mirror of https://github.com/LeOS-GSI/LeOS-Genesis
325 lines
14 KiB
Groff
325 lines
14 KiB
Groff
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.TH badvpn 7 "6 October 2010"
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.SH NAME
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BadVPN - peer-to-peer VPN system
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.SH DESCRIPTION
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.P
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BadVPN is a peer-to-peer VPN system. It provides a Layer 2 (Ethernet) network between
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the peers (VPN network nodes). The peers connect to a central server which acts as a chat
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server for them to establish direct connections between each other (data connections).
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These connections are used for transferring network data (Ethernet frames).
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.SS "Features"
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.P
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.B "Data connections"
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.P
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Peers can transfer network data either over UDP or TCP. For both there are ways of
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securing the data (see below).
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.P
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.B "IPv6 support"
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.P
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IPv6 can be used for both server connections and data connections, alongside with IPv4.
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Additionally, both can be combined to allow gradual migration to IPv6.
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.P
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.B "Address selection"
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.P
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Because NATs and firewalls are widespread, it is harder for peer-to-peer services to operate.
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In general, for two computers to be able to communicate, one computer must
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.I bind
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to one of its addresses, and the other computer must
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.I connect
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to the computer that binded (both for TCP and UDP). In a network with point-to-point
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connectivity, the connecting computer can connect to the same address as the binding computer
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bound to, so it is sufficient for the binding computer to send its address to the connecting
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computer. However, NATs and firewalls break point-to-point connectivity. When a network is
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behind a NAT, it is, by default, impossible for computers outside of that network to connect
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to computers inside the network. This is because computers inside the network have no externally
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visible IP address, and only communicate with the outside world through the external IP address
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of the NAT router. It is however possible to manually configure the NAT router to
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.I forward
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a specific port number on its external IP address to a specific computer inside the network.
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This makes it possible for a computer outside of the network to connect to a computer inside
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a network, however, it must connect to the external address of the NAT router (rather than
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the address the computer inside bound to, which is its internal address). So there needs
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to be some way for the connecting peer to know what address to connect to.
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.P
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BadVPN solves this problem with so-called
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.IR "address scopes" "."
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The peer that binds must have a list of external addresses for each address it can bind to,
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possibly ordered from best to worst. Each external address has its scope name. A scope name
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represents part of a network from which an external address can be reached. On the other hand,
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the peer that connects must have a list of scopes which it can reach. When a peer binds to an
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address, it sends the other peer a list of external addresses along with scope names. That peer
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than chooses the first external address whose scope it recognizes and attempts to connect to it
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(if there is one).
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.P
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BadVPN also allows a peer to have multiple addresses for binding to. It is possible to specify
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both an IPv4 and an IPv6 address to work in a multi-protocol environment.
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.P
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.B "Relaying"
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.P
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BadVPN can be configured to allow pairs of peers that cannot communicate directly (i.e. because of
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NATs or firewalls) to relay network data through a third peer. Relaying is only attempted if
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none of the two peers recognize any of the other peer's external addresses (or there are none).
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For relaying to work, for each of the two peers (P1, other one P2) there must be at least one
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third peer (R) that P1 it is allowed to relay through and can communicate directly with, and all
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such peers R must be able to communicate directly with P2.
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.P
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.B "IGMP snooping"
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.P
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BadVPN nodes perform IGMP snooping in order to efficiently deliver multicast frames. For example,
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this makes it possible to use BadVPN as a tunnel into an IPTV network of an Internet Service Provider
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for you to watch TV from wherever you want (given sufficient link quality).
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.P
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.B "Code quality"
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.P
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BadVPN has great focus on code quality and reliability. BadVPN is written in the C programming
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language. It is a single-threaded event-driven program. This allows for low resource usage and
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fast response times. Even though C is a relatively low-level language, the programs are made of
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small, highly cohesive and loosely coupled modules that are combined into a complete program on
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a high level. Modules are accesed and communicate through small, simple and to-the-point interfaces.
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It utilizes a flow-based design which greatly simplifies processing of data and input and output
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of the programs.
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.SS "Security features"
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.P
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BadVPN contains many security features, all of which are optional. The included security
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features are described here.
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.P
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.B TLS for client-server connections
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.P
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It is possible for the peers to communicate with the chat server securely with TLS. It is
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highly recommended that this feature is used if any security whatsoever is needed. Not
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using it renders all other security features useless, since clients exchange keys
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unencrypted via the server. When enabled, the chat server requires each client to identify
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itself with a certificate.
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.P
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BadVPN uses Mozilla's NSS library for TLS support. This means that the required certificates
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and keys must be available in a NSS database. The database and certificates can be
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generated with the
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.B certutil
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command. See the examples section on how to generate and distribute the certificates.
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.P
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.B TLS for peer messaging
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.P
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If TLS is being used for client-server connections, it will also be used between each pair of
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peers communicating via the server, on top of the TLS connections to the server. This secures
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the messages from the server itself. It is important because the messages may include
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encryption keys and other private data.
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.P
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.B TLS for TCP data connections
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.P
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If TCP is used for data connections between the peers, the data connections can be secured
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with TLS. This requires using TLS for client-server connections. The clients need to trust
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each others' certificates to be able to connect. Additionally, each client must identify to
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its peers with the same certificates it used for connecting to the server.
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.P
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.B Encryption for UDP data connections
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.P
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If UDP is used for data connections, it is possible for each pair of peers to encrypt their
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UDP packets with a symmetric block cipher. Note that the encryption keys are transmitted
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through the server unencrypted, so for this to be useful, server connections must be secured
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with TLS. The encryption aims to prevent third parties from seeing the real contents of
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the network data being transfered.
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.P
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.B Hashes for UDP data connections
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.P
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If UDP is used for data connections, it is possible to include hashes in packets. Note that
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hashes are only useful together with encryption. If enabled, the hash is calculated on the
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packet with the hash field zeroed and then written to the hash field. Hashes are calculated
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and included before encryption (if enabled). Combined with encryption, hashes aim to prevent
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third parties from tampering with the packets and injecting them into the network.
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.P
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.B One-time passwords for UDP data connections
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.P
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If UDP is used for data connections, it is possible to include one-time passwords in packets.
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Note that for this to be useful, server connections must be secured with TLS.
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One-time passwords are generated from a seed value by encrypting zero data with a block cipher.
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The seed contains the encryption key for the block cipher and the initialization vector.
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Only a fixed number of passwords are used from a single seed. The peers exchange seeds through
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the server. One-time passwords aim to prevent replay attacks.
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.P
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.B Control over peer communication
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.P
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It is possible to instruct the chat server to only allow certain peers to communicate. This
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will break end-to-end connectivity in the virtual network. It is useful in certain cases
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to improve security, for example when the VPN is used only to allow clients to securely connect
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to a central service.
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.SH "EXAMPLES"
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.SS "Setting up certificates"
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.P
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If you want to use TLS for server connections (recommended), the server and all the peers will
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need certificates. This section explains how to generate and distribute the certificates using
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NSS command line tools.
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.P
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.B Setting up the Certificate Authority (CA)
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.P
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On the system that will host the CA, create a NSS database for the CA and generate a CA certificate
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valid for 24 months:
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.P
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vpnca $ certutil -d sql:/home/vpnca/nssdb -N
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.br
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vpnca $ certutil -d sql:/home/vpnca/nssdb -S -n "vpnca" -s "CN=vpnca" -t "TC,," -x -2 -v 24
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.br
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> Is this a CA certificate [y/N]? y
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.br
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> Enter the path length constraint, enter to skip [<0 for unlimited path]: > -1
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.br
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> Is this a critical extension [y/N]? n
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.P
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Export the public CA certificate (this file is public):
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.P
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vpnca $ certutil -d sql:/home/vpnca/nssdb -L -n vpnca -a > ca.pem
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.P
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.B Setting up the server certificate
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.P
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On the CA system, generate a certificate for the server valid for 24 months, with TLS server usage context:
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.P
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vpnca $ certutil -d sql:/home/vpnca/nssdb -S -n "<insert_server_name>" -s "CN=<insert_server_name>" -c "vpnca" -t ",," -2 -6 -v 24
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.br
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> 0
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.br
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> -1
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.br
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> Is this a critical extension [y/N]? n
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.br
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> Is this a CA certificate [y/N]? n
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.br
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> Enter the path length constraint, enter to skip [<0 for unlimited path]: >
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.br
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> Is this a critical extension [y/N]? n
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.P
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Export the server certificate to a PKCS#12 file (this file must be kept secret):
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.P
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vpnca $ pk12util -d sql:/home/vpnca/nssdb -o server.p12 -n "<insert_server_name>"
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.P
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On the system that will run the server, create a NSS database and import the CA certificate
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and the server cerificate:
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.P
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vpnserver $ certutil -d sql:/home/vpnserver/nssdb -N
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.br
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vpnserver $ certutil -d sql:/home/vpnserver/nssdb -A -t "CT,," -n "vpnca" -i /path/to/ca.pem
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.br
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vpnserver $ pk12util -d sql:/home/vpnserver/nssdb -i /path/to/server.p12
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.P
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.B Setting up peer certificates
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.P
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On the CA system, generate a certificate for the peer valid for 24 months, with TLS client and
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TLS server usage contexts:
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.P
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vpnca $ certutil -d sql:/home/vpnca/nssdb -S -n "peer-<insert_name>" -s "CN=peer-<insert_name>" -c "vpnca" -t ",," -2 -6 -v 24
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.br
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> 0
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.br
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> 1
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.br
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> -1
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.br
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> Is this a critical extension [y/N]? n
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.br
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> Is this a CA certificate [y/N]? n
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.br
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> Enter the path length constraint, enter to skip [<0 for unlimited path]: >
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.br
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> Is this a critical extension [y/N]? n
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.P
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Export the peer certificate to a PKCS#12 file (this file must be kept secret):
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.P
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vpnca $ pk12util -d sql:/home/vpnca/nssdb -o peer-<insert_name>.p12 -n "peer-<insert_name>"
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.P
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On the system that will run the VPN client, create a NSS database and import the CA certificate
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and the peer cerificate:
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.P
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vpnclient $ certutil -d sql:/home/vpnclient/nssdb -N
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.br
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vpnclient $ certutil -d sql:/home/vpnclient/nssdb -A -t "CT,," -n "vpnca" -i /path/to/ca.pem
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.br
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vpnclient $ pk12util -d sql:/home/vpnclient/nssdb -i /path/to/peer-<insert_name>.p12
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.SS "Setting up TAP devices"
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.P
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You need to create and configure TAP devices on all computers that will participate in the virtual network
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(i.e. run the client program). See
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.BR badvpn-client (8),
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section `TAP DEVICE CONFIGURATION` for details.
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.SS "Example: Local IPv4 network, UDP transport, zero security"
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.P
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.B Starting the server:
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.P
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badvpn-server --listen-addr 0.0.0.0:7000
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.P
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.B Starting the peers:
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.P
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badvpn-client
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.RS
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--server-addr <insert_server_local_address>:7000
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.br
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--transport-mode udp --encryption-mode none --hash-mode none
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.br
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--scope local1
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.br
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--bind-addr 0.0.0.0:8000 --num-ports 30 --ext-addr {server_reported}:8000 local1
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.br
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--tapdev tap0
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.RE
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.SS "Example: Adding TLS and UDP security"
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.P
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.B Starting the server (other options as above):
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.P
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badvpn-server ...
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.RS
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--ssl --nssdb sql:/home/vpnserver/nssdb --server-cert-name "<insert_server_name>"
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.RE
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.P
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.B Starting the peers (other options as above):
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.P
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badvpn-client ...
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.RS
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--ssl --nssdb sql:/home/vpnclient/nssdb --client-cert-name "peer-<insert_name>"
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.br
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--encryption-mode blowfish --hash-mode md5 --otp blowfish 3000 2000
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.RE
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.SS "Example: Multiple local networks behind NATs, all connected to the Internet"
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.P
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For each peer in the existing local network, configure the NAT router to forward its
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range of ports to it (assuming their port ranges do not overlap). The clients also need
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to know the external IP address of the NAT router. If you don't have a static one,
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you'll need to discover it before starting the clients. Also forward the server port to
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the server.
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.P
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.B Starting the peers in the local network (other options as above):
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.P
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badvpn-client
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.RS
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.RB "..."
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.br
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--scope internet
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.br
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.RB "..."
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.br
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--ext-addr <insert_NAT_routers_external_IP>:<insert_start_of_forwarded_port_range> internet
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.br
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.RB "..."
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.RE
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.P
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The --ext-addr option applies to the previously specified --bind-addr option, and must come after
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the first --ext-addr option which specifies a local address.
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.P
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Now perform a similar setup in some other local network behind a NAT. However:
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.br
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- Don't set up a new server, instead make the peers connect to the existing server in the first
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local network.
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.br
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- You can't use {server_reported} for the local address --ext-addr options, because the server
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would report the NAT router's external address rather than the peer's internal address. Instead
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each peer has to know its internal IP address.
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.br
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- Use a different scope name for it, e.g. "local2" instead of "local1".
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.P
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If setup correctly, all peers will be able to communicate: those in the same local network will
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communicate directly through local addresses, and those in different local networks will
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communicate through the Internet.
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.SH "PROTOCOL"
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The protocols used in BadVPN are described in the source code in the protocol/ directory.
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.SH "SEE ALSO"
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.BR badvpn-server (8),
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.BR badvpn-client (8)
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.SH AUTHORS
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Ambroz Bizjak <ambrop7@gmail.com>
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