2020-06-03 15:42:43 +00:00
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vpncloud(1)
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===========
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== Name
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vpncloud - Peer-to-peer VPN
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== SYNOPSIS
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*vpncloud [options] [--config <file>] [-t <type>] [-d <name>] [-l <addr>] [-c <addr>...]*
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== OPTIONS
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*--config <file>*::
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Read configuration options from the specified file. Please see the section
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*CONFIG FILES* for documentation on the file format.
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If the same option is defined in the config file and as a parameter, the
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parameter overrides the config file.
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*-t <type>*, *--type <type>*::
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Set the type of network. There are two options: *tap* devices process
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Ethernet frames *tun* devices process IP packets. [default: *tap*]
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*-d <name>*, *--device <name>*::
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Name of the virtual device. Any *%d* will be filled with a free number.
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[default: *vpncloud%d*]
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*--device-path <path>*::
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The path of the base device inode, e.g. /dev/net/run.
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*-m <mode>*, *--mode <mode>*::
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The mode of the VPN. The VPN can like a router, a switch or a hub. A *hub*
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will send all data always to all peers. A *switch* will learn addresses
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from incoming data and only send data to all peers when the address is
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unknown. A *router* will send data according to known subnets of the
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peers and ignore them otherwise. The *normal* mode is switch for tap
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devices and router for tun devices. [default: *normal*]
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*-l <addr>*, *--listen <addr>*::
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The address on which to listen for data. This can be simply a port number
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or a full address in form IP:PORT. If the IP is specified as \'\*' or only
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a port number is given, then the socket will listen on all IPs (v4 and v6),
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otherwise the socket will only listen on the given IP. [default: **3210**]
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*-c <addr>*, *--connect <addr>*::
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Address of a peer to connect to. The address should be in the form
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*addr:port*. If the node is not started, the connection will be retried
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periodically. This parameter can be repeated to connect to multiple peers.
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2020-06-30 15:38:48 +00:00
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*-s <subnet>*, *--subnet <subnet>*::
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The local subnets to use. This parameter should be in the form
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*address/prefixlen* where address is an IPv4 address, an IPv6 address, or a
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MAC address. The prefix length is the number of significant front bits that
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distinguish the subnet from other subnets. Example: *10.1.1.0/24*.
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*--shared-key <key>*::
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An optional shared key to encrypt the VPN data. If this option is not set,
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the traffic will be sent unencrypted.
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*--crypto <method>*::
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The encryption method to use ("aes128", "aes256", or "chacha20"). Most
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current CPUs have special support for AES256 so this should be faster. For
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older computers lacking this support, CHACHA20 is the fastest option.
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[default: *chacha20*]
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*--magic <id>*::
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Override the 4-byte magic header of each packet. This header identifies the
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network and helps to distinguish it from other networks and other
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applications. The id can either be a 4 byte / 8 character hexadecimal
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string or an arbitrary string prefixed with "hash:" which will then be
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hashed into 4 bytes.
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*--peer-timeout <secs>*::
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Peer timeout in seconds. The peers will exchange information periodically
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and drop peers that are silent for this period of time. [default: **600**]
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*--keepalive <secs>*::
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Interval of peer exchange messages in seconds. The peers will exchange
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information periodically to keep connections alive. This setting overrides
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how often this will happen. [default: *peer-timeout/2-60*]
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*--dst-timeout <secs>*::
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Switch table entry timeout in seconds. This parameter is only used in switch
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mode. Addresses that have not been seen for the given period of time will
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be forgotten. [default: **300**]
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*--beacon-store <path|command>*::
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Periodically store beacons containing the address of this node in the given
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file or via the given command. If the parameter value starts with a pipe
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character (*|*), the rest of the value is interpreted as a shell command.
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Otherwise the value is interpreted as a file to write the beacon to.
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If this parameter is not given, beacon storage is disabled.
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Please see the section *BEACONS* for more information.
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*--beacon-load <path|command>*::
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Periodically load beacons containing the addresses of other nodes from the
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given file or via the given command. If the parameter value starts with a
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pipe character (*|*), the rest of the value is interpreted as a shell
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command. Otherwise the value is interpreted as a file to read the beacon
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from.
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If this parameter is not given, beacon loading is disabled.
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Please see the section *BEACONS* for more information.
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*--beacon-interval <secs>*::
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Beacon storage/loading interval in seconds. If configured to do so via
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*--beacon-store* and *--beacon-load*, the node will periodically store its
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beacon and load beacons of other nodes. This parameter defines the interval
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in seconds. [default: **3600**]
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*--ifup <command>*::
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A command to setup the network interface. The command will be run (as
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parameter to *sh -c*) when the device has been created to configure it.
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The name of the allocated device will be available via the environment
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variable *IFNAME*.
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Please note that this command is executed with the full permissions of the
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caller.
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*--ifdown <command>*::
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A command to bring down the network interface. The command will be run (as
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parameter to *sh -c*) to remove any configuration from the device.
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The name of the allocated device will be available via the environment
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variable *IFNAME*.
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Please note that this command is executed with the (limited) permissions of
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the user and group given as *--user* and *--group*.
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*--pid-file <file>*::
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Store the process id in this file when running in the background. If set,
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the given file will be created containing the process id of the new
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background process. This option is only used when running in background.
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*--user <user>*::
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*--group <group>*::
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Change the user and/or group of the process once all the setup has been
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done.
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*--log-file <file>*::
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If set, print logs also to the given file. The file will be created and
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truncated if is exists.
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*--stats-file <file>*::
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If set, periodically write statistics on peers and current traffic to the
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given file. The file will be periodically overwritten with new data.
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2020-06-30 15:38:48 +00:00
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*--statsd-server <server>*::
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If set, periodically send statistics on current traffic and some important
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events to the given statsd server (host:port).
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*--statsd-prefix <prefix>*::
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Sets the prefix to use for all statsd entries. [default: **vpncloud**]
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2020-06-03 15:42:43 +00:00
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*--daemon*::
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Spawn a background process instead of running the process in the foreground.
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If this flag is set, the process will first carry out all the
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initialization, then drop permissions if *--user* or *--group* is used and
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then spawn a background process and write its process id to a file if
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*--pid-file* is set. Then, the main process will exit and the background
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process continues to provide the VPN. At the time, when the main process
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exits, the interface exists and is properly configured to be used.
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*--no-port-forwarding*::
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Disable automatic port forward. If this option is not set, VpnCloud tries to
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detect a NAT router and automatically add a port forwarding to it.
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*-v*, *--verbose*::
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Print debug information, including information for data being received and
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sent.
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*-q*, *--quiet*::
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Only print errors and warnings.
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*-h*, *--help*::
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Display the help.
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== DESCRIPTION
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*VpnCloud* is a simple VPN over UDP. It creates a virtual network interface on
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the host and forwards all received data via UDP to the destination. It can work
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in 3 different modes:
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*Switch mode*:: In this mode, the VPN will dynamically learn addresses
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as they are used as source addresses and use them to forward data to its
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destination. Addresses that have not been seen for some time
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(option *switch_timeout*) will be forgotten. Data for unknown addresses will be
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broadcast to all peers. This mode is the default mode for TAP devices that
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process Ethernet frames but it can also be used with TUN devices and IP
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packets.
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*Hub mode*:: In this mode, all data will always be broadcast to all peers.
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This mode uses lots of bandwidth and should only be used in special cases.
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*Router mode*:: In this mode, data will be forwarded based on preconfigured
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address ranges ("subnets"). Data for unknown nodes will be silently ignored.
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This mode is the default mode for TUN devices that work with IP packets but
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it can also be used with TAP devices and Ethernet frames.
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All connected VpnCloud nodes will form a peer-to-peer network and cross-connect
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automatically until the network is fully connected. The nodes will periodically
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exchange information with the other nodes to signal that they are still active
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and to allow the automatic cross-connect behavior. There are some important
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things to note:
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. To avoid that different networks that reuse each others addresses merge due
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to the cross-connect behavior, the *magic* option can be used and set
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to any unique string to identify the network. The *magic* must be the
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same on all nodes of the same VPN network.
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. The cross-connect behavior can be able to connect nodes that are behind
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firewalls or NATs as it can function as hole-punching.
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. The management traffic will increase with the peer number quadratically.
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It should still be reasonably small for high node numbers (below 10 KiB/s
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for 10.000 nodes). A longer *peer_timeout* can be used to reduce the traffic
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further. For high node numbers, router mode should be used as it never
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broadcasts data.
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VpnCloud does not implement any loop-avoidance. Since data received on the UDP
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socket will only be sent to the local network interface and vice versa, VpnCloud
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cannot produce loops on its own. On the TAP device, however STP data can be
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transported to avoid loops caused by other network components.
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For TAP devices, IEEE 802.1q frames (VLAN tagged) are detected and forwarded
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based on separate MAC tables. Any nested tags (Q-in-Q) will be ignored.
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== EXAMPLES
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=== Switched TAP scenario
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In the example scenario, a simple layer 2 network tunnel is established. Most
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likely those commands need to be run as *root* using *sudo*.
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First, VpnCloud need to be started on both nodes (the address after *-c* is the
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address of the remote node and the the *X* in the interface address must be
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unique among all nodes, e.g. 0, 1, 2, ...):
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----
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vpncloud -c REMOTE_HOST:PORT --ifup 'ifconfig $IFNAME 10.0.0.X/24 mtu 1400 up'
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----
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Afterwards, the interface can be used to communicate.
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=== Routed TUN example
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In this example, 2 nodes and their subnets should communicate using IP.
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First, VpnCloud need to be started on both nodes:
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----
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vpncloud -t tun -c REMOTE_HOST:PORT --subnet 10.0.X.0/24 --ifup 'ifconfig $IFNAME 10.0.X.1/16 mtu 1400 up'
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----
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It is important to configure the interface in a way that all addresses on the
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VPN can be reached directly. E.g. if subnets 10.0.1.0/24, 10.0.2.0/24 and so on
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are used, the interface needs to be configured as 10.0.1.1/16.
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For TUN devices, this means that the prefix length of the subnets
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(/24 in this example) must be different than the prefix length that the
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interface is configured with (/16 in this example).
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=== Important notes
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. VpnCloud can be used to connect two separate networks. TAP networks can be
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bridged using *brctl* and TUN networks must be routed. It is very important
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to be careful when setting up such a scenario in order to avoid network loops,
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security issues, DHCP issues and many more problems.
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. TAP devices will forward DHCP data. If done intentionally, this can be used
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to assign unique addresses to all participants. If this happens accidentally,
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it can conflict with DHCP servers of the local network and can have severe
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side effects.
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. VpnCloud is not designed for high security use cases. Although the used crypto
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primitives are expected to be very secure, their application has not been
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reviewed.
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2020-06-09 07:03:52 +00:00
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The shared key is hashed using _PBKDF2_HMAC_SHA256_ to derive a key,
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which is used to encrypt the payload of messages using _ChaCha20Poly1305_,
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_AES128-GCM_, or _AES256-GCM_. The encryption includes an authentication that
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also protects the header.
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2020-06-03 15:42:43 +00:00
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This method does only protect against attacks on single messages but not
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against attacks that manipulate the message series itself (i.e. suppress
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messages, reorder them, or duplicate them).
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== CONFIG FILES
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The config file is a YAML file that contains configuration values. All entries
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are optional and override the defaults. Please see the section *OPTIONS* for
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detailed descriptions of the options.
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*device_type*:: Set the type of network. Same as *--type*
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*device_name*:: Name of the virtual device. Same as *--device*
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*device_path*:: Set the path of the base device. Same as *--device-path*
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*ifup*:: A command to setup the network interface. Same as *--ifup*
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*ifdown*:: A command to bring down the network interface. Same as *--ifdown*
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*crypto*:: The encryption method to use. Same as *--crypto*
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*shared_key*:: The shared key to encrypt all traffic. Same as *--shared-key*
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*magic*:: Override the 4-byte magic header of each packet. Same as *--magic*
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*port*:: A port number to listen on. This option is DEPRECATED.
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*listen*:: The address on which to listen for data. Same as *--listen*
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*peers*:: A list of addresses to connect to. See *--connect*
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*peer_timeout*:: Peer timeout in seconds. Same as**--peer-timeout**
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*beacon_store*:: Path or command to store beacons. Same as *--beacon-store*
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*beacon_load*:: Path or command to load beacons. Same as *--beacon-load*
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*beacon_interval*:: Interval for loading and storing beacons in seconds. Same as *--beacon-interval*
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*mode*:: The mode of the VPN. Same as *--mode*
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*switch_timeout*:: Switch table entry timeout in seconds. Same as *--dst-timeout*
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*subnets*:: A list of local subnets to use. See *--subnet*
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*port_forwarding*:: Whether to activate port forwardig. See *--no-port-forwarding*
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*user*:: The name of a user to run the background process under. Same as *--user*
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*group*:: The name of a group to run the background process under. Same as *--group*
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*pid_file*:: The path of the pid file to create. Same as *--pid-file*
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*stats_file*:: The path of the statistics file. Same as *--stats-file*
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*statsd_server*:: Server to report statistics to. Same as *--statsd-server*
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*statsd_prefix*:: Prefix to use when reporting to statsd. Same as *--statsd-prefix*
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=== Example
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device_type: tun
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device_name: vpncloud%d
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ifup: ifconfig $IFNAME 10.0.1.1/16 mtu 1400 up
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crypto: aes256
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shared_key: mysecret
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listen: 3210
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peers:
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- remote.machine.foo:3210
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- remote.machine.bar:3210
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peer_timeout: 600
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mode: normal
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subnets:
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- 10.0.1.0/24
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port_forwarding: true
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user: nobody
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group: nogroup
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pid_file: /run/vpncloud.pid
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== BEACONS
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Beacons are short character sequences that contain a timestamp and a list of
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addresses. They can be published and retrieved by other nodes to find peers
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without the need for static addresses.
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The beacons are short (less than 100 characters), encrypted and encoded with
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printable characters to allow publishing them in various places on the
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internet, e.g.:
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* On shared drives or synchronized folders (e.g. on Dropbox)
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* Via a dedicated database
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* Via a general purpose message board of message service (e.g. Twitter)
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The beacons are very robust. They only consist of alphanumeric characters
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and can be interleaved with non-alphanumeric characters (e.g. whitespace).
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Also the beacons contain a prefix and suffix that depends on the configured
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network magic and secret key (if set) so that all nodes can find beacons in
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a long text.
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When beacons are stored or loaded via a command (using the pipe character *|*),
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the command is interpreted using the configured shell *sh*. This command has
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access to the following environment variables:
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*$begin*:: The prefix of the beacon.
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*$end*:: The suffix of the beacon.
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*$data* (only on store):: The middle part of the beacon. Do not use this
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without prefix and suffix!
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*$beacon* (only on store):: The full beacon consisting of prefix, data and
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suffix.
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The commands are called in separate threads, so even longer running commands
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will not block the node.
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2020-06-30 15:38:48 +00:00
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== STATSD SUPPORT
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When a statsd server is configured (either via **--statsd-server** or the
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config option **statsd_server**), VpnCloud sends out the following statistics
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every minute.
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Gauge values:
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*peer_count*:: Current number of peers
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*table_entries*:: Number of routing table / switch table entries
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The following statistics consist of two keys: *.bytes* and *.packets* that hold
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the values in bytes and packets. All values refer to the traffic during the
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last minute:
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*traffic.protocol.inbound*:: Complete incoming traffic with all peers
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*traffic.protocol.outbound*:: Complete outgoing traffic with all peers
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*traffic.payload.inbound*:: Incoming payload traffic with all peers
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*traffic.payload.outbound*:: Outgoing payload traffic with all peers
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*invalid_protocol_traffic*:: Invalid incoming protocol traffic
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*dropped_payload*:: Outgoing traffic that could not be routed
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All keys are prefixed by a common prefix. The prefix defaults to *vpncloud* but
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can be changed via **--statsd-prefix** or the config option **statsd_prefix**.
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2020-06-03 15:42:43 +00:00
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== NETWORK PROTOCOL
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The protocol of VpnCloud is kept as simple as possible to allow other
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|
implementations and to maximize the performance.
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Every packet sent over UDP contains the following header (in order):
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4 bytes *magic*::
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|
This field is used to identify the packet and to sort out packets that do
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|
|
not belong. The default is *[0x76, 0x70, 0x6e, 0x01]* ("vpn\x01").
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|
This field can be used to identify VpnCloud packets and might be set to
|
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|
|
something different to hide the protocol.
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|
|
1 byte *crypto method*::
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|
This field specifies the method that must be used to decrypt the rest of the
|
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|
|
data. The currently supported methods are:
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|
** Method *0*, *No encryption*: Rest of the data can be read without
|
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|
|
decrypting it.
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** Method *1*, *ChaCha20*: The header is followed by a 12 byte
|
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|
|
_nonce_. The rest of the data is encrypted with the
|
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|
|
*libsodium::crypto_aead_chacha20poly1305_ietf* method, using the 8 byte
|
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|
|
header as additional data.
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** Method *2*, *AES256*: The header is followed by a 12 byte _nonce_.
|
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|
|
The rest of the data is encrypted with the
|
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|
|
*libsodium::crypto_aead_aes256gcm* method, using the 8 byte header
|
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|
|
as additional data.
|
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|
|
2 *reserved bytes*::
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|
|
that are currently unused and set to 0
|
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|
|
1 byte for the *message type*::
|
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|
|
This byte specifies the type of message that follows. Currently the
|
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|
|
following message types are supported:
|
|
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|
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|
|
** Type 0: Data packet
|
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|
|
** Type 1: Peer list
|
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|
|
** Type 2: Initial message
|
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|
|
** Type 3: Closing message
|
|
|
|
|
|
|
|
After this 8 byte header, the rest of the message follows. It is encrypted using
|
|
|
|
the method specified in the header.
|
|
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|
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|
|
In the decrypted data, the message as specified in the *message type* field
|
|
|
|
will follow:
|
|
|
|
|
|
|
|
*Data packet* (message type 0)::
|
|
|
|
This packet contains payload. The format of the data depends on the device
|
|
|
|
type. For TUN devices, this data contains an IP packet. For TAP devices it
|
|
|
|
contains an Ethernet frame. The data starts right after the header and ends
|
|
|
|
at the end of the packet.
|
|
|
|
If it is an Ethernet frame, it will start with the destination MAC and end
|
|
|
|
with the payload. It does not contain the preamble, SFD, padding, and CRC
|
|
|
|
fields.
|
|
|
|
*Peer list* (message type 1)::
|
|
|
|
This packet contains the peer list of the sender. The first byte after the
|
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|
|
switch byte contains the number of IPv4 addresses that follow.
|
|
|
|
After that, the specified number of addresses follow, where each address
|
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|
|
is encoded in 6 bytes. The first 4 bytes are the IPv4 address and the later
|
|
|
|
2 bytes are port number (both in network byte order).
|
|
|
|
After those addresses, the next byte contains the number of IPv6 addresses
|
|
|
|
that follow. After that, the specified number of addresses follow, where
|
|
|
|
each address is encoded in 18 bytes. The first 16 bytes are the IPv6 address
|
|
|
|
and the later 2 bytes are port number (both in network byte order).
|
|
|
|
*Initial message* (message type 2)::
|
|
|
|
This packet contains the following information:
|
|
|
|
** The stage of the initialization process
|
|
|
|
** A random node id to distinguish different nodes
|
|
|
|
** All the local subnets claimed by the nodes
|
|
|
|
|
|
|
|
+
|
|
|
|
Its first byte marks the stage of the initial handshake process.
|
|
|
|
The next 16 bytes contain the unique node id. After that,
|
|
|
|
the list of local subnets follows.
|
|
|
|
The subnet list is encoded in the following way: Its first byte of data
|
|
|
|
contains the number of encoded subnets that follow. After that, the given
|
|
|
|
number of encoded subnets follow.
|
|
|
|
For each subnet, the first byte is the length of bytes in the base address
|
|
|
|
and is followed by the given number of base address bytes and one additional
|
|
|
|
byte that is the prefix length of the subnet.
|
|
|
|
The addresses for the subnet will be encoded like they are encoded in their
|
|
|
|
native protocol (4 bytes for IPv4, 16 bytes for IPv6, and 6 bytes for a MAC
|
|
|
|
address) with the exception of MAC addresses in a VLan which will be encoded
|
|
|
|
in 8 bytes where the first 2 bytes are the VLan number in network byte order
|
|
|
|
and the later 6 bytes are the MAC address.
|
|
|
|
*Closing message* (message type 3)::
|
|
|
|
This packet does not contain any more data.
|
|
|
|
|
|
|
|
Nodes are expected to send an *initial message* with stage 0 whenever they
|
|
|
|
connect to a node they were not connected to before. As a reply to this message,
|
|
|
|
another initial should be sent with stage 1. Also a *peer list* message should
|
|
|
|
be sent as a reply.
|
|
|
|
|
|
|
|
When connected, nodes should periodically send their *peer list* to all
|
|
|
|
of their peers to spread this information and to avoid peer timeouts.
|
|
|
|
To avoid the cubic growth of management traffic, nodes should at a certain
|
|
|
|
network size start sending partial peer lists instead of the full list. A
|
|
|
|
reasonable number would be about 20 peers. The subsets should be selected
|
|
|
|
randomly.
|
|
|
|
|
|
|
|
Nodes should remove peers from their peer list after a certain period of
|
|
|
|
inactivity or when receiving a *closing message*. Before shutting down, nodes
|
|
|
|
should send the closing message to all of their peers in order to avoid
|
|
|
|
receiving further data until the timeout is reached.
|
|
|
|
|
|
|
|
Nodes should only add nodes to their peer list after receiving an initial
|
|
|
|
message from them instead of adding them right from the peer list of another
|
|
|
|
peer. This is necessary to avoid the case of a large network keeping dead nodes
|
|
|
|
alive.
|
|
|
|
|
|
|
|
== COPYRIGHT
|
|
|
|
|
|
|
|
Copyright (C) 2015-2020 Dennis Schwerdel
|
|
|
|
This software is licensed under GPL-3 or newer (see LICENSE.md)
|