# Laminar CI [Laminar](http://laminar.ohwg.net) is a lightweight and modular Continuous Integration service for Linux. It is self-hosted and developer-friendly, eschewing a configuration web UI in favor of simple version-controllable configuration files and scripts. Laminar encourages the use of existing GNU/Linux tools such as `bash` and `cron` instead of reinventing them. Although the status and progress front-end is very user-friendly, administering a Laminar instance requires writing shell scripts and manually editing configuration files. That being said, there is nothing esoteric here and the tutorial below should be straightforward for anyone with even very basic Linux server administration experience. ## Getting Started ### Building from source First install development packages for `capnproto (git)`, `rapidjson`, `websocketpp`, `sqlite` and `boost-filesystem` from your distribution's repository or other source. Then: ```bash git clone https://github.com/ohwgiles/laminar.git cd laminar cmake -DCMAKE_BUILD_TYPE=Release -DCMAKE_INSTALL_PREFIX=/ make -j4 sudo make install ``` `make install` includes a systemd unit file. If you intend to use it, consider creating a new user `laminar` or modifying the user specified in the unit file. ### Installation from binaries Alternatively to the source-based approach shown above, precompiled packages are supplied for x86_64 Debian Stable and CentOS 7. Under Debian: ```bash wget https://github.com/ohwgiles/laminar/releases/download/0.4/laminar-0.4-1-amd64.deb sudo dpkg -i laminar-0.4-1-amd64.deb ``` Under CentOS: ```bash wget https://github.com/ohwgiles/laminar/releases/download/0.4/laminar-0.4-1.x86_64.rpm sudo rpm -i laminar-0.4-1.x86_64.rpm ``` Both install packages will create a new `laminar` user and install (but not activate) a systemd service for launching the laminar daemon. ### Service Configuration Use `systemctl start laminar` to start the laminar system service and `systemctl enable laminar` to launch it automatically on system boot. After starting the service, an empty laminar dashboard should be available at http://localhost:8080 Laminar's configuration file may be found at `/etc/laminar.conf`. Laminar will start with reasonable defaults if no configuration can be found. #### Running on a different HTTP port or Unix socket Edit `/etc/laminar.conf` and change `LAMINAR_BIND_HTTP` to `IPADDR:PORT`, `unix:PATH/TO/SOCKET` or `unix-abstract:SOCKETNAME`. `IPADDR` may be `*` to bind on all interfaces. The default is `*:8080`. Do not attempt to run laminar on port 80. This requires running as `root`, and Laminar will not drop privileges when executing job scripts! For a more complete integrated solution (including SSL), simply run laminar as a reverse proxy behind a regular webserver. #### Running behind a reverse proxy Laminar relies on WebSockets to provide a responsive, auto-updating display without polling. This may require extra support from your frontend webserver. For nginx, see [NGINX Reverse Proxy](https://www.nginx.com/resources/admin-guide/reverse-proxy/) and [WebSocket proxying](http://nginx.org/en/docs/http/websocket.html). For Apache, see [Apache Reverse Proxy](https://httpd.apache.org/docs/2.4/howto/reverse_proxy.html) and [mod_proxy_wstunnel](https://httpd.apache.org/docs/2.4/mod/mod_proxy_wstunnel.html). #### Set the page title Change `LAMINAR_TITLE` in `/etc/laminar.conf` to your preferred page title. #### More configuration options See the [reference section](#reference) ## User Guide ### Terminology - *job*: a task, identified by a name, comprising of one or more executable scripts. - *run*: a numbered execution of a *job* Throughout this document, the fixed path `/var/lib/laminar` is used. This is simply a default value and can be changed by setting `LAMINAR_HOME` in `/etc/laminar.conf` as desired. ### Creating a job To create a job that downloads and compiles [GNU Hello](https://www.gnu.org/software/hello/), create the file `/var/lib/laminar/cfg/jobs/hello.run` with the following content: ```bash #!/bin/bash -ex wget ftp://ftp.gnu.org/gnu/hello/hello-2.10.tar.gz tar xzf hello-2.10.tar.gz cd hello-2.10 ./configure make ``` Laminar uses your script's exit code to determine whether to mark the run as successful or failed. If your script is written in bash, the [`-e` option](http://tldp.org/LDP/abs/html/options.html) is helpful for this. See also [Exit and Exit Status](http://tldp.org/LDP/abs/html/exit-status.html). Don't forget to mark the script executable: ```bash chmod +x /var/lib/laminar/cfg/hello.run ``` ### Triggering a run To trigger a run of the `hello` job, execute ```bash laminarc trigger hello ``` This causes the `/var/lib/laminar/cfg/hello.run` script to be executed, with a working directory of `/var/lib/laminar/run/hello/1` The result and log output should be visible in the Web UI at http://localhost:8080/jobs/hello/1 #### Triggering a job at a certain time This is what `cron` is for. To trigger a build of `hello` every day at 0300, add ``` 0 3 * * * LAMINAR_REASON="Nightly build" laminarc trigger hello ``` to `laminar`'s crontab. For more information about `cron`, see `man crontab`. `LAMINAR_REASON` is an optional human-readable string that will be displayed in the web UI as the cause of the build. #### Triggering on a git commit This is what [git hooks](https://git-scm.com/book/gr/v2/Customizing-Git-Git-Hooks) are for. To create a hook that triggers the `example-build` job when a push is made to the `example` repository, create the file `hooks/post-receive` in the `example.git` bare repository. ```bash #!/bin/bash LAMINAR_REASON="Push to git repository" laminarc trigger example-build ``` What if your git server is not the same machine as the laminar instance? #### Triggering on a remote laminar instance `laminarc` and `laminard` communicate by default over an [abstract unix socket](http://man7.org/linux/man-pages/man7/unix.7.html). This means that any user **on the same machine** can send commands to the laminar service. On a trusted network, you might want `laminard` to listen for commands on a TCP port instead. To achieve this, in `/etc/laminar.conf`, set ``` LAMINAR_BIND_RPC=*:9997 ``` or any interface/port combination you like. This option uses the same syntax as `LAMINAR_BIND_HTTP`. Then, point `laminarc` to the new location using an environment variable: ```bash LAMINAR_HOST=192.168.1.1:9997 laminarc trigger example ``` ##### Access control If you need more flexibility, consider running the communication channel as a regular unix socket and applying user and group permissions to the file. To achieve this, set ``` LAMINAR_BIND_RPC=unix:/var/run/laminar.sock ``` or similar path in `/etc/laminar.conf`. This can be securely and flexibly combined with remote triggering using `ssh`. There is no need to allow the client full shell access to the server machine, the ssh server can restrict certain users to certain commands (in this case `laminarc`). See [the authorized_keys section of the sshd man page](https://man.openbsd.org/sshd#AUTHORIZED_KEYS_FILE_FORMAT) for further information. ### Job chains A typical pipeline may involve several steps, such as build, test and deploy. Depending on the project, these may be broken up into seperate laminar jobs for maximal flexibility. The preferred way to accomplish this in Laminar is to use the same method as [regular run triggering](#triggering-a-run), that is, calling `laminarc` directly in your `example.run` scripts. In addition to `laminarc trigger`, `laminar start` triggers a job run, but waits for its completion and returns a non-zero exit code if the run failed. Furthermore, both `trigger` and `start` will accept multiple jobs in a single invocation: ```bash #!/bin/bash -xe # simultaneously starts example-test-qemu and example-test-target # and returns a non-zero error code if either of them fail laminarc start example-test-qemu example-test-target ``` An advantage to using this `laminarc` approach from bash or other scripting language is that it enables highly dynamic pipelines, since you can execute commands like ```bash if [ ... ]; then laminarc start example-downstream-special else laminarc start example-downstream-regular fi laminarc start example-test-$TARGET_PLATFORM ``` `laminarc` reads the `$JOB` and `$RUN` variables set by `laminard` and passes them as part of the trigger/start request so the dependency chain can always be traced back. ### Parameterized runs Any argument passed to `laminarc` of the form `var=value` will be exposed as an environment variable in the corresponding build scripts. For example: ```bash laminarc trigger example foo=bar ``` In `/var/lib/laminar/cfg/jobs/example.run`: ```bash #!/bin/bash if [ "$foo" == "bar" ]; then ... else ... fi ``` ### Pre-build actions If the script `/var/lib/laminar/cfg/jobs/example.before` exists, it will be executed as part of the `example` job, before the primary `/var/lib/laminar/cfg/jobs/example.run` script. See also [script execution order](#script-execution-order) #### Passing variables between run scripts Any script can set environment variables that will stay exposed for subsequent scripts of the same run using `laminarc set`. In `example.before`: ```bash #!/bin/bash laminarc set foo=bar ``` Then in `example.run` ```bash #!/bin/bash echo $foo # prints "bar" ``` This works because laminarc reads `$JOB` and `$NUM` and passes them to the laminar daemon as part of the `set` request. (It is thus possible to set environment variables on other jobs by overriding these variables, but this is not very useful). ### Post-build actions Analagously to [Pre-build actions](#pre-build-actions), if the script `example.after` exists, it will be executed after the primary `example.run` script. The `$RESULT` environment variable will contain the run result. See also [Environment variables](#environment-variables). #### Archiving artefacts Laminar's default behaviour is to remove the run directory `/var/lib/laminar/run/JOB/RUN` after its completion. This prevents the typical CI disk usage explosion and encourages the user to judiciously select artefacts for archive. Laminar provides an archive directory `/var/lib/laminar/archive/JOB/RUN` and exposes its path in `$ARCHIVE`. `example-build.after` might look like this: ```bash #!/bin/bash -xe cp example.out $ARCHIVE/ ``` This folder structure has been chosen to make it easy for system administrators to host the archive on a separate partition or network drive. #### Conditionally trigger a downstream job Often, you may wish to only trigger the `example-test` job if the `example-build` job completed successfully. `example-build.after` might look like this: ```bash #!/bin/bash -xe if [ "$RESULT" == "success" ]; then laminarc trigger example-test fi ``` #### Accessing artifacts from an upstream build Rather than implementing a separate mechanism for this, the path of the upstream's archive should be passed to the downstream run as a parameter. See [Parameterized runs](#parameterized-runs). #### Email and IM Notifications As well as per-job `.after` scripts, a common use case is to send a notification for every job completion. If the global `after` script at `/var/lib/laminar/cfg/after` exists, it will be executed after every job. One way to use this might be: ```bash #!/bin/bash -xe if [ "$RESULT" != "$LAST_RESULT" ]; then sendmail -t < MyProject.tar.gz # Archive the artifact (consider moving this to the .after script) mv MyProject.tar.gz $ARCHIVE/ ``` For a project with a large git history, it can be more efficient to store the sources in the workspace: ```bash #!/bin/bash -ex cd $WORKSPACE/myproject git pull cd - cmake $WORKSPACE/myproject make -j4 ``` **CAUTION**: By default, laminar permits multiple simultaneous runs of the same job. If a job can **modify** the workspace, this might result in inconsistent builds when the job has multiple simultaneous runs. This is unlikely to be an issue for nightly builds, but for SCM-triggered builds it will be. To solve this, use [nodes](#nodes-and-tags) to restrict simultaneous execution of jobs, or [locks](#locks) to temporarily take exclusive control of a resource. Laminar will automatically create the workspace for a job if it doesn't exist when a job is executed. In this case, the `/var/lib/laminar/cfg/jobs/JOBNAME.init` will be executed if it exists. This is an excellent place to prepare the workspace to a state where subsequent builds can rely on its content. ### Nodes and Tags In Laminar, a *node* is an abstract concept allowing more fine-grained control over job execution scheduling. Each node can be defined to support an integer number of *executors*, which defines how many runs can be executed simultaneously. A typical example would be to allow only a few concurrent CPU-intensive jobs (such as compilation), while simultaneously allowing many more less-intensive jobs (such as monitoring or remote jobs). To create a node named `build` with 3 executors, create the file `/var/lib/laminar/cfg/nodes/build.conf` with the following content: ``` EXECUTORS=3 ``` To associate jobs with nodes, laminar uses *tags*. Tags may be applied to nodes and jobs. If a node has tags, only jobs with a matching tag will be executed on it. If a node has no tags, it will accept any job. To tag a node, add them to `/var/lib/laminar/cfg/nodes/NODENAME.conf`: ``` EXECUTORS=3 TAGS=tag1,tag2 ``` To add a tag to a job, add the following to `/var/lib/laminar/cfg/jobs/JOBNAME.conf`: ``` TAGS=tag2 ``` If Laminar cannot find any node configuration, it will assume a single node with 6 executors and no tags. #### Grouping jobs with tags Tags are also used to group jobs in the web UI. Each tag will presented as a tab in the "Jobs" page. #### Node scripts If `/var/lib/laminar/cfg/nodes/NODENAME.before` exists, it will be executed before the run script of a job scheduled to that node. Similarly, if `/var/lib/laminar/cfg/nodes/NODENAME.after` exists, it will be executed after the run script of a job scheduled to that node. #### Node environment If `/var/lib/laminar/cfg/nodes/NODENAME.env` exists and can be parsed as a list of `KEY=VALUE` pairs, these variables will be exposed as part of the run's environment. ### Remote jobs Laminar provides no specific support, `bash`, `ssh` and possibly NFS are all you need. For example, consider two identical target devices on which test jobs can be run in parallel. You might create a [node](#nodes-and-tags) for each, `/var/lib/laminar/cfg/nodes/target{1,2}.conf` with a common tag: ``` EXECUTORS=1 TAGS=remote-target ``` In each node's `.env` file, set the individual device's IP address: ``` TARGET_IP=192.168.0.123 ``` And tag the job accordingly in `/var/lib/laminar/cfg/jobs/myproject-test.conf`: ``` TAGS=remote-target ``` This means the job script `/var/lib/laminar/cfg/jobs/myproject-test.run` can be generic: ```bash #!/bin/bash -e ssh root@$TARGET_IP /bin/bash -xe <<"EOF" uname -a ... EOF scp root@$TARGET_IP:result.xml "$ARCHIVE/" ``` Don't forget to add the `laminar` user's public ssh key to the remote's `authorized_keys`. ### Docker container jobs Laminar provides no specific support, but just like [remote jobs](#remote-jobs) these are easily implementable in plain bash: ```bash #!/bin/bash docker run --rm -ti -v $PWD:/root ubuntu /bin/bash -xe <