-%6
-%7
-%8
-%9
-%10
-%11
-%12
-
The test process consists of several stages. The results of the first stage,
planning, are descibed in this document. On the basis of this document actual
test cases will be designed. Afterwards the actual tests will be implemented
and executed. The results of these tests will then be evaluated against the
-exit criteria (see Section~\ref{sec:exitcriteria}) and depending on the outcome
-of these evaluations further tests might be deemed necessary.
+exit criteria found in Section~\ref{sec:exitcriteria} and depending on the
+outcome of these evaluations further tests might be deemed necessary.
\subsection{Quality Characteristics}
The quality characteristics that are to be tested are described using the
-ISO/IEC 25010 \cite{iso25010} as a guideline. In the following sections we will
+ISO/IEC 25010~\cite{iso25010} as a guideline. In the following sections we will
discuss the relevant \textit{product quality} and \textit{quality in use}
characteristics.
As described in Section~\ref{sec:risks} the SUT is core functionality of
the networking capable system. Because many other systems running on the
system could rely on it it is very important that the SUT is functionality
- suitable. Therefore all three sub characteristics of Functional
+ suitable. Therefore all three sub characteristics of Functional
Suitability (\textit{Functional completeness, Functional correctness,
Functional appropriateness}) are of vital importance. As was previously
mentioned in Section~\ref{sec:risks} extra emphasis should be placed on
testing \emph{Functional Correctness} as recovery from Failures in
computer-to-computer systems is problematic.
- \item \textbf{Performance efficiency} \label{sec:perf_eff}\\
+ \item \textbf{Performance efficiency} \label{sec:perf_eff}\\
As the SUT runs as a service on a system with other programs it must have
- efficient \emph{resouce utilisation}. It can not contain any memory leaks
+ efficient \emph{resource utilisation}. It can not contain any memory leaks
or use other resources more than necessary.
- \item \textbf{Compatibility}\\
- \emph{Interoperability} is the key feauture of the SUT as it's purpose is to
- communicate with other systems implementing the TCP protocol. Therefore
- it is of vital importance that the SUT impements the TCP procotol correctly.
- Furthermore it is very important that the SUT can \emph{co-exist} with other
- programs on the system it runs on, since it is used as a service by those
- programs. This means that the SUT has to handle preemption as well as having
- multiple programs requesting it's services at once.
- \item \textbf{Reliability}\\
- As stated before, the SUT is used as a core service, this means it has to be
- very \emph{mature}. It needs to behave as expected under normal working
- conditions. As it can continually be requested the SUT needs to have
+ \item \textbf{Compatibility}\\
+ \emph{Interoperability} is the key feature of the SUT as it's purpose is to
+ communicate with other systems implementing the TCP protocol. Therefore it
+ is of vital importance that the SUT implements the TCP protocol correctly.
+ Furthermore it is very important that the SUT can \emph{co-exist} with
+ other programs on the system it runs on, since it is used as a service by
+ those programs. This means that the SUT has to handle preemption as well as
+ having multiple programs requesting it's services at once.
+ \item \textbf{Reliability}\\
+ As stated before, the SUT is used as a core service, this means it has to
+ be very \emph{mature}. It needs to behave as expected under normal working
+ conditions. As it can continually be requested the SUT needs to have
constant
- \emph{availibility}. As the SUT relies on an (potentially) unreliable
- channel to send and receive data it needs to be \emph{fault tolerant}. The
- SUT needs to properly handle errors in received data or complete
- unavailibilty of the underlying channel.
- \item \textbf{Security}\\
- \emph{Confidentiliality} is an important aspect for the SUT. Received
- data should only be delivered to the program to which it is adressed.
+ \emph{availability}. As the SUT relies on a potentially unreliable channel
+ to send and receive data it needs to be \emph{fault tolerant}. The SUT
+ needs to properly handle errors in received data or complete unavailability
+ of the underlying channel.
\end{itemize}
-This leaves three categories which are not relevant the SUT. Below we will
-shortly discuss per categorie why these are not relevant. \emph{Maintainability}
+This leaves four categories which are not relevant the SUT. Below we will
+shortly discuss per category why these are not relevant. \emph{Maintainability}
is an important aspect of any software system, however for the SUT it is not a
core aspect, as it is first and foremost of importance that the implementation
-is correct, furthermore TCP does not change often. \emph{Usability} isn't a core
-aspect either, as the SUT is not used directly by humans, but is a service which
-is adressed when another program needs it. \emph{Portability} isn't either as
-the SUT is installed on a system once and intended to work on that system.
+is correct, furthermore TCP does not change often. \emph{Usability} isn't a
+core aspect either, as the SUT is not used directly by humans, but is a service
+which is addressed when another program needs it. \emph{Portability} isn't
+either as the SUT is installed on a system once and intended to work on that
+system. \emph{Security} isn't a feature of the SUT either, systems using the
+SUT can add their own security mechanisms on top of it.
+
\subsubsection{Quality in use}
Quality in use is dived into five subcategories. Below we will discuss the
categories which are relevant to the SUT.
\begin{itemize}
- \item \textbf{Effectiveness}\\
+ \item \textbf{Effectiveness}\\
This is the core aspect of the SUT, users (other programs) need to be able
to effectively use the SUT to send and receive data.
- \item \textbf{Efficiency}\\
+ \item \textbf{Efficiency}\\
This issue has already been covered above under
``performance efficiency''~\ref{sec:perf_eff}.
- \item \textbf{Satisfaction}\\
+ \item \textbf{Satisfaction}\\
It is important that programs using the SUT can \emph{trust} that the SUT
provides the promised services. This means that data is send and received
- reliably and the SUT provides clear and unambigious errors when this service
+ reliably and the SUT provides clear and unambiguous errors when this
+ service
can not be provided.
- \item \textbf{Context Coverage}\\
+ \item \textbf{Context Coverage}\\
The SUT needs to behave as expected in all specified contexts
(\emph{context completeness}).
\end{itemize}
-This leaves \emph{freedom from risk}, which we consider not relevant as the
-SUT itself does not pose any risks, and correct implementation (which is covered
-in the other categories) gives clear guarantees to programs using the services
-of the SUT.
-
-\subsection{Levels and types of testing} \label{levels}
-
-The client will deliver a product for certification. This means our team will only conduct acceptance testing and assume that the client who requested certification has conducted unit, module and integration testing. We will only be conducting black-box testing and the client is not required to handover any source-code. Initially we will conduct several basic test cases based on experience acquired from previous certification requests (error guessing). If the product fails these basic tests we reject it and seize all further activities. If the product is not rejected we will proceed with more thorough testing. For each test we produce a test report. If any of the test cases fail the product is still rejected but in order to deliver usable feedback to the client we will still produce a test report. For each test case a performance analysis will be included.
-
-\subsubsection{Test generation}
-
-The basic tests mentioned in section \ref{levels} are conducted using a checklist. If any of the checks fail we immediately reject the product.
+This leaves \emph{freedom from risk}, which we consider not relevant as the SUT
+itself does not pose any risks, and correct implementation (which is covered in
+the other categories) gives clear guarantees to programs using the services of
+the SUT.
+
+\subsection{Levels and types of testing} \label{section:levels}
+The client will deliver a product for certification. This means our team will
+only conduct \emph{acceptance testing} and assume that the client who requested
+certification has conducted \emph{unit}, \emph{module} and \emph{integration
+testing}. We will only be conducting \emph{black-box testing} and the client
+is not required to handover any source-code.
+
+Initially we will conduct a few basic \emph{manual tests} based on experience
+acquired from previous certification requests (\emph{error guessing}). If the
+product fails these basic tests we immediately reject it and seize all further
+activities.
+
+If the product is not rejected after the basic \emph{manual tests} we will
+proceed with the second stage of testing. For these follow-up tests we will use
+\emph{equivalence partitioning} to reduce the number of test cases. Every test
+case will result in a test report. If any of the test cases fail the product
+is rejected. In order to deliver usable feedback to the client we will still
+produce a test report.
+
+\subsubsection{Manual tests}
+
+The basic tests mentioned in Section~\ref{section:levels} are conducted using a
+checklist. If any of the checks fail we immediately reject the product.
\begin{enumerate}
\item Is the product complete?
\item Does the product come with a manual or quick start guide?
\item Is it possible to get the product in a usable state?
- \item Can we use the product to initiate a connection in a corruption free environment?
- \item ....
+ \item Can we use the product to initiate a connection in a corruption
+ free
+ environment?
\end{enumerate}
-For the remaining tests we first use equivalence partitioning to reduce the overall number of test cases.
+These\emph{ manual tests} are performed in order to ensure that the client has
+delivered a usable product.
+
+\subsubsection{Test generation}
+
+For the second state of testing we first use \emph{equivalence partitioning} to
+reduce the overall number of test cases as mentioned in
+Section~\ref{section:levels}. At the highest level we can define the following
+equivalent \emph{input classes} for the SUT.
\begin{enumerate}
\item Valid requests:
\end{enumerate}
\end{enumerate}
-For these requests we can introduce more cases using equivalence partitioning for the different packets that are sent during one request.
+For these requests we can introduce more cases by applying \emph{equivalence
+partitioning} to the different packets that are sent during one request.
\begin{enumerate}
\item Packets received in order.
\item Packets received out of order.
\end{enumerate}
-For each individual packet we can specify the follow equivalent classes.
+For each individual packet we can specify the follow \emph{equivalent classes}.
\begin{enumerate}
\item Valid packet.
\item Missing packets.
\end{enumerate}
-We will test all possible combinations of requests/packet order/packet content. For each combination we will use boundary value analysis to reduce the total number of test cases. Boundary values are constructed using the following parameters:
+A \emph{decision table} is used in order to ensure all different equivalent
+classes are covered in our tests. Valid packets can only exist in one form,
+the valid form and there is no need to divide these into additional classes.
+For the invalid packets we will construct a test case where only one parameter
+is made invalid. For the invalid value of this parameter we use \emph{boundary
+value analysis} to reduce the total number of test cases. The SUT input
+parameters correspond to different fields in the network packets. The
+following fields and there boundary values are considered during the testing.
\begin{enumerate}
- \item Checksum: valid/invalid
- \item Header: valid/invalid
- \item Payload: valid/invalid
- \item ...
+ \item Checksum: valid, invalid.
+ \item Header: valid, even or odd number of bits corrupted.
+ \item Payload: valid, even or odd number of bits corrupted.
\end{enumerate}
-\subsubsection{Test environment en automatization}
+\subsubsection{Test environment and automatization}
+\label{section:testenv}
+All the tools we are going to use together with the SUT gives us the following
+collection of software
-All the tools we are going to use together with the SUT gives us the following collection of software.
-
-\begin{enumerate}
- \item Windows, used as a host OS.
- \item Linux, used as both a host and guest OS.
- \item VirtualBox, used to run the guest OS containing the SUT.
- \item Wireshark, used on the guest in order to capture and analyze network traffic.
- \item Tcpdump, used to prepare network packets.
-\end{enumerate}
-
-All test will be conducted in a virtual environment. We will use VirtualBox to run a Linux distro with the product installed. All the tests are performed from within the VirtualBox environment. When testing network transmissions we will only analyze the packets sent/received to/from the guest OS. The host system is disconnected from the Internet or any other network in order to prevent unnecessary traffic.
-
-For each test case (except for the basic tests) a file containing previously captured network traffic will be replayed using Wireshark. We will use tcpdump to update the prepared packets with the MAC address of the guest network adapter. The response packets coming from the guest OS will be recorded and analyzed at a later stage. The valid packets are obtained by capturing traffic between known working alternatives to the SUT. Invalid packets are generated from this valid traffic using tcpdump. The boundary values for the different parameters (fields in packets) are determined by hand. Automated scripts are written that will generate packets with some fields replaced with these boundary values. The performance analysis will consists of measured latencies for all packets sent.
+\begin{itemize}
+ \item Windows\footnote{\url{http://www.microsoft.com/en-us/windows}}, used
+ as a host OS.
+ \item Ubuntu\footnote{\url{http://www.ubuntu.com}}, used as the guest OS
+ running the SUT.
+ \item VirtualBox\footnote{\url{https://www.virtualbox.org/}}, used to run
+ the guest OS containing the SUT.
+ \item Wireshark\footnote{\url{https://www.wireshark.org/}}, used on the
+ guest OS in order to capture and analyze network traffic.
+ \item Bit-Twist\footnote{\url{http://bittwist.sourceforge.net/}}, used to
+ prepare network packets.
+ \item Java\footnote{\url{http://www.java.com}} TCP driven echo server.
+\end{itemize}
-\begin{enumerate}
- \item VirtualBox, https://www.virtualbox.org/
- \item Whireshark, https://www.wireshark.org/
- \item Tcpdump, http://www.tcpdump.org/
-\end{enumerate}
+\begin{figure}[H]
+ \label{fig:sut}
+ \centering
+ \includegraphics[width=0.5\linewidth]{SUTsetup.eps}
+ \caption{Test environment}
+\end{figure}
+
+
+All test will be conducted in a virtual environment. We will use VirtualBox to
+run a Linux distribution with the product installed. The Linux distribution in
+question is Ubuntu. All the tests are performed from within the VirtualBox
+environment. When testing network transmissions we will only analyze the
+packets sent/received to/from the SUT. The host system is disconnected from the
+Internet or any other network in order to prevent unnecessary traffic.
+% Dit is niet nodig omdat het via loopback gaat
+% Zeker weten? de SUT ontvangt ook niet loopback packets toch?
+% Ja maar we geven de host gewoon geen interface?
+
+For each test case (except for the \emph{manual tests}) a file containing
+previously captured network traffic will be replayed using Wireshark and sent
+to the \emph{Java TCP driven echo server}. We will use Bit-Twist to update the
+prepared packets with the MAC address of the guest network adapter and provide
+them with a valid source address. This updating step is needed because the
+kernel would otherwise reject the packets and prevent them from reaching the
+SUT. The response packets sent by the \emph{Java TCP driven echo server} and
+passing trough the SUT will be recorded, analyzed and validated according to
+the \textit{RFC793} specification. The valid packets are build manually from
+the \textit{RFC793} specification. Invalid packets are generated from this
+valid traffic using Bit-Twist. The boundary values for the different
+parameters (fields in packets) are determined by hand. Automated scripts are
+used in order to generate packets with some fields replaced with these
+\emph{boundary values}.
repositories / tt2015.git / blobdiff