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author | Dimitri Staessens <[email protected]> | 2019-07-25 14:58:49 +0200 |
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committer | Dimitri Staessens <[email protected]> | 2019-07-25 14:58:49 +0200 |
commit | 26b9913b8a6e3fb8998a8b0497d934524eea09f5 (patch) | |
tree | 7cd5931cdf4139cb2ba471ece1632f5f04f42262 /content | |
parent | 51dbad4bd693cdd5b3024e51a1891e181f192064 (diff) | |
download | website-26b9913b8a6e3fb8998a8b0497d934524eea09f5.tar.gz website-26b9913b8a6e3fb8998a8b0497d934524eea09f5.zip |
content: Replace screenshots of irm commands
The irm commands in the irmd section are now replaced by listings.
Diffstat (limited to 'content')
-rw-r--r-- | content/docs/irmd.md | 54 |
1 files changed, 35 insertions, 19 deletions
diff --git a/content/docs/irmd.md b/content/docs/irmd.md index ee43967..f6b60bd 100644 --- a/content/docs/irmd.md +++ b/content/docs/irmd.md @@ -7,9 +7,11 @@ date: 2019-07-23 draft: false --- -The most important structure in recursive networks are layers, that -are built op from [elements](/docs/elements/) called Inter-Process -Communication Processes (IPCPs). +The most important structure in recursive networks are the layers, +that are built op from [elements](/docs/elements/) called +Inter-Process Communication Processes (IPCPs). (Note again that the +layers in recursive networks are not the same as layers in the OSI +model). <center> {{<figure class="fl w-90" @@ -36,37 +38,51 @@ creating IPCPs of a given *type*. This just runs the process without any further configuration. At this point, that process is not part of any layer. -<center> -{{<figure class="c w-60" - src="/images/irm_ipcp_create.png">}} -</center> +``` +$ irm ipcp create type unicast name my_ipcp +$ irm ipcp list ++---------+----------------------+------------+----------------------+ +| pid | name | type | layer | ++---------+----------------------+------------+----------------------+ +| 7224 | my_ipcp | unicast | Not enrolled | ++---------+----------------------+------------+----------------------+ +``` The example above creates a unicast IPCP and gives that IPCP a name (we called it "my_ipcp"). A listing of the IPCPs in the system shows -that the IPCP is running as process 4157, and it is not part of a +that the IPCP is running as process 7224, and it is not part of a layer ("*Not enrolled*"). To create a new functioning network layer, we need to configure the IPCP, using a primitive called __bootstrapping__. Bootstrapping sets a -number of parameters for the layer (such as the routing algorithm to -use) and activates the IPCP to allow it to start providing flows. The -Ouroboros command line allows creating an IPCP with some default -values, that are a bit like a vanilla IPv4 network: 32-bit addresses -and shortest-path link-state routing. +number of configuration optionss for the layer (such as the routing +algorithm to use) and activates the IPCP to allow it to start +providing flows. The Ouroboros command line allows creating an IPCP +with some default values, that are a bit like a vanilla IPv4 network: +32-bit addresses and shortest-path link-state routing. -<center> -{{<figure class="c w-60" - src="/images/irm_ipcp_bootstrap.png">}} -</center> +``` +$ irm ipcp bootstrap name my_ipcp layer my_layer +$ irm ipcp list ++---------+----------------------+------------+----------------------+ +| pid | name | type | layer | ++---------+----------------------+------------+----------------------+ +| 7224 | my_ipcp | unicast | my_layer | ++---------+----------------------+------------+----------------------+ +``` -Now, we have a single node-network. In order to create a larger +Now we have a single node-network. In order to create a larger network, we connect and configure new IPCPs using a third primitive called __enrollment__. When enrolling an IPCP in a network, it will create a flow (using a lower layer) to an existing member of the layer, download the bootstrapping information, and use it to configure itself as part of this layer. -[TODO: enrollment example] +The final primitive is the __connect__ (and __disconnect__) +primitive. This allows to create *adjacencies* between network nodes. + +An example of how to create a small two-node network is given in +[tutorial 2](/docs/tutorials/tutorial-2/) --- Changelog: |