etcd supports SSL/TLS as well as authentication through client certificates, both for clients to server as well as peer (server to server / cluster) communication.
To get up and running you first need to have a CA certificate and a signed key pair for one member. It is recommended to create and sign a new key pair for every member in a cluster.
For convenience the cfssl tool provides an easy interface to certificate generation, and we provide a full example using the tool at here. Alternatively this site provides a good reference on how to generate self-signed key pairs:
http://www.g-loaded.eu/2005/11/10/be-your-own-ca/
etcd takes several certificate related configuration options, either through command-line flags or environment variables:
Client-to-server communication:
--cert-file=<path>
: Certificate used for SSL/TLS connections to etcd. When this option is set, you can set advertise-client-urls using HTTPS schema.
--key-file=<path>
: Key for the certificate. Must be unencrypted.
--client-cert-auth
: When this is set etcd will check all incoming HTTPS requests for a client certificate signed by the trusted CA, requests that don't supply a valid client certificate will fail.
--trusted-ca-file=<path>
: Trusted certificate authority.
Peer (server-to-server / cluster) communication:
The peer options work the same way as the client-to-server options:
--peer-cert-file=<path>
: Certificate used for SSL/TLS connections between peers. This will be used both for listening on the peer address as well as sending requests to other peers.
--peer-key-file=<path>
: Key for the certificate. Must be unencrypted.
--peer-client-cert-auth
: When set, etcd will check all incoming peer requests from the cluster for valid client certificates signed by the supplied CA.
--peer-trusted-ca-file=<path>
: Trusted certificate authority.
If either a client-to-server or peer certificate is supplied the key must also be set. All of these configuration options are also available through the environment variables, ETCD_CA_FILE
, ETCD_PEER_CA_FILE
and so on.
For this you need your CA certificate (ca.crt
) and signed key pair (server.crt
, server.key
) ready.
Let us configure etcd to provide simple HTTPS transport security step by step:
$ etcd -name infra0 -data-dir infra0 \
-cert-file=/path/to/server.crt -key-file=/path/to/server.key \
-advertise-client-urls=https://127.0.0.1:2379 -listen-client-urls=https://127.0.0.1:2379
This should start up fine and you can now test the configuration by speaking HTTPS to etcd:
$ curl --cacert /path/to/ca.crt https://127.0.0.1:2379/v2/keys/foo -XPUT -d value=bar -v
You should be able to see the handshake succeed. Because we use self-signed certificates with our own certificate authorities you need to provide the CA to curl using the --cacert
option. Another possibility would be to add your CA certificate to the trusted certificates on your system (usually in /etc/ssl/certs
).
OSX 10.9+ Users: curl 7.30.0 on OSX 10.9+ doesn't understand certificates passed in on the command line.
Instead you must import the dummy ca.crt directly into the keychain or add the -k
flag to curl to ignore errors.
If you want to test without the -k
flag run open ./fixtures/ca/ca.crt
and follow the prompts.
Please remove this certificate after you are done testing!
If you know of a workaround let us know.
For now we've given the etcd client the ability to verify the server identity and provide transport security. We can however also use client certificates to prevent unauthorized access to etcd.
The clients will provide their certificates to the server and the server will check whether the cert is signed by the supplied CA and decide whether to serve the request.
You need the same files mentioned in the first example for this, as well as a key pair for the client (client.crt
, client.key
) signed by the same certificate authority.
$ etcd -name infra0 -data-dir infra0 \
-client-cert-auth -trusted-ca-file=/path/to/ca.crt -cert-file=/path/to/server.crt -key-file=/path/to/server.key \
-advertise-client-urls https://127.0.0.1:2379 -listen-client-urls https://127.0.0.1:2379
Now try the same request as above to this server:
$ curl --cacert /path/to/ca.crt https://127.0.0.1:2379/v2/keys/foo -XPUT -d value=bar -v
The request should be rejected by the server:
...
routines:SSL3_READ_BYTES:sslv3 alert bad certificate
...
To make it succeed, we need to give the CA signed client certificate to the server:
$ curl --cacert /path/to/ca.crt --cert /path/to/client.crt --key /path/to/client.key \
-L https://127.0.0.1:2379/v2/keys/foo -XPUT -d value=bar -v
You should able to see:
...
SSLv3, TLS handshake, CERT verify (15):
...
TLS handshake, Finished (20)
And also the response from the server:
{
"action": "set",
"node": {
"createdIndex": 12,
"key": "/foo",
"modifiedIndex": 12,
"value": "bar"
}
}
etcd supports the same model as above for peer communication, that means the communication between etcd members in a cluster.
Assuming we have our ca.crt
and two members with their own keypairs (member1.crt
& member1.key
, member2.crt
& member2.key
) signed by this CA, we launch etcd as follows:
DISCOVERY_URL=... # from https://discovery.etcd.io/new
# member1
$ etcd -name infra1 -data-dir infra1 \
-peer-client-cert-auth -peer-trusted-ca-file=/path/to/ca.crt -peer-cert-file=/path/to/member1.crt -peer-key-file=/path/to/member1.key \
-initial-advertise-peer-urls=https://10.0.1.10:2380 -listen-peer-urls=https://10.0.1.10:2380 \
-discovery ${DISCOVERY_URL}
# member2
$ etcd -name infra2 -data-dir infra2 \
-peer-client-cert-auth -peer-trusted-ca-file=/path/to/ca.crt -peer-cert-file=/path/to/member2.crt -peer-key-file=/path/to/member2.key \
-initial-advertise-peer-urls=https://10.0.1.11:2380 -listen-peer-urls=https://10.0.1.11:2380 \
-discovery ${DISCOVERY_URL}
The etcd members will form a cluster and all communication between members in the cluster will be encrypted and authenticated using the client certificates. You will see in the output of etcd that the addresses it connects to use HTTPS.
The internal protocol of etcd v2.0.x uses a lot of short-lived HTTP connections.
So, when enabling TLS you may need to increase the heartbeat interval and election timeouts to reduce internal cluster connection churn.
A reasonable place to start are these values: --heartbeat-interval 500 --election-timeout 2500
.
This issues is resolved in the etcd v2.1.x series of releases which uses fewer connections.
The crypto/tls
package of golang
checks the key usage of the certificate public key before using it.
To use the certificate public key to do client auth, we need to add clientAuth
to Extended Key Usage
when creating the certificate public key.
Here is how to do it:
Add the following section to your openssl.cnf:
[ ssl_client ]
...
extendedKeyUsage = clientAuth
...
When creating the cert be sure to reference it in the -extensions
flag:
$ openssl ca -config openssl.cnf -policy policy_anything -extensions ssl_client -out certs/machine.crt -infiles machine.csr
Make sure that you sign your certificates with a Subject Name your member's public IP address. The etcd-ca
tool for example provides an --ip=
option for its new-cert
command.
If you need your certificate to be signed for your member's FQDN in its Subject Name then you could use Subject Alternative Names (short IP SANs) to add your IP address. The etcd-ca
tool provides --domain=
option for its new-cert
command, and openssl can make it too.