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\chapter{Background and Literature Review}

\epigraph{Books serve to show a man that those original thoughts of
  his aren't very new after all}{\textit{Abraham Lincoln}}

The idea of unifying the storage provided by multiple Internet file
storage providers and storing all the content in an encrypted form is
not new. In the past, computer researchers and programmers have
devised different methods to use multiple file storage providers'
storage space. This chapter gives an overview of the work done by Yeo
et al. in unifying the storage provided by Dropbox, Box, Google Drive
and Skydrive on Android devices \cite{yeo}(Section \ref{2-yeo-sec});
SkyCDS, a content delivery service, by Gonzalez et al., which uses
publish/subscribe overlay paradigm and stores the content across
multiple cloud storage providers such that only part of the content
(in encrypted form) is stored on each file storage provider
\cite{skycds}(Section \ref{2-skycds-sec}); and, lastly,
\verb+git-annex+, by Joey Hess\cite{person:joeyh}, that allows one to
version control and keep track of large files with a possibility of
encrypting files that are stored in ``special remotes'' -- storage
provided by Internet file storage providers (Section
\ref{2-gitannex-sec}).

\section{Multi Cloud Storage Prototype}\label{2-yeo-sec}

In the paper ``Leveraging client-side storage techniques for enhanced
use of multiple consumer cloud storage services on
resource-constrained mobile devices'', Yeo et al. show their Android
mobile application, a prototype, which unifies storage provided by
Dropbox, Box, Google Drive and SkyDrive. The application allows the
user to store all their information in a single location on their
phone and it uses erasure coding \cite{weatherspoon} to split each
file into \verb`n + k` fragments and spreads the encrypted fragments
across storage provided by the file storage providers. All basic file
operations -- Create, Rename, Update, Delete (CRUD) -- are
possible. Information about the files stored in the unified location
is stored in a SQLite database. Unlike combox, which depends the file
storage provider' client to sync file fragments/shards to the file
storage provider's data store, the Android application developed by
Yeo et al. takes the responsibility to sync file fragments/shards to
each file storage provider and uses the OAuth
2.0\cite{protocol:oauth2} protocol for authorization.

For encrypting file fragments, they use AES-256; the key for
encrypting file fragments is derived from the user's password by using
Password-Based Key Derivation Function (PBKDF2)\cite{kaliski}. For
erasure coding they use the JigDFS library\cite{jigdfs}. The Android
application is able do ``progressive streaming'' of media files; this
means that large media files can be streamed in real-time from the
from the file storage providers' data store; this is an attractive
feature in a ``resource constrained'' device where storage is
expensive.

Yeo et al. propose methods for achieving data de-duplication; file
compression based on file type; intelligent pre-fetching and caching
of file fragments and ``automatic restoration in exploiting
file-versioning''. These features were not implemented in the
prototype Android application and there is possibility of Yeo et
al. implementing these features in the future.

It becomes apparent that Yeo et al. work is of immense
importance. This is particularly true when we taking into
consideration the research done by Yang et al., which found that 59\%
of the users who use ``cloud storage service'' access the service
through a smart phone and 42.2\% users access it for audio/video
\cite{yang}. The research by Yang et al. suggests a trend of users'
preference for small hand-held computers over laptops and desktops.

\section{SkyCDS}\label{2-skycds-sec}

SkyCDS, by Gonzalez et al., is a content delivery system that splits
and spreads the content across multiple file storage providers
\cite{skycds}. According to Gonzalez et al., the main reason for
designing and developing SkyCDS was to prevent content providers from
getting locked into just one file storage provider and to minimize
loss when a file storage provider goes out of business or if there is
temporary outage in the storage service provided by the file storage
provider.

In SkyCDS, the content delivery to subscribers of the content is
segregated into two distinct layers -- Metadata Flow Layer and the
Content Flow Layer. The publisher of the content largely interacts
with the Metadata Flow Layer that controls and keeps track of what
content is published and the subscriber also largely interacts with
the Metadata Flow layer to subscribe to content published in the
content delivery system. The Content Flow Layer is where the content
is stored across multiple file storage providers. The publisher is
responsible for publishing the content using the ``delivery workflow''
(part of the Content Flow Layer) and the subscriber uses the
``retrieve workflow'' to get access to the subscribed content.

When content has to be dispersed to $k$ file storage providers, the
content is split into $n$ chunks, $n > k$. This file splitting seems
to produce 66.7\% of redundancy overhead \cite{skycds}. This file
splitting scheme also looks very similar to erasure coding, but
Gonzalez et al. don't explicitly state that the content splitting
scheme is indeed ``erasure coding''. The splitting of content is done
by the ``delivery workflow'' engine which is invoked when the
publisher triggers the action to publish the respective content to
subscribers.

To evaluate the effectiveness of SkyCDS, Gonzalez et al. state that
they've done a case study using the data obtained from the European
Space Astronomy Center (ESAC) for the Soil Moisture Ocean Salinity. In
this study, a group of organizations, in two different continents,
used SkyCDS to share satellite images with each other. According to
Gonzalez et al. this study attested SkyCDS as a viable option for
content delivery with respective to performance, cost of file storage
space and reliability.

\section{git-annex}\label{2-gitannex-sec}

\verb+git-annex+ allows one to version controlled large files that are
not usually feasible to version control under
\verb+git+\cite{program:git}. \verb+git-annex+ checks in the name and
other meta-data about the files in git and stores the actual content
under \verb+.git/annex+ directory. When a file is added to
\verb+git-annex+, a symlink of the file is created in place of the
file and the content of the file itself is stored under the
\verb+.git/annex+ directory.

For instance, say there is a file called
\verb+deb-nicholson-80s.medium.webm+ that was downloaded from the
Internet to the \verb+git-annex+ directory:

\begin{verbatim}
↳ git status
On branch master
Untracked files:
  (use "git add <file>..." to include in what will be committed)

   deb-nicholson-80s.medium.webm

↳ ls -l
total 105708
...
-rw-r--r-- 1 rsd rsd 108196923 May  5  2015 deb-nicholson-80s.medium.webm
...
\end{verbatim}

When this file is added to \verb+git-annex+ with \verb+git annex add+,
the file turns into a symlink to a file under the \verb+.git/annex+
directory:

{\small
\begin{verbatim}
↳ git annex add deb-nicholson-80s.medium.webm
add deb-nicholson-80s.medium.webm ok
(recording state in git...)

↳ ls -l
...
lrwxrwxrwx 1 rsd rsd   207 May  5  2015 deb-nicholson-80s.medium.webm
-> ../.git/annex/objects/3j/vG/SHA256E-s108196923--7de9484ee96908268e
21b451eb9805552c32b44da08e70ee861332c87352944f.webm/SHA256E-s10819692
3--7de9484ee96908268e21b451eb9805552c32b44da08e70ee861332c87352944f.w
ebm

↳ git commit -m "Added video/deb-nicholson-80s.medium.webm"
[master efa1775] Added video/deb-nicholson-80s.medium.webm
 1 file changed, 1 insertion(+)
 create mode 120000 video/deb-nicholson-80s.medium.webm
\end{verbatim}
}

Now, the file \verb+deb-nicholson-80s.medium.webm+ is checked into
\verb+git-annex+ and the command \verb+git annex sync+ can be issued
to sync the repository to other \verb+git-annex+ repositories. It must
be noted here that when the repository is synced, the file content
itself is not transferred to the other \verb+git-annex+ repositories;
only the file's name and its meta-data that is stored in a separate
git branch called \verb+git-annex+ are
transferred\cite{documentation:git-annex-hworks}. In order to create a
copy of a given file in another git annex repository,
\verb+git annex get /path/to/filename.ext+ has to done.

\verb+git-annex+ has this feature called ``special
remotes''\cite{documentation:git-annex-sremotes}, that allows one to
push files checked into \verb+git-annex+ to storage provided by file
storage providers. At the time of writing this report,
\verb+git-annex+ supports pushing data to the following file storage
services:

{\scriptsize
  \begin{itemize}
  \item Amazon S3
  \item Amazon Glacier
  \item Internet Archive via S3
  \item Box.com
  \item Google drive
  \item Google Cloud Storage
  \item Mega.co.nz
  \item SkyDrive
  \item OwnCloud
  \item Flickr
  \item IMAP
  \item Usenet
  \item chef-vault
  \item hubiC
  \item pCloud
  \item ipfs
  \item Ceph
  \item Blackblaze's B2
  \end{itemize}
}

All data pushed to file storage provider's servers can optionally be
encrypted using one's GPG key. For instance, to encrypt data that is
pushed to the Amazon S3 special remote, the following command is used
\cite{docs:git-annex-as3}:

\begin{verbatim}
$ git annex initremote cloud type=S3 keyid=2512E3C7
initremote cloud (encryption setup with gpg key C910D9222512E3C7)
                 (checking bucket) (creating bucket in US) (gpg) ok
$ git annex describe cloud "at Amazon's US datacenter"
describe cloud ok
\end{verbatim}

where \verb+2512E3C7+ is the id of the GPG key to use for encrypting
data pushed to the Amazon S3 special remote. It is also possible to
store each file that is pushed to the remotes as a set of chunks of
size \verb+N+, to do that we do:

\begin{verbatim}
$ git annex initremote cloud type=S3 chunk=1MiB keyid=2512E3C7
initremote cloud (encryption setup with gpg key C910D9222512E3C7)
                 (checking bucket) (creating bucket in US) (gpg) ok
$ git annex describe cloud "at Amazon's US datacenter"
describe cloud ok
\end{verbatim}

Upon completion, each file that has to be pushed to the Amazon S3
special remote is divided into 1MiB chunks, each chunk is encrypted
using the GPG key \verb+2512E3C7+ and the encrypted chunks are finally
pushed to the Amazon S3 remote. It must be noted here that unlike the
Multi Cloud Storage Prototype or SkyCDS or combox, in \verb+git-annex+
when we are using file chunking all the chunks go to the same location
-- in this case, the Amazon S3 remote.