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Merge pull request #2100 from Carreau/2to3fixes...
Merge pull request #2100 from Carreau/2to3fixes python 2 and 3 compatibility without 2to3 apply some fixes : - apply (deactivated in setup.py now) - repr (deactivated in setup.py now) - print (only in modules with print >>) - raise (partially) don't touch deathrow and quarantine.

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execution.py
1022 lines | 40.0 KiB | text/x-python | PythonLexer
"""Implementation of execution-related magic functions.
"""
#-----------------------------------------------------------------------------
# Copyright (c) 2012 The IPython Development Team.
#
# Distributed under the terms of the Modified BSD License.
#
# The full license is in the file COPYING.txt, distributed with this software.
#-----------------------------------------------------------------------------
#-----------------------------------------------------------------------------
# Imports
#-----------------------------------------------------------------------------
# Stdlib
import __builtin__ as builtin_mod
import bdb
import os
import sys
import time
from StringIO import StringIO
# cProfile was added in Python2.5
try:
import cProfile as profile
import pstats
except ImportError:
# profile isn't bundled by default in Debian for license reasons
try:
import profile, pstats
except ImportError:
profile = pstats = None
# Our own packages
from IPython.core import debugger, oinspect
from IPython.core import magic_arguments
from IPython.core import page
from IPython.core.error import UsageError
from IPython.core.macro import Macro
from IPython.core.magic import (Magics, magics_class, line_magic, cell_magic,
line_cell_magic, on_off, needs_local_scope)
from IPython.testing.skipdoctest import skip_doctest
from IPython.utils import py3compat
from IPython.utils.io import capture_output
from IPython.utils.ipstruct import Struct
from IPython.utils.module_paths import find_mod
from IPython.utils.path import get_py_filename, unquote_filename
from IPython.utils.timing import clock, clock2
from IPython.utils.warn import warn, error
#-----------------------------------------------------------------------------
# Magic implementation classes
#-----------------------------------------------------------------------------
@magics_class
class ExecutionMagics(Magics):
"""Magics related to code execution, debugging, profiling, etc.
"""
def __init__(self, shell):
super(ExecutionMagics, self).__init__(shell)
if profile is None:
self.prun = self.profile_missing_notice
# Default execution function used to actually run user code.
self.default_runner = None
def profile_missing_notice(self, *args, **kwargs):
error("""\
The profile module could not be found. It has been removed from the standard
python packages because of its non-free license. To use profiling, install the
python-profiler package from non-free.""")
@skip_doctest
@line_cell_magic
def prun(self, parameter_s='', cell=None, user_mode=True,
opts=None,arg_lst=None,prog_ns=None):
"""Run a statement through the python code profiler.
Usage, in line mode:
%prun [options] statement
Usage, in cell mode:
%%prun [options] [statement]
code...
code...
In cell mode, the additional code lines are appended to the (possibly
empty) statement in the first line. Cell mode allows you to easily
profile multiline blocks without having to put them in a separate
function.
The given statement (which doesn't require quote marks) is run via the
python profiler in a manner similar to the profile.run() function.
Namespaces are internally managed to work correctly; profile.run
cannot be used in IPython because it makes certain assumptions about
namespaces which do not hold under IPython.
Options:
-l <limit>: you can place restrictions on what or how much of the
profile gets printed. The limit value can be:
* A string: only information for function names containing this string
is printed.
* An integer: only these many lines are printed.
* A float (between 0 and 1): this fraction of the report is printed
(for example, use a limit of 0.4 to see the topmost 40% only).
You can combine several limits with repeated use of the option. For
example, '-l __init__ -l 5' will print only the topmost 5 lines of
information about class constructors.
-r: return the pstats.Stats object generated by the profiling. This
object has all the information about the profile in it, and you can
later use it for further analysis or in other functions.
-s <key>: sort profile by given key. You can provide more than one key
by using the option several times: '-s key1 -s key2 -s key3...'. The
default sorting key is 'time'.
The following is copied verbatim from the profile documentation
referenced below:
When more than one key is provided, additional keys are used as
secondary criteria when the there is equality in all keys selected
before them.
Abbreviations can be used for any key names, as long as the
abbreviation is unambiguous. The following are the keys currently
defined:
Valid Arg Meaning
"calls" call count
"cumulative" cumulative time
"file" file name
"module" file name
"pcalls" primitive call count
"line" line number
"name" function name
"nfl" name/file/line
"stdname" standard name
"time" internal time
Note that all sorts on statistics are in descending order (placing
most time consuming items first), where as name, file, and line number
searches are in ascending order (i.e., alphabetical). The subtle
distinction between "nfl" and "stdname" is that the standard name is a
sort of the name as printed, which means that the embedded line
numbers get compared in an odd way. For example, lines 3, 20, and 40
would (if the file names were the same) appear in the string order
"20" "3" and "40". In contrast, "nfl" does a numeric compare of the
line numbers. In fact, sort_stats("nfl") is the same as
sort_stats("name", "file", "line").
-T <filename>: save profile results as shown on screen to a text
file. The profile is still shown on screen.
-D <filename>: save (via dump_stats) profile statistics to given
filename. This data is in a format understood by the pstats module, and
is generated by a call to the dump_stats() method of profile
objects. The profile is still shown on screen.
-q: suppress output to the pager. Best used with -T and/or -D above.
If you want to run complete programs under the profiler's control, use
'%run -p [prof_opts] filename.py [args to program]' where prof_opts
contains profiler specific options as described here.
You can read the complete documentation for the profile module with::
In [1]: import profile; profile.help()
"""
opts_def = Struct(D=[''],l=[],s=['time'],T=[''])
if user_mode: # regular user call
opts,arg_str = self.parse_options(parameter_s,'D:l:rs:T:q',
list_all=True, posix=False)
namespace = self.shell.user_ns
if cell is not None:
arg_str += '\n' + cell
else: # called to run a program by %run -p
try:
filename = get_py_filename(arg_lst[0])
except IOError as e:
try:
msg = str(e)
except UnicodeError:
msg = e.message
error(msg)
return
arg_str = 'execfile(filename,prog_ns)'
namespace = {
'execfile': self.shell.safe_execfile,
'prog_ns': prog_ns,
'filename': filename
}
opts.merge(opts_def)
prof = profile.Profile()
try:
prof = prof.runctx(arg_str,namespace,namespace)
sys_exit = ''
except SystemExit:
sys_exit = """*** SystemExit exception caught in code being profiled."""
stats = pstats.Stats(prof).strip_dirs().sort_stats(*opts.s)
lims = opts.l
if lims:
lims = [] # rebuild lims with ints/floats/strings
for lim in opts.l:
try:
lims.append(int(lim))
except ValueError:
try:
lims.append(float(lim))
except ValueError:
lims.append(lim)
# Trap output.
stdout_trap = StringIO()
if hasattr(stats,'stream'):
# In newer versions of python, the stats object has a 'stream'
# attribute to write into.
stats.stream = stdout_trap
stats.print_stats(*lims)
else:
# For older versions, we manually redirect stdout during printing
sys_stdout = sys.stdout
try:
sys.stdout = stdout_trap
stats.print_stats(*lims)
finally:
sys.stdout = sys_stdout
output = stdout_trap.getvalue()
output = output.rstrip()
if 'q' not in opts:
page.page(output)
print sys_exit,
dump_file = opts.D[0]
text_file = opts.T[0]
if dump_file:
dump_file = unquote_filename(dump_file)
prof.dump_stats(dump_file)
print '\n*** Profile stats marshalled to file',\
repr(dump_file)+'.',sys_exit
if text_file:
text_file = unquote_filename(text_file)
pfile = open(text_file,'w')
pfile.write(output)
pfile.close()
print '\n*** Profile printout saved to text file',\
repr(text_file)+'.',sys_exit
if opts.has_key('r'):
return stats
else:
return None
@line_magic
def pdb(self, parameter_s=''):
"""Control the automatic calling of the pdb interactive debugger.
Call as '%pdb on', '%pdb 1', '%pdb off' or '%pdb 0'. If called without
argument it works as a toggle.
When an exception is triggered, IPython can optionally call the
interactive pdb debugger after the traceback printout. %pdb toggles
this feature on and off.
The initial state of this feature is set in your configuration
file (the option is ``InteractiveShell.pdb``).
If you want to just activate the debugger AFTER an exception has fired,
without having to type '%pdb on' and rerunning your code, you can use
the %debug magic."""
par = parameter_s.strip().lower()
if par:
try:
new_pdb = {'off':0,'0':0,'on':1,'1':1}[par]
except KeyError:
print ('Incorrect argument. Use on/1, off/0, '
'or nothing for a toggle.')
return
else:
# toggle
new_pdb = not self.shell.call_pdb
# set on the shell
self.shell.call_pdb = new_pdb
print 'Automatic pdb calling has been turned',on_off(new_pdb)
@line_magic
def debug(self, parameter_s=''):
"""Activate the interactive debugger in post-mortem mode.
If an exception has just occurred, this lets you inspect its stack
frames interactively. Note that this will always work only on the last
traceback that occurred, so you must call this quickly after an
exception that you wish to inspect has fired, because if another one
occurs, it clobbers the previous one.
If you want IPython to automatically do this on every exception, see
the %pdb magic for more details.
"""
self.shell.debugger(force=True)
@line_magic
def tb(self, s):
"""Print the last traceback with the currently active exception mode.
See %xmode for changing exception reporting modes."""
self.shell.showtraceback()
@skip_doctest
@line_magic
def run(self, parameter_s='', runner=None,
file_finder=get_py_filename):
"""Run the named file inside IPython as a program.
Usage:\\
%run [-n -i -t [-N<N>] -d [-b<N>] -p [profile options]] file [args]
Parameters after the filename are passed as command-line arguments to
the program (put in sys.argv). Then, control returns to IPython's
prompt.
This is similar to running at a system prompt:\\
$ python file args\\
but with the advantage of giving you IPython's tracebacks, and of
loading all variables into your interactive namespace for further use
(unless -p is used, see below).
The file is executed in a namespace initially consisting only of
__name__=='__main__' and sys.argv constructed as indicated. It thus
sees its environment as if it were being run as a stand-alone program
(except for sharing global objects such as previously imported
modules). But after execution, the IPython interactive namespace gets
updated with all variables defined in the program (except for __name__
and sys.argv). This allows for very convenient loading of code for
interactive work, while giving each program a 'clean sheet' to run in.
Options:
-n: __name__ is NOT set to '__main__', but to the running file's name
without extension (as python does under import). This allows running
scripts and reloading the definitions in them without calling code
protected by an ' if __name__ == "__main__" ' clause.
-i: run the file in IPython's namespace instead of an empty one. This
is useful if you are experimenting with code written in a text editor
which depends on variables defined interactively.
-e: ignore sys.exit() calls or SystemExit exceptions in the script
being run. This is particularly useful if IPython is being used to
run unittests, which always exit with a sys.exit() call. In such
cases you are interested in the output of the test results, not in
seeing a traceback of the unittest module.
-t: print timing information at the end of the run. IPython will give
you an estimated CPU time consumption for your script, which under
Unix uses the resource module to avoid the wraparound problems of
time.clock(). Under Unix, an estimate of time spent on system tasks
is also given (for Windows platforms this is reported as 0.0).
If -t is given, an additional -N<N> option can be given, where <N>
must be an integer indicating how many times you want the script to
run. The final timing report will include total and per run results.
For example (testing the script uniq_stable.py)::
In [1]: run -t uniq_stable
IPython CPU timings (estimated):\\
User : 0.19597 s.\\
System: 0.0 s.\\
In [2]: run -t -N5 uniq_stable
IPython CPU timings (estimated):\\
Total runs performed: 5\\
Times : Total Per run\\
User : 0.910862 s, 0.1821724 s.\\
System: 0.0 s, 0.0 s.
-d: run your program under the control of pdb, the Python debugger.
This allows you to execute your program step by step, watch variables,
etc. Internally, what IPython does is similar to calling:
pdb.run('execfile("YOURFILENAME")')
with a breakpoint set on line 1 of your file. You can change the line
number for this automatic breakpoint to be <N> by using the -bN option
(where N must be an integer). For example::
%run -d -b40 myscript
will set the first breakpoint at line 40 in myscript.py. Note that
the first breakpoint must be set on a line which actually does
something (not a comment or docstring) for it to stop execution.
When the pdb debugger starts, you will see a (Pdb) prompt. You must
first enter 'c' (without quotes) to start execution up to the first
breakpoint.
Entering 'help' gives information about the use of the debugger. You
can easily see pdb's full documentation with "import pdb;pdb.help()"
at a prompt.
-p: run program under the control of the Python profiler module (which
prints a detailed report of execution times, function calls, etc).
You can pass other options after -p which affect the behavior of the
profiler itself. See the docs for %prun for details.
In this mode, the program's variables do NOT propagate back to the
IPython interactive namespace (because they remain in the namespace
where the profiler executes them).
Internally this triggers a call to %prun, see its documentation for
details on the options available specifically for profiling.
There is one special usage for which the text above doesn't apply:
if the filename ends with .ipy, the file is run as ipython script,
just as if the commands were written on IPython prompt.
-m: specify module name to load instead of script path. Similar to
the -m option for the python interpreter. Use this option last if you
want to combine with other %run options. Unlike the python interpreter
only source modules are allowed no .pyc or .pyo files.
For example::
%run -m example
will run the example module.
"""
# get arguments and set sys.argv for program to be run.
opts, arg_lst = self.parse_options(parameter_s, 'nidtN:b:pD:l:rs:T:em:',
mode='list', list_all=1)
if "m" in opts:
modulename = opts["m"][0]
modpath = find_mod(modulename)
if modpath is None:
warn('%r is not a valid modulename on sys.path'%modulename)
return
arg_lst = [modpath] + arg_lst
try:
filename = file_finder(arg_lst[0])
except IndexError:
warn('you must provide at least a filename.')
print '\n%run:\n', oinspect.getdoc(self.run)
return
except IOError as e:
try:
msg = str(e)
except UnicodeError:
msg = e.message
error(msg)
return
if filename.lower().endswith('.ipy'):
self.shell.safe_execfile_ipy(filename)
return
# Control the response to exit() calls made by the script being run
exit_ignore = 'e' in opts
# Make sure that the running script gets a proper sys.argv as if it
# were run from a system shell.
save_argv = sys.argv # save it for later restoring
# simulate shell expansion on arguments, at least tilde expansion
args = [ os.path.expanduser(a) for a in arg_lst[1:] ]
sys.argv = [filename] + args # put in the proper filename
# protect sys.argv from potential unicode strings on Python 2:
if not py3compat.PY3:
sys.argv = [ py3compat.cast_bytes(a) for a in sys.argv ]
if 'i' in opts:
# Run in user's interactive namespace
prog_ns = self.shell.user_ns
__name__save = self.shell.user_ns['__name__']
prog_ns['__name__'] = '__main__'
main_mod = self.shell.new_main_mod(prog_ns)
else:
# Run in a fresh, empty namespace
if 'n' in opts:
name = os.path.splitext(os.path.basename(filename))[0]
else:
name = '__main__'
main_mod = self.shell.new_main_mod()
prog_ns = main_mod.__dict__
prog_ns['__name__'] = name
# Since '%run foo' emulates 'python foo.py' at the cmd line, we must
# set the __file__ global in the script's namespace
prog_ns['__file__'] = filename
# pickle fix. See interactiveshell for an explanation. But we need to
# make sure that, if we overwrite __main__, we replace it at the end
main_mod_name = prog_ns['__name__']
if main_mod_name == '__main__':
restore_main = sys.modules['__main__']
else:
restore_main = False
# This needs to be undone at the end to prevent holding references to
# every single object ever created.
sys.modules[main_mod_name] = main_mod
try:
stats = None
with self.shell.readline_no_record:
if 'p' in opts:
stats = self.prun('', None, False, opts, arg_lst, prog_ns)
else:
if 'd' in opts:
deb = debugger.Pdb(self.shell.colors)
# reset Breakpoint state, which is moronically kept
# in a class
bdb.Breakpoint.next = 1
bdb.Breakpoint.bplist = {}
bdb.Breakpoint.bpbynumber = [None]
# Set an initial breakpoint to stop execution
maxtries = 10
bp = int(opts.get('b', [1])[0])
checkline = deb.checkline(filename, bp)
if not checkline:
for bp in range(bp + 1, bp + maxtries + 1):
if deb.checkline(filename, bp):
break
else:
msg = ("\nI failed to find a valid line to set "
"a breakpoint\n"
"after trying up to line: %s.\n"
"Please set a valid breakpoint manually "
"with the -b option." % bp)
error(msg)
return
# if we find a good linenumber, set the breakpoint
deb.do_break('%s:%s' % (filename, bp))
# Start file run
print "NOTE: Enter 'c' at the",
print "%s prompt to start your script." % deb.prompt
ns = {'execfile': py3compat.execfile, 'prog_ns': prog_ns}
try:
deb.run('execfile("%s", prog_ns)' % filename, ns)
except:
etype, value, tb = sys.exc_info()
# Skip three frames in the traceback: the %run one,
# one inside bdb.py, and the command-line typed by the
# user (run by exec in pdb itself).
self.shell.InteractiveTB(etype, value, tb, tb_offset=3)
else:
if runner is None:
runner = self.default_runner
if runner is None:
runner = self.shell.safe_execfile
if 't' in opts:
# timed execution
try:
nruns = int(opts['N'][0])
if nruns < 1:
error('Number of runs must be >=1')
return
except (KeyError):
nruns = 1
twall0 = time.time()
if nruns == 1:
t0 = clock2()
runner(filename, prog_ns, prog_ns,
exit_ignore=exit_ignore)
t1 = clock2()
t_usr = t1[0] - t0[0]
t_sys = t1[1] - t0[1]
print "\nIPython CPU timings (estimated):"
print " User : %10.2f s." % t_usr
print " System : %10.2f s." % t_sys
else:
runs = range(nruns)
t0 = clock2()
for nr in runs:
runner(filename, prog_ns, prog_ns,
exit_ignore=exit_ignore)
t1 = clock2()
t_usr = t1[0] - t0[0]
t_sys = t1[1] - t0[1]
print "\nIPython CPU timings (estimated):"
print "Total runs performed:", nruns
print " Times : %10.2f %10.2f" % ('Total', 'Per run')
print " User : %10.2f s, %10.2f s." % (t_usr, t_usr / nruns)
print " System : %10.2f s, %10.2f s." % (t_sys, t_sys / nruns)
twall1 = time.time()
print "Wall time: %10.2f s." % (twall1 - twall0)
else:
# regular execution
runner(filename, prog_ns, prog_ns, exit_ignore=exit_ignore)
if 'i' in opts:
self.shell.user_ns['__name__'] = __name__save
else:
# The shell MUST hold a reference to prog_ns so after %run
# exits, the python deletion mechanism doesn't zero it out
# (leaving dangling references).
self.shell.cache_main_mod(prog_ns, filename)
# update IPython interactive namespace
# Some forms of read errors on the file may mean the
# __name__ key was never set; using pop we don't have to
# worry about a possible KeyError.
prog_ns.pop('__name__', None)
self.shell.user_ns.update(prog_ns)
finally:
# It's a bit of a mystery why, but __builtins__ can change from
# being a module to becoming a dict missing some key data after
# %run. As best I can see, this is NOT something IPython is doing
# at all, and similar problems have been reported before:
# http://coding.derkeiler.com/Archive/Python/comp.lang.python/2004-10/0188.html
# Since this seems to be done by the interpreter itself, the best
# we can do is to at least restore __builtins__ for the user on
# exit.
self.shell.user_ns['__builtins__'] = builtin_mod
# Ensure key global structures are restored
sys.argv = save_argv
if restore_main:
sys.modules['__main__'] = restore_main
else:
# Remove from sys.modules the reference to main_mod we'd
# added. Otherwise it will trap references to objects
# contained therein.
del sys.modules[main_mod_name]
return stats
@skip_doctest
@line_cell_magic
def timeit(self, line='', cell=None):
"""Time execution of a Python statement or expression
Usage, in line mode:
%timeit [-n<N> -r<R> [-t|-c]] statement
or in cell mode:
%%timeit [-n<N> -r<R> [-t|-c]] setup_code
code
code...
Time execution of a Python statement or expression using the timeit
module. This function can be used both as a line and cell magic:
- In line mode you can time a single-line statement (though multiple
ones can be chained with using semicolons).
- In cell mode, the statement in the first line is used as setup code
(executed but not timed) and the body of the cell is timed. The cell
body has access to any variables created in the setup code.
Options:
-n<N>: execute the given statement <N> times in a loop. If this value
is not given, a fitting value is chosen.
-r<R>: repeat the loop iteration <R> times and take the best result.
Default: 3
-t: use time.time to measure the time, which is the default on Unix.
This function measures wall time.
-c: use time.clock to measure the time, which is the default on
Windows and measures wall time. On Unix, resource.getrusage is used
instead and returns the CPU user time.
-p<P>: use a precision of <P> digits to display the timing result.
Default: 3
Examples
--------
::
In [1]: %timeit pass
10000000 loops, best of 3: 53.3 ns per loop
In [2]: u = None
In [3]: %timeit u is None
10000000 loops, best of 3: 184 ns per loop
In [4]: %timeit -r 4 u == None
1000000 loops, best of 4: 242 ns per loop
In [5]: import time
In [6]: %timeit -n1 time.sleep(2)
1 loops, best of 3: 2 s per loop
The times reported by %timeit will be slightly higher than those
reported by the timeit.py script when variables are accessed. This is
due to the fact that %timeit executes the statement in the namespace
of the shell, compared with timeit.py, which uses a single setup
statement to import function or create variables. Generally, the bias
does not matter as long as results from timeit.py are not mixed with
those from %timeit."""
import timeit
import math
# XXX: Unfortunately the unicode 'micro' symbol can cause problems in
# certain terminals. Until we figure out a robust way of
# auto-detecting if the terminal can deal with it, use plain 'us' for
# microseconds. I am really NOT happy about disabling the proper
# 'micro' prefix, but crashing is worse... If anyone knows what the
# right solution for this is, I'm all ears...
#
# Note: using
#
# s = u'\xb5'
# s.encode(sys.getdefaultencoding())
#
# is not sufficient, as I've seen terminals where that fails but
# print s
#
# succeeds
#
# See bug: https://bugs.launchpad.net/ipython/+bug/348466
#units = [u"s", u"ms",u'\xb5',"ns"]
units = [u"s", u"ms",u'us',"ns"]
scaling = [1, 1e3, 1e6, 1e9]
opts, stmt = self.parse_options(line,'n:r:tcp:',
posix=False, strict=False)
if stmt == "" and cell is None:
return
timefunc = timeit.default_timer
number = int(getattr(opts, "n", 0))
repeat = int(getattr(opts, "r", timeit.default_repeat))
precision = int(getattr(opts, "p", 3))
if hasattr(opts, "t"):
timefunc = time.time
if hasattr(opts, "c"):
timefunc = clock
timer = timeit.Timer(timer=timefunc)
# this code has tight coupling to the inner workings of timeit.Timer,
# but is there a better way to achieve that the code stmt has access
# to the shell namespace?
transform = self.shell.input_splitter.transform_cell
if cell is None:
# called as line magic
setup = 'pass'
stmt = timeit.reindent(transform(stmt), 8)
else:
setup = timeit.reindent(transform(stmt), 4)
stmt = timeit.reindent(transform(cell), 8)
# From Python 3.3, this template uses new-style string formatting.
if sys.version_info >= (3, 3):
src = timeit.template.format(stmt=stmt, setup=setup)
else:
src = timeit.template % dict(stmt=stmt, setup=setup)
# Track compilation time so it can be reported if too long
# Minimum time above which compilation time will be reported
tc_min = 0.1
t0 = clock()
code = compile(src, "<magic-timeit>", "exec")
tc = clock()-t0
ns = {}
exec code in self.shell.user_ns, ns
timer.inner = ns["inner"]
if number == 0:
# determine number so that 0.2 <= total time < 2.0
number = 1
for i in range(1, 10):
if timer.timeit(number) >= 0.2:
break
number *= 10
best = min(timer.repeat(repeat, number)) / number
if best > 0.0 and best < 1000.0:
order = min(-int(math.floor(math.log10(best)) // 3), 3)
elif best >= 1000.0:
order = 0
else:
order = 3
print u"%d loops, best of %d: %.*g %s per loop" % (number, repeat,
precision,
best * scaling[order],
units[order])
if tc > tc_min:
print "Compiler time: %.2f s" % tc
@skip_doctest
@needs_local_scope
@line_magic
def time(self,parameter_s, user_locals):
"""Time execution of a Python statement or expression.
The CPU and wall clock times are printed, and the value of the
expression (if any) is returned. Note that under Win32, system time
is always reported as 0, since it can not be measured.
This function provides very basic timing functionality. In Python
2.3, the timeit module offers more control and sophistication, so this
could be rewritten to use it (patches welcome).
Examples
--------
::
In [1]: time 2**128
CPU times: user 0.00 s, sys: 0.00 s, total: 0.00 s
Wall time: 0.00
Out[1]: 340282366920938463463374607431768211456L
In [2]: n = 1000000
In [3]: time sum(range(n))
CPU times: user 1.20 s, sys: 0.05 s, total: 1.25 s
Wall time: 1.37
Out[3]: 499999500000L
In [4]: time print 'hello world'
hello world
CPU times: user 0.00 s, sys: 0.00 s, total: 0.00 s
Wall time: 0.00
Note that the time needed by Python to compile the given expression
will be reported if it is more than 0.1s. In this example, the
actual exponentiation is done by Python at compilation time, so while
the expression can take a noticeable amount of time to compute, that
time is purely due to the compilation:
In [5]: time 3**9999;
CPU times: user 0.00 s, sys: 0.00 s, total: 0.00 s
Wall time: 0.00 s
In [6]: time 3**999999;
CPU times: user 0.00 s, sys: 0.00 s, total: 0.00 s
Wall time: 0.00 s
Compiler : 0.78 s
"""
# fail immediately if the given expression can't be compiled
expr = self.shell.prefilter(parameter_s,False)
# Minimum time above which compilation time will be reported
tc_min = 0.1
try:
mode = 'eval'
t0 = clock()
code = compile(expr,'<timed eval>',mode)
tc = clock()-t0
except SyntaxError:
mode = 'exec'
t0 = clock()
code = compile(expr,'<timed exec>',mode)
tc = clock()-t0
# skew measurement as little as possible
glob = self.shell.user_ns
wtime = time.time
# time execution
wall_st = wtime()
if mode=='eval':
st = clock2()
out = eval(code, glob, user_locals)
end = clock2()
else:
st = clock2()
exec code in glob, user_locals
end = clock2()
out = None
wall_end = wtime()
# Compute actual times and report
wall_time = wall_end-wall_st
cpu_user = end[0]-st[0]
cpu_sys = end[1]-st[1]
cpu_tot = cpu_user+cpu_sys
print "CPU times: user %.2f s, sys: %.2f s, total: %.2f s" % \
(cpu_user,cpu_sys,cpu_tot)
print "Wall time: %.2f s" % wall_time
if tc > tc_min:
print "Compiler : %.2f s" % tc
return out
@skip_doctest
@line_magic
def macro(self, parameter_s=''):
"""Define a macro for future re-execution. It accepts ranges of history,
filenames or string objects.
Usage:\\
%macro [options] name n1-n2 n3-n4 ... n5 .. n6 ...
Options:
-r: use 'raw' input. By default, the 'processed' history is used,
so that magics are loaded in their transformed version to valid
Python. If this option is given, the raw input as typed as the
command line is used instead.
This will define a global variable called `name` which is a string
made of joining the slices and lines you specify (n1,n2,... numbers
above) from your input history into a single string. This variable
acts like an automatic function which re-executes those lines as if
you had typed them. You just type 'name' at the prompt and the code
executes.
The syntax for indicating input ranges is described in %history.
Note: as a 'hidden' feature, you can also use traditional python slice
notation, where N:M means numbers N through M-1.
For example, if your history contains (%hist prints it)::
44: x=1
45: y=3
46: z=x+y
47: print x
48: a=5
49: print 'x',x,'y',y
you can create a macro with lines 44 through 47 (included) and line 49
called my_macro with::
In [55]: %macro my_macro 44-47 49
Now, typing `my_macro` (without quotes) will re-execute all this code
in one pass.
You don't need to give the line-numbers in order, and any given line
number can appear multiple times. You can assemble macros with any
lines from your input history in any order.
The macro is a simple object which holds its value in an attribute,
but IPython's display system checks for macros and executes them as
code instead of printing them when you type their name.
You can view a macro's contents by explicitly printing it with::
print macro_name
"""
opts,args = self.parse_options(parameter_s,'r',mode='list')
if not args: # List existing macros
return sorted(k for k,v in self.shell.user_ns.iteritems() if\
isinstance(v, Macro))
if len(args) == 1:
raise UsageError(
"%macro insufficient args; usage '%macro name n1-n2 n3-4...")
name, codefrom = args[0], " ".join(args[1:])
#print 'rng',ranges # dbg
try:
lines = self.shell.find_user_code(codefrom, 'r' in opts)
except (ValueError, TypeError) as e:
print e.args[0]
return
macro = Macro(lines)
self.shell.define_macro(name, macro)
print 'Macro `%s` created. To execute, type its name (without quotes).' % name
print '=== Macro contents: ==='
print macro,
@magic_arguments.magic_arguments()
@magic_arguments.argument('output', type=str, default='', nargs='?',
help="""The name of the variable in which to store output.
This is a utils.io.CapturedIO object with stdout/err attributes
for the text of the captured output.
CapturedOutput also has a show() method for displaying the output,
and __call__ as well, so you can use that to quickly display the
output.
If unspecified, captured output is discarded.
"""
)
@magic_arguments.argument('--no-stderr', action="store_true",
help="""Don't capture stderr."""
)
@magic_arguments.argument('--no-stdout', action="store_true",
help="""Don't capture stdout."""
)
@cell_magic
def capture(self, line, cell):
"""run the cell, capturing stdout/err"""
args = magic_arguments.parse_argstring(self.capture, line)
out = not args.no_stdout
err = not args.no_stderr
with capture_output(out, err) as io:
self.shell.run_cell(cell)
if args.output:
self.shell.user_ns[args.output] = io