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Developing Emissary-ingress

Welcome to the Emissary-ingress Community!

Thank you for contributing, we appreciate small and large contributions and look forward to working with you to make Emissary-ingress better.

This document is intended for developers looking to contribute to the Emissary-ingress project. In this document you will learn how to get your development environment setup and how to contribute to the project. Also, you will find more information about the internal components of Emissary-ingress and other questions about working on the project.

Looking for end user guides for Emissary-ingress? You can check out the end user guides at https://www.getambassador.io/docs/emissary/.

After reading this document if you have questions we encourage you to join us on our Slack channel in the #emissary-ingress channel.

Table of Contents

Development Setup

This section provides the steps for getting started developing on Emissary-ingress. There are a number of prerequisites that need to be setup. In general, our tooling tries to detect any missing requirements and provide a friendly error message. If you ever find that this is not the case please file an issue.

Note: To enable developers contributing on Macs with Apple Silicon, we ensure that the artifacts are built for linux/amd64 rather than the host linux/arm64 architecture. This can be overriden using the BUILD_ARCH environment variable. Pull Request are welcome :).

Step 1: Install Build Dependencies

Here is a list of tools that are used by the build system to generate the build artifacts, packaging them up into containers, generating crds, helm charts and for running tests.

  • git
  • make
  • docker (make sure you can run docker commands as your dev user without sudo)
  • bash
  • rsync
  • golang - go.mod for current version
  • python (>=3.10.9)
  • kubectl
  • a kubernetes cluster (you need permissions to create resources, i.e. crds, deployments, services, etc...)
  • a Docker registry
  • bsdtar (Provided by libarchive-tools on Ubuntu 19.10 and newer)
  • gawk
  • jq
  • helm

Step 2: Clone Project

If you haven't already then this would be a good time to clone the project running the following commands:

# clone to your preferred folder
git clone https://github.com/emissary-ingress/emissary.git

# navigate to project
cd emissary

Step 3: Configuration

You can configure the build system using environment variables, two required variables are used for setting the container registry and the kubeconfig used.

Important: the test and build system perform destructive operations against your cluster. Therefore, we recommend that you use a development cluster. Setting the DEV_KUBECONFIG variable described below ensures you don't accidently perform actions on a production cluster.

Open a terminal in the location where you cloned the repository and run the following commands:

# set container registry using `export DEV_REGISTRY=<your-registry>
# note: you need to be logged in and have permissions to push
# Example:
export DEV_REGISTRY=docker.io/parsec86

# set kube config file using `export DEV_KUBECONFIG=<dev-kubeconfig>`
# your cluster needs the ability to read from the configured container registry
export DEV_KUBECONFIG="$HOME/.kube/dev-config.yaml"

Step 4: Building

The build system for this project leverages make and multi-stage docker builds to produce the following containers:

  • emissary.local/emissary - single deployable container for Emissary-ingress
  • emissary.local/kat-client - test client container used for testing
  • emissary.local/kat-server - test server container used for testing

Using the terminal session you opened in step 2, run the following commands

# This will pull and build the necessary docker containers and produce multiple containers.
# If this is the first time running this command it will take a little bit while the base images are built up and cached.
make images

# verify containers were successfully created, you should also see some of the intermediate builder containers as well
docker images | grep emissary.local

What just happened?

The build system generated a build container that pulled in envoy, the build dependencies, built various binaries from within this project and packaged them into a single deployable container. More information on this can be found in the Architecture Document.

Step 5: Push

Now that you have successfully built the containers its time to push them to your container registry which you setup in step 2.

In the same terminal session you can run the following command:

# re-tags the images and pushes them to your configured container registry
# docker must be able to login to your registry and you have to have push permissions
make push

# you can view the newly tag images by running
docker images | grep <your -registry>

# alternatively, we have two make targets that provide information as well
make env

# or in a bash export friendly format
make export

Step 6: Deploy

Now its time to deploy the container out to your Kubernetes cluster that was configured in step 2. Hopefully, it is already becoming apparent that we love to leverage Make to handle the complexity for you :).

# generate helm charts and K8's Configs with your container swapped in and apply them to your cluster
make deploy

# check your cluster to see if emissary is running
# note: kubectl doesn't know about  DEV_KUBECONFIG so you may need to ensure KUBECONFIG is pointing to the correct cluster
kubectl get pod -n ambassador

🥳 If all has gone well then you should have your development environment setup for building and testing Emissary-ingress.

Step 7: Dev-loop

Now that you are all setup and able to deploy a development container of Emissary-ingress to a cluster, it is time to start making some changes.

Lookup an issue that you want to work on, assign it to yourself and if you have any questions feel free to ping us on slack in the #emissary-dev channel.

Make a change to Emissary-ingress and when you want to test it in a live cluster just re-run

make deploy

This will:

  • recompile the go binary
  • rebuild containers
  • push them to the docker registry
  • rebuild helm charts and manifest
  • reapply manifest to cluster and re-deploy Emissary-ingress to the cluster

Do I have to run the other make targets make images or make push ? No you don't have to because make deploy will actually run those commands for you. The steps above were meant to introduce you to the various make targets so that you aware of them and have options when developing.

What should I do next?

Now that you have your dev system up and running here are some additional content that we recommend you check out:

Contributing

This section goes over how to contribute code to the project and how to get started contributing. More information on how we manage our branches can be found below in Development Workflow.

Before contributing be sure to read our Code of Conduct and Governance to get an understanding of how our project is structured.

Submitting a Pull Request (PR)

If you haven't set up your development environment then please see the Development Setup section.

When submitting a Pull Request (PR) here are a set of guidelines to follow:

  1. Search for an existing issue or create a new issue.

  2. Be sure to describe your proposed change and any open questions you might have in the issue. This allows us to collect historical context around an issue, provide feedback on the proposed solution and discuss what versions a fix should target.

  3. If you haven't done so already create a fork of the respository and clone it locally

    git clone <your-fork>
  4. Cut a new patch branch from master:

    git checkout master
    git checkout -b my-patch-branch master
  5. Make necessary code changes.

    Smaller pull requests are easier to review and can get merged faster thus reducing potential for merge conflicts so it is recommend to keep them small and focused.

  6. Commit your changes using descriptive commit messages.

    • we require that all commits are signed off so please be sure to commit using the --signoff flag, e.g. git commit --signoff
    • commit message should summarize the fix and motivation for the proposed fix. Include issue # that the fix looks to address.
    • we are "ok" with multiple commits but we may ask you to squash some commits during the PR review process
  7. Push your branch to your forked repository:

    It is good practice to make sure your change is rebased on the latest master to ensure it will merge cleanly so if it has been awhile since you rebased on upstream you should do it now to ensure there are no merge conflicts

    git push origin my-patch-branch
  8. Submit a Pull Request from your fork targeting upstream emissary/master.

Thanks for your contribution! One of the Maintainers will review your PR and discuss any changes that need to be made.

Pull Request Review Process

This is an opportunity for the Maintainers to review the code for accuracy and ensure that it solves the problem outlined in the issue. This is an iterative process and meant to ensure the quality of the code base. During this process we may ask you to break up Pull Request into smaller changes, squash commits, rebase on master, etc...

Once you have been provided feedback:

  1. Make the required updates to the code per the review discussion
  2. Retest the code and ensure linting is still passing
  3. Commit the changes and push to Github
  4. Repeat these steps as necessary

Once you have two approvals then one of the Maintainers will merge the PR.

🎉 Thank you for contributing and being apart of the Emissary-ingress Community!

Rebasing a branch under review

Many times the base branch will have new commits added to it which may cause merge conflicts with your open pull request. First, a good rule of thumb is to make pull request small so that these conflicts are less likely to occur but this is not always possible when have multiple people working on similiar features. Second, if it is just addressing commit feedback a fixup commit is also a good option so that the reviewers can see what changed since their last review.

If you need to address merge conflicts then it is preferred that you use Rebase on the base branch rather than merging base branch into the feature branch. This ensures that when the PR is merged that it will cleanly replay on top of the base branch ensuring we maintain a clean linear history.

To do a rebase you can do the following:

# add emissary.git as a remote repository, only needs to be done once
git remote add upstream https://github.com/emissary-ingress/emissary.git

# fetch upstream master
git fetch upstream master

# checkout local master and update it from upstream master
git checkout master
git pull -ff upstream master

# rebase patch branch on local master
git checkout my-patch-branch
git rebase -i master

Once the merge conflicts are addressed and you are ready to push the code up you will need to force push your changes because during the rebase process the commit sha's are re-written and it has diverged from what is in your remote fork (Github).

To force push a branch you can:

git push head --force-with-lease

Note: the --force-with-lease is recommended over --force because it is safer because it will check if the remote branch had new commits added during your rebase. You can read more detail here: https://itnext.io/git-force-vs-force-with-lease-9d0e753e8c41

Fixup commits during PR review

One of the major downsides to rebasing a branch is that it requires force pushing over the remote (Github) which then marks all the existing review history outdated. This makes it hard for a reviewer to figure out whether or not the new changes addressed the feedback.

One way you can help the reviewer out is by using fixup commits. Fixup commits are special git commits that append fixup! to the subject of a commit. Git provides tools for easily creating these and also squashing them after the PR review process is done.

Since this is a new commit on top of the other commits, you will not lose your previous review and the new commit can be reviewed independently to determine if the new changes addressed the feedback correctly. Then once the reviewers are happy we will ask you to squash them so that we when it is merged we will maintain a clean linear history.

Here is a quick read on it: https://jordanelver.co.uk/blog/2020/06/04/fixing-commits-with-git-commit-fixup-and-git-rebase-autosquash/

TL;DR;

# make code change and create new commit
git commit --fixup <sha>

# push to Github for review
git push

# reviewers are happy and ask you to do a final rebase before merging
git rebase -i --autosquash master

# final push before merging
git push --force-with-lease

Development Workflow

This section introduces the development workflow used for this repository. It is recommended that both Contributors, Release Engineers and Maintainers familiarize themselves with this content.

Branching Strategy

This repository follows a trunk based development workflow. Depending on what article you read there are slight nuances to this so this section will outline how this repository interprets that workflow.

The most important branch is master this is our Next Release version and it should always be in a shippable state. This means that CI should be green and at any point we can decided to ship a new release from it. In a traditional trunk based development workflow, developers are encouraged to land partially finished work daily and to keep that work hidden behind feature flags. This repository does NOT follow that and instead if code lands on master it is something we are comfortable with shipping.

We ship release candidate (RC) builds from the master branch (current major) and also from release/v{major.minor} branches (last major version) during our development cycles. Therefore, it is important that it remains shippable at all times!

When we do a final release then we will cut a new release/v{major.minor} branch. These are long lived release branches which capture a snapshot in time for that release. For example here are some of the current release branches (as of writing this):

  • release/v3.2
  • release/v3.1
  • release/v3.0
  • release/v2.4
  • release/v2.3
  • release/v1.14

These branches contain the codebase as it was at that time when the release was done. These branches have branch protection enabled to ensure that they are not removed or accidently overwritten. If we needed to do a security fix or bug patch then we may cut a new .Z patch release from an existing release branch. For example, the release/v2.4 branch is currently on 2.4.1.

As you can see we currently support mutliple major versions of Emissary-ingress and you can read more about our End-of-Life Policy.

For more information on our current RC and Release process you can find that in our Release Wiki.

Backport Strategy

Since we follow a trunk based development workflow this means that the majority of the time your patch branch will be based off from master and that most Pull Request will target master.

This ensures that we do not miss bug fixes or features for the "Next" shippable release and simplifies the mental-model for deciding how to get started contributing code.

What if I need a patch to land in a previous supported version?

Let's say I have a bug fix for CRD round trip conversion for AuthService, which is affecting both v2.y and v3.y.

First within the issue we should discuss what versions we want to target. This can depend on current cycle work and any upcoming releases we may have.

The general rules we follow are:

  1. land patch in "next" version which is master
  2. backport patch to any release/v{major}.{minor} branches

So, let's say we discuss it and say that the "next" major version is a long ways away so we want to do a z patch release on our current minor version(v3.2) and we also want to do a z patch release on our last supported major version (v2.4).

This means that these patches need to land in three separate branches:

  1. master - next release
  2. release/v3.2 - patch release
  3. release/v2.4 - patch release

In this scenario, we first ask you to land the patch in the master branch and then provide separate PR's with the commits backported onto the release/v* branches.

Recommendation: using the git cherry-pick -x will add the source commit sha to the commit message. This helps with tracing work back to the original commit.

What if my patch is only for a previous supported version?

Although, this should be an edge case, it does happen where the code has diverged enough that a fix may only be relevant to an existing supported version. In these cases we may need to do a patch release for that older supported version.

A good example, if we were to find a bug in the Envoy v2 protocol configuration we would only want to target the v2 release.

In this scenario, the base branch that we would create our feature branch off from would be the latest minor version for that release. As of writing this, that would be the release/v2.4 branch. We would not need to target master.

But, let's say during our fix we notice other things that need to be addressed that would also need to be fixed in master. Then you need to submit a separate Pull Request that should first land on master and then follow the normal backporting process for the other patches.

What if I'm still not sure?

This is what the issue discussions and disucssion in Slack are for so that we can help guide you so feel free to ping us in the #emissary-dev channel on Slack to discuss directly with us.

Merge Strategy

The audience for this section is the Maintainers but also beneficial for Contributors so that they are familiar with how the project operates.

Having a clean linear commit history for a repository makes it easier to understand what is being changed and reduces the mental load for new comers to the project.

To maintain a clean linear commit history the following rules should be followed:

First, always rebase patch branch on to base branch. This means NO merge commits from merging base branch into the patch branch. This can be accomplished using git rebase.

# first, make sure you pull latest upstream changes
git fetch upstream
git checkout master
git pull -ff upstream/master

# checkout patch branch and rebase interactive
# you may have merge conflicts you need to resolve
git checkout my-patch-branch
git rebase -i master

Note: this does rewrite your commit shas so be aware when sharing branches with co-workers.

Once the Pull Request is reviewed and has two approvals then a Maintainer can merge. Maintainers should follow prefer the following merge strategies:

  1. rebase and merge
  2. squash merge

When rebase and merge is used your commits are played on top of the base branch so that it creates a clean linear history. This will maintain all the commits from the Pull Request. In most cases this should be the preferred merge strategy.

When a Pull Request has lots of fixup commits, or pr feedback fixes then you should ask the Contributor to squash them as part of the PR process.

If the contributor is unable to squash them then using a squash merge in some cases makes sense. IMPORTANT, when this does happen it is important that the commit messages are cleaned up and not just blindly accepted the way proposed by Github. Since it is easy to miss that cleanup step, this should be used less frequently compared to rebase and merge.

What about merge commit strategy?

The audience for this section is the Maintainers but also beneficial for Contributors so that they are familiar with how the project operates.

When maintaining a linear commit history, each commit tells the story of what was changed in the repository. When using merge commits it adds an additional commit to the history that is not necessary because the commit history and PR history already tell the story.

Now merge commits can be useful when you are concerned with not rewriting the commit sha. Based on the current release process which includes using rel/v branches that are tagged and merged into release/v branches we must use a merge commit when merging these branches. This ensures that the commit sha a Git Tag is pointing at still exists once merged into the release/v branch.

Contributing to the Docs

The Emissary-ingress community will all benefit from having documentation that is useful and correct. If you have found an issue with the end user documentation, then please help us out by submitting an issue and/or pull request with a fix!

The end user documentation for Emissary-ingress lives in a different repository and can be found at https://github.com/datawire/ambassador-docs.

See this repository for details on how to contribute to either a pre-release or already-released version of Emissary-ingress.

Advanced Topics

This section is for more advanced topics that provide more detailed instructions. Make sure you go through the Development Setup and read the Architecture document before exploring these topics.

Running Emissary-ingress internals locally

The main entrypoint is written in go. It strives to be as compatible as possible with the normal go toolchain. You can run it with:

go run ./cmd/busyambassador entrypoint

Of course just because you can run it this way does not mean it will succeed. The entrypoint needs to launch diagd and envoy in order to function, and it also expect to be able to write to the /ambassador directory.

Setting up diagd

If you want to hack on diagd, its easiest to setup a virtualenv with an editable copy and launch your go run from within that virtualenv. Note that these instructions depend on the virtualenvwrapper (https://virtualenvwrapper.readthedocs.io/en/latest/) package:

# Create a virtualenv named venv with all the python requirements
# installed.
python3 -m venv venv
. venv/bin/activate
# If you're doing this in Datawire's apro.git, then:
cd ambassador
# Update pip and install dependencies
pip install --upgrade pip
pip install orjson    # see below
pip install -r builder/requirements.txt
# Created an editable installation of ambassador:
pip install -e python/
# Check that we do indeed have diagd in our path.
which diagd
# If you're doing this in Datawire's apro.git, then:
cd ..

(Note: it shouldn't be necessary to install orjson by hand. The fact that it is at the moment is an artifact of the way Ambassador builds currently happen.)

Changing the ambassador root

You should now be able to launch ambassador if you set the ambassador_root environment variable to a writable location:

ambassador_root=/tmp go run ./cmd/busyambassador entrypoint

Getting envoy

If you do not have envoy in your path already, the entrypoint will use docker to run it.

Shutting up the pod labels error

An astute observe of the logs will notice that ambassador complains vociferously that pod labels are not mounted in the ambassador container. To reduce this noise, you can:

mkdir /tmp/ambassador-pod-info && touch /tmp/ambassador-pod-info/labels

Extra credit

When you run ambassador locally it will configure itself exactly as it would in the cluster. That means with two caveats you can actually interact with it and it will function normally:

  1. You need to run telepresence connect or equivalent so it can connect to the backend services in its configuration.

  2. You need to supply the host header when you talk to it.

Debugging and Developing Envoy Configuration

Envoy configuration is generated by the ambassador compiler. Debugging the ambassador compiler by running it in kubernetes is very slow since we need to push both the code and any relevant kubernetes resources into the cluster. The following sections will provide tips for improving this development experience.

Making changes to Envoy

Emissary-ingress is built on top of Envoy and leverages a vendored version of Envoy (we track upstream very closely). This section will go into how to make changes to the Envoy that is packaged with Emissary-ingress.

This is a bit more complex than anyone likes, but here goes:

1. Preparing your machine

Building and testing Envoy can be very resource intensive. A laptop often can build Envoy... if you plug in an external hard drive, point a fan at it, and leave it running overnight and most of the next day. At Ambassador Labs, we'll often spin up a temporary build machine in GCE, so that we can build it very quickly.

As of Envoy 1.15.0, we've measure the resource use to build and test it as:

Command Disk Size Disk Used Duration[1]
make update-base 450G 12GB ~11m
make check-envoy 450G 424GB ~45m

[1] On a "Machine type: custom (32 vCPUs, 512 GB memory)" VM on GCE, with the following entry in its /etc/fstab:

tmpfs:docker  /var/lib/docker  tmpfs  size=450G  0  0

If you have the RAM, we've seen huge speed gains from doing the builds and tests on a RAM disk (see the /etc/fstab line above).

2. Setting up your workspace to hack on Envoy

  1. From your emissary.git checkout, get Emissary-ingress's current version of the Envoy sources, and create a branch from that:

    make $PWD/_cxx/envoy
    git -C _cxx/envoy checkout -b YOUR_BRANCHNAME
  2. To build Envoy in FIPS mode, set the following variable:

    export FIPS_MODE=true

    It is important to note that while building Envoy in FIPS mode is required for FIPS compliance, additional steps may be necessary. Emissary does not claim to be FIPS compliant or certified. See here for more information on FIPS and Envoy.

NOTE: FIPS_MODE is NOT supported by the emissary-ingress maintainers but we provide this for developers as convience

3. Hacking on Envoy

Modify the sources in ./_cxx/envoy/. or update the branch and/or ENVOY_COMMIT as necessary in ./_cxx/envoy.mk

4. Building and testing your hacked-up Envoy

See ./_cxx/envoy.mk for the full list of targets.

Multiple Phony targets are provided so that developers can run the steps they are interested in when developing, here are few of the key ones:

  • make update-base: will perform all the steps necessary to verify, build envoy, build docker images, push images to the container repository and compile the updated protos.

  • make build-envoy: will build the envoy binaries using the same build container as the upstream Envoy project. Build outputs are mounted to the _cxx/envoy-docker-build directory and Bazel will write the results there.

  • make build-base-envoy-image: will use the release outputs from building envoy to generate a new base-envoy container which is then used in the main emissary-ingress container build.

  • make push-base-envoy: will push the built container to the remote container repository.

  • make check-envoy: will use the build docker container to run the Envoy test suite against the currently checked out envoy in the _cxx/envoy folder.

  • make envoy-shell: will run the envoy build container and open a bash shell session. The _cxx/envoy folder is volume mounted into the container and the user is set to the envoybuild user in the container to ensure you are not running as root to ensure hermetic builds.

5. Test Devloop

Running the Envoy test suite will compile all the test targets. This is a slow process and can use lots of disk space.

The Envoy Inner Devloop for build and testing:

  • You can make a change to Envoy code and run the whole test by just calling make check-envoy

  • You can run a specific test instead of the whole test suite by setting the ENVOY_TEST_LABEL environment variable.

    • For example, to run just the unit tests in test/common/network/listener_impl_test.cc, you should run:
    ENVOY_TEST_LABEL='//test/common/network:listener_impl_test' make check-envoy
  • Alternatively, you can run make envoy-shell to get a bash shell into the Docker container that does the Envoy builds and you are free to interact with Bazel directly.

Interpreting the test results:

  • If you see the following message, don't worry, it's harmless; the tests still ran:

    There were tests whose specified size is too big. Use the --test_verbose_timeout_warnings command line option to see which ones these are.
    

    The message means that the test passed, but it passed too quickly, and Bazel is suggesting that you declare it as smaller. Something along the lines of "This test only took 2s, but you declared it as being in the 60s-300s ('moderate') bucket, consider declaring it as being in the 0s-60s ('short') bucket".

    Don't be confused (as I was) in to thinking that it was saying that the test was too big and was skipped and that you need to throw more hardware at it.

  • Build or test Emissary-ingress with the usual make commands, with the exception that you MUST run make update-base first whenever Envoy needs to be recompiled; it won't happen automatically. So make test to build-and-test Emissary-ingress would become make update-base && make test, and make images to just build Emissary-ingress would become make update-base && make images.

The Envoy changes with Emissary-ingress:

  • Either run make update-base to build, and push a new base container and then you can run make test for the Emissary-ingress test suite.
  • If you do not want to push the container you can instead:
    • Build Envoy - make build-envoy
    • Build container - make build-base-envoy-image
    • Test Emissary - make test

6. Protobuf changes

If you made any changes to the Protocol Buffer files or if you bumped versions of Envoy then you should make sure that you are re-compiling the Protobufs so that they are available and checked-in to the emissary.git repository.

make compile-envoy-protos

This will copy over the raw proto files, compile and copy the generated go code over to emisary-ignress repository.

7. Finalizing your changes

NOTE: we are no longer accepting PR's in datawire/envoy.git.

If you have custom changes then land them in your custom envoy repository and update the ENVOY_COMMIT and ENVOY_DOCKER_REPO variable in _cxx/envoy.mk so that the image will be pushed to the correct repository.

Then run make update-base does all the bits so assuming that was successful then are all good.

For maintainers:

You will want to make sure that the image is pushed to the backup container registries:

# upload image to the mirror in GCR
SHA=GET_THIS_FROM_THE_make_update-base_OUTPUT
TAG="envoy-0.$SHA.opt"
docker pull "docker.io/emissaryingress/base-envoy:envoy-0.$TAG.opt"
docker tag "docker.io/emissaryingress/base-envoy:$TAG" "gcr.io/datawire/ambassador-base:$TAG"
docker push "gcr.io/datawire/ambassador-base:$TAG"

8. Final Checklist

For Maintainers Only

Here is a checklist of things to do when bumping the base-envoy version:

  • The image has been pushed to...
    • docker.io/emissaryingress/base-envoy
    • gcr.io/datawire/ambassador-base
  • The datawire/envoy.git commit has been tagged as datawire-$(git describe --tags --match='v*') (the --match is to prevent datawire-* tags from stacking on each other).
  • It's been tested with...
    • make check-envoy

The check-envoy-version CI job will double check all these things, with the exception of running the Envoy tests. If the check-envoy-version is failing then double check the above, fix them and re-run the job.

Developing Emissary-ingress (Maintainers-only advice)

At the moment, these techniques will only work internally to Maintainers. Mostly this is because they require credentials to access internal resources at the moment, though in several cases we're working to fix that.

Updating license documentation

When new dependencies are added or existing ones are updated, run make generate and commit changes to DEPENDENCIES.md and DEPENDENCY_LICENSES.md

Upgrading Python dependencies

Delete python/requirements.txt, then run make generate.

If there are some dependencies you don't want to upgrade, but want to upgrade everything else, then

  1. Remove from python/requirements.txt all of the entries except for those you want to pin.
  2. Delete python/requirements.in (if it exists).
  3. Run make generate.

Note: If you are updating orjson you will need to also update docker/base-python/Dockerfile before running make generate for the new version. orjson uses rust bindings and the default wheels on PyPI rely on glibc. Because our base python image is Alpine based, it is built from scratch using rustc to build a musl compatable version.

⚠️ You may run into an error when running make generate where it can't detect the licenses for new or upgraded dependencies, which is needed so that so that we can properly generate DEPENDENCIES.md and DEPENDENCY_LICENSES.md. If that is the case, you may also have to update build-aux/tools/src/py-mkopensource/main.go:parseLicenses for any license changes then run make generate again.

FAQ

This section contains a set of Frequently Asked Questions that may answer a question you have. Also, feel free to ping us in Slack.

How do I find out what build targets are available?

Use make help and make targets to see what build targets are available along with documentation for what each target does.

How do I develop on a Mac with Apple Silicon?

To ensure that developers using a Mac with Apple Silicon can contribute, the build system ensures the build artifacts are linux/amd64 rather than the host architecture. This behavior can be overriden using the BUILD_ARCH environment variable (e.g. BUILD_ARCH=linux/arm64 make images).

How do I develop on Windows using WSL?

How do I test using a private Docker repository?

If you are pushing your development images to a private Docker repo, then:

export DEV_USE_IMAGEPULLSECRET=true
export DOCKER_BUILD_USERNAME=...
export DOCKER_BUILD_PASSWORD=...

and the test machinery should create an imagePullSecret from those Docker credentials such that it can pull the images.

How do I change the loglevel at runtime?

curl localhost:8877/ambassador/v0/diag/?loglevel=debug

Note: This affects diagd and Envoy, but NOT the AES amb-sidecar. See the AES CONTRIBUTING.md for how to do that.

Can I build from a docker container instead of on my local computer?

If you want to build within a container instead of setting up dependencies on your local machine then you can run the build within a docker container and leverage "Docker in Docker" to build it.

  1. docker pull docker:latest
  2. docker run --rm -v /var/run/docker.sock:/var/run/docker.sock -it docker:latest sh
  3. apk add --update --no-cache bash build-base go curl rsync python3 python2 git libarchive-tools gawk jq
  4. git clone https://github.com/emissary-ingress/emissary.git && cd emissary
  5. make images

Steps 0 and 1 are run on your machine, and 2 - 4 are from within the docker container. The base image is a "Docker in Docker" image, ran with -v /var/run/docker.sock:/var/run/docker.sock in order to connect to your local daemon from the docker inside the container. More info on Docker in Docker here.

The images will be created and tagged as defined above, and will be available in docker on your local machine.

How do I clear everything out to make sure my build runs like it will in CI?

Use make clobber to completely remove all derived objects, all cached artifacts, everything, and get back to a clean slate. This is recommended if you change branches within a clone, or if you need to make generate when you're not certain that your last make generate was using the same Envoy version.

Use make clean to remove derived objects, but not clear the caches.

My editor is changing go.mod or go.sum, should I commit that?

If you notice this happening, run make go-mod-tidy, and commit that.

(If you're in Ambassador Labs, you should do this from apro/, not apro/ambassador/, so that apro.git's files are included too.)

How do I debug "This should not happen in CI" errors?

These checks indicate that some output file changed in the middle of a run, when it should only change if a source file has changed. Since CI isn't editing the source files, this shouldn't happen in CI!

This is problematic because it means that running the build multiple times can give different results, and that the tests are probably not testing the same image that would be released.

These checks will show you a patch showing how the output file changed; it is up to you to figure out what is happening in the build/test system that would cause that change in the middle of a run. For the most part, this is pretty simple... except when the output file is a Docker image; you just see that one image hash is different than another image hash.

Fortunately, the failure showing the changed image hash is usually immediately preceded by a docker build. Earlier in the CI output, you should find an identical docker build command from the first time it ran. In the second docker build's output, each step should say ---> Using cache; the first few steps will say this, but at some point later steps will stop saying this; find the first step that is missing the ---> Using cache line, and try to figure out what could have changed between the two runs that would cause it to not use the cache.

If that step is an ADD command that is adding a directory, the problem is probably that you need to add something to .dockerignore. To help figure out what you need to add, try adding a RUN find DIRECTORY -exec ls -ld -- {} + step after the ADD step, so that you can see what it added, and see what is different on that between the first and second docker build commands.

How do I run Emissary-ingress tests?

  • export DEV_REGISTRY=<your-dev-docker-registry> (you need to be logged in and have permission to push)
  • export DEV_KUBECONFIG=<your-dev-kubeconfig>

If you want to run the Go tests for cmd/entrypoint, you'll need diagd in your PATH. See the instructions below about Setting up diagd to do that.

Group Command
All Tests make test
All Golang make gotest
All Python make pytest
Some/One Golang make gotest GOTEST_PKGS=./cmd/entrypoint GOTEST_ARGS="-run TestName"
Some/One Python make pytest PYTEST_ARGS="-k TestName"

Please note the python tests use a local cache to speed up test results. If you make a code update that changes the generated envoy configuration, those tests will fail and you will need to update the python test cache.

Note that it is invalid to run one of the main[Plain.*] Python tests without running all of the other main[Plain*] tests; the test will fail to run (not even showing up as a failure or xfail--it will fail to run at all). For example, PYTEST_ARGS="-k WebSocket" would match the main[Plain.WebSocketMapping-GRPC] test, and that test would fail to run; one should instead say PYTEST_ARGS="-k Plain or WebSocket" to avoid breaking the sub-tests of "Plain".

How do I type check my python code?

Ambassador uses Python 3 type hinting and the mypy static type checker to help find bugs before runtime. If you haven't worked with hinting before, a good place to start is the mypy cheat sheet.

New code must be hinted, and the build process will verify that the type check passes when you make test. Fair warning: this means that PRs will not pass CI if the type checker fails.

We strongly recommend using an editor that can do realtime type checking (at Datawire we tend to use PyCharm and VSCode a lot, but many many editors can do this now) and also running the type checker by hand before submitting anything:

  • make lint/mypy will check all the Ambassador code

Ambassador code should produce no warnings and no errors.

If you're concerned that the mypy cache is somehow wrong, delete the .mypy_cache/ directory to clear the cache.