84 lines
4.3 KiB
TeX
84 lines
4.3 KiB
TeX
\chapter{Conclusion}
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\label{chapter:conclusion}
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\subsubsection{Cycle Accurate Tracing}
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Hypothesis~\ref{hyp:1} asks whether there is a trace technique capable of
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recording cycle accurate traces with a duration of at least one second. There
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exists three general measurement techniques. Hybrid and software based trace
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tools rely on instrumentation. Thus, they change the runtime behavior of
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an application and do not allow cycle accurate trace recording.
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Additionally, an on-chip memory to buffer the recorded trace events is
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required. Hence, the trace duration is strongly limited by the available
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memory. An application with 28 tasks can only be traced for \unit[350]{ms}
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using the Gliwa T1 hybrid trace tool \cite{kastner2011integrated} providing
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events solely on task level. Runnables were not even considered.
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Hardware tracing is the only trace technique that allows cycle accurate traces
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with a duration of at least one second. Actually, durations of over ten
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seconds are possible with the correct hardware configuration.
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However, there are certain limitations for the hardware platform used in this
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thesis. Depending on the clock configuration not all data events are recorded.
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This can be avoided by using a CPU core clock frequency smaller or equal than
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\unit[160]{MHz}. Therefore, Hypothesis~\ref{hyp:1} is true.
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\subsubsection{ORTI Based Software to System Mapping}
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Hardware trace tools create traces on software level. This level is not
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sufficient for the real-time analysis of embedded systems. A transformation
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from software to system level is therefore required. \gls{orti} was designed
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to give third party tools additional information for the trace recording of
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applications that use an \gls{osek} compliant \gls{os}. Hypothesis~\ref{hyp:2}
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asks if \gls{orti} is sufficient to create a complete mapping from software to
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system level.
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It has been shown that \gls{orti} can be used to cover only a subset of the
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\gls{os} entity types specified in the \gls{btf} standard. Even for those
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entities covered by \gls{orti} no complete mapping is feasible. For example,
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information about task entities is included in the \gls{orti} file, but it is
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not feasible to determine the source entity for a \emph{mtalimitexceeded}
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event. Consequently, Hypothesis~\ref{hyp:2} does not hold.
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However, it should be noted that \gls{orti} allows it to specify \gls{os}
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vendor specific attributes. This means in case a mapping is basically possible
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as claimed by Hypothesis~\ref{hyp:3} then it would be possible to include the
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required information in the \gls{orti} file.
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Nevertheless, to the best of my knowledge this thesis is the first work to show
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that \gls{btf} \emph{trigger} actions and all process actions except
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\emph{mtalimitexceeded} can be created based on the \gls{orti} sections
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specified by \gls{osek}.
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\subsubsection{Software to System Mapping}
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No complete mapping from software to system entities is feasible by relying
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solely on the information in the \gls{orti} file. Additional information is
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required to achieve a complete mapping. On the one hand a detailed
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understanding of the \gls{os} internals is required, on the other hand meta
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information must be provided to the transformation algorithm.
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The concept of runnables and signals is not specified by \gls{osek}.
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Basically, runnables are functions and signals are variables. It is possible
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to create runnable and signal events via function and data tracing. A list of
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all entities is required to distinguish regular functions from runnables and
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regular variables from signals.
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To create \gls{btf} events for the event entity type it is necessary to
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understand the respective code of the \gls{os}. By parsing the statically
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created C header files the event \glspl{id} can be retrieved and the correct
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events can be created.
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Semaphore events are the most complex entity types to reconstruct via
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hardware tracing. \gls{btf} supports all possible types of semaphore like
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synchronization mechanisms. Hence, a variety of different actions are
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specified. A possible mapping for \gls{osek} resource entities is nevertheless
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provided in this thesis.
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To the best of my knowledge this is the first work to show that all \gls{btf}
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signal, runnable, event, and semaphore actions can be recreated from an
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\gls{osek} compliant \gls{os}. Therefore, Hypothesis~\ref{hyp:3} is true.
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