This is an implementation of an ACME-based CA. The ACME protocol allows the CA to automatically verify that an applicant for a certificate actually controls an identifier, and allows domain holders to issue and revoke certificates for their domains.
Boulder has a Dockerfile to make it easy to install and set up all its dependencies. This is how the maintainers work on Boulder, and is our main recommended way to run it.
Make sure you have a local copy of Boulder in your $GOPATH
:
export GOPATH=~/gopath
git clone https://github.com/letsencrypt/boulder/ $GOPATH/src/github.com/letsencrypt/boulder
To start Boulder in a Docker container, run:
docker-compose up
To run tests:
docker-compose run boulder ./test.sh
To run a specific unittest:
docker-compose run boulder go test ./ra
The configuration in docker-compose.yml mounts your
$GOPATH
on top of its own
$GOPATH
. So you can edit code on your host and it will be immediately
reflected inside Docker images run with docker-compose.
If docker-compose fails with an error message like "Cannot start service
boulder: oci runtime error: no such file or directory" or "Cannot create
container for service boulder" you should double check that your $GOPATH
exists and doesn't contain any characters other than letters, numbers, -
and _
.
If you have problems with Docker, you may want to try removing all containers and volumes.
By default, Boulder uses a fake DNS resolver that resolves all hostnames to 127.0.0.1. This is suitable for running integration tests inside the Docker container. If you want Boulder to be able to communicate with a client running on your host instead, you should find your host's Docker IP with:
ifconfig docker0 | grep "inet addr:" | cut -d: -f2 | awk '{ print $1}'
And edit docker-compose.yml to change the FAKE_DNS environment variable to match.
Alternatively, you can override the docker-compose.yml default with an environmental variable using -e (replace 172.17.0.1 with the host IPv4 address found in the command above)
docker-compose run -e FAKE_DNS=172.17.0.1 --service-ports boulder ./start.py
Boulder's default VA configuration (test/config/va.json
) is configured to
connect to port 5002 to validate HTTP-01 challenges and port 5001 to validate
TLS-SNI-01 challenges. If you want to solve challenges with a client running on
your host you should make sure it uses these ports to respond to validation
requests, or update the VA configuration's portConfig
to use ports 80 and 443
to match how the VA operates in production and staging environments. If you use
a host-based firewall (e.g. ufw
or iptables
) make sure you allow connections
from the Docker instance to your host on the required ports.
If a base image changes (i.e. letsencrypt/boulder-tools
) you will need to rebuild
images for both the boulder and bhsm containers and re-create them. The quickest way
to do this is with this command:
./docker-rebuild.sh
If you can't use the Docker setup, here are instructions for setting up a Boulder development environment without it.
We recommend setting git's fsckObjects setting for better integrity guarantees when getting updates.
Boulder requires an installation of libtool-ltdl, goose, SoftHSM, and MariaDB 10.1 to work correctly. If you want to save some trouble installing MariaDB and SoftHSM you can run them using Docker:
docker-compose up -d bmysql bhsm
Also, Boulder requires Go 1.5. As of September 2015 this version is not yet
available in OS repositories, so you will have to install from https://golang.org/dl/.
Add ${GOPATH}/bin
to your path.
Ubuntu:
sudo apt-get install libltdl3-dev mariadb-server rabbitmq-server
CentOS:
sudo yum install libtool-ltdl-devel MariaDB-server MariaDB-client rabbitmq-server
Arch Linux:
sudo pacman -S libtool mariadb rabbitmq --needed
OS X:
brew install libtool mariadb rabbitmq
or
sudo port install libtool mariadb-server rabbitmq-server
(On OS X, using port, you will have to add CGO_CFLAGS="-I/opt/local/include" CGO_LDFLAGS="-L/opt/local/lib"
to your environment or go
invocations.)
Edit /etc/hosts to add this line:
127.0.0.1 boulder boulder-rabbitmq boulder-mysql
Resolve Go-dependencies, set up a database:
./test/setup.sh
Note: setup.sh
calls create_db.sh
, which uses the root MariaDB
user with the default password, so if you have disabled that account
or changed the password you may have to adjust the file or recreate the commands.
Install SoftHSM to store the CA private key in a way that can be accessed using PKCS#11. Then run ./test/make-softhsm.sh and follow its instructions.
Install Python packages for integration test:
virtualenv venv
. venv/bin/activate
pip install -r test/requirements.txt
# If you want to develop against a locally modified Python acme package,
# this will install the package such that updates are reflected immediately:
pip install -e ~/certbot/acme[dev]
Start all boulder components with test configs (Ctrl-C kills all):
./start.py
Run tests:
./test.sh
Check out the Certbot client from https://github.com/certbot/certbot and follow the setup instructions there. Once you've got the client set up, you'll probably want to run it against your local Boulder. There are a number of command line flags that are necessary to run the client against a local Boulder, and without root access. The simplest way to run the client locally is to source a file that provides an alias for certbot (certbot_test
) that has all those flags:
source ~/certbot/tests/integration/_common.sh
certbot_test certonly -a standalone -d example.com
Your local Boulder instance uses a fake DNS server that returns 127.0.0.1 for any query, so you can use any value for the -d flag. You can also override that value by setting the environment variable FAKE_DNS=1.2.3.4
The CA is divided into the following main components:
- Web Front End
- Registration Authority
- Validation Authority
- Certificate Authority
- Storage Authority
- OCSP Updater
- OCSP Responder
This component model lets us separate the function of the CA by security context. The Web Front End and Validation Authority need access to the Internet, which puts them at greater risk of compromise. The Registration Authority can live without Internet connectivity, but still needs to talk to the Web Front End and Validation Authority. The Certificate Authority need only receive instructions from the Registration Authority. All components talk to the SA for storage, so lines indicating SA RPCs are not shown here.
+--------- OCSP Updater
| |
v |
CA |
^ |
| v
Subscriber -> WFE --> RA --> SA --> MariaDB
| ^
Subscriber server <- VA <----+ |
|
Browser ------------------> OCSP Responder
Internally, the logic of the system is based around four types of objects: registrations, authorizations, challenges, and certificates, mapping directly to the resources of the same name in ACME.
Requests from ACME clients result in new objects and changes to objects. The Storage Authority maintains persistent copies of the current set of objects.
Objects are also passed from one component to another on change events. For example, when a client provides a successful response to a validation challenge, it results in a change to the corresponding validation object. The Validation Authority forwards the new validation object to the Storage Authority for storage, and to the Registration Authority for any updates to a related Authorization object.
Boulder uses gRPC for inter-component communication. For components that you want to be remote, it is necessary to instantiate a "client" and "server" for that component. The client implements the component's Go interface, while the server has the actual logic for the component. More details on this communication model can be found in the gRPC documentation.
The full details of how the various ACME operations happen in Boulder are laid out in DESIGN.md
All Go dependencies are vendored under the vendor directory, to make dependency management easier.
Local development also requires a MariaDB 10 installation. MariaDB should be run on port 3306 for the default integration tests.
To update the Go dependencies:
# Fetch godep
go get -u github.com/tools/godep
# Check out the currently vendorized version of each dependency.
godep restore
# Update to the latest version of a dependency. Alternately you can cd to the
# directory under GOPATH and check out a specific revision. Here's an example
# using cfssl:
go get -u github.com/cloudflare/cfssl/...
# Update the Godep config to the appropriate version.
godep update github.com/cloudflare/cfssl/...
# Save the dependencies
godep save ./...
git add Godeps vendor
git commit
NOTE: If you get "godep: no packages can be updated," there's a good chance
you're trying to update a single package that belongs to a repo with other
packages. For instance, godep update golang.org/x/crypto/ocsp
will produce
this error, because it's part of the golang.org/x/crypto
repo, from which we
also import the pkcs12
package. Godep requires that all packages from the same
repo be on the same version, so it can't update just one. The error message is
not particularly helpful. See tools/godep#164 for the
issue dedicated to fixing it.
NOTE: Updating cfssl in particular is tricky, because cfssl vendors
github.com/google/certificate-transparency/...
and
golang.org/x/crypto/ocsp/...
, which we also vendor. In practice this means you
need to check out those two dependencies to the same version cfssl uses
(available in vendor/manifest
in the cfssl repo). If you fail to do this,
you will get conflicting types between our vendored version and the cfssl vendored version.
godep update golang.org/x/crypto/... github.com/cloudflare/cfssl/... github.com/google/certificate-transparency/...
godep save ./...
Boulder uses gRPC for all RPCs. To add a new RPC method, add it to the relevant .proto file, then run:
docker-compose run boulder go generate ./path/to/pkg/...