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author | Dimitri Staessens <dimitri@ouroboros.rocks> | 2021-08-14 13:00:58 +0200 |
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committer | Dimitri Staessens <dimitri@ouroboros.rocks> | 2021-08-14 13:00:58 +0200 |
commit | 4624770b7ab1ab330cc634af689a1b5ca5e9f076 (patch) | |
tree | 11adc6e20b1f488f80122e35228fe4a1059c9210 /content/en/docs/Concepts | |
parent | a937f20da422f35accd5612da23b1887d802b7cb (diff) | |
download | website-4624770b7ab1ab330cc634af689a1b5ca5e9f076.tar.gz website-4624770b7ab1ab330cc634af689a1b5ca5e9f076.zip |
docs: Some additions to problem with OSI
Diffstat (limited to 'content/en/docs/Concepts')
-rw-r--r-- | content/en/docs/Concepts/problem_osi.md | 98 |
1 files changed, 64 insertions, 34 deletions
diff --git a/content/en/docs/Concepts/problem_osi.md b/content/en/docs/Concepts/problem_osi.md index 20ddb9a..2d09102 100644 --- a/content/en/docs/Concepts/problem_osi.md +++ b/content/en/docs/Concepts/problem_osi.md @@ -94,49 +94,79 @@ layers of OSI as an "application layer". ### Some issues with these models -However, when looking at current networking solutions in more depth, -things are not as simple as these 5/7 layers seem to -indicate. Consider, for instance, __Virtual Private Network__ (VPN) -technologies and SSH __tunnels__. We are all familiar enough with this -kind of technologies to take them for granted. But a VPN, such as -openVPN, creates a new network on top of IP, for instance a layer 2 -network over TAP interfaces supported by a Layer 4 (using, for -instance Transport Layer Security) connection to the VPN server. -Technologies such as VPNs and various so-called _tunnels_ seriously -jumble around the layers in this layered model. - -Which protocol fits in which layer is also not clear-cut. - -Multi-Protocol Label switching MPLS, a technology that makes IP -networks more ATM-like, and allows establishing and managing fixed -paths (circuits), typically sits in between Layer 2 and IP and is -categorized as a Layer 2.5 technology. +When looking at current networking solutions in more depth, +things are not as simple as these 5/7 layers seem to indicate. + +#### The order of the layers is not fixed. + +Consider, for instance, __Virtual Private Network__ (VPN) technologies +and SSH __tunnels__. We are all familiar enough with this kind of +technologies to take them for granted. But a VPN, such as openVPN, +creates a new network on top of IP. In _bridging_ mode this is a Layer +2 (Ethernet) network over TAP interfaces, in _routing_ mode this is a +Layer 3 (IP) network over TUN interfaces. In both cases they are +supported by a Layer 4 connection (using, for instance Transport Layer +Security) to the VPN server that provides the network +access. Technologies such as VPNs and various so-called _tunnels_ +seriously jumble around the layers in this layered model. + +#### How many layers are there exactly? + +Multi-Protocol Label switching (MPLS), a technology that allows +operators to establish and manage circuit-like paths in IP networks, +typically sits in between Layer 2 and IP and is categorized as a +_Layer 2.5_ technology. So are there 8 layers? Why not revise the +model and number them 1-8 then? QUIC is a protocol that performs transport-layer functions such as retransmission, flow control and congestion control, but works around the initial performance bottleneck after starting a TCP connection (3-way handsake, slow start) and some other optimizations dealing with re-establishing connections for which security keys are known. But -QUIC runs on top of UDP. If UDP is layer 4, then what layer is QUIC? +QUIC runs on top of UDP. If UDP is Layer 4, then what layer is QUIC? + +One could argue that UDP is an incomplete Layer 4 protocol and QUIC +adds its missing Layer 4 functionalities. Fair enough, but then what +is the minimum functionality for each of the protocols? Layer 2 +protocol? What is the minimum function of a Layer 3 protocol? And a +Layer 4 protocol? + +#### Which protocol fits in which layer is not clear-cut. + +There are a whole slew of protocols that are situated in Layer 3: +ICMP, SNMP... They don't really need the features that Layer 4 +provides (retransmission, ...). But again, they run on _top of Layer +3_ (IP). They get assigned a protocol number in the IP field, instead +of a port number in the UDP header. But doesn't a Layer 3 protocol +number indicate a Layer 4 protocol? Apparently only in some cases, but +not in others. The Border Gateway Protocol (BGP) performs (inter-domain) routing. Routing is a function that is usually associated with Layer -3. But BGP runs on top of TCP, which is Layer 4. There is no real -concensus of what layer BGP is in, some say Layer 3, some (probably -most) say Layer 4, because it is using TCP, and some say it's -application layer. But the concensus does seem to be that the BGP -conundrum doesn't matter. BGP works, and the OSI and TCP/IP models are -_just theoretical models_, not _rules_ that are set in stone. - +3. But BGP runs on top of TCP, which is Layer 4, so is it in the +application layer? There is no real concensus of what layer BGP is in, +some say Layer 3, some (probably most) say Layer 4, because it is +using TCP, and some say it's application layer. But the concensus does +seem to be that the BGP conundrum doesn't matter. BGP works, and the +OSI and TCP/IP models are _just theoretical models_, not _rules_ that +are set in stone. ### Are these issues _really_ a problem? -Well, in my opinion: yes! And _big_ ones too! If there is no -universally valid theoretical model, if we have no clear definitions -of the fundamental concepts and no clearly defined set of rules that -unequivocally lay out what the _necessary and sufficient conditions -for networking_ are, then we are all just _engineering in the dark_. -Progress in developing computer networks is condemned to a sisyphean -effort of perpetual incremental fixes, its fate to remain a craft that -builds on tradition, cobbling together an ever-growing bungle of -technologies and protocols that stretches the limits of manageability. +Well, in my opinion: yes! These models have no predictive value and +don't even fit with observation of the real-world Internet most of us +use every day. They are about as arbitrary as a seven-course tasting +menu of home-grown vegetables. Their only uses are as technobabble for +network engineers and as tools for university professors to gauge +their students' ability to retain a moderate amount of +pseudoscientific dribble. + +If there is no universally valid theoretical model, if we have no +clear definitions of the fundamental concepts and no clearly defined +set of rules that unequivocally lay out what the _necessary and +sufficient conditions for networking_ are, then we are all just +_engineering in the dark_, progress in developing computer networks +condemned to a sisyphean effort of perpetual incremental fixes, its +fate to remain a craft that builds on tradition, cobbling together an +ever-growing bungle of technologies and protocols that stretch the +limits of manageability. |