.. _containersrun: Computational reproducibility with software containers ------------------------------------------------------ Just after submitting your midterm data analysis project, you get together with your friends. "I'm curious: So what kind of analyses did y'all carry out?" you ask. The variety of methods and datasets the others used is huge, and one analysis interests you in particular. Later that day, you decide to install this particular analysis dataset to learn more about the methods used in there. However, when you :dlcmd:`rerun` your friends analysis script, it throws an error. Hastily, you call her -- maybe she can quickly fix her script and resubmit the project with only minor delays. "I don't know what you mean", you hear in return. "On my machine, everything works fine!" On its own, DataLad datasets can contain almost anything that is relevant to ensure reproducibility: Data, code, human-readable analysis descriptions (e.g., ``README.md`` files), provenance on the origin of all files obtained from elsewhere, and machine-readable records that link generated outputs to the commands, scripts, and data they were created from. This however may not be sufficient to ensure that an analysis *reproduces* (i.e., produces the same or highly similar results), let alone *works* on a computer different than the one it was initially composed on. This is because the analysis does not only depend on data and code, but also the *software environment* that it is conducted in. A lack of information about the operating system of the computer, the precise versions of installed software, or their configurations may make it impossible to replicate your analysis on a different machine, or even on your own machine once a new software update is installed. Therefore, it is important to communicate all details about the computational environment for an analysis as thoroughly as possible. Luckily, DataLad provides an extension that can link computational environments to datasets, the `datalad containers `_ extension. This section will give a quick overview on what containers are and demonstrate how ``datalad-container`` helps to capture full provenance of an analysis by linking containers to datasets and analyses. .. importantnote:: Install the datalad-container extension This section uses the :term:`DataLad extension` ``datalad-container``. As other extensions, it is a stand-alone Python package, and can be installed using :term:`pip`: .. code-block:: bash $ pip install datalad-container As with DataLad and other Python packages, you might want to do the installation in a :term:`virtual environment`. .. index:: pair: recipe; software container concept pair: image; software container concept pair: container; software container concept Containers ^^^^^^^^^^ To put it simple, computational containers are cut-down virtual machines that allow you to package all software libraries and their dependencies (all in the precise version your analysis requires) into a bundle you can share with others. On your own and other's machines, the container constitutes a secluded software environment that - contains the exact software environment that you specified, ready to run analyses - does not effect any software outside of the container Unlike virtual machines, software containers do not run a full operating system on virtualized hardware. Instead, they use basic services of the host operating system (in a read-only fashion). This makes them lightweight and still portable. By sharing software environments with containers, others (and also yourself) have easy access to the correct software without the need to modify the software environment of the machine the container runs on. Thus, containers are ideal to encapsulate the software environment and share it together with the analysis code and data to ensure computational reproducibility of your analyses, or to create a suitable software environment on a computer that you do not have permissions to deploy software on. There are a number of different tools to create and use containers, with `Docker `_ being one of the most well-known of them. While being a powerful tool, it is only rarely used on high performance computing (HPC) infrastructure [#f2]_. An alternative is `Singularity `_. Both of these tools share core terminology: :term:`container recipe` A text file that lists all required components of the computational environment. It is made by a human user. :term:`container image` This is *built* from the recipe file. It is a static file system inside a file, populated with the software specified in the recipe, and some initial configuration. :term:`container` A running instance of an image that you can actually use for your computations. If you want to create and run your own software container, you start by writing a recipe file and build an image from it. Alternatively, you can can also *pull* an image built from a publicly shared recipe from the *Hub* of the tool you are using. hub A storage resource to share and consume images. Examples are :term:`Singularity-Hub`, :term:`Docker-Hub`, and `Amazon ECR `_ which hosts Docker images. Note that as of now, the ``datalad-container`` extension supports Singularity and Docker images. Singularity furthermore is compatible with Docker -- you can use Docker images as a basis for Singularity images, or run Docker images with Singularity (even without having Docker installed). See the :windows-wit:`on Docker ` for installation options. .. importantnote:: Additional requirement: Singularity To use Singularity containers you have to `install `_ the software singularity. .. index:: pair: installation; Docker pair: install Docker; on Windows .. find-out-more:: Docker installation Windows :name: ww-docker The software singularity is not available for Windows. Windows users therefore need to install :term:`Docker`. The currently recommended way to do so is by installing `Docker Desktop `_, and use its "WSL2" backend (a choice one can set during the installation). In the case of an "outdated WSL kernel version" issue, run ``wsl --update`` in a regular Windows Command Prompt (CMD). After the installation, run Docker Desktop, and wait several minutes for it to start the Docker engine in the background. To verify that everything works as it should, run ``docker ps`` in a Windows Command Prompt (CMD). If it reports an error that asks "Is the docker daemon running?" give it a few more minutes to let Docker Desktop start it. If it can't find the docker command, something went wrong during installation. .. index:: pair: containers-add; DataLad command pair: containers-run; DataLad command Using ``datalad containers`` ^^^^^^^^^^^^^^^^^^^^^^^^^^^^ One core feature of the ``datalad containers`` extension is that it registers computational containers with a dataset. This is done with the :dlcmd:`containers-add` command. Once a container is registered, arbitrary commands can be executed inside of it, i.e., in the precise software environment the container encapsulates. All it needs for this it to swap the :dlcmd:`run` command introduced in section :ref:`run` with the :dlcmd:`containers-run` command. Let's see this in action for the ``midterm_analysis`` dataset by rerunning the analysis you did for the midterm project within a Singularity container. We start by registering a container to the dataset. For this, we will pull an image from Singularity hub. This image was made for the handbook, and it contains the relevant Python setup for the analysis. Its recipe lives in the handbook's `resources repository `_. If you are curious how to create a Singularity image, the :find-out-more:`on this topic ` has some pointers: .. index:: pair: build container image; with Singularity .. windows-wit:: How to make a Singularity image :name: fom-container-creation Singularity containers are build from image files, often called "recipes", that hold a "definition" of the software container and its contents and components. The `singularity documentation `_ has its own tutorial on how to build such images from scratch. An alternative to writing the image file by hand is to use `Neurodocker `_. This command-line program can help you generate custom Singularity recipes (and also ``Dockerfiles``, from which Docker images are built). A wonderful tutorial on how to use Neurodocker is `this introduction `_ by Michael Notter. Once a recipe exists, the command .. code-block:: console $ sudo singularity build will build a container (called ````) from the recipe. Note that this command requires ``root`` privileges ("``sudo``"). You can build the container on any machine, though, not necessarily the one that is later supposed to actually run the analysis, e.g., your own laptop versus a compute cluster. .. index:: pair: add container image to dataset; with DataLad The :dlcmd:`containers-add` command takes an arbitrary name to give to the container, and a path or URL to a container image: .. runrecord:: _examples/DL-101-133-101 :language: console :workdir: dl-101/DataLad-101/midterm_project :cast: 10_yoda :notes: Computational reproducibility: add a software container $ # we are in the midterm_project subdataset $ datalad containers-add midterm-software --url shub://adswa/resources:2 .. index:: pair: hub; Docker .. find-out-more:: How do I add an image from Docker-Hub, Amazon ECR, or a local container? Should the image you want to use sit on Dockerhub, specify the ``--url`` option prefixed with ``docker://`` or ``dhub://`` instead of ``shub://``: .. code-block:: console $ datalad containers-add midterm-software --url docker://adswa/resources:2 If your image lives on Amazon ECR, use a ``dhub://`` prefix followed by the AWS ECR URL as in .. code-block:: console $ datalad containers-add --url dhub://12345678.dkr.ecr.us-west-2.amazonaws.com/maze-code/data-import:latest data-import If you want to add a container that exists locally, specify the path to it like this: .. code-block:: console $ datalad containers-add midterm-software --url path/to/container This command downloaded the container from Singularity Hub, added it to the ``midterm_project`` dataset, and recorded basic information on the container under its name "midterm-software" in the dataset's configuration at ``.datalad/config``. You can find out more about them in a dedicated :ref:`find-out-more on these additional configurations `. .. index:: pair: DataLad concept; container image registration .. find-out-more:: What changes in .datalad/config when one adds a container? :name: fom-containerconfig :float: .. include:: topic/container-imgcfg.rst Such configurations can, among other things, be important to ensure correct container invocation on specific systems or across systems. One example is *bind-mounting* directories into containers, i.e., making a specific directory and its contents available inside a container. Different containerization software (versions) or configurations of those determine *default bind-mounts* on a given system. Thus, depending on the system and the location of the dataset on this system, a shared dataset may be automatically bind-mounted or not. To ensure that the dataset is correctly bind-mounted on all systems, let's add a call-format specification with a bind-mount to the current working directory following the information in the :ref:`find-out-more on additional container configurations `. .. index:: single: configuration.item; datalad.containers..cmdexec .. runrecord:: _examples/DL-101-133-104 :language: console :workdir: dl-101/DataLad-101/midterm_project :cast: 10_yoda $ git config -f .datalad/config datalad.containers.midterm-software.cmdexec 'singularity exec -B {{pwd}} {img} {cmd}' $ datalad save -m "Modify the container call format to bind-mount the working directory" .. index:: pair: run command with provenance capture; with DataLad pair: run command; with DataLad containers-run Now that we have a complete computational environment linked to the ``midterm_project`` dataset, we can execute commands in this environment. Let us, for example, try to repeat the :dlcmd:`run` command from the section :ref:`yoda_project` as a :dlcmd:`containers-run` command. The previous ``run`` command looked like this: .. code-block:: console $ datalad run -m "analyze iris data with classification analysis" \ --input "input/iris.csv" \ --output "pairwise_relationships.png" \ --output "prediction_report.csv" \ "python3 code/script.py {inputs} {outputs}" How would it look like as a ``containers-run`` command? .. runrecord:: _examples/DL-101-133-105 :language: console :workdir: dl-101/DataLad-101/midterm_project :cast: 10_yoda :notes: The analysis can be rerun in a software container $ datalad containers-run -m "rerun analysis in container" \ --container-name midterm-software \ --input "input/iris.csv" \ --output "pairwise_relationships.png" \ --output "prediction_report.csv" \ "python3 code/script.py {inputs} {outputs}" Almost exactly like a :dlcmd:`run` command! The only additional parameter is ``container-name``. At this point, though, the ``--container-name`` flag is even *optional* because there is only a single container registered to the dataset. But if your dataset contains more than one container you will *need* to specify the name of the container you want to use in your command. The complete command's structure looks like this: .. code-block:: console $ datalad containers-run --name [-m ...] [--input ...] [--output ...] .. index:: pair: containers-remove; DataLad command pair: containers-list; DataLad command pair: list known containers; with DataLad .. find-out-more:: How can I list available containers or remove them? The command :dlcmd:`containers-list` will list all containers in the current dataset: .. runrecord:: _examples/DL-101-133-110 :language: console :workdir: dl-101/DataLad-101/midterm_project $ datalad containers-list The command :dlcmd:`containers-remove` will remove a container from the dataset, if there exists a container with name given to the command. Note that this will remove not only the image from the dataset, but also the configuration for it in ``.datalad/config``. Here is how the history entry looks like: .. runrecord:: _examples/DL-101-133-111 :language: console :workdir: dl-101/DataLad-101/midterm_project :cast: 10_yoda :notes: Here is how that looks like in the history: $ git log -p -n 1 If you would :dlcmd:`rerun` this commit, it would be re-executed in the software container registered to the dataset. If you would share the dataset with a friend and they would :dlcmd:`rerun` this commit, the image would first be obtained from its registered url, and thus your friend can obtain the correct execution environment automatically. Note that because this new :dlcmd:`containers-run` command modified the ``midterm_project`` subdirectory, we need to also save the most recent state of the subdataset to the superdataset ``DataLad-101``. .. runrecord:: _examples/DL-101-133-112 :language: console :workdir: dl-101/DataLad-101/midterm_project :cast: 10_yoda :notes: Save the change in the superdataset $ cd ../ $ datalad status .. runrecord:: _examples/DL-101-133-113 :language: console :workdir: dl-101/DataLad-101 :cast: 10_yoda :notes: Save the change in the superdataset $ datalad save -d . -m "add container and execute analysis within container" midterm_project Software containers, the ``datalad-container`` extension, and DataLad thus work well together to make your analysis completely reproducible -- by not only linking code, data, and outputs, but also the software environment of an analysis. And this does not only benefit your future self, but also whomever you share your dataset with, as the information about the container is shared together with the dataset. How cool is that? .. only:: adminmode Add a tag at the section end. .. runrecord:: _examples/DL-101-133-114 :language: console :workdir: dl-101/DataLad-101 $ git branch sct_computational_reproducibility .. rubric:: Footnotes .. [#f2] The main reason why Docker is not deployed on HPC systems is because it grants users "`superuser privileges `_". On multi-user systems such as HPC, users should not have those privileges, as it would enable them to tamper with other's or shared data and resources, posing a severe security threat.