The basic-client example shows the functionality of the ca.Client
type. The
methods work as an SDK for integrating services with the Certificate Authority (CA).
In basic-client/client.go we see the initialization of a client:
client, err := ca.NewClient("https://localhost:9000", ca.WithRootSHA256("84a033e84196f73bd593fad7a63e509e57fd982f02084359c4e8c5c864efc27d"))
The previous code uses the CA address and the root certificate fingerprint.
The CA url will be present in the token, and the root fingerprint can be present
too if the --root root_ca.crt
option is used in the creation of the token. If
the token does contain the root fingerprint then it is simpler to use:
client, err := ca.Bootstrap(token)
After the initialization, there are examples of all the client methods. These
methods are a convenient way to use the CA API. The first method, Health
,
returns the status of the CA server. If the server is up it will return
{"status":"ok"}
.
health, err := client.Health()
// Health is a struct created from the JSON response {"status": "ok"}
The next method Root
is used to get and verify the root certificate. We
pass a fingerprint and it downloads the root certificate from the CA and
verifies that the fingerprint matches. This method uses an insecure HTTP
client as it might be used in the initialization of the client, but the response
is considered secure because we have compared against the expected digest.
root, err := client.Root("84a033e84196f73bd593fad7a63e509e57fd982f02084359c4e8c5c864efc27d")
Next we have the most important method; Sign
. Sign
will authorize and sign a
CSR (Certificate Signing Request) that we provide. To authorize this request we use
a provisioning token issued by an authorized provisioner.
You can build your own certificate request and add it in
the *api.SignRequest
, but our CA SDK contains a method that will generate a
secure random key and create a CSR - combining the key with the information
provided in the provisioning token.
// Create a CSR from a token and return the SignRequest, the private key, and an
// error if something failed.
req, pk, err := ca.CreateSignRequest(token)
if err != nil { ... }
// Do the Sign request and return the signed certificate.
sign, err := client.Sign(req)
if err != nil { ... }
Next is the Renew
method which is used to (you guessed it!) renew certificates.
Certificate renewal relies on a mTLS connection with using an existing certificate.
So, as input we will need to pass a transport with the current certificate.
// Get a cancelable context to stop the renewal goroutines and timers.
ctx, cancel := context.WithCancel(context.Background())
defer cancel()
// Create a transport with the sign response and the private key.
tr, err := client.Transport(ctx, sign, pk)
if err != nil { ... }
// Renew the certificate. The return type is equivalent to the Sign method.
renew, err := client.Renew(tr)
if err != nil { ... }
The following methods are for inpsecting Provisioners. One method that returns a list of provisioners or an encrypted key of one provisioner.
// Without options it will return the first 20 provisioners.
provisioners, err := client.Provisioners()
// We can also set a limit up to 100.
provisioners, err := client.Provisioners(ca.WithProvisionerLimit(100))
// With a pagination cursor.
provisioners, err := client.Provisioners(ca.WithProvisionerCursor("1f18c1ecffe54770e9107ce7b39b39735"))
// Or combine both.
provisioners, err := client.Provisioners(
ca.WithProvisionerCursor("1f18c1ecffe54770e9107ce7b39b39735"),
ca.WithProvisionerLimit(100),
)
// Return the encrypted key of one of the returned provisioners. The key
// returned is an encrypted JWE with the private key used to sign tokens.
key, err := client.ProvisionerKey("DmAtZt2EhmZr_iTJJ387fr4Md2NbzMXGdXQNW1UWPXk")
The following example shows how to create a tls.Config object that can be injected into servers and clients. By default, these methods will spin off Go routines that auto-renew a certificate once (approximately) two thirds of the duration of the certificate has passed.
// Get a cancelable context to stop the renewal goroutines and timers.
ctx, cancel := context.WithCancel(context.Background())
defer cancel()
// Get tls.Config for a server.
tlsConfig, err := client.GetServerTLSConfig(ctx, sign, pk)
// Get tls.Config for a client.
tlsConfig, err := client.GetClientTLSConfig(ctx, sign, pk)
// Get an http.Transport for a client; this can be used as a http.RoundTripper
// in an http.Client.
tr, err := client.Transport(ctx, sign, pk)
To run the example you need to start the certificate authority:
certificates $ bin/step-ca examples/pki/config/ca.json
2018/11/02 18:29:25 Serving HTTPS on :9000 ...
Then run client.go with a new token:
certificates $ export STEPPATH=examples/pki
certificates $ export STEP_CA_URL=https://localhost:9000
certificates $ go run examples/basic-client/client.go $(step ca token client.smallstep.com)
In this example we are going run the CA alongside a simple Server using TLS and a simple client making TLS requests to the server.
The examples directory already contains a sample pki configuration with the
password password
hardcoded, but you can create your own using step ca init
.
These examples show the use of some other helper methods - simple ways to
create TLS configured http.Server and http.Client objects. The methods are
BootstrapServer
and BootstrapClient
.
// Get a cancelable context to stop the renewal goroutines and timers.
ctx, cancel := context.WithCancel(context.Background())
defer cancel()
// Create an http.Server that requires a client certificate
srv, err := ca.BootstrapServer(ctx, token, &http.Server{
Addr: ":8443",
Handler: handler,
})
if err != nil {
panic(err)
}
srv.ListenAndServeTLS("", "")
// Get a cancelable context to stop the renewal goroutines and timers.
ctx, cancel := context.WithCancel(context.Background())
defer cancel()
// Create an http.Server that does not require a client certificate
srv, err := ca.BootstrapServerWithMTLS(ctx, token, &http.Server{
Addr: ":8443",
Handler: handler,
}, ca.VerifyClientCertIfGiven())
if err != nil {
panic(err)
}
srv.ListenAndServeTLS("", "")
// Get a cancelable context to stop the renewal goroutines and timers.
ctx, cancel := context.WithCancel(context.Background())
defer cancel()
// Create an http.Client
client, err := ca.BootstrapClient(ctx, token)
if err != nil {
panic(err)
}
resp, err := client.Get("https://localhost:8443")
We will demonstrate the mTLS configuration in a different example. In this example we will configure the server to only verify client certificates if they are provided.
To being with let's start the Step CA:
certificates $ bin/step-ca examples/pki/config/ca.json
2018/11/02 18:29:25 Serving HTTPS on :9000 ...
Next we will start the bootstrap-tls-server and enter password
prompted for the
provisioner password:
certificates $ export STEPPATH=examples/pki
certificates $ export STEP_CA_URL=https://localhost:9000
certificates $ go run examples/bootstrap-tls-server/server.go $(step ca token localhost)
β Key ID: DmAtZt2EhmZr_iTJJ387fr4Md2NbzMXGdXQNW1UWPXk ([email protected])
Please enter the password to decrypt the provisioner key:
Listening on :8443 ...
Let's try to cURL our new bootstrap server with the system certificates bundle as our root. It should fail.
certificates $ curl https://localhost:8443
curl: (60) SSL certificate problem: unable to get local issuer certificate
More details here: https://curl.haxx.se/docs/sslcerts.html
curl performs SSL certificate verification by default, using a "bundle"
of Certificate Authority (CA) public keys (CA certs). If the default
bundle file isn't adequate, you can specify an alternate file
using the --cacert option.
If this HTTPS server uses a certificate signed by a CA represented in
the bundle, the certificate verification probably failed due to a
problem with the certificate (it might be expired, or the name might
not match the domain name in the URL).
If you'd like to turn off curl's verification of the certificate, use
the -k (or --insecure) option.
HTTPS-proxy has similar options --proxy-cacert and --proxy-insecure.
Now let's use the root certificate generated for the Step PKI. It should work.
certificates $ curl --cacert examples/pki/secrets/root_ca.crt https://localhost:8443
Hello nobody at 2018-11-03 01:49:25.66912 +0000 UTC!!!
Notice that in the response we see nobody
. This is because the server did not
detected a TLS client configuration.
But if we create a client with its own certificate (generated by the Step CA), we should see the Common Name of the client certificate:
certificates $ export STEPPATH=examples/pki
certificates $ export STEP_CA_URL=https://localhost:9000
certificates $ go run examples/bootstrap-client/client.go $(step ca token Mike)
β Key ID: DmAtZt2EhmZr_iTJJ387fr4Md2NbzMXGdXQNW1UWPXk ([email protected])
Please enter the password to decrypt the provisioner key:
Server responded: Hello Mike at 2018-11-03 01:52:52.678215 +0000 UTC!!!
Server responded: Hello Mike at 2018-11-03 01:52:53.681563 +0000 UTC!!!
Server responded: Hello Mike at 2018-11-03 01:52:54.682787 +0000 UTC!!!
...
This example demonstrates a stricter configuration of the bootstrap-server. Here we configure the server to require mTLS (mutual TLS) with a valid client certificate.
As always, we begin by starting the CA:
certificates $ bin/step-ca examples/pki/config/ca.json
2018/11/02 18:29:25 Serving HTTPS on :9000 ...
Next we start the mTLS server and we enter password
when prompted for the
provisioner password:
certificates $ export STEPPATH=examples/pki
certificates $ export STEP_CA_URL=https://localhost:9000
certificates $ go run examples/bootstrap-mtls-server/server.go $(step ca token localhost)
β Key ID: DmAtZt2EhmZr_iTJJ387fr4Md2NbzMXGdXQNW1UWPXk ([email protected])
Please enter the password to decrypt the provisioner key:
Listening on :8443 ...
Now that the server is configured to require mTLS cURL-ing should fail even if we use the correct root certificate bundle.
certificates $ curl --cacert examples/pki/secrets/root_ca.crt https://localhost:8443
curl: (35) error:1401E412:SSL routines:CONNECT_CR_FINISHED:sslv3 alert bad certificate
However, if we use our client (which requests a certificate from the Step CA when it starts):
certificates $ export STEPPATH=examples/pki
certificates $ export STEP_CA_URL=https://localhost:9000
certificates $ go run examples/bootstrap-client/client.go $(step ca token Mike)
β Key ID: DmAtZt2EhmZr_iTJJ387fr4Md2NbzMXGdXQNW1UWPXk ([email protected])
Please enter the password to decrypt the provisioner key:
Server responded: Hello Mike at 2018-11-07 21:54:00.140022 +0000 UTC!!!
Server responded: Hello Mike at 2018-11-07 21:54:01.140827 +0000 UTC!!!
Server responded: Hello Mike at 2018-11-07 21:54:02.141578 +0000 UTC!!!
...
We can use the bootstrap-server to demonstrate certificate rotation. We've
added a second provisioner, named [email protected]
, to the CA configuration.
This provisioner is has a default certificate duration of 2 minutes.
Let's run the server, and inspect the certificate. We can should be able to
see the certificate rotate once approximately 2/3rds of its lifespan has passed.
certificates $ export STEPPATH=examples/pki
certificates $ export STEP_CA_URL=https://localhost:9000
certificates $ go run examples/bootstrap-server/server.go $(step ca token localhost)
β Key ID: YYNxZ0rq0WsT2MlqLCWvgme3jszkmt99KjoGEJJwAKs ([email protected])
Please enter the password to decrypt the provisioner key:
Listening on :8443 ...
In this case, the certificate will rotate after 74-80 seconds.
The exact formula is <duration>-<duration>/3-rand(<duration>/20)
(duration=120
in our example).
We can use the following command to check the certificate expiration and to make sure the certificate changes after 74-80 seconds.
certificates $ step certificate inspect --insecure https://localhost:8443
The example under the docker
directory shows how to combine the Step CA
with NGINX to serve or proxy services using certificates created by the
Step CA.
This example creates 3 different docker images:
- nginx-test: docker image with NGINX and a script using inotify-tools to watch for changes in the certificate to reload NGINX.
- step-ca-test: docker image with the Step CA
- step-renewer-test: docker image with the step cli tool - it creates the certificate and sets a cron that renews the certificate (the cron runs every minute for testing purposes).
To run this test you need to have the docker daemon running. With docker running
swith to the examples/docker directory
and run make
:
certificates $ cd examples/docker/
docker $ make
GOOS=linux go build -o ca/step-ca github.com/smallstep/certificates/cmd/step-ca
GOOS=linux go build -o renewer/step github.com/smallstep/cli/cmd/step
docker build -t nginx-test:latest nginx
...
docker-compose up
WARNING: The Docker Engine you're using is running in swarm mode.
Compose does not use swarm mode to deploy services to multiple nodes in a swarm. All containers will be scheduled on the current node.
To deploy your application across the swarm, use `docker stack deploy`.
Creating network "docker_default" with the default driver
Creating docker_ca_1 ... done
Creating docker_renewer_1 ... done
Creating docker_nginx_1 ... done
Attaching to docker_ca_1, docker_renewer_1, docker_nginx_1
ca_1 | 2018/11/12 19:39:16 Serving HTTPS on :443 ...
nginx_1 | Setting up watches.
nginx_1 | Watches established.
...
Make will build the binaries for step and step-ca, create the images, create the containers and start them using docker composer.
NGINX will be listening on your local machine on https://localhost:4443, but to
make sure the cert is right we need to add the following entry to /etc/hosts
:
127.0.0.1 nginx
Now we can use cURL to verify:
docker $ curl --cacert ca/pki/secrets/root_ca.crt https://nginx:4443/
<!DOCTYPE html>
<html>
<head>
<title>Welcome to nginx!</title>
<style>
body {
width: 35em;
margin: 0 auto;
font-family: Tahoma, Verdana, Arial, sans-serif;
}
</style>
</head>
<body>
<h1>Welcome to nginx!</h1>
<p>If you see this page, the nginx web server is successfully installed and
working. Further configuration is required.</p>
<p>For online documentation and support please refer to
<a href="http://nginx.org/">nginx.org</a>.<br/>
Commercial support is available at
<a href="http://nginx.com/">nginx.com</a>.</p>
<p><em>Thank you for using nginx.</em></p>
</body>
</html>
We can use make inspect
to witness the certificate being rotated every minute.
docker $ make inspect | head
step certificate inspect https://localhost:4443 --insecure
Certificate:
Data:
Version: 3 (0x2)
Serial Number: 220353801925419530569669982276277771655 (0xa5c6993a7e110e6f009c83c79edc1d87)
Signature Algorithm: ECDSA-SHA256
Issuer: CN=Smallstep Intermediate CA
Validity
Not Before: Nov 10 02:13:00 2018 UTC
Not After : Nov 11 02:13:00 2018 UTC
docker $ make inspect | head
step certificate inspect https://localhost:4443 --insecure
Certificate:
Data:
Version: 3 (0x2)
Serial Number: 207756171799719353821615361892302471392 (0x9c4c621c04d3e8be401ff0d14c5440e0)
Signature Algorithm: ECDSA-SHA256
Issuer: CN=Smallstep Intermediate CA
Validity
Not Before: Nov 10 02:14:00 2018 UTC
Not After : Nov 11 02:14:00 2018 UTC
Finally, to cleanup the containers and volumes created in this demo use make down
:
docker $ make down
docker-compose down
Stopping docker_nginx_1 ... done
Stopping docker_renewer_1 ... done
Stopping docker_ca_1 ... done
Removing docker_nginx_1 ... done
Removing docker_renewer_1 ... done
Removing docker_ca_1 ... done
Removing network docker_default
The basic-federation example showcases how to securely facilitate communication between relying parties of multiple autonomous certificate authorities. Federation is what's required when services are spread between multiple independent Kubernetes clusters, public clouds, and/or serverless cloud functions to enable service communication across boundaries.
This example uses a pre-generated PKI (public/private key material). Do not use pre-generated PKIs for dev, staging, or production purposes outside of this example.
Bring up two online CAs; Cloud CA
and Kubernetes CA
.
$ step-ca ./pki/cloud/config/ca.federated.json
Please enter the password to decrypt intermediate_ca_key: password
2019/01/22 13:38:52 Serving HTTPS on :1443 ...
$ step-ca ./pki/kubernetes/config/ca.federated.json
Please enter the password to decrypt intermediate_ca_key: password
2019/01/22 13:39:44 Serving HTTPS on :2443 ...
Notice the difference between the two configuration options below. Cloud CA
will list Kubernetes CA
in the federatedRoots
section and vice versa for the federated options.
$ diff pki/cloud/config/ca.json pki/cloud/config/ca.federated.json
3c3
< "federatedRoots": [],
---
> "federatedRoots": ["pki/cloud/certs/kubernetes_root_ca.crt"],
This demo server leverages step's SDK to obtain certs, automatically renew them, and fetch a bundle of trusted roots. When it starts up it will report what root certificates it will use to authenticate client certs.
go run server/main.go $(step ca token \
--ca-url https://localhost:1443 \
--root ./pki/cloud/certs/root_ca.crt \
127.0.0.1)
β Key ID: EE1ZiqkMaxsUdpz8SCSkRBzwK9TWUoidQnMnJ8Eryn8 ([email protected])
β Please enter the password to decrypt the provisioner key: password
Server is using federated root certificates
Accepting certs anchored in CN=Smallstep Public Cloud Root CA
Accepting certs anchored in CN=Smallstep Kubernetes Root CA
Listening on :8443 ...
Similarly step's SDK provides a client option to mutually authenticate connections to servers. It automatically handles cert bootstrapping, renewal, and fetches a bundle of trusted roots. The demo client will send HTTP requests to the demo server periodically (every 5s).
$ go run client/main.go $(step ca token sdk_client \
--ca-url https://localhost:2443 \
--root ./pki/kubernetes/certs/root_ca.crt)
β Key ID: S5gYgpeqcIAgc1Zr4myZXpgJ_Ao4ryS6F6wqg9o8RYo ([email protected])
β Please enter the password to decrypt the provisioner key: password
Server responded: Hello sdk_client (cert issued by 'Smallstep Kubernetes Root CA') at 2019-01-23 00:51:38.576648 +0000 UTC
While the demo client provides a convenient way to periodically send requests to the demo server curl in combination with a client cert from Kubernetes CA
can be used to hit the server instead:
$ step ca certificate kube_client kube_client.crt kube_client.key \
--ca-url https://localhost:2443 \
--root pki/kubernetes/certs/root_ca.crt
β Key ID: S5gYgpeqcIAgc1Zr4myZXpgJ_Ao4ryS6F6wqg9o8RYo ([email protected])
β Please enter the password to decrypt the provisioner key:
β CA: https://localhost:2443/1.0/sign
β Certificate: kube_client.crt
β Private Key: kube_client.key
Federation relies on a bundle of multiple trusted roots which need to be fetched before passed into curl.
$ step ca federation --ca-url https://localhost:1443 \
--root pki/cloud/certs/root_ca.crt \
federated.pem
The federation certificate bundle has been saved in federated.pem.
Passing the cert (issued by Kubernetes CA
) into curl using the appropriate command line flags:
$ curl -i --cacert federated.pem \
--cert kube_client.crt \
--key kube_client.key \
https://127.0.0.1:8443
HTTP/2 200
content-type: text/plain; charset=utf-8
content-length: 105
date: Mon, 28 Jan 2019 15:24:54 GMT
Hello kube_client (cert issued by 'Smallstep Kubernetes Root CA') at 2019-01-28 15:24:54.864373 +0000 UTC
Since the demo server is enrolled with the federated Cloud CA
that trusts certs issued by the Kubernetes CA
through federation the connection is successfully established.
Bring up the certificate authority with the example:
certificates $ step-ca examples/pki/config/ca.json
2019/03/11 13:37:03 Serving HTTPS on :9000 ...
The example comes with multiple provisioner options, two of which have custom claims to expand the validity of certificates:
$ step ca provisioner list | jq '.[] | "\(.name): \(.claims.defaultTLSCertDuration)"'
# null means step default of 24h for cert validity
"[email protected]: null"
"[email protected]: 2m0s"
"decade: 87600h0m0s"
"90days: 2160h0m0s"
A closer look at a duration-bound provisioner, 90days
for instance, reveals the custom configuration for certificate validity.
$ step ca provisioner list | jq '.[3].claims'
{
"maxTLSCertDuration": "2160h0m0s",
"defaultTLSCertDuration": "2160h0m0s"
}
Certificates with different validity periods can be generated using the respective provisioners. The durations are strings which are a sequence of decimal numbers, each with optional fraction and a unit suffix, such as "300ms" or "2h45m". Valid time units are "ns", "us" (or "Β΅s"), "ms", "s", "m", "h".
Please see Getting Started in the docs directory to learn what custom claims configuration options are available and how to use them.
$ step ca certificate decade decade.crt decade.key
β Key ID: iu7VZxKUcquv1BCWuvEUOyRy4zYyCmgt61OpRW5VbRE (decade)
β Please enter the password to decrypt the provisioner key: password
β CA: https://localhost:9000/1.0/sign
β Certificate: decade.crt
β Private Key: decade.key
$ step certificate inspect --format json decade.crt | jq .validity
{
"start": "2019-03-11T22:34:30Z",
"end": "2029-03-08T22:34:30Z",
"length": 315360000
}
$ step ca certificate 90days 90days.crt 90days.key
β Key ID: 2LgjIvfirblnFMC6FjUr8jYkO8nOqz4rKoarCc8kiGU (90days)
β Please enter the password to decrypt the provisioner key: password
β CA: https://localhost:9000/1.0/sign
β Certificate: 90days.crt
β Private Key: 90days.key
$ step certificate inspect --format json 90days.crt | jq .validity
{
"start": "2019-03-11T22:35:39Z",
"end": "2019-06-09T22:35:39Z",
"length": 7776000
}
Configuration management tools such as Puppet, Chef, Ansible, Salt, etc. make automation and deployment a whole lot easier and more manageable. Step CLI and CA are built with automation in mind and are easy to configure using your favorite tools
The following are snippets and files that users can add to their puppet manifests to easily instrument services with TLS.
** step.pp ** - Install step
from source and configure the step
user, group,
and home directory for use by the Step CLI and CA.
** step_ca.pp ** - Install step-ca
from source. Configure
certificates and secrets and run the Step CA.
** tls_server.pp ** - This is your service, instrumented
with the Step CA SDK to request, receive, and renew TLS certificates. See
the bootstrap-tls-server for a
simple integration example.
Note: This is a significantly oversimplified example that will not work standalone. A complete Puppet configuration should use a service manager (like systemctl) and a secret store (like Hiera). If you are interested in seeing a more complete example please let us know and we'll make one available.