugins import util, schedulers

@util.renderer
@defer.inlineCallbacks
def builderNames(props):
    # If "buildername_pattern" is defined with "buildbot sendchange",
    # check if the builder name matches it.
    pattern = props.getProperty('buildername_pattern')

    # If "builder_tags" is defined with "buildbot sendchange",
    # only schedule builders that have the specified tags.
    tags = props.getProperty('builder_tags')

    builders = []

    for b in (yield props.master.data.get(('builders',))):
        if pattern and not fnmatch.fnmatchcase(b['name'], pattern):
            continue
        if tags and not set(tags.split()).issubset(set(b['tags'])):
            continue
        builders.append(b['name'])

    return builders

c['schedulers'] = [
   schedulers.AnyBranchScheduler(
      name='matrix',
      builderNames=builderNames,
   )
]

properties (optional)

This is a dictionary specifying properties that will be transmitted to all builds started by this scheduler. The owner property may be of particular interest, as its contents (list) will be added to the list of “interested users” (Doing Things With Users) for each triggered build. For example:

sched = Scheduler(...,
    properties = {
        'owner': ['zorro@example.com', 'silver@example.com']
    })

codebases (optional)

Specifies codebase definitions that are used when the scheduler processes data from more than one repository at the same time.

The codebases parameter is only used to fill in missing details about a codebase when scheduling a build. For example, when a change to codebase A occurs, a scheduler must invent a sourcestamp for codebase B. Source steps that specify codebase B as their codebase will use the invented timestamp.

The parameter does not act as a filter on incoming changes – use a change filter for that purpose.

This parameter can be specified in two forms:

  • as a list of strings. This is the simplest form; use it if no special overrides are needed. In this form, just the names of the codebases are listed.

  • as a dictionary of dictionaries. In this form, the per-codebase overrides of repository, branch and revision can be specified.

Each codebase definition dictionary is a dictionary with any of the keys: repository, branch, revision. The codebase definitions are combined in a dictionary keyed by the name of the codebase.

codebases = {'codebase1': {'repository':'....',
                           'branch':'default',
                           'revision': None},
             'codebase2': {'repository':'....'} }

fileIsImportant (optional)

A callable which takes as argument a Change instance and returns True if the change is worth building, and False if it is not. Unimportant Changes are accumulated until the build is triggered by an important change. The default value of None means that all Changes are important.

change_filter (optional)

The change filter that will determine which changes are recognized by this scheduler (see ChangeFilter). Note that this is different from fileIsImportant; if the change filter filters out a change, the change is completely ignored by the scheduler. If a change is allowed by the change filter but is deemed unimportant, it will not cause builds to start but will be remembered and shown in status displays. The default value of None does not filter any changes at all.

onlyImportant (optional)

A boolean that, when True, only adds important changes to the buildset as specified in the fileIsImportant callable. This means that unimportant changes are ignored the same way a change_filter filters changes. The default value is False and only applies when fileIsImportant is given.

reason (optional)

A string that will be used as the reason for the triggered build. By default it lists the type and name of the scheduler triggering the build.

priority (optional)

Specifies the default priority for BuildRequests created by this scheduler. It can either be an integer or a function (see Scheduler Priority Functions). By default it creates BuildRequests with priority 0.

The remaining subsections represent a catalog of the available scheduler types. All these schedulers are defined in modules under buildbot.schedulers, and their docstrings are the best source of documentation on the arguments each one takes.

2.5.5.2. Scheduler Resiliency

In a multi-master configuration, schedulers with the same name can be configured on multiple masters. Only one instance of the scheduler will be active. If that instance becomes inactive, due to its master being shut down or failing, then another instance will become active after a short delay. This provides resiliency in scheduler configurations, so that schedulers are not a single point of failure in a Buildbot infrastructure.

The Data API and web UI display the master on which each scheduler is running.

There is currently no mechanism to control which master’s scheduler instance becomes active. The behavior is nondeterministic, based on the timing of polling by inactive schedulers. The failover is non-revertive.

2.5.5.3. Usage example

A quick scheduler might exist to give immediate feedback to developers, hoping to catch obvious problems in the code that can be detected quickly. These typically do not run the full test suite, nor do they run on a wide variety of platforms. They also usually do a VC update rather than performing a brand-new checkout each time.

A separate full scheduler might run more comprehensive tests, to catch more subtle problems. It might be configured to run after the quick scheduler, to give developers time to commit fixes to bugs caught by the quick scheduler before running the comprehensive tests. This scheduler would also feed multiple Builders.

Many schedulers can be configured to wait a while after seeing a source-code change - this is the tree stable timer. The timer allows multiple commits to be “batched” together. This is particularly useful in distributed version control systems, where a developer may push a long sequence of changes all at once. To save resources, it’s often desirable only to test the most recent change.

Schedulers can also filter out the changes they are interested in, based on a number of criteria. For example, a scheduler that only builds documentation might skip any changes that do not affect the documentation. Schedulers can also filter on the branch to which a commit was made.

Periodic builds (those which are run every N seconds rather than after new Changes arrive) are triggered by a special Periodic scheduler.

Each scheduler creates and submits BuildSet objects to the BuildMaster, which is then responsible for making sure the individual BuildRequests are delivered to the target Builders.

Scheduler instances are activated by placing them in the schedulers list in the buildmaster config file. Each scheduler must have a unique name.

2.5.5.4. Scheduler Types
SingleBranchScheduler

This is the original and still most popular scheduler class. It follows exactly one branch, and starts a configurable tree-stable-timer after each change on that branch. When the timer expires, it starts a build on some set of Builders. This scheduler accepts a fileIsImportant function which can be used to ignore some Changes if they do not affect any important files.

If treeStableTimer is not set, then this scheduler starts a build for every Change that matches its change_filter and satisfies fileIsImportant. If treeStableTimer is set, then a build is triggered for each set of Changes that arrive in intervals shorter than the configured time and match the filters.

Note

The behavior of this scheduler is undefined, if treeStableTimer is set, and changes from multiple branches, repositories or codebases are accepted by the filter.

Note

The codebases argument will filter out codebases not specified there, but won’t filter based on the branches specified there.

The arguments to this scheduler are:

name

builderNames

properties (optional)

codebases (optional)

fileIsImportant (optional)

change_filter (optional)

onlyImportant (optional)

reason (optional)

treeStableTimer

The scheduler will wait for this many seconds before starting the build. If new changes are made during this interval, the timer will be restarted. So the build will be started after this many seconds of inactivity following the last change.

If treeStableTimer is None, then a separate build is started immediately for each Change.

categories (deprecated; use change_filter)

A list of categories of changes that this scheduler will respond to. If this is specified, then any non-matching changes are ignored.

branch (deprecated; use change_filter)

The scheduler will pay attention to this branch, ignoring Changes that occur on other branches. Setting branch equal to the special value of None means it should only pay attention to the default branch.

Note

None is a keyword, not a string, so write None and not "None".

Example:

from buildbot.plugins import schedulers, util
quick = schedulers.SingleBranchScheduler(
            name="quick",
            change_filter=util.ChangeFilter(branch='master'),
            treeStableTimer=60,
            builderNames=["quick-linux", "quick-netbsd"])
full = schedulers.SingleBranchScheduler(
            name="full",
            change_filter=util.ChangeFilter(branch='master'),
            treeStableTimer=5*60,
            builderNames=["full-linux", "full-netbsd", "full-OSX"])
c['schedulers'] = [quick, full]

In this example, the two quick builders are triggered 60 seconds after the tree has been changed. The full builders do not run quite that quickly (they wait 5 minutes), so that hopefully, if the quick builds fail due to a missing file or a simple typo, the developer can discover and fix the problem before the full builds are started. Both schedulers only pay attention to the default branch: any changes on other branches are ignored. Each scheduler triggers a different set of builders, referenced by name.

Note

The old names for this scheduler, buildbot.scheduler.Scheduler and buildbot.schedulers.basic.Scheduler, are deprecated in favor of using buildbot.plugins:

from buildbot.plugins import schedulers

However if you must use a fully qualified name, it is buildbot.schedulers.basic.SingleBranchScheduler.

AnyBranchScheduler

This scheduler uses a tree-stable-timer like the default one, but uses a separate timer for each branch.

If treeStableTimer is not set, then this scheduler is indistinguishable from SingleBranchScheduler. If treeStableTimer is set, then a build is triggered for each set of Changes that arrive in intervals shorter than the configured time and match the filters.

The arguments to this scheduler are:

name

builderNames

properties (optional)

codebases (optional)

fileIsImportant (optional)

change_filter (optional)

onlyImportant (optional)

reason (optional)

treeStableTimer

The scheduler will wait for this many seconds before starting a build. If new changes are made on the same branch during this interval, the timer will be restarted.

branches (deprecated; use change_filter)

Changes on branches not specified on this list will be ignored.

categories (deprecated; use change_filter)

A list of categories of changes that this scheduler will respond to. If this is specified, then any non-matching changes are ignored.

Dependent Scheduler

It is common to wind up with one kind of build which should only be performed if the same source code was successfully handled by some other kind of build first. An example might be a packaging step: you might only want to produce .deb or RPM packages from a tree that was known to compile successfully and pass all unit tests. You could put the packaging step in the same Build as the compile and testing steps, but there might be other reasons to not do this (in particular you might have several Builders worth of compiles/tests, but only wish to do the packaging once). Another example is if you want to skip the full builds after a failing quick build of the same source code. Or, if one Build creates a product (like a compiled library) that is used by some other Builder, you’d want to make sure the consuming Build is run after the producing one.

You can use dependencies to express this relationship to Buildbot. There is a special kind of scheduler named Dependent that will watch an upstream scheduler for builds to complete successfully (on all of its Builders). Each time that happens, the same source code (i.e. the same SourceStamp) will be used to start a new set of builds, on a different set of Builders. This downstream scheduler doesn’t pay attention to Changes at all. It only pays attention to the upstream scheduler.

If the build fails on any of the Builders in the upstream set, the downstream builds will not fire. Note that, for SourceStamps generated by a Dependent scheduler, the revision is None, meaning HEAD. If any changes are committed between the time the upstream scheduler begins its build and the time the dependent scheduler begins its build, then those changes will be included in the downstream build. See the Triggerable scheduler for a more flexible dependency mechanism that can avoid this problem.

The arguments to this scheduler are:

name

builderNames

properties (optional)

codebases (optional)

upstream

The upstream scheduler to watch. Note that this is an instance, not the name of the scheduler.

Example:

from buildbot.plugins import schedulers
tests = schedulers.SingleBranchScheduler(name="just-tests",
                                         treeStableTimer=5*60,
                                         builderNames=["full-linux",
                                                       "full-netbsd",
                                                       "full-OSX"])
package = schedulers.Dependent(name="build-package",
                               upstream=tests, # <- no quotes!
                               builderNames=["make-tarball", "make-deb",
                                             "make-rpm"])
c['schedulers'] = [tests, package]
Periodic Scheduler

This simple scheduler just triggers a build every N seconds.

The arguments to this scheduler are:

name

builderNames

properties (optional)

codebases (optional)

fileIsImportant (optional)

change_filter (optional)

onlyImportant (optional)

reason (optional)

createAbsoluteSourceStamps (optional)

This option only has effect when using multiple codebases. When True, it uses the last seen revision for each codebase that does not have a change. When False (the default), codebases without changes will use the revision from the codebases argument.

onlyIfChanged (optional)

If this is True, then builds will be scheduled at the designated time only if the specified branch has seen an important change since the previous build. If there is no previous build or the previous build was made when this option was False then the build will be scheduled even if there are no new changes. By default this setting is False.

periodicBuildTimer

The time, in seconds, after which to start a build.

Example:

from buildbot.plugins import schedulers
nightly = schedulers.Periodic(name="daily",
                              builderNames=["full-solaris"],
                              periodicBuildTimer=24*60*60)
c['schedulers'] = [nightly]

The scheduler in this example just runs the full solaris build once per day. Note that this scheduler only lets you control the time between builds, not the absolute time-of-day of each Build, so this could easily wind up an evening or every afternoon scheduler depending upon when it was first activated.

Nightly Scheduler

This is highly configurable periodic build scheduler, which triggers a build at particular times of day, week, month, or year. The configuration syntax is very similar to the well-known crontab format, in which you provide values for minute, hour, day, and month (some of which can be wildcards), and a build is triggered whenever the current time matches the given constraints. This can run a build every night, every morning, every weekend, alternate Thursdays, on your boss’s birthday, etc.

Pass some subset of minute, hour, dayOfMonth, month, and dayOfWeek; each may be a single number or a list of valid values. The builds will be triggered whenever the current time matches these values. Wildcards are represented by a ‘*’ string. All fields default to a wildcard except ‘minute’, so with no fields, this defaults to a build every hour, on the hour. The full list of parameters is:

name

builderNames

properties (optional)

codebases (optional)

fileIsImportant (optional)

change_filter (optional)

onlyImportant (optional)

reason (optional)

createAbsoluteSourceStamps (optional)

This option only has effect when using multiple codebases. When True, it uses the last seen revision for each codebase that does not have a change. When False (the default), codebases without changes will use the revision from the codebases argument.

onlyIfChanged (optional)

If this is True, then builds will not be scheduled at the designated time unless the change filter has accepted an important change since the previous build. The default value is False.

branch (optional)

(Deprecated; use change_filter and codebases.) The branch to build when the time comes, and the branch to filter for if change_filter is not specified. Remember that a value of None here means the default branch, and will not match other branches!

minute (optional)

The minute of the hour on which to start the build. This defaults to 0, meaning an hourly build.

hour (optional)

The hour of the day on which to start the build, in 24-hour notation. This defaults to *, meaning every hour.

dayOfMonth (optional)

The day of the month to start a build. This defaults to *, meaning every day or L for last day. Last day option respects leap years.

month (optional)

The month in which to start the build, with January = 1. This defaults to *, meaning every month. Month or month range / list as standard C abbreviated name jan-feb, jan,dec.

dayOfWeek (optional)

The day of the week to start a build, with Monday = 0. This defaults to *, meaning every day of the week or nth weekday of month. Like first Monday of month 1#1, last Monday of month L1, Monday + Friday mon,fri or ranges Monday to Friday mon-fri.

For example, the following master.cfg clause will cause a build to be started every night at 3:00am:

from buildbot.plugins import schedulers, util
c['schedulers'].append(
    schedulers.Nightly(name='nightly',
                       change_filter=util.ChangeFilter(branch='master'),
                       builderNames=['builder1', 'builder2'],
                       hour=3, minute=0))

This scheduler will perform a build each Monday morning at 6:23am and again at 8:23am, but only if someone has committed code in the interim:

c['schedulers'].append(
    schedulers.Nightly(name='BeforeWork',
                       change_filter=util.ChangeFilter(branch='default'),
                       builderNames=['builder1'],
                       dayOfWeek=0, hour=[6,8], minute=23,
                       onlyIfChanged=True))

The following runs a build every two hours, using Python’s range function:

c.schedulers.append(
    schedulers.Nightly(name='every2hours',
                       change_filter=util.ChangeFilter(branch=None),  # default branch
                       builderNames=['builder1'],
                       hour=range(0, 24, 2)))

Finally, this example will run only on December 24th:

c['schedulers'].append(
    schedulers.Nightly(name='SleighPreflightCheck',
                       change_filter=util.ChangeFilter(branch=None),  # default branch
                       builderNames=['flying_circuits', 'radar'],
                       month=12,
                       dayOfMonth=24,
                       hour=12,
                       minute=0))
Try Schedulers

This scheduler allows developers to use the buildbot try command to trigger builds of code they have not yet committed. See try for complete details.

Two implementations are available: Try_Jobdir and Try_Userpass. The former monitors a job directory, specified by the jobdir parameter, while the latter listens for PB connections on a specific port, and authenticates against userport.

The buildmaster must have a scheduler instance in the config file’s schedulers list to receive try requests. This lets the administrator control who may initiate these trial builds, which branches are eligible for trial builds, and which Builders should be used for them.

The scheduler has various means to accept build requests. All of them enforce more security than the usual buildmaster ports do. Any source code being built can be used to compromise the worker accounts, but in general that code must be checked out from the VC repository first, so only people with commit privileges can get control of the workers. The usual force-build control channels can waste worker time but do not allow arbitrary commands to be executed by people who don’t have those commit privileges. However, the source code patch that is provided with the trial build does not have to go through the VC system first, so it is important to make sure these builds cannot be abused by a non-committer to acquire as much control over the workers as a committer has. Ideally, only developers who have commit access to the VC repository would be able to start trial builds, but unfortunately, the buildmaster does not, in general, have access to the VC system’s user list.

As a result, the try scheduler requires a bit more configuration. There are currently two ways to set this up:

jobdir (ssh)

This approach creates a command queue directory, called the jobdir, in the buildmaster’s working directory. The buildmaster admin sets the ownership and permissions of this directory to only grant write access to the desired set of developers, all of whom must have accounts on the machine. The buildbot try command creates a special file containing the source stamp information and drops it in the jobdir, just like a standard maildir. When the buildmaster notices the new file, it unpacks the information inside and starts the builds.

The config file entries used by ‘buildbot try’ either specify a local queuedir (for which write and mv are used) or a remote one (using scp and ssh).

The advantage of this scheme is that it is quite secure, the disadvantage is that it requires fiddling outside the buildmaster config (to set the permissions on the jobdir correctly). If the buildmaster machine happens to also house the VC repository, then it can be fairly easy to keep the VC userlist in sync with the trial-build userlist. If they are on different machines, this will be much more of a hassle. It may also involve granting developer accounts on a machine that would not otherwise require them.

To implement this, the worker invokes ssh -l username host buildbot tryserver ARGS, passing the patch contents over stdin. The arguments must include the inlet directory and the revision information.

user+password (PB)

In this approach, each developer gets a username/password pair, which are all listed in the buildmaster’s configuration file. When the developer runs buildbot try, their machine connects to the buildmaster via PB and authenticates themselves using that username and password, then sends a PB command to start the trial build.

The advantage of this scheme is that the entire configuration is performed inside the buildmaster’s config file. The disadvantages are that it is less secure (while the cred authentication system does not expose the password in plaintext over the wire, it does not offer most of the other security properties that SSH does). In addition, the buildmaster admin is responsible for maintaining the username/password list, adding and deleting entries as developers come and go.

For example, to set up the jobdir style of trial build, using a command queue directory of MASTERDIR/jobdir (and assuming that all your project developers were members of the developers unix group), you would first set up that directory:

mkdir -p MASTERDIR/jobdir MASTERDIR/jobdir/new MASTERDIR/jobdir/cur MASTERDIR/jobdir/tmp
chgrp developers MASTERDIR/jobdir MASTERDIR/jobdir/*
chmod g+rwx,o-rwx MASTERDIR/jobdir MASTERDIR/jobdir/*

and then use the following scheduler in the buildmaster’s config file:

from buildbot.plugins import schedulers
s = schedulers.Try_Jobdir(name="try1",
                          builderNames=["full-linux", "full-netbsd", "full-OSX"],
                          jobdir="jobdir")
c['schedulers'] = [s]

Note that you must create the jobdir before telling the buildmaster to use this configuration, otherwise you will get an error. Also remember that the buildmaster must be able to read and write to the jobdir as well. Be sure to watch the twistd.log file (Logfiles) as you start using the jobdir, to make sure the buildmaster is happy with it.

Note

Patches in the jobdir are encoded using netstrings, which place an arbitrary upper limit on patch size of 99999 bytes. If your submitted try jobs are rejected with BadJobfile, try increasing this limit with a snippet like this in your master.cfg:

from twisted.protocols.basic import NetstringReceiver
NetstringReceiver.MAX_LENGTH = 1000000

To use the username/password form of authentication, create a Try_Userpass instance instead. It takes the same builderNames argument as the Try_Jobdir form, but accepts an additional port argument (to specify the TCP port to listen on) and a userpass list of username/password pairs to accept. Remember to use good passwords for this: the security of the worker accounts depends upon it:

from buildbot.plugins import schedulers
s = schedulers.Try_Userpass(name="try2",
                            builderNames=["full-linux", "full-netbsd", "full-OSX"],
                            port=8031,
                            userpass=[("alice","pw1"), ("bob", "pw2")])
c['schedulers'] = [s]

Like in most classes in Buildbot, the port argument takes a strports specification. See twisted.application.strports for details.

Triggerable Scheduler

The Triggerable scheduler waits to be triggered by a Trigger step (see Trigger) in another build. That step can optionally wait for the scheduler’s builds to complete. This provides two advantages over Dependent schedulers. First, the same scheduler can be triggered from multiple builds. Second, the ability to wait for Triggerable’s builds to complete provides a form of “subroutine call”, where one or more builds can “call” a scheduler to perform some work for them, perhaps on other workers. The Triggerable scheduler supports multiple codebases. The scheduler filters out all codebases from Trigger steps that are not configured in the scheduler.

The parameters are just the basics:

name

builderNames

properties (optional)

codebases (optional)

reason (optional)

This class is only useful in conjunction with the Trigger step. Here is a fully-worked example:

from buildbot.plugins import schedulers, steps, util

checkin = schedulers.SingleBranchScheduler(name="checkin",
                                           change_filter=util.ChangeFilter(branch=None),
                                           treeStableTimer=5*60,
                                           builderNames=["checkin"])
nightly = schedulers.Nightly(name='nightly',
                             change_filter=util.ChangeFilter(branch=None),
                             builderNames=['nightly'],
                             hour=3, minute=0)

mktarball = schedulers.Triggerable(name="mktarball", builderNames=["mktarball"])
build = schedulers.Triggerable(name="build-all-platforms",
                               builderNames=["build-all-platforms"])
test = schedulers.Triggerable(name="distributed-test",
                              builderNames=["distributed-test"])
package = schedulers.Triggerable(name="package-all-platforms",
                                 builderNames=["package-all-platforms"])
c['schedulers'] = [mktarball, checkin, nightly, build, test, package]

# on checkin, make a tarball, build it, and test it
checkin_factory = util.BuildFactory()
checkin_factory.addStep(steps.Trigger(schedulerNames=['mktarball'],
                                      waitForFinish=True))
checkin_factory.addStep(steps.Trigger(schedulerNames=['build-all-platforms'],
                                      waitForFinish=True))
checkin_factory.addStep(steps.Trigger(schedulerNames=['distributed-test'],
                                      waitForFinish=True))

# and every night, make a tarball, build it, and package it
nightly_factory = util.BuildFactory()
nightly_factory.addStep(steps.Trigger(schedulerNames=['mktarball'],
                                      waitForFinish=True))
nightly_factory.addStep(steps.Trigger(schedulerNames=['build-all-platforms'],
                                      waitForFinish=True))
nightly_factory.addStep(steps.Trigger(schedulerNames=['package-all-platforms'],
                                      waitForFinish=True))
NightlyTriggerable Scheduler
class buildbot.schedulers.timed.NightlyTriggerable

The NightlyTriggerable scheduler is a mix of the Nightly and Triggerable schedulers. This scheduler triggers builds at a particular time of day, week, or year, exactly as the Nightly scheduler. However, the source stamp set that is used is provided by the last Trigger step that targeted this scheduler.

The following parameters are just the basics:

name

builderNames

properties (optional)

codebases (optional)

reason (optional)

minute (optional)

See Nightly.

hour (optional)

See Nightly.

dayOfMonth (optional)

See Nightly.

month (optional)

See Nightly.

dayOfWeek (optional)

See Nightly.

This class is only useful in conjunction with the Trigger step. Note that waitForFinish is ignored by Trigger steps targeting this scheduler.

Here is a fully-worked example:

from buildbot.plugins import schedulers, steps, util

checkin = schedulers.SingleBranchScheduler(name="checkin",
                                           change_filter=util.ChangeFilter(branch=None),
                                           treeStableTimer=5*60,
                                           builderNames=["checkin"])
nightly = schedulers.NightlyTriggerable(name='nightly',
                                        builderNames=['nightly'],
                                        hour=3, minute=0)
c['schedulers'] = [checkin, nightly]

# on checkin, run tests
checkin_factory = util.BuildFactory([
    steps.Test(),
    steps.Trigger(schedulerNames=['nightly'])
])

# and every night, package the latest successful build
nightly_factory = util.BuildFactory([
    steps.ShellCommand(command=['make', 'package'])
])
ForceScheduler Scheduler

The ForceScheduler scheduler is the way you can configure a force build form in the web UI.

In the /#/builders/:builderid web page, you will see, on the top right of the page, one button for each ForceScheduler scheduler that was configured for this builder. If you click on that button, a dialog will let you choose various parameters for requesting a new build.

The Buildbot framework allows you to customize exactly how the build form looks, which builders have a force build form (it might not make sense to force build every builder), and who is allowed to force builds on which builders.

You do so by configuring a ForceScheduler and adding it to the list of schedulers.

The scheduler takes the following parameters:

name

See name scheduler argument. Force buttons are ordered by this property in the UI (so you can prefix by 01, 02, etc, in order to control precisely the order).

builderNames

List of builders where the force button should appear. See builderNames scheduler argument.

reason

A parameter allowing the user to specify the reason for the build. The default value is a string parameter with a default value “force build”.

reasonString

A string that will be used to create the build reason for the forced build. This string can contain the placeholders %(owner)s and %(reason)s, which represents the value typed into the reason field.

username

A parameter specifying the username associated with the build (aka owner). The default value is a username parameter.

codebases

A list of strings or CodebaseParameter specifying the codebases that should be presented. The default is a single codebase with no name (i.e. codebases=[‘’]).

properties

A list of parameters, one for each property. These can be arbitrary parameters, where the parameter’s name is taken as the property name, or AnyPropertyParameter, which allows the web user to specify the property name. The default value is an empty list.

buttonName

The name of the “submit” button on the resulting force-build form. This defaults to the name of scheduler.

An example may be better than long explanation. What you need in your config file is something like:

from buildbot.plugins import schedulers, util

sch = schedulers.ForceScheduler(
    name="force",
    buttonName="pushMe!",
    label="My nice Force form",
    builderNames=["my-builder"],

    codebases=[
        util.CodebaseParameter(
            "",
            label="Main repository",
            # will generate a combo box
            branch=util.ChoiceStringParameter(
                name="branch",
                choices=["master", "hest"],
                default="master"),

            # will generate nothing in the form, but revision, repository,
            # and project are needed by buildbot scheduling system so we
            # need to pass a value ("")
            revision=util.FixedParameter(name="revision", default=""),
            repository=util.FixedParameter(name="repository", default=""),
            project=util.FixedParameter(name="project", default=""),
        ),
    ],

    # will generate a text input
    reason=util.StringParameter(name="reason",
                                label="reason:",
                                required=True, size=80),

    # in case you don't require authentication, this will display
    # input for user to type their name
    username=util.UserNameParameter(label="your name:",
                                    size=80),
    # A completely customized property list.  The name of the
    # property is the name of the parameter
    properties=[
        util.NestedParameter(name="options", label="Build Options",
                             layout="vertical", fields=[
            util.StringParameter(name="pull_url",
                                 label="optionally give a public Git pull url:",
                                 default="", size=80),
            util.BooleanParameter(name="force_build_clean",
                                  label="force a make clean",
                                  default=False)
        ])
    ])

This will result in the following UI:

Force Form Result
Authorization

The force scheduler uses the web interface’s authorization framework to determine which user has the right to force which build. Here is an example of code on how you can define which user has which right:

user_mapping = {
    re.compile("project1-builder"): ["project1-maintainer", "john"] ,
    re.compile("project2-builder"): ["project2-maintainer", "jack"],
    re.compile(".*"): ["root"]
}
def force_auth(user,  status):
    global user_mapping
    for r,users in user_mapping.items():
        if r.match(status.name):
            if user in users:
                    return True
    return False

# use authz_cfg in your WebStatus setup
authz_cfg=authz.Authz(
    auth=my_auth,
    forceBuild = force_auth,
)
ForceScheduler Parameters

Most of the arguments to ForceScheduler are “parameters”. Several classes of parameters are available, each describing a different kind of input from a force-build form.

All parameter types have a few common arguments:

name (required)

The name of the parameter. For properties, this will correspond to the name of the property that your parameter will set. The name is also used internally as the identifier for in the HTML form.

label (optional; default is same as name)

The label of the parameter. This is what is displayed to the user.

tablabel (optional; default is same as label)

The label of the tab if this parameter is included into a tab layout NestedParameter. This is what is displayed to the user.

default (optional; default: “”)

The default value for the parameter that is used if there is no user input.

required (optional; default: False)

If this is true, then an error will be shown to user if there is no input in this field

maxsize (optional; default: None)

The maximum size of a field (in bytes). Buildbot will ensure the field sent by the user is not too large.

autopopulate (optional; default: None)

If not None, autopopulate is a dictionary which describes how other parameters are updated if this one changes. This is useful for when you have lots of parameters, and defaults depends on e.g. the branch. This is implemented generically, and all parameters can update others. Beware of infinite loops!

c['schedulers'].append(schedulers.ForceScheduler(
name="custom",
builderNames=["runtests"],
buttonName="Start Custom Build",
codebases = [util.CodebaseParameter(
    codebase='', project=None,
    branch=util.ChoiceStringParameter(
        name="branch",
        label="Branch",
        strict=False,
        choices=["master", "dev"],
        autopopulate={
        'master': {
            'build_name': 'build for master branch',
        },
        'dev': {
            'build_name': 'build for dev branch',
        }
        }
))],
properties=[
    util.StringParameter(
        name="build_name",
        label="Name of the Build release.",
        default="")]))  # this parameter will be auto populated when user chooses branch

The parameter types are:

NestedParameter
NestedParameter(name="options", label="Build options", layout="vertical", fields=[...]),

This parameter type is a special parameter which contains other parameters. This can be used to group a set of parameters together, and define the layout of your form. You can recursively include NestedParameter into NestedParameter, to build very complex UIs.

It adds the following arguments:

layout (optional, default is “vertical”)

The layout defines how the fields are placed in the form.

The layouts implemented in the standard web application are:

  • simple: fields are displayed one by one without alignment.

    They take the horizontal space that they need.

  • vertical: all fields are displayed vertically, aligned in columns (as per the column attribute of the NestedParameter)

  • tabs: each field gets its own tab.

    This can be used to declare complex build forms which won’t fit into one screen. The children fields are usually other NestedParameters with vertical layout.

columns (optional, accepted values are 1, 2, 3, 4)

The number of columns to use for a vertical layout. If omitted, it is set to 1 unless there are more than 3 visible child fields in which case it is set to 2.

FixedParameter
FixedParameter(name="branch", default="trunk"),

This parameter type will not be shown on the web form and always generates a property with its default value.

StringParameter
StringParameter(name="pull_url",
    label="optionally give a public Git pull url:",
    default="", size=80)

This parameter type will show a single-line text-entry box, and allow the user to enter an arbitrary string. It adds the following arguments:

regex (optional)

A string that will be compiled as a regex and used to validate the input of this parameter.

size (optional; default is 10)

The width of the input field (in characters).

TextParameter
TextParameter(name="comments",
    label="comments to be displayed to the user of the built binary",
    default="This is a development build", cols=60, rows=5)

This parameter type is similar to StringParameter, except that it is represented in the HTML form as a textarea, allowing multi-line input. It adds the StringParameter arguments and the following ones:

cols (optional; default is 80)

The number of columns the textarea will have.

rows (optional; default is 20)

The number of rows the textarea will have.

This class could be subclassed to have more customization, e.g.

  • developer could send a list of Git branches to pull from

  • developer could send a list of Gerrit changes to cherry-pick,

  • developer could send a shell script to amend the build.

Beware of security issues anyway.

IntParameter
IntParameter(name="debug_level",
    label="debug level (1-10)", default=2)

This parameter type accepts an integer value using a text-entry box.

BooleanParameter
BooleanParameter(name="force_build_clean",
    label="force a make clean", default=False)

This type represents a boolean value. It will be presented as a checkbox.

UserNameParameter
UserNameParameter(label="your name:", size=80)

This parameter type accepts a username. If authentication is active, it will use the authenticated user instead of displaying a text-entry box.

size (optional; default is 10)

The width of the input field (in characters).

need_email (optional; default is True)

If true, requires a full email address rather than arbitrary text.

ChoiceStringParameter
ChoiceStringParameter(name="branch",
    choices=["main","devel"], default="main")

This parameter type lets the user choose between several choices (e.g. the list of branches you are supporting, or the test campaign to run). If multiple is false, then its result is a string with one of the choices. If multiple is true, then the result is a list of strings from the choices.

Note that for some use cases, the choices need to be generated dynamically. This can be done via subclassing and overriding the ‘getChoices’ member function. An example of this is provided by the source for the InheritBuildParameter class.

Its arguments, in addition to the common options, are:

choices

The list of available choices.

strict (optional; default is True)

If true, verify that the user’s input is from the list. Note that this only affects the validation of the form request; even if this argument is False, there is no HTML form component available to enter an arbitrary value.

multiple

If true, then the user may select multiple choices.

Example:

ChoiceStringParameter(name="forced_tests",
                      label="smoke test campaign to run",
                      default=default_tests,
                      multiple=True,
                      strict=True,
                      choices=["test_builder1", "test_builder2",
                               "test_builder3"])

# .. and later base the schedulers to trigger off this property:

# triggers the tests depending on the property forced_test
builder1.factory.addStep(Trigger(name="Trigger tests",
                                schedulerNames=Property("forced_tests")))

Example of scheduler allowing to choose which worker to run on:

worker_list = ["worker1", "worker2", "worker3"]
ChoiceStringParameter(name="worker",
                      label="worker to run the build on",
                      default="*",
                      multiple=False,
                      strict=True,
                      choices=worker_list)

# .. and in nextWorker, use this property:
def nextWorker(bldr, workers, buildrequest):
    forced_worker = buildrequest.properties.getProperty("worker", "*")
    if forced_worker == "*":
        return random.choice(workers) if workers else None
    for w in workers:
        if w.worker.workername == forced_worker:
            return w
    return None  # worker not yet available

c['builders'] = [
  BuilderConfig(name='mybuild', factory=f, nextWorker=nextWorker,
        workernames=worker_list),
]
CodebaseParameter
CodebaseParameter(codebase="myrepo")

This is a parameter group to specify a sourcestamp for a given codebase.

codebase

The name of the codebase.

branch (optional; default is StringParameter)

A parameter specifying the branch to build.

revision (optional; default is StringParameter)

A parameter specifying the revision to build.

repository (optional; default is StringParameter)

A parameter specifying the repository for the build.

project (optional; default is StringParameter)

A parameter specifying the project for the build.

patch (optional; default is None)

A PatchParameter specifying that the user can upload a patch for this codebase.

FileParameter

This parameter allows the user to upload a file to a build. The user can either write some text to a text area, or select a file from the browser. Note that the file is then stored inside a property, so a maxsize of 10 megabytes has been set. You can still override that maxsize if you wish.

PatchParameter

This parameter allows the user to specify a patch to be applied at the source step. The patch is stored within the sourcestamp, and associated to a codebase. That is why PatchParameter must be set inside a CodebaseParameter.

PatchParameter is actually a NestedParameter composed of following fields:

FileParameter('body'),
IntParameter('level', default=1),
StringParameter('author', default=""),
StringParameter('comment', default=""),
StringParameter('subdir', default=".")

You can customize any of these fields by overwriting their field name e.g:

c['schedulers'] = [
    schedulers.ForceScheduler(
        name="force",
        codebases=[util.CodebaseParameter("foo", patch=util.PatchParameter(
            body=FileParameter('body', maxsize=10000)))],  # override the maximum size
                                                           # of a patch to 10k instead of 10M
        builderNames=["testy"])]
InheritBuildParameter

Note

InheritBuildParameter is not yet ported to data API, and cannot be used with buildbot nine yet (bug #3521).

This is a special parameter for inheriting force build properties from another build. The user is presented with a list of compatible builds from which to choose, and all forced-build parameters from the selected build are copied into the new build. The new parameter is:

compatible_builds

A function to find compatible builds in the build history. This function is given the master instance as first argument, and the current builder name as second argument, or None when forcing all builds.

Example:

@defer.inlineCallbacks
def get_compatible_builds(master, builder):
    if builder is None: # this is the case for force_build_all
        return ["cannot generate build list here"]
    # find all successful builds in builder1 and builder2
    builds = []
    for builder in ["builder1", "builder2"]:
        # get 40 last builds for the builder
        build_dicts = yield master.data.get(('builders', builder, 'builds'),
                                            order=['-buildid'], limit=40)
        for build_dict in build_dicts:
            if build_dict['results'] != SUCCESS:
                continue
            builds.append(builder + "/" + str(build_dict['number']))
    return builds

# ...

sched = Scheduler(...,
    properties=[
        InheritBuildParameter(
            name="inherit",
            label="promote a build for merge",
            compatible_builds=get_compatible_builds,
            required = True),
            ])
WorkerChoiceParameter

Note

WorkerChoiceParameter is not yet ported to data API, and cannot be used with buildbot nine yet (bug #3521).

This parameter allows a scheduler to require that a build is assigned to the chosen worker. The choice is assigned to the workername property for the build. The enforceChosenWorker functor must be assigned to the canStartBuild parameter for the Builder.

Example:

from buildbot.plugins import util

# schedulers:
ForceScheduler(
    # ...
    properties=[
        WorkerChoiceParameter(),
    ]
)

# builders:
BuilderConfig(
    # ...
    canStartBuild=util.enforceChosenWorker,
)
AnyPropertyParameter

This parameter type can only be used in properties, and allows the user to specify both the property name and value in the web form.

This Parameter is here to reimplement old Buildbot behavior, and should be avoided. Stricter parameter names and types should be preferred.

2.5.6. Workers

The workers configuration key specifies a list of known workers. In the common case, each worker is defined by an instance of the buildbot.worker.Worker class. It represents a standard, manually started machine that will try to connect to the Buildbot master as a worker. Buildbot also supports “on-demand”, or latent, workers, which allow Buildbot to dynamically start and stop worker instances.

2.5.6.1. Defining Workers

A Worker instance is created with a workername and a workerpassword. These are the same two values that need to be provided to the worker administrator when they create the worker.

The workername must be unique, of course. The password exists to prevent evildoers from interfering with Buildbot by inserting their own (broken) workers into the system and thus displacing the real ones. Password may be a Secret.

Workers with an unrecognized workername or a non-matching password will be rejected when they attempt to connect, and a message describing the problem will be written to the log file (see Logfiles).

A configuration for two workers would look like:

from buildbot.plugins import worker
c['workers'] = [
    worker.Worker('bot-solaris', 'solarispasswd'),
    worker.Worker('bot-bsd', 'bsdpasswd'),
]
2.5.6.2. Worker Options
Properties

Worker objects can also be created with an optional properties argument, a dictionary specifying properties that will be available to any builds performed on this worker. For example:

c['workers'] = [
    worker.Worker('bot-solaris', 'solarispasswd',
                  properties={'os': 'solaris'}),
]

Worker properties have priority over other sources (Builder, Scheduler, etc.). You may use the defaultProperties parameter that will only be added to Build Properties if they are not already set by another source:

c['workers'] = [
    worker.Worker('fast-bot', 'fast-passwd',
                  defaultProperties={'parallel_make': 10}),
]

Worker collects and exposes /etc/os-release fields for interpolation. These can be used to determine details about the running operating system, such as distribution and version. See https://www.linux.org/docs/man5/os-release.html for details on possible fields. Each field is imported with os_ prefix and in lower case. os_id, os_id_like, os_version_id and os_version_codename are always set, but can be null.

Limiting Concurrency

The Worker constructor can also take an optional max_builds parameter to limit the number of builds that it will execute simultaneously:

c['workers'] = [
    worker.Worker('bot-linux', 'linuxpassword',
                  max_builds=2),
]

Note

In Worker For Builders concept only one build from the same builder would run on the worker.

Master-Worker TCP Keepalive

By default, the buildmaster sends a simple, non-blocking message to each worker every hour. These keepalives ensure that traffic is flowing over the underlying TCP connection, allowing the system’s network stack to detect any problems before a build is started.

The interval can be modified by specifying the interval in seconds using the keepalive_interval parameter of Worker (defaults to 3600):

c['workers'] = [
    worker.Worker('bot-linux', 'linuxpasswd',
                  keepalive_interval=3600)
]

The interval can be set to None to disable this functionality altogether.

When Workers Go Missing

Sometimes, the workers go away. One very common reason for this is when the worker process is started once (manually) and left running, but then later the machine reboots and the process is not automatically restarted.

If you’d like to have the administrator of the worker (or other people) be notified by email when the worker has been missing for too long, just add the notify_on_missing= argument to the Worker definition. This value can be a single email address, or a list of addresses:

c['workers'] = [
    worker.Worker('bot-solaris', 'solarispasswd',
                  notify_on_missing='bob@example.com')
]

By default, this will send an email when the worker has been disconnected for more than one hour. Only one email per connection-loss event will be sent. To change the timeout, use missing_timeout= and give it a number of seconds (the default is 3600).

You can have the buildmaster send an email to multiple recipients by providing a list of addresses instead of a single one:

c['workers'] = [
    worker.Worker('bot-solaris', 'solarispasswd',
                  notify_on_missing=['bob@example.com', 'alice@example.org'],
                  missing_timeout=300)  # notify after 5 minutes
]

The email sent this way will use a MailNotifier (see MailNotifier) status target, if one is configured. This provides a way for you to control the from address of the email, as well as the relayhost (aka smarthost) to use as an SMTP server. If no MailNotifier is configured on this buildmaster, the worker-missing emails will be sent using a default configuration.

Note that if you want to have a MailNotifier for worker-missing emails but not for regular build emails, just create one with builders=[], as follows:

from buildbot.plugins import status, worker
m = status.MailNotifier(fromaddr='buildbot@localhost', builders=[],
                        relayhost='smtp.example.org')
c['reporters'].append(m)

c['workers'] = [
    worker.Worker('bot-solaris', 'solarispasswd',
                  notify_on_missing='bob@example.com')
]
Workers States

There are some times when a worker misbehaves because of issues with its configuration. In those cases, you may want to pause the worker, or maybe completely shut it down.

There are three actions that you may take (in the worker’s web page Actions dialog):

  • Pause: If a worker is paused, it won’t accept new builds. The action of pausing a worker will not affect any ongoing build.

  • Graceful Shutdown: If a worker is in graceful shutdown mode, it won’t accept new builds, but will finish the current builds. When all of its build are finished, the buildbot-worker process will terminate.

  • Force Shutdown: If a worker is in force shutdown mode, it will terminate immediately, and the build it was currently doing will be put to retry state.

Those actions will put the worker in either of two states:

  • paused: the worker is paused if it is connected but doesn’t accept new builds.

  • graceful: the worker is graceful if it doesn’t accept new builds, and will shutdown when builds are finished.

A worker might not be able to accept a job for a period of time if buildbot detects a misbehavior. This is called the quarantine timer.

Quarantine timer is an exponential back-off mechanism for workers. This prevents a misbehaving worker from eating the build queue by quickly finishing builds in EXCEPTION state. When misbehavior is detected, the timer will pause the worker for 10 seconds, and then the time will double with each misbehavior detection until the worker finishes a build.

The first case of misbehavior is for a latent worker to not start properly. The second case of misbehavior is for a build to end with an EXCEPTION status.

Pausing and unpausing a worker will force it to leave quarantine immediately. The quarantine timeout will not be reset until the worker finishes a build.

Worker states are stored in the database, can be queried via REST API, and are visible in the UI’s workers page.

2.5.6.3. Local Workers

For smaller setups, you may want to just run the workers on the same machine as the master. To simplify the maintenance, you may even want to run them in the same process.

This is what LocalWorker is for. Instead of configuring a worker.Worker, you have to configure a worker.LocalWorker. As the worker is running on the same process, password is not necessary. You can run as many local workers as your machine’s CPU and memory allows.

A configuration for two workers would look like:

from buildbot.plugins import worker
c['workers'] = [
    worker.LocalWorker('bot1'),
    worker.LocalWorker('bot2'),
]

In order to use local workers you need to have buildbot-worker package installed.

2.5.6.4. Latent Workers

The standard Buildbot model has workers started manually. The previous section described how to configure the master for this approach.

Another approach is to let the Buildbot master start workers when builds are ready, on-demand. Thanks to services such as Amazon Web Services’ Elastic Compute Cloud (“AWS EC2”), this is relatively easy to set up, and can be very useful for some situations.

The workers that are started on-demand are called “latent” workers. You can find the list of Supported Latent Workers below.

Common Options

The following options are available for all latent workers.

build_wait_timeout

This option allows you to specify how long a latent worker should wait after a build for another build before it shuts down. It defaults to 10 minutes. If this is set to 0, then the worker will be shut down immediately. If it is less than 0, it will be shut down only when shutting down master.

check_instance_interval

This option controls the interval that the health checks run during worker startup. The health checks speed up the detection of irrecoverably crashed worker (e.g. due to an issue with Docker image in the case of Docker workers). Without such checks build would continue waiting for the worker to connect until missing_timeout time elapses. The value of the option defaults to 10 seconds.

Supported Latent Workers

As of time of writing, Buildbot supports the following latent workers:

Amazon Web Services Elastic Compute Cloud (“AWS EC2”)
class buildbot.worker.ec2.EC2LatentWorker

EC2 is a web service that allows you to start virtual machines in an Amazon data center. Please see their website for details, including costs. Using the AWS EC2 latent workers involves getting an EC2 account with AWS and setting up payment; customizing one or more EC2 machine images (“AMIs”) on your desired operating system(s) and publishing them (privately if needed); and configuring the buildbot master to know how to start your customized images for “substantiating” your latent workers.

This document will guide you through setup of a AWS EC2 latent worker:

Get an AWS EC2 Account

To start off, to use the AWS EC2 latent worker, you need to get an AWS developer account and sign up for EC2. Although Amazon often changes this process, these instructions should help you get started:

  1. Go to http://aws.amazon.com/ and click to “Sign Up Now” for an AWS account.

  2. Once you are logged into your account, you need to sign up for EC2. Instructions for how to do this have changed over time because Amazon changes their website, so the best advice is to hunt for it. After signing up for EC2, it may say it wants you to upload an x.509 cert. You will need this to create images (see below) but it is not technically necessary for the buildbot master configuration.

  3. You must enter a valid credit card before you will be able to use EC2. Do that under ‘Payment Method’.

  4. Make sure you’re signed up for EC2 by going to Your Account ‣ Account Activity and verifying EC2 is listed.

Create an AMI

Now you need to create an AMI and configure the master. You may need to run through this cycle a few times to get it working, but these instructions should get you started.

Creating an AMI is out of the scope of this document. The EC2 Getting Started Guide is a good resource for this task. Here are a few additional hints.

  • When an instance of the image starts, it needs to automatically start a buildbot worker that connects to your master (to create a buildbot worker, Creating a worker; to make a daemon, Launching the daemons).

  • You may want to make an instance of the buildbot worker, configure it as a standard worker in the master (i.e., not as a latent worker), and test and debug it that way before you turn it into an AMI and convert to a latent worker in the master.

  • In order to avoid extra costs in case of master failure, you should configure the worker of the AMI with maxretries option (see Worker Options) Also see example systemd unit file example

Configure the Master with an EC2LatentWorker

Now let’s assume you have an AMI that should work with the EC2LatentWorker. It’s now time to set up your buildbot master configuration.

You will need some information from your AWS account: the Access Key Id and the Secret Access Key. If you’ve built the AMI yourself, you probably already are familiar with these values. If you have not, and someone has given you access to an AMI, these hints may help you find the necessary values:

  • While logged into your AWS account, find the “Access Identifiers” link (either on the left, or via Your Account ‣ Access Identifiers.

  • On the page, you’ll see alphanumeric values for “Your Access Key Id:” and “Your Secret Access Key:”. Make a note of these. Later on, we’ll call the first one your identifier and the second one your secret_identifier.

When creating an EC2LatentWorker in the buildbot master configuration, the first three arguments are required. The name and password are the first two arguments, and work the same as with normal workers. The next argument specifies the type of the EC2 virtual machine (available options as of this writing include m1.small, m1.large, m1.xlarge, c1.medium, and c1.xlarge; see the EC2 documentation for descriptions of these machines).

Here is the simplest example of configuring an EC2 latent worker. It specifies all necessary remaining values explicitly in the instantiation.

from buildbot.plugins import worker
c['workers'] = [
    worker.EC2LatentWorker('bot1', 'sekrit', 'm1.large',
                           ami='ami-12345',
                           identifier='publickey',
                           secret_identifier='privatekey'
                           keypair_name='latent_buildbot_worker',
                           security_name='latent_buildbot_worker',
                           )
]

The ami argument specifies the AMI that the master should start. The identifier argument specifies the AWS Access Key Id, and the secret_identifier specifies the AWS Secret Access Key. Both the AMI and the account information can be specified in alternate ways.

Note

Whoever has your identifier and secret_identifier values can request AWS work charged to your account, so these values need to be carefully protected. Another way to specify these access keys is to put them in a separate file. Buildbot supports the standard AWS credentials file. You can then make the access privileges stricter for this separate file, and potentially let more people read your main configuration file. If your master is running in EC2, you can also use IAM roles for EC2 to delegate permissions.

keypair_name and security_name allow you to specify different names for these AWS EC2 values.

You can make an .aws directory in the home folder of the user running the buildbot master. In that directory, create a file called credentials. The format of the file should be as follows, replacing identifier and secret_identifier with the credentials obtained before.

[default]
aws_access_key_id = identifier
aws_secret_access_key = secret_identifier

If you are using IAM roles, no config file is required. Then you can instantiate the worker as follows.

from buildbot.plugins import worker
c['workers'] = [
    worker.EC2LatentWorker('bot1', 'sekrit', 'm1.large',
                           ami='ami-12345',
                           keypair_name='latent_buildbot_worker',
                           security_name='latent_buildbot_worker',
                           )
]

Previous examples used a particular AMI. If the Buildbot master will be deployed in a process-controlled environment, it may be convenient to specify the AMI more flexibly. Rather than specifying an individual AMI, specify one or two AMI filters.

In all cases, the AMI that sorts last by its location (the S3 bucket and manifest name) will be preferred.

One available filter is to specify the acceptable AMI owners, by AWS account number (the 12 digit number, usually rendered in AWS with hyphens like “1234-5678-9012”, should be entered as in integer).

from buildbot.plugins import worker
bot1 = worker.EC2LatentWorker('bot1', 'sekrit', 'm1.large',
                              valid_ami_owners=[11111111111,
                                                22222222222],
                              identifier='publickey',
                              secret_identifier='privatekey',
                              keypair_name='latent_buildbot_worker',
                              security_name='latent_buildbot_worker',
                              )

The other available filter is to provide a regular expression string that will be matched against each AMI’s location (the S3 bucket and manifest name).

from buildbot.plugins import worker
bot1 = worker.EC2LatentWorker(
        'bot1', 'sekrit', 'm1.large',
        valid_ami_location_regex=r'buildbot\-.*/image.manifest.xml',
        identifier='publickey',
        secret_identifier='privatekey',
        keypair_name='latent_buildbot_worker',
        security_name='latent_buildbot_worker',
        )

The regular expression can specify a group, which will be preferred for the sorting. Only the first group is used; subsequent groups are ignored.

from buildbot.plugins import worker
bot1 = worker.EC2LatentWorker(
    'bot1', 'sekrit', 'm1.large',
    valid_ami_location_regex=r'buildbot\-.*\-(.*)/image.manifest.xml',
    identifier='publickey',
    secret_identifier='privatekey',
    keypair_name='latent_buildbot_worker',
    security_name='latent_buildbot_worker',
    )

If the group can be cast to an integer, it will be. This allows 10 to sort after 1, for instance.

from buildbot.plugins import worker
bot1 = worker.EC2LatentWorker(
        'bot1', 'sekrit', 'm1.large',
        valid_ami_location_regex=r'buildbot\-.*\-(\d+)/image.manifest.xml',
        identifier='publickey',
        secret_identifier='privatekey',
        keypair_name='latent_buildbot_worker',
        security_name='latent_buildbot_worker',
        )

In addition to using the password as a handshake between the master and the worker, you may want to use a firewall to assert that only machines from a specific IP can connect as workers. This is possible with AWS EC2 by using the Elastic IP feature. To configure, generate a Elastic IP in AWS, and then specify it in your configuration using the elastic_ip argument.

from buildbot.plugins import worker
c['workers'] = [
    worker.EC2LatentWorker('bot1', 'sekrit', 'm1.large',
                           'ami-12345',
                           identifier='publickey',
                           secret_identifier='privatekey',
                           elastic_ip='208.77.188.166',
                           keypair_name='latent_buildbot_worker',
                           security_name='latent_buildbot_worker',
                           )
]

One other way to configure a worker is by settings AWS tags. They can for example be used to have a more restrictive security IAM policy. To get Buildbot to tag the latent worker specify the tag keys and values in your configuration using the tags argument.

from buildbot.plugins import worker
c['workers'] = [
    worker.EC2LatentWorker('bot1', 'sekrit', 'm1.large',
                           'ami-12345',
                           identifier='publickey',
                           secret_identifier='privatekey',
                           keypair_name='latent_buildbot_worker',
                           security_name='latent_buildbot_worker',
                           tags={'SomeTag': 'foo'})
]

If the worker needs access to additional AWS resources, you can also enable your workers to access them via an EC2 instance profile. To use this capability, you must first create an instance profile separately in AWS. Then specify its name on EC2LatentWorker via instance_profile_name.

from buildbot.plugins import worker
c['workers'] = [
    worker.EC2LatentWorker('bot1', 'sekrit', 'm1.large',
                           ami='ami-12345',
                           keypair_name='latent_buildbot_worker',
                           security_name='latent_buildbot_worker',
                           instance_profile_name='my_profile'
                           )
]

You may also supply your own boto3.Session object to allow for more flexible session options (ex. cross-account) To use this capability, you must first create a boto3.Session object. Then provide it to EC2LatentWorker via session argument.

import boto3
from buildbot.plugins import worker

session = boto3.session.Session()
c['workers'] = [
    worker.EC2LatentWorker('bot1', 'sekrit', 'm1.large',
                           ami='ami-12345',
                           keypair_name='latent_buildbot_worker',
                           security_name='latent_buildbot_worker',
                           session=session
                           )
]

The EC2LatentWorker supports all other configuration from the standard Worker. The missing_timeout and notify_on_missing specify how long to wait for an EC2 instance to attach before considering the attempt to have failed, and email addresses to alert, respectively. missing_timeout defaults to 20 minutes.

Volumes

If you want to attach existing volumes to an ec2 latent worker, use the volumes attribute. This mechanism can be valuable if you want to maintain state on a conceptual worker across multiple start/terminate sequences. volumes expects a list of (volume_id, mount_point) tuples to attempt attaching when your instance has been created.

If you want to attach new ephemeral volumes, use the the block_device_map attribute. This follows the AWS API syntax, essentially acting as a passthrough. The only distinction is that the volumes default to deleting on termination to avoid leaking volume resources when workers are terminated. See boto documentation for further details.

from buildbot.plugins import worker
c['workers'] = [
    worker.EC2LatentWorker('bot1', 'sekrit', 'm1.large',
                           ami='ami-12345',
                           keypair_name='latent_buildbot_worker',
                           security_name='latent_buildbot_worker',
                           block_device_map= [
                             {
                                "DeviceName": "/dev/xvdb",
                                "Ebs" : {
                                   "VolumeType": "io1",
                                   "Iops": 1000,
                                   "VolumeSize": 100
                                }
                             }
                           ]
                           )
]
VPC Support

If you are managing workers within a VPC, your worker configuration must be modified from above. You must specify the id of the subnet where you want your worker placed. You must also specify security groups created within your VPC as opposed to classic EC2 security groups. This can be done by passing the ids of the vpc security groups. Note, when using a VPC, you can not specify classic EC2 security groups (as specified by security_name).

from buildbot.plugins import worker
c['workers'] = [
    worker.EC2LatentWorker('bot1', 'sekrit', 'm1.large',
                           ami='ami-12345',
                           keypair_name='latent_buildbot_worker',
                           subnet_id='subnet-12345',
                           security_group_ids=['sg-12345','sg-67890']
                           )
]
Spot instances

If you would prefer to use spot instances for running your builds, you can accomplish that by passing in a True value to the spot_instance parameter to the EC2LatentWorker constructor. Additionally, you may want to specify max_spot_price and price_multiplier in order to limit your builds’ budget consumption.

from buildbot.plugins import worker
c['workers'] = [
    worker.EC2LatentWorker('bot1', 'sekrit', 'm1.large',
                           'ami-12345', region='us-west-2',
                           identifier='publickey',
                           secret_identifier='privatekey',
                           elastic_ip='208.77.188.166',
                           keypair_name='latent_buildbot_worker',
                           security_name='latent_buildbot_worker',
                           placement='b', spot_instance=True,
                           max_spot_price=0.09,
                           price_multiplier=1.15,
                           product_description='Linux/UNIX')
]

This example would attempt to create a m1.large spot instance in the us-west-2b region costing no more than $0.09/hour. The spot prices for ‘Linux/UNIX’ spot instances in that region over the last 24 hours will be averaged and multiplied by the price_multiplier parameter, then a spot request will be sent to Amazon with the above details. If the multiple exceeds the max_spot_price, the bid price will be the max_spot_price.

Either max_spot_price or price_multiplier, but not both, may be None. If price_multiplier is None, then no historical price information is retrieved; the bid price is simply the specified max_spot_price. If the max_spot_price is None, then the multiple of the historical average spot prices is used as the bid price with no limit.

Libvirt
class buildbot.worker.libvirt.LibVirtWorker

libvirt is a virtualization API for interacting with the virtualization capabilities of recent versions of Linux and other OSes. It is LGPL and comes with a stable C API, and Python bindings.

This means we now have an API which when tied to buildbot allows us to have workers that run under Xen, QEMU, KVM, LXC, OpenVZ, User Mode Linux, VirtualBox and VMWare.

The libvirt code in Buildbot was developed against libvirt 0.7.5 on Ubuntu Lucid. It is used with KVM to test Python code on VMs, but obviously isn’t limited to that. Each build is run on a new VM, images are temporary and thrown away after each build.

This document will guide you through setup of a libvirt latent worker:

Setting up libvirt

We won’t show you how to set up libvirt as it is quite different on each platform, but there are a few things you should keep in mind.

  • If you are using the system libvirt (libvirt and buildbot master are on same server), your buildbot master user will need to be in the libvirtd group.

  • If libvirt and buildbot master are on different servers, the user connecting to libvirt over ssh will need to be in the libvirtd group. Also need to setup authorization via ssh-keys (without password prompt).

  • If you are using KVM, your buildbot master user will need to be in the KVM group.

  • You need to think carefully about your virtual network first. Will NAT be enough? What IP will my VMs need to connect to for connecting to the master?

Configuring your base image

You need to create a base image for your builds that has everything needed to build your software. You need to configure the base image with a buildbot worker that is configured to connect to the master on boot.

Because this image may need updating a lot, we strongly suggest scripting its creation.

If you want to have multiple workers using the same base image it can be annoying to duplicate the image just to change the buildbot credentials. One option is to use libvirt’s DHCP server to allocate an identity to the worker: DHCP sets a hostname, and the worker takes its identity from that.

Doing all this is really beyond the scope of the manual, but there is a vmbuilder script and a network.xml file to create such a DHCP server in master/contrib/ (Contrib Scripts) that should get you started:

sudo apt-get install ubuntu-vm-builder
sudo contrib/libvirt/vmbuilder

Should create an ubuntu/ folder with a suitable image in it.

virsh net-define contrib/libvirt/network.xml
virsh net-start buildbot-network

Should set up a KVM compatible libvirt network for your buildbot VM’s to run on.

Configuring your Master

If you want to add a simple on demand VM to your setup, you only need the following. We set the username to minion1, the password to sekrit. The base image is called base_image and a copy of it will be made for the duration of the VM’s life. That copy will be thrown away every time a build is complete.

from buildbot.plugins import worker, util
c['workers'] = [
    worker.LibVirtWorker('minion1', 'sekrit',
                         uri="qemu:///session",
                         hd_image='/home/buildbot/images/minion1',
                         base_image='/home/buildbot/images/base_image')
]

You can use virt-manager to define minion1 with the correct hardware. If you don’t, buildbot won’t be able to find a VM to start.

LibVirtWorker accepts the following arguments:

name

Both a buildbot username and the name of the virtual machine.

password

A password for the buildbot to login to the master with.

connection

Connection instance wrapping connection to libvirt. (deprecated, use uri).

hd_image

The path to a libvirt disk image, normally in qcow2 format when using KVM.

base_image

If given a base image, buildbot will clone it every time it starts a VM. This means you always have a clean environment to do your build in.

uri

The URI of the connection to libvirt.

masterFQDN

(optional, defaults to socket.getfqdn()) Address of the master the worker should connect to. Use if you master machine does not have proper fqdn. This value is passed to the libvirt image via domain metadata.

xml

If a VM isn’t predefined in virt-manager, then you can instead provide XML like that used with virsh define. The VM will be created automatically when needed, and destroyed when not needed any longer.

Note

The hd_image and base_image must be on same machine with buildbot master.

Connection to master

If xml configuration key is not provided, then Buildbot will set libvirt metadata for the domain. It will contain the following XML element: <auth username="..." password="..." master="..."/>. Here username, password and master are the name of the worker, password to use for connection and the FQDN of the master. The libvirt metadata will be placed in the XML namespace buildbot=http://buildbot.net/.

Configuring Master to use libvirt on remote server

If you want to use libvirt on remote server configure remote libvirt server and buildbot server following way.

  1. Define user to connect to remote machine using ssh. Configure connection of such user to remote libvirt server (see https://wiki.libvirt.org/page/SSHSetup) without password prompt.

  2. Add user to libvirtd group on remote libvirt server sudo usermod -G libvirtd -a <user>.

Configure remote libvirt server:

  1. Create virtual machine for buildbot and configure it.

  2. Change virtual machine image file to new name, which will be used as temporary image and deleted after virtual machine stops. Execute command sudo virsh edit <VM name>. In xml file locate devices/disk/source and change file path to new name. The file must not be exists, it will create via hook script.

  3. Add hook script to /etc/libvirt/hooks/qemu to recreate VM image each start:

#!/usr/bin/python

# Script /etc/libvirt/hooks/qemu
# Don't forget to execute service libvirt-bin restart
# Also see https://www.libvirt.org/hooks.html

# This script make clean VM for each start using base image

import os
import subprocess
import sys

images_path = '/var/lib/libvirt/images/'

# build-vm - VM name in virsh list --all
# vm_base_image.qcow2 - base image file name, must exist in path /var/lib/libvirt/images/
# vm_temp_image.qcow2 - temporary image. Must not exist in path /var/lib/libvirt/images/, but
# defined in VM config file
domains = {
    'build-vm' : ['vm_base_image.qcow2', 'vm_temp_image.qcow2'],
}

def delete_image_clone(vir_domain):
    if vir_domain in domains:
        domain = domains[vir_domain]
        os.remove(images_path + domain[1])

def create_image_clone(vir_domain):
    if vir_domain in domains:
        domain = domains[vir_domain]
        cmd = ['/usr/bin/qemu-img', 'create', '-b', images_path + domain[0],
               '-f', 'qcow2', images_path + domain[1]]
        subprocess.call(cmd)

if __name__ == "__main__":
    vir_domain, action = sys.argv[1:3]

    if action in ["prepare"]:
        create_image_clone(vir_domain)

    if action in ["release"]:
        delete_image_clone(vir_domain)

Configure buildbot server:

  1. On buildbot server in virtual environment install libvirt-python package: pip install libvirt-python

  2. Create worker using remote ssh connection.

from buildbot.plugins import worker, util
c['workers'] = [
    worker.LibVirtWorker(
        'minion1', 'sekrit',
        util.Connection("qemu+ssh://<user>@<ip address or DNS name>:<port>/session"),
        '/home/buildbot/images/minion1')
]
OpenStack
class buildbot.worker.openstack.OpenStackLatentWorker

OpenStack is a series of interconnected components that facilitates managing compute, storage, and network resources in a data center. It is available under the Apache License and has a REST interface along with a Python client.

This document will guide you through setup of an OpenStack latent worker:

Install dependencies

OpenStackLatentWorker requires python-novaclient to work, you can install it with pip install python-novaclient.

Get an Account in an OpenStack cloud

Setting up OpenStack is outside the domain of this document. There are four account details necessary for the Buildbot master to interact with your OpenStack cloud: username, password, a tenant name, and the auth URL to use.

Create an Image

OpenStack supports a large number of image formats. OpenStack maintains a short list of prebuilt images; if the desired image is not listed, The OpenStack Compute Administration Manual is a good resource for creating new images. You need to configure the image with a buildbot worker to connect to the master on boot.

Configure the Master with an OpenStackLatentWorker

With the configured image in hand, it is time to configure the buildbot master to create OpenStack instances of it. You will need the aforementioned account details. These are the same details set in either environment variables or passed as options to an OpenStack client.

OpenStackLatentWorker accepts the following arguments:

name

The worker name.

password

A password for the worker to login to the master with.

flavor

A string containing the flavor name or UUID to use for the instance.

image

A string containing the image name or UUID to use for the instance.

os_username

os_password

os_tenant_name

os_user_domain

os_project_domain

os_auth_url

The OpenStack authentication needed to create and delete instances. These are the same as the environment variables with uppercase names of the arguments.

os_auth_args

Arguments passed directly to keystone. If this is specified, other authentication parameters (see above) are ignored. You can use auth_type to specify auth plugin to load. See OpenStack documentation <https://docs.openstack.org/python-keystoneclient/> for more information. Usually this should contain auth_url, username, password, project_domain_name and user_domain_name.

block_devices

A list of dictionaries. Each dictionary specifies a block device to set up during instance creation. The values support using properties from the build and will be rendered when the instance is started.

Supported keys

uuid

(required): The image, snapshot, or volume UUID.

volume_size

(optional): Size of the block device in GiB. If not specified, the minimum size in GiB to contain the source will be calculated and used.

device_name

(optional): defaults to vda. The name of the device in the instance; e.g. vda or xda.

source_type

(optional): defaults to image. The origin of the block device. Valid values are image, snapshot, or volume.

destination_type

(optional): defaults to volume. Destination of block device: volume or local.

delete_on_termination

(optional): defaults to True. Controls if the block device will be deleted when the instance terminates.

boot_index

(optional): defaults to 0. Integer used for boot order.

meta

A dictionary of string key-value pairs to pass to the instance. These will be available under the metadata key from the metadata service.

nova_args

(optional) A dict that will be appended to the arguments when creating a VM. Buildbot uses the OpenStack Nova version 2 API by default (see client_version).

client_version

(optional) A string containing the Nova client version to use. Defaults to 2. Supports using 2.X, where X is a micro-version. Use 1.1 for the previous, deprecated, version. If using 1.1, note that an older version of novaclient will be needed so it won’t switch to using 2.

region

(optional) A string specifying region where to instantiate the worker.

Here is the simplest example of configuring an OpenStack latent worker.

from buildbot.plugins import worker
c['workers'] = [
    worker.OpenStackLatentWorker('bot2', 'sekrit',
                flavor=1, image='8ac9d4a4-5e03-48b0-acde-77a0345a9ab1',
                os_username='user', os_password='password',
                os_tenant_name='tenant',
                os_auth_url='http://127.0.0.1:35357/v2.0')
]

The image argument also supports being given a callable. The callable will be passed the list of available images and must return the image to use. The invocation happens in a separate thread to prevent blocking the build master when interacting with OpenStack.

from buildbot.plugins import worker

def find_image(images):
    # Sort oldest to newest.
    def key_fn(x):
        return x.created

    candidate_images = sorted(images, key=key_fn)
    # Return the oldest candidate image.
    return candidate_images[0]

c['workers'] = [
    worker.OpenStackLatentWorker('bot2', 'sekrit',
                flavor=1, image=find_image,
                os_username='user', os_password='password',
                os_tenant_name='tenant',
                os_auth_url='http://127.0.0.1:35357/v2.0')
]

The block_devices argument is minimally manipulated to provide some defaults and passed directly to novaclient. The simplest example is an image that is converted to a volume and the instance boots from that volume. When the instance is destroyed, the volume will be terminated as well.

from buildbot.plugins import worker
c['workers'] = [
    worker.OpenStackLatentWorker('bot2', 'sekrit',
                flavor=1, image='8ac9d4a4-5e03-48b0-acde-77a0345a9ab1',
                os_username='user', os_password='password',
                os_tenant_name='tenant',
                os_auth_url='http://127.0.0.1:35357/v2.0',
                block_devices=[
                    {'uuid': '3f0b8868-67e7-4a5b-b685-2824709bd486',
                    'volume_size': 10}])
]

The nova_args can be used to specify additional arguments for the novaclient. For example network mappings, which is required if your OpenStack tenancy has more than one network, and default cannot be determined. Please refer to your OpenStack manual whether it wants net-id or net-name.

Other useful parameters are availability_zone, security_groups and config_drive. Refer to Python bindings to the OpenStack Nova API for more information. It is found on section Servers, method create.

from buildbot.plugins import worker
c['workers'] = [
    worker.OpenStackLatentWorker('bot2', 'sekrit',
                flavor=1, image='8ac9d4a4-5e03-48b0-acde-77a0345a9ab1',
                os_username='user', os_password='password',
                os_tenant_name='tenant',
                os_auth_url='http://127.0.0.1:35357/v2.0',
                nova_args={
                  'nics': [
                            {'net-id':'uid-of-network'}
                          ]})
]

OpenStackLatentWorker supports all other configuration from the standard Worker. The missing_timeout and notify_on_missing specify how long to wait for an OpenStack instance to attach before considering the attempt to have failed and email addresses to alert, respectively. missing_timeout defaults to 20 minutes.

Docker latent worker
class buildbot.worker.docker.DockerLatentWorker
class buildbot.plugins.worker.DockerLatentWorker

Docker is an open-source project that automates the deployment of applications inside software containers. The DockerLatentWorker attempts to instantiate a fresh image for each build to assure consistency of the environment between builds. Each image will be discarded once the worker finished processing the build queue (i.e. becomes idle). See build_wait_timeout to change this behavior.

This document will guide you through the setup of such workers.

Docker Installation

An easy way to try Docker is through installation of dedicated Virtual machines. Two of them stands out:

Beside, it is always possible to install Docker next to the buildmaster. Beware that in this case, overall performance will depend on how many builds the computer where you have your buildmaster can handle as everything will happen on the same one.

Note

It is not necessary to install Docker in the same environment as your master as we will make use to the Docker API through docker-py. More in master setup.

CoreOS

CoreOS is targeted at building infrastructure and distributed systems. In order to get the latent worker working with CoreOS, it is necessary to expose the docker socket outside of the Virtual Machine. If you installed it via Vagrant, it is also necessary to uncomment the following line in your config.rb file:

$expose_docker_tcp=2375

The following command should allow you to confirm that your Docker socket is now available via the network:

docker -H tcp://127.0.0.1:2375 ps
boot2docker

boot2docker is one of the fastest ways to boot to Docker. As it is meant to be used from outside of the Virtual Machine, the socket is already exposed. Please follow the installation instructions on how to find the address of your socket.

Image Creation

Our build master will need the name of an image to perform its builds. Each time a new build will be requested, the same base image will be used again and again, actually discarding the result of the previous build. If you need some persistent storage between builds, you can use Volumes.

Each Docker image has a single purpose. Our worker image will be running a buildbot worker.

Docker uses Dockerfiles to describe the steps necessary to build an image. The following example will build a minimal worker. This example is voluntarily simplistic, and should probably not be used in production, see next paragraph.

 1FROM debian:stable
 2RUN apt-get update && apt-get install -y \
 3   python-dev \
 4   python-pip
 5RUN pip install buildbot-worker
 6RUN groupadd -r buildbot && useradd -r -g buildbot buildbot
 7RUN mkdir /worker && chown buildbot:buildbot /worker
 8# Install your build-dependencies here ...
 9USER buildbot
10WORKDIR /worker
11RUN buildbot-worker create-worker . <master-hostname> <workername> <workerpassword>
12ENTRYPOINT ["/usr/local/bin/buildbot-worker"]
13CMD ["start", "--nodaemon"]

On line 11, the hostname for your master instance, as well as the worker name and password is setup. Don’t forget to replace those values with some valid ones for your project.

It is a good practice to set the ENTRYPOINT to the worker executable, and the CMD to ["start", "--nodaemon"]. This way, no parameter will be required when starting the image.

When your Dockerfile is ready, you can build your first image using the following command (replace myworkername with a relevant name for your case):

docker build -t myworkername - < Dockerfile
Reuse same image for different workers

Previous simple example hardcodes the worker name into the dockerfile, which will not work if you want to share your docker image between workers.

You can find in buildbot source code in master/contrib/docker one example configurations:

pythonnode_worker

a worker with Python and node installed, which demonstrate how to reuse the base worker to create variations of build environments. It is based on the official buildbot/buildbot-worker image.

The master setups several environment variables before starting the workers:

BUILDMASTER

The address of the master the worker shall connect to

BUILDMASTER_PORT

The port of the master’s worker ‘pb’ protocol.

WORKERNAME

The name the worker should use to connect to master

WORKERPASS

The password the worker should use to connect to master

Master Setup

We will rely on docker-py to connect our master with docker. Now is the time to install it in your master environment.

Before adding the worker to your master configuration, it is possible to validate the previous steps by starting the newly created image interactively. To do this, enter the following lines in a Python prompt where docker-py is installed:

>>> import docker
>>> docker_socket = 'tcp://localhost:2375'
>>> client = docker.client.APIClient(base_url=docker_socket)
>>> worker_image = 'my_project_worker'
>>> container = client.create_container(worker_image)
>>> client.start(container['Id'])
>>> # Optionally examine the logs of the master
>>> client.stop(container['Id'])
>>> client.wait(container['Id'])
0

It is now time to add the new worker to the master configuration under workers.

The following example will add a Docker latent worker for docker running at the following address: tcp://localhost:2375, the worker name will be docker, its password: password, and the base image name will be my_project_worker:

from buildbot.plugins import worker
c['workers'] = [
    worker.DockerLatentWorker('docker', 'password',
                              docker_host='tcp://localhost:2375',
                              image='my_project_worker')
]
password

(mandatory) The worker password part of the Latent Workers API. If the password is None, then it will be automatically generated from random number, and transmitted to the container via environment variable.

In addition to the arguments available for any Latent Workers, DockerLatentWorker will accept the following extra ones:

docker_host

(renderable string, mandatory) This is the address the master will use to connect with a running Docker instance.

image

(renderable string, mandatory) This is the name of the image that will be started by the build master. It should start a worker. This option can be a renderable, like Interpolate, so that it generates from the build request properties.

command

(optional) This will override the command setup during image creation.

volumes

(a renderable list of strings, optional) Allows to share directory between containers, or between a container and the host system. Refer to Docker documentation for more information about Volumes.

Each string within the volumes array specify a volume in the following format: volumename:bindname. The volume name has to be appended with :ro if the volume should be mounted read-only.

Note

This is the same format as when specifying volumes on the command line for docker’s own -v option.

dockerfile

(renderable string, optional if image is given) This is the content of the Dockerfile that will be used to build the specified image if the image is not found by Docker. It should be a multiline string.

Note

In case image and dockerfile are given, no attempt is made to compare the image with the content of the Dockerfile parameter if the image is found.

version

(optional, default to the highest version known by docker-py) This will indicates which API version must be used to communicate with Docker.

tls

(optional) This allow to use TLS when connecting with the Docker socket. This should be a docker.tls.TLSConfig object. See docker-py’s own documentation for more details on how to initialise this object.

followStartupLogs

(optional, defaults to false) This transfers docker container’s log inside master logs during worker startup (before connection). This can be useful to debug worker startup. e.g network issues, etc.

masterFQDN

(optional, defaults to socket.getfqdn()) Address of the master the worker should connect to. Use if you master machine does not have proper fqdn. This value is passed to the docker image via environment variable BUILDMASTER

hostconfig

(renderable dictionary, optional) Extra host configuration parameters passed as a dictionary used to create HostConfig object. See docker-py’s HostConfig documentation for all the supported options.

autopull

(optional, defaults to false) Automatically pulls image if requested image is not on docker host.

alwaysPull

(optional, defaults to false) Always pulls (update) image if autopull is set to true. Also affects the base image specified by FROM …. if using a dockerfile, autopull is not needed then.

target

(renderable string, optional) Sets target build stage for multi-stage builds when using a dockerfile.

custom_context
(renderable boolean, optional)

Boolean indicating that the user wants to use custom build arguments for the docker environment. Defaults to False.

encoding
(renderable string, optional)

String indicating the compression format for the build context. defaults to ‘gzip’, but ‘bzip’ can be used as well.

buildargs
(renderable dictionary, optional if custom_context is True)

Dictionary, passes information for the docker to build its environment. Eg. {‘DISTRO’:’ubuntu’, ‘RELEASE’:’11.11’}. Defaults to None.

hostname

(renderable string, optional) This will set container’s hostname.

Marathon latent worker

Marathon Marathon is a production-grade container orchestration platform for Mesosphere’s Data-center Operating System (DC/OS) and Apache Mesos.

Buildbot supports using Marathon to host your latent workers. It requires either txrequests or treq to be installed to allow interaction with http server. See HTTPClientService for details.

class buildbot.worker.marathon.MarathonLatentWorker
class buildbot.plugins.worker.MarathonLatentWorker

The MarathonLatentWorker attempts to instantiate a fresh image for each build to assure consistency of the environment between builds. Each image will be discarded once the worker finished processing the build queue (i.e. becomes idle). See build_wait_timeout to change this behavior.

In addition to the arguments available for any Latent Workers, MarathonLatentWorker will accept the following extra ones:

marathon_url

(mandatory) This is the URL to Marathon server. Its REST API will be used to start docker containers.

marathon_auth

(optional) This is the optional ('userid', 'password') BasicAuth credential. If txrequests is installed, this can be a requests authentication plugin.

image

(mandatory) This is the name of the image that will be started by the build master. It should start a worker. This option can be a renderable, like Interpolate, so that it generates from the build request properties. Images are by pulled from the default docker registry. MarathonLatentWorker does not support starting a worker built from a Dockerfile.

masterFQDN

(optional, defaults to socket.getfqdn()) Address of the master the worker should connect to. Use if you master machine does not have proper fqdn. This value is passed to the docker image via environment variable BUILDMASTER

If the value contains a colon (:), then BUILDMASTER and BUILDMASTER_PORT environment variables will be passed, following scheme: masterFQDN="$BUILDMASTER:$BUILDMASTER_PORT"

marathon_extra_config

(optional, defaults to {}`) Extra configuration to be passed to Marathon API. This implementation will setup the minimal configuration to run a worker (docker image, BRIDGED network) It will let the default for everything else, including memory size, volume mounting, etc. This configuration is voluntarily very raw so that it is easy to use new marathon features. This dictionary will be merged into the Buildbot generated config, and recursively override it. See Marathon API documentation to learn what to include in this config.

Kubernetes latent worker

Kubernetes is an open-source system for automating deployment, scaling, and management of containerized applications.

Buildbot supports using Kubernetes to host your latent workers.

class buildbot.worker.kubernetes.KubeLatentWorker
class buildbot.plugins.worker.KubeLatentWorker

The KubeLatentWorker attempts to instantiate a fresh container for each build to assure consistency of the environment between builds Each container will be discarded once the worker finished processing the build queue (i.e. becomes idle). See build_wait_timeout to change this behavior.

In addition to the arguments available for any Latent Workers, KubeLatentWorker will accept the following extra ones:

image

(optional, default to buildbot/buildbot-worker) Docker image. Default to the official buildbot image.

namespace

(optional) This is the name of the namespace. Default to the current namespace

kube_config

(mandatory) This is the object specifying how to connect to the kubernetes cluster. This object must be an instance of abstract class KubeConfigLoaderBase, which have 3 implementations:

  • KubeHardcodedConfig

  • KubeCtlProxyConfigLoader

  • KubeInClusterConfigLoader

masterFQDN

(optional, default to None) Address of the master the worker should connect to. Put the service master service name if you want to place a load-balancer between the workers and the masters. The default behaviour is to compute address IP of the master. This option works out-of-the box inside kubernetes but don’t leverage the load-balancing through service. You can pass any callable, such as KubeLatentWorker.get_fqdn that will set masterFQDN=socket.getfqdn().

For more customization, you can subclass KubeLatentWorker and override following methods. All those methods can optionally return a deferred. All those methods take props object which is a L{IProperties} allowing to get some parameters from the build properties

createEnvironment(self, props)

This method compute the environment from your properties. Don’t forget to first call super().createEnvironment(props) to get the base properties necessary to connect to the master.

getBuildContainerResources(self, props)

This method compute the pod resources part of the container spec (spec.containers[].resources. This is important to reserve some CPU and memory for your builds, and to trigger node auto-scaling if needed. You can also limit the CPU and memory for your container.

getServicesContainers(self, props)

This method compute a list of containers spec to put alongside the worker container. This is useful for starting services around your build pod, like a database container. All containers within the same pod share the same localhost interface, so you can access the other containers TCP ports very easily.

Kubernetes config loaders

Kubernetes provides many options to connect to a cluster. It is especially more complicated as some cloud providers use specific methods to connect to their managed kubernetes. Config loaders objects can be shared between LatentWorker.

There are three options you may use to connect to your clusters.

When running both the master and slaves run on the same Kubernetes cluster, you should use the KubeInClusterConfigLoader. If not, but having a configured kubectl tool available to the build master is an option for you, you should use KubeCtlProxyConfigLoader. If neither of these options is convenient, use KubeHardcodedConfig.

class buildbot.util.kubeclientservice.KubeCtlProxyConfigLoader
class buildbot.plugins.util.KubeCtlProxyConfigLoader
KubeCtlProxyConfigLoader

With KubeCtlProxyConfigLoader, buildbot will user kubectl proxy to get access to the cluster. This delegates the authentication to the kubectl golang binary, and thus avoid to implement a python version for every authentication scheme that kubernetes provides. kubectl must be available in the PATH, and configured to be able to start pods. While this method is very convenient and easy, it also opens an unauthenticated http access to your cluster via localhost. You must ensure that this is properly secured, and your buildbot master machine is not on a shared multi-user server.

proxy_port

(optional defaults to 8001) HTTP port to use.

namespace

(optional defaults to "default" default namespace to use if the latent worker do not provide one already.

class buildbot.util.kubeclientservice.KubeHardcodedConfig
class buildbot.plugins.util.KubeHardcodedConfig
KubeHardcodedConfig

With KubeHardcodedConfig, you just configure the necessary parameters to connect to the clusters.

master_url

(mandatory) The http url of you kubernetes master. Only http and https protocols are supported

headers

(optional) Additional headers to be passed to the HTTP request

basicAuth

(optional) Basic authorization info to connect to the cluster, as a {‘user’: ‘username’, ‘password’: ‘psw’ } dict.

Unlike the headers argument, this argument supports secret providers, e.g:

basicAuth={'user': 'username', 'password': Secret('k8spassword')}
bearerToken

(optional)

A bearer token to authenticate to the cluster, as a string. Unlike the headers argument, this argument supports secret providers, e.g:

bearerToken=Secret('k8s-token')

When using the Google Kubernetes Engine (GKE), a bearer token for the default service account can be had with:

gcloud container clusters get-credentials --region [YOURREGION] YOURCLUSTER
kubectl describe sa
kubectl describe secret [SECRET_ID]

Where SECRET_ID is displayed by the describe sa command line. The default service account does not have rights on the cluster (to create/delete pods), which is required by BuildBot’s integration. You may give it this right by making it a cluster admin with

kubectl create clusterrolebinding service-account-admin \
    --clusterrole=cluster-admin \
    --serviceaccount default:default
cert

(optional) Client certificate and key to use to authenticate. This only works if txrequests is installed:

cert=('/path/to/certificate.crt', '/path/to/certificate.key')
verify

(optional) Path to server certificate authenticate the server:

verify='/path/to/kube_server_certificate.crt'

When using the Google Kubernetes Engine (GKE), this certificate is available from the admin console, on the Cluster page. Verify that it is valid (i.e. no copy/paste errors) with openssl verify PATH_TO_PEM.

namespace

(optional defaults to "default" default namespace to use if the latent worker do not provide one already.

class buildbot.util.kubeclientservice.KubeInClusterConfigLoader
class buildbot.plugins.util.KubeInClusterConfigLoader
KubeInClusterConfigLoader

Use KubeInClusterConfigLoader, if your Buildbot master is itself located within the kubernetes cluster. In this case, you would associated a service account to the Buildbot master pod, and KubeInClusterConfigLoader will get the credentials from that.

This config loader takes no arguments.

UpCloud
class buildbot.worker.upcloud.UpcloudLatentWorker

UpCloud is a web service that allows you to start virtual machines in cloud. Please see their website for details, including costs.

This document will guide you through setup of a UpCloud latent worker:

Get an UpCloud Account

To start off, to use the UpCloud latent worker, you need to sign up on UpCloud.

  1. Go to https://www.upcloud.com/ and create an account.

  2. Once you are logged into your account, create a sub-account for buildbot to use. You need to tick the box enabling it for API usage. You should disable the box enabling web interface. You should not use your primary account for safety and security reasons.

Configure the Master with an UpcloudLatentWorker

Quick-start sample

from buildbot.plugins import worker
c['workers'].append(upcloud.UpcloudLatentWorker('upcloud-worker','pass',
    image='Debian GNU/Linux 9.3 (Stretch)',
    api_username="username",
    api_password="password",
    hostconfig = {
        "user_data":"""
/usr/bin/apt-get update
/usr/bin/apt-get install -y buildbot-slave
/usr/bin/buildslave create-slave --umask=022 /buildslave buildbot.example.com upcloud-01 slavepass
/usr/bin/buildslave start /buildslave
"""}))

Complete example with default values

from buildbot.plugins import worker
c['workers'].append(upcloud.UpcloudLatentWorker('upcloud-worker','pass',
    image='Debian GNU/Linux 9.3 (Stretch)',
    api_username="username",
    api_password="password",
    hostconfig = {
        "zone":"de-fra1",
        "plan":"1xCPU-1GB",
        "hostname":"hostname",
        "ssh_keys":["ssh-rsa ...."],
        "os_disk_size":10,
        "core_number":1,
        "memory_amount":512,
        "user_data":""
    }))

The image argument specifies the name of image in the image library. UUID is not currently supported.

The api_username and api_password are for the sub-account you created on UpCloud.

hostconfig can be used to set various aspects about the created host.
  • zone is a valid execution zone in UpCloud environment, check their API documentation <https://developers.upcloud.com/> for valid values.

  • plan is a valid pre-configured machine specification, or custom if you want to define your own. See their API documentation for valid values

  • user_data field is used to specify startup script to run on the host.

  • hostname specifies the hostname for the worker. Defaults to name of the worker.

  • ssh_keys specifies ssh key(s) to add for root account. Some images support only one SSH key. At the time of writing, only RSA keys are supported.

  • os_disk_size specifies size of the system disk.

  • core_number can be used to specify number of cores, when plan is custom.

  • memory_amount can be used to specify memory in megabytes, when plan is custom.

  • user_data can be used to specify either URL to script, or script to execute when machine is started.

Note that by default buildbot retains latent workers for 10 minutes, see build_wait_time on how to change this.

Dangers with Latent Workers

Any latent worker that interacts with a for-fee service, such as the EC2LatentWorker, brings significant risks. As already identified, the configuration will need access to account information that, if obtained by a criminal, can be used to charge services to your account. Also, bugs in the Buildbot software may lead to unnecessary charges. In particular, if the master neglects to shut down an instance for some reason, a virtual machine may be running unnecessarily, charging against your account. Manual and/or automatic (e.g. Nagios with a plugin using a library like boto) double-checking may be appropriate.

A comparatively trivial note is that currently if two instances try to attach to the same latent worker, it is likely that the system will become confused. This should not occur, unless, for instance, you configure a normal worker to connect with the authentication of a latent buildbot. If this situation does occurs, stop all attached instances and restart the master.

2.5.7. Builder Configuration

The builders configuration key is a list of objects holding the configuration of the Builders. For more information on the Builders’ function in Buildbot, see the Concepts chapter. The class definition for the builder configuration is in buildbot.config. However, there is a simpler way to use it and it looks like this:

from buildbot.plugins import util
c['builders'] = [
    util.BuilderConfig(name='quick', workernames=['bot1', 'bot2'], factory=f_quick),
    util.BuilderConfig(name='thorough', workername='bot1', factory=f_thorough),
]

BuilderConfig takes the following keyword arguments:

name

The name of the Builder, which is used in status reports.

workername workernames

These arguments specify the worker or workers that will be used by this Builder. All worker names must appear in the workers configuration parameter. Each worker can accommodate multiple builders. The workernames parameter can be a list of names, while workername can specify only one worker.

factory

This is a buildbot.process.factory.BuildFactory instance which controls how the build is performed by defining the steps in the build. Full details appear in their own section, Build Factories.

Other optional keys may be set on each BuilderConfig:

builddir

(string, optional).

Specifies the name of a subdirectory of the master’s basedir in which everything related to this builder will be stored. This holds build status information. If not set, this parameter defaults to the builder name, with some characters escaped. Each builder must have a unique build directory.

workerbuilddir

(string, optional).

Specifies the name of a subdirectory (under the worker’s configured base directory) in which everything related to this builder will be placed on the worker. This is where checkouts, compilations, and tests are run. If not set, defaults to builddir. If a worker is connected to multiple builders that share the same workerbuilddir, make sure the worker is set to run one build at a time or ensure this is fine to run multiple builds from the same directory simultaneously.

tags

(list of strings, optional).

Identifies tags for the builder. A common use for this is to add new builders to your setup (for a new module or a new worker) that do not work correctly yet and allow you to integrate them with the active builders. You can tag these new builders with a test tag, make your main status clients ignore them, and have only private status clients pick them up. As soon as they work, you can move them over to the active tag.

project

(string, optional).

If provided, the builder will be associated with the specific project.

nextWorker

(function, optional).

If provided, this is a function that controls which worker will be assigned future jobs. The function is passed three arguments, the Builder object which is assigning a new job, a list of WorkerForBuilder objects and the BuildRequest. The function should return one of the WorkerForBuilder objects, or None if none of the available workers should be used. As an example, for each worker in the list, worker.worker will be a Worker object, and worker.worker.workername is the worker’s name. The function can optionally return a Deferred, which should fire with the same results.

nextBuild

(function, optional).

If provided, this is a function that controls which build request will be handled next. The function is passed two arguments, the Builder object which is assigning a new job, and a list of BuildRequest objects of pending builds. The function should return one of the BuildRequest objects, or None if none of the pending builds should be started. This function can optionally return a Deferred which should fire with the same results.

canStartBuild

(boolean, optional).

If provided, this is a function that can veto whether a particular worker should be used for a given build request. The function is passed three arguments: the Builder, a Worker, and a BuildRequest. The function should return True if the combination is acceptable, or False otherwise. This function can optionally return a Deferred which should fire with the same results.

See canStartBuild Functions for a concrete example.

locks

(list of instances of buildbot.locks.WorkerLock or buildbot.locks.MasterLock, optional).

Specifies the locks that should be acquired before starting a Build from this Builder. Alternatively, this could be a renderable that returns this list depending on properties related to the build that is just about to be created. This lets you defer picking the locks to acquire until it is known which Worker a build would get assigned to. The properties available to the renderable include all properties that are set to the build before its first step excluding the properties that come from the build itself and the builddir property that comes from worker. The Locks will be released when the build is complete. Note that this is a list of actual Lock instances, not names. Also note that all Locks must have unique names. See Interlocks.

env

(dictionary of strings, optional).

A Builder may be given a dictionary of environment variables in this parameter. The variables are used in ShellCommand steps in builds created by this builder. The environment variables will override anything in the worker’s environment. Variables passed directly to a ShellCommand will override variables of the same name passed to the Builder.

For example, if you have a pool of identical workers it is often easier to manage variables like PATH from Buildbot rather than manually editing them in the workers’ environment.

f = factory.BuildFactory
f.addStep(ShellCommand(
              command=['bash', './configure']))
f.addStep(Compile())

c['builders'] = [
  BuilderConfig(name='test', factory=f,
        workernames=['worker1', 'worker2', 'worker3', 'worker4'],
        env={'PATH': '/opt/local/bin:/opt/app/bin:/usr/local/bin:/usr/bin'}),
]

Unlike most builder configuration arguments, this argument can contain renderables.

collapseRequests

(boolean, optional)

Specifies how build requests for this builder should be collapsed. See Collapsing Build Requests, below.

properties

(dictionary of strings, optional)

A builder may be given a dictionary of Build Properties specific for this builder in this parameter. Those values can be used later on like other properties. Interpolate.

defaultProperties

(dictionary of strings, optional)

Similar to the properties parameter. But defaultProperties will only be added to Build Properties if they are not already set by another source.

description

(string, optional).

A builder may be given an arbitrary description, which will show up in the web status on the builder’s page.

description_format

(string, optional)

The format of the description parameter. By default, it is None and corresponds to plain text format. Allowed values: None, markdown.

2.5.7.1. Collapsing Build Requests

When more than one build request is available for a builder, Buildbot can “collapse” the requests into a single build. This is desirable when build requests arrive more quickly than the available workers can satisfy them, but has the drawback that separate results for each build are not available.

Requests are only candidated for a merge if both requests have exactly the same codebases.

This behavior can be controlled globally, using the collapseRequests parameter, and on a per-Builder basis, using the collapseRequests argument to the Builder configuration. If collapseRequests is given, it completely overrides the global configuration.

Possible values for both collapseRequests configurations are:

True

Requests will be collapsed if their sourcestamp are compatible (see below for definition of compatible).

False

Requests will never be collapsed.

callable(builder, req1, req2)

Requests will be collapsed if the callable returns true. See Collapse Request Functions for detailed example.

Sourcestamps are compatible if all of the below conditions are met:

  • Their codebase, branch, project, and repository attributes match exactly

  • Neither source stamp has a patch (e.g., from a try scheduler)

  • Either both source stamps are associated with changes, or neither is associated with changes but they have matching revisions.

2.5.7.2. Prioritizing Builds

The BuilderConfig parameter nextBuild can be used to prioritize build requests within a builder. Note that this is orthogonal to Prioritizing Builders, which controls the order in which builders are called on to start their builds. The details of writing such a function are in Build Priority Functions.

Such a function can be provided to the BuilderConfig as follows:

def pickNextBuild(builder, requests):
    ...
c['builders'] = [
    BuilderConfig(name='test', factory=f,
        nextBuild=pickNextBuild,
        workernames=['worker1', 'worker2', 'worker3', 'worker4']),
]
2.5.7.3. Virtual Builders

Dynamic Trigger is a method which allows to trigger the same builder, with different parameters. This method is used by frameworks which store the build config along side the source code like Buildbot_travis. The drawback of this method is that it is difficult to extract statistics for similar builds. The standard dashboards are not working well due to the fact that all the builds are on the same builder.

In order to overcome these drawbacks, Buildbot has the concept of virtual builder. If a build has the property virtual_builder_name, it will automatically attach to that builder instead of the original builder. That created virtual builder is not attached to any master and is only used for better sorting in the UI and better statistics. The original builder and worker configuration is still used for all other build behaviors.

The virtual builder metadata is configured with the following properties:

  • virtual_builder_name: The name of the virtual builder.

  • virtual_builder_description: The description of the virtual builder.

  • virtual_builder_project: The project of the virtual builder.

  • virtual_builder_tags: The tags for the virtual builder.

You can also use virtual builders with SingleBranchScheduler. For example if you want to automatically build all branches in your project without having to manually create a new builder each time one is added:

c['schedulers'].append(schedulers.SingleBranchScheduler(
    name='myproject-epics',
    change_filter=util.ChangeFilter(branch_re='epics/.*'),
    builderNames=['myproject-epics'],
    properties={
        'virtual_builder_name': util.Interpolate("myproject-%(ss::branch)s")
    }
))

2.5.8. Projects

The projects configuration key is a list of objects holding the configuration of the Projects. For more information on the Project function in Buildbot, see the Concepts chapter.

Project takes the following keyword arguments:

name

The name of the Project. Builders are associated to the Project using this string as their project parameter.

The following arguments are optional:

slug

(string, optional) A short string that is used to refer to the project in the URLs of the Buildbot web UI.

description

(string, optional) A description of the project that appears in the Buildbot web UI.

description_format

(string, optional)

The format of the description parameter. By default, it is None and corresponds to plain text format. Allowed values: None, markdown.

2.5.8.1. Example

The following is a demonstration of defining several Projects in the Buildbot configuration

from buildbot.plugins import util
c['projects'] = [
    util.Project(name="example",
                 description="An application to build example widgets"),
    util.Project(name="example-utils",
                 description="Utilities for the example project"),
]

2.5.9. Build Factories

Each Builder is equipped with a build factory, which defines the steps used to perform a particular type of build. This factory is created in the configuration file, and attached to a Builder through the factory element of its dictionary.

The steps used by these builds are defined in the next section, Build Steps.

Note

Build factories are used with builders, and are not added directly to the buildmaster configuration dictionary.

2.5.9.1. Defining a Build Factory

A BuildFactory defines the steps that every build will follow. Think of it as a glorified script. For example, a build factory which consists of an SVN checkout followed by a make build would be configured as follows:

from buildbot.plugins import util, steps

f = util.BuildFactory()
f.addStep(steps.SVN(repourl="http://..", mode="incremental"))
f.addStep(steps.Compile(command=["make", "build"]))

This factory would then be attached to one builder (or several, if desired):

c['builders'].append(
    BuilderConfig(name='quick', workernames=['bot1', 'bot2'], factory=f))

It is also possible to pass a list of steps into the BuildFactory when it is created. Using addStep is usually simpler, but there are cases where it is more convenient to create the list of steps ahead of time, perhaps using some Python tricks to generate the steps.

from buildbot.plugins import steps, util

all_steps = [
    steps.CVS(cvsroot=CVSROOT, cvsmodule="project", mode="update"),
    steps.Compile(command=["make", "build"]),
]
f = util.BuildFactory(all_steps)

Finally, you can also add a sequence of steps all at once:

f.addSteps(all_steps)
Attributes

The following attributes can be set on a build factory after it is created, e.g.,

f = util.BuildFactory()
f.useProgress = False
useProgress

(defaults to True): if True, the buildmaster keeps track of how long each step takes, so it can provide estimates of how long future builds will take. If builds are not expected to take a consistent amount of time (such as incremental builds in which a random set of files are recompiled or tested each time), this should be set to False to inhibit progress-tracking.

workdir

(defaults to ‘build’): workdir given to every build step created by this factory as default. The workdir can be overridden in a build step definition.

If this attribute is set to a string, that string will be used for constructing the workdir (worker base + builder builddir + workdir). The attribute can also be a Python callable, for more complex cases, as described in Factory Workdir Functions.

2.5.9.2. Dynamic Build Factories

In some cases you may not know what commands to run until after you checkout the source tree. For those cases, you can dynamically add steps during a build from other steps.

The Build object provides 2 functions to do this:

addStepsAfterCurrentStep(self, step_factories)

This adds the steps after the step that is currently executing.

addStepsAfterLastStep(self, step_factories)

This adds the steps onto the end of the build.

Both functions only accept as an argument a list of steps to add to the build.

For example, let’s say you have a script checked in into your source tree called build.sh. When this script is called with the argument --list-stages it outputs a newline separated list of stage names. This can be used to generate at runtime a step for each stage in the build. Each stage is then run in this example using ./build.sh --run-stage <stage name>.

from buildbot.plugins import util, steps
from buildbot.process import buildstep, logobserver
from twisted.internet import defer

class GenerateStagesCommand(buildstep.ShellMixin, steps.BuildStep):

    def __init__(self, **kwargs):
        kwargs = self.setupShellMixin(kwargs)
        super().__init__(**kwargs)
        self.observer = logobserver.BufferLogObserver()
        self.addLogObserver('stdio', self.observer)

    def extract_stages(self, stdout):
        stages = []
        for line in stdout.split('\n'):
            stage = str(line.strip())
            if stage:
                stages.append(stage)
        return stages

    @defer.inlineCallbacks
    def run(self):
        # run './build.sh --list-stages' to generate the list of stages
        cmd = yield self.makeRemoteShellCommand()
        yield self.runCommand(cmd)

        # if the command passes extract the list of stages
        result = cmd.results()
        if result == util.SUCCESS:
            # create a ShellCommand for each stage and add them to the build
            self.build.addStepsAfterCurrentStep([
                steps.ShellCommand(name=stage, command=["./build.sh", "--run-stage", stage])
                for stage in self.extract_stages(self.observer.getStdout())
            ])

        return result

f = util.BuildFactory()
f.addStep(steps.Git(repourl=repourl))
f.addStep(GenerateStagesCommand(
    name="Generate build stages",
    command=["./build.sh", "--list-stages"],
    haltOnFailure=True))
2.5.9.3. Predefined Build Factories

Buildbot includes a few predefined build factories that perform common build sequences. In practice, these are rarely used, as every site has slightly different requirements, but the source for these factories may provide examples for implementation of those requirements.

GNUAutoconf
class buildbot.process.factory.GNUAutoconf

GNU Autoconf is a software portability tool, intended to make it possible to write programs in C (and other languages) which will run on a variety of UNIX-like systems. Most GNU software is built using autoconf. It is frequently used in combination with GNU automake. These tools both encourage a build process which usually looks like this:

% CONFIG_ENV=foo ./configure --with-flags
% make all
% make check
# make install

(except, of course, from Buildbot, which always skips the make install part).

The Buildbot’s buildbot.process.factory.GNUAutoconf factory is designed to build projects which use GNU autoconf and/or automake. The configuration environment variables, the configure flags, and command lines used for the compile and test are all configurable, in general the default values will be suitable.

Example:

f = util.GNUAutoconf(source=source.SVN(repourl=URL, mode="copy"),
                     flags=["--disable-nls"])

Required Arguments:

source

This argument must be a step specification tuple that provides a BuildStep to generate the source tree.

Optional Arguments:

configure

The command used to configure the tree. Defaults to ./configure. Accepts either a string or a list of shell argv elements.

configureEnv

The environment used for the initial configuration step. This accepts a dictionary which will be merged into the worker’s normal environment. This is commonly used to provide things like CFLAGS="-O2 -g" (to turn off debug symbols during the compile). Defaults to an empty dictionary.

configureFlags

A list of flags to be appended to the argument list of the configure command. This is commonly used to enable or disable specific features of the autoconf-controlled package, like ["--without-x"] to disable windowing support. Defaults to an empty list.

reconf

use autoreconf to generate the ./configure file, set to True to use a buildbot default autoreconf command, or define the command for the ShellCommand.

compile

this is a shell command or list of argv values which is used to actually compile the tree. It defaults to make all. If set to None, the compile step is skipped.

test

this is a shell command or list of argv values which is used to run the tree’s self-tests. It defaults to make check. If set to None, the test step is skipped.

distcheck

this is a shell command or list of argv values which is used to run the packaging test. It defaults to make distcheck. If set to None, the test step is skipped.

BasicBuildFactory
class buildbot.process.factory.BasicBuildFactory

This is a subclass of GNUAutoconf which assumes the source is in CVS, and uses mode='full' and method='clobber' to always build from a clean working copy.

QuickBuildFactory
class buildbot.process.factory.QuickBuildFactory

The QuickBuildFactory class is a subclass of GNUAutoconf which assumes the source is in CVS, and uses mode='incremental' to get incremental updates.

The difference between a full build and a quick build is that quick builds are generally done incrementally, starting with the tree where the previous build was performed. That simply means that the source-checkout step should be given a mode='incremental' flag, to do the source update in-place.

In addition to that, this class sets the useProgress flag to False. Incremental builds will (or at least the ought to) compile as few files as necessary, so they will take an unpredictable amount of time to run. Therefore it would be misleading to claim to predict how long the build will take.

This class is probably not of use to new projects.

BasicSVN
class buildbot.process.factory.BasicSVN

This class is similar to QuickBuildFactory, but uses SVN instead of CVS.

CPAN
class buildbot.process.factory.CPAN

Most Perl modules available from the CPAN archive use the MakeMaker module to provide configuration, build, and test services. The standard build routine for these modules looks like:

% perl Makefile.PL
% make
% make test
# make install

(except again Buildbot skips the install step)

Buildbot provides a CPAN factory to compile and test these projects.

Arguments:

source

(required): A step specification tuple, like that used by GNUAutoconf.

perl

A string which specifies the perl executable to use. Defaults to just perl.

Distutils
class buildbot.process.factory.Distutils

Most Python modules use the distutils package to provide configuration and build services. The standard build process looks like:

% python ./setup.py build
% python ./setup.py install

Unfortunately, although Python provides a standard unit-test framework named unittest, to the best of my knowledge, distutils does not provide a standardized target to run such unit tests. (Please let me know if I’m wrong, and I will update this factory.)

The Distutils factory provides support for running the build part of this process. It accepts the same source= parameter as the other build factories.

Arguments:

source

(required): A step specification tuple, like that used by GNUAutoconf.

python

A string which specifies the python executable to use. Defaults to just python.

test

Provides a shell command which runs unit tests. This accepts either a string or a list. The default value is None, which disables the test step (since there is no common default command to run unit tests in distutils modules).

Trial
class buildbot.process.factory.Trial

Twisted provides a unit test tool named trial which provides a few improvements over Python’s built-in unittest module. Many Python projects which use Twisted for their networking or application services also use trial for their unit tests. These modules are usually built and tested with something like the following:

% python ./setup.py build
% PYTHONPATH=build/lib.linux-i686-2.3 trial -v PROJECTNAME.test
% python ./setup.py install

Unfortunately, the build/lib directory into which the built/copied .py files are placed is actually architecture-dependent, and I do not yet know of a simple way to calculate its value. For many projects it is sufficient to import their libraries in place from the tree’s base directory (PYTHONPATH=.).

In addition, the PROJECTNAME value where the test files are located is project-dependent: it is usually just the project’s top-level library directory, as common practice suggests the unit test files are put in the test sub-module. This value cannot be guessed, the Trial class must be told where to find the test files.

The Trial class provides support for building and testing projects which use distutils and trial. If the test module name is specified, trial will be invoked. The library path used for testing can also be set.

One advantage of trial is that the Buildbot happens to know how to parse trial output, letting it identify which tests passed and which ones failed. The Buildbot can then provide fine-grained reports about how many tests have failed, when individual tests fail when they had been passing previously, etc.

Another feature of trial is that you can give it a series of source .py files, and it will search them for special test-case-name tags that indicate which test cases provide coverage for that file. Trial can then run just the appropriate tests. This is useful for quick builds, where you want to only run the test cases that cover the changed functionality.

Arguments:

testpath

Provides a directory to add to PYTHONPATH when running the unit tests, if tests are being run. Defaults to . to include the project files in-place. The generated build library is frequently architecture-dependent, but may simply be build/lib for pure-Python modules.

python

Which Python executable to use. This list will form the start of the argv array that will launch trial. If you use this, you should set trial to an explicit path (like /usr/bin/trial or ./bin/trial). The parameter defaults to None, which leaves it out entirely (running trial args instead of python ./bin/trial args). Likely values are ['python'], ['python2.2'], or ['python', '-Wall'].

trial

Provides the name of the trial command. It is occasionally useful to use an alternate executable, such as trial2.2 which might run the tests under an older version of Python. Defaults to trial.

trialMode

A list of arguments to pass to trial, specifically to set the reporting mode. This defaults to ['--reporter=bwverbose'], which only works for Twisted-2.1.0 and later.

trialArgs

A list of arguments to pass to trial, available to turn on any extra flags you like. Defaults to [].

tests

Provides a module name or names which contain the unit tests for this project. Accepts a string, typically PROJECTNAME.test, or a list of strings. Defaults to None, indicating that no tests should be run. You must either set this or testChanges.

testChanges

If True, ignore the tests parameter and instead ask the Build for all the files that make up the Changes going into this build. Pass these filenames to trial and ask it to look for test-case-name tags, running just the tests necessary to cover the changes.

recurse

If True, tells Trial (with the --recurse argument) to look in all subdirectories for additional test cases.

reactor

which reactor to use, like ‘gtk’ or ‘java’. If not provided, the Twisted’s usual platform-dependent default is used.

randomly

If True, tells Trial (with the --random=0 argument) to run the test cases in random order, which sometimes catches subtle inter-test dependency bugs. Defaults to False.

The step can also take any of the ShellCommand arguments, e.g., haltOnFailure.

Unless one of tests or testChanges are set, the step will generate an exception.

2.5.10. Build Sets

A BuildSet represents a set of Builds that all compile and/or test the same version of the source tree. Usually, these builds are created by multiple Builders and will thus execute different steps.

The BuildSet is tracked as a single unit, which fails if any of the component Builds have failed, and therefore can succeed only if all of the component Builds have succeeded. There are two kinds of status notification messages that can be emitted for a BuildSet: the firstFailure type (which fires as soon as we know the BuildSet will fail), and the Finished type (which fires once the BuildSet has completely finished, regardless of whether the overall set passed or failed).

A BuildSet is created with a set of one or more source stamp tuples of (branch, revision, changes, patch), some of which may be None, and a list of Builders on which it is to be run. They are then given to the BuildMaster, which is responsible for creating a separate BuildRequest for each Builder.

There are a couple of different likely values for the SourceStamp:

(revision=None, changes=CHANGES, patch=None)

This is a SourceStamp used when a series of Changes have triggered a build. The VC step will attempt to check out a tree that contains CHANGES (and any changes that occurred before CHANGES, but not any that occurred after them.)

(revision=None, changes=None, patch=None)

This builds the most recent code on the default branch. This is the sort of SourceStamp that would be used on a Build that was triggered by a user request, or a Periodic scheduler. It is also possible to configure the VC Source Step to always check out the latest sources rather than paying attention to the Changes in the SourceStamp, which will result in the same behavior as this.

(branch=BRANCH, revision=None, changes=None, patch=None)

This builds the most recent code on the given BRANCH. Again, this is generally triggered by a user request or a Periodic scheduler.

(revision=REV, changes=None, patch=(LEVEL, DIFF, SUBDIR_ROOT))

This checks out the tree at the given revision REV, then applies a patch (using patch -pLEVEL <DIFF) from inside the relative directory SUBDIR_ROOT. Item SUBDIR_ROOT is optional and defaults to the builder working directory. The try command creates this kind of SourceStamp. If patch is None, the patching step is bypassed.

The buildmaster is responsible for turning the BuildSet into a set of BuildRequest objects and queueing them on the appropriate Builders.

2.5.11. Properties

Build properties are a generalized way to provide configuration information to build steps; see Build Properties for the conceptual overview of properties.

Some build properties come from external sources and are set before the build begins; others are set during the build and are available for later steps. The sources for properties are:

global configuration

These properties apply to all builds.

schedulers

A scheduler can specify properties that become available to all builds it starts.

changes

A change can have properties attached to it, supplying extra information gathered by the change source. This is most commonly used with the sendchange command.

forced builds

The “Force Build” form allows users to specify properties

workers

A worker can pass properties on to the builds it performs.

builds

A build automatically sets a number of properties on itself.

builders

A builder can set properties on all the builds it runs.

steps

The steps of a build can set properties that are available to subsequent steps. In particular, source steps set the got_revision property.

If the same property is supplied in multiple places, the final appearance takes precedence. For example, a property set in a builder configuration will override the one supplied by the scheduler.

Properties are stored internally in JSON format, so they are limited to basic types of data: numbers, strings, lists, and dictionaries.

2.5.11.1. Common Build Properties

The following build properties are set when the build is started, and are available to all steps.

got_revision

This property is set when a Source step checks out the source tree, and provides the revision that was actually obtained from the VC system. In general this should be the same as revision, except for non-absolute sourcestamps, where got_revision indicates what revision was current when the checkout was performed. This can be used to rebuild the same source code later.

Note

For some VC systems (Darcs in particular), the revision is a large string containing newlines, and is not suitable for interpolation into a filename.

For multi-codebase builds (where codebase is not the default ‘’), this property is a dictionary, keyed by codebase.

buildername

This is a string that indicates which Builder the build was a part of. The combination of buildername and buildnumber uniquely identify a build.

buildnumber

Each build gets a number, scoped to the Builder (so the first build performed on any given Builder will have a build number of 0). This integer property contains the build’s number.

workername

This is a string which identifies which worker the build is running on.

scheduler

If the build was started from a scheduler, then this property will contain the name of that scheduler.

builddir

The absolute path of the base working directory on the worker of the current builder.

For single codebase builds, where the codebase is ‘’, the following Source Stamp Attributes are also available as properties: branch, revision, repository, and project .

2.5.11.2. Source Stamp Attributes

branch revision repository project codebase

For details of these attributes see Concepts.

changes

This attribute is a list of dictionaries representing the changes that make up this sourcestamp.

2.5.11.3. Using Properties in Steps

For the most part, properties are used to alter the behavior of build steps during a build. This is done by using renderables (objects implementing the IRenderable interface) as step parameters. When the step is started, each such object is rendered using the current values of the build properties, and the resultant rendering is substituted as the actual value of the step parameter.

Buildbot offers several renderable object types covering common cases. It’s also possible to create custom renderables.

Note

Properties are defined while a build is in progress; their values are not available when the configuration file is parsed. This can sometimes confuse newcomers to Buildbot! In particular, the following is a common error:

if Property('release_train') == 'alpha':
    f.addStep(...)

This does not work because the value of the property is not available when the if statement is executed. However, Python will not detect this as an error - you will just never see the step added to the factory.

You can use renderables in most step parameters. Please file bugs for any parameters which do not accept renderables.

Property

The simplest renderable is Property, which renders to the value of the property named by its argument:

from buildbot.plugins import steps, util

f.addStep(steps.ShellCommand(command=['echo', 'buildername:',
                             util.Property('buildername')]))

You can specify a default value by passing a default keyword argument:

f.addStep(steps.ShellCommand(command=['echo', 'warnings:',
                             util.Property('warnings', default='none')]))

The default value is used when the property doesn’t exist, or when the value is something Python regards as False. The defaultWhenFalse argument can be set to False to force Buildbot to use the default argument only if the parameter is not set:

f.addStep(steps.ShellCommand(command=['echo', 'warnings:',
                             util.Property('warnings', default='none',
                                           defaultWhenFalse=False)]))

The default value can be a renderable itself, e.g.,

command=util.Property('command', default=util.Property('default-command'))
Interpolate

Property can only be used to replace an entire argument: in the example above, it replaces an argument to echo. Often, properties need to be interpolated into strings, instead. The tool for that job is Interpolate.

The more common pattern is to use Python dictionary-style string interpolation by using the %(prop:<propname>)s syntax. In this form, the property name goes in the parentheses, as above. A common mistake is to omit the trailing “s”, leading to a rather obscure error from Python (“ValueError: unsupported format character”).

from buildbot.plugins import steps, util
f.addStep(steps.ShellCommand(
    command=['make',
            util.Interpolate('REVISION=%(prop:got_revision)s'),
            'dist']))

This example will result in a make command with an argument like REVISION=12098.

The syntax of dictionary-style interpolation is a selector, followed by a colon, followed by a selector specific key, optionally followed by a colon and a string indicating how to interpret the value produced by the key.

The following selectors are supported.

prop

The key is the name of a property.

src

The key is a codebase and source stamp attribute, separated by a colon. Note, the syntax is %(src:<codebase>:<ssattr>)s, which differs from other selectors.

kw

The key refers to a keyword argument passed to Interpolate. Those keyword arguments may be ordinary values or renderables.

secret

The key refers to a secret provided by a provider declared in secretsProviders .

worker

The key refers to an info item provided by workers.

The following ways of interpreting the value are available.

-replacement

If the key exists, substitute its value; otherwise, substitute replacement. replacement may be empty (default), %(prop:propname:-)s.

~replacement

Like -replacement, but only substitutes the value of the key if it is something Python regards as True. Python considers None, 0, empty lists, and the empty string to be false, so such values will be replaced by replacement.

+replacement

If the key exists, substitute replacement; otherwise, substitute an empty string.

?|sub_if_exists|sub_if_missing

#?|sub_if_true|sub_if_false

Ternary substitution, depending on either the key being present (with ?, similar to +) or being True (with #?, like ~). Notice that there is a pipe immediately following the question mark and between the two substitution alternatives. The character that follows the question mark is used as the delimiter between the two alternatives. In the above examples, it is a pipe, but any character other than ( can be used.

Note

Although these are similar to shell substitutions, no other substitutions are currently supported.

Example:

from buildbot.plugins import steps, util
f.addStep(steps.ShellCommand(
    command=[
        'save-build-artifacts-script.sh',
        util.Interpolate('-r %(prop:repository)s'),
        util.Interpolate('-b %(src::branch)s'),
        util.Interpolate('-d %(kw:data)s', data="some extra needed data")
    ]))

Note

We use %(src::branch)s in most examples, because codebase is empty by default.

Example:

from buildbot.plugins import steps, util
f.addStep(steps.ShellCommand(
    command=[
        'make',
        util.Interpolate('REVISION=%(prop:got_revision:-%(src::revision:-unknown)s)s'),
        'dist'
    ]))

In addition, Interpolate supports using positional string interpolation. Here, %s is used as a placeholder, and the substitutions (which may be renderables) are given as subsequent arguments:

f.addStep(steps.ShellCommand(
    command=[
        'echo',
        util.Interpolate('%d warnings and %d errors',
                         util.Property('warnings'),
                         util.Property('errors'))
    ]))

Note

Like Python, you can use either positional interpolation or dictionary-style interpolation, but not both. Thus you cannot use a string like Interpolate("foo-%(src::revision)s-%s", "branch").

Renderer

While Interpolate can handle many simple cases, and even some common conditionals, more complex cases are best handled with Python code. The renderer decorator creates a renderable object whose rendering is obtained by calling the decorated function when the step to which it’s passed begins. The function receives an IProperties object, which it can use to examine the values of any and all properties. For example:

from buildbot.plugins import steps, util

@util.renderer
def makeCommand(props):
    command = ['make']
    cpus = props.getProperty('CPUs')
    if cpus:
        command.extend(['-j', str(cpus+1)])
    else:
        command.extend(['-j', '2'])
    command.extend([util.Interpolate('%(prop:MAKETARGET)s')])
    return command

f.addStep(steps.ShellCommand(command=makeCommand))

You can think of renderer as saying “call this function when the step starts”.

Note

Since 0.9.3, renderer can itself return IRenderable objects or containers containing IRenderable.

Optionally, extra arguments may be passed to the rendered function at any time by calling withArgs on the renderable object. The withArgs method accepts *args and **kwargs arguments which are stored in a new renderable object which is returned. The original renderable object is not modified. Multiple withArgs calls may be chained. The passed *args and **kwargs parameters are rendered and the results are passed to the rendered function at the time it is itself rendered. For example:

from buildbot.plugins import steps, util

@util.renderer
def makeCommand(props, target):
    command = ['make']
    cpus = props.getProperty('CPUs')
    if cpus:
        command.extend(['-j', str(cpus+1)])
    else:
        command.extend(['-j', '2'])
    command.extend([target])
    return command

f.addStep(steps.ShellCommand(command=makeCommand.withArgs('mytarget')))

Note

The rendering of the renderable object may happen at unexpected times, so it is best to ensure that the passed extra arguments are not changed.

Note

Config errors with Renderables may not always be caught via checkconfig.

Transform

Transform is an alternative to renderer. While renderer is useful for creating new renderables, Transform is easier to use when you want to transform or combine the renderings of preexisting renderables.

Transform takes a function and any number of positional and keyword arguments. The function must either be a callable object or a renderable producing one. When rendered, a Transform first replaces all of its arguments that are renderables with their renderings, then calls the function, passing it the positional and keyword arguments, and returns the result as its own rendering.

For example, suppose my_path is a path on the worker, and you want to get it relative to the build directory. You can do it like this:

import os.path
from buildbot.plugins import util

my_path_rel = util.Transform(os.path.relpath, my_path, start=util.Property('builddir'))

This works whether my_path is an ordinary string or a renderable. my_path_rel will be a renderable in either case, however.

FlattenList

If a nested list should be flattened for some renderables, FlattenList can be used. For example:

from buildbot.plugins import steps, util
f.addStep(steps.ShellCommand(
    command=[ 'make' ],
    descriptionDone=util.FlattenList([ 'make ', [ 'done' ]])
))

descriptionDone will be set to [ 'make', 'done' ] when the ShellCommand executes. This is useful when a list-returning property is used in renderables.

Note

ShellCommand automatically flattens nested lists in its command argument, so there is no need to use FlattenList for it.

WithProperties

Warning

This class is deprecated. It is an older version of Interpolate. It exists for compatibility with older configs.

The simplest use of this class is with positional string interpolation. Here, %s is used as a placeholder, and property names are given as subsequent arguments:

from buildbot.plugins import steps, util
f.addStep(steps.ShellCommand(
    command=["tar", "czf",
            util.WithProperties("build-%s-%s.tar.gz", "branch", "revision"),
            "source"]))

If this BuildStep were used in a tree obtained from Git, it would create a tarball with a name like build-master-a7d3a333db708e786edb34b6af646edd8d4d3ad9.tar.gz.

The more common pattern is to use Python dictionary-style string interpolation by using the %(propname)s syntax. In this form, the property name goes in the parentheses, as above. A common mistake is to omit the trailing “s”, leading to a rather obscure error from Python (“ValueError: unsupported format character”).

from buildbot.plugins import steps, util
f.addStep(steps.ShellCommand(
    command=['make',
            util.WithProperties('REVISION=%(got_revision)s'),
            'dist']))

This example will result in a make command with an argument like REVISION=12098.

The dictionary-style interpolation supports a number of more advanced syntaxes in the parentheses.

propname:-replacement

If propname exists, substitute its value; otherwise, substitute replacement. replacement may be empty (%(propname:-)s)

propname:~replacement

Like propname:-replacement, but only substitutes the value of property propname if it is something Python regards as True. Python considers None, 0, empty lists, and the empty string to be false, so such values will be replaced by replacement.

propname:+replacement

If propname exists, substitute replacement; otherwise, substitute an empty string.

Although these are similar to shell substitutions, no other substitutions are currently supported, and replacement in the above cannot contain more substitutions.

Note: like Python, you can use either positional interpolation or dictionary-style interpolation, not both. Thus you cannot use a string like WithProperties("foo-%(revision)s-%s", "branch").

Custom Renderables

If the options described above are not sufficient, more complex substitutions can be achieved by writing custom renderables.

The IRenderable interface is simple - objects must provide a getRenderingFor method. The method should take one argument - an IProperties provider - and should return the rendered value or a deferred firing with one. You can pass instances of the class anywhere other renderables are accepted. For example:

import time
from buildbot.interfaces import IRenderable
from zope.interface import implementer

@implementer(IRenderable)
class DetermineFoo(object):
    def getRenderingFor(self, props):
        if props.hasProperty('bar'):
            return props['bar']
        elif props.hasProperty('baz'):
            return props['baz']
        return 'qux'
ShellCommand(command=['echo', DetermineFoo()])

or, more practically,

from buildbot.interfaces import IRenderable
from zope.interface import implementer
from buildbot.plugins import util

@implementer(IRenderable)
class Now(object):
    def getRenderingFor(self, props):
        return time.clock()
ShellCommand(command=['make', util.Interpolate('TIME=%(kw:now)s', now=Now())])

This is equivalent to:

from buildbot.plugins import util

@util.renderer
def now(props):
    return time.clock()
ShellCommand(command=['make', util.Interpolate('TIME=%(kw:now)s', now=now)])

Note that a custom renderable must be instantiated (and its constructor can take whatever arguments you like), whereas a function decorated with renderer can be used directly.

URL for build

Its common to need to use the URL for the build in a step. For this, you can use a special custom renderer as following:

from buildbot.plugins import *

ShellCommand(command=['make', util.Interpolate('BUILDURL=%(kw:url)s', url=util.URLForBuild)])
Renderable Comparison

Its common to need to make basic comparison or calculation with properties. The Property and Interpolate objects contain necessary operator overloads to make this possible.

from buildbot.plugins import *

ShellCommand(command=['make'], doStepIf=Interpolate("worker:os_id")  == 'ubuntu')

In previous code, the value of the comparison can only be computed at runtime, so the result of the comparison is actually a renderable which will be computed at the start of the step.

from buildbot.plugins import *

ShellCommand(command=['make'], doStepIf=Interpolate("worker:os_id").in_(['debian', 'ubuntu']))

‘in’ operator cannot be overloaded, so we add a simple in_ method to Property and Interpolate.

Currently supported operators are in_, ==, !=, <, <=, >, >=, +, -, *, /, //, %.

2.5.12. Build Steps

2.5.12.1. Parameters Common to all Steps

All BuildSteps accept some common parameters. Some of these control how their individual status affects the overall build. Others are used to specify which Locks (see Interlocks) should be acquired before allowing the step to run.

Arguments common to all BuildStep subclasses:

name

The name used to describe the step on the status display. Since 0.9.8, this argument might be renderable.

haltOnFailure

If True, a FAILURE of this build step will cause the build to halt immediately. Any steps with alwaysRun=True will still be run. Generally speaking, haltOnFailure implies flunkOnFailure (the default for most BuildSteps). In some cases, particularly with a series of tests, it makes sense to haltOnFailure if something fails early on but not flunkOnFailure. This can be achieved with haltOnFailure=True, flunkOnFailure=False.

flunkOnWarnings

When True, a WARNINGS or FAILURE of this build step will mark the overall build as FAILURE. The remaining steps will still be executed.

flunkOnFailure

When True, a FAILURE of this build step will mark the overall build as a FAILURE. The remaining steps will still be executed.

warnOnWarnings

When True, a WARNINGS or FAILURE of this build step will mark the overall build as having WARNINGS. The remaining steps will still be executed.

warnOnFailure

When True, a FAILURE of this build step will mark the overall build as having WARNINGS. The remaining steps will still be executed.

alwaysRun

If True, this build step will always be run, even if a previous buildstep with haltOnFailure=True has failed.

description

This will be used to describe the command (on the Waterfall display) while the command is still running. It should be a single imperfect-tense verb, like compiling or testing. The preferred form is a single, short string, but for historical reasons a list of strings is also acceptable.

descriptionDone

This will be used to describe the command once it has finished. A simple noun like compile or tests should be used. Like description, this may either be a string or a list of short strings.

If neither description nor descriptionDone are set, the actual command arguments will be used to construct the description. This may be a bit too wide to fit comfortably on the Waterfall display.

All subclasses of BuildStep will contain the description attributes. Consequently, you could add a ShellCommand step like so:

from buildbot.plugins import steps

f.addStep(steps.ShellCommand(command=["make", "test"],
                             description="testing",
                             descriptionDone="tests"))
descriptionSuffix

This is an optional suffix appended to the end of the description (ie, after description and descriptionDone). This can be used to distinguish between build steps that would display the same descriptions in the waterfall. This parameter may be a string, a list of short strings or None.

For example, a builder might use the Compile step to build two different codebases. The descriptionSuffix could be set to projectFoo and projectBar, respectively for each step, which will result in the full descriptions compiling projectFoo and compiling projectBar to be shown in the waterfall.

doStepIf

A step can be configured to only run under certain conditions. To do this, set the step’s doStepIf to a boolean value, or to a function that returns a boolean value or Deferred. If the value or function result is false, then the step will return SKIPPED without doing anything. Otherwise, the step will be executed normally. If you set doStepIf to a function, that function should accept one parameter, which will be the BuildStep object itself.

hideStepIf

A step can be optionally hidden from the waterfall and build details web pages. To do this, set the step’s hideStepIf to a boolean value, or a function that takes two parameters (the results and the BuildStep) and returns a boolean value. Steps are always shown while they execute; however, after the step has finished, this parameter is evaluated (if it’s a function), and if the value is true, the step is hidden. For example, in order to hide the step if the step has been skipped:

factory.addStep(Foo(..., hideStepIf=lambda results, s: results==SKIPPED))
locks

A list of Locks (instances of buildbot.locks.WorkerLock or buildbot.locks.MasterLock) that should be acquired before starting this BuildStep. Alternatively, this could be a renderable that returns this list during build execution. This lets you defer picking the locks to acquire until the build step is about to start running. The Locks will be released when the step is complete. Note that this is a list of actual Lock instances, not names. Also note that all Locks must have unique names. See Interlocks.

logEncoding

The character encoding to use to decode logs produced during the execution of this step. This overrides the default logEncoding; see Log Handling.

updateBuildSummaryPolicy

The policy to use to propagate the step summary to the build summary. If False, the build summary will never include the step summary. If True, the build summary will always include the step summary. If set to a list (e.g. [FAILURE, EXCEPTION]), the step summary will be propagated if the step results id is present in that list. If not set or None, the default is computed according to other BuildStep parameters using following algorithm:

self.updateBuildSummaryPolicy = [EXCEPTION, RETRY, CANCELLED]
if self.flunkOnFailure or self.haltOnFailure or self.warnOnFailure:
    self.updateBuildSummaryPolicy.append(FAILURE)
if self.warnOnWarnings or self.flunkOnWarnings:
    self.updateBuildSummaryPolicy.append(WARNINGS)

Note that in a custom step, if BuildStep.getResultSummary is overridden and sets the build summary, updateBuildSummaryPolicy is ignored and the build summary will be used regardless.

2.5.12.2. Common Parameters of source checkout operations

All source checkout steps accept some common parameters to control how they get the sources and where they should be placed. The remaining per-VC-system parameters are mostly to specify where exactly the sources are coming from.

mode method

These two parameters specify the means by which the source is checked out. mode specifies the type of checkout and method tells about the way to implement it.

from buildbot.plugins import steps

factory = BuildFactory()
factory.addStep(steps.Mercurial(repourl='path/to/repo', mode='full',
                                method='fresh'))

The mode parameter a string describing the kind of VC operation that is desired (defaults to incremental). The options are:

incremental

Update the source to the desired revision, but do not remove any other files generated by previous builds. This allows compilers to take advantage of object files from previous builds. This mode is exactly same as the old update mode.

full

Update the source, but delete remnants of previous builds. Build steps that follow will need to regenerate all object files.

Methods are specific to the VC system in question, as they may take advantage of special behaviors in that VC system that can make checkouts more efficient or reliable.

workdir

Like all Steps, this indicates the directory where the build will take place. Source Steps are special in that they perform some operations outside of the workdir (like creating the workdir itself).

alwaysUseLatest

If True, bypass the usual behavior of checking out the revision in the source stamp, and always update to the latest revision in the repository instead. If the specific VC system supports branches and a specific branch is specified in the step parameters via branch or defaultBranch, then the latest revision on that branch is checked out.

retry

If set, this specifies a tuple of (delay, repeats) which means that when a full VC checkout fails, it should be retried up to repeats times, waiting delay seconds between the attempts. If you don’t provide this, it defaults to None, which means VC operations should not be retried. This is provided to make life easier for workers which are stuck behind poor network connections.

repository

The name of this parameter might vary depending on the Source step you are running. The concept explained here is common to all steps and applies to repourl as well as for baseURL (when applicable).

A common idiom is to pass Property('repository', 'url://default/repo/path') as repository. This grabs the repository from the source stamp of the build. This can be a security issue, if you allow force builds from the web, or have the WebStatus change hooks enabled; as the worker will download code from an arbitrary repository.

codebase

This specifies which codebase the source step should use to select the right source stamp. The default codebase value is ''. The codebase must correspond to a codebase assigned by the codebaseGenerator. If there is no codebaseGenerator defined in the master, then codebase doesn’t need to be set; the default value will match all changes.

timeout

Specifies the timeout for worker-side operations, in seconds. If your repositories are particularly large, then you may need to increase this value from the default of 1200 (20 minutes).

logEnviron

If this option is true (the default), then the step’s logfile will describe the environment variables on the worker. In situations where the environment is not relevant and is long, it may be easier to set logEnviron=False.

env

A dictionary of environment strings which will be added to the child command’s environment. The usual property interpolations can be used in environment variable names and values - see Properties.

2.5.12.3. Bzr
class buildbot.steps.source.bzr.Bzr

bzr is a descendant of Arch/Baz, and is frequently referred to as simply Bazaar. The repository-vs-workspace model is similar to Darcs, but it uses a strictly linear sequence of revisions (one history per branch) like Arch. Branches are put in subdirectories. This makes it look very much like Mercurial.

from buildbot.plugins import steps

factory.addStep(steps.Bzr(mode='incremental',
                          repourl='lp:~knielsen/maria/tmp-buildbot-test'))

The step takes the following arguments:

repourl

(required unless baseURL is provided): the URL at which the Bzr source repository is available.

baseURL

(required unless repourl is provided): the base repository URL, to which a branch name will be appended. It should probably end in a slash.

defaultBranch

(allowed if and only if baseURL is provided): this specifies the name of the branch to use when a Build does not provide one of its own. This will be appended to baseURL to create the string that will be passed to the bzr checkout command. If alwaysUseLatest is True then the branch and revision information that comes with the Build is ignored and branch specified in this parameter is used.

mode method

No method is needed for incremental mode. For full mode, method can take the values shown below. If no value is given, it defaults to fresh.

clobber

This specifies to remove the workdir and make a full checkout.

fresh

This method first runs bzr clean-tree to remove all the unversioned files then update the repo. This remove all unversioned files including those in .bzrignore.

clean

This is same as fresh except that it doesn’t remove the files mentioned in .bzrginore i.e, by running bzr clean-tree --ignore.

copy

A local bzr repository is maintained and the repo is copied to build directory for each build. Before each build the local bzr repo is updated then copied to build for next steps.

2.5.12.4. CVS
class buildbot.steps.source.cvs.CVS

The CVS build step performs a CVS checkout or update.

from buildbot.plugins import steps

factory.addStep(steps.CVS(mode='incremental',
                cvsroot=':pserver:me@cvs.example.net:/cvsroot/myproj',
                cvsmodule='buildbot'))

This step takes the following arguments:

cvsroot

(required): specify the CVSROOT value, which points to a CVS repository, probably on a remote machine. For example, if Buildbot was hosted in CVS then the CVSROOT value you would use to get a copy of the Buildbot source code might be :pserver:anonymous@cvs.example.net:/cvsroot/buildbot.

cvsmodule

(required): specify the cvs module, which is generally a subdirectory of the CVSROOT. The cvsmodule for the Buildbot source code is buildbot.

branch

a string which will be used in a -r argument. This is most useful for specifying a branch to work on. Defaults to HEAD. If alwaysUseLatest is True then the branch and revision information that comes with the Build is ignored and branch specified in this parameter is used.

global_options

a list of flags to be put before the argument checkout in the CVS command.

extra_options

a list of flags to be put after the checkout in the CVS command.

mode method

No method is needed for incremental mode. For full mode, method can take the values shown below. If no value is given, it defaults to fresh.

clobber

This specifies to remove the workdir and make a full checkout.

fresh

This method first runs cvsdisard in the build directory, then updates it. This requires cvsdiscard which is a part of the cvsutil package.

clean

This method is the same as method='fresh', but it runs cvsdiscard --ignore instead of cvsdiscard.

copy

This maintains a source directory for source, which it updates copies to the build directory. This allows Buildbot to start with a fresh directory, without downloading the entire repository on every build.

login

Password to use while performing login to the remote CVS server. Default is None meaning that no login needs to be performed.

2.5.12.5. Darcs
class buildbot.steps.source.darcs.Darcs

The Darcs build step performs a Darcs checkout or update.

from buildbot.plugins import steps

factory.addStep(steps.Darcs(repourl='http://path/to/repo',
                            mode='full', method='clobber', retry=(10, 1)))

Darcs step takes the following arguments:

repourl

(required): The URL at which the Darcs source repository is available.

mode

(optional): defaults to 'incremental'. Specifies whether to clean the build tree or not.

incremental

The source is update, but any built files are left untouched.

full

The build tree is clean of any built files. The exact method for doing this is controlled by the method argument.

method

(optional): defaults to copy when mode is full. Darcs’ incremental mode does not require a method. The full mode has two methods defined:

clobber

It removes the working directory for each build then makes full checkout.

copy

This first checkout source into source directory then copy the source directory to build directory then performs the build operation in the copied directory. This way we make fresh builds with very less bandwidth to download source. The behavior of source checkout follows exactly same as incremental. It performs all the incremental checkout behavior in source directory.

2.5.12.6. Gerrit
class buildbot.steps.source.gerrit.Gerrit

Gerrit step is exactly like the Git step, except that it integrates with GerritChangeSource, and will automatically checkout the additional changes.

Gerrit integration can be also triggered using forced build with property named gerrit_change with values in format change_number/patchset_number. This property will be translated into a branch name. This feature allows integrators to build with several pending interdependent changes, which at the moment cannot be described properly in Gerrit, and can only be described by humans.

2.5.12.7. GitHub
class buildbot.steps.source.github.GitHub

GitHub step is exactly like the Git step, except that it will ignore the revision sent by the GitHub change hook, and rather take the branch if the branch ends with /merge.

This allows to test github pull requests merged directly into the mainline.

GitHub indeed provides refs/origin/pull/NNN/merge on top of refs/origin/pull/NNN/head which is a magic ref that always creates a merge commit to the latest version of the mainline (i.e., the target branch for the pull request).

The revision in the GitHub event points to /head, and it’s important for the GitHub reporter as this is the revision that will be tagged with a CI status when the build is finished.

If you want to use Trigger to create sub tests and want to have the GitHub reporter still update the original revision, make sure you set updateSourceStamp=False in the Trigger configuration.

2.5.12.8. GitLab
class buildbot.steps.source.gitlab.GitLab

GitLab step is exactly like the Git step, except that it uses the source repo and branch sent by the GitLab change hook when processing merge requests.

When configuring builders, you can use a ChangeFilter with category = "push" to select normal commits, and category = "merge_request" to select merge requests.

See master/docs/examples/gitlab.cfg in the Buildbot distribution for a tutorial example of integrating Buildbot with GitLab.

Note

Your build worker will need access to the source project of the changeset, or it won’t be able to check out the source. This means authenticating the build worker via ssh credentials in the usual way, then granting it access [via a GitLab deploy key or GitLab project membership](https://docs.gitlab.com/ee/ssh/). This needs to be done not only for the main git repo, but also for each fork that wants to be able to submit merge requests against the main repo.

2.5.12.9. Git
class buildbot.steps.source.git.Git

The Git build step clones or updates a Git repository and checks out the specified branch or revision.

Note

Buildbot supports Git version 1.2.0 or later.

from buildbot.plugins import steps

factory.addStep(steps.Git(repourl='git://path/to/repo', mode='full',
                          method='clobber', submodules=True))

The Git step takes the following arguments:

repourl (required)

The URL of the upstream Git repository.

branch (optional)

This specifies the name of the branch or the tag to use when a Build does not provide one of its own. If this parameter is not specified, and the Build does not provide a branch, the default branch of the remote repository will be used. If alwaysUseLatest is True then the branch and revision information that comes with the Build is ignored and the branch specified in this parameter is used.

submodules (optional, default: False)

When initializing/updating a Git repository, this tells Buildbot whether to handle Git submodules. If remoteSubmodules is True, then this tells Buildbot to use remote submodules: Git Remote Submodules

shallow (optional)

Instructs Git to attempt shallow clones (--depth 1). The depth defaults to 1 and can be changed by passing an integer instead of True. This option can be used only in incremental builds, or full builds with clobber method.

reference (optional)

Use the specified string as a path to a reference repository on the local machine. Git will try to grab objects from this path first instead of the main repository, if they exist.

origin (optional)

By default, any clone will use the name “origin” as the remote repository (eg, “origin/master”). This renderable option allows that to be configured to an alternate name.

filters (optional, type: list)

For each string in the passed in list, adds a --filter <filter> argument to git clone. This allows for adding filters like --filter "tree:0" to speed up the clone step. This requires git version 2.27 or higher.

progress (optional)

Passes the (--progress) flag to (git fetch). This solves issues of long fetches being killed due to lack of output, but requires Git 1.7.2 or later. Its value is True on Git 1.7.2 or later.

retryFetch (optional, default: False)

If true, if the git fetch fails, then Buildbot retries to fetch again instead of failing the entire source checkout.

clobberOnFailure (optional, default: False)

If a fetch or full clone fails, we can retry to checkout the source by removing everything and cloning the repository. If the retry fails, it fails the source checkout step.

mode (optional, default: 'incremental')

Specifies whether to clean the build tree or not.

incremental

The source is update, but any built files are left untouched.

full

The build tree is clean of any built files. The exact method for doing this is controlled by the method argument.

method (optional, default: fresh when mode is full)

Git’s incremental mode does not require a method. The full mode has four methods defined:

clobber

It removes the build directory entirely then makes full clone from repo. This can be slow as it need to clone whole repository. To make faster clones enable the shallow option. If the shallow option is enabled and the build request has unknown revision value, then this step fails.

fresh

This removes all other files except those tracked by Git. First it does git clean -d -f -f -x, then fetch/checkout to a specified revision (if any). This option is equal to update mode with ignore_ignores=True in old steps.

clean

All the files which are tracked by Git, as well as listed ignore files, are not deleted. All other remaining files will be deleted before the fetch/checkout. This is equivalent to git clean -d -f -f then fetch. This is equivalent to ignore_ignores=False in old steps.

copy

This first checks out source into source directory, then copies the source directory to build directory, and then performs the build operation in the copied directory. This way, we make fresh builds with very little bandwidth to download source. The behavior of source checkout follows exactly the same as incremental. It performs all the incremental checkout behavior in source directory.

getDescription (optional)

After checkout, invoke a git describe on the revision and save the result in a property; the property’s name is either commit-description or commit-description-foo, depending on whether the codebase argument was also provided. The argument should either be a bool or dict, and will change how git describe is called:

  • getDescription=False: disables this feature explicitly

  • getDescription=True or empty dict(): runs git describe with no args

  • getDescription={...}: a dict with keys named the same as the Git option. Each key’s value can be False or None to explicitly skip that argument.

    For the following keys, a value of True appends the same-named Git argument:

    • all : –all

    • always: –always

    • contains: –contains

    • debug: –debug

    • long: –long`

    • exact-match: –exact-match

    • tags: –tags

    • dirty: –dirty

    For the following keys, an integer or string value (depending on what Git expects) will set the argument’s parameter appropriately. Examples show the key-value pair:

    • match=foo: –match foo

    • abbrev=7: –abbrev=7

    • candidates=7: –candidates=7

    • dirty=foo: –dirty=foo

config (optional)

A dict of Git configuration settings to pass to the remote Git commands.

sshPrivateKey (optional)

The private key to use when running Git for fetch operations. The ssh utility must be in the system path in order to use this option. On Windows, only Git distribution that embeds MINGW has been tested (as of July 2017, the official distribution is MINGW-based). The worker must either have the host in the known hosts file or the host key must be specified via the sshHostKey option.

sshHostKey (optional)

Specifies public host key to match when authenticating with SSH public key authentication. This may be either a Secret or just a string. sshPrivateKey must be specified in order to use this option. The host key must be in the form of <key type> <base64-encoded string>, e.g. ssh-rsa AAAAB3N<…>FAaQ==.

sshKnownHosts (optional)

Specifies the contents of the SSH known_hosts file to match when authenticating with SSH public key authentication. This may be either a Secret or just a string. sshPrivateKey must be specified in order to use this option. sshHostKey must not be specified in order to use this option.

2.5.12.10. Mercurial
class buildbot.steps.source.mercurial.Mercurial

The Mercurial build step performs a Mercurial (aka hg) checkout or update.

Branches are available in two modes: dirname, where the name of the branch is a suffix of the name of the repository, or inrepo, which uses Hg’s named-branches support. Make sure this setting matches your changehook, if you have that installed.

from buildbot.plugins import steps

factory.addStep(steps.Mercurial(repourl='path/to/repo', mode='full',
                                method='fresh', branchType='inrepo'))

The Mercurial step takes the following arguments:

repourl

where the Mercurial source repository is available.

defaultBranch

this specifies the name of the branch to use when a Build does not provide one of its own. This will be appended to repourl to create the string that will be passed to the hg clone command. If alwaysUseLatest is True then the branch and revision information that comes with the Build is ignored and branch specified in this parameter is used.

branchType

either ‘dirname’ (default) or ‘inrepo’ depending on whether the branch name should be appended to the repourl or the branch is a Mercurial named branch and can be found within the repourl.

clobberOnBranchChange

boolean, defaults to True. If set and using inrepos branches, clobber the tree at each branch change. Otherwise, just update to the branch.

mode method

Mercurial’s incremental mode does not require a method. The full mode has three methods defined:

clobber

It removes the build directory entirely then makes full clone from repo. This can be slow as it need to clone whole repository

fresh

This remove all other files except those tracked by VCS. First it does hg purge --all then pull/update

clean

All the files which are tracked by Mercurial and listed ignore files are not deleted. Remaining all other files will be deleted before pull/update. This is equivalent to hg purge then pull/update.

2.5.12.11. Monotone
class buildbot.steps.source.mtn.Monotone

The Monotone build step performs a Monotone checkout or update.

from buildbot.plugins import steps

factory.addStep(steps.Monotone(repourl='http://path/to/repo',
                               mode='full', method='clobber',
                               branch='some.branch.name', retry=(10, 1)))

Monotone step takes the following arguments:

repourl

the URL at which the Monotone source repository is available.

branch

this specifies the name of the branch to use when a Build does not provide one of its own. If alwaysUseLatest is True then the branch and revision information that comes with the Build is ignored and branch specified in this parameter is used.

progress

this is a boolean that has a pull from the repository use --ticker=dot instead of the default --ticker=none.

mode

(optional): defaults to 'incremental'. Specifies whether to clean the build tree or not. In any case, the worker first pulls from the given remote repository to synchronize (or possibly initialize) its local database. The mode and method only affect how the build tree is checked-out or updated from the local database.

incremental

The source is update, but any built files are left untouched.

full

The build tree is clean of any built files. The exact method for doing this is controlled by the method argument. Even in this mode, the revisions already pulled remain in the database and a fresh pull is rarely needed.

method

(optional): defaults to copy when mode is full. Monotone’s incremental mode does not require a method. The full mode has four methods defined:

clobber

It removes the build directory entirely then makes fresh checkout from the database.

clean

This remove all other files except those tracked and ignored by Monotone. It will remove all the files that appear in mtn ls unknown. Then it will pull from remote and update the working directory.

fresh

This remove all other files except those tracked by Monotone. It will remove all the files that appear in mtn ls ignored and mtn ls unknows. Then pull and update similar to clean

copy

This first checkout source into source directory then copy the source directory to build directory then performs the build operation in the copied directory. This way we make fresh builds with very less bandwidth to download source. The behavior of source checkout follows exactly same as incremental. It performs all the incremental checkout behavior in source directory.

2.5.12.12. P4
class buildbot.steps.source.p4.P4

The P4 build step creates a Perforce client specification and performs an update.

from buildbot.plugins import steps, util

factory.addStep(steps.P4(
    p4port=p4port,
    p4client=util.WithProperties('%(P4USER)s-%(workername)s-%(buildername)s'),
    p4user=p4user,
    p4base='//depot',
    p4viewspec=p4viewspec,
    mode='incremental'))

You can specify the client spec in two different ways. You can use the p4base, p4branch, and (optionally) p4extra_views to build up the viewspec, or you can utilize the p4viewspec to specify the whole viewspec as a set of tuples.

Using p4viewspec will allow you to add lines such as:

//depot/branch/mybranch/...             //<p4client>/...
-//depot/branch/mybranch/notthisdir/... //<p4client>/notthisdir/...

If you specify p4viewspec and any of p4base, p4branch, and/or p4extra_views you will receive a configuration error exception.

p4base

A view into the Perforce depot without branch name or trailing /.... Typically //depot/proj.

p4branch

(optional): A single string, which is appended to the p4base as follows <p4base>/<p4branch>/... to form the first line in the viewspec

p4extra_views

(optional): a list of (depotpath, clientpath) tuples containing extra views to be mapped into the client specification. Both will have /... appended automatically. The client name and source directory will be prepended to the client path.

p4viewspec

This will override any p4branch, p4base, and/or p4extra_views specified. The viewspec will be an array of tuples as follows:

[('//depot/main/','')]

It yields a viewspec with just:

//depot/main/... //<p4client>/...
p4viewspec_suffix

(optional): The