This is a set of minimal scripts to run the emulator in a container for various systems such as Docker, for external consumption. The scripts are compatible with both Python version 2 and 3.

*Note that this is still an experimental feature and we recommend installing this tool in a python virtual environment. Please file issues if you notice that anything is not working as expected.

These demos are intended to be run on a linux OS. Your system must meet the following requirements:

• A Python interpreter must be installed (python3 with python3-venv to create virtual environments)

• ADB must be available on the path. ADB comes as part of th Android SDK. Note that installing the command line tools is sufficient.

• Docker must be installed. Make sure you can run it as non-root user

• Docker-compose must be installed.

• KVM must be available. You can get access to KVM by running on "bare metal", or on a (virtual) machine that provides nested virtualization. If you are planning to run this in the cloud (gce/azure/aws/etc..) you first must make sure you have access to KVM. Details on how to get access to KVM on the various cloud providers can be found here:

  • AWS provides bare metal instances that provide access to KVM.
  • Azure: Follow these instructions to enable nested virtualization.
  • GCE: Follow these instructions to enable nested virtualization.

Keep in mind that you will see reduced performance if you are making use of nested virtualization. The containers have been tested under Debian and Ubuntu running kernel 5.2.17.

NOTE: The images will not run in docker on mac or windows

We now host a set of containers in a public repository. You can find details about the containers here. You can now run these containers without building them. For example:

docker run \
  -e ADBKEY="$(cat ~/.android/adbkey)" \
  --device /dev/kvm \
  --publish 8554:8554/tcp \
  --publish 5555:5555/tcp  \
  us-docker.pkg.dev/android-emulator-268719/images/30-google-x64:30.1.2

This will pull down the container if it is not locally available and launch it. You can see that is starting:

After this you can connect to the device by configuring adb:

  adb connect localhost:5555

The device should now show up after a while as:

$ adb devices

List of devices attached
localhost:5555 device

If you wish to use this in a script you could do the following:

docker run -d \
  -e ADBKEY="$(cat ~/.android/adbkey)" \
  --device /dev/kvm \
  --publish 8554:8554/tcp \
  --publish 5555:5555/tcp  \
  us-docker.pkg.dev/android-emulator-268719/images/30-google-x64:30.1.2
  adb connect localhost:5555
  adb wait-for-device

  # The device is now booting, or close to be booted

A more detailed script can be found in run-in-script-example.sh.

You can install the python package as follows:

source ./configure.sh

This will activate a virtual environment and make the executable emu-docker available. You can get detailed information about the usage by launching it as follows:

emu-docker -h

You will have to accept the license agreements before you can create docker containers.

You can interactively select which version of android and emulator you wish to use by running:

emu-docker interactive --start

You will be asked to select a system image and an emulator version, after which a docker file will be created. The system image and emulator will be downloaded to the current directory if needed. The script will provide you with a command to see the logs as well as the command to stop the container.

If the local adb server detected the started container automatically, you have nothing to do to query it through adb. If that's not the case, you can now connect to the running device using adb:

adb connect localhost:5555

To check if adb has seen the container, you can use the:

adb devices

command and check if a device is detected.

Do not forget to stop the docker container once you are done!

Read the section on making the emulator available on the web to run the emulator using webrtc

Issuing:

emu-docker list

will query the currently published Android SDK and output URLs for the zip files of:

• Available and currently Docker-compatible system images
• Currently published and advertised emulator binaries

For each system image, the API level, variant, ABI, and URL are displayed. For each emulator, the update channel (stable vs canary), version, host os, and URL are displayed.

Example output:

SYSIMG android 21 L x86_64 https://dl.google.com/android/repository/sys-img/android/x86_64-21_r05.zip
SYSIMG android 22 L x86_64 https://dl.google.com/android/repository/sys-img/android/x86_64-22_r06.zip
SYSIMG android 23 M x86_64 https://dl.google.com/android/repository/sys-img/android/x86_64-23_r10.zip
SYSIMG android 24 N x86_64 https://dl.google.com/android/repository/sys-img/android/x86_64-24_r08.zip
SYSIMG android 25 N x86_64 https://dl.google.com/android/repository/sys-img/android/x86_64-25_r01.zip
SYSIMG android 26 O x86_64 https://dl.google.com/android/repository/sys-img/android/x86_64-26_r01.zip
SYSIMG android 27 O x86_64 https://dl.google.com/android/repository/sys-img/android/x86_64-27_r01.zip
SYSIMG android 28 P x86_64 https://dl.google.com/android/repository/sys-img/android/x86_64-28_r04.zip
SYSIMG android 28 Q x86_64 https://dl.google.com/android/repository/sys-img/android/x86_64-Q_r04.zip
SYSIMG google_apis 21 L x86_64 https://dl.google.com/android/repository/sys-img/google_apis/x86_64-21_r30.zip
SYSIMG google_apis 22 L x86_64 https://dl.google.com/android/repository/sys-img/google_apis/x86_64-22_r24.zip
SYSIMG google_apis 23 M x86_64 https://dl.google.com/android/repository/sys-img/google_apis/x86_64-23_r31.zip
SYSIMG google_apis 24 N x86_64 https://dl.google.com/android/repository/sys-img/google_apis/x86_64-24_r25.zip
SYSIMG google_apis 25 N x86_64 https://dl.google.com/android/repository/sys-img/google_apis/x86_64-25_r16.zip
SYSIMG google_apis 26 O x86_64 https://dl.google.com/android/repository/sys-img/google_apis/x86_64-26_r13.zip
SYSIMG google_apis 28 P x86_64 https://dl.google.com/android/repository/sys-img/google_apis/x86_64-28_r09.zip
SYSIMG google_apis 28 Q x86_64 https://dl.google.com/android/repository/sys-img/google_apis/x86_64-Q_r04.zip
SYSIMG google_apis_playstore 28 P x86_64 https://dl.google.com/android/repository/sys-img/google_apis_playstore/x86_64-28_r08.p
SYSIMG google_apis_playstore 28 Q x86_64 https://dl.google.com/android/repository/sys-img/google_apis_playstore/x86_64-Q_r04.zp
EMU stable 29.0.11 windows https://dl.google.com/android/repository/emulator-windows-5598178.zip
EMU stable 29.0.11 macosx https://dl.google.com/android/repository/emulator-darwin-5598178.zip
EMU stable 29.0.11 linux https://dl.google.com/android/repository/emulator-linux-5598178.zip
EMU stable 28.0.25 windows https://dl.google.com/android/repository/emulator-windows-5395263.zip
EMU canary 29.0.12 windows https://dl.google.com/android/repository/emulator-windows-5613046.zip
EMU canary 29.0.12 macosx https://dl.google.com/android/repository/emulator-darwin-5613046.zip
EMU canary 29.0.12 linux https://dl.google.com/android/repository/emulator-linux-5613046.zip

One can then use tools like wget or a browser to download a desired emulator and system image. After the two are obtained, we can build a Docker image.

Given an emulator zip file and a system image zip file, we can build a directory that can be sent to docker build via the following invocation of emu-docker:

emu-docker create <emulator-zip> <system-image-zip>  [--dest docker-src-dir
(getcwd()/src by default)]

This places all the right elements to run a docker image, but does not build, run or publish yet. A Linux emulator zip file must be used.

To build the Docker image corresponding to these emulators and system images:

docker build <docker-src-dir, either ./src or specified argument to
emu_docker.py>

A Docker image ID will output; save this image ID.

We currently assume that KVM will be used with docker in order to provide CPU virtualization capabilities to the resulting Docker image.

We provide the following run script:

./run.sh <docker-image-id> <additional-emulator-params>

It does the following:

docker run -e ADBKEY="$(cat ~/.android/adbkey)" \
--device /dev/kvm \
--publish 8554:8554/tcp \
--publish 5555:5555/tcp <docker-image-id>

• Sets up the ADB key, assuming one exists at ~/.android/adbkey
• Uses --device /dev/kvm to have CPU acceleration
• Starts the emulator in the docker image with its gRPC service, forwarding the host ports 8554/5555 to container ports 8554/5555 respectively.
• The gRPC service is used to communicate with the running emulator inside the container.

Note: You can use a public adbkey by injecting the ADBKEY_PUB variable, i.e.: -e ADBKEY_PUB="$(cat ~/.android/adbkey.pub)"

You also have the option to mount a /data partition which the emulator will use if available. This enables you to use a tmpfs which can give increased performance, especially in the nested virtualization scenario.

For example:

docker run -e ADBKEY="$(cat ~/.android/adbkey)" \
--device /dev/kvm \
--mount type=tmpfs,destination=/data \
--publish 8554:8554/tcp \
--publish 5555:5555/tcp <docker-image-id>

We currently only support hardware acceleration for NVIDIA. In order to make use of hardware acceleration you might have to install the NVIDIA docker extensions from here if you are running an older version of docker (<19.03). You must make sure you have a minimal X installation if you are using a cloud instance. For example Xvfb can be used. You must build the containers by passing in the --gpu flag:

emu-docker create stable Q --gpu

You can now launch the emulator with the run-with-gpu.sh script:

./run-with-gpu.sh <docker-image-id> <additional-emulator-params>

The script is similar as to the one described above with the addition that it will:

• Make all the available gpu's available (--gpu all)
• Opens up xhost access for the container
• Enable the domain socket under /tmp/.X11-unix to communicate with hosts X server

Hardware acceleration will significantly improve performance of applications that heavily rely on graphics. Note that even though we need a X11 server for gpu acceleration there will be no ui displayed.

You can push the created images to a repository by providing the --push and --repo and --tag parameters when creating an image. The --tag parameter is optional and is used to indicate the version of the created image. This will default to the build-id of the emulator, as system images are rarely updated.

We adopted the following naming scheme for images:

{api}-{sort}-{abi}

Where:

• api is the api level
• sort is one of: aosp, google, playstore
  • aosp: A basic android open source image
  • google: A system image that includes access to Google Play services.
  • playstore: A system image that includes the Google Play Store app and access to Google Play services, including a Google Play tab in the Extended controls dialog that provides a convenient button for updating Google Play services on the device.
• abi indicates the underlying CPU architecture, which is one of: x86, x86_64, a32, a64. Note that arm images are not hardware accelerated and might not be fast enough.

For example: 29-playstore-x86:30.1.2 indicates a playstore enabled system image with Q running on 32-bit x86.

An example invocation for publishing all Q images to google cloud repo could be:

    emu-docker -v create --push --repo us.gcr.io/emulator-project/ stable "Q"

Images that have been pushed to a repository can be launched directly from the repository. For example:

    docker run --device /dev/kvm --publish 8554:8554/tcp --publish 5555:5555/tcp \
    us.gcr.io/emulator-project/29-playstore-x86:30.1.2

We forward the port 5555 for adb access to the emulator running inside the container. Adb might not automatically detect the device, so run:

adb connect localhost:5555

Your device should now show up as:

$ adb devices

List of devices attached:
localhost:5555 device

This repository also contains an example that demonstrates how you can use docker to make the emulator accessible through the web. This is done by composing the following set of docker containers:

• Envoy, an edge and service proxy: The proxy is responsible for the following:
  • Offer TLS (https) using a self signed certificate
  • Redirect traffic on port 80 (http) to port 443 (https)
  • Act as a gRPC proxy for the emulator.
  • Verifying tokens to permit access to the emulator gRPC endpoint.
  • Redirect other requests to the Nginx component which hosts a React application.
• Nginx, a webserver hosting a compiled React App
• Firebase. We use firebase for authentication and authorization. Firebase will hand out JWT tokens that allow access to the emulator. If you use firebase you must configure your project properly!
• The emulator with a gRPC endpoint and a WebRTC video bridge.

In order to run this sample and be able to interact with the emulator you must keep the following in mind:

• The demo has two methods to display the emulator.
  1. Create an image every second, which is displayed in the browser. This approach will always work, but gives poor performance.
  2. Use WebRTC to display the state of the emulator in real time. This will only work if you are able to create a peer to peer connection to the server hosting the emulator. This is usually not a problem when your server is publicly visible, or if you are running the emulator on your own intranet.

• You will need docker-compose.

• You must have port 80 and 443 available. The docker containers will create an internal network and expose the http and https ports.

• You will need to create an emulator docker image, as described in the documentation above.

• Depending on your network you might need turn

• We are currently using firebase to handle authentication and authorization. you will need to provide a JSON configuation of the project you wish to use. You can use the sample provided here, but it will only work on localhost. You can get the firebase configuration from the console Place the firebase josn configuration here:

  ./js/firebase_config.json

  This will be used to generate the configuration and envoy settings.

In order to create the web containers you must have the following tools available:

• NodeJS
• Npm

Next you must create a container with the emulator & system image version you wish to use. For example:

. ./configure.sh && emu-docker create canary "P.*x86_64"

Once you have taken care of the steps above you can create the containers using the create_web_container.sh script:

$ ./create_web_container.sh -h
   usage: create_web_container.sh [-h] [-a] [-s] [-i] -p user1,pass1,user2,pass2,...

   optional arguments:
   -h        show this help message and exit.
   -a        expose adb. Requires ~/.android/adbkey.pub to be available at run.
   -s        start the container after creation.
   -i        install systemd service, with definition in /opt/emulator

For example:

./create_web_container.sh

This will do the following:

• Create a virtual environment
• Create the set of containers to interact with the emulator.
• Note that the systemd service has only been tested on debian/ubuntu.

You can now launch the container as follows:

docker-compose -f js/docker/docker-compose.yaml up

If you wish to make ADB available you can apply the overlay found in js/docker/development.yaml as follows:

docker-compose -f js/docker/docker-compose.yaml -f js/docker/development.yaml up

Point your browser to localhost. You will likely get a warning due to the usage of the self signed certificate. Once you accept the cert you should be able to login and start using the emulator.

Keep the following things in mind when you make the emulator accessible over adb:

• Port 5555 will be exposed in the container.
• The container must have access to the file: ~/.android/adbkey. This is the PRIVATE key used by adb. Without this you will not be able to access the device over adb.
• The adb client you use to connect to the container must have access to the private key (~/.android/adbkey). This is usually the case if you are on the same machine.
• You must run: adb connect ip-address-of-container:5555 before you can interact with the device. For example:

$ adb connect localhost:5555
$ adb shell getprop

There is a sample cloud-init script that provides details on how you can configure an instance that will automatically launch and configure an emulator on creation. Details on how to do this can be found here.

We have a separate document related to dealing with issues.

Details on the design and how to modify the React application can be found here