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Lots of small markup adjustments.
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High performance logging profiler}
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\declaremodule{standard}{hotshot}
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\modulesynopsis{High performance logging profiler, mostly written in C.}
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\moduleauthor{Fred L. Drake, Jr.}{fdrake@acm.org}
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\sectionauthor{Anthony Baxter}{anthony@interlink.com.au}
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\versionadded{2.2}
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\modulesynopsis{High performance logging profiler, mostly written in C.}
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This module provides a nicer interface to the \code{_hotshot} C module.
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This module provides a nicer interface to the \module{_hotshot} C module.
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Hotshot is a replacement for the existing \refmodule{profile} module. As it's
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written mostly in C, it should result in a much smaller performance impact
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than the existing profile module.
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than the existing \refmodule{profile} module.
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\begin{classdesc}{Profile}{logfile, \optional{, lineevents=0, linetimings=1}}
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The profiler object. The argument \var{logfile} is the name of a log file
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to use for logged profile data. The argument \var{lineevents} specifies whether
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to generate events for every source line, or just on function call/return. It
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defaults to 0 (only log function call/return). The argument \var{linetimings}
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specifies whether to record timing information. It defaults to 1 (store timing
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\begin{classdesc}{Profile}{logfile\optional{,
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lineevents\code{=0}\optional{,
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linetimings\code{=1}}}}
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The profiler object. The argument \var{logfile} is the name of a log
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file to use for logged profile data. The argument \var{lineevents}
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specifies whether to generate events for every source line, or just on
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function call/return. It defaults to \code{0} (only log function
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call/return). The argument \var{linetimings} specifies whether to
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record timing information. It defaults to \code{1} (store timing
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information).
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\end{classdesc}
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\subsection{Profile Objects \label{hotshot-objects}}
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Profile objects have the following methods:
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@ -39,21 +39,18 @@ Add an arbitrary labelled value to the profile output.
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Close the logfile and terminate the profiler.
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\end{methoddesc}
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%
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\begin{methoddesc}{fileno}{}
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Return the file descriptor of the profiler's log file.
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\end{methoddesc}
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\begin{methoddesc}{run}{cmd}
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Profile an exec-compatible string in the script environment.
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The globals from the \module{__main__} module are used as
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Profile an \keyword{exec}-compatible string in the script environment.
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The globals from the \refmodule[main]{__main__} module are used as
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both the globals and locals for the script.
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\end{methoddesc}
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\begin{methoddesc}{runcall}{func, *args, **keywords}
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Profile a single call of a callable.
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Additional positional and keyword arguments may be passed
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along; the result of the call is returned, and exceptions are
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allowed to propogate cleanly, while ensuring that profiling is
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@ -62,8 +59,7 @@ disabled on the way out.
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\begin{methoddesc}{runctx}{cmd, globals, locals}
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Evaluate an exec-compatible string in a specific environment.
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Evaluate an \keyword{exec}-compatible string in a specific environment.
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The string is compiled before profiling begins.
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\end{methoddesc}
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@ -75,9 +71,10 @@ Start the profiler.
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Stop the profiler.
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\end{methoddesc}
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\subsection{Using hotshot data}
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\declaremodule{standard}{hotshot.stats}
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\subsection{Using hotshot data}
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\declaremodule{standard}{hotshot.stats}
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\modulesynopsis{Statistical analysis for Hotshot}
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\versionadded{2.2}
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@ -91,16 +88,16 @@ of the \class{pstats.Stats} class.
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\end{funcdesc}
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\begin{seealso}
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\seemodule{profile}{The profile module's \class{Stats} class }
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\seemodule{profile}{The \module{profile} module's \class{Stats} class}
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\end{seealso}
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\subsection{Example Usage \label{hotshot-example}}
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Note that this example runs the python "benchmark" pystones. It can
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Note that this example runs the python ``benchmark'' pystones. It can
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take some time to run, and will produce large output files.
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\begin{verbatim}
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>>> import hotshot, hotshot.stats, test.pystone
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>>> prof = hotshot.Profile("stones.prof")
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>>> benchtime, stones = prof.runcall(test.pystone.pystones)
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.
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.
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.
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\end{verbatim}
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@ -4,36 +4,36 @@
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\declaremodule{standard}{timeit}
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\modulesynopsis{Measure the execution time of small code snippets.}
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\versionadded{2.3}
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\index{Benchmarking}
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\index{Performance}
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\versionadded{2.3}
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This module provides a simple way to time small bits of Python code.
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It has both command line as well as callable interfaces. It avoids a
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number of common traps for measuring execution times. See also Tim
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Peters' introduction to the ``Algorithms'' chapter in the
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\citetitle{Python Cookbook}, published by O'Reilly.
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This module provides a simple way to time small bits of Python code. It has
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both command line as well as callable interfaces. It avoids a number of
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common traps for measuring execution times. See also Tim Peters'
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introduction to the Algorithms chapter in the ``Python Cookbook'', published
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by O'Reilly.
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The module defines the following public class:
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The module interface defines the following public class:
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\begin{classdesc}{Timer}{\optional{stmt='pass'
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\optional{, setup='pass'
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\begin{classdesc}{Timer}{\optional{stmt=\code{'pass'}
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\optional{, setup=\code{'pass'}
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\optional{, timer=<timer function>}}}}
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Class for timing execution speed of small code snippets.
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The constructor takes a statement to be timed, an additional statement used
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for setup, and a timer function. Both statements default to 'pass'; the
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timer function is platform-dependent (see the module doc string).
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The constructor takes a statement to be timed, an additional statement
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used for setup, and a timer function. Both statements default to
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\code{'pass'}; the timer function is platform-dependent (see the
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module doc string). The statements may contain newlines, as long as
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they don't contain multi-line string literals.
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To measure the execution time of the first statement, use the timeit()
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method. The repeat() method is a convenience to call timeit() multiple
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times and return a list of results.
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To measure the execution time of the first statement, use the
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\method{timeit()} method. The \method{repeat()} method is a
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convenience to call \method{timeit()} multiple times and return a list
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of results.
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\end{classdesc}
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The statements may contain newlines, as long as they don't contain
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multi-line string literals.
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\begin{methoddesc}{print_exc}{\optional{file=None}}
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\begin{methoddesc}{print_exc}{\optional{file=\constant{None}}}
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Helper to print a traceback from the timed code.
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Typical use:
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The advantage over the standard traceback is that source lines in the
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compiled template will be displayed.
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The optional file argument directs where the traceback is sent; it defaults
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to \code{sys.stderr}.
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The optional \var{file} argument directs where the traceback is sent;
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it defaults to \code{sys.stderr}.
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\end{methoddesc}
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\begin{methoddesc}{repeat}{\optional{repeat=3\optional{, number=1000000}}}
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\begin{methoddesc}{repeat}{\optional{repeat\code{=3}\optional{,
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number\code{=1000000}}}}
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Call \method{timeit()} a few times.
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This is a convenience function that calls the \method{timeit()} repeatedly,
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returning a list of results. The first argument specifies how many times to
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call \function{timeit()}. The second argument specifies the \code{number}
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argument for \function{timeit()}.
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This is a convenience function that calls the \method{timeit()}
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repeatedly, returning a list of results. The first argument specifies
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how many times to call \method{timeit()}. The second argument
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specifies the \var{number} argument for \function{timeit()}.
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Note: it's tempting to calculate mean and standard deviation from the result
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\begin{notice}
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It's tempting to calculate mean and standard deviation from the result
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vector and report these. However, this is not very useful. In a typical
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case, the lowest value gives a lower bound for how fast your machine can run
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the given code snippet; higher values in the result vector are typically not
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probably the only number you should be interested in. After that, you
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should look at the entire vector and apply common sense rather than
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statistics.
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\end{notice}
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\end{methoddesc}
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\begin{methoddesc}{timeit}{\optional{number=1000000}}
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Time \code{number} executions of the main statement.
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To be precise, this executes the setup statement once, and then returns the
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time it takes to execute the main statement a number of times, as a float
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measured in seconds. The argument is the number of times through the loop,
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defaulting to one million. The main statement, the setup statement and the
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timer function to be used are passed to the constructor.
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\begin{methoddesc}{timeit}{\optional{number\code{=1000000}}}
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Time \var{number} executions of the main statement.
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This executes the setup statement once, and then
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returns the time it takes to execute the main statement a number of
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times, measured in seconds as a float. The argument is the number of
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times through the loop, defaulting to one million. The main
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statement, the setup statement and the timer function to be used are
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passed to the constructor.
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\end{methoddesc}
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\end{classdesc}
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\subsection{Command Line Interface}
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When called as a program from the command line, the following form is used:
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\begin{verbatim}
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python timeit.py [-n N] [-r N] [-s S] [-t] [-c] [-h] [statement ...]
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python timeit.py [-n N] [-r N] [-s S] [-t] [-c] [-h] [statement ...]
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\end{verbatim}
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where the following options are understood:
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\item[-n N/--number=N] how many times to execute 'statement'
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\item[-r N/--repeat=N] how many times to repeat the timer (default 3)
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\item[-s S/--setup=S] statement to be executed once initially (default
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'pass')
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\item[-t/--time] use time.time() (default on all platforms but Windows)
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\item[-c/--clock] use time.clock() (default on Windows)
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\code{'pass'})
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\item[-t/--time] use \function{time.time()}
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(default on all platforms but Windows)
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\item[-c/--clock] use \function{time.clock()} (default on Windows)
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\item[-v/--verbose] print raw timing results; repeat for more digits
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precision
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\item[-h/--help] print a short usage message and exit
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\end{description}
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A multi-line statement may be given by specifying each line as a separate
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statement argument; indented lines are possible by enclosing an argument in
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quotes and using leading spaces. Multiple -s options are treated similarly.
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A multi-line statement may be given by specifying each line as a
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separate statement argument; indented lines are possible by enclosing
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an argument in quotes and using leading spaces. Multiple
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\programopt{-s} options are treated similarly.
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If -n is not given, a suitable number of loops is calculated by trying
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successive powers of 10 until the total time is at least 0.2 seconds.
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If \programopt{-n} is not given, a suitable number of loops is
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calculated by trying successive powers of 10 until the total time is
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at least 0.2 seconds.
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The default timer function is platform dependent. On Windows, clock() has
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microsecond granularity but time()'s granularity is 1/60th of a second; on
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Unix, clock() has 1/100th of a second granularity and time() is much more
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precise. On either platform, the default timer functions measures wall
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clock time, not the CPU time. This means that other processes running on
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the same computer may interfere with the timing. The best thing to do when
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accurate timing is necessary is to repeat the timing a few times and use the
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best time. The -r option is good for this; the default of 3 repetitions is
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probably enough in most cases. On Unix, you can use clock() to measure CPU
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time.
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The default timer function is platform dependent. On Windows,
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\function{time.clock()} has microsecond granularity but
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\function{time.time()}'s granularity is 1/60th of a second; on \UNIX,
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\function{time.clock()} has 1/100th of a second granularity and
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\function{time.time()} is much more precise. On either platform, the
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default timer functions measures wall clock time, not the CPU time.
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This means that other processes running on the same computer may
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interfere with the timing. The best thing to do when accurate timing
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is necessary is to repeat the timing a few times and use the best
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time. The \programopt{-r} option is good for this; the default of 3
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repetitions is probably enough in most cases. On \UNIX, you can use
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\function{time.clock()} to measure CPU time.
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Note: there is a certain baseline overhead associated with executing a pass
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statement. The code here doesn't try to hide it, but you should be aware of
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it. The baseline overhead can be measured by invoking the program without
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arguments.
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\begin{notice}
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There is a certain baseline overhead associated with executing a
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pass statement. The code here doesn't try to hide it, but you
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should be aware of it. The baseline overhead can be measured by
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invoking the program without arguments.
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\end{notice}
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The baseline overhead differs between Python versions! Also, to fairly
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compare older Python versions to Python 2.3, you may want to use python -O
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for the older versions to avoid timing SET_LINENO instructions.
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The baseline overhead differs between Python versions! Also, to
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fairly compare older Python versions to Python 2.3, you may want to
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use Python's \programopt{-O} option for the older versions to avoid
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timing \code{SET_LINENO} instructions.
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\subsection{Examples}
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Here are two example sessions (one using the command line, one using the
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module interface) that compare the cost of using \function{hasattr()}
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vs. try/except to test for missing and present object attributes.
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Here are two example sessions (one using the command line, one using
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the module interface) that compare the cost of using
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\function{hasattr()} vs. \keyword{try}/\keyword{except} to test for
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missing and present object attributes.
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\begin{verbatim}
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\% timeit.py 'try:' ' str.__nonzero__' 'except AttributeError:' ' pass'
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% timeit.py 'try:' ' str.__nonzero__' 'except AttributeError:' ' pass'
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100000 loops, best of 3: 15.7 usec per loop
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\% timeit.py 'if hasattr(str, "__nonzero__"): pass'
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% timeit.py 'if hasattr(str, "__nonzero__"): pass'
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100000 loops, best of 3: 4.26 usec per loop
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\% timeit.py 'try:' ' int.__nonzero__' 'except AttributeError:' ' pass'
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% timeit.py 'try:' ' int.__nonzero__' 'except AttributeError:' ' pass'
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1000000 loops, best of 3: 1.43 usec per loop
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\% timeit.py 'if hasattr(int, "__nonzero__"): pass'
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% timeit.py 'if hasattr(int, "__nonzero__"): pass'
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100000 loops, best of 3: 2.23 usec per loop
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\end{verbatim}
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