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-rw-r--r--content/docs/tutorials/ovpn-tut.md217
-rw-r--r--content/docs/tutorials/tutorial-2.md17
2 files changed, 226 insertions, 8 deletions
diff --git a/content/docs/tutorials/ovpn-tut.md b/content/docs/tutorials/ovpn-tut.md
new file mode 100644
index 0000000..6db6812
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+---
+title: "Tutorial: How to create an encrypted IP tunnel"
+draft: false
+description: "ovpn"
+date: 2019-08-31
+#type: page
+draft: false
+---
+
+We recently added 256-bit ECDHE-AES encryption to Ouroboros (in the
+_be_ branch). This tutorial shows how to create an *encrypted IP
+tunnel* using the Ouroboros VPN (ovpn) tool, which exposes _tun_
+interfaces to inject Internet Protocol traffic into an Ouroboros flow.
+
+We'll first illustrate what's going on over an ethernet loopback
+adapter and then show how to create an encrypted tunnel between two
+machines connected over an IP network.
+
+<center> {{<figure
+class="w-80"
+src="/images/ovpn_tut.png">}}
+</center>
+
+We'll create an encrypted tunnel between IP addresses 127.0.0.3 /24 and
+127.0.0.8 /24, as shown in the diagram above.
+
+To run this tutorial, make sure that
+[openssl](https://www.openssl.org) is installed on your machine(s) and
+get the latest version of Ouroboros from the _be_ branch.
+
+```
+$ git clone --branch be https://ouroboros.rocks/git/ouroboros
+$ cd ouroboros
+$ mkdir build && cd build
+$ cmake ..
+$ make && sudo make install
+```
+
+# Encrypted tunnel over the loopback interface
+
+Open a terminal window and start ouroboros (add --stdout to log to
+stdout):
+
+```
+$ sudo irmd --stdout
+```
+
+To start, the network will just consist of the loopback adapter _lo_,
+so we'll create a layer _my\_layer_ consisting of a single ipcp-eth-dix
+named _dix_, register the name _my\_vpn_ for the ovpn server in
+_my\_layer_, and bind the ovpn binary to that name.
+
+```
+$ irm ipcp bootstrap type eth-dix name dix layer my_layer dev lo
+$ irm reg name my_vpn layer my_layer
+$ irm bind program ovpn name my_vpn
+```
+
+We can now start an ovpn server on 127.0.0.3. This tool requires
+superuser privileges as it creates a tun device.
+
+```
+$ sudo ovpn --ip 127.0.0.3 --mask 255.255.255.0
+```
+
+From another terminal, we can start an ovpn client to connect to the
+server (which listens to the name _my\_vpn_) and pass the --crypt
+option to encrypt the tunnel:
+
+```
+$ sudo ovpn -n my_vpn -i 127.0.0.8 -m 255.255.255.0 --crypt
+```
+
+The ovpn tool now created two _tun_ interfaces attached to the
+endpoints of the flow, and will act as an encrypted pipe for any
+packets sent to that interface:
+
+```
+$ ip a
+...
+6: tun0: <POINTOPOINT,MULTICAST,NOARP,UP,LOWER_UP> mtu 1500 qdisc fq_codel state UNKNOWN group default qlen 500
+ link/none
+ inet 127.0.0.3/24 scope host tun0
+ valid_lft forever preferred_lft forever
+ inet6 fe80::f81d:9038:9358:fdf4/64 scope link stable-privacy
+ valid_lft forever preferred_lft forever
+7: tun1: <POINTOPOINT,MULTICAST,NOARP,UP,LOWER_UP> mtu 1500 qdisc fq_codel state UNKNOWN group default qlen 500
+ link/none
+ inet 127.0.0.8/24 scope host tun1
+ valid_lft forever preferred_lft forever
+ inet6 fe80::c58:ca40:5839:1e32/64 scope link stable-privacy
+ valid_lft forever preferred_lft forever
+```
+
+To test the setup, we can tcpdump one of the _tun_ interfaces, and
+send some ping traffic into the other _tun_ interface.
+The encrypted traffic can be shown by tcpdump on the loopback interface.
+Open two more terminals:
+
+```
+$ sudo tcpdump -i tun1
+```
+
+```
+$ sudo tcpdump -i lo
+```
+
+and from another terminal, send some pings into the other endpoint:
+
+```
+$ ping 10.10.10.1 -i tun0
+```
+
+The tcpdump on the _tun1_ interface shows the ping messages arriving:
+
+```
+$ sudo tcpdump -i tun1
+[sudo] password for dstaesse:
+tcpdump: verbose output suppressed, use -v or -vv for full protocol decode
+listening on tun1, link-type RAW (Raw IP), capture size 262144 bytes
+13:35:20.229267 IP heteropoda > 10.10.10.1: ICMP echo request, id 3011, seq 1, length 64
+13:35:21.234523 IP heteropoda > 10.10.10.1: ICMP echo request, id 3011, seq 2, length 64
+13:35:22.247871 IP heteropoda > 10.10.10.1: ICMP echo request, id 3011, seq 3, length 64
+```
+
+while the tcpdump on the loopback shows the AES encrypted traffic that
+is actually sent on the flow:
+
+```
+$ sudo tcpdump -i lo
+tcpdump: verbose output suppressed, use -v or -vv for full protocol decode
+listening on lo, link-type EN10MB (Ethernet), capture size 262144 bytes
+13:35:20.229175 00:00:00:00:00:00 (oui Ethernet) > 00:00:00:00:00:00 (oui Ethernet), ethertype Unknown (0xa000), length 130:
+ 0x0000: 0041 0070 31f2 ae4c a03a 3e72 ec54 7ade .A.p1..L.:>r.Tz.
+ 0x0010: f2f3 1db4 39ce 3b62 d3ad c872 93b0 76c1 ....9.;b...r..v.
+ 0x0020: 4f76 b977 aa66 89c8 5c3c eedf 3085 8567 Ov.w.f..\<..0..g
+ 0x0030: ed60 f224 14b2 72d1 6748 b04a 84dc e350 .`.$..r.gH.J...P
+ 0x0040: d020 637a 6c2c 642a 214b dd83 7863 da35 ..czl,d*!K..xc.5
+ 0x0050: 28b0 0539 a06e 541f cd99 7dac 0832 e8fb (..9.nT...}..2..
+ 0x0060: 9e2c de59 2318 12e0 68ee da44 3948 2c18 .,.Y#...h..D9H,.
+ 0x0070: cd4c 58ed .LX.
+13:35:21.234343 00:00:00:00:00:00 (oui Ethernet) > 00:00:00:00:00:00 (oui Ethernet), ethertype Unknown (0xa000), length 130:
+ 0x0000: 0041 0070 4295 e31d 05a7 f9b2 65a1 b454 .A.pB.......e..T
+ 0x0010: 5b6f 873f 0016 16ea 7c83 1f9b af4a 0ff2 [o.?....|....J..
+ 0x0020: c2e6 4121 8bf9 1744 6650 8461 431e b2a0 ..A!...DfP.aC...
+ 0x0030: 94da f17d c557 b5ac 1e80 825c 7fd8 4532 ...}.W.....\..E2
+ 0x0040: 11b3 4c32 626c 46a5 b05b 0383 2aff 022a ..L2blF..[..*..*
+ 0x0050: e631 e736 a98e 9651 e017 7953 96a1 b959 .1.6...Q..yS...Y
+ 0x0060: feac 9f5f 4b02 c454 7d31 e66f 2d19 3eaf ..._K..T}1.o-.>.
+ 0x0070: a5c8 d77f ....
+13:35:22.247670 00:00:00:00:00:00 (oui Ethernet) > 00:00:00:00:00:00 (oui Ethernet), ethertype Unknown (0xa000), length 130:
+ 0x0000: 0041 0070 861e b65e 4227 5a42 0db4 8317 .A.p...^B'ZB....
+ 0x0010: 6a75 c0c1 94d0 de18 10e9 45f3 db96 997f ju........E.....
+ 0x0020: 7461 2716 d9af 124d 0dd0 b6a0 e83b 95e7 ta'....M.....;..
+ 0x0030: 9e5f e4e6 068f d171 727d ba25 55c7 168b ._.....qr}.%U...
+ 0x0040: 7aab 2d49 be53 1133 eab0 624a 5445 d665 z.-I.S.3..bJTE.e
+ 0x0050: ca5c 7a28 9dfa 58c2 e2fd 715d 4b87 246a .\z(..X...q]K.$j
+ 0x0060: f54c b8c8 5040 1c1b aba1 6107 39e7 604b .L..P@....a.9.`K
+ 0x0070: 5fb2 73ef
+```
+
+# Encrypted tunnel between two IP hosts connected to the Internet
+
+To create an encrypted tunnel between two Internet hosts, the same
+procedure can be followed. The only difference is that we need to use
+an ipcpd-udp on the end hosts connected to the ip address of the
+machine, and on the client side, add the MD5 hash for that name to the
+hosts file. The machines must have a port that is reachable from
+outside, the default is 3435, but this can be configured using the
+sport option.
+
+On both machines (fill in the correct IP address):
+
+```
+irm i b t udp n udp l my_layer ip <address>
+```
+
+On the server machine, bind and register the ovpn tool as above:
+
+```
+$ irm reg name my_vpn layer my_layer
+$ irm bind program ovpn name my_vpn
+```
+
+On the _client_ machine, add a DNS entry for the MD5 hash for "my_vpn"
+with the server IP address to /etc/hosts:
+
+```
+$ cat /etc/hosts
+# Static table lookup for hostnames.
+# See hosts(5) for details.
+
+...
+
+<server_ip> 2694581a473adbf3d988f56c79953cae
+
+```
+
+and you should be able to create the ovpn tunnel as above.
+
+On the server:
+
+```
+$ sudo ovpn --ip 127.0.0.3 --mask 255.255.255.0
+```
+
+And on the client:
+
+```
+$ sudo ovpn -n my_vpn -i 127.0.0.8 -m 255.255.255.0 --crypt
+```
+
+---
+
+Changelog:
+
+2018-08-31: Initial version. \ No newline at end of file
diff --git a/content/docs/tutorials/tutorial-2.md b/content/docs/tutorials/tutorial-2.md
index 392a659..c3925dc 100644
--- a/content/docs/tutorials/tutorial-2.md
+++ b/content/docs/tutorials/tutorial-2.md
@@ -3,18 +3,19 @@ title: "Tutorial 2: Adding a layer"
draft: false
---
-In this tutorial we will add a *normal layer* on top of the local layer.
-Make sure you have a local layer running. The network will look like
-this:
+In this tutorial we will add a __unicast layer__ on top of the local
+layer. Make sure you have a [local
+layer](/docs/tutorials/tutorial-1/) running. The network will look
+like this:
-![Tutorial 2 setup](/images/ouroboros_tut2_overview.png)
+![Tutorial 2 setup](/images/tut-2-1.jpg)
-Let's start adding the normal layer. We will first bootstrap a normal
-IPCP, with name "normal_1" into the "normal_layer" (using default
-options). In terminal 2, type:
+Let's start adding the unicast layer. We will first bootstrap a
+unicast IPCP, with name "U1" into the layer "U" (using
+default options). In terminal 2, type:
```
-$ irm ipcp bootstrap type normal name normal_1 layer normal_layer
+$ irm ipcp bootstrap type unicast name U1 layer U
```
The IRMd and IPCP will report the bootstrap: