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The wireguard is mostly used to compute metadata. Metadata is now computed by main.go and encoded in node.go, the cluster only receives a function generating the binary metadata. |
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LICENSE | ||
Makefile | ||
README.md | ||
cluster.go | ||
config.go | ||
go.mod | ||
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main.go | ||
netlink.go | ||
node.go | ||
wireguard.go | ||
wireguard_test.go |
README.md
wesher
wesher
creates and manages an encrypted mesh overlay network across a group of nodes, using wireguard.
Its main use-case is adding low-maintenance security to public-cloud networks or connecting different cloud providers.
⚠ WARNING: since mesh membership is controlled by a mesh-wide pre-shared key, this effectively downgrades some of the security benefits from wireguard. See security considerations below for more details.
Quickstart
-
Before starting:
-
make sure the wireguard kernel module is installed on all nodes.
-
The following ports must be accessible between all nodes (see configuration options to change these):
- 51820 UDP
- 7946 UDP and TCP
-
-
Download the latest release for your architecture:
$ wget -O wesher https://github.com/costela/wesher/releases/latest/download/wesher-$(go env GOARCH) $ chmod a+x wesher
-
On the first node:
# ./wesher
This will start the wesher daemon in the foreground and - when running on a terminal - will currently output a generated cluster key as follows:
new cluster key generated: XXXXX
Note: to avoid accidentally leaking it in the logs, the created key will only be displayed if running on a terminal. When started via other means (e.g.: desktop session manager or init system), the key can be retreived with
grep ClusterKey /var/lib/wesher/state.json
. -
Lastly, on any further node:
# wesher --cluster-key XXXXX --join x.x.x.x
Where
XXXXX
is the base64 encoded 256 bit key printed by the step above, andx.x.x.x
is the hostname or IP of any of the nodes already joined to the mesh cluster.
Permissions
Note that wireguard
- and therefore wesher
- need root access to work properly.
It is also possible to give the wesher
binary enough capabilities to manage the wireguard
interface via:
# setcap cap_net_admin=eip wesher
This will enable running as an unprivileged user, but some functionality (like automatic adding peer entries to
/etc/hosts
; see configuration options below) will not work.
(optional) systemd integration
A minimal systemd
unit file is provided under the dist
folder and can be copied to /etc/systemd/system
:
# wget -O /etc/systemd/system/wesher.service https://raw.githubusercontent.com/costela/wesher/master/dist/wesher.service
# systemctl daemon-reload
# systemctl enable wesher
The provided unit file assumes wesher
is installed to /usr/local/sbin
.
Note that, as mentioned above, the initial cluster key will not be displayed in the journal.
It can either be initialized by running wesher
manually once, or by pre-seeding via /etc/default/wesher
as the WESHER_CLUSTER_KEY
environment var (see configuration options below).
Installing from source
There are a couple of ways of installing wesher
from sources:
Preferred:
$ git clone https://github.com/costela/wesher.git
$ cd wesher
$ make
This method can build a bit-by-bit identical binary to the released ones, assuming the same go version is used to build its respective git tag.
Alternatively:
$ GO111MODULE=on go get github.com/costela/wesher
Note: this method will not provide a meaningful output for --version
.
Features
The wesher
tool builds a cluster and manages the configuration of wireguard on each node to create peer-to-peer
connections between all nodes, thus forming a full mesh VPN.
This approach may not scale for hundreds of nodes (benchmarks accepted 😉), but is sufficiently performant to join
several nodes across multiple cloud providers, or simply to secure inter-node comunication in a single public-cloud.
Automatic Key management
The wireguard private keys are created on startup for each node and the respective public keys are then broadcast across the cluster.
The control-plane cluster communication is secured with a pre-shared AES-256 key. This key can be be automatically created during startup of the first node in a cluster, or it can be provided (see configuration). The cluster key must then be sent to other nodes via a out-of-band secure channel (e.g. ssh, cloud-init, etc). Once set, the cluster key is saved locally and reused on the next startup.
Automatic IP address management
The overlay IP address of each node is automatically selected out of a private network (10.0.0.0/8
by default; MUST be different from the underlying network used for cluster communication) and is consistently hashed based on the peer's hostname.
The use of consistent hashing means a given node will always receive the same overlay IP address (see limitations of this approach below).
Note: the node's hostname is also used by the underlying cluster management (using memberlist) to identify nodes and must therefore be unique in the cluster.
Automatic /etc/hosts management
To ease intra-node communication, wesher
also adds entries to /etc/hosts
for each peer in the mesh. This enables using the nodes' hostnames to ensure communication over the secured overlay network (assuming files
is the first entry for hosts
in /etc/nsswitch.conf
).
See configuration below for how to disable this behavior.
Seamless restarts
If a node in the cluster is restarted, it will attempt to re-join the last-known nodes using the same cluster key. This means a restart requires no manual intervention.
Configuration options
All options can be passed either as command-line flags or environment variables:
Option | Env | Description | Default |
---|---|---|---|
--cluster-key KEY |
WESHER_CLUSTER_KEY | shared key for cluster membership; must be 32 bytes base64 encoded; will be generated if not provided | autogenerated/loaded |
--join HOST,... |
WESHER_JOIN | comma separated list of hostnames or IP addresses to existing cluster members; if not provided, will attempt resuming any known state or otherwise wait for further members | |
--init |
WESHER_INIT | whether to explicitly (re)initialize the cluster; any known state from previous runs will be forgotten | false |
--bind-addr ADDR |
WESHER_BIND_ADDR | IP address to bind to for cluster membership (cannot be used with --bind-iface) | autodetected |
--bind-iface IFACE |
WESHER_BIND_IFACE | Interface to bind to for cluster membership (cannot be used with --bind-addr) | |
--cluster-port PORT |
WESHER_CLUSTER_PORT | port used for membership gossip traffic (both TCP and UDP); must be the same across cluster | 7946 |
--wireguard-port PORT |
WESHER_WIREGUARD_PORT | port used for wireguard traffic (UDP); must be the same across cluster | 51820 |
--overlay-net ADDR/MASK |
WESHER_OVERLAY_NET | the network in which to allocate addresses for the overlay mesh network (CIDR format); smaller networks increase the chance of IP collision | 10.0.0.0/8 |
--interface DEV |
WESHER_INTERFACE | name of the wireguard interface to create and manage | wgoverlay |
--no-etc-hosts |
WESHER_NO_ETC_HOSTS | whether to skip writing hosts entries for each node in mesh | false |
--log-level LEVEL |
WESHER_LOG_LEVEL | set the verbosity (one of debug/info/warn/error) | warn |
Security considerations
The decision of whom to allow in the mesh is made by memberlist and is secured by a cluster-wide pre-shared key. Compromise of this key will allow an attacker to:
- access services exposed on the overlay network
- impersonate and/or disrupt traffic to/from other nodes It will not, however, allow the attacker access to decrypt the traffic between other nodes.
This pre-shared key is currently static, set up during cluster bootstrapping, but will - in a future version - be rotated for improved security.
Current known limitations
Overlay IP collisions
Since the assignment of IPs on the overlay network is currently decided by the individual node and implemented as a naive hashing of the hostname, there can be no guarantee two hosts will not generate the same overlay IPs. This limitation may be worked around in a future version.
Split-brain
Once a cluster is joined, there is currently no way to distinguish a failed node from an intentionally removed one. This is partially by design: growing and shrinking your cluster dynamically (e.g. via autoscaling) should be as easy as possible.
However, this does mean longer connection loss between any two parts of the cluster (e.g. across a WAN link between different cloud providers) can lead to a split-brain scenario where each side thinks the other side is simply "gone".
There is currently no clean solution for this problem, but one could work around it by designating edge nodes which
periodically restart wesher
with the --join
option pointing to the other side.
Future versions might include the notion of a "static" node to more cleanly avoid this.