master-thesis/doc/Introduction.tex

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%** Introduction.tex: Contains an introduction to
% the topic and motivates the work.
% State what the reader can find where.
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%** Problem.tex: Documentation in own words of the problem to
% be addressed in this document:
% What is the challenge, why is it useful what you
% plan to do.
%% In \ref{introduction} we start with our introduction to the problem that we
%% are going to address. Since we do not want to waste the readers time we
%% go and show the essential issues of latex in section
%% \ref{chapter2:essentials}.
\chapter{\label{introduction}Introduction}
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In this chapter we give an introduction about the topic of the master
thesis, the motivation and problemes that we address. We explain the
current state of IPv4 exhaustion and IPv6 adoption and describe how
it motivates our work to support ease transition to IPv6 networks.
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% ----------------------------------------------------------------------
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\section{\label{introduction:ipv4ipv6}IPv4 exhaustion and IPv6 adoption}
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The Internet has almost completely run out of public IPv4 space. The
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5 Regional Internet Registries (RIRs) report IPv4 exhaustion world wide
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\cite{ripe_exhaustion},
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\cite{apnic_exhaustion},
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\cite{lacnic:_ipv4_deplet_phases},
\cite{afrinic:_afrin_ipv4_exhaus},
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\cite{arin:_ipv4_addres_option}.
Figure \ref{fig:riripv4rundown} contains summarised data from all RIRs
and projects complete IPv4 addresses depletion by 2021.
The LACNIC project even predicts complete exhaustion for 2020 as shown
in figure \ref{fig:lacnicexhaust}.
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\begin{figure}[h]
\includegraphics[scale=0.7]{lacnicdepletion}
\centering
\caption{LACNIC Exhaustion projection,
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~\cite{lacnic:_ipv4_deplet_phases}}
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\label{fig:lacnicexhaust}
\end{figure}
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\begin{figure}[h]
\includegraphics[scale=0.6]{rir-ipv4-rundown}
\centering
\caption{RIR IPv4 rundown projection from~\cite{huston:_ipv4_addres_repor}}
\label{fig:riripv4rundown}
\end{figure}
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On the other hand IPv6 adoption grows significantly, with at least
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three countries (India, US, Belgium) surpassing 50\%
adoption~\cite{akamai:_ipv6_adopt_visual},
\cite{vyncke:_ipv6_deploy_aggreg_status},
\cite{cisco:_ipv6}. Traffic from Google users reaches almost 30\% as
of 2019-08-08~\cite{google:_ipv6_googl}, see figure \ref{fig:googlev6}.
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\begin{figure}[h]
\includegraphics[scale=0.2]{googlev6}
\centering
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\caption{Google IPv6 Statistics from~\cite{google:_ipv6_googl}}
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\label{fig:googlev6}
\end{figure}
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We conclude that IPv6 is a technology strongly gaining importance with
the IPv4 depletion that is estimated to be world wide happening in the
next years. Thus more devices will be using IPv6, while communication
to legacy IPv4 devices still needs to be provided.
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% ok
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% ----------------------------------------------------------------------
\section{\label{introduction:motivation}Motivation}
IPv6 nodes and IPv4 nodes cannot directly connect to each other,
because the protocols are incompatible to each other.
To allow communication between different protocol nodes,
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several transition mechanism have been
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proposed~\cite{wikipedia:_ipv6},~\cite{rfc4213}.
\begin{figure}[h]
\includegraphics[scale=0.4]{v6-v6-separated}
\centering
\caption{Separated IPv6 and IPv4 network segments}
\label{fig:v6v4separated}
\end{figure}
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However installation and configuration of the transition mechanism
usually require in depth knowledge about both protocols and require
additional hardware to be added in the network.
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In this thesis we show an in-network transition method based on
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NAT64~\cite{rfc6146}. Compared to traditional NAT64 methods which
require hosts to explicitly use an extra device in the
network,\footnote{Usually the default router will take this role.}
our proposed method is transparent to the hosts.
This way the routing and network configuration does not need to be
changed to support NAT64 within a network.
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Currently network operators have to focus on two network stacks when
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designing networks: IPv6 and IPv4. While in a small scale setup this
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might not introduce significant complexity, figure
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\ref{fig:v6v4separated} shows how the complexity quickly grows
even with a small number of hosts.
The proposed in-network solution does not only ease the installation and
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deployment of IPv6, but it also allows line speed translation, because
it is compiled into target dependent low level code that can run in
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ASICs~\cite{networks:_tofin},
FPGAs~\cite{netfpga:_p4_netpf_public_github}
or even in
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software~\cite{_implem_your_switc_target_with_bmv2}. Figure
\ref{fig:v6v4mixed} shows how the design differs for an in-network
solution.
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Even on fast CPUs, software solutions like
tayga~\cite{lutchansky:_tayga_simpl_nat64_linux}
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can be CPU bound (see section \ref{results:softwarenat64}) and are
incapabale of translating protocols at line speed.