From 7b329bcdecfd820db98f015fbdd670c49dbdc777 Mon Sep 17 00:00:00 2001
From: Sander Vrijders <sander@ouroboros.rocks>
Date: Tue, 19 Feb 2019 11:48:45 +0100
Subject: Initial commit

This adds the initial files for the website, powered by Hugo.

Signed-off-by: Sander Vrijders <sander@ouroboros.rocks>
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+---
+title: "Tutorial 1: local test"
+draft: false
+---
+
+This tutorial runs through the basics of Ouroboros. Here, we will see
+the general use of two core components of Ouroboros, the IPC Resource
+Manager daemon (IRMd) and an IPC Process (IPCP).
+
+![Tutorial 1 setup](/images/ouroboros_tut1_overview.png)
+
+We will start the IRMd, create a local IPCP, start a ping server and
+connect a client. This will involve **binding (1)** that server to a
+name and **registering (2)** that name into the local layer. After that
+the client will be able to **allocate a flow (3)** to that name for
+which the server will respond.
+
+We recommend to open 3 terminal windows for this tutorial. In the first
+window, start the IRMd (as a superuser) in stdout mode. The output shows
+the process id (pid) of the IRMd, which will be different on your
+machine.
+
+```
+$ sudo irmd --stdout
+==02301== irmd(II): Ouroboros IPC Resource Manager daemon started\...
+```
+
+The type of IPCP we will create is a "local" IPCP. The local IPCP is a
+kind of loopback interface that is native to Ouroboros. It implements
+all the functions that the Ouroboros API provides, but only for a local
+scope. The IPCP create function will instantiate a new local IPC
+process, which in our case has pid 2324. The "ipcp create" command
+merely creates the IPCP. At this point it is not a part of a layer. We
+will also need to bootstrap this IPCP in a layer, we will name it
+"local_layer". As a shortcut, the bootstrap command will
+automatically create an IPCP if no IPCP by than name exists, so in this
+case, the IPCP create command is optional. In the second terminal, enter
+the commands:
+
+```
+$ irm ipcp create type local name local_ipcp
+$ irm ipcp bootstrap type local name local_ipcp layer local_layer
+```
+
+The IRMd and ipcpd output in the first terminal reads:
+
+```
+==02301== irmd(II): Created IPCP 2324.
+==02324== ipcpd-local(II): Bootstrapped local IPCP with pid 2324.
+==02301== irmd(II): Bootstrapped IPCP 2324 in layer local_layer.
+```
+
+From the third terminal window, let's start our oping application in
+server mode ("oping --help" shows oping command line parameters):
+
+```
+$ oping --listen
+Ouroboros ping server started.
+```
+
+The IRMd will notice that an oping server with pid 10539 has started:
+
+```
+==02301== irmd(DB): New instance (10539) of oping added.
+==02301== irmd(DB): This process accepts flows for:
+```
+
+The server application is not yet reachable by clients. Next we will
+bind the server to a name and register that name in the
+"local_layer". The name for the server can be chosen at will, let's
+take "oping_server". In the second terminal window, execute:
+
+```
+$ irm bind proc 2337 name oping_server
+$ irm register name oping_server layer local_layer
+```
+
+The IRMd and IPCPd in terminal one will now acknowledge that the name is
+bound and registered:
+
+```
+==02301== irmd(II): Bound process 2337 to name oping_server.
+==02324== ipcpd-local(II): Registered 4721372d.
+==02301== irmd(II): Registered oping_server in local_layer as
+4721372d.
+```
+
+Ouroboros registers name not in plaintext but using a (configurable)
+hashing algorithm. The default hash is a 256 bit SHA3 hash. The output
+in the logs is truncated to the first 4 bytes in a HEX notation.
+
+Now that we have bound and registered our server, we can connect from
+the client. In the second terminal window, start an oping client with
+destination oping_server and it will begin pinging:
+
+```
+$ oping -n oping_server -c 5
+Pinging oping_server with 64 bytes of data:
+
+64 bytes from oping_server: seq=0 time=0.694 ms
+64 bytes from oping_server: seq=1 time=0.364 ms
+64 bytes from oping_server: seq=2 time=0.190 ms
+64 bytes from oping_server: seq=3 time=0.269 ms
+64 bytes from oping_server: seq=4 time=0.351 ms
+
+--- oping_server ping statistics ---
+5 SDUs transmitted, 5 received, 0% packet loss, time: 5001.744 ms
+rtt min/avg/max/mdev = 0.190/0.374/0.694/0.192 ms
+```
+
+The server will acknowledge that it has a new flow connected on flow
+descriptor 64, which will time out a few seconds after the oping client
+stops sending:
+
+```
+New flow 64.
+Flow 64 timed out.
+```
+
+The IRMd and IPCP logs provide some additional output detailing the flow
+allocation process:
+
+```
+==02324== ipcpd-local(DB): Allocating flow to 4721372d on fd 64.
+==02301== irmd(DB): Flow req arrived from IPCP 2324 for 4721372d.
+==02301== irmd(II): Flow request arrived for oping_server.
+==02324== ipcpd-local(II): Pending local allocation request on fd 64.
+==02301== irmd(II): Flow on port_id 0 allocated.
+==02324== ipcpd-local(II): Flow allocation completed, fds (64, 65).
+==02301== irmd(II): Flow on port_id 1 allocated.
+==02301== irmd(DB): New instance (2337) of oping added.
+==02301== irmd(DB): This process accepts flows for:
+==02301== irmd(DB): oping_server
+```
+
+First, the IPCPd shows that it will allocate a flow towards a
+destination hash "4721372d" (truncated). The IRMd logs that IPCPd 2324
+(our local IPCPd) requests a flow towards any process that is listening
+for "4721372d", and resolves it to "oping_server", as that is a
+process that is bound to that name. At this point, the local IPCPd has a
+pending flow on the client side. Since this is the first port_id in the
+system, it has port_id 0. The server will accept the flow and the other
+end of the flow gets port_id 1. The local IPCPd sees that the flow
+allocation is completed. Internally it sees the endpoints as flow
+descriptors 64 and 65 which map to port_id 0 and port_id 1. The IPCP
+cannot directly access port_ids, they are assigned and managed by the
+IRMd. After it has accepted the flow, the oping server enters
+flow_accept() again. The IRMd notices the instance and reports that it
+accepts flows for "oping_server".
+
+This concludes this first short tutorial. All running processes can be
+terminated by issuing a Ctrl-C command in their respective terminals or
+you can continue with the next tutorial.
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