Marsha
is a video management & playback service. It is intended to be operated independently: it's like having your very own YouTube for education.
Marsha also supports hosting documents and distribute them on all your courses.
Instructors & organizations can use Marsha to upload and manage their videos (and associated files, such as subtitles or transcripts) or documents directly from a course as they are creating it.
Once the course is published, learners simply see a video player or documents in the course.
This seamless integration works with any LMS (Open edX
, Moodle
, ...) thanks to the LTI standard for interoperability.
Here is what Marsha
offers out of the box:
Video:
- automatic transcoding of videos to all suitable formats from a single video file uploaded by the instructor;
- adaptive-bitrate streaming playback (both HLS and DASH);
- accessibility through the player itself and support for subtitles, closed captions and transcripts;
Document:
- upload any type of documents;
- prevent disk storage quota by using AWS S3;
Moreover, Marsha provides:
- access control to resources through LTI authentication;
- easy deployment & management of environments through
Terraform
;
Marsha
is made up of 3 building blocks: a container-native Django
backend, an AWS
transcoding and file storage environment, and a React
frontend application.
The Django
backend is tasked with serving the LTI pages that are integrated into the LMS. It also manages all the objects with their relationships, user accounts and all authentication concerns. It exposes a JSON API to communicate with the part of the infrastructure that operates on AWS lambdas
and the React
frontend.
It is defined using a docker-compose file for development, and can be deployed on any container environment (such as Kubernetes
) for production.
Source files (video, documents, subtitles,...) are directly uploaded to an S3
bucket by instructors. Depending the uploaded resource a lambda will be triggered to do different jobs:
- Launch
MediaConvert
to generate all necessary video files (various formats and fragments & manifests for adaptive-bitrate streaming) into a destinationS3
bucket. Those files are then served through theCloudFront
CDN. - Convert any kind of subtitles (also captions and transcripts) in WebVTT format and encode them properly.
- Resize thumbnails in many formats.
- Copy documents from a source to a destination
S3
Bucket accessible through theCloudFront
CDN.
Lambdas are used to manage and monitor the process and report back to the Django
backend.
This storage & transcoding environment requires AWS
as it heavily relies on AWS MediaConvert
to do the heavy lifting when it comes to transcoding. All the services it relies on are configured through Terraform
and can be deployed effortlessly through a make
command.
Please note that the only objects we handle in AWS
are the actual video, documents or subtitles files, from the upload to the distribution through transcoding and storage. It is not required to deploy any database or application backend to AWS
or send any user's personal information there.
The React
frontend is responsible for the interfaces with which users interact in the LTI Iframes. It gets an authenticated token with permissions
from the view and interacts with the Django
backend to manage objects and directly with AWS s3
to upload files.
It also powers the same resource view when loaded by a learner to display a video player (thanks to videojs) or a document reader.
To have the best possible user experience for instructors, we need to be able to change the size of the <iframe>
depending on its contents. This can be done through the iframe-resizer library.
iframe-resizer
requires to run some JS inside the <iframe>
(which we include with our React
frontend bundle) and some JS inside the host page. It then communicates through message-passing to adjust the size of the <iframe>
.
This means that to have the best interfaces for instructors, you need to include the host-side iframe-resizer
JS in your LMS pages. For Open edX, this is already done in our custom LTI consumer Xblock.
If you cannot or do not want to include this host-side JS, you can still run Marsha
. It will work exactly the same for learners (provided you adjust the size of the LTI <iframe>
for video), and instructors will only have to scroll inside the <iframe>
on some occasions.
Make sure you have a recent version of Docker and Docker Compose installed on your laptop:
$ docker -v
Docker version 19.03.6, build 369ce74a3c
$ docker-compose --version
docker-compose version 1.24.1, build 4667896b
sudo
but this can be avoided by assigning your user to the docker
group.
All tasks related to this environment are run from the ./src/aws
directory. We use Terraform
to keep this infrastructure configuration as code and easily manage several independent deployments of the whole AWS
infrastructure.
Note for Mac users: Marsha's AWS development setup uses
getopt
. The version that comes with macOS is not suitable for our use case. You need to install the GNU version and add it to your path so it is used by default.
brew install gnu-getopt
echo 'export PATH="/usr/local/opt/gnu-getopt/bin:$PATH"' >> ~/.zshrc
There are 2 Terraform projects in Marsha with two different purposes:
./src/aws/shared_resources
: this project manages resources common to all marsha environments on the same AWS account. These resources must not live in different workspaces so you must work in thedefault
workspace. To ease the use of this project, a dedicated script is available in./src/aws/bin/shared-resources
which uses and configures theTerraform
docker image. You have to run a Terraform command as if you were using the terraform cli. (eg:./bin/shared-resources plan
will execute Terraform's "plan" command)../src/aws
: this is the main project we use, most of the infrastructure is managed here (in all*.tf
files). This project must useTerraform
workspaces and we highly recommand you to not use the default one. With multiple workspaces, you can manage multiple environments for your Marsha instance with a single AWS account. To ease the use of this project, a dedicated script is available in./src/aws/bin/terraform
which uses and configures theTerraform
docker image. You have to run a Terraform command as if you were using the terraform cli. (eg:./bin/terraform plan
will execute Terraform's "plan" command).
Terraform manages a state of your infrastructure. By default this state is stored locally on your machine but it is highly recommanded to use a remote backend.
You will find all you need to configure a remote backend in the Terraform documentation: https://www.terraform.io/docs/configuration/blocks/backends/index.html
β You must configure your state management before running any of the commands hereafter. The first init
will initiate your state and after that you will have to deal with state migration if you want to modify it. You can create a file src/aws/state.tf
and src/aws/shared-resources/state.tf
to configure a backend, there is an example in each project (state.tf.dist
file).
π§ Before you go further, you need to create ./src/aws/env.d/development
and replace the relevant values with your own. You can take a look at the environment documentation for more details on this topic. You should use this command to create the file from the existing model:
$ cp ./src/aws/env.d/development.dist ./src/aws/env.d/development
Initialize your Terraform
config:
$ cd src/aws
$ make init
The make init
command will also create an ECR repository. Before going further you have to build and publish the lambda docker image. Unfortunately AWS doesn't allow to use a public image, so you have to host this one on a private ECR instance. Copy the output of the init
command, you will use them in the next step.
For this step, we cooked a script to help you build, tag and deploy images. All the scripts are run from the marsha root directory.
π§ Before you go further, you need to create ./env.d/lambda
and replace the relevant values with your own. The ECR
url is available in the shared_resources
terraform output you copied earlier. You should use this command to create the file from the existing model:
$ cp ./env.d/lambda.dist ./env.d/lambda
You have to successively run these commands :
Build the image:
$ ./bin/lambda build
Tag the image:
$ ./bin/lambda tag
And then publish it:
$ ./bin/lambda publish
Terraform is split in two parts. The main one, directly in src/aws
can work on multiple Terraform
workspaces. You will use this feature if you want separate environments (development, staging, preprod and production). We also need some resources available across all workspaces. For this we have an other terraform in src/aws/shared_resources
.
To apply all plans at once run this command in the src/aws
directory.
$ make apply-all
Everything should be set up! You can check on your AWS
management console.
You may have noticed that the AWS
development environment requires a URL where the Django
backend is running. You can easily get a URL that points to your locally running Django
app using a tool such as ngrok
.
All tasks related to the Django
backend are run from the project root (where this README.md
is located).
The easiest way to start working on the project is to use our Makefile
:
$ make bootstrap
This command builds the app
container, installs back-end dependencies and performs database migrations. It's a good idea to use this command each time you are pulling code from the project repository to avoid dependency-related or migration-related issues.
π§ Before you go further, you should take a look at the newly created ./env.d/development
file and replace the relevant values with your own. You can take a look at the environment documentation for more details on this topic.
Now that your Docker
services are ready to be used, start the application by running:
$ make run
You should be able to view the development view at localhost:8060/development/.
All tasks related to the React
frontend are run from the ./src/frontend
directory.
We use yarn
for all those tasks. Make sure you have a recent version installed:
$ yarn --version
1.13.0
If you need to install yarn
, please take a look at the official documentation.
Install all the dependencies:
$ yarn install
Run the build and copy the iframe-resizer
host-side JS into your local Django
assets:
$ yarn build-lti
$ yarn copy-iframe-resizer
Run the build for libraries and start the standalone frontend:
$ yarn build-tests
$ yarn start-site
Now the standalone frontend is available at localhost:3000.
The front application is tested using jest. Every js module has its corresponding spec file containing related tests:
βββ VideoPlayer
βΒ Β βββ index.spec.tsx
βΒ Β βββ index.tsx
Run the tests (this will run all tests: for both LTI and standalone frontends and libraries):
$ yarn test
Browser testing provided by:
π Before you go further, you need to create a Consumer Site
and Passport
in Marsha's admin panel.
You should be all set to make the LTI request on the development view and access Marsha
's frontend interface!
This project is intended to be community-driven, so please, do not hesitate to get in touch if you have any question related to our implementation or design decisions.
We try to raise our code quality standards and expect contributors to follow the recommandations from our handbook.
This work is released under the MIT License (see LICENSE).