source: doc/theses/andrew_beach_MMath/performance.tex@ d83b266

\chapter{Performance}
\label{c:performance}

Performance has been of secondary importance for most of this project.
Instead, the focus has been to get the features working. The only performance
requirements is to ensure the tests for correctness run in a reasonable
amount of time.

\section{Test Set-Up}
Tests will be run in \CFA, C++, Java and Python.
In addition there are two sets of tests for \CFA,
one for termination exceptions and once with resumption exceptions.

C++ is the most comparable language because both it and \CFA use the same
framework, libunwind.
In fact, the comparison is almost entirely a quality of implementation
comparison. \CFA's EHM has had significantly less time to be optimized and
does not generate its own assembly. It does have a slight advantage in that
there are some features it does not handle, through utility functions,
but otherwise \Cpp has a significant advantage.

Java is another very popular language with similar termination semantics.
It is implemented in a very different environment, a virtual machine with
garbage collection.
It also implements the finally clause on try blocks allowing for a direct
feature-to-feature comparison.
As with \Cpp, Java's implementation is more mature, has more optimizations
and more extra features.

Python was used as a point of comparison because of the \CFA EHM's
current performance goals, which is not be prohibitively slow while the
features are designed and examined. Python has similar performance goals for
creating quick scripts and its wide use suggests it has achieved those goals.

Unfortunately there are no notable modern programming languages with
resumption exceptions. Even the older programming languages with resumptions
seem to be notable only for having resumptions.
So instead resumptions are compared to a less similar but much more familiar
feature, termination exceptions.

All tests are run inside a main loop which will perform the test
repeatedly. This is to avoids start-up or tear-down time from
affecting the timing results.
Most test were run 1 000 000 (a million) times.
The Java versions of the test also run this loop an extra 1000 times before
beginning to time the results to ``warm-up" the JVM.

Timing is done internally, with time measured immediately before and
immediately after the test loop. The difference is calculated and printed.

The loop structure and internal timing means it is impossible to test
unhandled exceptions in \Cpp and Java as that would cause the process to
terminate.
Luckily, performance on the ``give-up and kill the process" path is not
critical.

The exceptions used in these tests will always be a exception based off of
the base exception. This requirement minimizes performance differences based
on the object model used to repersent the exception.

All tests were designed to be as minimal as possible while still preventing
exessive optimizations.
For example, empty inline assembly blocks are used in \CFA and \Cpp to
prevent excessive optimizations while adding no actual work.

% We don't use catch-alls but if we did:
% Catch-alls are done by catching the root exception type (not using \Cpp's
% \code{C++}{catch(...)}).

\section{Tests}
The following tests were selected to test the performance of different
components of the exception system.
The should provide a guide as to where the EHM's costs can be found.

\paragraph{Raise and Handle}
The first group of tests involve setting up
So there is three layers to the test. The first is set up and a loop, which
configures the test and then runs it repeatedly to reduce the impact of
start-up and shutdown on the results.
Each iteration of the main loop
\begin{itemize}[nosep]
\item Empty Function:
The repeating function is empty except for the necessary control code.
\item Destructor:
The repeating function creates an object with a destructor before calling
itself.
\item Finally:
The repeating function calls itself inside a try block with a finally clause
attached.
\item Other Handler:
The repeating function calls itself inside a try block with a handler that
will not match the raised exception. (But is of the same kind of handler.)
\end{itemize}

\paragraph{Cross Try Statement}
The next group measures the cost of a try statement when no exceptions are
raised. The test is set-up, then there is a loop to reduce the impact of
start-up and shutdown on the results.
In each iteration, a try statement is executed. Entering and leaving a loop
is all the test wants to do.
\begin{itemize}[nosep]
\item Handler:
The try statement has a handler (of the matching kind).
\item Finally:
The try statement has a finally clause.
\end{itemize}

\paragraph{Conditional Matching}
This group of tests checks the cost of conditional matching.
Only \CFA implements the language level conditional match,
the other languages must mimic with an ``unconditional" match (it still
checks the exception's type) and conditional re-raise if it was not supposed
to handle that exception.
\begin{itemize}[nosep]
\item Match All:
The condition is always true. (Always matches or never re-raises.)
\item Match None:
The condition is always false. (Never matches or always re-raises.)
\end{itemize}

%\section{Cost in Size}
%Using exceptions also has a cost in the size of the executable.
%Although it is sometimes ignored
%
%There is a size cost to defining a personality function but the later problem
%is the LSDA which will be generated for every function.
%
%(I haven't actually figured out how to compare this, probably using something
%related to -fexceptions.)

\section{Results}
Each test is was run five times, the best and worst result were discarded and
the remaining values were averaged.

In cases where a feature is not supported by a language the test is skipped
for that language. Similarly, if a test is does not change between resumption
and termination in \CFA, then only one test is written and the result
was put into the termination column.

\begin{tabular}{|l|c c c c c|}
\hline
              & \CFA (Terminate) & \CFA (Resume) & \Cpp & Java & Python \\
\hline
Raise Empty   & 0.0 & 0.0 & 0.0 & 0.0 & 0.0 \\
Raise D'tor   & 0.0 & 0.0 & 0.0 & N/A & N/A \\
Raise Finally & 0.0 & 0.0 & N/A & 0.0 & 0.0 \\
Raise Other   & 0.0 & 0.0 & 0.0 & 0.0 & 0.0 \\
Cross Handler & 0.0 & 0.0 & 0.0 & 0.0 & 0.0 \\
Cross Finally & 0.0 & N/A & N/A & 0.0 & 0.0 \\
Match All     & 0.0 & 0.0 & 0.0 & 0.0 & 0.0 \\
Match None    & 0.0 & 0.0 & 0.0 & 0.0 & 0.0 \\
\hline
\end{tabular}